U.S. patent application number 15/690630 was filed with the patent office on 2018-02-08 for air cooled horticulture lighting fixture.
This patent application is currently assigned to IP Holdings, LLC. The applicant listed for this patent is IP Holdings, LLC. Invention is credited to John Stanley.
Application Number | 20180035617 15/690630 |
Document ID | / |
Family ID | 54016977 |
Filed Date | 2018-02-08 |
United States Patent
Application |
20180035617 |
Kind Code |
A1 |
Stanley; John |
February 8, 2018 |
AIR COOLED HORTICULTURE LIGHTING FIXTURE
Abstract
An air cooled horticulture lamp fixture for growing plants in
confined indoor spaces. The fixture substantially seals the lamp
and heat generated thereby to a reflector interior. A flow
disruptor diverts moving air away from an aperture in the reflector
through which a lamp bulb socket protrudes into the reflector
interior, and the flow disruptor creates turbulence in a cooling
chamber thereby enhancing thermal transfer into a cooling air
stream that flows over and around the reflector's exterior side
thereby convectively cooling the fixture using the reflector as a
heat sink.
Inventors: |
Stanley; John; (Vancouver,
WA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
IP Holdings, LLC |
Vancouver |
WA |
US |
|
|
Assignee: |
IP Holdings, LLC
Vancouver
WA
|
Family ID: |
54016977 |
Appl. No.: |
15/690630 |
Filed: |
August 30, 2017 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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14665381 |
Mar 23, 2015 |
9750199 |
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15690630 |
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13945794 |
Jul 18, 2013 |
9016907 |
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14665381 |
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29493634 |
Jun 11, 2014 |
D748849 |
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13945794 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
Y02P 60/146 20151101;
A01G 7/045 20130101; Y02P 60/14 20151101; F21V 29/60 20150115; H01J
61/22 20130101 |
International
Class: |
A01G 7/04 20060101
A01G007/04; H01J 61/22 20060101 H01J061/22; F21V 29/60 20060101
F21V029/60 |
Claims
1. A method of cooling a horticulture lighting fixture, the method
comprising the steps of: providing said horticulture lighting
fixture having a housing 200 with a downward facing bottom opening
205, a first duct 235, a second duct 245, a housing interior 220, a
reflector 100 captured within said housing interior 220, and a
socket 830 extending through said housing interior 220 and oriented
so that said socket 830 holds a lamp bulb 2 in a substantially
parallel orientation in relation to a longitudinal axis extending
between the first duct 235 and the second duct 245; installing said
lamp bulb 2 into said socket 830 so that operation of said lamp
bulb 2 illuminates surfaces of a reflector exterior side 102 of
reflector 100 to reflect light downward through opening 205;
hanging said horticulture lighting fixture at a predetermined
height above plants to be grown thereunder in a plant growing
environment; attaching a fan to said first duct 235; energizing
said fan so as to flow cooling air between said first duct 235 and
second duct 245; energizing said lamp bulb 2 so as to reflect light
downward through opening 205; removing heat from said fixture by
flowing cooling air between said first duct 235 and second duct 245
through a cooling chamber defined by the space between said housing
interior 220 and a reflector interior side 101, with said cooling
chamber formed so as to substantially prevent cooling air flowing
between said first duct 235 and said second duct 245 from flowing
between said reflector exterior side 102 and said reflector
interior side 101; and allowing said lamp bulb 2 to operate
substantially free from contact with cooling air flowing between
said first duct 235 and said second duct 245, so that operating
temperatures of said lamp bulb 2 are allowed to be higher than if
said lamp bulb 2 were subjected to contact with cooling air flowing
between said first duct 235 and said second duct 245.
2. The method of claim 1 further comprising: connecting intake
ducting to said fan and configuring said fan so as to force cooling
air into said first duct 235.
3. The method of claim 2 further comprising: connecting exhaust
ducting to said second duct 245.
4. The method of claim 3 further comprising: configuring said
intake and exhaust ducting so that said plant growing environment,
with said lighting fixture oriented above a plant growing space
thereunder, is isolated from cooling air flowing into the first
duct 235 and exhausted through the second duct 245.
