KR100932712B1 - Thermal-detective operation device and solid-aerosol automatic extinguisher - Google Patents

Abstract

PURPOSE: A heat sensing-operating apparatus and a solid aerosol automatic extinguisher including the same are provided, which can detect malfunction due to overheat or fire in an early stage. CONSTITUTION: A heat sensing-operating apparatus comprises a sensor body(10) which is equipped with a first pipe having the first inside diameter, a second pipe located in the bottom of the first pipe, a jaw between the first pipe and second pipe, and two grooves formed in the top of the first pipe; a pestle(20) including the pestle needle located on the lower part of the pestle disc; and a heat sensing member(30) releasing the pestle head. The pestle is equipped with a pestle head, an elastic member insertion part, a pestle connection part, and a pestle disc.

Description

Thermal-detective operation device and solid-aerosol automatic extinguisher including the same

The present invention relates to a heat sensor and an automatic fire extinguisher, and more particularly to a heat sensing operation device and a solid aerosol automatic fire extinguishing device.

In general, the thermal sensor is used in various fields, for example, reactor temperature detection or fire detection to prevent the reactor from overheating, or an unmanned military weapon system, and effectively detects heat to prevent the failure of the device. Various studies have been conducted to prevent or to make an early evolution of fire.

In addition, in the case of a fire, a fire caused by electricity occupies a substantial portion of the entire fire gun, and a fire occurs frequently due to a short circuit in an electrical outlet, a switch box, a light fixture, or an electronic product. In addition, if a fire occurs in an unattended or uninhabited area, the fire will progress to some extent after the upper time has elapsed since the fire has occurred and the temperature should rise and the smoke and flame should be activated so that a fire detector occurs and the fire extinguishing facility operates. Since it was mature, there were many difficulties in suppression. In particular, most of the fire-extinguishing facilities are installed on the ceiling, so there is a considerable distance from the electrical equipment that is the point of ignition of the fire, and thus there is a problem that the fire is not detected early or the fire suppression is not properly performed. Therefore, various studies have been made on the thermal sensor and the automatic fire extinguishing apparatus to recognize the fire at an early stage to block the spread of the fire and extinguish the fire.

Accordingly, the technical problem of the present invention is to provide a heat sensing operation apparatus capable of effectively detecting heat and recognizing a failure or fire due to overheating of the device at an early stage. In addition, another technical problem of the present invention is to provide an automatic fire extinguishing device capable of automatically extinguishing a topic at an early stage.

According to an aspect of the present invention, there is provided a heat sensing operating device including a first tube having a first inner diameter therein, a second tube having a second inner diameter larger than the first inner diameter and positioned below the first tube, A cylindrical sensing body having a jaw between the first tube and the second tube and at least two grooves formed on an upper end of the first tube; A ball head having a diameter smaller than the first inner diameter and positioned inside the first pipe and having a safety pin hole protruding above the first pipe and into which a safety pin is inserted, and located below the ball head and inside the second pipe. An elastic means inserting portion into which the elastic means is inserted, a ball connecting the elastic means inserting portion and the ball head is located under the elastic means inserting portion, and has a diameter larger than that of the elastic means inserting portion to support the elastic means. A ball including a disc, and a ball in which the ball is located below the disc, the ball including sinking; And a heat-sensing member inserted into the at least two grooves to have a horseshoe shape to fix the head, which is opened out at a predetermined temperature or more to release the ball head.

In one example, the heat sensing member may be a bimetal, and may include a high expansion portion located inside and a low expansion portion located outside. Herein, the material of the low expansion portion may include an invar. The material of the high expansion portion may include at least one selected from the group consisting of nickel-chromium-iron alloys, nickel-manganese-iron alloys, and manganese-copper-nickel alloys. The material of the sensing body and the ball may include stainless steel.

The heat sensing operating device may further include a sensing coupling part including a thread formed on the outer wall of the second tube.

