U.S. patent application number 14/771611 was filed with the patent office on 2016-01-07 for insect trap device and method of using.
The applicant listed for this patent is ARTHROPOD BIOSCIENCES, LLC. Invention is credited to Daniel LAZARCHIK, Lars LIEBERWIRTH, Andrew SANDFORD, Hans Peter SCHAEFER.
Application Number | 20160000060 14/771611 |
Document ID | / |
Family ID | 51428825 |
Filed Date | 2016-01-07 |
United States Patent
Application |
20160000060 |
Kind Code |
A1 |
SANDFORD; Andrew ; et
al. |
January 7, 2016 |
INSECT TRAP DEVICE AND METHOD OF USING
Abstract
An insect trap device and methods of using the device are
described herein. In some embodiments, an insect trap includes a
light source, a removable enclosure with at least one opening, an
adhesive surface at least partially within the enclosure, and
optics to redirect light from the light source onto an adhesive
trapping surface. The light source may include at least one light
emitting diode (LED). The optics may be attached to the removable
enclosure, and may be located at least partially within the
enclosure. The optics may include optical enhancers such as a
reflector, a lens and/or a diffuser. The insect trap may further
include an insect attractant that emits sound or scent.
Inventors: |
SANDFORD; Andrew;
(Marlborough, MA) ; LAZARCHIK; Daniel; (South
Boston, MA) ; LIEBERWIRTH; Lars; (Shanghai, CN)
; SCHAEFER; Hans Peter; (Wayland, MA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
ARTHROPOD BIOSCIENCES, LLC |
Marlborough |
MA |
US |
|
|
Family ID: |
51428825 |
Appl. No.: |
14/771611 |
Filed: |
February 28, 2014 |
PCT Filed: |
February 28, 2014 |
PCT NO: |
PCT/US2014/019175 |
371 Date: |
August 31, 2015 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
61771774 |
Mar 1, 2013 |
|
|
|
61787629 |
Mar 15, 2013 |
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Current U.S.
Class: |
43/113 ; 29/428;
361/641; 43/114; 43/132.1 |
Current CPC
Class: |
A01M 1/145 20130101;
A01M 1/02 20130101; A01M 1/106 20130101; A01M 1/04 20130101; A01M
1/14 20130101; A01M 1/023 20130101 |
International
Class: |
A01M 1/14 20060101
A01M001/14; A01M 1/10 20060101 A01M001/10; A01M 1/04 20060101
A01M001/04 |
Claims
1. An insect trap comprising: a trap portion including an enclosure
having an adhesive surface and a first opening, wherein the
adhesive surface is at least partially contained within the
enclosure and is configured to adhere to an insect; and a base
portion including a lighting element and a mounting portion,
wherein the lighting element is configured to provide light to the
trap portion, and wherein the mounting portion is configured to
communicate with and receive power from a power source; wherein the
trap portion is configured to removably engage with the base
portion and receive light from the base portion when engaged
therewith.
2-69. (canceled)
70. An insect trap comprising: a trap portion including: an
enclosure having an adhesive surface and a first opening, wherein
the adhesive surface is at least partially contained within the
enclosure and is configured to adhere to an insect, and a lighting
element at least partially contained within the enclosure, wherein
the lighting element is configured to provide light within the
enclosure and wherein the lighting element is configured to
communicate with and receive power from a power source; and a base
portion configured to removably engage the trap portion and provide
access to the power source.
71-73. (canceled)
74. A removable insect trap cartridge comprising: an enclosure
defining the cartridge, the enclosure having an adhesive surface
and a first opening, wherein the adhesive surface is at least
partially contained within the enclosure and is configured to
adhere to an insect, wherein the first opening is configured to
allow an insect to enter the enclosure, and wherein the enclosure
is configured to provide light in a predetermined pattern within
the enclosure.
75-102. (canceled)
103. A method comprising: providing a base portion of an insect
trap; providing a first trap portion of an insect trap, wherein the
first trap portion comprises an opening; mounting the first trap
portion to the base portion; coupling the base portion to a power
source to provide power to a lighting element, wherein the lighting
element is within the base portion or first trap portion and
wherein the lighting element is configured to attract an insect
into the first trap portion; and receiving an insect into the first
trap portion through the opening.
104-111. (canceled)
112. A docking apparatus comprising: a docking structure configured
to activate in response to a docking activator, the docking
activator located on a separate piece configured to engage the
docking structure, wherein the docking structure is in
communication with a power source and is configured to control
power to a lighting element.
113-116. (canceled)
117. A removable insect trap cartridge comprising: an enclosure
defining the cartridge, the enclosure having an adhesive surface
and a first opening, wherein the adhesive surface is at least
partially contained within the enclosure and is configured to
adhere to an insect, and a docking activator, the docking activator
configured to engage a docking structure in a mounting portion.
118. An insect trap portion, comprising: a front enclosure; a rear
enclosure; a divider comprising an adhesive, wherein the divider
separates the insect trap portion into the front enclosure and the
rear enclosure; and a first opening through which an insect may fly
or crawl into the front enclosure.
119. The insect trap portion according to claim 118, wherein the
adhesive is transparent or translucent.
120. The insect trap portion according to claim 118, wherein the
insect trap portion further comprises a second opening or window
through which light from the lighting element is transmitted into
the rear enclosure when the insect trap portion engages the base
portion.
121. The insect trap portion according to claim 120, wherein the
first opening is formed in the front housing and the second opening
or window is formed in a bottom surface of the rear housing.
122. The insect trap portion according to claim 118, wherein the
insect trap portion further comprises an insect attractant.
123. The insect trap portion according to claim 118, wherein the
divider further comprises a transparent or translucent material
onto which the adhesive is coated.
124. An insect trap comprising a base portion and an insect trap
portion according to claim 118, wherein the base portion comprises
the lighting element and electrically conductive prongs insertable
into an electric socket.
125. The insect trap portion according to claim 118, wherein the
insect trap further comprises a transparent or translucent window
(128) through which light from the lighting element is
transmitted.
126. The insect trap portion according to claim 118, wherein the
base portion further comprises a slot in a top surface of the base
portion that engages the insect trap portion when the insect trap
portion is mounted on the base portion.
127. The insect trap portion according to claim 118, wherein the
base portion further comprises protrusions on the top surface that
engage the insect trap portion when the insect trap portion is
mounted on the base portion.
128. A method of making an insect trap portion according to claim
118, comprising: forming a front housing comprising a first opening
through which an insect may fly or crawl; forming a rear housing;
forming a divider comprising an adhesive; and joining together the
front housing, the rear housing and the divider.
129. An insect trap, comprising: a base portion comprising a
lighting element, electrically conductive prongs and an upstanding
rear housing; and an insect trap portion removably mounted to the
base portion, the insect trap portion comprising an adhesive and an
opening through which an insect may fly or crawl into the insect
trap portion, wherein light emitted from the lighting element is
transmitted through the adhesive.
130. A method of using an insect trap according to claim 129,
comprising: inserting the insect trap portion into the base
portion; emitting light from the lighting element of the base
portion; transmitting the light through the adhesive; trapping
insects in the adhesive; removing the insect trap portion from the
base portion; discarding the entire insect trap portion without
touching the trapped insects or adhesive; and inserting a new
insect trap portion into the base portion.
131. An insect trap, comprising: an insect trap portion and a base
portion, the base portion comprising a lighting element and a
switch, and the insect trap portion comprising: an enclosure
comprising an adhesive and a first opening through which an insect
may fly or crawl into the insect trap portion; and a downwardly
protruding tab that displaces the switch of a base portion to close
the switch when the insect trap portion is mounted on the base
portion.
132. A method of using an insect trap according to claim 131,
comprising: mounting an insect trap portion on the base portion,
wherein the base portion further comprises electrically conductive
prongs insertable into an electric socket, the tab displacing the
switch of the base portion to close the switch and activating the
light emitting element when the switch is closed.
133. A method of using an insect trap, comprising: a) inserting an
insect trap portion into a base portion, the insect trap portion
comprising an adhesive and the base portion comprising a lighting
element; b) emitting light from the lighting element of the base
portion, wherein the light is transmitted through the adhesive; c)
trapping insects in the adhesive; d) removing the insect trap
portion from the base portion; e) discarding the entire insect trap
portion without touching the trapped insects or the adhesive; and
f) inserting a new insect trap portion into the base portion.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] The present application claims the benefit of U.S.
provisional patent application No. 61/771,774, entitled "Insect
Trap Device and Method of Using" filed Mar. 1, 2013, and U.S.
provisional patent application No. 61/787,629, entitled "Insect
Trap Device and Method of Using" filed Mar. 15, 2013, which are
incorporated herein by reference in their entirety.
TECHNICAL FIELD
[0002] The present disclosure is related generally to an insect
trap, more particularly, to a removable insect trap having a
minimal footprint and an aesthetically pleasing design.
BACKGROUND
[0003] Flying insect pests have long been a nuisance and a health
hazard. Since ancient times, insect traps have been used to
eliminate flying insects, and hundreds of different traps have been
proposed and developed over the centuries. There has always been a
need to eliminate flies and mosquitoes that inevitably find their
way into homes. Recent US outbreaks of Eastern Equine Encephalitis,
West Nile virus and harmful E. Coli infections, public health
threats that can be spread by flying insects, have only increased
this need. Because insects may see and be attracted to a
combination of ultraviolet (UV) and visible light, an indoor insect
trap may have its own UV and visible light sources. Insect traps
commonly have a fluorescent tube that emits both UV and visible
light to attract insects and a glue board to trap them. However,
insect traps incorporating fluorescent tubes and the transformers
that power them may be too large to fit wherever they're needed and
too expensive to afford one for every room in the house. In
addition, insects may contact the fluorescent tube and over time it
may accumulate dust and insect debris, blocking the light and
reducing the trap's effectiveness. Furthermore, the glue board may
be difficult to remove and replace without touching trapped insects
and adhesive.
SUMMARY
[0004] An insect trap device and methods of using the device are
described herein. The insect trap may effectively attract and trap
insects indoors and may be manufactured and sold at a lower cost
than commercially available traps. The insect trap device may be
smaller than competing indoor insect traps, and may be conveniently
movable from one location to another. The insect trap device may be
easier to clean and maintain without contacting trapped
insects.
[0005] In a first aspect, an insect trap is disclosed including: a
trap portion including an enclosure having an adhesive surface and
a first opening, wherein the adhesive surface is at least partially
contained within the enclosure and is configured to adhere to an
insect; and a base portion including a lighting element and a
mounting portion, wherein the lighting element is configured to
provide light to the trap portion, and wherein the mounting portion
is configured to communicate with and receive power from a power
source; wherein the trap portion is configured to removably engage
with the base portion and receive light from the base portion when
engaged therewith. In an embodiment of the first aspect, the first
opening is configured to allow an insect to enter into the
enclosure. In an embodiment of the first aspect, the enclosure
includes a second opening, the second opening configured to allow
light to emit from the enclosure. In an embodiment of the first
aspect, within the base portion, the light is not manipulated. In
an embodiment of the first aspect, the enclosure includes a third
opening, the third opening configured to allow light to be received
from base portion into the enclosure. In an embodiment of the first
aspect, wherein the enclosure is configured to distribute the light
in a predetermined pattern. In an embodiment of the first aspect,
the enclosure includes: a front housing portion having a first
internal surface; and a rear housing portion having a second
internal surface, wherein the front housing portion and rear
housing portion are matingly engaged with each other to form the
enclosure; and wherein at least one of the first or second internal
surfaces is configured to manipulate light. In an embodiment of the
first aspect, at least one of the first or second internal surfaces
includes an adhesive surface. In an embodiment of the first aspect,
the rear housing portion has a concave surface, the concave surface
configured to reflect light evenly within the enclosure. In an
embodiment of the first aspect, light is transmitted through the
adhesive surface, illuminating the adhesive surface to attract an
insect to the adhesive surface. In an embodiment of the first
aspect, the enclosure includes: a front housing portion having a
first internal surface; a rear housing portion having a second
internal surface; and a divider portion disposed at least partially
between the front housing portion and rear housing portion, wherein
the front housing portion and rear housing portion are matingly
engaged with each other to form the enclosure; and wherein the
divider portion divides the enclosure into a front enclosure
portion and a rear enclosure portion. In an embodiment of the first
aspect, the divider portion includes a rear surface including
translucent material and includes a front surface including an
adhesive surface. In an embodiment of the first aspect, the second
internal surface of the rear housing portion includes a concave
surface, the concave surface configured to reflect light onto the
rear surface of the divider portion. In an embodiment of the first
aspect, light is transmitted through the adhesive surface,
illuminating the adhesive surface to attract an insect to the
adhesive surface. In an embodiment of the first aspect, the rear
surface of the divider portion is configured to receive the light
from the second internal surface of the rear housing portion or
directly from the lighting element. In an embodiment of the first
aspect, the divider portion is configured to receive light at an
oblique angle and spread across the divider portion. In an
embodiment of the first aspect, the divider portion is configured
to manipulate light. In an embodiment of the first aspect, the
divider portion includes a planar or contoured shape, wherein the
shape of the divider portion is configured to optimize light
distribution. In an embodiment of the first aspect, the base
portion includes a protrusion and wherein the trap portion includes
a recess for receiving the protrusion, wherein when the protrusion
is received by the trap portion, the base portion and trap portion
are engaged. In an embodiment of the first aspect, the trap portion
includes a protrusion and wherein the base portion includes a
recess for receiving the protrusion, wherein when the protrusion is
received by the base portion, the base portion and trap portion are
engaged. In an embodiment of the first aspect, the trap portion
includes a polymeric, fibrous, or carbon-based material. In an
embodiment of the first aspect, the mounting portion includes an
electrical plug having rigid conductors protruding substantially
perpendicularly and directly from the rear surface of the mounting
portion, wherein the conductors are insertable into an electrical
power outlet. In an embodiment of the first aspect, the power
source includes an electrical power outlet or a battery. In an
embodiment of the first aspect, the lighting element includes a
light emitting diode (LED). In an embodiment of the first aspect,
the lighting element includes an ultraviolet (UV) LED and a blue
LED. In an embodiment of the first aspect, the base portion
includes an energy stabilizer configured to provide a constant
voltage to the lighting element. In an embodiment of the first
aspect, the energy stabilizer includes full rectifier circuit. In
an embodiment of the first aspect, the base portion includes an
opening, the opening configured to allow light to emit from the
base portion to the trap portion. In an embodiment of the first
aspect, the opening includes a transparent or translucent window.
