RU2527722C1 - Thermal mechanism of actuation fire extinguishing generator - Google Patents

Abstract

FIELD: fire-fighting equipment.

SUBSTANCE: thermal mechanism of actuation of the fire extinguishing generator comprises a striker located in the housing with a spring enveloping it, loading the striker in the direction of the capsules, a fixing device which blocks the striker from movement in the idle state, and an initiating element mounted in the additional housing, holding the fixing device in the idle state, at that the fixing device is made of the blocking sleeve located in the housing and contacting with the striker, and the retainer which is in contact with the initiating element in the idle state, mounted with the ability to move on the junction of the housing and the additional housing with partial entering into each of them, at that the blocking sleeve has lobes of the resilient material entering in the idle state in the gap between the housing and the retainer and moving out from it when actuation of the initiating element, and the spring is located in the blocking sleeve.

EFFECT: improving the reliability of the start of the fire extinguishing generator.

8 cl, 1 dwg

Description

The invention relates to fire fighting equipment, in particular to fire extinguishers, the use of which is possible in automatic mode. It is used for autonomous start-up of gas, powder and aerosol fire extinguisher generators.

A known mechanism for actuating a fire extinguishing generator, comprising a housing in which a valve with a spring and a rod is located. The housing is mounted on the neck of the tank and contains a cylinder with a spring and a plunger with a striker. The striking platoon means is made in the form of a collet interacting by means of hooks with an annular ledge and a sleeve. In another embodiment, the striking platoon means is made in the form of latches by means of a step [1].

A disadvantage of the known mechanism is the design complexity, which makes it possible for the mechanism to fail.

The known thermal mechanism for actuating a fire extinguishing generator, including a cylindrical body, a cover with a central hole, a spring located in the body and a hammer fixed in the body. The latch is installed in the hole in the wall of the housing and interacts with the transverse groove of the hammer. A sleeve is installed between the spring and the housing cover, which interacts with the end face from the side of the cover with a washer made of fusible material covering its central hole. A glass is attached to the body, rigidly connected to the sleeve by a pin passing through a longitudinal groove in the body wall. On the inner surface of the glass grooves are made for the retainer in the form of a ball [2].

A disadvantage of the known mechanism is the reduced reliability in operation, due to the implementation of the fixing device in the form of a ball, allowing the possibility of misfire at startup.

Closest to the proposed one is the thermal mechanism for actuating the fire extinguishing generator, including a firing pin located in the housing with a spring covering it, loading the firing pin in the direction of the capsule, a fixing device that blocks the firing pin from moving in the standby state, and an initiating element mounted in the additional housing the locking device is in a standby state [3].

The disadvantage of the closest analogue is the presence of two springs, one of which is constantly cocked, and a complex locking mechanism, which reduces the reliability of the launch.

The objective of the proposed invention is to increase the efficiency of the fire extinguishing generator.

The technical result of the proposed invention is to increase the reliability of starting a fire extinguishing generator.

The technical result is achieved by the fact that in the thermal mechanism for actuating the fire extinguishing generator, including a firing pin located in the housing with a spring surrounding it, loading the firing pin in the direction of the capsule, a fixing device that blocks the firing pin from moving in the standby state, and an initiating element installed in the additional housing holding the fixing device in the standby state, according to the invention, the fixing device is made of the locking sleeve that is in tact with the striker and is in contact with the initiating element in the standby state of the stopper mounted to move at the junction of the housing and the additional housing with partial entry into each of them, while the locking sleeve has lobes of spring material that enter the gap between the standby state housing and stopper and emerging from it when the initiating element is triggered, and the spring is located inside the locking sleeve.

To implement the possibility of moving the stopper in the standby state can be installed with a gap of 1.5-2.5 mm to the additional housing.

The locking sleeve can be made cylindrical and can have from 4 to 8 petals with a thickness of 0.6-0.8 mm and a width of 1.5-3.0 mm.

The petals can be located around the circumference through 45-90 ° relative to each other, and the gap for the petals between the body and the stopper can be made at an angle of 25-30 ° to the axis of the hammer.

The locking sleeve can be made in a single design with a hammer.

The initiating element can be made in the form of a glass ampoule containing a liquid expanding when heated, which, when a certain temperature is reached, breaks the ampoule.

The initiating element may be made of a Wood alloy or of metal with shape memory, for example nitinol.

The striker striker can be made in the form of a sharpened needle.

The capsule can be performed in a firing action.

The proposed invention is illustrated in the drawing.