Automatic extinguishing device according to the present invention for achieving the another technical problem is the heat sensing operation device; A fire extinguishing portion coupled with the sensing coupling portion by having a screw thread opposite to that of the sensing coupling portion; A fire extinguishing body positioned below the fire extinguishing unit and including an outlet for discharging at least one solid extinguishing aerosol; A igniter, which is located between the fire extinguishing portion and the fire extinguishing body and ignites when a physical shock is applied by the ball sinking; A solid extinguishing agent located in the extinguishing body and combusted by ignition of the igniter; A coolant located in the extinguishing body to cool the solid extinguishing aerosol resulting from combustion of the solid extinguishing agent; And a separation network positioned in the extinguishing body and including at least one hole for separating from the solid extinguishing agent and the coolant and passing the solid extinguishing aerosol.

According to the heat sensing operation apparatus and the solid aerosol automatic fire extinguishing apparatus including the same according to the present invention, the heat sensing member is opened out at a predetermined temperature or more, and when the ball releases the head, the ball is released by the elastic restoring force of the elastic means. Will be lowered automatically. This allows the ball to sink and physically impact the fire extinguishing agent of the automatic fire extinguishing system to ignite the fire extinguishing agent to activate the solid aerosol automatic fire extinguishing system, which generates a solid extinguishing aerosol to quickly extinguish the fire. The heat sensing automatic device may also be used in other automatic fire extinguishing system systems (not shown) in addition to the solid aerosol automatic fire extinguishing device illustrated herein. That is, the heat sensing operation device is operated at a predetermined temperature or more, so that the ball falling down can press the fire extinguishing device operating button or the emergency bell which may be provided in another automatic fire extinguishing system. The heat sensing actuation device of the present invention may also be used in unmanned military weapon systems. The thermally sensitive actuating device of the present invention can also be used in a variety of industrial equipment. For example, the heat sensing operation device may be mounted in a semiconductor manufacturing equipment or a reactor, and when the reactor light is overheated above a certain temperature, the heat sensing operation device is operated to press a power cutoff button to heat the reactor light. It can also be prevented.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein but may be embodied in other forms. Rather, the embodiments introduced herein are provided to ensure that the disclosed subject matter is thorough and complete, and that the spirit of the invention will be fully conveyed to those skilled in the art.

1 is a perspective view of a heat sensing operating apparatus according to an embodiment of the present invention, FIG. 2 is a perspective exploded view of FIG. 1, and FIG. 3 is a cross-sectional view taken along line I-I of FIG. 1.

1 to 3, the heat sensing operating device 100 according to the present invention includes a first tube 16 having a first inner diameter D1 therein and a second inner diameter larger than the first inner diameter D1. (D2) has a second tube 17 located below the first tube 16, the jaw 13 between the first tube 16 and the second tube 17, and the first tube ( 16) It includes a cylindrical sensor body 10 having at least two grooves 14 formed on the top. The sensing unit body 10 is threaded on the lower outer wall of the second tube 17 so that the heat sensing operating device 100 can be used in combination with other devices such as an automatic fire extinguishing device and is coupled with other devices. It may further include a sensing coupling unit 15 to be. The first tube 16 and the second tube 17 are divided for convenience of description, and the two tubes may be separated from each other or integrally attached. The shape or position of the sensing coupling unit 15 may be changed in various ways depending on the equipment or the device on which the heat sensing operating device 100 is mounted.

The material of the sensing unit body 10 may include stainless steel.

The heat sensing operating device 100 has a diameter D3 smaller than the first inner diameter D1, is located inside the first tube 16, protrudes above the first tube 16, and the safety pin 40 is disposed. Ball head 22 having a safety pin hole (21) to be inserted, the elastic means insertion portion which is located under the ball head 22 and is located inside the second tube 17 and the elastic means 24 is inserted 26, a ball connecting the elastic means inserting portion 26 and the ball head 22 is a connecting portion 27 and a diameter of the elastic means inserting portion 26 positioned below the elastic means inserting portion 26. A ball having a larger diameter to support the elastic means 24 comprises a disc 25, and a ball 20 including a ball sink 23 where the ball is located below the disc 25. The material of the ball 20 may include stainless steel. The elastic means 24 is contracted with the jaw 13 and the ball located between the disk 25. The elastic means 24 may be made of a material different from the other elements that make up the ball 20. The ball connecting portion 27 should be smaller than the diameter (D3) of the ball head 22. In addition, the elastic means inserting portion 25 may have a diameter of the ball is equal to or smaller than the diameter of the head (22).

