U.S. patent number 3,929,259 [Application Number 05/476,314] was granted by the patent office on 1975-12-30 for chemical dispensing anti-burglar device.
Invention is credited to Werner F. Esseluhn, Charles R. Fegley.
United States Patent |
3,929,259 |
Fegley , et al. |
December 30, 1975 |
Chemical dispensing anti-burglar device
Abstract
A chemical dispensing anti-burglar device is disclosed in which
a chemical such as tear gas is discharged into the area to be
protected when an intruder opens a window or a door or forces open
a window or a door to enter a private or unauthorized area with
which the device is associated. The anti-burglar device employs an
expandable cartridge for moving a reciprocal member which will
discharge a chemical from a pressurized container. An improved
means for releasing a chemical from a pressurized container is
described.
Inventors: |
Fegley; Charles R. (Laureldale,
PA), Esseluhn; Werner F. (Wyomissing, PA) |
Family
ID: |
23891355 |
Appl.
No.: |
05/476,314 |
Filed: |
June 4, 1974 |
Current U.S.
Class: |
222/61; 116/86;
222/162; 222/82; 222/325 |
Current CPC
Class: |
G08B
15/02 (20130101) |
Current International
Class: |
G08B
15/00 (20060101); G08B 15/02 (20060101); B67D
005/08 () |
Field of
Search: |
;42/1G
;116/65,75,86,139,142
;222/3,5,52,61,79,81-83,160,162,389,180,182,183,325-326,319,320-324 |
References Cited
[Referenced By]
U.S. Patent Documents
Primary Examiner: Reeves; Robert B.
Assistant Examiner: Skaggs, Jr.; H. Grant
Claims
We claim:
1. A chemical dispensing anti-burglar device for use with a
pressurized container, the device comprising: a housing, means for
supporting said pressurized container in said housing; a fluid
passageway extending through said housing having an entry section,
means for discharging fluid from said pressurized container into
said entry section of said passageway, a reciprocal member
slideably mounted within said housing and adapted upon movement to
discharge fluid from said pressurized container, an enclosed
expansion chamber within said housing, an expansive charge within
said chamber, means for causing expansion of said charge within
said chamber, said reciprocal member having a surface against which
the gases resulting from said expansion react to move said
reciprocal member within said housing to cause discharge, a spring
activated retaining means for locking said reciprocal member in
position to cause discharge after said expansion, a sealing means
formed around said entry section and said discharging means and
arranged to prevent fluid leakage as fluid is discharged from said
pressurized container into said passageway.
2. The invention of claim 1 wherein said means to cause expansion
of said charge comprises an electric element through which an
electric current is passed to cause said expansion.
3. The invention of claim 1 wherein said means to cause expansion
of said charge comprises firing member; a means for releasably
retaining said firing member in a cocked position displaced from
said expandable cartridge; said retaining means including a trigger
element; said trigger element being mounted for movement within
said body member between an actuation position and a release
position; said trigger element in said actuation position in
engagement with surface of said firing member to retain said firing
member in said cocked position; said trigger element in said
release position allowing said firing member to cause said
expansion.
4. The invention of claim 1 wherein said passageway contains a
means of producing sound; said means of producing sound comprising
a chamber in said passageway to cause vibrations of the fluid in
said chamber resulting from oscillations produced as said fluid is
flowing through a narrow slot against a knifeedge forming part of
said passageway.
5. A chemical dispensing anti-burglar device for use with a
pressurized container including a projecting dispensing spout
actuated to emit fluid discharge therethrough upon depresson
thereof, a housing, means for supporting said pressurized container
in said housing, a fluid passageway extending through said housing
having an entry section, a reciprocal member slideably mounted
within said housing and adapted upon movement to actuate said
dispensing spout, an enclosed expansion chamber within said
housing, an expansive charge within said chamber, means for causing
expansion of said charge within said chamber, said reciprocal
member having a surface against which the gases resulting from said
expansion react to move said reciprocal member, a spring activated
retaining means for locking said reciprocal member in a position to
actuate said dispensing spout and thereby cause discharge after
said expansion, a sealing means formed around said entry section
and dispensing spout and arranged to prevent fluid leakage as fluid
is discharged from said pressurized container into said
passageway.
6. A chemical dispensing anti-burglar device for use with a
pressurized container including a pierceable section, a housing,
means for supporting said pressurized container in said housing, a
fluid passageway extending through said housing having an entry
section, means for piercing said pierceable section whereby fluid
may be discharged into said passageway, said means for piercing
comprises a projecting spout depending from said entry section of
said passageway, a reciprocal member slideably mounted within said
housing and adapted upon movement to cause piercing of said
pierceable section, an enclosed expansion chamber within said
housing, an expansive charge within said chamber, means for causing
expansion of said charge within said chamber, said reciprocal
member having a surface against which the gases resulting from said
expansion react to move said reciprocal member, a spring activated
retaining means for locking said reciprocal member in a position to
cause discharge after said expansion, a sealing means formed around
said entry section and pierceable section and arranged to prevent
fluid leakage as fluid is discharged from said pressurized
container into said passageway.
Description
BACKGROUND OF THE INVENTION
The invention relates generally to an anti-burglar device and more
particularly to an anti-burglar device which discharges a chemical
such as tear gas from a pressurized container, one type of which is
an aerosol container, into a protected area upon activation by an
unauthorized person, causing the protected area to be flooded with
a chemical and forcing evacuation of the protected area by the
intruder; but the invention is not limited to the use of the
aerosol type container.
Chemical weapons have been known in the art for many years. One
type of chemical weapon is the conventional tear gas grenade in
which the firing member is generally triggered manually and the
grenade is manually hurled at a target area, causing the target
area to be flooded with the chemical irritant.
In another type of chemical weapon, the chemical irritant is stored
under pressure in an aerosol type container. The firing member is
again generally triggered manually and the chemical irritant in the
form of a spray is manually directed at a target.
A third type of chemical anti-burglar device discharges an
explosive tear gas shell into the area but this type is both
dangerous and very limited as to the amount of tear gas which is
discharged into the area to be protected.
