RU201238U1 - THERMAL MECHANISM OF ACTIVATING THE FIRE EXTINGUISHING GENERATOR - Google Patents

Abstract

The utility model relates to fire fighting equipment, in particular to fire extinguishers, the use of which is possible in automatic mode. The thermal mechanism for actuating the fire extinguishing generator contains a striker located in the body in the form of a rod with a spring enclosing it, loading the striker in the direction of the capsule, a locking device that blocks the striker from moving in a waiting state, and an initiating element installed in the upper part of the body that holds the locking device in a waiting state. The fixing device is made consisting of a spherical element that performs the function of the actual retainer and an auxiliary part that protects the actual retainer from relative displacement and performs the function of a blocking crack. The upper part of the blocking cracker is fixed on the initiating element, and its lower part is made beveled at an angle of 60 ± 0.1 with respect to the vertical axis and contacts in the standby mode with the lock itself, which is installed with the possibility of radial movement in an annular recess provided in the upper part of the striker rod. The model allows to expand the arsenal of devices for similar purposes and to improve the reliability of the device. 7 c.p f-ly, 4 fig.

Description

The proposed utility model relates to fire fighting equipment, in particular to fire extinguishers, which can be used in an automatic mode. It is used for autonomous starting of generators of gas, powder and aerosol fire extinguishers.

Known thermal mechanism for actuating a fire extinguishing generator [1], including a cylindrical body, placed in it a drummer, loaded with a spring in the direction of the capsule. In the standby state, the striker is held in the body by a locking device, which is blocked by an initiating element installed in the body opening and made on the basis of a eutectic composition. In another embodiment of the thermal mechanism, the eutectic is held in place by a restraining clip, which, when removed, releases the spring loaded hammer to initiate the primer. The disadvantage of this mechanism is the unreliability of the constructive solution of the eutectic initiating element, which causes a high probability of failure of the mechanism to operate.

Also known is a thermal mechanism for actuating a fire extinguishing generator [2], which includes a striker located in the housing with a spring enclosing it, loading the striker in the direction of the capsule, a fixing device that blocks the striker from moving in a standby state, and an initiating element installed in an additional housing that holds a locking device in a waiting state, wherein the locking device is made of a blocking sleeve located in the body and in contact with the striker and a stopper in contact with the initiating element in the waiting state, installed with the ability to move at the junction of the body and the additional body with partial entry into each of them. The blocking sleeve has petals made of a springy material that enter in the standby state into the gap between the housing and the stopper and leave it when the initiating element is triggered, and the spring is located inside the blocking sleeve. The disadvantage of this mechanism is the complexity of the design and, associated with this, its sensitivity to vibration and shock loads, which limits the scope of its application.

The closest to the proposed device is a thermal mechanism for actuating a fire extinguishing generator [3], which includes a striker located in the body with a spring enclosing it, loading the striker in the direction of the capsule, a fixing device with an additional spring that blocks the striker from moving in a standby state, and installed in a separate housing, an initiating element that holds the locking device in a waiting state. The disadvantage of the closest analogue is the presence in its design of two springs, which are constantly in the charged state, and the complex mechanism of the lock, which reduces the reliability of starting.

The technical problem to be solved by the proposed utility model is to expand the arsenal of devices for a similar purpose and 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, which includes a striker located in the body in the form of a rod with a spring covering it, loading the striker in the direction of the capsule, a fixing device that blocks the striker from moving in a waiting state, and installed in the upper part of the body, the initiating element holding the locking device in a waiting state, according to the utility model, the locking device is made consisting of a spherical element that performs the function of the lock itself and an auxiliary part that protects the element from relative displacement and performs the function of a locking cracker, while the upper part of the locking cracker is fixed on the initiating element, and its lower part is made beveled at an angle of 60 ± 0.1 ° relative to the vertical axis and contacts in standby mode with a latch, which is installed with the possibility of radial movement in a ring tse-shaped recess provided in the upper part of the striker rod.

For the implementation of the possibility of vertical movement, the blocking cracker in the standby state is installed in the housing with a sliding fit.

The initiating element is made of a material that changes shape when the environment is heated.

In particular, the initiating element is made, for example, in the form of an ampoule containing a liquid expanding upon heating, which breaks the ampoule at a certain temperature, or is made of Wood's alloy or a metal with a shape memory, for example, nitinol.

The striker's striker is made in the form of a sharpened needle, while the capsule is made with a puncture or impact action.

The annular recess in the upper part of the striker rod is a recess or groove with a depth equal to about 1/3 of the diameter of the ball (spherical) retainer.