In addition, the heat sensing operating device 100 has a horseshoe shape inserted into the at least two grooves 14 to fix the head 22, and is opened out at a predetermined temperature to release the ball head 22. And a heat sensing member 30.

4 illustrates a heat sensing member according to an embodiment of the present invention.

Referring to FIG. 4, the heat sensing member 30 according to the present invention may be a kind of bimetal, and may have a shape in which both ends are further retracted inward in the shape of a horseshoe. Before the heat sensing member 30 is opened out by heat, the spacing W1 between both ends must be smaller than the diameter D3 of the head 22. As a result, the ball head 22 may be fixed.

The heat sensing member 30 is made of a material having a different coefficient of thermal expansion for both the sensing body 10 and the ball 20. Specifically, the heat sensing member 30 may include a low expansion portion 31 positioned outside and a high expansion portion 32 positioned inside. The low expansion portion 31 and the high expansion portion 32 may be attached by a rolling method. The low expansion portion 31 may be made of a metal alloy having a smaller thermal expansion coefficient than the high expansion portion 32. The high expansion portion 32 may be made of a metal alloy having a greater thermal expansion coefficient than the low expansion portion 31. Herein, the material of the low expansion portion 31 may include invar, and the material of the high expansion portion 32 may include nickel-chromium-iron alloy, nickel-manganese-iron alloy, and manganese-copper-nickel alloy. It may include at least one selected from the group. As a result, the thermal sensing member 30 of the present invention is opened out due to the difference in thermal expansion rate between the low expansion portion 31 and the high expansion portion 32 at a predetermined temperature or more. The width between both ends is greater than W1 and the ball is larger than the diameter D3 of the head 22. The constant temperature may be, for example, 72 ℃, 94 ℃, 105 ℃ or 124 ℃.

Although not shown, the thermal sensing member 30 may further include one or more alloy layers interposed between the low expansion portion 31 and the high expansion portion 32.

Again, referring to FIGS. 1 to 3, the mounting process of the thermal sensing operation apparatus 100 will be described. First, the ball 20 is located at the bottom of the sensing unit body 10. Inside). Then, the ball presses the lower surface of the disk 25 upwards so that the ball 22 protrudes above the first pipe 16 to expose the safety pin through hole 21. In this state, the safety pin 40 is inserted into the safety pin through-hole 21 to allow the ball 20 to be fixed in the sensing unit body 10. Then insert the heat sensing member 30 into the groove 14 from above the sensing body 10 and at the same time the end of the sensing body 10 is fitted so that the ball supports the bottom of the head 22. . After that, the safety pin 40 is removed. In this manner, the heat sensing operation device 100 may be operated as follows.

5 shows the operating principle of the heat sensing actuator of FIG.

Referring to FIGS. 3 and 5, when a heat such as a fire occurs around the temperature and rises above a predetermined temperature, the heat sensing member 30 is opened to the outside and the ball 22 is released. At this time, the ball 20 is lowered by the elastic restoring force of the elastic means 24 that the jaw 13 and the ball are contracted between the disk 25. As a result, the ball sinking 25 may cause a fire by physically impacting the fire extinguishing agent of the automatic fire extinguishing apparatus, which will be described later, or by pressing an operation button or an emergency bell of various automatic fire extinguishing systems. Can be. In addition, the thermally sensitive actuating device 100 of the present invention can also be used in unmanned military weapon systems. In addition, the thermally sensitive actuating device 100 of the present invention can be used in a variety of industrial equipment. For example, the heat sensing operation device may be mounted in a semiconductor manufacturing equipment or a reactor, and when the reactor light is overheated above a certain temperature, the heat sensing operation device is operated to press a power cutoff button to heat the reactor light. It can also be prevented.