5. The method of claim 4 further comprising: substantially
preventing air within said growing environment from mixing with
cooling air flowing between the first duct 235 and the second duct
245.
6. The method of claim 4 further comprising: substantially
preventing air within said growing environment from being pulled in
to said lighting fixture and exhausted through said second duct 245
with a positive pressure between said first duct 235 and said
second duct 245, said positive pressure created by forcing cooling
air from said fan into said first duct 235.
Description
RELATED APPLICATIONS
[0001] This application is a continuation of U.S. patent
application Ser. No. 14/665,381 filed on Mar. 23, 2015, which is a
continuation-in-part of U.S. patent application Ser. No. 13/945,794
filed on Jul. 18, 2013, now U.S. Pat. No. 9,016,907 issued on Apr.
28, 2015, and is a continuation-in-part of U.S. Design Patent
Application Serial No. 29/493,634 filed on Jun. 11, 2014, now U.S.
Design Patent D748,849 issued on Feb. 2, 2016.
TECHNICAL FIELD OF THE INVENTION
[0002] This invention relates generally to horticulture light
fixtures for growing plants indoors, and particularly to an air
cooled fixture used in confined indoor growing spaces that burns a
high intensity horticulture lamp.
DESCRIPTION OF RELATED AND PRIOR ART
[0003] Horticulture light fixtures used for growing plants in
confined indoor spaces must provide adequate light to grow plants,
while not excessively raising the temperature of the growing
environment. Removal of the heat generated by the fixture is
commonly achieved by forcing cooling air around the lamp and
through the fixture, exhausting the same out of the growing
environment. The air used for cooling the fixture is not mixed with
the growing atmosphere, as the growing atmosphere is specially
controlled and often enhanced with Carbon Dioxide to aid in plant
development and health.
[0004] Innovations in electronic ballast technology made feasible
for use in the indoor garden industry an improved high pressure
sodium TIPS' grow lamp that is connected to power at each end of
the lamp, thus the term "Double Ended". The double ended lamp as
powered from each end is also supported by sockets at each end,
thereby eliminating the need for a frame support wire inside the
lamp as required in standard single ended HPS lamps. The absence of
frame wire eliminates shadows that commonly plague single ended HPS
lamps. The double ended lamp further benefits from a smaller arc
tube that is gas filled rather than vacuum encapsulated. The
smaller arc tube equates to a smaller point source of light,
thereby improving light projection control and photometric
performance. The double ended HPS lamp proves to be more efficient
than its single ended HPS lamp equivalent, last longer than like
wattage HPS lamps, and produces more light in beneficial wavelength
for growing plants than any single ended HPS lamps of the same
light output rating.
[0005] The double ended HPS lamp, with all of its light output
performance advantages, has a significant particularity in
operation, specifically when cooling the lamp. Operating
temperatures at the lamp envelope surface must be maintained within
a narrow operating range else the double ended HPS lamp's
efficiencies in electrical power conversion into light energy are
significantly reduced. When impacted by moving air, the double
ended HPS lamp draws excessive electrical current which may cause
failure or shutdown of the ballast powering the lamp. When bounded
by stagnant air held at constant operating temperature the double
ended HPS lamp proves more efficient in converting electricity to
light energy and produces more light in the plant usable spectrum.
This particularity in the double ended HPS lamp makes it an
excellent grow lamp, but also thwarted earlier attempts to enclose,
seal, and air cool the double ended HPS lamp to be used in confined
indoor growing application due to the lamp's substantial
sensitivity to moving cooling air.
[0006] Another challenges not resolved by the prior art involves
sealing the glass sheet to the bottom of the fixture. The reflector
interior temperatures when burning a double ended HPS lamp cause
failures of gasket materials. Further, the ultraviolet and infrared
light energies produced by the double ended HPS lamp degrade and
make brittle rubber, neoprene, and most other gasket materials
suitable for sealing the glass sheet.
