US2703527A

US2703527A - Fire extinguishing or incendiary bomb

Info

Publication number: US2703527A
Application number: US253864A
Authority: US
Inventors: Arne B Hansen
Original assignee: Individual
Current assignee: Individual
Priority date: 1951-10-30
Filing date: 1951-10-30
Publication date: 1955-03-08
Anticipated expiration: 1972-03-08

Description

March 1955 A. B. HANSEN 2,703,527

FIRE EXTINGUISHING OR INCENDIARY BOMB Filed Oct. 30, 1951 4 Sheets-Sheet l INVENTOR.

ARNE B. HANSEN AT'rorNEYs March 8, 1955 A. B. HANSEN 2,703,527

FIRE EXTINGUISHING OR INCENDIARY BOMB Filed om. 50, 1951 4 Sheets-Sheet 3 ATTORNEYS ARNE B. HANSEN I l -.lE- RY 364 gm T 3721 B March 8, 1955 A. B. HANSEN FIRE EXTINGUISHING 0R INCENDIARY BOMB Filed 06%. so, 1951 4 Sheets-Sheet 4 I INVENTOR.

AFNE B-HANsEN BY ATTORNEYS nite States FIRE EXTINGUISHING OR IN CENDIARY BOMB Arne B. Hansen, Sacramento, Calif.

Application October 30, 1951, Serial No. 253,864

Claims. (Cl. 102-6) An object of my invention is to provide a bomb which may be dropped from airplanes and when used for putting out forest fires, it will automatically dispense fire extinguishing material over a prescribed area upon striking the ground or other object. Many forest fires originate in almost inaccessible places and frequently the fire gets beyond control before the fire fighters can reach the locality of the fire. One of the purposes of my invention is to provide a bomb that can be quickly flown by airplane to the scene of the fire and released for immediately combating the forest or brush fire, or other raging conflagration, such as a fire engulfed oil field, refinery, or a fire caused by an explosion.

Because of the element of time and the remote inaccessibility of many forest fires, and the intense heat of forest and petroleum fires, I have designed my device as a bomb which may be launched from an airborne craft. The bomb can be launched as a complete unit which will automatically dispense a given quantity of fire-extinguishing fluid over a certain area as it strikes the ground or an object.

A further object of my invention is to provide a device of the type described in which the fire-extinguishing fluid is retained within a casing and novel means is used for expelling all of the fluid from the casing when the bomb strikes the ground or other object.

A further object of my invention is to provide a device of the type described that makes use of a parachutetype tail for retarding the fall of the bomb through the air and for imparting a rotative movement tothe bomb so that the conical-shaped forward end of the bomb with its threaded outer surface, will screw its way into the ground due to the rotative force plus the penetrating force exerted by the bomb at the moment of impact. The embedded conical head will hold the bomb in an erect position and the bomb has fluid out-let openings which are automatically opened upon the bombs impact with the ground and therefore the fluid will be sprayed radially from the bomb in all directions to cover a large area. I make use of both spring and gas pressure in expelling the fire extinguishing fluid from the bomb.

The bomb can also be used as an incendiary bomb if a highly inflammable fluid is substituted for the fire extinguishing fluid. An automatically ignitable element can be used which will ignite upon the bomb striking the ground or other object and which will set the inflammable fluid to burning as the latter issues from the bomb. Very little change is necessary to alter the bomb from a fire extinguishing type to an incendiary type.

There are numerous uses to which the bomb could be put when acting as an incendiary bomb. The bomb could be used as a defensive weapon in warfare. For example, an enemy charging a beach head objectivecould be forced to retire if the bomb were used and the objective suddenly became a seething mass of flame. An en- :tire attacking force advancing through a narrow pass, could be stopped by the use of the bomb. A near miss on an enemy concrete emplacement or tank would still render either object untenable.

Other objects and advantages will appear in the following. specification, and the novel features of the device will be particularly pointed out in the appended claims.

My invention is illustrated in the accompanying drawings forming apart of this application, in which:

Figure '1 is a side elevation of the bomb shown in 2,703,527 Patented Mar. 8, 1955 "ice a position it would occupy as it descended through the air from an airplane;

Figure 2 is a top plan view of the tail assembly, when looking in the direction of the arrows IIII of Figure 1.