In an embodiment of the first aspect, the opening is proximate to
the lighting element. In an embodiment of the first aspect, the
trap portion includes an insect attractant. In an embodiment of the
first aspect, the insect attractant is selected from the group
consisting of: sorbitol, coleopteran attractants, dipteran
attractants, homopteran attractants, lepidopteran, straight chain
lepidopteran pheromones, eugenol, methyl eugenol, and siglure. In
an embodiment of the first aspect, the coleopteran attractants
include brevicomin, dominicalure, frontalin, grandlure, ipsdienol,
ipsenol, japonilure, lineatin, megatomoic acid, multistriatin,
oryctalure, sulcatol, and trunc-call. In an embodiment of the first
aspect, the dipteran attractants include ceralure, cue-lure,
latilure, medlure, moguchun, muscalure, and trimedlure. In an
embodiment of the first aspect, the homopteran attractants include
rescalure. In an embodiment of the first aspect, the lepidopteran
attractants include disparlure. In an embodiment of the first
aspect, the straight chain lepidopteran pheromones include
codlelure, gossyplure, hexalure, litlure, looplure, orfralure, and
ostramone. In an embodiment of the first aspect, the insect
attractant is integral to the enclosure. In an embodiment of the
first aspect, the base portion includes a transmitter. In an
embodiment of the first aspect, the transmitter includes a
piezoelectric speaker configured to emit an insect-attracting
sound. In an embodiment of the first aspect, the insect-attracting
sound includes frequencies in the range of approximately 0.2 Hz to
240 KHz. In an embodiment of the first aspect, the base includes a
switch, the switch configured to allow a user to control a property
of the trap. In an embodiment of the first aspect, the property is
selected from the group consisting of: power, light intensity,
light wavelength or frequency, light flickering, light patterns,
and combinations thereof. In an embodiment of the first aspect, the
switch includes a mechanical switch, an optical switch, an
electronic switch, an electromechanical switch, or a Hall effect
sensor. In an embodiment of the first aspect, the enclosure
includes a reflective surface. In an embodiment of the first
aspect, the adhesive surface is proximate to the reflective
surface. In an embodiment of the first aspect, the base portion
includes a circuit configured to a varying voltage to the lighting
element, wherein the lighting element provides intermittent light
to the trap portion. In an embodiment of the first aspect, the
enclosure includes an outer surface, the outer surface at least
partially surrounded by sleeve that is configured to reduce the
amount of light emitted by the enclosure. In an embodiment of the
first aspect, the at least one of the first or second internal
surfaces includes a textured surface, the textured surface
configured to increase the surface area of the enclosure. In an
embodiment of the first aspect, the textured surfaces include ribs
extending at least a portion of the length of the first or second
internal surfaces. In an embodiment of the first aspect, the at
least one of the first or second internal surfaces include a
textured surface, the textured surface configured to increase the
surface area of the enclosure. In an embodiment of the first
aspect, the textured surfaces include ribs extending at least a
portion of the length of the first or second internal surfaces. In
an embodiment of the first aspect, the trap further includes: a
light conducting body located proximate to the second internal
surface of the rear housing portion, the light conducting body
having a front surface and a rear surface and the light conducting
body configured to receive light from the base portion and
distribute the light in a predetermined pattern in the enclosure.
In an embodiment of the first aspect, the front surface of the
light conducting body further includes an adhesive material. In an
embodiment of the first aspect, the rear surface of the light
reflecting body is configured to reduce the amount of light from
being emitted in a predetermined direction. In an embodiment of the
first aspect, the light conducting body is tapered, having a
thicker depth at a portion proximate to the base portion and a
thinner depth at an opposite end. In an embodiment of the first
aspect, the rear surface of the light conducting body is configured
to reflect light into the light conducting body. In an embodiment
of the first aspect, light is reflected multiple times within the
light conducting body before being emitted into the enclosure. In
an embodiment of the first aspect, the rear surface includes a rear
cover or a matte layer. In an embodiment of the first aspect, the
base portion further includes an optical enhancer, the optical
enhancer configured to direct the light into the trap portion in a
predetermined pattern. In an embodiment of the first aspect, the
optical enhancer includes a lens. In an embodiment of the first
aspect, the enclosure includes an inner sleeve and the base portion
includes an outer sleeve, the inner sleeve configured to align with
the outer sleeve. In an embodiment of the first aspect, the outer
sleeve includes a face plate having an opening. In an embodiment of
the first aspect, the face plate opening corresponds to an
enclosure opening, the openings providing an alignment means. In an
embodiment of the first aspect, the inner sleeve is configured to
be dropped into the outer sleeve. In an embodiment of the first
aspect, the inner sleeve includes a tab for holding on to the inner
sleeve. In an embodiment of the first aspect, the base portion
includes a docking switch, the docking switch configured to
activate the lighting element when the trap portion is correctly
engaged with the base portion. In an embodiment of the first
aspect, the trap portion includes a docking switch activator, the
docking switch activator configured to activate the docking switch
when the trap portion is correctly engaged with the base portion.
In an embodiment of the first aspect, the docking switch includes a
mechanical switch, an optical switch, an electronic switch, an
electromechanical switch, or a Hall effect sensor.
[0006] In a second aspect, an insect trap is disclosed including: a
trap portion including: an enclosure having an adhesive surface and
a first opening, wherein the adhesive surface is at least partially
contained within the enclosure and is configured to adhere to an
insect, and a lighting element at least partially contained within
the enclosure, wherein the lighting element is configured to
provide light within the enclosure and wherein the lighting element
is configured to communicate with and receive power from a power
source; and a base portion configured to removably engage the trap
portion and provide access to the power source. In an embodiment of
the second aspect, the lighting element includes a plurality of
electrical trap contacts and wherein the base portion includes a
plurality of electrical base contacts, the trap contacts configured
to communicate with the base contacts to provide power to the
lighting element. In an embodiment of the second aspect, the base
contacts are in communication with the power source. In an
embodiment of the second aspect, the lighting element includes a
light emitting diode (LED).
[0007] In a third aspect, a removable insect trap cartridge is
disclosed including: an enclosure defining the cartridge, the
enclosure having an adhesive surface and a first opening, wherein
the adhesive surface is at least partially contained within the
enclosure and is configured to adhere to an insect, wherein the
first opening is configured to allow an insect to enter the
enclosure, and wherein the enclosure is configured to provide light
in a predetermined pattern within the enclosure. In an embodiment
of the third aspect, the enclosure further includes a lighting
element. In an embodiment of the third aspect, the lighting element
includes a light emitting diode (LED). In an embodiment of the
third aspect, the lighting element includes an ultraviolet (UV) LED
and a blue LED. In an embodiment of the third aspect, the enclosure
includes: a front housing portion having a first internal surface;
and a rear housing portion having a second internal surface,
wherein the front housing portion and rear housing portion are
matingly engaged with each other to form the enclosure; and wherein
at least one of the first or second internal surfaces is configured
to manipulate light. In an embodiment of the third aspect, at least
one of the first or second internal surfaces includes an adhesive
surface. In an embodiment of the third aspect, the rear housing
portion has a concave surface, the concave surface configured to
reflect light evenly within the enclosure. In an embodiment of the
third aspect, light is transmitted through the adhesive surface,
illuminating the adhesive surface to attract an insect to the
adhesive surface. In an embodiment of the third aspect, the
enclosure includes: a front housing portion having a first internal
surface; a rear housing portion having a second internal surface;
and a divider portion disposed at least partially between the front
housing portion and rear housing portion, wherein the front housing
portion and rear housing portion are matingly engaged with each
other to form the enclosure; and wherein the divider portion
divides the enclosure into a front enclosure portion and a rear
enclosure portion. In an embodiment of the third aspect, the
divider portion includes a rear surface having translucent material
and includes a front surface having an adhesive surface. In an
embodiment of the third aspect, the second internal surface of the
rear housing portion includes a concave surface, the concave
surface configured to reflect light onto the rear surface of the
divider portion. In an embodiment of the third aspect, light is
transmitted through the adhesive surface, illuminating the adhesive
surface to attract an insect to the adhesive surface. In an
embodiment of the third aspect, the rear surface of the divider
portion is configured to receive the light from the second internal
surface of the rear housing portion or directly from a lighting
element. In an embodiment of the third aspect, the enclosure
includes a bottom surface, the bottom surface configured to be
removably received in a pluggable base. In an embodiment of the
third aspect, wherein the enclosure includes biodegradable
materials. In an embodiment of the third aspect, the enclosure
includes an outer surface, the outer surface including a decorative
element. In an embodiment of the third aspect, the decorative
element includes a shape selected from the group consisting of: a
flower, a plant, a shell, a company logo, a sports team logo, a
football, a basketball, a soccer ball, a hockey puck, a football
helmet or a hockey stick. In an embodiment of the third aspect, the
trap portion includes an insect attractant. In an embodiment of the
third aspect, the insect attractant is selected from the group
consisting of: sorbitol, coleopteran attractants, dipteran
attractants, homopteran attractants, lepidopteran, straight chain
lepidopteran pheromones, eugenol, methyl eugenol, and siglure. In
an embodiment of the third aspect, the insect attractant is
detectable by an insect at a distance of approximately 2 meters
from the cartridge. In an embodiment of the third aspect, the
enclosure includes a textured surface, the textured surface
configured to increase the surface area of the enclosure. In an
embodiment of the third aspect, the textured surface includes ribs
extending at least a portion of the length of the enclosure. In an
embodiment of the third aspect, the cartridge further includes: a
light conducting body located within the enclosure, the light
conducting body configured to receive light and distribute the
light in a predetermined pattern in the enclosure. In an embodiment
of the third aspect, the enclosure includes an inner sleeve that is
configured to be received into and aligned with an outer sleeve. In
an embodiment of the third aspect, the outer sleeve includes a face
plate having an opening. In an embodiment of the third aspect, the
face plate opening corresponds to an enclosure opening, the
openings providing an alignment means. In an embodiment of the
third aspect, the inner sleeve includes a tab for holding on to the
inner sleeve. In an embodiment of the third aspect, the cartridge
includes a docking switch activator, the docking switch activator
configured to activate a docking switch when the cartridge is
correctly engaged with a base portion. In an embodiment of the
third aspect, the docking switch activator includes a mechanical
switch, an optical switch, an electronic switch, an
electromechanical switch, or a Hall effect sensor.
[0008] In a fourth aspect, a method is disclosed including:
providing a base portion of an insect trap; providing a first trap
portion of an insect trap, wherein the first trap portion includes
an opening; mounting the first trap portion to the base portion;
coupling the base portion to a power source to provide power to a
lighting element, wherein the lighting element is within the base
portion or first trap portion and wherein the lighting element is
configured to attract an insect into the first trap portion; and
receiving an insect into the first trap portion through the
opening. In an embodiment of the fourth aspect, the method further
includes: separating the first trap portion from the base portion;
and disposing of the first trap portion, wherein the insect remains
in the disposed first trap portion. In an embodiment of the fourth
aspect, the first trap portion is disposed without the human
contact with the insect in the first trap portion. In an embodiment
of the fourth aspect, the first trap portion includes an adhesive
surface and wherein the insect adheres to the adhesive surface. In
an embodiment of the fourth aspect, the base portion includes a
docking switch, wherein the docking switch is configured to
activate the lighting element when the first trap portion is
correctly mounted to the base portion. In an embodiment of the
fourth aspect, upon separating the first trap portion from the base
portion, the lighting element is powered off. In an embodiment of
the fourth aspect, upon separating the first trap portion from the
base portion, the lighting element is partially shielded from
emitting light. In an embodiment of the fourth aspect, the method
further includes: providing a second trap portion of an insect
trap, wherein the second trap portion includes an opening; and
mounting the second trap portion to the base portion. In an
embodiment of the fourth aspect, the first insect trap and second
insect trap have different configurations.
[0009] In a fifth aspect, a docking apparatus is disclosed
including: a docking structure configured to activate in response
to a docking activator, the docking activator located on a separate
piece configured to engage the docking structure, wherein the
docking structure is in communication with a power source and is
configured to control power to a lighting element. In an embodiment
of the fifth aspect, the docking activator includes a surface, a
protrusion, a tab or a magnet. In an embodiment of the fifth
aspect, the docking structure is configured to close when the
docking activator engages with it and is configured to open when
the docking activator disengages from it. In an embodiment of the
fifth aspect, the docking structure is configured to activate in
response to pressure from the docking activator. In an embodiment
of the fifth aspect, the docking structure is configured to
activate in response to displacement from the docking
activator.
[0010] In a sixth aspect, a removable insect trap cartridge is
disclosed including: an enclosure defining the cartridge, the
enclosure having an adhesive surface and a first opening, wherein
the adhesive surface is at least partially contained within the
enclosure and is configured to adhere to an insect, and a docking
activator, the docking activator configured to engage a docking
structure in a mounting portion.
[0011] Further objects, features, and advantages of the disclosure
will be apparent from the following detailed description when taken
in conjunction with the following drawings.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS
[0012] While the appended claims set forth the features of the
present techniques with particularity, these techniques, together
with their objects and advantages, may be best understood from the
following detailed description taken in conjunction with the
accompanying drawings of which:
[0013] FIG. 1 is a front perspective view of a first embodiment of
an insect trap in accordance with principles of the disclosure;
[0014] FIG. 2 is a rear perspective view of a base portion of the
insect trap of FIG. 1 with a trap portion removed;
[0015] FIG. 3 is an exploded view of the trap portion of the insect
trap of FIG. 1;
[0016] FIG. 4 is a cross-sectional view through the insect trap of
FIG. 1;
[0017] FIG. 5 is a cross-sectional view through a second embodiment
of an insect trap in accordance with principles of the
disclosure;
[0018] FIG. 6 is a front perspective view of a third embodiment of
an insect trap in accordance with principles of the disclosure;
[0019] FIG. 7 is a rear perspective view of a base portion of the
insect trap of FIG. 6 with a trap portion removed;
[0020] FIG. 8 is a perspective view, partly broken away, of the
trap portion of the insect trap of FIG. 6;
[0021] FIG. 9 is a cross-sectional view through the insect trap of
FIG. 6 showing the interior of the base portion and the trap
portion;
[0022] FIG. 10 is a front perspective view of a fourth embodiment
of an insect trap in accordance with principles of the
disclosure;
[0023] FIG. 11 is a rear perspective view of the insect trap of
FIG. 10;
[0024] FIG. 12 is a front perspective view of a fifth embodiment of
an insect trap in accordance with principles of the disclosure;
[0025] FIG. 13 is a rear perspective view of the insect trap of
FIG. 12;
[0026] FIG. 14 is a front perspective view of the insect trap of
FIG. 12 showing a trap portion partially removed from a base
portion;
[0027] FIG. 15 is a perspective view, partly broken away, of the
trap portion of the insect trap of FIG. 12;
[0028] FIG. 16 is a cross-sectional view through the insect trap of
FIG. 12 showing the interiors of the base portion and the trap
portion;
[0029] FIG. 17 is an exploded view of a sixth embodiment of an
insect trap in accordance with principles of the disclosure;
[0030] FIG. 18 is a cross-sectional view through the insect trap of
FIG. 17 showing the interiors of a base portion and a trap
portion;
[0031] FIG. 19 is a cross-sectional view through a seventh
embodiment of an insect trap in accordance with principles of the
disclosure;
[0032] FIG. 20 is an enlarged view of a portion of FIG. 19;
[0033] FIG. 21 is a perspective view of an eighth embodiment of an
insect trap in accordance with principles of the disclosure showing
a trap portion removed from a base portion;
[0034] FIG. 22 is a cross sectional view of the insect trap of FIG.
21; and
[0035] FIG. 23 is an enlarged view of a portion of FIG. 22.
DETAILED DESCRIPTION
[0036] To provide an overall understanding of the devices and
methods described herein, certain illustrative embodiments will now
be described. For the purpose of clarity and illustration, these
devices and methods will be described with respect to insect traps
used for indoor residential or commercial purposes. It will be
understood by one of ordinary skill in the art that the devices and
methods described herein may be adapted and modified as
appropriate.