[0007] Gavita, a lighting company from Holland produces various
fixtures utilizing the double ended HPS lamp. The usual
configuration includes a reflector with a spine, the spine having a
socket on each opposing end such that the double ended lamp is
suspended under a reflector over the plants. The reflector is not
sealed from the growing environment, nor is there a housing
enclosure or ducts to facilitate forced air cooling. The Gavita
fixtures provide the benefit of the high performing double ended
HPS lamp, but lacks air cooling capability which is necessary in
many indoor growing applications as discussed above.
[0008] What is needed, are horticulture lighting fixtures and
methods for using such fixtures that address particular aspects of
the high intensity horticulture lamps use in such fixtures.
SUMMARY OF THE INVENTION
[0009] In view of the foregoing, one object of the present
invention is to provide an air cooled double ended HPS lamp fixture
for growing plants in confined indoor environments.
[0010] A further object of this invention is to provide a fixture
construct wherein the excessive heat generated by the lamp is
removed using a stream of forced air.
[0011] It is another object of the present invention to provide a
stagnant air space around the lamp that is maintained at constant
temperatures within the reflector during operation to prevent the
lamp from drawing excessive current when subjected to temperatures
differentials, or direct moving cooling air.
[0012] Another object of the present invention is to provide a
positive air tight seal between the fixture and the growing
environment using a gasket that is protected from the lamp's
damaging light.
[0013] This invention further features turbulence enhancement of
the cooling air stream by a diverter that disrupts the air stream
creating eddies over the top of the reflector.
[0014] An object of the present invention is to provide a
horticulture lighting fixture that allows for improved operation of
single ended high pressure sodium horticulture lamps.
[0015] An object of the present invention is to provide a
horticulture lighting fixture that allows for improved operation of
a high intensity horticulture lamp tube oriented horizontally and
substantially parallel to the fixture opening.
[0016] An object of the present invention is to provide alternative
structures for an air cooled horticulture lighting fixture that
utilizes a cooling chamber to remove heat conducted through
reflective material isolating the lamp from the cooling
chamber.
[0017] Other objects, advantages, and features of this invention
will become apparent from the following detailed description of the
invention when contemplated with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0018] Elements in the figures have not necessarily been drawn to
scale in order to enhance their clarity and improve understanding
of these various elements and embodiments of the invention.
Furthermore, elements that are known to be common and well
understood to those in the industry such as electrical power
connection are not necessarily depicted in order to provide a clear
view of the various embodiments of the invention, thus the drawings
are generalized in form in the interest of clarity and
conciseness.
[0019] FIG. 1 shows an isometric exploded view of a preferred
embodiment of the inventive fixture.
[0020] FIG. 2 is a cutaway exploded side view of the fixture in
FIG. 1.
[0021] FIG. 3 is a diagrammatically section end view of the fixture
in FIG. 1.
[0022] FIG. 3A is a perspective exploded view of the flow disruptor
in FIG. 1.
[0023] FIG. 3B is a perspective exploded view of the flow disruptor
in FIG. 3A further including turbulators.
[0024] FIG. 4 is a cutaway corner of the fixture in FIG. 1 showing
the compressively deformed shadowed gasket.
[0025] FIG. 5 is a front end view of a fixture having a different
flow disruptor structure than shown in FIG. 3, according to
preferred embodiments.
[0026] FIG. 6 is a rear end view of the fixture depicted in FIG. 5,
according to preferred embodiments.
[0027] FIG. 7 is a top view of the fixture depicted in FIGS. 5 and
6, according to preferred embodiments.
[0028] FIG. 8 is a bottom view of the fixture depicted in FIGS.
5-7, showing incorporation of a single ended lamp socket protruding
from an aperture in the reflector interior surface, according to
preferred embodiments.
[0029] FIG. 9 is a perspective view of the fixture shown in FIGS.
5-8, as viewed from below, according to preferred embodiments.
[0030] FIG. 10 is a perspective view of an air flow diverter or
disruptor structure, according to various preferred
embodiments.