Thus what is needed is an anti-burglar device in the form of a
chemical dispenser which an intruder will activate the dispensing
means of the pressurized chemical container with sufficient force
to release the chemical from the pressurized container but which
anti-burglar device is positively secured against accidental
release until triggered by an intruder and which will then release
a sufficient volume of the chemical into the protected area to
force evacuation by the intruder.
SUMMARY OF THE INVENTION
The principle object of the present invention is to provide an
anti-burglar device of the chemical dispensing type which may be
triggered directly by a small amount of mechanical movement, and
yet is positively secured against accidental release.
A further object of the invention is to provide an anti-burglar
device of the chemical weapon type which is readily triggered by
opening a door or window by an intruder entering an unauthorized
area or by moving an object with which the device is connected.
Another object of the invention is to provide an improved means of
spraying or discharging the chemical into the protected area in a
minimum amount of time in order to force the intruder from the
protected area and to prevent the intruder from re-entering the
protected area for a reasonable amount of time.
Another object of the present invention is to provide a directable
emission of the chemical, such as by means of rotatably adjustable
spray head, so that the invention might be located on a door, wall,
or the like, and yet, when the device is discharged, the chemical
is directed into the area to be protected.
An additional object of the invention is to produce an audible
alarm on certain embodiments of the chemical dispensing
anti-burglar device; so that the chemical dispensing anti-burglar
device will provide a warning to the intended victim, the owner, or
security personnel.
According to the principle aspect of the present invention there is
provided an improved means of releasing a chemical from a
pressurized container of the anti-burglar device. Such means
includes an expansive cartridge containing an expansive charge
which increases in volume when activated causing a reciprocal
member to discharge the chemical from the pressurized container.
The anti-burglar device is connected to a door or window or other
object which might be moved by an unauthorized person entering a
room or building, or other area from which it is desired to
restrict unauthorized persons.
When the door or window associated with the device is opened by an
unauthorized person or when the object is moved by an authorized
person or when the person enters the restricted area, a contact
closure sends an electric current from a power source through an
electric element in the cartridge which causes the expansive charge
to expand in volume. The expanding gases resulting from the
expansion moves a reciprocal member which causes the discharge of
the pressurized container.
Since the anti-burglar device is triggered by an electric current;
the anti-burglary device can very easily be placed in a safe mode
by authorized personnel by disconnecting the power source or
opening a switch remote from the actuation switch.
A mechanical means for discharging the anti-burglar device through
the means of a cord connected to the device is also disclosed.
The anti-burglar device of the chemical weapon type of the present
invention may be utilized in homes, factories, farms, office
buildings by attaching the device to doors, windows, etc. and may
be used in connection with vehicles such as automobiles, boats,
trucks, airplanes, etc. The device may also be employed for any
other application wherein it is desired to prevent unauthorized
persons from moving certain objects by placing the object against
the actuator arm of the actuation switch to hold the actuation
switch contacts open thereby preventing the device from firing
until unauthorized movement of the subject objects.
Once actuated, the spray cannot be turned off by the intruder and
the entire amount of pressurized chemical will be discharged into
the protected area making it impossible for the intruder to remain
in the protected area without having protective equipment.
Other objects, aspects and advantages of the invention will become
apparent from the following description taken in connection with
the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWING
FIG. 1 is an elevational view of a wall of a room having one
embodiment of the chemical dispensing anti-burglar device of the
present invention secured to the wall and connected by means of
wires to a switch on the sash of a window in the wall.
FIG. 2 is an elevational similar to FIG. 1, but showing the window
open and showing the device discharging.
FIG. 3 is a side elevational view of the chemical dispensing
anti-burglar device.
FIG. 4 is a front elevational view of the chemical dispensing
anti-burglar device.
FIG. 5 is a top view of the chemical dispensing anti-burglar
device.
FIG. 6 is a partial horizontal section taken along line A--A of
FIG. 3.
FIG. 7 is a vertical section taken along line B--B of FIG. 5
showing the expansive cartridge in its cocked position displaced
from the pressurized container.
FIG. 8 is a vertical section taken along line C--C of FIG. 7
showing the device discharging.
FIG. 9 is a horizontal section taken along line D--D of FIG. 7.
FIG. 10 is a horizontal section taken along line E--E of FIG.
7.
FIG. 11 is a partial vertical section taken along line B--B of FIG.
5 showing a second embodiment of the antiburglar device containing
a pressurized container of the aerosol type but with a recessed
valve.
FIG. 12 is a partial vertical taken along line B--B of FIG. 5 but
showing a third embodiment of the anti-burglar device wherein the
device is inverted and the chemical dispensing device contains a
pressurized container having a pierceable seal.
FIG. 13 is a front elevational view similar to FIG. 3 but showing a
fourth embodiment of the chemical dispensing anti-burglar device
containing a pressurized container of the aerosol type with a
projecting cap.
FIG. 14 is a partial vertical section taken along line F--F of FIG.
13 showing the device discharging.
FIG. 15 is a top view of the fourth embodiment containing a
projecting cap.
FIG. 16 is partial vertical sectional taken along line G--G of FIG.
15.
FIG. 17 is a diagram of the circuit using the internal batteries of
the anti-burglar device.
FIG. 18 is a diagram showing a circuit using an external power
supply by-passing the on-off switch of the device.
FIG. 19 is a side elevational view similar to FIG. 13 but showing a
fifth embodiment of the anti-burglar device wherein the reciprocal
member activates the dispensing spout.
FIG. 20 is a front elevational view similar to FIG. 14 of the
anti-burglar device.
FIG. 21 is a partial horizontal section taken along line H--H of
FIG. 19.
FIG. 22 is a partial horizontal section taken along line J--J of
FIG. 19.
FIG. 23 is a vertical section taken along line K--K of FIG. 20
showing the expansive cartridge and the reciprocal member in its
cocked position displaced from the dispensing spout of the
pressurized container.
FIG. 24 is a partial vertical section taken along line L--L of FIG.