Figure 3 is a transverse section taken along the line IIIIII of Figure 5, and illustrates a part of the release mechanism for forcing fluid from the bomb;

Figure 4- is a transverse section taken along th line IV1V of Figure 5, and illustrates a part of the gas release mechanism that in turn is utilized for forcing fluid from the bomb;

Figure 5 is an enlarged vertical section of the lower portion of the device and illustrates the release and driving mechanism for moving a piston through a cylinder for expelling fluid therefrom;

Figures 6 and 7 are horizontal sections taken along the lines VI-Vl and VIIVII of Figure 5;

Figure 8 is an enlarged vertical section of the upper portion of the device and shows the mechanism for uncovering the outlet openings through which the fluid is forced when the bomb strikes its object;

Figure 9 is a detail of a part of Figure 8 and illustrates the fluid outlet openings uncovered;

Figure 10 is a sectional view similar to Figure 8, but showing the bomb altered so as to act as an incendiary bomb;

Figure 11 is a sectional detail view of a portion of Figure 10 and indicates the fluid outlet openings as being uncovered; and

Figure 12 is a side elevation of the incendiary bomb.

While I have shown only the preferred forms of my invention, it should be understood that various changes or modifications may be made within the scope of the appended claims without departing from the spirit and scope of the invention.

in carrying out my invention, I provide a bomb having a cylindrical housing A, as clearly shown in Figure ,1. The forward end of the bomb is provided with a primer head B, while the rear end of the bomb carries atail assembly indicated generally at C. It might be best to set forth the structure of the tail assembly C first, and then describe the internal structure of the bomb itself and show how the bomb is automatically set in operation when the primer head B strikes the ground or other object.

Tail assembly The tail assembly is illustrated in Figures 1, 2 and 8. The cylindrical housing A of the bomb has the rear end 1 permanently secured thereto by screws ,2 or other suitable fastening means, see Figure 8. The rear end 1 has a conical portion 3 which is perforated at 4 in the manner shown in Figure 9. The perforations extend entirely around the conical portion 3 and constitute a plurality of outlet openings .for the escape of fluid that is .housed within the cylinder A. The rear end 1 of the bomb is connected to a conical-shaped tail piece 5 whose outer surface is practically a continuation of the conical portion 3, see Figure 1. The tail piece 5 .has a threaded cylindrical projection 6, see Figure v8, that is removably secured to a threaded recess 7 provided at the top of the rear end 1.

Figure 8 further shows the conical-shaped tail piece 5 as being integral with a cylindrical-shaped end member 8. Referring to Figure 2 as well as Figure 8, it will be seen that the cylindrical member 8 hasa disc 9 secured thereto. The end 8 has a shoulder 10 against which the disc 9 rests. The free end of the cylindrical member 8 extending beyond the shoulder '10, is upset as at 11 for rigidly securing the disc to the member 8. A cylindrical casing 12 encircles the periphery of the disc 9 and faces toward the body A of the bomb. Both Figures 2 and 8 illustrate how the disc 9 is provided with a plurality of slots 13 which are placed adjacent to the casing 12 and are for the purpose of retarding the flow of air through the casing. In fact, the disc9 and casing 12 act as :an open parachute for retarding the fall of the bomb through the air. The air passing into the casing 12 cannot escape except through the slots 13. The area of theslots cuts 0 down the flow .of air passing. through the casing, because slots. In this way the speed of the bomb as it drops toward the ground is retarded.

I further utilize the tail'assembly C for imparting a ,rotative movement to the cylinder housing 8 and to the entire bor'nb as it falls through the air. In both Figures 1 and 2, I show a plurality of vanes 14 that extend from the entrance end 12a of the housing 12 up to the inner surface of the disc 9. The vanes are curved slightly in 1 and 2. The flow of air' through the housing 12 1s indicated by the arrows b in Figure 1. I do not wish to be confined to any particular size for the tail assembly C because this will depend entirely upon the weight of the bomb and its size as well as its shape. The function of the tail assembly is to retard the falling of the bomb as it moves toward the earth from an airplane that has just released it, and the additional function of the tail assembly is to impart a rotative movement to the entire bomb along its longitudinal axis. This rotational movement will tend to keep the bomb moving along its course and will cause the primer head B to enter the ground upon the impact of the bomb therewith.