In the thermal sensing operation device 100 of the present invention, the groove 14 is shown in two, but the groove 14 may be three or more. The shape of the heat sensing member 30 may also be changed according to the number of the grooves 14. Alternatively, the grooves 14 are all along the upper edge of the first tube 16, so that the heat sensing member 30 has a concave lid or bowl shape without the grooves 14 at all. It may support (22).

6 is a cross-sectional view of a solid aerosol automatic fire extinguishing apparatus including a heat sensing operation device according to an embodiment of the present invention.

Referring to FIG. 6, the automatic fire extinguishing device 200 according to an embodiment of the present invention includes the heat sensing operating device 100; Fire-extinguishing unit 120 having a thread opposite to the thread of the sensing coupling unit 15 and coupled to the sensing coupling unit 15; Located on the lower extinguishing coupling portion and includes a fire extinguishing body 110 including an outlet 115 for discharging at least one solid extinguishing aerosol. Between the fire extinguishing portion 120 and the fire extinguishing body 110, the ball igniter 130 is ignited when a physical impact is applied by the ball sinking 23 is located. The igniter 130 may be a kind of gunpowder. The automatic fire extinguishing device 200 of the present invention is operated by using the property of gunpowder that instantaneously ignites when subjected to physical shock.

The extinguishing body 110 includes a solid extinguishing agent 140 that is burned by the ignition of the igniter 130 and a coolant 160 that cools the solid extinguishing aerosol generated by the combustion of the solid extinguishing agent 140. These are 140, 160 in the form of solid particles. The solid extinguishing agent 140 may be, for example, a solid mixture including KNO ₃ , KClO _4, and carbon. The solid extinguishing agent 140 is combusted due to the heat of ignition when the igniter 130 is ignited, and at this time, a solid extinguishing aerosol component containing a large amount of potassium (K) is generated. An aerosol is referred to as an aerosol when particles in the solid or liquid state are present in the gas. Solid extinguishing aerosol thus means that solid extinguishing component particles are present in the gas.

The coolant 160 may be, for example, a solid mixture of at least one material selected from the group comprising Mg (OH) ₂ , Na ₂ CO ₃ , H ₃ BO ₃ , KClO ₄ , KNO ₃ and CaCO ₄ . have.

 It is separated from each other by a plurality of separation networks (150a, 150b, 150c) located in the fire extinguishing body (110). The separation nets 150a, 150b, 150c include at least one hole through the solid extinguishing aerosol. The diameter of at least one hole of the separation nets 150a, 150b, 150c is smaller than the particles of the solid extinguishing agent 140 and the coolant 160 such that the solid extinguishing agent 140 and the coolant 160 are smaller. Do not let it pass.

Although not shown, the automatic fire extinguishing device 200 is located on the inner wall of the fire extinguishing body 110 has a heat dissipation function that blocks the combustion heat generated when the solid extinguishing agent 140 is burned to the outside. It may be further included to.

FIG. 7 shows the operating principle of the solid aerosol automatic fire extinguishing device of FIG. 6.

Referring to FIG. 7, when heat, such as a fire, is generated in the surrounding area and rises above a predetermined temperature, the heat sensing member 30 is opened to the outside and the ball 22 is released. At this time, the ball 20 is lowered by the elastic restoring force of the elastic means 24, the jaw 13 and the ball is contracted between the disk 25, thereby the ball sinking 23 Physical impact is applied to the igniter 130. The ignition agent 130 of the gunpowder component is ignited by the physical impact, and the solid extinguishing agent 140 is burned due to the heat of ignition. As the solid extinguishing agent 140 burns, a solid extinguishing aerosol is generated, and the solid extinguishing aerosol is cooled by passing through the coolant 160 along the dotted arrow 199, and the separation network 150a. And discharged through the outlet 115 through the ends 150b and 150c. The discharge-injected solid extinguishing aerosol 199 may be extinguished by blocking oxygen in the fire generating area or blocking a chain reaction of the fire. This allows early completion of fire extinguishing lamps.