23 but showing the device discharging.
FIG. 25 is a partial horizontal section taken along line M--M of
FIG. 23.
FIG. 26 is a partial horizontal section taken along line N-N of
FIG. 24.
FIG. 27 is a partial vertical section taken along line K--K of FIG.
20 but showing a sixth embodiment of the anti-burglar device
containing a pressurized container of the aerosol type but with
recessed valve.
FIG. 28 is a partial vertical section taken along line K--K of FIG.
20 but showing a seventh embodiment of the antiburglar device
wherein the device is inverted and the chemical dispensing device
contains a pressurized container having a pierceable seal.
FIG. 29 is a partial vertical section taken along line K--K of FIG.
20 but showing an eighth embodiment of the device containing a
pressurized container of the aerosol type with a projecting
cap.
FIG. 30 is an elevational view similar to FIG. 1 but showing the
anti-burglar device mounted on a wall and connected by means of a
cord to the sash of a window in the wall.
FIG. 31 is an elevational view similar to FIG. 30 but showing the
window open and showing the device discharging.
FIG. 32 is a side elevational view of the chemical dispensing
anti-burglar device.
FIG. 33 is a front elevational of the chemical dispensing
anti-burglar device.
FIG. 34 is a top elevational view of the chemical dispensing
anti-burglar device.
FIG. 35 is a partial horizontal section taken along line P--P of
FIG. 33.
FIG. 36 is a vertical section taken along line R--R of FIG. 33
showing the expansive cartridge and the reciprocal member in its
cocked position and the pressurized container displaced from its
discharging means.
FIG. 37 is a vertical section taken along line T--T of FIG. 36.
FIG. 38 is a horizontal section taken along line S--S of FIG.
36.
FIG. 39 is a horizontal section taken along line Q--Q of FIG.
37.
FIG. 40 is a vertical section taken along R--R of FIG. 33 but
showing the chemical dispensing device discharging.
FIG. 41 is a horizontal section taken along line U--U of FIG.
40.
FIG. 42 is a vertical section similar to FIG. 37 but showing a
tenth embodiment wherein the pressurized container has a recessed
valve.
FIG. 43 is a partial vertical section similar to FIG. 40 but
showing an eleventh embodiment wherein the device is inverted and
the chemical dispensing device contains a pressurized container
having a pierceable seal.
FIG. 44 is a front elevational view showing a twelfth embodiment of
the device wherein the device contains a projecting dispensing
cap.
FIG. 45 is a vertical section taken along line V--V of FIG. 44.
FIG. 46 is a vertical section similar to FIG. 45 but showing the
device discharging.
Description of the Preferred Embodiment
Referring now to the drawings in detail, wherein like reference
characters designate like parts throughout the various views, there
is shown in FIGS. 1-10, one form of the anti-burglar chemical
dispensing device, called device hereafter, of the chemical weapon
type according to the present invention, generally designated
1.
As shown in FIGS. 1-2, the device 1 is secured to a wall 90 and
connected with connecting wires 44 and 45 to an actuation switch 43
mounted on the window frame 70. A switch actuation pin 48 is
mounted on window 50 in a manner that the switch actuation pin 48
depresses the switch actuation lever 49 and holds the switch
actuation lever 49 such that the switch contacts are held open. The
device 1 includes a self-contained power source such as a battery
17 but the power source is not limited to the battery 17 nor is the
power source limited to being self-contained.
The device 1 whose front is shown in FIGS. 4 and 7 is comprised of
a valved pressurized chemical container 35, called pressurized
container 35 hereafter, a housing 4, an expansion chamber 42, an
expansive charge 30 and a reciprocal member 28. One type of housing
4 is shown as being comprised of a left housing half 2 and a right
housing half 3 which when assembled provide three flat sides, other
than the back for mounting the device 1 to the wall 90 adjacent to
the window 70 or elsewhere, as may be convenient or desired.
Now referring to FIGS. 4 and 8, the container and expansion chamber
cavity 34, the battery cavity 62, the switch cavity 63, and the
cylindrical bore 64 are formed when the symetrically opposite
housing halves 2 and 3 are joined together. As shown in FIGS. 7 and
8, the container and expansion chamber cavity 34 provides a means
for slidably mounting the pressurized container 35 which is
slidably confined in proper position. The pressurized container 35
of which one type is sold Penquin Industries, Inc., Parkesburg, Pa.
identified as their "10-4 Chemical Billy" but the invention is not
limited to the use of this container. The pressurized container
comprises of a spring urged dispensing spout 37 which when
depressed discharges a chemical 39 through the center of the
dispensing spout 37. Again referring to FIGS. 7 and 8, one type of
expansion chamber 42 is shown as an expansive cartridge 65, but the
invention is not limited to the use of the expansive cartridge 65
shown. The pressurized container and expansive cartridge cavity 34
also provides a means for mounting the expansive cartridge 65 and
contains small vertical slots 33 formed in its sides. The purpose
of these slots will become apparent later.
The battery cavity 62 provides a means for installing an electrical
power source such as a battery 17 and the switch cavity 63 provides
a means for installing an electrical switch 11 which is used to
turn the device 1 off or on as desired.
As shown in FIGS. 3 and 7, terminals 14, 15 and 16 are installed on
the bottom of the device 1 for convenience. The use of the
terminals 14, 15 and 16 will be described in the description of
electrical circuits showing different methods of making electrical
connections to device 1.
Still referring to FIG. 7, a rotatable nozzle section 6 is
rotatably mounted in the cylindrical bore 64 formed when the
symetrically opposite housing halves 2 and 3 are joined together as
shown in FIGS. 4 and 8. It is important that the rotatable nozzle 6
and its fluid passageway 8 be in coaxial alignment with projecting
dispensing spout 37 of the pressurized container 35. As the
pressurized container 35 moves in the direction of arrow 41; the
fluid passageway 8 and nozzle section 9 provide a means for the
chemical 39 to be discharged into and directed from when the
dispensing spout 37 of the pressurized container 35 is forced into
the entry section 7 by the action of the expansive charge 30
contained in the expansive cartridge 65, the action of which will
be later described. The funnel shape of the entry section 7 engages
the dispensing spout 37, which is made of relatively soft material
and therefore provides an adequate seal at the entry section 7 to
retain fluid flow in the passageway 8 at pressures normally used in
pressurized containers.