Body structure As already stated, the body of the bomb includes the cylindrical housing A. This housing extends from a conical shaped forward end 15 for the bomb, see Figure 5, to the conical-shaped rear end 1 shown in Figure 8. The forward end of the cylindrical housing A is secured to the conical-shaped forward end 15 of the bomb by screws 16, see Figure 5, or other suitable fastening means. A plunger rod D extends entirely through the length of the cylinder housing A and has its forward end screwed into the primer head B as clearly shown in Figure 5. The plunger rod is slidably received in a bore 17 and the conical-shaped forward end 15 has diametrically opposed grooves 18 facing the bore 17 and in which the ends of a pin 19 are adapted to slide. The pin extends transversely through the plunger rod D and it will be seen that the structure permits the primer head B to move toward the adjacent end of the conical-shaped member 15, but the rod will be prevented from rotating within the end 15. In Figure 8, I show the opposite end of the plunger rod D slidably received in a bore 20 that is formed in the conical-shaped tail piece 5. The purpose of permitting longitudinal movement of the rod D within the housing A while preventing rotational movement, will be described hereinafter.

A piston indicated generally at E in Figure 5 is slidably mounted within the housing A and the piston is free to slide on the plunger rod D. The piston can move from the forward end of the housing A, shown in Figure 5, into the tail end 1 of the housing as shown by the dot dash lines in Figure 8. Normally a fire extinguisher llquid 21 is placed within the housing A and extends from the piston E to the rear end 1 of the bomb. The movement of the piston E from the forward end of the bomb to the rear end thereof by a means presently to be described, will force the fire extinguishing liquid out through the outlet openings 4 shown in Figure 9, and the liquid will be sprayed radially from the openings 4 in all directions as indicated by the arrows c in Figure 9.

The openings 4 are normally closed so as to confine the fire extinguishing liquid 21 within the bomb housmg A. I accomplish the closing of the openings 4 by a conical-shaped valve member F that is rotatably mounted within the interior of the rear end 1, see Figure 8. The conical valve F has a conical portion 22 that is coextensive with the conical portion 3 and is provided with a plurallty of outlet openings 23 of the same spacing and mm as the openings 4, but are normally out of registration with the outlet openings 4. When the conical valve F is rotated with respect to the rear end 1, the openings 23 will be brought into registration with the openings 4 and the fire extinguishing liquid 21 will be free to pass out through the aligned openings. has a rim that rides on a bearing ring 24 which in turn is secured to the interior of the rear end 1, see Figure 8.

Valve and piston operating mechanism In Figures 3 and 5, I show the housing A provided with a lock ring G that is secured to the housing so as to The conical valve F be held against rotation with respect to the housing. The ring G has a plurality of inwardly-extending projections 25, see Figure 3, that are spaced apart, and these projections are normally disposed above a like number of radially and outwardly-extending projections 26 that are carried by a release disc H. In Figure 5 I disclose the release disc H as having a hub 27 for receiving a spiral toothed portion 28 of the plunger rod D. The interior of the hub 27 is provided with spiral grooves which will receive the spiral toothed portion 28. The pitch of the teeth 28 and their complementary grooves in the hub 27 is such as to cause the disc H to rotate when the plunger rod D is moved upwardly in Figure 5 due to the primer head B striking the ground or another object. The angular movement imparted to the release disc H is sufiicient to swing its outwardly-extending projections 26 out of registration with the inwardly-extending projections 25 of the ring G. Passageways 29 are formed between the adjacent inwardly-extending projections 25 of the ring G and when the disc H is rotated, the projections 26 thereof will be brought into registration with the passageways and therefore the disc H will be free to move along the longitudinal axis of the housing A because the projections 26 can move through the passageways 29.