DETAILED DESCRIPTION OF THE DRAWINGS
[0031] As depicted and shown in the FIGS., a "heat sink" is a
component used for absorbing, transferring, or dissipating heat
from a system. Here, the reflector 100 acts as the "heat sink" for
the lamp 2 which is isolated from the cooling air stream 310 within
the reflector interior side 101. The reflector 100 convectively
transfers heat generated by the lamp 2 into the cooling air stream
310. "Convectively transfers" refers to the transport of heat by a
moving fluid which is in contact with a heated component. Here, the
fluid is air, specifically the cooling air stream 310 and the
heated component is the reflector 100. Due to the special
prerequisite criteria that the double ended high pressure sodium
(HPS) lamp 2 be isolated from moving air, and specifically the
cooling air stream 310, the heat transfer is performed convectively
from the reflector exterior side 102 to the cooling air stream 310.
The rate at which the heat transfer can convectively occur depends
on the capacity of the replenishable fluid (i.e. cooling air stream
310) to absorb the heat energy via intimate contact with the
relatively high temperature at the reflector exterior surface 102.
This relationship is expressed by the equation q=hA.DELTA.T,
wherein, "h" is the fluid convection coefficient that is derived
from the fluid's variables including composition, temperature,
velocity and turbulence. "Turbulence" referring to a chaotic flow
regime wherein the fluid/air undergoes irregular changes in
magnitude and direction, swirling and flowing in eddies. "Laminar"
flow referring to a smooth streamlined flow or regular parallel
patterns, generally having a boundary layer of air against the
surface over which the laminar flow moves. When cooling with a heat
sink device within a cooling medium such as air, turbulent flow
proves more effective in transferring heat energy from the heat
sink into the flowing air. Turbulent flow acts to scrub away the
boundary layer or push away the stagnant layer of air that is
closest to the heat sink, thereby enhancing the fluid convection
coefficient increasing heat transfer. Turbulent flow also increases
velocities and pressures on the surface to be cooled, increasing
thermal transfer. The term "Turbulator" as referenced herein is a
device that enhances disruption of a laminar flow into a more
turbulent flow.
[0032] Although repeated reference may be made to a preferred
embodiment, and although preferred embodiments may be described in
the context of a horticulture lighting fixture configured to use a
double ended high pressure sodium lamp, various embodiments are
described that the inventor discovered apply to other types of
lamps and especially high intensity lamps used for horticulture
applications and those lamps that benefit from various aspects of
the various embodiments. The various inventive aspects are
separable and may apply to lighting fixtures generally, to lighting
fixtures requiring cooling, to lighting fixtures with air cooling
features and using lamps that have improved performance when the
lamp is isolated from moving air used to cool the fixture, to
lighting fixtures that use a single ended type high intensity
horticulture lamp, or to other applications.
[0033] Referring now to FIG. 1-2, a preferred embodiment of the
fixture comprises a reflector 100 captured within a housing 200
defining a cooling chamber 300 within the air space located between
the reflector exterior side 102 and housing interior 220, the
cooling chamber 300 being in air communication with a first duct
and second duct. A cooling air stream 310 is disposed through the
cooling chamber 300 between the first duct 235 and the second duct
245. Two lamp sockets 230A-B located partially through two opposing
reflector apertures 105A-B provide the install location for the
double ended HPS lamp within the reflector interior side 101. A
flow disruptor 160 fixates over each socket 230A-B and aperture
105A-B diverting moving air from entering the reflector interior
side 101 while further creating air eddies and local air turbulence
within the cooling chamber 300 between the sockets over the
reflector top 104 at the reflector's 100 hottest spot,
substantially above the lamp 2. The flow disruptor 160 interference
with the cooling air stream 310 creates air eddies, increases local
vortex velocities within the cooling chamber 300, scrubs away
boundary layers of air proximal to the reflector exterior side 102
that reduce heat transfer, thereby enhancing convective heat
transfer from the reflector 100 into the cooling air stream
310.
