RU2603578C1 - Lock with thermal disengagement - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: invention relates to automatic fire extinguishing means and can be used for fire extinguishing. Before operation shaft 6 is set by a clockwise turn to the initial position. Herewith body of revolution 3 extends from locking surface 5 overcoming spring 8 force thus enabling shaft 6 turn, and spring 8 twists to make the shaft return moment. After the moment of installation is over the revolution body is again at the locking surface, self-locking of shaft 6 occurs and mark 11 will stay on top. Herewith separation of the inlet and the outlet branch pipes of housing 1 by shaft 6 takes place. Fire occurrence will lead to higher temperature near housing 1 and further heating of ring 9, which will start increasing in diameter. Between the ring and ledge 10 a gap will appear, under the effect of return moment of shaft 6 revolution body 3 will move along locking surface 5 of cantilever beam 2 lifting the latter. Flowing through the whole locking surface 5, the body of revolution starts turning not preventing rotation of shaft 6 counterclockwise due to return moment of spring 8. Hyped by spring shaft rotates at high angle, as the result of which the inlet and the outlet branch pipes are connected through hole 7 of the shaft, and a fire-extinguishing substance is delivered into actuating devices feeding it into a source of fire.

EFFECT: simplified design, expanded functional capabilities and better operational characteristics.

4 cl, 2 dwg

Description

The invention relates to automatic fire extinguishing means and can be used to extinguish fires.

The prototype is a lock for sprinklers and nozzles with thermal release, having a nozzle body, an outlet channel and an outlet, and on the nozzle body above the outlet there is a structural element that seals the outlet and the outlet channel, while the structural element is held by a protective plate connected to using fusible uncoupling means with the ring, firmly connected to the nozzle body by mechanical means, while the heating element is installed in the ring [Pat. RF 2425703, IPC A62C 37/12, 2011].

The disadvantages of the prototype are:

- limited functionality of the lock, due to the inability to perform additional functions without other sensors, for example, a warning signal about a fire before the release of the extinguishing agent, which, if fired, can lead to unjustified damage to property and other material values. In addition, such a lock cannot, for example, be mounted (embedded) in a pipeline and used as a valve;

- inconvenience in operation, caused by the inability to conduct a planned (control) check of the castle;

- the complexity of the design, due to the presence of a large number of parts.

The objective of the invention is to eliminate these disadvantages, namely, simplifying the design, expanding functionality and improving performance.

The problem is solved in that the thermal trip lock, comprising a housing with inlet and outlet nozzles, a structural element hermetically closing the latter, a ring placed on the housing, and an elastic element is provided with a rolling body, and the structural element is made in the form of a shaft with a radial hole, connecting the pipes, and in the case there is a groove with a cantilever beam having a wedged surface that interacts with the free end with the ring, while the rolling body is placed in the groove and has the ability to contact a wedged surface and the shaft, and the elastic member is a spring, one end of which is fixed on the shaft, and the other - to the housing.

Part of the shaft is made in the form of a trigger element. The ring is placed on the body with a gap. A mark is made on the shaft.

These distinctive features allow you to achieve the following advantages compared with the prototype.

The castle is supplied with a rolling body, a structural element is made in the form of a shaft with a radial hole connecting the nozzles, and a groove in the housing with a cantilever beam having a jamming surface, which interacts with the free end with the ring, as well as placing the rolling body in a groove that can contact with the jamming surface and with a shaft, allows you to simplify the design of the castle by reducing the number of elements. In addition, its functionality is expanding, allowing the use of such a lock not only for the release of extinguishing agent, but also in the form of a pipeline valve.

The execution of the elastic element in the form of a spring, one end of which is mounted on the shaft, and the other on the body, reduces the dimensions of the device, which improves operational characteristics.

The execution of the shaft part in the form of a trigger element extends the functionality of the device, allowing, for example, to turn on the fire warning signal before discharging the extinguishing agent.

Placing the ring on the housing with a gap reduces the contact area of the ring with the housing, so that the heat of the upward flow of warm air during a fire is not removed from the ring onto the housing, which increases the accuracy of the device and improves performance.

The implementation of the mark on the shaft allows you to control its position visually in the process of scheduled inspections, which increases operational characteristics.

The invention is illustrated by drawings.

In FIG. 1 shows a thermal release lock. In FIG. 2- section AA.