I provide novel means for releasing gas under pressure at the moment the release disc H is rotated so as to be freed from the lock ring G. Again referring to Figure 5, it will be seen that I provide a receptacle I within the conical end 15 for holding a liquid carbon dioxide indicated generally at 30. This liquid carbon dioxide has previously been forced into the receptacle or container I under pressure by means of a self-closing inlet valve 31, also shown in Figure 5. A plurality of outlet valves K are mounted on the top of the receptacle I, see Figures 4 and 5, and these valves are provided with handles 32 that are normally closed so that no liquid carbon dioxide can escape from the receptacle I The handles 32 extend in an upright position when the valves K are closed. The under side of the disc H carries triggers 33 and these triggers will be moved when the release disc H is rotated. The triggers are in line to contact the upraised handles 32 when the disc is rotated and to swing the handles 32 for opening the outlet valves K. The result will be that the liquid carbon dioxide which is under pressure within the container I will issue from the outlet valves K as a gas and will exert its force against the release disc H and the piston E to move them. Inasmuch as the disc H is now freed from the ring G, the disc and piston will be moved upwardly in Figure 5 from the forward end of the housing A and will continue to move until they reach the rear end 1 It should be noted at this point that the same movement of the plunger rod D which will rotate the release disc H into its freed position, will also rotate the valve F for bringing the openings 23 of the valve into registration with the outlet openings 4. To accomplish this, I provide a second member on the rod D with helical teeth 34, see Figure 8. This second member on the rod D is slidably received within a hub portion 35 provided in the rear end 1. The interior of the hub 35 has complementary helical-shaped grooves that .will receive the helical shaped teeth 34 on the second member. Therefore, an upward vertical movement of the rod D in Figure 8 will rotate the valve F to uncover the outlet openings 4. This rotative movement of the valve F takes place simultaneously with the rotative movement of the release disc H and therefore the opening of the valves K and the release of the carbon dioxide as a gas will permit the piston and disc H to move upwardly in Figure 8 to the dot dash line position and force the fire extinguishing liquid 21 from the housing A, out through the outlet openings 4. I do not wish to be confined to any particular liquid or gas that might be placed in the container J. I am merely setting forth compressed liquid carbon dioxide as an example because this will change into a gas when released and will increase in volume many times. Also the particular type of fire extinguishing liquid can be varied to meet the situation involved.

I not only use gas for moving the piston E for expelling the fire extinguishing liquid from the bomb, but in addition I use a coil spring shown at L in Figure 5 for the same purpose. The coil spring is housed within a bore 36 and the conical member 15 and the spring is compressed when the release disc H is held against movement by the lock ring G. However, as soon as the release disc H is rotated for freeingit from the lock ring, the full energy of the compressed spring L will be exertedagainst the disc H for moving. it along the interior of the housingA. In Figure 8, I show the coil spring L in extended position by the dot dash lines after the spring has moved the piston E to the rear of the housing A. Of course the release of the gas aids the coil spring in moving the piston.

Operation From the foregoing description of the various parts of the device, the operation thereof may be readily understood.

The cylindrical housing A is filled with the fire extinguishing liquid 21 and the container J is likewise filled with carbon dioxide liquid under pressure. Until the bomb is used, a safety U-shaped block M, see Figure 7, is inserted between the primer head B and the forward conical end 15. The safety block acts'as a spacer and prevents accidental movement of the primer head B toward the conical end 15. It will be noted from Figure 1 that the primer head B and the conical head 15 are provided with a spiral rib or thread'37'-38, respectively.

The bomb is placed in an airplane or other airborne craft and is flown to the fire at which point it is released. The tail assembly C will cause the bomb to assume the vertical position shown in Figure 1 as it moves toward the ground through the air. At the same time the curved vanes 14 will impart a rotative movement to the tail assembly and to the bomb, causing the bomb to rotate during its descent. Before the bomb is dropped the safety U-shaped block M- is removed from between the primer head B and the forward conical end 15. A

U'-shaped rubber washer M1 may be substituted for the block M1. When the bomb strikes the ground, its rotation and downward thrust will cause the primer head B to screw its way into the earth. The initial impact will cause the conical end 15 to move downwardly toward the primer head B and this will cause the plunger rod D to move upwardly within the interior of the bomb housi'ng A. The rubber washer M1 will act as a butter as the end 15 and head B are forced toward each other.

As already explained, the upward movement of the rod D will cause the spiral toothed portion 28 of the rod, see Figure 3, to rotate the release disc H and move the disc projections 26 out of alignment with the lock ring projections 25. The same rotative movement of the disc will cause "the triggers 33 to open the gas outlet valves K. At the top end of the bomb, the same upward movement of the plunger rod D within the housing A will cause the helical teeth 34 to rotate the valve F and uncover the outlet openings 4 as clearly shown in Figure 9.