[0034] With reference to FIG. 1 and FIG. 2, the fixture 1 includes
a housing 200, a reflector 100 captured within the housing 200, a
cooling chamber 300 defined by the air space between the housing
200 interior and the reflector exterior side 102. The cooling
chamber 300 being in air communication with a first duct 235 and
second duct 245, located substantially on opposite sides of the
housing 200. Between the first duct 235 and the second duct 245
flows the cooling air stream 310 through the cooling chamber 300,
the cooling air stream 310 which is pushed or pulled by remote fan
not shown but commonly used in the prior art, connected by hose or
ducting to the first duct 235.
[0035] Before flowing over the reflector top 104, the cooling air
stream 310 is split or deflected by the flow disruptor 160
enhancing turbulent flow thereby increasing thermal transfer from
the reflector interior side 101, through the reflector 100,
convectively transferring from the reflector exterior side 102 into
the cooling air stream 310. The hottest area of the reflector 100
is the reflector top 104 directly above the lamp 2, which is the
closest structure to the light source. As captured within the
housing 200, the reflector 100 has a reflector top air gap 104A
defined between the reflector top 104 and the housing interior 220.
The reflector top 104 air gap 104A for the preferred embodiment
using a 1000 watt double ended HPS lamp is 3/8 of an inch, which
provides ample cooling chamber 300 space for turbulent air movement
as between the reflector top 104 and the housing interior 220
facilitating adequate cooling while maintaining an acceptably air
insulated housing 200 exterior temperature.
[0036] By cutaway illustration with dashed lines in FIG. 2, the
lamp 2 is shown installed by its ends into the sockets 230A-B
within the reflector interior side 101 near the reflector top 104.
The lamp 2 is shown oriented parallel to the cooling air stream
310, however, the robust design allows for the lamp 2 to be
oriented within the reflector 100 at any diverging angle relative
to the cooling air stream 310.
[0037] As shown diagrammatically by sectioned view in FIG. 3,
cooling air directions being depicted by arrows illustrates the
cooling air stream 310 as impacted by the flow disruptor 160. In
operation, the cooling air stream 310 is being forced to move with
a fan (not shown) either by fan push or fan pull through the first
duct 235, then into and through the cooling chamber 300 to be
exhausted out the second duct 245. The cooling air stream 310 is
diverted and split by a flow disruptor 160 directing part of the
air over one side of the reflector exterior 102, the other part
over the other side of the reflector exterior 102. The diverted
cooling air stream 310 is redirected within the fixture 1 such that
moving air is discouraged from pressuring any apertures, gaps, or
through holes in the reflector 100.
[0038] As depicted in FIG. 3 and shown in FIG. 3A, the flow
disruptor 160 constructed to be deflecting and disrupting to moving
air and arranged to attach over at least one socket 230 and enclose
at least one aperture 105 such that cooling air moving through the
cooling chamber 300 is diverted and disrupted into a more turbulent
flow than a laminar flow regime. A preferred embodiment locates the
flow disruptor 160 to encourage deflection of moving air away from
the sockets 230 and aperture 105 as discussed above, essentially
fulfilling two functions, creating turbulence within the cooling
chamber 300 while also redirecting moving air away from reflector
areas 100 that may be subject to leaks. The flow disruptor 160
location is not limited to enclosing the sockets 230 or apertures
105, as a flow disruptor 160 located within the first duct 235 or
second annular duct 245, depending on which receives the incoming
cooling air stream 310, is effective at introducing turbulence into
the cooling air stream 310, and depending on which configuration
may be preferred. Additional flow disruptors 160 working
independently or in cooperation may be included within the cooling
chamber 300 mounted to the reflector 100 or the housing 200.
[0039] The preferred embodiment design of the flow disruptor 160
shown in FIG. 3A is simply constructed from a first sheet metal
portion 160A and a second sheet metal portion 160B, the preferred
metal being steel over aluminum, as the thermal conductivity of the
flow disruptor 160 is not as important as the costs associated with
manufacture, but in practice both metals are suitable. As shown in
FIG. 3A, the flow disruptor 160 is impervious to moving air to
facilitate the dual function of deflecting moving air away from the
reflector apertures 105 while also creating turbulence within the
cooling chamber 300.
[0040] As shown in FIG. 3B, an enhanced flow disruptor 160 having
turbulators 161 illustratively depicted as rows of through holes.
