JPS63267821A - Safety device for open type burner - Google Patents

Abstract

PURPOSE:To make it possible to actuate an automatic aseismatic fire extinguisher to extinguish fire at the time of oxygen deficiency and to lock the same at the time of no-fuel burning by providing a thermal deformation element sensing a temperature fluctuation at the time of oxygen deficiency within the room and changing its position, and also providing a no-fuel burning locking knob pushing up and fixing an operating frame to the side of an interlocking member at the time of no-fuel burning. CONSTITUTION:When indoor air becomes oxygen deficient, the temperature on the surface or in the vicinity of a combustion cylinder 6 lowers. This displaces a bimetal 5 provided between an outer flame cylinder 26 of the combustion cylinder 6 and an outer cylinder 27. When an interlocking member 8 having an inverted L-shaped tip end is rotated in the direction indicated by arrow by utilizing this displacement force, the interlocking member 8 is dis engaged from an engaging part 13 and falls. As a result, an automatic aseismatic fire extin guisher 7 operates and extinguishes fire. Further, when an idle burning locking knob 18 is provided at the other end of a lock lever 14 provided below the interlocking member 8, and the lower 14 is set in the direction indicated by arrow along a slit 21 of a no-fuel burning lock guide 19, the interlocking member 8 is pushed up through the lever 14, and an automatic aseismatic fire extinguisher cannot operate even when the temperature lowers at the time of no-fuel burning. Therefore, complete no-fuel burning can be performed.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a safety device for an open type combustor that safely extinguishes the fire in the event of abnormal combustion such as an indoor oxygen deficiency.

Conventional technology Conventionally, open-type combustors such as kerosene stoves are open indoors, so the combustion exhaust gas reduces the oxygen concentration in the room, creating a risk of oxygen deficiency. As you can see, Japanese Patent Application Laid-Open No. 58-9 is a safety device for abnormal combustion due to lack of oxygen in open type combustors such as kerosene stoves.
As in Publication No. 9620, a device detects oxygen deficiency with an oxygen deficiency detection sensor installed on the exterior above the combustion cylinder, and uses the output from the oxygen deficiency detection sensor to make a judgment by a control circuit that operates an alarm means or combustion stop means to issue an alarm or extinguish the fire. is published.

Also, Utility Model Publication No. 50-55239 and Utility Model Publication No. 56-
As stated in Publication No. 20707, in the event of an emergency fire extinguishment or abnormal combustion (abnormal temperature rise), the temperature at the location where the temperature changes compared to the temperature during normal combustion (for example, near the core outer cylinder or inside the fire pan) should be Heat deformable element (e.g. bimetal)
By utilizing the deflection force of the thermal deformation element, the operating frame linked to the automatic seismic fire extinguishing system is moved at the time of abnormal combustion to activate the automatic seismic fire extinguishing system and extinguish the fire.

Problems to be Solved by the Invention The oxygen deficiency detection sensor has a structure that is installed on the exterior above the combustion cylinder, and the sensor extracts an electrical signal and activates the seismic sensor using a solenoid to electrically extinguish the fire. It could not be detected when it was exhausted.

In addition, with a structure in which the operating frame is placed in contact with the heat deformable element, there are problems such as it is only effective in the case of abnormal combustion (when the flame becomes abnormally large) and is not effective in reducing the temperature in the case of oxygen deficiency. was there.

On the other hand, when a normal fire is extinguished, the temperature of the detection part equipped with a heat deformable element gradually decreases until the fire is completely extinguished, just as in the case of oxygen deficiency. The problem was that the anti-seismic automatic fire extinguishing system was activated and extinguished the fire more quickly than in normal fire extinguishing conditions, making it unsuitable for use due to the excessive odor it produced during the extinguishing process.

In addition, when dry firing the core, the temperature of the detection part provided with a heat deformable element gradually decreases until the dry baking is completely completed, as in the case of oxygen deficiency, so the oxygen deficiency device works and automatically takes countermeasures. The earthquake automatic fire extinguishing system activates and extinguishes the fire.

Therefore, there was a problem in that the core could not be completely dry-fired.