1 is a perspective view of a heat sensing actuator according to an embodiment of the present invention.

2 shows a perspective exploded view of FIG. 1.

3 is a cross-sectional view taken along the line I-I of FIG. 1.

4 illustrates a heat sensing member according to an embodiment of the present invention.

5 shows the operating principle of the heat sensing actuator of FIG.

6 is a cross-sectional view of a solid aerosol automatic fire extinguishing apparatus including a heat sensing operation device according to an embodiment of the present invention.

FIG. 7 shows the operating principle of the solid aerosol automatic fire extinguishing device of FIG. 6.

<Explanation of symbols for the main parts of the drawings>

100: heat sensing operating device 200: solid aerosol automatic fire extinguishing device

10: Sensing Body Torso 13: Jaw

14: groove 15: sensing coupling

16: tube 1 17: tube 2

20: Ball 21: Safety pin through

22: the ball head 23: the ball is sunk

24: elastic means 25: elastic means insertion portion

27: ball connection 30: heat sensing member

31: low expansion portion 32: high expansion portion

110: extinguishing body 115: outlet

120: digestive coupling 130: igniter

140: solid extinguishing agent 150a, 150b, 150c: separation network

160: coolant 199: flow of solid extinguishing aerosol

Claims (7)

A first tube having a first inner diameter therein, a second tube having a second inner diameter larger than the first inner diameter and positioned below the first tube, a jaw between the first tube and the second tube, and the first tube A cylindrical sensing unit body having at least two grooves formed at the top of the tube; A ball head having a diameter smaller than the first inner diameter and positioned inside the first pipe and having a safety pin hole protruding above the first pipe and into which a safety pin is inserted, and located below the ball head and inside the second pipe. An elastic means inserting portion into which the elastic means is inserted, a ball connecting the elastic means inserting portion and the ball head is located at the bottom of the elastic means inserting portion, and has a diameter larger than that of the elastic means inserting portion to support the elastic means. A ball including a disc, and a ball in which the ball is located below the disc, the ball including sinking; And And a heat-sensing member inserted into the at least two grooves and having a horseshoe shape to fix the head, which is opened outside at a predetermined temperature to release the ball head. The method of claim 1, The heat sensing member is a bimetal, the heat sensing operating device, characterized in that it comprises a high expansion portion located in the inner and a low expansion portion located in the outer. The method of claim 2, The material of the low-expansion portion includes invar, the material of the high-expansion portion includes at least one selected from the group consisting of nickel-chromium-iron alloy, nickel-manganese-iron alloy and manganese-copper-nickel alloy, Heat sensing operating device, characterized in that the material of the sensing body and the ball comprises a stainless steel. The method of claim 1, And a sensing coupling part including a screw thread formed on the outer wall of the second tube. A heat sensing operating device of claim 4; A fire extinguishing portion coupled with the sensing coupling portion by having a screw thread opposite to that of the sensing coupling portion; A fire extinguishing body positioned below the fire extinguishing unit and including an outlet for discharging at least one solid extinguishing aerosol; A igniter, which is located between the fire extinguishing portion and the fire extinguishing body and ignites when a physical shock is applied by the ball sinking; A solid extinguishing agent located in the extinguishing body and combusted by ignition of the igniter; A coolant located in the extinguishing body to cool the solid extinguishing aerosol resulting from combustion of the solid extinguishing agent; And A solid aerosol automatic fire extinguishing device comprising a separation network located in the extinguishing body and separated from the solid extinguishing agent and the coolant and including at least one hole through which the solid extinguishing aerosol passes. The method of claim 5, wherein The heat sensing member is a bimetal, solid aerosol automatic fire extinguishing device comprising a high expansion portion located in the inner and a low expansion portion located in the outer. The method of claim 6, The material of the low-expansion portion includes invar, the material of the high-expansion portion includes at least one selected from the group consisting of nickel-chromium-iron alloy, nickel-manganese-iron alloy and manganese-copper-nickel alloy, Solid material aerosol automatic fire extinguishing device, characterized in that the material of the sensing body and the ball comprises a stainless steel.

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