As best seen in FIG. 7, the expansive cartridge 65 comprises: an
electric element 31, a cartridge case 27, a reciprocal member 28, a
retainer spring 66, and the expansive charge 30. The expansive
cartridge 65 has a an electric element 31 installed and
electrically insulated from the cartridge case 27. The expansive
charge 30 such as gunpowder or any other material which will expand
upon ignition, heating or release, is placed in the cartridge case
27. The reciprrocal member 28 is installed over the cartridge case
27 and the assembly is held together by a light press fit between
the cartridge case 27 and the reciprocal member 28. The retaining
spring 66 is then placed over the assembled expansive cartridge 65
and the unit is mounted in the bottom of the pressurized cylinder
cavity 34.
The retaining spring 66 has four spring sections 29 which are set
in the retaining spring guide slots 32 formed in the housing halves
2 and 3. The friction of the retaining spring 66 and the retaining
spring guide slots 32 holds the reciprocal number 28 in place until
fired.
As can best be seen in FIGS. 1 and 7, one method of electrically
connecting the device 1 is shown. The electric element wire 31 is
connected to the terminal 15 by wire 23. Terminal 15 has an
additional wire 22 attached to it which connects to the negative
terminal of battery 17 through wire 22. The positive terminal of
the battery 17 is connected to one pole of switch 11 by wire 20.
The other pole of switch 11 is connected by wire 21 to terminal 17.
A wire 44 is then connected from terminal 14 to a switch 43 located
in an area where the intruder will activate the switch 43, one
example of which is shown in FIG. 1. A wire 45 connects the other
pole of switch 43 to terminal 16 thereby completing the
circuit.
Switch 11 is turned on to activate the protective device 1. When an
unauthorized person or intruder opens window 50; the pin 48 mounted
on window 50 releases the activator arm 49 of switch 43 closing the
contact of switch 43 and completing the circuit. The electric
current then causes the an electric element 31 to heat which causes
the expansive charge 30 to expand rapidly forcing the reciprocal
members 28 and the retainer spring 29 toward the container 35. The
reciprocal member 28 and container 35 continue to move in direction
of arrow 41 forcing the projecting dispensing spout 37 into
engagement with the entry section 7 of passageway 8 causing
discharge. In addition, the retainer springs 29 snap open into the
retainer spring slots 33 and prevent the reciprocal member 28 from
moving in an opposite direction to arrow 41 thereby holding the
projecting spout 37 in engagement with entry section 7 of fluid
passageway 8 and causing the pressurized container 35 to discharge
its contents 39 completely into the area to be protected.
It is an important feature that the pressurized cylinder 35 and the
retaining spring 29 ride freely in their respective cavities formed
in housing halves 2 and 3 and present a surface which will ride
smoothly when the reciprocal member 28 is set off. Hence,
substantially less force is required to discharge the device 1 of
the present invention then would be required if the retaining
spring 29 and pressurized cylinder 35 were tightly fit into their
cavities, yet the device 1 can be safely handled in its cocked
position because of the force required to depress the projecting
dispensing spout 37. It is also important in this embodiment that
the discharging means is comprised of a projecting dispensing spout
37 for activating a valved pressurized container 35 wherein fluid
discharge is caused when the projecting dispensing spout 37 is
depressed. The housing 4 contains a fluid passageway 8 having a
funnel shaped entry section 7 for engaging the projecting spout 37
and for forming a seal between the funnel shaped entry section 7
and the dispensing spout 37, thereby, permitting fluid flow through
the dispensing spout 37 and the funnel shaped entry section 7 when
the pressurized container 35 is moved toward the fluid passageway
8.
A second embodiment of the invention is illustrated in FIG. 11 as
device 71. In this embodiment the basic structure is as previously
described and like numbers are used to indicate like or
corresponding parts.
In the second embodiment, the pressurized chemical container 35,
shown in FIG. 7 having a projecting dispensing spout 37, is
replaced with a pressurized chemical container 75, shown in FIG.
11, having a recessed valve. Pressurized containers of the aerosol
type with a recessed dispensing valve are well known in the trade.
In addition, the funnel shape of the entry section 7 of the fluid
passageway 8 of the first embodiment shown in FIG. 7 is replaced
with projecting spout 77 depending from housing halves 72 and 73,
all of which are shown in FIG. 11.
In the second embodiment, all elements function as described in the
first embodiment with the following difference. The pressurized
container 75 is discharged by the action of the reciprocal member
28 moving the pressurized container 75 such that the recessed valve
of the pressurized container 75 is depressed through engagement
with projecting spout 77 and thereby effects discharge.
The chemical is then discharged through the valve of the
pressurized container 75, through the projecting spout 77 and
passageway 78 and out the orifice 79, then into the area to be
protected.
A third embodiment of the invention is illustrated in FIG. 12 as
device 81. In this embodiment, the structure is as previously
described in the first embodiment and like numbers are used to
indicate like or corresponding parts.
In the third embodiment, the pressurized chemical container 35,
shown in FIG. 7 of the first embodiment and having a projecting
dispensing spout 37, is replaced with a pressurized chemical
container 85 shown in FIG. 12, having a pierceable seal 87.
Pressurized container having pierceable seals are well known in the
trade. In addition, the funnel shaped entry section 7 of the
housing halves 1 and 2 of the first embodiment shown in FIG. 7 is
replaced with housing halves 81 and 82 having a projecting section
67 shaped to pierce seal 87 and a means of making a seal capable of
withstanding the pressure required for effectively discharging the
chemical through the passageway 88 and into the restricted
area.
Now referring to FIG. 12, FIG. 12 is an inverted embodiment of FIG.