The turbulators 161 could also be fins, blades, vents, or grating,
most any disrupting structure, redirecting channel, or obstacle for
the cooling air stream 310 will cause turbulence and thereby
increase thermal conductivity from the reflector 100 into the
cooling air stream 310.
[0041] As discussed above, the reflector 100 is a thermally
conductive component of the fixture acting as a heat sink for the
lamp 2. The reflector 100 preferably is constructed from aluminum,
which is the favored material because of its relatively high
thermal conductivity, easily shaped and formed, and highly
reflective when polished. The high thermal conductivity of aluminum
provides beneficial heat transfer between the reflector interior
side 101 to the reflector exterior side 102 thermally transferring
or heat sinking through the reflector 100. Steel is also a suitable
material, however the lower thermal conductivity makes aluminum the
preferred reflector 100 material.
[0042] As shown in the FIGS., openings, gaps, or spaces through the
reflector 100 are preferably filled, blocked, or covered such that
the reflector interior side 101 is substantially sealed from moving
air. As assembled and captured within the housing 200, a first
socket 230A is disposed to fill a reflector 100 first aperture 105A
sealing the first aperture 105A from moving air. A second socket
230B is disposed to fill the second aperture 105B sealing the
second aperture 105B against moving air. The first socket 230A and
second socket 230B constructed and arranged to cooperatively
receive the ends of the double ended HPS lamp 2 as located within
the reflector interior side 101 between the two sockets 230A-B. As
shown from the side in FIG. 2 and by depiction in FIG. 3, flow
disruptors 160 attach over the sockets 230A-B and over both
apertures 105A-B within the path of the cooling air stream 310. In
this way, the flow disruptors 160 enclose any opening or space
between either socket 230A-B and aperture 105A-B respectively,
thereby diverting air moving through the cooling chamber 300 away
from any potential opening into the reflector interior side 101.
Filling of each aperture 105A-B by partial insert of each socket
230A-B requires precise manufacturing tolerances or specially
formed sockets 230 in order to prevent or substantially stop moving
air from traveling around the socket 230 into the reflector
interior side 101. Heat resistant sealing mediums like metal tape
or high temp calk are available to positively seal the aperture 105
to the socket 230 thereby diverting the cooling air path 310 from
entering the reflector interior side 101. However, high temperature
sealing mediums tend to be expensive, and application of the
sealing medium as performed manually is often messy, slow, and
leaves one more step in the manufacturing process subject to human
error. As discussed herein, a preferred embodiment utilizes flow
disruptors 160 constructed from sheet metal that are impervious to
air rather than sealing mediums. However sealing mediums if
properly applied will work in the place of a flow disruptor 160 for
the limited purpose of sealing the reflector interior 101, but lack
the aerodynamic structure necessary to disturb the cooling air
stream 310 creating turbulence between the first socket 230A and
second socket 230B for enhanced convective transfer of heat from
the reflector 100 into the cooling air stream 310.
[0043] In FIG. 4 a sectional view with a close up of the bottom
corner of the fixture 1 showing by illustration the cooling chamber
300 as defined between the reflector 100 and the housing 200. The
cooling chamber 300 is shown in cross section demonstrating from
top to bottom the relative size of air space between the reflector
100 and the housing 200 for the preferred embodiment. As shown,
there is only one continuous cooling chamber 300, however several
smaller cooling chambers 300 split by disruptors 160 or mounting
fins between the housing interior 220 and the reflector 100 provide
greater control of the movement of the cooling air stream 310
through the fixture 1.
[0044] The lower left close up view shown in FIG. 4 of the bottom
corner of the fixture 1 demonstrates the lower lip 103 of the
reflector 100 location as captured within the housing 200, wherein
the lower lip 103 is adjacent to and slightly extending below the
housing lower edge 210. As captured, the reflector's 100 lower lip
103 and housing lower edge 210 thermally transfer heat energy. This
heat sinking occurring between the reflector's 100 hotter lower lip
103 and the housing 200 cooler lower edge 210 makes the lower lip
103 the coolest part of the reflector 100, making for the most
suitable place to seal the reflector 100 using a gasket 31. A
specially formed reflector lip 103 protectively shadows the gasket
31 from damaging light energy produced by the double ended HPS lamp
2 thereby preventing premature failure of the gasket 31 during
operation. As compressed, the gasket seals against the housing edge
surface slightly deforming 31A to further seal against the
reflector lip 103. In this way, a double redundant seal is provided
between the fixture interior and the growing environment, while
also providing a positive air tight seal between the cooling
chamber 300 and the reflector interior side 101 that is not as
susceptible to premature seal failure.