The movement of these various parts is automatic upon the bomb striking the ground and during the rotative movement of the primer head B and the conical end 15, the

helical ribs

37 and 38 will screw their way into the earth so as to support the bomb in an upright position when it comes to rest. The freeing of the release disc H from the lock ring G will permit the compressed coil spring L to move the disc and piston E upwardly in Figure 5. The same rotative movement of the disc H will open the outlet valves K and the carbon dioxide gas issuing from these valves will aid in moving both the disc and piston E upwardly. Inasmuch as the carbon dioxide liquid is under pressure in the container I, its release from the container will change it into a gas which will have many times the volume it formerly occupied as a liquid. Both the gas and the spring cooperate to move the piston E upwardly and to force the fire extinguishing fluid 21 out through the openings 4 as indicated by the arrows c in Figure 9. The fire extinguishing liquid will cut ofi the supply of oxygen to the blaze and will put out the fire. It is possible with this bomb and an airplane to reach a fire almost as soon as it is detected and to put out the fire by the release of the bomb before the fire has had a chance to gain any headway.

Incendiary bomb It is possible to use the bomb as an incendiary bomb and a modified form of the tail end of the bomb is illustrated in Figures and 11 to show how my present bomb can be used for this purpose. Like parts shown in Figures 1 to 9, inclusive, and in Fimires 10 and ll,

will be given similar reference letters and numerals and where the part in the modified form has been changed slightly the letter or numeral will be primed from that shown in Figures 1 to 9, inclusive. Figures 10 and 11 correspond with Figures 8 and 9 except that the conical shaped tail piece 5 is now made hollow at 50 to receive a fluid 51 or. other burnable material. The bore 20 that receives the upper end of the slidable rod D communicates with a cartridge-receiving recess 52. The cartridge 53 is placed in the recess and. the top of the rod D has a pin 54' that will strike the cartridge 53 and cause it to explode when the rod is moved upwardly due to the impact of the bomb upon striking the ground.

Radially extending passages 55- lead from the recess 52 into the interior 50 of the tail piece 5 and convey the fire created by the exploding cartridge, to the fuel 51 for igniting it. Blowout plugs 56 normally close openings 57 leading from the interior 50 to the atmosphere. The sudden buildup of pressure caused by the burning fluid 51 will force these blowout plugs out from the openings 57 and the burning. fluid 51 will then issue from these openings and will pass out through an annular slot 58 that separates the tail piece 5 from the rear end 1.

It will be understo'odthat the upward movement of the plunger D to explode the cartridge 53 will also rotate the release disc H shown in Figure 5 to open the gas outlet valves K and free the disc from the lock ring G. At the same time the outlet openings 4 in the tail section 1 will be uncovered by the rotation of the valve F. Therefore, the incendiary material 59 contained within the cylindrical housing A will be forced out through the openings 4 and will be ignited by the flame that issues from the openings 57 and passes through the annular slot 58 as shown by the arrow '41 in Figure 11. The result will be that the highly inflammable fluid 59 will be ignited by the flame issuing from the compartment 50 and all of the fluid 59 will burn and create an intense heat.

It is possible to make most of the bomb structure shown in Figures 10 and 11 from a heavy duty plastic that would be consumed by the burning of the highly inflammable fluid 5 9. In this way all of the working parts of the bomb would be destroyed and the enemy could not detect it-sstructure nor how it operated. If necessary the rod D could be made of metal but I do not wish to be limited to any particular type of material forming the various parts of the bomb. Figure 10 illustrates the firing pin 54 spaced from the cartridge 53, While Figure 11 shows the firing pin in actual contact with the cartridge for exploding it. In fact, Figure 11 further illustrates the partial consumption of the burnable fluid or other material 51 disposed in the hollow interior 50. This is the material that issues from the openings 57 and ignites the liquid 59 after passing from the annular slot 58.

No mention need be made of the tail assembly C in the modified form of the invention, because it will be of the same construction as that shown in the form of the device illustrated Figures 1 through 9, inclusive. The bomb shown in Figures 10 and 11 will operate in identically the same manner as the preferred form of the bomb, the only diiference being that in the first form the device is used as a fire extinguisher, while in the second form the bomb is used as an incendiary one.

The

helical ribs

37 and 38 shown in Figure 1, may be changed to a plurality of spaced rings 37a and 381:, shown 1n Figure 12 when the bomb is used as an incendiary bomb. The rings are spaced a few inches apart and th s wall enable the incendiary bomb to continue its rotary spinning when it strikes the ground and the centrifugal force derived therefrom will cause the burning fluid issurug from the bomb to cover a much larger area than it would if the spiral ribs were used and the screwing in process halted the rotary spinning of the unit.