7 of the first embodiment in which all elements function as
previously described in the first embodiment with the following
exceptions. The expansive cartridge 65 when fired forces the
pressurized container 85 into pierceable engagement with the
piercing projecting section 67. As the pierceable seal 87 is
pierced by the action of the projecting forward section 67 of the
housing halves 82 and 83 the reciprocal member 28 continues to move
the pressurized container 85 forming a seal by the action of the
O-Ring 68 and its retaining seat 69 and the pierceable seal 87 of
the pressurized container 85. The chemical 39 is then discharged
through the pierced seal 87 of the pressurized container 85,
through passageway 88, out the orifice 89, and then into the area
to be protected. It is important in this embodiment that the
discharging means comprises a shaped projecting forward section 67
of the housing halves 82 and 83 to facilitate piercing the
pierceable seal 87 of the pressurized container 85. Upon movement
of the pressurized container 85 toward the shaped projecting
forward section 67, the shaped projecting forward section 67
pierces the pierceable seal 87 of the pressurized container 85.
Continued movement of the pressurized container 85 compresses the
O-Ring 68 forming a seal between the retaining seat 69 and the
pressurized container 85 whereby fluid is dhscharged through the
pierced seal 87 and the passageway 88.
A fourth embodiment of the invention is illustrated in FIGS. 13,
14, 15 and 16 as device 51. In this embodiment, the structure is as
previously described in the first embodiment and like numbers are
used to indicate like or corresponding parts.
In the fourth embodiment, the projecting dispensing spout 37 of the
pressurized container 35, shown in FIG. 7, is replaced with a
projecting dispensing cap 57 shown in FIGS. 13, 14 and 16. In
addition, the fluid passageway 8 and the open entry section 7 are
replaced with three apertures 54, 55 and 56.
Now referring to FIG. 14 and FIG. 16, the expansive cartridge 65
and reciprocal member 28 operates as before to move the pressurized
cylinder 35. In this embodiment, the reciprocal member 28 urged
pressurized cylinder 35 causes the projecting cap 57 to be
depressed against the inside top portion of housing halves 52 and
53; thereby causing discharge through aperture 54.
Since it is possible to have more discharge apertures than aperture
54 in communication with the dispensing cap 57; apertures 55 and 56
are provided so that the dispensing cap 57 may be rotated to the
desired apertures 54, 55 or 56 through the use of a screw driver in
slot 60. It is also important in this embodiment that the
discharging means comprises a projecting dispensing cap 57 for
activating a valved pressurized container 35 wherein fluid
discharge is caused when the projecting dispensing cap 57 is
depressed. The housing 52 contains apertures 54 in communication
with the orifice 59 of the projecting dispensing cap 57 for fluid
discharge therethrough. Upon movement of the pressurized container
35, the projecting dispensing cap 57 is moved toward the housing.
Continued movement causes the projecting dispensing cap 57 to be
depressed whereupon the fluid is discharged through the projecting
dispensing cap 57 and through aperture 54.
Now referring to FIG. 17, a typical circuit is shown using the
battery 17 of device 1. The circuit shown within the dotted lines
is contained within the device 1. An actuation switch 43 is
connected by wires 44 and 45 to terminals 14 and 16 of the device
1. This places the component of device 1 in series with the
activation switch 43 such that with switch 11 closed; an
unauthorized person closing actuation switch 43 will cause electric
current to flow. The current will then flow from battery 17
through: wire 20, switch 10, wire 21, terminal 14, wire 44, switch
43, wire 45, terminal 16, wire 24, electric element 31, wire 23,
terminal 15, wire 22 and back to battery 17; thereby causing the
device 1 to discharge.
FIG. 18 shows an additional circuit in which the power source is
placed across 47. The circuit can be easily understood by those
familiar with electrical schematics.
The preceding embodiments disclosed the preferred embodiments
wherein an expansion cartridge is placed under a slidably mounted
pressurized container. The following four embodiments will show
that the chemical dispensing anti-burglar device will also work
with an expansion cartridge in a manner to discharge the
pressurized cylinder through the use of a reciprocal member in the
form of a cylindrical plunger. In the following four embodiments,
the basic structure is as described in previous embodiments and
like numbers are increased by 100 to indicate like or corresponding
parts. In addition, these embodiments are electrically connected in
the same manner as previous described and shown in FIGS. 1 and
2.
The device 101 whose front is shown in FIGS. 20 and 23 comprises of
a valved pressurized chemical container 135, called pressurized
container 135 hereafter, a housing 104, an expansion chamber 142,
an expansive charge 130, and a reciprocal member 106. One type of
housing 104 is shown as being comprised of a left housing half 102
and a right housing half 103. The housing halves 102 and 103 when
assembled provide three flat sides, other than the back for
mounting the devices 101 to the wall 90 adjacent to the window 70
or elsewhere, as may be convenient or desired.
Now referring to FIGS. 20 and 24 the container cavity 134, the
expansion chamber cavity 164, the battery cavity 162, the switch
cavity 163, and the cylindrical bore 151 are formed when the
symetrically opposite housing halves 102 and 103 are joined
together. As shown in FIGS. 23 and 24, the container cavity 134
provides a means for mounting the pressurized container 135 which
is held in its proper position. The pressurized container 135 of
which one type is sold by Penquin Industries, Inc., Parkesburg, Pa.
identified as their "10-4 Chemical Billy" but the invention is not
limited to the use of this container. The pressurized container
comprises of a spring urged dispensing spout 137 which when
depressed discharges a chemical 139 through the center of the
dispensing spout 137.
The battery cavity 162 provides a means for installing an
electrical power source such as a battery 117 and the switch cavity
163 provides a means for installing an electrical switch 111 which
is used to turn the device 101 off or on as desired.
As shown in FIGS. 19 and 23, terminals 114, 115 and 116 are
installed on the bottom of the device for convenience. The use of
the terminals 114, 115 and 116 will be described in the description
of electrical circuits showing different methods of making
electrical connections to device 101.