Means for Solving the Problems The present invention provides a heat deformable element that senses temperature changes during indoor oxygen depletion and displaces in the core guide tube that guides the core and the combustion tube that is placed on the core outer tube. In a structure in which an interlocking body is provided via an operating frame that operates an anti-seismic automatic fire extinguishing device in response to a heat deformable element, and a locking portion for locking the interlocking body is provided near the heat deformable element, An operating frame for pushing the interlocking body upward and locking it in the locking part is disposed below the interlocking body, and a dry-firing lock knob for pushing the operating frame toward the interlocking body and fixing it during dry-firing is provided. It was installed in conjunction with the operating frame.

When the interlocking body set in the action locking part is abnormally burned due to lack of oxygen,
By displacing the heat deformable element (hereinafter referred to as bimetal), it is released and its interlocking body is suddenly lowered, thereby properly operating the anti-seismic automatic fire extinguishing system.

That is, the interlocking body is disengaged from the locking part by the deflection force of the bimetal, and the anti-seismic automatic fire extinguishing device is activated by the spring force to extinguish the fire.

In addition, here, since the structure is such that the interlocking body is moved by the heat deformation element while the temperature is cooling, conversely, even when the temperature is rising, such as during ignition, the heat deformation element ( bimetal) hit, and the tip of the bimetal bent, allowing it to overcome the interlocking body. This may cause the bimetal to deform, so the door opens freely in the direction in which the bimetal shifts due to temperature rise, but does not open in the opposite direction. By providing it at the tip of the door, the one-way door opens even when the bimetal hits the interlocking body during the temperature rise at the initial stage of ignition, allowing the bimetal to smoothly cross over the interlocking body.

Also, when setting the interlocking body to the locking part of the guide plate, a compression spring is used to push up the interlocking body and rotate the interlocking body in the direction of the locking part, and a rotational force in the direction of the locking part is applied to this spring. By providing this additionally, the interlocking body can be rotated toward the locking portion by simply pushing it up, and can be set in the locking portion.

In addition, when normally extinguishing a fire, an operating knob is used to lower the wick, and an oxygen-deficient fire extinguishing lock lever is provided that is linked to this, allowing the interlocking body to be pushed up and fixed via one lock lever, thereby preventing oxygen deficiency. Lock the earthquake automatic fire extinguishing system.

In other words, when normally extinguishing a fire, by moving the operating knob that lowers the wick in the extinguishing direction, the lock lever that is linked to this operating knob prevents the interlocking body from moving downward, and the automatic fire extinguishing system is locked. Also, when the wick is raised using the operating knob for normal combustion, this fire extinguishing lock lever rotates, and the anti-seismic automatic extinguishing system in the event of oxygen deficiency is unlocked, and the interlocking body becomes free, allowing the automatic anti-seismic extinguishing system to function in the event of oxygen deficiency. will be able to operate freely.

Also, by setting the dry firing lock knob when dry firing the core,
A lock lever interlocked with this locks the interlocking body so that it cannot be moved downward and locks the anti-seismic automatic fire extinguishing system in the event of oxygen deficiency. In other words, when dry-firing the core, if you set the dry-burning rotary knob downward along the slit in the dry-firing lock guide, the interlocking body cannot move downward via the lock lever, and the anti-seismic automatic fire extinguishing system will be locked in the event of oxygen deficiency. be done. Also 1. When the dry firing is completed, the interlocking body becomes free by removing the set of the dry firing lock knob, and the anti-seismic automatic fire extinguishing system in the case of oxygen deficiency becomes operable.

Example An embodiment of the present invention will be described with reference to the drawings.

In the figure, 1 is a wick that sucks up liquid fuel from a tank and evaporates it. The core 1 is held by a core guide tube 2 on the inside and a core outer tube 3 on the outside. Core guide tube 2 and core outer tube 3
A combustion cylinder 6 is provided at the upper end of the cylinder. A heat deformable element 5 (here, a bimetal is used for explanation) is installed in the inner flame tube 25 of the combustion tube 6 or between the outer flame tube 26 and the outer tube 27 via an operating frame 9 to provide an anti-seismic automatic fire extinguishing system. It is provided so as to be in contact with one end of the interlocking body 8 which is interlocked with the interlocking body 7. This interlocking body 8 is provided with a spring 10 (the same effect can be obtained with a weight) that biases and compresses the interlocking body 8 downward, and the force of this spring 10 acts to push down the interlocking body 8. An operating frame 9 is provided in contact with or as a device at the lower end of the interlocking body 8, and the other end of this operating frame 9 is provided in contact with the anti-seismic automatic fire extinguishing device 7.