[0037] As described herein, an insect trap may include a light
source, a removable enclosure with at least one opening, an
adhesive surface at least partially within the enclosure, and
optics to redirect light from the light source onto the adhesive
trapping surface. The light source may include at least one light
emitting diode (LED). The optics may be attached to the removable
enclosure, and may be located at least partially within the
enclosure. The optics may include optical enhancers such as a
reflector, a lens and/or a diffuser. The insect trap may further
include an insect attractant that emits sound or scent. The light
source in the insect trap may deactivate when the removable
enclosure is removed from the insect trap. The insect trap may
further include rigid conductors protruding substantially
perpendicularly and directly from a rear surface of the insect
trap, wherein the conductors may be insertable into an electrical
socket, whereby the insect trap may be mounted by inserting the
electrical plug into an electrical socket. Alternately, the insect
trap may include a battery power supply electrically coupled to the
light source.
[0038] The insect trap may effectively attract and trap insects
indoors and may be manufactured and sold at a lower cost than
traditionally available insect traps. An insect trap with this
example configuration may be smaller than competing indoor insect
traps, and may be conveniently movable from one location to
another. An insect trap with this example configuration may be
easier to clean and maintain without contacting trapped
insects.
[0039] With reference to the drawings, FIG. 1 shows a front
perspective view of a first embodiment of an insect trap, indicated
generally at 110. The insect trap 110 includes a base portion 112
and a removable trap portion 114. A front surface 160 of base
portion 112 may include a switch 116, configurable to enable the
insect trap 110 to be turned on or off by closing or opening the
switch 116 as desired by the user. Alternatively, switch 116 may be
configured to control other features such as light intensity,
combinations of light wavelengths, different modes or frequencies
of flickering light, an automatic setting that turns on when the
room gets dark, or a remote control setting, for example. Trap
portion 114 includes a front housing 118 with at least one opening
120 in a front surface 168.
[0040] FIG. 2 shows a rear perspective view of base portion 112 of
insect trap 110 with trap portion 114 removed. Protruding from a
rear surface 162 of base portion 112 are two electrically
conductive prongs 122, adapted to mount insect trap 110 to a wall
and provide power to insect trap 110 by inserting prongs 122 into a
standard household electrical wall socket. Alternatively, base
portion 112 may be configured to sit or hang wherever desired and
receive power from batteries (not shown) mounted in base portion
112. While an electrical socket and batteries have been described
as providing power to trap 110, any suitable power source may be
used. Base portion 112 includes a lighting element such as one or
more light emitting diodes (LEDs) 124. In some embodiments, the
LEDs 124 include one that emits ultraviolet (UV) light and one that
emits visible light (e.g., blue light). In some embodiments, the
lighting element emits a combination of wavelengths to mimic
sunlight. Mounted in top surface 126 of base portion 112 may be a
transparent or translucent window 128, shown partially cut away to
reveal LEDs 124. Transparent or translucent window 128 protects the
one or more LEDs 124 from dust and insect debris, and allows base
portion 112 to be easily cleaned. In top surface 126 may be a slot
130, and on perimeter 164 of top surface 126 is a rim or upwardly
directed protrusions 132.
[0041] FIG. 3 shows an exploded view of trap portion 114 of insect
trap 110. Trap portion 114 includes front housing 118 with at least
one opening 120, a divider 134, and a rear housing 140. In some
embodiments, divider 134 is constructed from or includes a
transparent or translucent material and may be coated with a
transparent or translucent adhesive 136 on a front surface 138. In
some embodiments, the material and thickness of divider 134 and the
material and thickness of adhesive 136 are selected to transmit a
substantial proportion of the UV and visible light, for example
greater than 60% of the light is transmitted through divider 134
and adhesive 136. In some embodiments, rear housing 140 includes a
reflective-coated inside surface 142. Alternatively, the material
and surface finish of rear housing 140 may be configured to reflect
UV and/or visible light without a reflective coating. The rear
housing 140 may include an opening 144 on its bottom surface 166,
or alternatively opening 144 may be replaced by a transparent or
translucent window (not shown).
[0042] Front housing 118 and rear housing 140 may be constructed
from any suitable material, including a thermoformed opaque plastic
material or other opaque, transparent or translucent materials such
as paper, paperboard, cardboard or paper pulp. In some embodiments,
front housing 118 and rear housing 140 are constructed by injection
molding or by other suitable manufacturing techniques. As shown,
divider 134 is substantially planar, although it may be formed into
a convex, concave or saddle-shaped contour, or a combination of
contours to optimize the even distribution of light. Alternatively,
divider 134 may have ribs or other features that increase adhesive
surface area and create regions of light/dark contrast, which are
highly visible to a wide variety of insects and may be more
attractive to them.
[0043] In some embodiments, front housing 118 may be coated with
transparent, translucent or opaque adhesive on an inside surface
170 to provide additional insect trapping efficiency and capacity.
In addition, front housing 118 may also have a reflective coating
underneath the adhesive coating on inside surface 170 to enhance
its attraction to insects and further improve the insect trapping
efficiency and effectiveness.
[0044] In some embodiments, front housing 118, divider 134 and rear
housing 140 are joined together at their perimeters with adhesive,
although they may also be joined by other commonly used packaging
assembly techniques such as ultrasonic welding or RF sealing, or
any other suitable assembly method. The materials of trap portion
114 may also include insect attractants. For example, trap portion
114 may be impregnated with sorbitol, coleopteran attractants
including brevicomin, dominicalure, frontalin, grandlure,
ipsdienol, ipsenol, japonilure, lineatin, megatomoic acid,
multistriatin, oryctalure, sulcatol, and trunc-call, dipteran
attractants including ceralure, cue-lure, latilure, medlure,
moguchun, muscalure, and trimedlure, homopteran attractants
including rescalure, lepidopteran attractants such as disparlure,
straight chain lepidopteran pheromones including codlelure,
gossyplure, hexalure, litlure, looplure, orfralure, and ostramone,
and other insect attractants such as eugenol, methyl eugenol, and
siglure, or other substances to provide a scent that further
increases the insect-attracting efficiency of the insect trap 110.
In such embodiments, the insect attractant is integral to trap
portion 114. Alternatively, the insect attractants may be embedded
in a separate piece that mounts on inside surface 170 of front
housing 118 or through an opening 120 in front housing 118 or on
front surface 138 of divider 134. It is desirable for such
attractants to be detectable by an insect for approximately a 2
meter radius from trap 110.
[0045] FIG. 4 is a cross-sectional, cut-away view through insect
trap 110 showing the interiors of base portion 112 and trap portion
114. As shown, divider 134 separates the trap portion 114 into a
front enclosure 146 and a rear enclosure 148. In some embodiments,
base portion 112 includes a circuit board 150 having a programmable
processor or chip (not shown) for executing commands, electrically
connected to conductive prongs 122, switch 116 and the one or more
LEDs 124. For clarity, however, not all of the electrical
connections are shown. The circuit board 150 may include electronic
circuitry to receive ordinary household current from conductive
prongs 122, respond to the position of switch 116 and provide power
to illuminate the one or more LEDs 124. Circuit board 150 may
include an energy stabilizer such as a full wave rectifier circuit
or any other circuit that provides steady voltage to the one or
more LEDs 124 when switch 116 is in the closed position, although
it may also provide a varying voltage to the one or more LEDs 124
to provide a flickering light, which some species of insects find
attractive. For example, light flickering frequencies in the
approximate range of 0.05 Hz (e.g., to mimic the breathing rate of
large mammals) to 250 Hz (e.g., the highest flicker frequency known
to attract male houseflies), may be desirable and the lighting
element may be configured to flicker within this range. Circuit
board 150 may provide power to the one or more LEDs 124 to provide
both UV and visible light, although it may be configured to provide
power to only the one or more UV LEDs 124 or to only the one or
more visible light LEDs 124, or to provide variable power to
produce combinations of flickering UV and visible light. Circuit
board 150 may also be configured to drive a transmitter or
transceiver such as a piezoelectric speaker (not shown) or other
device that may be mounted in the base portion 112 to emit an
insect-attracting sound. For example, the transmitter or
transceiver may emit an insect-attracting sound having a frequency
in the range of approximately 0.5 Hz (e.g., the heart rate of large
mammals) to 240 KHz (e.g., the highest frequency detectable by
insects). In some embodiments, the frequency is in the range of
approximately 5 Hz to 100 KHz. In some embodiments, the frequency
is in the range of approximately 35 Hz to 50 Khz. It is desirable
for such insect-attracting sound to be detectable by an insect for
approximately a 2 meter radius from trap 110. It is desirable for
such insect-attracting sound to be undetectable by a human beyond
approximately a 1 meter radius from trap 110.
[0046] As shown, slot 130 in top surface 126 of base portion 112
and protrusions 132 on top surface 126 of base portion 112 engage
with trap portion 114 to secure it in place during use, although
any other form of attachment may be substituted that allows trap
portion 114 to be securely but removably mounted to base portion
112.
[0047] In the operation of insect trap insect trap 110, conductive
prongs 122 are inserted into a wall electrical socket, and switch
116 may be moved to a closed position. The one or more LEDs 124
emit light, represented by arrows, preferably UV and visible light,
which is transmitted through window 128 in base portion 112,
through opening 144 in rear housing 140 of trap portion 114, into
rear enclosure 148, and directly onto reflective-coated inside
surface 142 of rear housing 140 and a rear surface 152 of divider
134. In some embodiments, light is not manipulated in base portion
112 and is emitted directly into trap portion 114.
Reflective-coated inside surface 142 of rear housing 140 may
include a concave shape and may be configured to reflect the UV and
visible light from the one or more LEDs 124 to distribute the light
evenly onto rear surface 152 of the divider 134, although the shape
of the inside surface 142 of the rear housing 140 may have a convex
shape or a saddle shape or a combination of shapes, or may also
have ribs or other features to more evenly distribute the
light.
[0048] Alternatively, an optical enhancer such as an anamorphic
lens (not shown) or any other lens or combination of lenses
configured to distribute the UV and visible light (e.g., evenly,
according to specific patterns, at a focal point, etc.) onto rear
surface 152 of divider 134, may be mounted to the rear housing 140
at or near opening 144, and may replace or augment the role of the
reflective-coated inside surface 142 of rear housing 140. In some
embodiments, the UV and visible light from the one or more LEDs 124
may directly strike rear surface 152 of divider 134 at an oblique
angle (e.g., an acute angle from approximately 0.degree. to
90.degree.) and be spread across divider 134, and may replace or
augment the role of reflective-coated inside surface 142 of rear
housing 140 or of the lens or lenses mounted to rear housing
140.
[0049] Thereafter, light may transmit through divider 134 and
adhesive coating 136 on its front surface 138, and into front
enclosure 146. Light may be further evenly distributed by the
light-diffusing properties of divider 134, adhesive coating 136 on
its front surface 138, or both. A portion of the light entering
front enclosure 146 continues through one or more openings 120 in
front housing 118 and is emitted into the surrounding area where
the trap is installed. Insects may be attracted to the UV and/or
visible light emitted through adhesive coating 136 and one or more
openings 120 in the front housing 118, and fly or crawl into the
one or more openings 120 and onto the adhesive coating 136, where
they become trapped in adhesive (e.g. from adhesive coating 136). A
user may observe trapped insects by looking through one or more
openings 120 in front housing 118. When a sufficient number of
insects have been trapped, the user may easily remove and discard
the entire used trap portion 114 without touching the trapped
insects, insect debris or adhesive, which remain out of reach
inside trap portion 114, and replace it with a new trap portion
114. The new trap portion 114 may have fresh adhesive-coated
surfaces and light-directing surfaces, ensuring that insect trap
110 will continue to efficiently and effectively attract and trap
insects.
[0050] It should be appreciated that a benefit of trap 110 is the
manipulation of light within trap portion 114. In some embodiments,
light manipulation occurs solely within trap portion 114. Light
manipulation may include reflection, refraction, polarization
and/or diffusion and is achieved by engaging with a manipulative
element or surface (e.g., inside surface 142, divider 134 and
adhesive coating 136). In some embodiments, light manipulation
produces an even distribution of light on an adhesive surface or
adhesive coating 136. In some embodiments, light is manipulated to
produce a predetermined pattern on the adhesive coating 136 or
within trap portion 114, for example, an even distribution, an even
distribution with hot spots of higher intensity, hot spot patterns,
and/or combinations thereof.
[0051] Any suitable adhesive material may be used as part of an
adhesive surface for trapping an insect. In some embodiments,
pressure sensitive adhesives such as acrylics, butyl rubber,
natural rubber, nitriles, silicones, styrene block copolymers,
styrene-ethylene/propylene, styrene-isoprene-styrene, vinyl ethers
may be used. Generally, the thickness of such adhesives will be in
the range of approximately 0.01 mm to 1 mm. In some embodiments,
the adhesive thickness is in the range of approximately 0.05 mm to
0.2 mm, with a thickness of approximately 0.1 mm being most often
used.
[0052] An insect trap 110 of this configuration may accommodate a
variety of different trap portions 114 that may be removably
mounted to base portion 112, each trap portion 114 being uniquely
configured to attract and trap a specific species or multiple
species of flying insect. For example, the overall size and shape
of trap portion 114, and the size, shape, and orientation of the
openings 120 in the front housing 118 of the trap portion 114, may
be uniquely configured to attract and trap a specific species or
multiple species of flying insect. For example, in some
embodiments, trap portion 114 is approximately 20 mm to 600 mm
wide, 20 mm to 600 mm high and 5 mm to 150 mm deep. In some
embodiments, trap portion 114 is approximately 20 mm to 200 mm
wide, 20 mm to 200 mm high and 5 mm to 80 mm deep. In some
embodiments, trap portion 114 is approximately 20 mm to 130 mm
wide, 20 mm to 130 mm high and 5 mm to 50 mm deep.
[0053] In some embodiments, base portion 112 is approximately 20 mm
to 600 mm wide, 10 mm to 150 mm high and 10 mm to 150 mm deep. In
some embodiments, base portion 112 is 20 mm to 200 mm wide, 10 mm
to 100 mm high and 10 mm to 80 mm deep. In some embodiments, base
portion 112 is 20 mm to 130 mm wide, 10 mm to 50 mm high and 10 mm
to 50 mm deep.
[0054] As provided herein, openings 120 may be a variety of shapes
and/or sizes. For example, openings 120 may be circular, square,
rectangular, polygonal and/or elliptical in shape. Alternatively,
openings 120 may be slots having straight, curved or undulating
shapes or patterns. When openings 120 are circular, openings 120
may be approximately 0.5 mm to 30 mm in diameter. In some
embodiments, circular openings 120 are approximately 0.5 mm to 20
mm in diameter. In some embodiments, circular openings 120 are
approximately 0.5 mm to 15 mm in diameter. When openings 120 are
slot shaped, openings 120 may be approximately 2 mm to 30 mm wide
and 5 mm to 500 mm long. In some embodiments, slot openings 120 are
approximately 2 mm to 20 mm wide and 5 mm to 200 mm long. In some
embodiments, slot openings 120 are approximately 2 mm to 15 mm wide
and 5 mm to 100 mm long.