Now referring to FIG. 23, 24, 25 and 26; the cylindrical bores 151
are coaxial to the pressurized container cavity 134. The
cylindrical bores 151 slidably mount a reciprocal member 106 which
is coaxial to the pressurized container cavity 134 and in
communication with the projecting dispensing spout 137 of the
pressurized container 135 but is also displaced from the projecting
dispensing spout 137. The reciprocal member 106 contains a forward
annular flange section 152. When the device is triggered, the
reciprocal member 106 will move down as indicated by arrow 141. As
the reciprocal member 106 moves down, the flat springs 132 slide
off the annular flange section 152 onto the smaller diameter of the
reciprocal member 106 and prevent the reciprocal member 106 from
moving in a direction opposite arrow 141.
The pressurized container 135 comprises a spring urged dispensing
spout 137 which when depressed in the direction of the arrow 141
will discharge the chemical 139 through the center of the
dispensing spout 137. The reciprocal member 106 contains a fluid
passageway 108 with an entry section 107 on the bottom and a
horizontal passage 109 on the side to mount a nozzle section 159.
The fluid passageways 108, 109 and nozzle section 159 provide a
means for the chemical 139 to be discharged when the entry section
107 of the reciprocal member 106 is forced over the dispensing
spout 137 by the expansive cartridge 165 and held in discharge
position by springs 132 acting on annular section 152 of reciprocal
member 106. The action of the expansive cartridge 165 will be shown
later. The funnel shape of the entry section 107 engages the
dispensing spout 137 which is made of relatively soft material and
therefore provides an adequate seal at the entry section 107 to
retain fluid flow in the passageways 108 and 109 at pressures
normally used in the pressurized container 137.
As best seen in FIGS. 23 and 24, the expansive cartridge 165
comprises: electric element 131, a cartridge case 128, the
reciprocal member 106 and the expansive charge 130. The expansive
cartridge 165 has a filament 131 installed and electrically
insulated from the cartridge case 128. The expansive charge 130
such as gunpowder or any other material which will expand upon
ignition, heating or release, is placed in the catridge case 128.
The reciprocal member 106 is installed in the cartridge case 128
and the assembly is held together by a light press fit between the
catridge case 128 and the reciprocal member 106. The device 101 is
electrically connected as previously disclosed wherein device 101
is substituted for device 1 in FIG. 1. Switch 111 is turned on to
activate the protective device 101. When an unauthorized person or
intruder opens window 50; the pin 48 mounted on window 50 releases
the activator arm 49 of switch 43 closes the contact of switch 43
and completes the circuit. The electric current then causes the
electric element 131 to heat which causes the expansive charge 130
to expand rapidly forcing the reciprocal member 106 down toward the
pressurized container 135. The reciprocal member 106 continues to
move in direction of arrow 141 forcing the entry section 107 of
passageway 108 over the dispensing spout 137 of the pressurized
container 135, thereby causing discharge. As the reciprocal member
106 moves down over the dispensing spout 137, the retaining springs
132 slip off the annular ring 152 onto the smaller diameter of the
reciprocal member 106, thereby locking the reciprocal member 106
into engagement with the projecting spout 137. At the bottom of the
stroke, the expansive gases 142 are permitted to escape through
vent holes 160.
It is an important feature that the reciprocal member 106 ride
freely in the cylindrical bores 151 and present a surface which
will ride smoothly when the expansive cartridge 165 is set off.
Hence, substantially less force is required to discharge the device
of the present invention then would be required if the device were
tightly fit, yet the device can be safely handled in its cocked
position.
A sixth embodiment of the invention is illustrated in FIG. 27 as
device 171. In this embodiment the basic structure is as previously
described and like numbers are used to indicate like or
corresponding parts.
In the sixth embodiment, the pressurized chemical container 135,
shown in FIG. 23 having a projecting dispensing spout 137, is
replaced with a pressurized chemical container 175, shown in FIG.
27, having a recessed valve. Pressurized containers of the aerosol
type with a recessed dispensing valve are well known in the trade.
In addition, the forward section 152 and the entry section 107 of
the reciprocal member 106 of the fifth embodiment shown in FIG. 23
is replaced with a reciprocal member 176 having a projecting
forward section 182 and an entry section 177 all of which are shown
in FIG. 27. In this embodiment, all elements function as described
in the fifth embodiment with the following difference. The
pressurized container 175 is discharged by the action off the
expansion cartridge 165 forcing the projecting forward section 182
of the reciprocal member 176 to engage with and to depress the
recessed valve of the pressurized container 175 when the device 171
is triggered.
The chemical 139 is then discharged through the valve of the
pressurized container 175, through the entry section 177 and
passageway 178 and out the orifice 180, then into the area to be
protected.
A seventh embodiment of the invention is illustrated in FIG. 28 as
device 211. In this embodiment the structure is as previously
described in the first embodiment and like numbers are used to
indicate like or corresponding parts.
In this embodiment, the pressurized chemical container 135, shown
in FIG. 23 of the fifth embodiment and having a projecting
dispensing spout 137, is replaced with a pressurized chemical
container 215 shown in FIG. 28, having a pierceable seal 217.
Pressurized containers having pierceable seals are well known in
the trade. In addition, the forward section 152 and the entry
section 107 of the reciprocal member 106 of the fifth embodiment
shown in FIG. 23 is replaced with a reciprocal member 216 having a
projecting forward section 227 shaped to pierce seal 217 and a
means of making a fluid seal capable of withstanding the pressure
required for effectively discharging the chemical 139 through the
passageway 218 and into the restricted area.
Now referring to FIG. 28, FIG. 28 is an inverted embodiment of FIG.
23 of the fifth embodiment in which all elements function as
previously described in the fifth embodiment with the following
exceptions. The reciprocal member 216 when moved by the expansive
cartridge 165 is forced into pierceable engagement with the
pierceable seal 217 of the pressurized cylinder 215 by the action
of the expansive cartridge 165. As the pierceable seal 217 is
pierced by the action of the projection forward section 227 of the
reciprocal member 216. The reciprocal member 216 continues to move
by the urging of the expansive cartridge 165 forming a seal by the
action of the O-Ring 228 and its retaining seat 229 and the
pierceable seal 217 of the pressurized container 215. The chemical
is then discharged through the pierced seal 217 of the pressurized
container 215, through passageway 218, out the orifice 220, and
then into the area to be protected.