[0045] As shown in FIG. 4, a compressive sealing between a glass
sheet 30 and the housing edge 210 with a gasket 31 sandwiched in
between thereby seals the growing environment from the fixture
interior, in preferred embodiments. The gasket 31 being located
relative to the reflector 100 such that the reflector lower lip 103
shadows or blocks direct light 2A produced by the lamp from
impacting the gasket 31. As shown, the glass sheet 30 is preferably
held in place compressively by at least one latch 32 with enough
compressive force to deform the gasket 31. The deformed gasket 31A
sealingly contacts the lower lip 103 making a second redundant seal
against the coolest part of the reflector 100 at the lower lip 103
which is shadowed and protected from the direct light energy
produced by the lamp 2. For a preferred embodiment the gasket 31 is
constructed of a porous neoprene material, however many suitable
heat resistant gasket materials may be used to construct the gasket
31.
[0046] In less preferred embodiments, the gasket 31 may be, as
shown in FIG. 4, compressed between the lower lip 103 and the
perimeter material shown retaining the glass 30 and fastenable to
latch 32, but without the glass sheet 30 itself. That is, in less
preferred embodiments the glass sheet 30 may be omitted with the
structure shown in FIG. 4 still providing isolation between the
reflector interior 101 and the cooling chamber 300. As shown, the
housing 200 cooler lower edge 210 may be formed so as to maintain a
substantially sealed lower edge 210 portion of the cooling chamber
300. The inventor discovered horticulture applications not
requiring the thermal protective aspects (i.e. to protect plants
growing under the fixture from burning) benefit from increase light
projected from the lamp and reflector interior 101 when a glass
sheet 30 is not used with the fixture. Without the glass sheet 30,
the inventor discovered, an open (i.e. no glass) air cooled
horticulture lighting fixture is provided that beneficially
isolates cooling air flow from the lamp, which the inventor
discovered in turn improves light performance from the fixture.
[0047] In some embodiments, the fixture 1 may comprise an air
cooled horticulture lighting fixture having the cooling chamber 300
and other features previously described, except configured with a
different flow disruptor 560 as shown in FIG. 5 which is a front
end view of a fixture 1 having a different flow disruptor 560
structure than shown in FIG. 3. The cooling air stream 310, as
shown, flows in through a first duct 235 and is diverted by a
disruptor 560, with part of the moving air diverted to one side of
the reflector exterior 102 by a first angled surface 502 and part
of the moving air diverted to the other side of the reflector
exterior 102 by a second angled surface 504. The diverted cooling
air stream 310 is redirected within the fixture 1 such that moving
air is discouraged from pressuring any apertures, gaps, or through
holes in the reflector 100.
[0048] In some embodiments a disruptor such as the disruptor 560 is
oriented in one or the other of the first duct 235 or the second
duct 245, or both the first duct 235 and the second duct 245, as
illustrated in FIG. 2. In one embodiment, as shown in FIGS. 5 and
6, a disrupter 560 is oriented in the first duct 235 but not the
second duct 245. FIG. 6 is a rear end view of the fixture depicted
in FIG. 5, according to preferred embodiments, with the cooling air
stream 310 flowing over and around the reflector exterior 102 and
out of the second duct 245.
[0049] FIG. 7 is a top view of the fixture depicted in FIGS. 5 and
6, according to preferred embodiments, and FIG. 8 is a bottom view
of the fixture depicted in FIGS. 5-7, showing incorporation of a
single ended lamp socket 830 protruding from an aperture 805 in the
reflector interior surface 101, according to preferred embodiments.