The thermal mechanism for actuating the fire extinguishing generator includes a firing pin 2 located in the housing 1 with a spring 3 covering it, loading the firing pin 2 in the direction of the capsule 4. An initiating element 6 is installed in the additional housing 5.

The locking device is made of a locking sleeve 7 located in the housing 1 and in contact with the striker 2 and in contact with the initiating element 6 in the standby state of the stopper 8, mounted to move at the junction of the housing 1 and the additional housing 5 with a partial entry into each of them.

The locking sleeve 7 has petals 9 made of spring material, entering the standby gap 10 between the housing 1 and the stopper 8 and coming out of it when the triggering element 6. The spring 3 is located inside the locking sleeve 7.

The stop 8 in the standby state is installed with a gap 11 to the additional housing equal to 1.5-2.5 mm.

The locking sleeve 7 is cylindrical and has from 4 to 8 petals 9 with a thickness of 0.6-0.8 mm and a width of 1.5-3.0 mm. Petals 9 are located around a circle through 45-90 ° relative to each other. The gap 10 for the petals 9 between the housing 1 and the stopper 8 is made at an angle of 25-30 ° to the axis of the hammer 2. The locking sleeve 7 can be made in a single design with the hammer 2.

The initiating element 6 can be made in the form of a glass ampoule (as shown in the drawing) containing a liquid expanding when heated, which, when a certain temperature is reached, breaks the ampoule, either from a Wood alloy or from a shape-memory metal, such as nitinol.

The firing pin 12 of the striker 2 is made in the form of a sharpened needle. Capsule 4 is made of firing action.

The mechanism has a safety pin 13 with a ring 14, which protects the hammer 2 from arbitrary movement during assembly and transportation.

The thermal mechanism for actuating the fire extinguishing generator operates as follows.

The thermal mechanism is installed in the body of the fire extinguishing generator at the guarded object and the safety pin 13 is removed.

When a fire occurs and reaches a predetermined temperature, for example 37 ° C, the initiating element 6 is destroyed. The spring 3, which is in a state of constant compression, partially releases and moves the stopper 8 by 1.5-2.5 mm through the gap 11 until it stops in the additional housing 5. In this case, the petals 9 of the locking sleeve 7 are released from the gap 10 and, due to their implementation from the spring material, freely deflect to the axis of the mechanism. As a result of this, the fixation of the striker 2 is removed. The compressed spring 3 is unloaded onto the striker 2. The striker 12 of the striker 2 hits the capsule 4, which initiates the chemical activator 15. The resulting hot gases start the fire extinguishing generator.

Information sources

1. RF patent No. 20183320 C1, cl. A62C 13/12, publ. 08/30/1994.

2. RF patent No. 2046612 C1, cl. A62C 35/02, publ. 10/27/1995.

3. RF patent No. 2491972 C2, cl. A62C 5/00, publ. 08/10/2013.

Claims (8)

1. The thermal mechanism for actuating the fire extinguishing generator, including a firing pin located in the housing with a spring surrounding it, loading the firing pin in the direction of the capsule, a fixing device that blocks the firing pin from moving in the standby state, and an initiating element installed in the additional housing holding the fixing device in standby condition, characterized in that the locking device is made of a locking sleeve located in the housing and in contact with the hammer contacting the initiating element in the standby state of the stopper installed with the possibility of movement at the junction of the housing and the additional housing with partial entry into each of them, while the locking sleeve has lobes of spring material that enter the standby gap between the housing and the stopper and exit it when the initiating element is triggered, and the spring is located inside the blocking sleeve. 2. The thermal mechanism according to claim 1, characterized in that for the possibility of moving the stopper in the standby state is installed with a gap of 1.5-2.5 mm to the additional housing. 3. The thermal mechanism according to claim 1, characterized in that the locking sleeve is cylindrical and has from 4 to 8 petals with a thickness of 0.6-0.8 mm and a width of 1.5-3.0 mm, while the petals are located along circles through 45-90 ° relative to each other, and the gap for the petals between the body and the stopper is made at an angle of 25-30 ° to the axis of the hammer. 4. The thermal mechanism according to claim 1, characterized in that the locking sleeve is made in a single design with a hammer. 5. The thermal mechanism according to claim 1, characterized in that the initiating element is made in the form of a glass ampoule containing expanding when heated liquid, which upon reaching a certain temperature breaks the ampoule. 6. The thermal mechanism according to claim 1, characterized in that the initiating element is made of a Wood alloy or metal with shape memory, for example nitinol. 7. The thermal mechanism according to claim 1, characterized in that the striker head is made in the form of a sharpened needle. 8. The thermal mechanism according to claim 7, characterized in that the capsule is made of firing.