[0055] In some embodiments, openings 120 cover all or a portion of
trap portion 114. For example, openings 120 may cover a range of
approximately 1% to 75% of the surface area of trap portion 114. In
some embodiments, openings 120 cover approximately 5% to 50% of the
surface area of trap portion 114. In some embodiments, openings 120
cover approximately 10% to 30% of the surface area of trap portion
114.
[0056] FIG. 5 shows a cross-sectional view of a second embodiment
of an insect trap, indicated generally at 210. Insect trap 210
includes a base portion 212 and a removable trap portion 214.
Protruding from a rear surface 262 of base portion 212 are two
electrically conductive prongs 216, only one of which is shown,
adapted to mount insect trap 210 to a wall and provide power to
insect trap 210 by inserting prongs 216 into a standard household
electrical wall socket. Alternatively, base portion 212 may be
configured to sit or hang wherever desired and receive power from
batteries (not shown) mounted in base portion 212. While an
electrical socket and batteries have been described as providing
power to trap 210, any suitable power source may be used. Base
portion 212 includes a lighting element such as one or more LEDs
218. In some embodiments, LEDs 218 include one that emits
ultraviolet (UV) light and one that emits visible light (e.g., blue
light). In some embodiments, the lighting element emits a
combination of wavelengths to mimic sunlight.
[0057] In some embodiments, mounted in a top surface 220 of base
portion 212 is a transparent or translucent window 222, shown
partially cut away to reveal LEDs 218. Transparent or translucent
window 222 protects the one or more LEDs 218 from dust and insect
debris, and allows base portion 212 to be easily cleaned. Top
surface 220 of base portion 212 may include a slot 224, and on
perimeter 270 of top surface 220 are upwardly directed protrusions
226.
[0058] Trap portion 214 includes a front housing 228 with at least
one opening 230 and a light-conducting body 238. In some
embodiments, light-conducting body 238 includes a front surface
254, an adhesive coating or an adhesive layer 234 on the front
surface 254, and a rear cover 248. In some embodiments, the
material and thickness of adhesive layer 234 are selected to
transmit a substantial proportion of the UV and visible light, for
example greater than 60% of the light is transmitted through
adhesive layer 234. Light-conducting body may be tapered and
configured to receive light through its bottom surface 240 from the
one or more LEDs 218 and deflect and evenly distribute the light
(e.g., through front surface 254 and adhesive layer 234). Rear
cover 248 may be configured to prevent light from escaping through
the back, top and side surfaces of light-conducting body 238. As
provided herein, any suitable light-conducting body may be
used.
[0059] Front housing 228 may be constructed from any suitable
material, including a thermoformed opaque plastic material or other
opaque, transparent or translucent materials such as paper,
paperboard, cardboard or paper pulp. In some embodiments, front
housing 228 is constructed by injection molding or by other
suitable manufacturing techniques.
[0060] The front housing 228 may also be coated with transparent,
translucent or opaque adhesive on an inside surface (not shown) to
provide additional insect trapping efficiency and capacity. In
addition, the front housing 228 may also have a reflective coating
underneath the adhesive coating on its inside surface to enhance
its attraction to insects and further improve the insect trapping
efficiency and effectiveness. Front housing 228 and
light-conducting body 238 may be joined together at their
perimeters with adhesive, although they may also be joined by other
commonly used packaging assembly techniques such as ultrasonic
welding or RF sealing, or any other suitable assembly method.
[0061] As shown, front housing 228 and light-conducting body 238
together form a front enclosure 246. Light-conducting body 238 may
be tapered (e.g., thicker at a bottom surface 240 and thinner at a
top surface 242), and may be constructed from any transparent
material that conducts UV and/or visible light, such as acrylic or
polycarbonate plastic. The inside surfaces (not shown) of rear
cover 248 may have a reflective coating to reflect light back into
light-conducting body 238 and through its front surface 254,
thereby increasing its light-transmitting efficiency.
Light-conducting body 238 may also have facets or other features of
varying size, depth, and density on front surface 254 to enhance
its light-transmitting efficiency.
[0062] Alternatively, in some embodiments, light-conducting body
238 has facets or other features on its front surface 254 and is
not tapered. Light-conducting body 238 with microscopic facets or
other features on its front surface 254 is commonly referred to as
a Light Guide Plate, although the facets or other features may also
be larger and still function effectively.
[0063] Alternatively, in some embodiments, light-conducting body
238 may not have an adhesive coating, and light conducting body 238
and rear cover 248 may be part of the base portion 212. In such
embodiments, trap portion 214 may include a transparent or
translucent back plate (not shown) with an adhesive coating on its
front surface, attached at its perimeter to the front housing
228.
[0064] The materials of the trap portion 214 may also include
insect attractants. For example, trap portion 214 may be
impregnated with sorbitol, coleopteran attractants including
brevicomin, dominicalure, frontalin, grandlure, ipsdienol, ipsenol,
japonilure, lineatin, megatomoic acid, multistriatin, oryctalure,
sulcatol, and trunc-call, dipteran attractants including ceralure,
cue-lure, latilure, medlure, moguchun, muscalure, and trimedlure,
homopteran attractants including rescalure, lepidopteran
attractants such as disparlure, straight chain lepidopteran
pheromones including codlelure, gossyplure, hexalure, litlure,
looplure, orfralure, and ostramone, and other insect attractants
such as eugenol, methyl eugenol, and siglure, or other substances
to provide a scent that further increases the insect-attracting
efficiency of the insect trap. In such embodiments, the insect
attractant is integral to trap portion 214. Alternatively, the
insect attractants may be embedded in a separate piece that mounts
on an inside surface 250 of front housing 228 or through the at
least one opening 230 in front housing 228 or on front surface 254
of light-conducting body 238. It is desirable for such attractants
to be detectable by an insect for approximately a 2 meter radius
from trap 210.
[0065] In some embodiments, base portion 212 includes a circuit
board 252 having a programmable processor or chip (not shown) for
executing commands, electrically connected to the conductive prongs
216 and one or more LEDs 218. For clarity, however, not all of the
electrical connections are shown. Circuit board 252 may include
electronic circuitry to receive ordinary household current from
conductive prongs 216 and provide power to illuminate the one or
more LEDs 218. Circuit board 252 may include an energy stabilizer
such as a full wave rectifier circuit or any other circuit that
provides steady voltage to one or more LEDs 218, although it may
also provide a varying voltage to the one or more LEDs 218 to
provide a flickering light, which some species of insects find
attractive. For example, light flickering frequencies in the
approximate range from 0.05 Hz (e.g., to mimic the breathing rate
of large mammals), to 270 Hz (e.g., the highest flicker frequency
known to attract male houseflies), may be desirable and the
lighting element may be configured to flicker within this range.
Circuit board 252 may provide power to the one or more LEDs 218 to
provide both UV and visible light although it may be configured to
provide power to only the one or more UV LEDs 218 or to only the
one or more visible light LEDs 218, or to provide variable power to
produce combinations of flickering UV and visible light. Circuit
board 252 may also be configured to drive a transmitter or
transceiver such as a piezoelectric speaker or other device that
may be mounted in base portion 212 to emit an insect-attracting
sound. For example, the transmitter or transceiver may emit an
insect-attracting sound having a frequency in the range of
approximately 0.5 Hz (e.g., the heart rate of large mammals), to
240 KHz (e.g., the highest frequency detectable by insects). In
some embodiments, the frequency is in the range of approximately 5
Hz to 100 KHz. In some embodiments, the frequency is in the range
of approximately 35 Hz to 50 Khz. It is desirable for such
insect-attracting sound to be detectable by an insect for
approximately a 2 meter radius from trap 210. It is desirable for
such insect-attracting sound to be undetectable by a human beyond
approximately a 1 meter radius from trap 210.
[0066] As shown, slot 224 in top surface 220 of base portion 212
and protrusions 226 on top surface 220 of base portion 212 engage
with trap portion 214 to secure it in place during use, although
any other form of attachment may be substituted that allows trap
portion 214 to be securely but removably mounted on base portion
212.
[0067] In the operation of insect trap 210, conductive prongs 216
are inserted into a wall electrical socket, and one or more LEDs
218 emit light, represented by arrows, preferably UV and visible
light. The light from one or more LEDs 218 may transmit through
window 222, enter the thicker bottom surface 240 of tapered
light-conducting body 238 and repeatedly reflect off of its front
surface 254 and its rear surface 256. In some embodiments, light is
not manipulated in base portion 212 and is emitted directly into
trap portion 214. A portion of the reflected light may transmit
through front surface 254 of the light-conducting body 238 to
provide an evenly-distributed light onto and through adhesive
coating 234 and into front enclosure 246. The light may be further
evenly distributed by refractive and light-diffusing properties of
adhesive coating 234 on front surface 254 of light-conducting body
238. A portion of the light entering the front enclosure 246
continues through one or more openings 230 in front housing 228 and
is emitted into the surrounding area where the trap 210 is
installed. Insects may be attracted to the UV and/or visible light
transmitted through adhesive coating 234 and through one or more
openings 230 in the front housing 228, and fly or crawl into one or
more openings 230 and onto the adhesive coating 234, where they
become trapped in the adhesive. The user may observe trapped
insects by looking through one or more openings 230 in front
housing 228. When a sufficient number of insects have been trapped,
the user may easily remove and discard the entire used trap portion
214 without touching the trapped insects, insect debris or
adhesive, which remain out of reach inside trap portion 114, and
replace it with a new trap portion 214. The new trap portion 214
may have fresh adhesive-coated surfaces and light-directing
surfaces, ensuring that the insect trap 210 will continue to
efficiently and effectively attract and trap insects.
[0068] It should be appreciated that a benefit of trap 210 is the
manipulation of light within trap portion 214. In some embodiments,
light manipulation occurs solely within trap portion 214. Light
manipulation may include reflection, refraction, polarization
and/or diffusion and is achieved by engaging with a manipulative
element or surface (e.g., light-conducting body 238, front surface
254 and rear surface 256, and adhesive coating 234). In some
embodiments, light manipulation produces an even distribution of
light on an adhesive surface or adhesive coating 234. In some
embodiments, light is manipulated to produce a predetermined
pattern on the adhesive coating 234 or within trap portion 214, for
example, an even distribution, an even distribution with hot spots
of higher intensity, hot spot patterns, and/or combinations
thereof.
[0069] Any suitable adhesive material may be used as part of an
adhesive surface for trapping an insect. In some embodiments,
pressure sensitive adhesives such as acrylics, butyl rubber,
natural rubber, nitriles, silicones, styrene block copolymers,
styrene-ethylene/propylene, styrene-isoprene-styrene, vinyl ethers
may be used. Generally, the thickness of such adhesives will be in
the range of approximately 0.01 mm to 1 mm. In some embodiments,
the adhesive thickness is in the range of approximately 0.05 mm to
0.2 mm, with a thickness of approximately 0.1 mm being most often
used.
[0070] An insect trap 210 of this configuration may accommodate a
variety of different trap portions 214 that may be removably
mounted to base portion 212, each trap portion 214 being uniquely
configured to attract and trap a specific species or multiple
species of insects. For example, the overall size and shape of trap
portion 214, and the size, shape, and orientation of the openings
230 in front housing 228 of trap portion 214, may be uniquely
configured to attract and trap a specific species or multiple
species of insects. For example, in some embodiments, trap portion
214 is approximately 20 mm to 600 mm wide, 20 mm to 600 mm high and
5 mm to 150 mm deep. In some embodiments, trap portion 214 is
approximately 20 mm to 200 mm wide, 20 mm to 200 mm high and 5 mm
to 80 mm deep. In some embodiments, trap portion 214 is
approximately 20 mm to 130 mm wide, 20 mm to 130 mm high and 5 mm
to 50 mm deep.
[0071] In some embodiments, base portion 212 is approximately 20 mm
to 600 mm wide, 10 mm to 150 mm high and 10 mm to 150 mm deep. In
some embodiments, base portion 212 is 20 mm to 200 mm wide, 10 mm
to 100 mm high and 10 mm to 80 mm deep. In some embodiments, base
portion 212 is 20 mm to 130 mm wide, 10 mm to 50 mm high and 10 mm
to 50 mm deep.
[0072] As provided herein, openings 230 may be a variety of shapes
and/or sizes. For example, openings 230 may be circular, square,
rectangular, polygonal and/or elliptical in shape. Alternatively,
openings 230 may be slots having straight, curved or undulating
shapes or patterns. When openings 230 are circular, openings 230
may be approximately 0.5 mm to 30 mm in diameter. In some
embodiments, circular openings 230 are approximately 0.5 mm to 20
mm in diameter. In some embodiments, circular openings 230 are
approximately 0.5 mm to 15 mm in diameter. When openings 230 are
slot shaped, openings 230 may be approximately 2 mm to 30 mm wide
and 5 mm to 500 mm long. In some embodiments, slot openings 230 are
approximately 2 mm to 20 mm wide and 5 mm to 200 mm long. In some
embodiments, slot openings 230 are approximately 2 mm to 15 mm wide
and 5 mm to 100 mm long.
[0073] In some embodiments, openings 230 cover all or a portion of
trap portion 214. For example, openings 230 may cover a range of
approximately 1% to 75% of the surface area of trap portion 214. In
some embodiments, openings 230 cover approximately 5% to 50% of the
surface area of trap portion 214. In some embodiments, openings 230
cover approximately 10% to 30% of the surface area of trap portion
214.
[0074] FIG. 6 shows a front perspective view of a third embodiment
of an insect trap, indicated generally at 310. Insect trap 310
includes a base portion 312 and a removable trap portion 314. In
some embodiments, front surface 360 of base portion 312 includes a
switch 316, configurable to enable insect trap 310 to be turned on
or off by closing or opening switch 316, as desired by the user.
Alternatively, switch 316 may be configured to control other
features such as light intensity, combinations of light
wavelengths, different flickering frequencies or modes, an
automatic setting that turns on when the room gets dark, or a
remote control setting, for example. Trap portion 314 includes a
housing 318 with at least one opening 320.
[0075] FIG. 7 shows a rear perspective view of base portion 312 of
insect trap 310 with trap portion 314 removed. Protruding from a
rear surface 362 of base portion 312 are two electrically
conductive prongs 322, adapted to mount insect trap 310 to a wall
and provide power to insect trap 310 by inserting into a standard
household electrical wall socket. Alternatively, base portion 312
may be configured to sit or hang wherever desired and receive power
from batteries (not shown) mounted in base portion 312. While an
electrical socket and batteries have been described as providing
power to trap 310, any suitable power source may be used. Base
portion 312 includes a lighting element such as one or more LEDs
324. In some embodiments, the LEDs 324 include one that emits
ultraviolet (UV) light and one that emits visible light (e.g., blue
light). In some embodiments, the lighting element emits a
combination of wavelengths to mimic sunlight. Mounted in top
surface 326 of base portion 312 may be a transparent or translucent
window 328, shown partially cut away to reveal LEDs 324.
Transparent or translucent window 328 protects the one or more LEDs
324 from dust and insect debris, and allows base portion 312 to be
easily cleaned. Upwardly directed protrusions or a rim 330
protruding from perimeter 364 of top surface 326 of base portion
312 may serve to secure trap portion 314 in place during use,
although any other form of attachment may be substituted that
allows trap portion 314 to be securely but removably mounted to
base portion 312.