FIG. 9 is a perspective view of the fixture shown in FIGS. 5-8, as
viewed from below, according to preferred embodiments.
[0050] The socket 830 preferably receives a single ended high
pressure sodium horticulture lamp, orienting the (tube shaped) lamp
(not shown) to extend from the socket 830 nearest the first duct
235 longitudinally in a direction toward the second duct 245. The
lamp when fit into the socket 830 is preferably oriented
substantially parallel to a longitudinal axis extending between the
first duct 235 and the second duct 245. In preferred embodiments,
the lamp when fit into the socket 830 is oriented substantially
parallel to a plane formed by the lower edges 210 of the housing
200, or parallel to a plane formed by the lower lip 103 of the
reflector 100, and on the reflector interior 101 side of the
reflector 100, isolated from the cooling chamber 300.
[0051] In preferred embodiments, the portion of the socket 830
extending through the aperture 805 in the reflector 100 comprises
structure that discourages air flow from pressuring the aperture
805, and preferably comprises structure in common with the
disruptor 560. FIG. 10 is a perspective view of an air flow
diverter or disruptor 560 structure, according to various preferred
embodiments. Preferably the flow disruptor 560 shown in FIG. 10 is
simply constructed from a first sheet metal portion 560A and a
second sheet metal portion 560B. Also preferably, the disruptor 560
comprises diverter surfaces 502 and 504 on one end, with similarly
angled diverter surfaces on the other end, so that air moving
longitudinally in either direction to or from the first duct 235 or
the second duct 245 is diverted around the aperture 805 in the
reflector 100 and portions of the socket 830 extending into the
reflector exterior side 102.
[0052] The various embodiments described herein may have cooling
air pushed or pulled through the cooling chamber 300 by fan or
other forced air apparatus, and in either direction. The robust
fixture 1 cools effectively with either a negative pressure or
positive pressure within the housing 200 due to the isolated
reflector 100 interior side 101. Two fans used in cooperation may
be implemented without diverging from the disclosed embodiment, and
linking fixtures together along one cooling system is also
feasible, similar to current `daisy chaining` configurations.
[0053] Also illustrated in FIGS. 8 and 9 are surface regions of
reflector interior 101, shown numbered consecutively from 852 to
869. Each surface region is preferably (as shown) a flat interior
surface of the reflector interior 101. The inventor discovered that
using different surface finishes for different regions affect the
light intensity directed to particular target areas. Depending upon
the particular type of lamp bulb used, choosing a mirror reflective
finish, in one embodiment, for regions in the corners--shown
numbered consecutively from 852 to 859--and a hammertone reflective
surface finish in the side and end regions--shown numbered
consecutively from 860 to 869--may soften hot spots in the light
projected from the fixture 1 that would otherwise exist if a mirror
reflective finish were used. In another embodiment, choosing the
reverse--mirror finish in the side and end regions and hammertone
finish in the corners--may achieve the softening of hot spots,
depending upon the particular type of lamp bulb used, for example
whether a double ended HPS bulb or a single ended HPS bulb is used
in the horticulture lighting fixture 1 as shown and described in
the FIGS. In similar fashion, the inventor discovered that any
particular region--any one or more of the regions consecutively
numbered from 852 to 869--may comprise a hammertone finish with the
rest of the regions being a mirror reflective finish, to maximize
the amount of light directed to the plant growing target and
selectively soften hot spots that may be characteristic for
particular types or manufacture of horticulture high intensity lamp
bulbs.
[0054] The foregoing detailed description has been presented for
purposes of illustration. To improve understanding while increasing
clarity in disclosure, not all of the electrical power connection
or mechanical components of the air cooled horticulture light
fixture were included, and the invention is presented with
components and elements most necessary to the understanding of the
inventive apparatus. The intentionally omitted components or
elements may assume any number of known forms from which one of
normal skill in the art having knowledge of the information
disclosed herein will readily realize. It is understood that
certain forms of the invention have been illustrated and described,
but the invention is not limited thereto excepting the limitations
included in the following claims and allowable functional
equivalents thereof.
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