The fixing device is equipped with an element that protects against unintended actuation.

The essence of the utility model is illustrated by graphic materials, where

figure 1 presents a General sectional view of the proposed device;

figure 2 is a general side view of the device;

Fig. 3 is a general view of a bread crumbs in section;

figure 4 is a general view of a biscuit in perspective.

The proposed thermal mechanism for actuating the fire extinguishing generator includes a striker located in the housing 1 in the form of a rod 2 with a spring 3 enclosing it, loading the striker towards the capsule 10, and with an annular recess 9 provided in its upper part. The mechanism also contains a locking device that blocks the striker 2 from moving in a waiting state, and an initiating element 6 installed in the upper part of the housing 1, which holds the locking device in a waiting state. The fixing device is made of an element 4 of approximately spherical shape, which performs the function of the actual fixture and an auxiliary part 5, which protects the element 4 from relative displacement and performs the function of a blocking crack. The upper part of the blocking cracker 5 is fixed to the initiating element 6. The lower part of the cracker 5 is made with a bevel (beveled) at an angle of 60 ± 0.1 ° relative to the vertical axis.

The latch 4 is installed with the possibility of radial movement in an annular recess 9 (recess, groove) provided in the upper part of the striker rod 2.

The blocking cracker 5 in the standby state is installed in the housing 1 with a sliding fit.

The initiating element 6 is fixed in the housing 1 by means of a stop nut 7. The element 6 can be made in the form of a glass ampoule (as shown in the given drawing) containing a liquid expanding when heated, which, when a certain temperature is reached, ruptures the ampoule made either from Wood's alloy or shape memory metal such as nitinol.

Striker 12 striker 2 is made in the form of a sharpened needle. Capsule 10 is made with a puncture effect.

The mechanism has a safety pin 8, which protects the striker 2 from arbitrary movement during assembly and transportation.

The position 11 denotes a chemical activator, which, when the thermal mechanism is triggered, activates a fire extinguishing generator (not indicated in the drawing).

The proposed thermal mechanism for driving a fire-extinguishing generator works as follows.

The thermal mechanism is installed in the body of the fire extinguishing generator at the guarded facility and the safety pin 8 is removed.

When a fire breaks out and a predetermined temperature is reached, for example, 37 ° C, the initiating element 6 is destroyed. In this case, the spring 3, which is in a state of constant compression, is partially released and the elastic force of the spring 3, acting on the striker 2, pushes the retainer 4 itself out of the ring-shaped recess 9 and pushes the cracker 5 upward, finally removing the fixation of the striker 2. The compressed spring 3 is unloaded onto the striker 2. The striker 12 of the striker 2 hits the capsule 10, which activates the chemical activator 11. The resulting hot gases start the fire extinguishing generator.

Thus, the above description of the device and its operation confirm the possibility of implementing the utility model with the achievement of the claimed technical result, namely, increasing the reliability of starting the fire extinguishing generator by simplifying the design of the fixing device.

Claims (8)

(1) A thermal mechanism for actuating a fire extinguishing generator, which includes a rod-shaped striker located in the body with a spring covering it, loading the striker towards the capsule, a fixing device that blocks the striker from moving in a standby state, and an initiating element installed in the upper part of the case, holding the fixing device in a waiting state, characterized in that the fixing device is made consisting of a spherical element that performs the function of the actual latch, and an auxiliary part that protects the latch itself from relative displacement and performs the function of a blocking rim, while the upper part of the blocking rim is fixed on the initiating element, and its lower part is made beveled at an angle of 60 ± 0.1 ^{about the} vertical axis and contacts in standby mode with the actual latch, which is installed with the possibility of radial movement in an annular recess, provided in the upper part of the striker rod. 2. The thermal mechanism according to claim. 1, characterized in that for the implementation of the possibility of vertical movement, the blocking cracker in the waiting state is installed in a housing with a sliding fit. 3. The thermal mechanism according to claim 1, characterized in that the initiating element is made of a material that changes shape when the environment is heated. 4. Thermal mechanism according to claim 3, characterized in that the initiating element is made, for example, in the form of an ampoule containing a liquid expanding upon heating, which at a certain temperature ruptures the ampoule. 5. Thermal mechanism according to claim. 3, characterized in that the initiating element is made of Wood's alloy or metal with shape memory, for example, nitinol. 6. The thermal mechanism of claim. 1, characterized in that the striker firing pin is made in the form of a sharpened needle. 7. Thermal mechanism according to claim 1, characterized in that the capsule is made with a knock or impact action. 8 Thermal mechanism according to claim 1, characterized in that it is provided with an element that protects it from unexpected operation.

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