[0076] FIG. 8 shows a perspective view, partly broken away, of trap
portion 314 of insect trap 310. Trap portion 314 includes housing
318, which forms an enclosure with one or more openings 320, and a
transparent or translucent adhesive coating applied to one or more
inside surface 334. In some embodiments, the material and thickness
of housing 318 and the material and thickness of the adhesive
coating are selected to transmit a substantial proportion of the UV
and visible light, for example greater than 60% of the light is
transmitted through housing 318 and the adhesive coating. Housing
318 may be constructed from any suitable material, including a
thermoformed opaque plastic material or other opaque, transparent
or translucent materials such as paper, paperboard, cardboard or
paper pulp. In some embodiments, housing 318 is constructed by
injection molding or by other suitable manufacturing
techniques.
[0077] As shown, housing 318 includes ribs 336 or other features
that increase the adhesive-coated surface area, produce alternating
light/dark regions that some insect species find attractive, and
enhance the transmission of insect-attracting light into interior
370 of trap portion 314. A sleeve 338, configured to reduce the
amount of light emitted by outside surface 368 of housing 318,
covers outside surface 368 of housing 318 except for a bottom
surface 366 and at one or more openings 320. Sleeve 338 may be
constructed from any suitable material, including a thermoformed
opaque plastic material or other opaque, transparent or translucent
materials such as paper, paperboard, cardboard or paper pulp. In
some embodiments, sleeve 338 includes a reflective coating on one
or more of its inside surfaces, allowing sleeve 338 to direct more
light through adhesive-coated inside surfaces 334 of housing 318
and further enhance the insect attracting and trapping efficiency
and effectiveness. In some embodiments, sleeve 338 is replaced by a
coating configured to reduce the amount of light emitted by outside
surface 368 of housing 318, or by the coating applied over a
reflective coating, applied to outside surface 368 of housing 318,
except for bottom surface 366.
[0078] The materials of the trap portion 314 may also include
insect attractants. For example, trap portion 314 may be
impregnated with sorbitol, coleopteran attractants including
brevicomin, dominicalure, frontalin, grandlure, ipsdienol, ipsenol,
japonilure, lineatin, megatomoic acid, multistriatin, oryctalure,
sulcatol, and trunc-call, dipteran attractants including ceralure,
cue-lure, latilure, medlure, moguchun, muscalure, and trimedlure,
homopteran attractants including rescalure, lepidopteran
attractants such as disparlure, straight chain lepidopteran
pheromones including codlelure, gossyplure, hexalure, litlure,
looplure, orfralure, and ostramone, and other insect attractants
such as eugenol, methyl eugenol, and siglure, or other substances
to provide a scent that increases the insect-attracting efficiency
of the insect trap. In such embodiments, the insect attractant is
integral to trap portion 314. Alternatively, the insect attractants
may be embedded in a separate piece that mounts on inside surface
334 of housing 318 or through opening 320 in housing 318. It is
desirable for such attractants to be detectable by an insect for
approximately a 2 meter radius from trap 310.
[0079] FIG. 9 is a cross-sectional view through insect trap 310
showing the interiors of base portion 312 and trap portion 314. In
some embodiments, base portion 312 includes a circuit board 340
having a programmable processor or chip (not shown) for executing
commands, electrically connected to conductive prongs 322, only one
of which is shown, switch 316 and the one or more LEDs 324. For
clarity, however, not all of the electrical connections are shown.
Circuit board 340 may include electronic circuitry to receive
ordinary household current from the conductive prongs 322, respond
to the position of switch 316 and provide power to illuminate the
one or more LEDs 324. Circuit board 340 may include an energy
stabilizer such as a full wave rectifier filter circuit or any
other circuit that provides steady voltage to one or more LEDs 324
when switch 316 is in a closed position, although it may also
provide a varying voltage to one or more LEDs 324 to provide a
flickering light, which some species of insect find attractive. For
example, light flickering frequencies in the approximate range of
0.05 Hz (e.g., to mimic the breathing rate of mammals) to 250 Hz
(e.g., the highest flicker frequency known to attract male
houseflies), may be desirable and the lighting element may be
configured to flicker within this range. Circuit board 340 may
provide power to one or more LEDs 324 to provide both UV and
visible light, although it could be configured to provide power to
only one or more UV LEDs 324 or to only one or more visible light
LEDs 324, or to provide variable power to produce combinations of
flickering UV and visible light. In some embodiments, circuit board
340 may be configured to drive a transmitter or transceiver such as
a piezoelectric speaker or other device that may be mounted in base
portion 312 to emit an insect-attracting sound. For example, the
transmitter or transceiver may emit an insect-attracting sound
having a frequency in the range of approximately 0.5 Hz (e.g., the
heart rate of large mammals) to 240 KHz (e.g., the highest
frequency detectable by insects). In some embodiments, the
frequency is in the range of approximately 5 Hz to 100 KHz. In some
embodiments, the frequency is in the range of approximately 35 Hz
to 50 Khz. It is desirable for such insect-attracting sound to be
detectable by an insect for approximately a 2 meter radius from
trap 310. It is desirable for such insect-attracting sound to be
undetectable by a human beyond approximately a 1 meter radius from
trap 310.
[0080] In the operation of insect trap 310, conductive prongs 322
are inserted into a wall electrical socket and switch 316 may be
moved to a closed position. The one or more LEDs 324 emit light,
represented by arrows, preferably UV and visible light, which
transmit through at least one window 328 in base portion 312 and
through bottom surface 366 of housing 318. In some embodiments,
light is not manipulated in base portion 312 and is emitted
directly into trap portion 314. A portion of the light continues
within the enclosure, up one or more sides 372 of housing 318, and
out through adhesive-coated inside surfaces 334. Another portion of
the light continues through bottom surface 366 of housing 318 and
into the enclosure, where it illuminates adhesive-coated inside
surfaces 334. A portion of the light entering housing 318 continues
through openings 320 and is emitted into the surrounding area where
the trap is installed. Insects in the area are attracted to the UV
and/or visible light transmitted through openings 320 and fly or
crawl into openings 320 and onto adhesive coated inside surfaces
334, where they become stuck in the adhesive and are trapped. The
user may observe trapped insects by looking through openings 320.
When a sufficient number of insects have been trapped, the user may
easily remove and discard the entire used trap portion 314 without
touching trapped insects, insect debris or adhesive, which remain
out of reach inside trap portion 314, and replace it with a new
trap portion 314. The new trap portion 314 may have fresh
adhesive-coated inside surfaces 334, housing 318 has a clean bottom
surface 366 through which the UV and/or visible light is
transmitted into trap portion 314, and the transparent or
translucent material of trap portion 314 has not been degraded by
prolonged exposure to UV light, thereby ensuring that insect trap
310 will continue to efficiently and effectively attract and trap
insects.
[0081] It should be appreciated that a benefit of trap 310 is the
manipulation of light within trap portion 314. In some embodiments,
light manipulation occurs solely within trap portion 314. Light
manipulation may include reflection, refraction, polarization
and/or diffusion and is achieved by engaging with a manipulative
element or surface (e.g., housing 318 and adhesive-coated inside
surfaces 334). In some embodiments, light manipulation produces an
even distribution of light on an adhesive surface or adhesive
coating. In some embodiments, light is manipulated to produce a
predetermined pattern on the adhesive coating or within trap
portion 314, for example, an even distribution, an even
distribution with hot spots of higher intensity, hot spot patterns,
and/or combinations thereof.
[0082] Any suitable adhesive material may be used as part of an
adhesive surface for trapping an insect. In some embodiments,
pressure sensitive adhesives such as acrylics, butyl rubber,
natural rubber, nitriles, silicones, styrene block copolymers,
styrene-ethylene/propylene, styrene-isoprene-styrene, vinyl ethers
may be used. Generally, the thickness of such adhesives will be in
the range of approximately 0.01 mm to 1 mm. In some embodiments,
the adhesive thickness is in the range of approximately 0.05 mm to
0.2 mm, with a thickness of approximately 0.1 mm being most often
used.
[0083] An insect trap 310 of this configuration may accommodate a
variety of different trap portions 314 that may be removably
mounted to base portion 312, each trap portion 314 being uniquely
configured to attract and trap a specific species or multiple
species of insects. For example, the overall size and shape of trap
portion 314, and the size, shape, and orientation of openings 320
in housing 318 of the trap portion 314, may be uniquely configured
to attract and trap a specific species or multiple species of
insects. For example, in some embodiments, trap portion 314 is
approximately 20 mm to 600 mm wide, 20 mm to 600 mm high and 5 mm
to 150 mm deep. In some embodiments, trap portion 314 is
approximately 20 mm to 200 mm wide, 20 mm to 200 mm high and 5 mm
to 80 mm deep. In some embodiments, trap portion 314 is
approximately 20 mm to 130 mm wide, 20 mm to 130 mm high and 5 mm
to 50 mm deep.
[0084] In some embodiments, base portion 312 is approximately 20 mm
to 600 mm wide, 10 mm to 150 mm high and 10 mm to 150 mm deep. In
some embodiments, base portion 312 is 20 mm to 200 mm wide, 10 mm
to 100 mm high and 10 mm to 80 mm deep. In some embodiments, base
portion 312 is 20 mm to 130 mm wide, 10 mm to 50 mm high and 10 mm
to 50 mm deep.
[0085] As provided herein, openings 320 may be a variety of shapes
and/or sizes. For example, openings 320 may be circular, square,
rectangular, polygonal and/or elliptical in shape. Alternatively,
openings 320 may be slots having straight, curved or undulating
shapes or patterns. When openings 320 are circular, openings 320
may be approximately 0.5 mm to 30 mm in diameter. In some
embodiments, circular openings 320 are approximately 0.5 mm to 20
mm in diameter. In some embodiments, circular openings 320 are
approximately 0.5 mm to 15 mm in diameter. When openings 320 are
slot shaped, openings 320 may be approximately 2 mm to 30 mm wide
and 5 mm to 500 mm long. In some embodiments, slot openings 320 are
approximately 2 mm to 20 mm wide and 5 mm to 200 mm long. In some
embodiments, slot openings 320 are approximately 2 mm to 15 mm wide
and 5 mm to 100 mm long.
[0086] In some embodiments, openings 320 cover all or a portion of
trap portion 314. For example, openings 320 may cover a range of
approximately 1% to 75% of the surface area of trap portion 314. In
some embodiments, openings 320 cover approximately 5% to 50% of the
surface area of trap portion 314. In some embodiments, openings 320
cover approximately 10% to 30% of the surface area of trap portion
314.
[0087] Although as shown in the embodiments of FIGS. 1-9, the trap
portion mounts on a top surface of the base portion, other
configurations may also work effectively. For example, FIGS. 10 and
11 show a fourth embodiment of an insect trap, where the trap
portion mounts to the front of the base portion.
[0088] FIG. 10 is a front perspective view and FIG. 11 is a rear
perspective view, both showing the fourth embodiment of an insect
trap, indicated generally at 410. Base portion 412 mounts and is
provided power by plugging into a household wall electrical socket.
Alternatively, base portion 412 may be configured to sit or hang
wherever desired and receive power from batteries (not shown)
mounted in base portion 412. While an electrical socket and
batteries have been described as providing power to trap 410, any
suitable power source may be used. In some embodiments, base
portion 412 includes a circuit board (not shown) having a
programmable processor or chip (not shown) for executing
commands.
[0089] A lighting element such as one or more LEDs 414 may be
mounted on a cross-shaped protrusion 416 protruding from front
surface 418 of base portion 412. Alternatively, LEDs 414 may form a
protrusion themselves. While shown as a cross-shaped protrusion,
the mounting surface and/or LED 414 configuration may be any
desired shape. Trap portion 420 includes a housing 450 of
translucent or transparent material with one or more
adhesive-coated inside surfaces 422 and one or more openings 424.
In some embodiments, the material and thickness of housing 450 and
the material and thickness of the adhesive are selected to transmit
a substantial proportion of the UV and visible light, for example
greater than 60% of the light is transmitted through housing 450
and the adhesive coating. Trap portion 420 may include a coating
configured to reduce the amount of light emitted by the one or more
outside surfaces 452, on one or more outside surfaces 452 except
for at the one or more openings 424 and at opening 426 in rear
surface 428. As shown, opening 426 is a cross-shaped cavity 454,
but may be any desired shape. For example, cross-shaped protrusion
416 on front surface 418 of base portion 412 may engage with a
recess in cross-shaped cavity 454 in rear surface 428 of trap
portion 420 to removably attach trap portion 420 to base portion
412. In this configuration, therefore, trap portion 414 mounts in
front of base portion 412.
[0090] In the operation of insect trap 410, base portion 412 is
plugged into an electrical wall socket and trap portion 420 is
mounted in front of base portion 412. Light from one or more LEDs
414, in UV and/or visible light wavelengths, may transmit into
cross-shaped cavity 454 in rear surface 428 of trap portion 420. In
some embodiments, light is not manipulated in base portion 412 and
is emitted directly into trap portion 414. A portion of the light
may continue within the translucent or transparent walls of the
trap portion 420, diffusing the light and spreading it evenly
within trap portion 420 and through adhesive-coated inside surfaces
422. Another portion of the light may continue through rear wall
456 of trap portion 420 and into interior 430 of trap portion 420,
where it illuminates adhesive-coated inside surfaces 422. A portion
of the light entering trap portion 420 may continue through one or
more openings 424 and is emitted into the surrounding area where
the trap 410 is installed. Insects in the area are attracted to the
UV and/or visible light transmitted through one or more openings
424, and fly or crawl into one or more openings 424 and onto
adhesive coated inside surfaces 422, where they become stuck in the
adhesive and are trapped. The user may observe trapped insects by
looking through one or more openings 424. When a sufficient number
of insects have been trapped, the user may easily remove and
discard the entire used trap portion 420 without touching trapped
insects, insect debris or adhesive, which remain out of reach
inside trap portion 314, and replace it with a new trap portion
420. The new trap portion 420 may have fresh adhesive-coated inside
surfaces 422, a clean opening 426 in rear surface 428 through which
the UV and/or visible light is transmitted into trap portion 420,
and the transparent or translucent material of trap portion 420 has
not been degraded by prolonged exposure to UV light, thereby
ensuring that insect trap 410 will continue to efficiently and
effectively attract and trap insects.
[0091] It should be appreciated that a benefit of trap 410 is the
manipulation of light within trap portion 420. In some embodiments,
light manipulation occurs solely within trap portion 420. Light
manipulation may include reflection, refraction, polarization
and/or diffusion and is achieved by engaging with a manipulative
element or surface (e.g., trap portion 420 and adhesive-coated
inside surfaces 422). In some embodiments, light manipulation
produces an even distribution of light on an adhesive surface or
adhesive coating. In some embodiments, light is manipulated to
produce a predetermined pattern on the adhesive coating or within
trap portion 420, for example, an even distribution, an even
distribution with hot spots of higher intensity, hot spot patterns,
and/or combinations thereof.
[0092] Any suitable adhesive material may be used as part of an
adhesive surface for trapping an insect. In some embodiments,
pressure sensitive adhesives such as acrylics, butyl rubber,
natural rubber, nitriles, silicones, styrene block copolymers,
styrene-ethylene/propylene, styrene-isoprene-styrene, vinyl ethers
may be used. Generally, the thickness of such adhesives will be in
the range of approximately 0.01 mm to 1 mm. In some embodiments,
the adhesive thickness is in the range of approximately 0.05 mm to
0.2 mm, with a thickness of approximately 0.1 mm being most often
used.