An eighth embodiment of the invention is illustrated in FIG. 29 as
device 191. In this embodiment the basic structure is as previously
described and like numbers are used to indicate like or
corresponding parts.
In this embodiment, the pressurized chemical container 135, shown
in FIG. 23 having a projecting dispensing spout 137, is replaced
with a pressurized container 135, shown in FIG. 29, having a
projecting dispensing cap 194. Pressurized containers of the
aerosol type with projecting dispensing caps are well known in the
trade. In addition, the forward section 152 and the entry section
107 of the reciprocal member 106 of the fifth embodiment shown in
FIG. 23 is replaced with a reciprocal member 196 in communication
with but displaced from the projecting dispensing cap 194 all of
which are shown in FIG. 29.
In this embodiment, all elements function as described in the fifth
embodiment with the following difference. The pressurized container
135 is discharged by the action of the expansive cartridge 165
forcing the cylindrical plunger 196 to engage with and to depress
the projecting dispensing cap 194 of the pressurized container 135
when the device 191 is triggered.
The chemical is then discharged through the valve of the
pressurized container 135, through the passageway of the projecting
dispensing cap 194, through the orifice 199 and out aperture 205,
then into the area to be protected.
The preceding embodiments disclosed the embodiments wherein an
expansive cartridge is electrically activated to discharge the
chemical into an area to be protected. The following four
embodiments will show that the chemical dispensing anti-burglar
device can be activated mechanically.
Referring now to the drawings in detail, wherein like reference
characters designate like parts throughout the various views, there
is shown in FIGS. 30-41, one form of the chemical dispensing
anti-burglar device, called device hereafter, of the chemical
weapon type according to the present invention, generally
designated 303. The device 303 is secured to a wall 304 and
connected by means of a core 302 to a window sash 301, in the wall
304 so that upon opening of the window sash 301 by a burglar or
other intruder, the device 303 will be actuated to discharge a
chemical 334 into the restricted area. The device 303 whose front
is shown in FIG. 33 comprises of a valved pressurized chemical
container 311, called pressurized container 311 hereafter, a
housing 304, an expansion chamber 359, an expansive charge 318 and
a reciprocal member 316. One type of housing is shown as being
comprised of a right housing half 309 and a left housing half 310.
The housing halves 309 and 310 when assembled provide three flat
sides, other than the front, for mounting the device 303 to the
wall 304 adjacent to the window sash 301 or elsewhere, as may be
convenient.
Now referring to FIGS. 33, 36 and 37 the container and expansion
chamber cavity 314, the spring cavity 327, and the cylindrical bore
332 are formed when the symetrically opposite housing halves 309
and 310 are joined together. As shown in FIGS. 36 and 37, the
container and expansion chamber cavity 314 provides a means for
slidably mounting the pressurized container 311 which is slidably
confined in proper position. The pressurized container 311 of which
one type is sold by Penquin Industries, Inc., Parkesburg, Pa.
identified as their "10-4 Chemical Billy" but the invention is not
limited to the use of this container. The pressurized container 311
comprises of a spring urged dispensing spout 313 which when
depressed discharges a chemical 334 through the center of the
dispensing spout 313.
Again referring to FIGS. 36 and 37, the container and expansion
chamber cavity 314 also provides a mounting means for the expansive
cartridge 315 and contains small vertical slots 320 formed in its
sides. The purpose of these slots will become apparent later.
Still referring to FIG. 36, a rotatable nozzle section 305 is
rotatably mounted in the cylindrical bore 332 formed when the
symetrically opposite housing halves 309 and 310 are joined
together as shown in FIGS. 33 and 37. It is important that the
rotatable nozzle 305 and its fluid passageway 324 be in coaxial
alignment with projecting dispensing spout 313 of the pressurized
container 311. As the pressurized container 311 moves in the
direction of arrow 339; the fluid passageway 324 and nozzle section
305 provide a means for the chemical 334 to be discharged into and
directed from when the dispensing spout 313 of the pressurized
container 311 is forced into the entry section 325 by the action of
the expansive charge 318 contained in the expansive cartridge 315,
the action of which will be later described. The funnel shape of
the entry section 325 engages the dispensing spout 313, which is
made of relatively soft material and therefore provides an adequate
seal at the entry section 325 to retain fluid flow in the
passageway 324 at pressures normally used in pressurized
containers.
As best seen in FIG. 36, the expansive cartridge 315 comprises: an
element for causing expansion, one type of which is shown as a
primer 330, the operation of which will become apparent, a
cartridge case 331, a reciprocal member 316, a retainer spring 317
and the expansive charge 318. The expansive cartridge 315 has a
primer 330 installed in it. The primer 330 of which one type is
sold by Cascade Cartridge, Inc., Lewiston, Idaho, identified as
their Large Pistol Primers. The expansive charge 318 such as
gunpowder or any other material which will expand upon release is
placed in the cartridge case 331. The reciprocal member 316 is
installed over the cartridge case 331 and the assembly is held
together by a light press fit between the cartridge case 331 and
the reciprocal member 316. The retaining spring 317 is then placed
over the assembled expansive cartridge 315 and the unit is mounted
in the bottom of the pressurized cylinder cavity 314.
The retaining spring 317 has four spring sections 335 which are set
in the retaining spring guide slots 319 formed in the housing
halves 309 and 310. The friction of the retaining spring 317 and
the retaining spring guide slots 319 holds the reciprocal member in
place until fired.