I claim:

1. In a bomb of the type described; an elongated housing for containing a dispensible fluid; a valve disposed near one end of the housing and being normally closed for retaining the fluid in the housing; a fluid dispensing piston disposed within the housing at the end opposite from the valve; automatic valve opening means including a rod that is carried by the housing and is slidable in the direction of its length and has an end projecting beyond the same housing end at which the piston is disposed; a tail assembly carried by the housing end at which the valve is disposed and causing the housing to point the exposed end of the rod in the direction of travel when the bomb is moving through the air; whereby the exposed end of the rod will be the first to contact with and be moved by the ground upon the impact of the bomb therewith; means normally holding the piston from moving; a coil spring for moving the piston; means operatively connected to said rod for releasing said piston holding means when the rod is moved; whereby the spring will move the piston; said rod being operatively connected to the valve opening means so that a movement of the rod upon contact with the ground will actuate the valve opening means to open the valve and permit the fluid in the housing to escape therefrom as the piston is moved by the spring.

2. In a bomb of the type described; an elongated housing for containing a dispensible fluid; a valve disposed near one end of the housing and being normally closed for retaining the fluid in the housing; valve opening means; a fluid dispensing piston disposed within the housing at the end opposite from the valve; piston moving means disposed adjacent to the piston; means normally maintaining the piston moving means inactive; a rod carried by the housing and slidable in the direction of its length and provided with an end projecting beyond the same housing end at which the piston is disposed; a tail assembly carried by the housing end at which the valve is disposed and causing the housing to point the exposed end of the rod in the direction of travel when the bomb is moving through the air; whereby the exposed end of the rod will be the first to contact with and be moved by the ground upon impact of the bomb therewith; said rod being operatively connected to the valve opening means and to the means that maintains the piston moving means inactive so that a movement of the rod upon contact with the ground will actuate the valve opening means to open the valve and will free the piston moving means; whereby the piston will force the fluid from the housing through the opened valve.

3. In a bomb of the type described; an elongated housing for containing a dispensible fluid and having outlet openings therefor disposed at one end; a piston normally disposed at the other housing end and being movable in the housing for expelling the fluid through the openings; a container mounted adjacent to the piston and holding a piston moving fluid; at least one outlet valve for the container; a release disc rotatably and slidably mounted in the housing and having outwardly extending projections spaced from each other; a ring carried by the housing and having inwardly-extending projections that normally overlie the disc projections and prevent movement of the disc toward the piston; and means carried by the disc for opening the container outlet valve when the disc is rotated for disposing its projections between the ring projections; whereby the escaping fluid from the container will move the disc and piston for causing the latter to expel the dispensible fluid from the housing.

4. A bomb of the type described; an elongated housing spaced from each other; a ring carried by the housing and having inwardly-extending projections that normally overlie the disc projections and prevent movement of the disc toward the piston; means carried by the disc for opening the container outlet valve when the disc is rotated for disposing its projections between the ring projections; whereby the escaping fluid from the container will move the disc and piston for causing the latter to expel the inflammable fluid from the housing; a reservoir for holding a burnable material; means for igniting the burnable material; means for guiding the burnable material to the outlet openings for igniting the inflammable fluid as it issues from the outlet openings; a valve normally closing the outlet openings; and connections between the means for igniting the burnable material and the valve, for opening the valve when the igniting means ignites the burnable material.

5. In a bomb of the type described: an elongated housing for containing a dispensible fluid and having outlet openings therefor disposed at one end; a piston normally disposed atthe other housing end and being movable in the housing for expelling the fluid through the openings; a container carried by the housing and mounted adjacent to the housing end disposed opposite to the outlet openings and holding a piston moving fluid; at least one outlet valve for the container; a release disc rotatably and slidably mounted in the housing and having outwardly extending projections spaced from each other; a ring carried by the housing and having inwardly-extending projections that normally overlie the disc projections and prevent movement of the disc toward the piston; means carried by the disc for opening the container outlet valve when the disc is rotated for disposing its projections between the ring projections; whereby the escaping fluid from the container will move the disc and piston for causing the latter to expel the dispensible fluid from the housing; and a coil spring for moving the piston; said spring cooperating with the escaping fluid from the container for aiding in moving the piston.

References Cited in the file of this patent