[0093] An insect trap 410 of this configuration may accommodate a
variety of different trap portions 420 that may be removably
mounted to base portion 412, each trap portion 420 being uniquely
configured to attract and trap a specific species or multiple
species of insects. For example, the overall size and shape of trap
portion 420, and the size, shape, and orientation of openings 424
in trap portion 420, may be uniquely configured to attract and trap
a specific species or multiple species of insects. For example, in
some embodiments, trap portion 420 is approximately 20 mm to 600 mm
wide, 20 mm to 600 mm high and 5 mm to 150 mm deep. In some
embodiments, trap portion 420 is approximately 20 mm to 200 mm
wide, 20 mm to 200 mm high and 5 mm to 80 mm deep. In some
embodiments, trap portion 420 is approximately 20 mm to 130 mm
wide, 20 mm to 130 mm high and 5 mm to 50 mm deep.
[0094] In some embodiments, base portion 412 is approximately 10 mm
to 600 mm wide, 10 mm to 150 mm high and 10 mm to 150 mm deep. In
some embodiments, base portion 412 is 10 mm to 200 mm wide, 10 mm
to 100 mm high and 10 mm to 80 mm deep. In some embodiments, base
portion 412 is 10 mm to 130 mm wide, 10 mm to 50 mm high and 10 mm
to 50 mm deep.
[0095] As provided herein, openings 424 may be a variety of shapes
and/or sizes. For example, openings 424 may be circular, square,
rectangular, polygonal and/or elliptical in shape. Alternatively,
openings 424 may be slots having straight, curved or undulating
shapes or patterns. When openings 424 are circular, openings 424
may be approximately 0.5 mm to 30 mm in diameter. In some
embodiments, circular openings 424 are approximately 0.5 mm to 20
mm in diameter. In some embodiments, circular openings 424 are
approximately 0.5 mm to 15 mm in diameter. When openings 424 are
slot shaped, openings 424 may be approximately 2 mm to 30 mm wide
and 5 mm to 500 mm long. In some embodiments, slot openings 424 are
approximately 2 mm to 20 mm wide and 5 mm to 200 mm long. In some
embodiments, slot openings 320 are approximately 2 mm to 15 mm wide
and 5 mm to 100 mm long.
[0096] In some embodiments, openings 424 cover all or a portion of
trap portion 420. For example, openings 424 may cover a range of
approximately 1% to 75% of the surface area of trap portion 420. In
some embodiments, openings 424 cover approximately 5% to 50% of the
surface area of trap portion 420. In some embodiments, openings 424
cover approximately 10% to 30% of the surface area of trap portion
420.
[0097] FIG. 12 is a front perspective view and FIG. 13 is a rear
perspective view of a fifth embodiment of an insect trap, indicated
generally at 510. Insect trap 510 includes a base portion 512 and a
removable trap portion 514. Base portion 512 includes a housing 516
with a large opening 518 in top surface 560 to receive trap portion
514, one or more smaller openings 520 on front surface 562, and two
electrically conductive prongs 522 on rear surface 564, adapted to
mount insect trap 510 to a wall and provide power to insect trap
510 by inserting into a standard household electrical wall socket.
While an electrical socket has been described as providing power to
trap 510, any suitable power source may be used. Base portion 512
may be injection molded of opaque plastic, although other materials
and construction techniques could also be used.
[0098] FIG. 14 is a front perspective view of insect trap 510
showing removable trap portion 514 partially removed from base
portion 512. Trap portion 514 may include a housing 524 with one or
more openings 526 and a tab 528 adapted for removing and replacing
trap portion 514. Trap portion 514 may be removed by grasping tab
528 and lifting trap portion 514 out of housing 516 of base portion
512. In some embodiments, openings 526 in trap portion 514 match or
correspond to openings 520 in base portion 512 with respect to
size, shape, orientation and location, so that they align when trap
portion 514 is mounted into base portion 512. In such embodiments,
trap portion 514 may be viewed as an inner sleeve or pocket and
base portion 512 may be viewed as an outer sleeve, where the inner
sleeve can be dropped or inserted into the outer sleeve by a
user.
[0099] FIG. 15 is a perspective view, partly broken away, of trap
portion 514. Housing 524 includes inside surfaces 530 coated with
translucent or transparent adhesive. As shown, housing 524 includes
ribs 532 or other features that increase the adhesive-coated
surface area, produce alternating light/dark regions that some
insect species find attractive, and enhance the transmission of
insect-attracting light into the interior of trap portion 514. In
some embodiments, trap portion 514 is thermoformed of translucent
or transparent sheet plastic, in two separate pieces, or in a
`clamshell` design, in which the two sides are joined at one side
and folded together, although trap portion 514 could also be
injection molded of translucent or transparent plastic or
constructed of translucent paper or of other materials. In some
embodiments, the material and thickness of trap portion 514 and the
material and thickness of the adhesive are selected to transmit a
substantial proportion of the UV and visible light, for example
greater than 60% of the light is transmitted through trap portion
514 and the adhesive coating. The materials of the trap portion 514
may also include insect attractants. For example, the materials of
the trap portion 514 may be impregnated with, or coated with,
sorbitol, coleopteran attractants including brevicomin,
dominicalure, frontalin, grandlure, ipsdienol, ipsenol, japonilure,
lineatin, megatomoic acid, multistriatin, oryctalure, sulcatol, and
trunc-call, dipteran attractants including ceralure, cue-lure,
latilure, medlure, moguchun, muscalure, and trimedlure, homopteran
attractants including rescalure, lepidopteran attractants such as
disparlure, straight chain lepidopteran pheromones including
codlelure, gossyplure, hexalure, litlure, looplure, orfralure, and
ostramone, and other insect attractants such as eugenol, methyl
eugenol, and siglure, or any other substance that may provide a
scent or other attractant that increases the insect-attracting
efficiency of the insect trap. In such embodiments, the insect
attractant is integral to trap portion 514. Alternatively, the
insect attractants may be embedded in a separate piece that mounts
on an inside surface 530 of housing 524 or through an opening 526
in housing 524. It is desirable for such attractants to be
detectable by an insect for approximately a 2 meter radius from
trap 510.
[0100] FIG. 16 is a cross-sectional view through insect trap 510
showing the interiors of base portion 512 and trap portion 514. In
some embodiments, base portion 512 includes a circuit board 534
having a programmable processor or chip (not shown) for executing
commands, electrically connected to conductive prongs 522, only one
of which is shown, and a lighting element such as one or more LEDs
536, one that emits ultraviolet (UV) light and/or one that emits
visible light (e.g., blue light). For clarity, not all of the
electrical connections are shown. The circuit board 534 may include
electronic circuitry to receive any household current from
conductive prongs 522 and provide power to illuminate the one or
more LEDs 536. Alternatively, circuit board 534 may be configured
to receive power from batteries (not shown) mounted in base portion
512. While an electrical socket and batteries have been described
as providing power to trap 510, any suitable power source may be
used. Circuit board 534 may include an energy stabilizer such as a
full wave rectifier circuit or any other circuit to provide steady
voltage to the one or more LEDs 536, although it could also provide
a varying voltage to the one or more LEDs 536 to provide a
flickering light, which some species of insect find attractive. For
example, light flickering frequencies in the approximate range of
0.05 Hz (e.g., to mimic the breathing rate of mammals) to 270 Hz
(e.g., the highest flicker frequency known to attract male
houseflies), may be desirable and the lighting element may be
configured to flicker within this range. Circuit board 534 may
provide power to one or more LEDs 536 to provide both UV and
visible light, although it could be configured to provide power to
only one or more UV LEDs 536 or to only one or more visible light
LEDs 536, or to provide variable power to produce combinations of
flickering UV and visible light. Circuit board 534 may also be
configured to drive a transmitter or transceiver such as a
piezoelectric speaker or other device that may be mounted in base
portion 512 to emit an insect-attracting sound. For example, the
transmitter or transceiver may emit an insect-attracting sound
having a frequency in the range of approximately 0.5 Hz (e.g., the
heart rate of large mammals) to 240 KHz (e.g., the highest
frequency detectable by insects). In some embodiments, the
frequency is in the range of approximately 5 Hz to 100 KHz. In some
embodiments, the frequency is in the range of approximately 35 Hz
to 50 Khz. It is desirable for such insect-attracting sound to be
detectable by an insect for approximately a 2 meter radius from
trap 510. It is desirable for such insect-attracting sound to be
undetectable by a human beyond approximately a 1 meter radius from
trap 510.
[0101] In the operation of insect trap 510, conductive prongs 522
are inserted into a wall electrical socket. One or more LEDs 536
emit light, represented by arrows, preferably UV and visible light,
which transmit though rear surface 538 of housing 524 of trap
portion 514. In some embodiments, light is not manipulated in base
portion 512 and is emitted directly into trap portion 514. A
portion of the light continues within the enclosure, up one or more
sides 572 of housing 524, and out through adhesive-coated inside
surfaces 530. Another portion of the light may continue through the
wall of housing 524 and into the enclosure, where it illuminates
the adhesive-coated inside surfaces 530. A portion of the light
entering the enclosure may continue through openings 526 in trap
portion 514 and corresponding openings 520 in base portion and be
emitted into the area where the insect trap 510 is installed.
Insects in the area are attracted to the UV and/or visible light
transmitted through openings 520 in base portion 512, and fly or
crawl into openings 520 and onto the adhesive-coated inside
surfaces 530 of trap portion 514, where they become stuck in the
adhesive and are trapped. The user may observe trapped insects by
looking through openings 520 and 526. When a sufficient number of
insects have been trapped, the user may easily remove and discard
the entire used trap portion 514 without touching trapped insects,
insect debris or adhesive, which remain out of reach inside trap
portion 514, and replace it with a new trap portion 514. The new
trap portion 514 may include fresh adhesive coating its inside
surfaces 530, housing 524 has a clean rear surface 538, through
which the UV and visible light is transmitted into trap portion
514, and the transparent or translucent material of trap portion
514 has not been degraded by prolonged exposure to UV light,
thereby ensuring that insect trap 510 will continue to efficiently
and effectively attract and trap insects.
[0102] It should be appreciated that a benefit of trap 510 is the
manipulation of light within trap portion 514. In some embodiments,
light manipulation occurs solely within trap portion 514. Light
manipulation may include reflection, refraction, polarization
and/or diffusion and is achieved by engaging with a manipulative
element or surface (e.g., housing 516 and adhesive-coated inside
surfaces 530). In some embodiments, light manipulation produces an
even distribution of light on an adhesive surface or adhesive
coating. In some embodiments, light is manipulated to produce a
predetermined pattern on the adhesive coating or within trap
portion 514, for example, an even distribution, an even
distribution with hot spots of higher intensity, hot spot patterns,
and/or combinations thereof.
[0103] Any suitable adhesive material may be used as part of an
adhesive surface for trapping an insect. In some embodiments,
pressure sensitive adhesives such as acrylics, butyl rubber,
natural rubber, nitriles, silicones, styrene block copolymers,
styrene-ethylene/propylene, styrene-isoprene-styrene, vinyl ethers
may be used. Generally, the thickness of such adhesives will be in
the range of approximately 0.01 mm to 1 mm. In some embodiments,
the adhesive thickness is in the range of approximately 0.05 mm to
0.2 mm, with a thickness of approximately 0.1 mm being most often
used.
[0104] An insect trap 510 of this configuration may accommodate a
variety of different trap portions 514 that may be removably
mounted to base portion 512, each trap portion 514 being uniquely
configured to attract and trap a specific species or multiple
species of insects. For example, the overall size and shape of trap
portion 514, and the size, shape, and orientation of openings 526
in housing 524 of trap portion 514, may be uniquely configured to
attract and trap a specific species or multiple species of insects.
For example, in some embodiments, trap portion 514 is approximately
20 mm to 600 mm wide, 20 mm to 600 mm high and 5 mm to 150 mm deep.
In some embodiments, trap portion 514 is approximately 20 mm to 200
mm wide, 20 mm to 200 mm high and 5 mm to 80 mm deep. In some
embodiments, trap portion 514 is approximately 20 mm to 130 mm
wide, 20 mm to 130 mm high and 5 mm to 50 mm deep.
[0105] In some embodiments, base portion 512 is approximately 20 mm
to 600 mm wide, 10 mm to 150 mm high and 10 mm to 150 mm deep. In
some embodiments, base portion 512 is 20 mm to 200 mm wide, 10 mm
to 100 mm high and 10 mm to 80 mm deep. In some embodiments, base
portion 512 is 20 mm to 130 mm wide, 10 mm to 50 mm high and 10 mm
to 50 mm deep.
[0106] As provided herein, openings 526 and openings 520 may be a
variety of shapes and/or sizes. For example, openings 526 and
openings 520 may be circular, square, rectangular, polygonal and/or
elliptical in shape. Alternatively, openings 526 and openings 520
may be slots having straight, curved or undulating shapes or
patterns. When openings 526 and openings 520 are circular, openings
526 and openings 520 may be approximately 0.5 mm to 30 mm in
diameter. In some embodiments, circular openings 526 and circular
openings 520 are approximately 0.5 mm to 20 mm in diameter. In some
embodiments, circular openings 526 and circular openings 520 are
approximately 0.5 mm to 15 mm in diameter. When openings 526 and
openings 520 are slot shaped, openings 526 and openings 526 may be
approximately 2 mm to 30 mm wide and 5 mm to 500 mm long. In some
embodiments, slot openings 526 and slot openings 520 are
approximately 2 mm to 20 mm wide and 5 mm to 200 mm long. In some
embodiments, slot openings 526 and slot openings 520 are
approximately 2 mm to 15 mm wide and 5 mm to 100 mm long.
[0107] In some embodiments, openings 526 cover all or a portion of
trap portion 514. For example, openings 526 may cover a range of
approximately 1% to 75% of the surface area of trap portion 514. In
some embodiments, openings 526 cover approximately 5% to 50% of the
surface area of trap portion 514. In some embodiments, openings 526
cover approximately 10% to 30% of the surface area of trap portion
514.
[0108] FIG. 17 shows an exploded view of a sixth embodiment of an
insect trap, indicated generally at 610. Insect trap 610 includes a
base portion 612 and a removable trap portion 614. Trap portion 614
is shown removed from base portion 612 in this view. In some
embodiments, base portion 612 includes a switch 616, configurable
to enable insect trap 610 to be turned on or off by closing or
opening switch 616, as desired by the user. Alternatively, switch
616 may be configured to control other features such as light
intensity, combinations of light wavelengths, different modes or
frequencies of flickering light, an automatic setting that turns on
when the room gets dark, or a remote control setting, for example.
Trap portion 614 includes a front housing 618 with at least one
opening 620.