As shown best in FIGS. 36 and 38, a means to cause expansion is
shown comprising of a firing member 338; the firing member 338 is
urged toward the expansive cartridge 315 by spring action shown as
a torsion spring 321. The torsion spring 321 is mounted over a
shaft 328 such that an extension 326 of the torsion spring 321 is
supported against a stop 345 in the housing 304. The firing member
338 is releasably retained in a cocked position displaced from the
expansive cartridge 315. The firing member 338 is mounted for
movement between an actuation position shown in FIG. 36 and a
release position shown in FIG. 40. In the actuation position, a
trigger element 306 is in engagement with the firing member 338 to
retain the firing member 338 in a cocked position. Upon release,
the firing member 338 is spring urged to strike the primer 330 and
cause expansion of the expansive cartridge 315.
When it is desired to activate the anti-burglary device, a cord 302
is connected to a window 301 and the device 303 as shown in FIG. 30
or any other object expected to be moved or the cord 302 positioned
such that an intruder would trip the cord 302. The safety pin 308
would be removed to arm the device 303.
As shown in FIGS. 30, 31, 36 and 40, an intruder opening the window
301, would pull on cord 302, which would then pull trigger pin 306
thereby releasing spring arm 338. The firing extension 322 of
spring arm 338 would strike the primer 330 with sufficient force to
cause the discharge of the primer 330. As the cartridge 315
expands, the spring arm 319 of spring 317 would snap into slots 320
formed in housing halves 309 and 310 and lock the pressurized
container 311 in a position to discharge its entire contents.
it is an important feature that the pressurized cylinder 311 and
the retaining spring 317 ride freely in their respective cavities
formed in housing halves 309 and 310 and present a surface which
will ride smoothly when the reciprocal member 316 is set off.
Hence, substantially less force is required to discharge the device
303 of the present invention then would be required if the
retaining spring 317 and pressurized cylinder 311 were tightly fit
into their cavity, yet the device 303 can be safely handled in its
cocked position because of the force required to depress the
projecting dispensing spout 37.
A tenth embodiment of the invention is illustrated in FIG. 42 as
device 340. In this embodiment the basic structure is as previously
described and like numbers are used to indicate like or
corresponding parts.
In this embodiment, the pressurized chemical container 311, shown
in FIG. 36 having a projecting dispensing spout 313, is replaced
with a pressurized container 343, shown in FIG. 42, having a
recessed valve. Pressurized containers of the aerosol type having a
recessed valve are well known in the trade. In addition, the funnel
shape of the entry section 325 of the fluid passageway 324 of the
ninth embodiment shown in FIG. 36 is replaced with a projecting
dispensing spout 325 depending from housing half 342, all of which
are shown in FIG. 42.
In this embodiment, all elements function as previously described
in the ninth embodiment with the following difference. The
pressurized container 343 is discharged by the action of the
expansive cartridge 315 moving the pressurized container 311 such
that the recessed valve of the pressurized container 343 is
depressed through engagement with the projecting spout 344 and
thereby effects discharge.
The chemical 334 is then discharged through the valve of the
pressurized container 343, through projecting spout 344, through
vertical passageway 324, through horizontal passageway 346 and out
slot 348, then into the area to be protected. As the chemical 334
is being discharged, a whistle like sound will be produced as the
chemical 334 is discharged, the pitch of which can be controlled by
the chamber 347. Thereby issuing a warning sound in addition to
filling the area with a chemical to protect the area where the
device 340 is installed.
An eleventh embodiment of the invention is illustrated in FIG. 43
as device 350. In this embodiment, the structure is as previously
described in the ninth embodiment and like numbers are used to
indicate like or corresponding parts.
In this embodiment, the pressurized chemical container 311, shown
in FIG. 36 of the ninth embodiment and having a projecting
dispensing spout 313, is replaced with a pressurized chemical
container 355 shown in FIG. 43, having a pierceable seal 356.
Pressurized containers having pierceable seals are well known in
the trade. In addition, the funnel shaped entry section 325 of the
housing halves 309 and 310 of the ninth embodiment shown in FIG. 36
is replaced with housing half 352 having a projecting section 354
shaped to pierce seal 356 and a means of making a seal capable of
withstanding the pressure required for effectively discharging the
chemical 334 through the passage 324 and into the restricted
area.
The spring 353 is installed to hold the slidable mounted container
355 and its pierceable seal 356 away from the projecting piercing
section 354. It is important that the spring 353 be strong enough
to support the pressurized container 355 yet be sufficiently weak
to be overcome by the expandable cartridge 315 when fired.
Now referring to FIG. 43, FIG. 43 is an inverted embodiment of FIG.
36 of the ninth embodiment in which all elements function as
described in the ninth embodiment with the following exceptions.
The expansive cartridge 315 when fired forces the pressurized
container 355 into pierceable engagement with the piercing
projecting section 354. As the pierceable seal 356 is pierced by
the action of the projecting piercing section 354, the reciprocal
member 316 continues to move the pressurized container 355 forming
a seal by the action the O-Ring 357 and its retaining seat 358 and
the pierceable seal 356 of the pressurized container 355. The
chemical 334 is then discharged through the pierced seal 356 of the
container 355, through passageway 324, out the orifice 307 and then
into the area to be protected.
A twelfth embodiment of the invention is illustrated in FIGS. 44,
45 and 46 as device 360. In this embodiment, the structure is as
previously described in the ninth embodiment and like numbers are
used to indicate like or corresponding parts.
In this embodiment, the projecting dispensing spout 313 of the
pressurized container 311, shown in FIG. 36, is replaced with a
projecting dispensing cap 366 shown in FIGS. 44, 45 and 46. In
addition, the fluid passageway 324 and the entry section 325 are
replaced with an aperture 364.
Now referring to FIGS. 44, 45 and 46, the expansive cartridge 315
operate as before to move the pressurized cylinder 311. In this
embodiment, the reciprocal member 316 urged pressurized cylinder
311 causes the projecting dispensing cap 366 to be depressed
against the inside top portion of housing halves 361 and 362;
thereby causing discharge through aperture 364.
Although we have herein shown and described the invention in what
we have conceived to be the most practical and preferred
embodiments, it is recognized that departure may be made therefrom
within the scope of our invention, which is not to be limited to
the details disclosed herein, but is to be accoded the full scope
of the claims so as to embrace any and all equivalent structures
and devices.
* * * * *