The thermal trip lock comprises a housing 1 with inlet and outlet nozzles, in which a groove is made with a cantilever beam 2 in contact with the rolling body 3, pressed by a spring 4 to its wedging surface 5 and to a shaft 6 rotatably mounted in the housing and having an opening 7 for the passage of the extinguishing agent from the inlet to the outlet pipe. A torsion spring 8, the other end of which is attached to the housing, is freely mounted and fixedly fixed at one end on the shaft. Ring 9, which has a greater coefficient of linear expansion than the body, covers it with a protrusion 10 of the cantilever beam. The shaft may be labeled 11.

The thermal release lock operates as follows.

Before starting operation, the shaft 6 is set (turning, for example, with a key or handle, clockwise) to its original position (Fig. 1). In this case, the rolling body 3 moves away from the jamming surface 5, overcoming the force of the spring 8, allowing the shaft 6 to rotate clockwise, and the spring 8 is twisted, creating a moment returning the shaft (Fig. 2). However, after removing the installation moment, the rolling body 3 will again be on the jamming surface 5, the shaft 6 will self-decelerate and the mark 11 will remain, for example, at the top. In this case, the separation of the input and output nozzles by the shaft 6 will occur.

The occurrence of a fire will cause an increase in temperature near the housing 1 and subsequent heating of the ring 9, which will begin to increase in diameter. After the diameter of the ring increases so that a gap appears between it and the protrusion 10, under the action of the returning moment of the shaft 6, the rolling body 3 moves along the jamming surface 5 of the cantilever beam 2, lifting the latter and thereby choosing the specified gap. The disappearance of the gap will lead to a stop of the rolling body 3 on the surface 5 and self-braking of the shaft 6. At the same time, together with the mark 11, it will turn a certain angle from its original position, which will indicate a significant increase in temperature. If the mark 11 is made, for example, protruding, then through it it is possible, for example, to close the contacts of the sound signal, warning of an increase in temperature in the area of the lock and the possible subsequent operation of the lock.

The higher the temperature, the greater the angle the shaft will turn. If the temperature does not increase anymore, then the rolling body and the shaft will remain in place, mechanically fixing ("remembering") the maximum temperature (or the fact of its increase) in the castle area. Lowering the temperature around the lock, for example, after eliminating the heat radiation source, will also not cause the shaft to rotate, since when the ring 9 is compressed, the protrusion 10 will move down, i.e. the cantilever beam 2 is slightly bent (bent) on the rolling body, while leaving it in its original place. Note that, at the same time, the ring 9 will also slightly extend (within the limits of elastic deformation), assuming a slightly oval shape. During the next inspection of the fire system, the deviation of the mark 11 from the initial upper position judges the thermal conditions around the castle. If the mark 11 is close to the position at which the warning sound signal is generated (electric or mechanical), it is necessary to establish the reason for such heating. The mark 11 can then be returned to its original state by turning the shaft 6 clockwise. Note that you can periodically check the operation of the lock by manually removing the ring 9 from the housing 1.

If the temperature continues to rise, which occurs during a fire, then the ring 9 will expand so that the rolling body 3 passes the entire jamming surface 5 and begins to turn, not preventing the rotation of the shaft 6 counterclockwise due to the return moment of the spring 8. The shaft untwisted by the spring will rotate at a large angle, as a result of which the inlet and outlet nozzles will be connected through the shaft hole 7 and a fire extinguishing agent, such as water, will enter the actuators supplying it to the fire.

Note that the lock can be actuated remotely by heating the ring from an additional source or deforming in the horizontal direction.

The implementation of the invention will create a simple and easy to use lock for an automatic fire extinguishing system.

Claims (4)

1. The thermal release lock, comprising a housing with inlet and outlet nozzles, a structural element hermetically closing the latter, a ring placed on the housing, and an elastic element, characterized in that it is provided with a rolling body, and the structural element is made in the form of a shaft with a radial a hole connecting the nozzles, and in the case there is a groove with a cantilever beam having a wedged surface, interacting with the free end with a ring having a greater coefficient of linear expansion than the body s, wherein the rolling body is arranged in the groove and has a possibility of contact with the wedging surface and the shaft, and the elastic member is a spring, one end of which is fixed on the shaft, and the other - to the housing. 2. The lock according to claim 1, characterized in that the shaft part is made in the form of a trigger element. 3. The lock according to claim 1, characterized in that the ring is placed on the housing with a gap. 4. The lock according to claim 1, characterized in that the mark is made on the shaft.

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