[0109] Protruding from a rear surface 670 (shown in FIG. 18) of
base portion 612 are two electrically conductive prongs 622, only
one of which is shown, adapted to mount insect trap 610 to a wall
and provide power to insect trap 610 by inserting prongs 622 into a
standard household electrical wall socket. Alternatively, base
portion 612 may be configured to sit or hang wherever desired and
receive power from batteries (not shown) mounted in base portion
612. While an electrical socket and batteries have been described
as providing power to trap 610, any suitable power source may be
used. Base portion 612 includes a lighting element such as one or
more LEDs 624 and a rear housing 626 which includes a
reflective-coated inside surface 628. In some embodiments, the LEDs
include one that emits ultraviolet (UV) light and one that emits
visible light (e.g., blue light). In some embodiments, the lighting
element emits a combination of wavelengths to mimic sunlight. In
some embodiments, the material and surface finish of rear housing
626 may be configured to reflect UV and/or visible light without a
reflective coating. As shown, base portion 612 includes a
transparent or translucent window 630, shown partially cut away to
reveal the LEDs 624. Transparent or translucent window 630 protects
the reflective-coated inside surface 628 of rear housing 626 and
one or more LEDs 624 from dust and insect debris and allows base
portion 612 to be easily cleaned. Transparent or translucent window
630 may be attached at its perimeter (not shown) to rear housing
626 by any suitable manufacturing technique such as gluing or
ultrasonic welding. In some embodiments, transparent or translucent
window 630 is removably attached to rear housing 626. Base portion
612 includes one or more openings 632. In some embodiments, on
perimeter 672 of top surface 634 of base 612 is an upwardly
directed rim or protrusions 636.
[0110] FIG. 18 shows a cross-sectional view of the of insect trap
610, with removable trap portion 614 mounted on base portion 612,
and showing the interiors of base portion 612 and removable trap
portion 614. Removable trap portion 614 includes front housing 618
with the at least one opening 620 and a back plate 638, which may
be constructed of transparent or translucent material and coated
with a transparent or translucent adhesive 640 on a front surface
642. In some embodiments, the material and thickness of back plate
638 and the material and thickness of the adhesive 640 are selected
to transmit a substantial proportion of the UV and/or visible
light, for example greater than 60% of the light is transmitted
through back plate 638 and adhesive 640. Front housing 618 of trap
portion 614 and rear housing 626 of base portion 612 may be
constructed from any suitable material, including a thermoformed
opaque plastic material or other opaque, transparent or translucent
materials such as paper, paperboard, cardboard or paper pulp. In
some embodiments, front housing 618 and rear housing 626 are
constructed by injection molding or by other suitable manufacturing
techniques. Back plate 638 may be substantially planar, although it
may be formed into a convex, concave or saddle-shaped contour, or a
combination of contours to optimize the even distribution of light.
Alternatively, back plate 638 may have ribs or other features that
increase the adhesive-coated surface area, produce alternating
light/dark regions that some insect species find attractive, and
enhance the transmission of insect-attracting light into trap
portion 614.
[0111] In some embodiments, front housing 618 is be coated with
transparent, translucent or opaque adhesive on an inside surface to
provide additional insect trapping efficiency and capacity. In
addition, front housing 618 may also have a reflective coating
underneath the adhesive coating on its inside surface to enhance
its attraction to insects and further improve the insect trapping
efficiency and effectiveness. Front housing 618 and back plate 638
may be joined together at their perimeters with adhesive, although
they may also be joined by other commonly used packaging assembly
techniques such as ultrasonic welding or RF sealing, or any other
suitable assembly method. The materials of trap portion 614 may
include an insect attractant. For example, the materials of trap
portion 614 may be impregnated with sorbitol, coleopteran
attractants including brevicomin, dominicalure, frontalin,
grandlure, ipsdienol, ipsenol, japonilure, lineatin, megatomoic
acid, multistriatin, oryctalure, sulcatol, and trunc-call, dipteran
attractants including ceralure, cue-lure, latilure, medlure,
moguchun, muscalure, and trimedlure, homopteran attractants
including rescalure, lepidopteran attractants such as disparlure,
straight chain lepidopteran pheromones including codlelure,
gossyplure, hexalure, litlure, looplure, orfralure, and ostramone,
and other insect attractants such as eugenol, methyl eugenol, and
siglure, or other substances to provide a scent that further
increases the insect-attracting efficiency of the insect trap. In
such embodiments, the insect attractant is integral to trap portion
614. Alternatively, the insect attractants may be embedded in a
separate piece that mounts on an inside surface of front housing
618 or through an opening 620 in front housing 618 or on front
surface 642 of back plate 638. It is desirable for such attractants
to be detectable by an insect for approximately a 2 meter radius
from trap 610.
[0112] As shown, front housing 618 and back plate 638 form a front
enclosure 644 in trap portion 614, and rear housing 626 and window
630 form a rear enclosure 646 in base portion 612. In some
embodiments, base portion 612 includes a circuit board 648 having a
programmable processor or chip (not shown) for executing commands,
electrically connected to conductive prongs 622, switch 616 and one
or more LEDs 624. For clarity, however, not all of the electrical
connections are shown. Circuit board 648 may include electronic
circuitry to receive ordinary household current from conductive
prongs 622, respond to the position of switch 616 and provide power
to illuminate one or more LEDs 624. Circuit board 648 may include
an energy stabilizer such as a full wave rectifier circuit or any
other circuit that provides steady voltage to one or more LEDs 624
when switch 616 is in a closed position, although it may also
provide a varying voltage to one or more LEDs 624 to provide a
flickering light, which some species of insects find attractive.
For example, light flickering frequencies in the approximate range
of 0.05 Hz (e.g., to mimic the breathing rate of large mammals) to
250 Hz (e.g., the highest flicker frequency known to attract male
houseflies), may be desirable and the lighting element may be
configured to flicker within this range. Circuit board 648 may
provide power to one or more LEDs 624 to provide both UV and
visible light, although it may be configured to provide power to
only one or more UV LEDs 624 or to only one or more visible light
LEDs 624, or to provide variable power to produce combinations of
flickering UV and visible light. Circuit board 648 may also be
configured to drive a transmitter or transceiver such as a
piezoelectric speaker or other device that may be mounted in the
base portion 612 to emit an insect-attracting sound. For example,
the transmitter or transceiver may emit an insect-attracting sound
having a frequency in the range of approximately 0.5 Hz (e.g., the
heart rate of large mammals) to 240 KHz (e.g., the highest
frequency detectable by insects). In some embodiments, the
frequency is in the range of approximately 5 Hz to 100 KHz. In some
embodiments, the frequency is in the range of approximately 35 Hz
to 50 Khz. It is desirable for such insect-attracting sound to be
detectable by an insect for approximately a 2 meter radius from
trap 610. It is desirable for such insect-attracting sound to be
undetectable by a human beyond approximately a 1 meter radius from
trap 610.
[0113] As shown, upward protrusions or rim 636 on top surface 634
of base portion 612 engage with trap portion 614 to secure it in
place during use, although any other form of attachment may be
substituted that allows trap portion 614 to be securely but
removably mounted to base portion 612.
[0114] In the operation of insect trap 610, conductive prongs 622
are inserted into a wall electrical socket, and switch 616 is moved
to a closed position. One or more LEDs 624 emit light, preferably
UV and visible light, represented by arrows, which transmit through
at least one opening 632 in base portion 612, into rear enclosure
646, and onto reflective-coated inside surface 628 of rear housing
626 and rear surface 650 of window 630. In some embodiments, light
is not manipulated in base portion 612 and is emitted directly into
trap portion 614. Reflective-coated inside surface 628 of rear
housing 626 may include a concave shape and may be configured to
reflect the UV and visible light from one or more LEDs 624 to
distribute the light evenly onto rear surface 650 of window 630,
although inside surface 628 of rear housing 626 may have a convex
shape or a saddle shape or a combination of shapes, or may also
have ribs or other features to more evenly distribute the light.
Alternatively, an optical enhancer such as an anamorphic lens (not
shown) or any other lens or combination of lenses configured to
distribute UV and/or visible light (e.g., evenly, according to
specific patterns, at a focal point, etc.) onto rear surface 650 of
window 630, may be mounted to base portion 612 at or near opening
632 in base portion 612, and may replace or augment the role of
reflective-coated inside surface 628 of rear housing 626.
Alternatively, the UV and/or visible light from one or more LEDs
624 may directly strike rear surface 650 of window 630 at an
oblique angle (e.g., an acute angle from approximately 0.degree. to
90.degree.) and be spread across and through window 630 of base
portion 612 and onto back plate 638 of trap portion 614, and may
replace or augment the role of reflective-coated inside surface 628
of rear housing 626 or of the lens or lenses mounted to base
portion 612. The light may transmit through back plate 638 and
adhesive coating 640 on front surface 642, and into front enclosure
644. The light may be further evenly distributed by light-diffusing
properties of window 630 of base portion 612, back plate 638 of
trap portion 614, adhesive coating 640 on front surface 642 of back
plate 638, or any combination of window 630, back plate 638 and
adhesive coating 640. In some embodiments, a portion of the light
entering front enclosure 644 continues through one or more openings
620 in front housing 618 and is emitted into the area where the
trap is installed. Insects may be attracted to the UV and/or
visible light transmitted through adhesive coating 640 and/or
through one or more openings 620 in front housing 618, and fly or
crawl into one or more openings 620 and onto adhesive coating 640,
where they become trapped in the adhesive. The user may observe
trapped insects by looking through one or more openings 620 in
front housing 618. When a sufficient number of insects have been
trapped, the user may easily remove and discard the entire used
trap portion 614 without touching trapped insects, insect debris or
adhesive, which remain out of reach inside trap portion 614, and
replace it with a new trap portion 614. The new trap portion 614
may have fresh adhesive-coated surfaces, ensuring that insect trap
610 will continue to efficiently and effectively attract and trap
insects.
[0115] It should be appreciated that a benefit of trap 610 is the
manipulation of light within trap portion 614. In some embodiments,
light manipulation occurs solely within trap portion 614. Light
manipulation may include reflection, refraction, polarization
and/or diffusion and is achieved by engaging with a manipulative
element or surface (e.g., inside surface 628, window 630, back
plate 638 and adhesive coating 640). In some embodiments, light
manipulation produces an even distribution of light on an adhesive
surface or adhesive coating 640. In some embodiments, light is
manipulated to produce a predetermined pattern on the adhesive
coating 640 or within trap portion 614, for example, an even
distribution, an even distribution with hot spots of higher
intensity, hot spot patterns, and/or combinations thereof.
[0116] Any suitable adhesive material may be used as part of an
adhesive surface for trapping an insect. In some embodiments,
pressure sensitive adhesives such as acrylics, butyl rubber,
natural rubber, nitriles, silicones, styrene block copolymers,
styrene-ethylene/propylene, styrene-isoprene-styrene, vinyl ethers
may be used. Generally, the thickness of such adhesives will be in
the range of approximately 0.01 mm to 1 mm. In some embodiments,
the adhesive thickness is in the range of approximately 0.05 mm to
0.2 mm, with a thickness of approximately 0.1 mm being most often
used.
[0117] An insect trap 610 of this configuration may accommodate a
variety of different trap portions 614 that may be removably
mounted to base portion 612, each trap portion 614 being uniquely
configured to attract and trap a specific species or multiple
species of insects. For example, the overall size and shape of trap
portion 614, and the size, shape, and orientation of openings 620
in front housing 618 of trap portion 614, may be uniquely
configured to attract and trap a specific species or multiple
species of insects. For example, in some embodiments, trap portion
614 is approximately 20 mm to 600 mm wide, 20 mm to 600 mm high and
5 mm to 150 mm deep. In some embodiments, trap portion 614 is
approximately 20 mm to 200 mm wide, 20 mm to 200 mm high and 5 mm
to 80 mm deep. In some embodiments, trap portion 614 is
approximately 20 mm to 130 mm wide, 20 mm to 130 mm high and 5 mm
to 50 mm deep.
[0118] In some embodiments, base portion 612 is approximately 20 mm
to 600 mm wide, 10 mm to 150 mm high and 10 mm to 150 mm deep. In
some embodiments, base portion 612 is 20 mm to 200 mm wide, 10 mm
to 100 mm high and 10 mm to 80 mm deep. In some embodiments, base
portion 612 is 20 mm to 130 mm wide, 10 mm to 50 mm high and 10 mm
to 50 mm deep.
[0119] As provided herein, openings 620 may be a variety of shapes
and/or sizes. For example, openings 620 may be circular, square,
rectangular, polygonal and/or elliptical in shape. Alternatively,
openings 620 may be slots having straight, curved or undulating
shapes or patterns. When openings 620 are circular, openings 620
may be approximately 0.5 mm to 30 mm in diameter. In some
embodiments, circular openings 620 are approximately 0.5 mm to 20
mm in diameter. In some embodiments, circular openings 620 are
approximately 0.5 mm to 15 mm in diameter. When openings 620 are
slot shaped, openings 620 may be approximately 2 mm to 30 mm wide
and 5 mm to 500 mm long. In some embodiments, slot openings 620 are
approximately 2 mm to 20 mm wide and 5 mm to 200 mm long. In some
embodiments, slot openings 120 are approximately 2 mm to 15 mm wide
and 5 mm to 100 mm long.
[0120] In some embodiments, openings 620 cover all or a portion of
trap portion 614. For example, openings 620 may cover a range of
approximately 1% to 75% of the surface area of trap portion 614. In
some embodiments, openings 620 cover approximately 5% to 50% of the
surface area of trap portion 614. In some embodiments, openings 620
cover approximately 10% to 30% of the surface area of trap portion
614.
[0121] FIG. 19 shows a cross-sectional view of a seventh embodiment
of an insect trap, indicated generally at 710, and FIG. 20 is an
enlarged view of a portion of FIG. 19. Insect trap 710 includes a
base portion 712 and a removable trap portion 714. As shown, base
portion 712 includes a switch 716, configurable to enable insect
trap 710 to be turned on or off by closing or opening switch 716,
as desired by the user. Alternatively, switch 716 may be configured
to control other features such as light intensity, combinations of
light wavelengths, different modes or frequencies of flickering
light, an automatic setting that turns on when the room gets dark,
or a remote control setting, for example. Protruding from a rear
surface 770 of base portion 712 are two electrically conductive
prongs 718 (only one of which is shown in this view) adapted to
mount insect trap 710 to a wall and provide power to insect trap
710 by inserting prongs 718 into a standard household electrical
wall socket. Alternatively, base portion 712 may be configured to
sit or hang wherever desired and receive power from batteries (not
shown) mounted in base portion 712. While an electrical socket and
batteries have been described as providing power to trap 710, any
suitable power source may be used. In some embodiments, a slot 722
is located in a top surface 720 of base portion 712, and upwardly
directed protrusions 724 are located on a perimeter of top surface
720.
[0122] Trap portion 714 includes a front housing 726 with at least
one opening 728, a divider 730, a rear housing 736, a lighting
element such as one or more LEDs 740, and electrical trap contacts
742. In some embodiments, divider 730 is constructed from
transparent or translucent material and is coated with a
transparent or translucent adhesive 732 on a front surface 734. In
some embodiments, the material and thickness of the divider 730 and
the material and thickness of the adhesive 732 are selected to
transmit a substantial proportion of the UV and/or visible light,
for example greater than 60% of the light is transmitted through
divider 730 and adhesive 732. In some embodiments, LEDs 740 include
one that emits ultraviolet (UV) light and one that emits visible
light (e.g., blue light). In some embodiments, the lighting element
emits a combination of wavelengths to mimic sunlight. As shown,
there are two electrical trap contacts 742 for each of the one or
more LEDs 740. Thus, each pair of trap contacts 742 are
electrically connected to their respective LED 740.
[0123] In some embodiments, rear housing 736 includes a
reflective-coated inside surface 738. The material and surface
finish of rear housing 736 may alternatively be configured to
reflect UV and/or visible light without a reflective coating. Front
housing 726 and rear housing 736 may be constructed from any
suitable material, including a thermoformed opaque plastic material
or other opaque, transparent or translucent materials such as
paper, paperboard, cardboard or paper pulp. In some embodiments,
front housing 726 and rear housing 736 are constructed by injection
molding or by other suitable manufacturing techniques.
[0124] As shown, divider 730 may be substantially planar, although
it may be formed into a convex, concave or saddle-shaped contour,
or a combination of contours to optimize the even distribution of
light. Alternatively, divider 730 may include ribs or other
features that increase the adhesive-coated surface area, produce
alternating light/dark regions that some insect species find
attractive, and enhance the transmission of insect-attracting light
into interior of trap portion 714. In some embodiments, front
housing 726 is coated with transparent, translucent or opaque
adhesive on an inside surface to provide additional insect trapping
efficiency and capacity. In addition, front housing 726 may include
a reflective coating underneath the adhesive coating on an inside
surface to enhance its attraction to insects and further improve
the insect trapping efficiency and effectiveness. Front housing
726, divider 730 and rear housing 736 may be joined together at
their perimeters with adhesive, although they may also be joined by
other commonly used packaging assembly techniques such as
ultrasonic welding or RF sealing, or any other suitable assembly
method.
[0125] The materials of trap portion 714 may also include insect
attractants. For example, trap portion 714 may be impregnated with
be impregnated with sorbitol, coleopteran attractants including
brevicomin, dominicalure, frontalin, grandlure, ipsdienol, ipsenol,
japonilure, lineatin, megatomoic acid, multistriatin, oryctalure,
sulcatol, and trunc-call, dipteran attractants including ceralure,
cue-lure, latilure, medlure, moguchun, muscalure, and trimedlure,
homopteran attractants including rescalure, lepidopteran
attractants such as disparlure, straight chain lepidopteran
pheromones including codlelure, gossyplure, hexalure, litlure,
looplure, orfralure, and ostramone, and other insect attractants
such as eugenol, methyl eugenol, and siglure, or other substances
to provide a scent that further increases the insect-attracting
efficiency of the insect trap. In such embodiments, the insect
attractant is integral to trap portion 714. Alternatively, the
insect attractants may be embedded in a separate piece that mounts
on an inside surface of front housing 726 or through an opening 728
in front housing 726 or on front surface 734 of divider 730. It is
desirable for such attractants to be detectable by an insect for
approximately a 2 meter radius from trap 710. As shown, divider 730
separates trap portion 714 into a front enclosure 744 and a rear
enclosure 746.
[0126] In some embodiments, base portion 712 includes a circuit
board 748 having a programmable processor or chip (not shown) for
executing commands, electrically connected to conductive prongs
718, switch 716, and electrical base contacts 750. For clarity,
however, not all of the electrical connections are shown. While two
base contacts 750 in the base portion 712 for each of the LEDs 740
in the trap portion 714 are shown, any suitable number may be used.
Base contacts 750 may be configured to provide an electrical
connection with trap contacts 742 when trap portion 714 is
removably mounted to base portion 712. Circuit board 748 may
include electronic circuitry to receive ordinary household current
from conductive prongs 718, respond to the position of switch 716
and provide power to base contacts 750, which, in turn, provide
power to trap contacts 742 and illuminate LEDs 740 in trap portion
714 when trap portion 714 is mounted to base portion 712. In some
embodiments, circuit board 748 includes an energy stabilizer such
as a full wave rectifier circuit or any other circuit that provides
steady voltage to one or more LEDs 740 when switch 716 is in a
closed position and trap portion 714 is mounted to base portion
712, although it may also provide a varying voltage to one or more
LEDs 740 to provide a flickering light, which some species of
insects find attractive. For example, light flickering frequencies
in the approximate range of 0.05 Hz (e.g., to mimic the breathing
rate of large mammals) to 250 Hz (e.g., the highest flicker
frequency known to attract male houseflies), may be desirable and
the lighting element may be configured to flicker within this
range. Circuit board 748 may provide power to one or more LEDs 740
to provide both UV and visible light, although it may be configured
to provide power to only one or more UV LEDs 740 or to only one or
more visible light LEDs 740, or to provide variable power to
produce combinations of flickering UV and visible light. Circuit
board 748 may also be configured to drive a transmitter or
transceiver such as a piezoelectric speaker or other device that
may be mounted in base portion 712 to emit an insect-attracting
sound. For example, the transmitter or transceiver may emit an
insect-attracting sound having a frequency in the range of
approximately 0.5 Hz (e.g., the heart rate of large mammals) to 240
KHz (e.g., the highest frequency detectable by insects). In some
embodiments, the frequency is in the range of approximately 5 Hz to
100 KHz. In some embodiments, the frequency is in the range of
approximately 35 Hz to 50 Khz. It is desirable for such
insect-attracting sound to be detectable by an insect for
approximately a 2 meter radius from trap 710. It is desirable for
such insect-attracting sound to be undetectable by a human beyond
approximately a 1 meter radius from trap 710.
[0127] In some embodiments, base portion 712 includes a slot 722
and protrusions 724 in top surface 720, which are configured to
engage with trap portion 714 to secure it in place during use,
although any other form of attachment may be substituted that
allows trap portion 714 to be securely but removably mounted to
base portion 712.
[0128] In the operation of insect trap insect trap 710, conductive
prongs 718 are inserted into a wall electrical socket, switch 716
is moved to a closed position, and trap portion 714 is mounted to
base portion 712. One or more LEDs 740 emit light, represented by
arrows, preferably UV and visible light, which transmit light into
rear enclosure 746, and onto reflective-coated inside surface 738
of rear housing 736 and rear surface 752 of divider 730. In some
embodiments, light is not manipulated in base portion 712 and is
emitted directly into trap portion 714. Reflective-coated inside
surface 738 of rear housing 736 may be a concave shape and
configured to reflect UV and/or visible light from one or more LEDs
740 to distribute the light evenly onto rear surface 752 of divider
730, although the shape of inside surface 738 of rear housing 736
may have a convex shape or a saddle shape or a combination of
shapes, or may also have ribs (not shown) or other features to more
evenly distribute the light. Alternatively, an optical enhancer
such as an anamorphic lens (not shown) or any other lens or
combination of lenses configured to distribute UV and/or visible
light (e.g., evenly, according to specific patterns, at a focal
point, etc.) onto rear surface 752 of divider 730, may be mounted
to rear housing 736 proximate to or above LEDs 740 or may be
mounted to LEDs 740, and may replace or augment the role of
reflective-coated inside surface 738 of rear housing 736.
Alternatively, the UV and/or visible light from one or more LEDs
740 may directly strike the rear surface 752 of divider 730 at an
oblique angle (e.g., an acute angle from approximately 0.degree. to
90.degree.) and may be spread across divider 730, and may replace
or augment the role of reflective-coated inside surface 738 of rear
housing 736, or of the lens or lenses mounted to rear housing 736
or to LEDs 740. The light may transmit through divider 730 and
adhesive coating 732 on front surface 734, and into front enclosure
744. The light may be further evenly distributed by the
light-diffusing properties of divider 730, adhesive coating 732 on
front surface 734, or both. A portion of the light entering front
enclosure 744 continues through one or more openings 728 in front
housing 726 and is emitted into the area where trap 710 is
installed. Insects may be attracted to the UV and/or visible light
transmitted through adhesive coating 732 and/or through one or more
openings 728 in front housing 726, and fly or crawl into one or
more openings 728 and onto adhesive coating 732, where they become
trapped in the adhesive. The user may observe trapped insects by
looking through one or more openings 728 in front housing 726. When
a sufficient number of insects have been trapped, the user may
easily remove and discard the entire used trap portion 714 without
touching trapped insects, insect debris or adhesive, which remain
out of reach inside trap portion 714, and replace it with a new
trap portion 714. The new trap portion 714 may have fresh
adhesive-coated surfaces and light-directing surfaces, ensuring
that the insect trap 710 will continue to efficiently and
effectively attract and trap insects.
[0129] It should be appreciated that a benefit of trap 710 is the
manipulation of light within trap portion 714. In some embodiments,
light manipulation occurs solely within trap portion 714. Light
manipulation may include reflection, refraction, polarization
and/or diffusion and is achieved by engaging with a manipulative
element or surface (e.g., inside surface 738, divider 730 and
adhesive coating 732). In some embodiments, light manipulation
produces an even distribution of light on an adhesive surface or
adhesive coating. In some embodiments, light is manipulated to
produce a predetermined pattern on the adhesive coating or within
trap portion 714, for example, an even distribution, an even
distribution with hot spots of higher intensity, hot spot patterns,
and/or combinations thereof.
[0130] Any suitable adhesive material may be used as part of an
adhesive surface for trapping an insect. In some embodiments,
pressure sensitive adhesives such as acrylics, butyl rubber,
natural rubber, nitriles, silicones, styrene block copolymers,
styrene-ethylene/propylene, styrene-isoprene-styrene, vinyl ethers
may be used. Generally, the thickness of such adhesives will be in
the range of approximately 0.01 mm to 1 mm. In some embodiments,
the adhesive thickness is in the range of approximately 0.05 mm to
0.2 mm, with a thickness of approximately 0.1 mm being most often
used.
[0131] An insect trap 710 of this configuration may accommodate a
variety of different trap portions 714 that may be removably
mounted to base portion 712, each trap portion 714 being uniquely
configured to attract and trap a specific species or multiple
species of insects. For example, the overall size and shape of trap
portion 714, the size, shape, and orientation of openings 728 in
front housing 726 of trap portion 714, and the wavelength and
intensity of the LEDs 740 may be uniquely configured to attract and
trap a specific species or multiple species of insects. For
example, in some embodiments, trap portion 714 is approximately 20
mm to 600 mm wide, 20 mm to 600 mm high and 5 mm to 150 mm deep. In
some embodiments, trap portion 714 is approximately 20 mm to 200 mm
wide, 20 mm to 200 mm high and 5 mm to 80 mm deep. In some
embodiments, trap portion 714 is approximately 20 mm to 130 mm
wide, 20 mm to 130 mm high and 5 mm to 50 mm deep.
[0132] In some embodiments, base portion 712 is approximately 20 mm
to 600 mm wide, 10 mm to 150 mm high and 10 mm to 150 mm deep. In
some embodiments, base portion 712 is 20 mm to 200 mm wide, 10 mm
to 100 mm high and 10 mm to 80 mm deep. In some embodiments, base
portion 712 is 20 mm to 130 mm wide, 10 mm to 50 mm high and 10 mm
to 50 mm deep.
[0133] As provided herein, openings 728 may be a variety of shapes
and/or sizes. For example, openings 728 may be circular, square,
rectangular, polygonal and/or elliptical in shape. Alternatively,
openings 728 may be slots having straight, curved or undulating
shapes or patterns. When openings 728 are circular, openings 728
may be approximately 0.5 mm to 30 mm in diameter. In some
embodiments, circular openings 728 are approximately 0.5 mm to 20
mm in diameter. In some embodiments, circular openings 728 are
approximately 0.5 mm to 15 mm in diameter. When openings 728 are
slot shaped, openings 728 may be approximately 2 mm to 30 mm wide
and 5 mm to 500 mm long. In some embodiments, slot openings 728 are
approximately 2 mm to 20 mm wide and 5 mm to 200 mm long. In some
embodiments, slot openings 728 are approximately 2 mm to 15 mm wide
and 5 mm to 100 mm long.
[0134] In some embodiments, openings 728 cover all or a portion of
trap portion 714. For example, openings 728 may cover a range of
approximately 1% to 75% of the surface area of trap portion 714. In
some embodiments, openings 728 cover approximately 5% to 50% of the
surface area of trap portion 714. In some embodiments, openings 728
cover approximately 10% to 30% of the surface area of trap portion
714.
[0135] FIG. 21 is a perspective view of an eighth embodiment of an
insect trap, indicated generally at 810. Insect trap 810 includes a
trap portion 814 and a base portion 812. In FIG. 21, trap portion
814 is shown removed from the base portion 812. In some
embodiments, trap portion 814 includes a tab 818 protruding
downward from a bottom surface 850. Base portion 812 may have a
corresponding opening 824 (shown in FIG. 23) to receive tab 818
when trap portion 814 is mounted to base portion 812. As shown,
base portion 812 includes a switch 816.
[0136] FIG. 22 is a cross sectional view of insect trap 810 showing
trap portion 814 mounted to base portion 812 and FIG. 23 is an
enlarged view of a portion of FIG. 22. In some embodiments, base
portion 812 includes a circuit board 822 having a programmable
processor or chip (not shown) for executing commands, and
configured to provide power and instructions to desired components
(e.g., switch 816, LEDs 826, etc.). For clarity, however, not all
of the electrical connections are shown. In some embodiments,
circuit board 822 includes a docking or trap switch 820 mounted
thereon. Tab 818 on trap portion 814 may protrude through
corresponding opening 824 in base portion 812 and engage electrical
trap switch 820 when trap portion 814 is mounted to base portion
812. Trap switch 820 may be configured to close when tab 818 on
trap portion 814 engages with it and may be configured to open when
the 818 is lifted from trap switch 820 (e.g., when trap portion 814
is removed from base portion 812). In some embodiments, trap switch
820 is configured to activate in response to pressure from tab 818
on trap portion 814. Alternatively, trap switch 820 may be
configured to activate in response to displacement by tab 818 on
trap portion 814. Alternatively, trap switch 820 may be configured
as an optical switch to close when a light beam is broken by tab
818 of trap portion 814, or may be configured as a Hall effect
sensor to close when in proximity to a magnet on trap portion 814,
or may be configured as any other switch or sensor that opens or
closes when trap portion 814 is mounted or removed from base
portion 812.
[0137] Trap switch 820 is electrically connected to circuit board
822 and/or switch 816 to deactivate a lighting element such as UV
and/or visible light LEDs 826 when trap portion 814 is removed from
base portion 812, thereby preventing the user from looking directly
at the UV and/or visible light from the LEDs 826. Alternatively,
trap switch 820 may be electrically connected to circuit board 822
and/or switch 816 to deactivate only the UV LEDs 826 when trap
portion 814 is removed from the portion 812.
[0138] In view of the many possible embodiments to which the
principles of the present discussion may be applied, it should be
recognized that the embodiments described herein with respect to
the drawing figures are meant to be illustrative only and should
not be taken as limiting the scope of the claims. For example,
while angle measurements have been described as relative to the
primary direction of light from the LEDs, for simplicity, the
angles could also be relative to the vertical axis. In addition,
for each of the embodiments, the front of the housing (or the
entire housing or the entire trap portion) may be formed in a
variety of decorative and/or functional shapes. For example, the
housing may be shaped to resemble a flower or a plant, or a shell,
or a company logo, or a sports team logo, or a football, or
basketball, or soccer ball, or hockey puck, or a football helmet,
or a hockey stick, or any other shape. Each of the example
embodiments may include elements from other embodiments, even if
not explicitly shown. Therefore, the techniques as described herein
contemplate all such embodiments as may come within the scope of
the following claims and equivalents thereof.
* * * * *