The tip of the interlocking body 8 has an inverted shape, and is set in the locking portion 13 when the anti-seismic automatic fire extinguishing system is set in the event of oxygen deficiency. The upper end of the compressible spring 10 provided on the interlocking body 8 is fixed to the guide tube 22, and the lower end thereof is fixed to the interlocking body 8. Furthermore, this compressing spring 10 is twisted and set so as to rotate the tip of the interlocking body 8 toward the locking portion 13.

Furthermore, a one-way opening door 12 is provided at the tip of the bimetal 5 in contact with the interlocking body 8 via a shaft 23, and the door 12 can be opened freely in the direction of deviation when the temperature rises with the shaft 23 as a fulcrum. It is designed to open in the direction in which the temperature decreases, and close in the direction in which the temperature decreases.

Further, a lock lever is attached to the lower end of the interlocking body 8 via an operating frame 9.
14 is movably provided, and a normal fire extinguishing lock lever 15 is provided so as to be in contact with the other end of this lock lever 14, and this normal fire extinguishing lock lever 15 is rotatably mounted via a shaft 16. An operating knob 17 is provided at the other end. The shaft 16 is also provided with a lever (not shown) for moving the core 1 up and down.

Further, another dry firing lock knob 18 is provided at the other end of the lock lever 14 provided at the lower end of the interlocking body 8, and this dry firing lock knob 18 has a slit 21 formed in the dry firing lock guide 19. A shaft is provided as a fulcrum 20 to be guided.

In addition, the dry firing lock knob 18 is configured to be pushed back by a normal fire extinguishing lock lever 15 which is interlocked with the operating knob 17, and the dry firing lock knob 18 is released from the set.

The operation of the above configuration will be explained next.

During steady combustion, the temperature at or near the surface of the combustion tube 6 maintains the temperature T1 shown in FIG. 2, but when it enters an oxygen-deficient condition, the tip of the wick 1 The combustion reaction in the vicinity is slowed down, the temperature at which the reaction takes place is lowered, and the amount of combustion is reduced.

Therefore, the temperature at or near the surface inside the combustion tube 6 drops as shown by T. Here, this temperature change is used to deflect the bimetal 5 provided inside the inner flame tube 25 of the combustion tube 6 (between the outer flame tube 26 and the outer tube 27), and the deflection force of this bimetal 5 is utilized. However, when oxygen is depleted, as shown in FIG.
is released from the locking part 13 and lowered by the force of the spring 10 or its own weight, and the anti-seismic automatic fire extinguishing device 7 is activated via the operating frame 9 provided at the lower end of the interlocking body 8 to extinguish the fire.

Here, when the temperature is rising, even if the one-way opening door 12 provided at the tip of the bimetal 5 hits the interlocking body 8, the door 12
opens and allows the user to easily climb over the interlocking body 8.

Next, when setting up the anti-seismic automatic fire extinguishing system in case of oxygen deficiency, when the interlocking body 8 is pushed up by the lock lever 14, the reversely shaped tip of the interlocking body 8 will automatically close due to the rotational force of the compressing spring 10. It can be rotated in the direction of the locking part 13 and set in the locking part 13.

Further, a lock lever 14 is provided at the lower part of the interlocking body 8, and a fire extinguishing lock lever 15 is normally attached to the other end of the lock lever 14 and rotates when the operating knob 17 is raised in the extinguishing direction via a shaft 16. When the operating knob 17 is pushed up during normal fire extinguishing, the interlocking body 8 is pushed up via the lock lever 14 by the normal fire extinguishing lock lever 15, and during normal fire extinguishing, even if the temperature drops, the anti-seismic automatic fire extinguishing system W17 is activated in the event of oxygen deficiency. A lock lever 14 is provided at the bottom of the interlocking body 8, and the lock lever 14 can be locked in the direction of the arrow with a dry rotor knob 18 provided at the other end of the lock lever 14. If it is set along the slit 21 of the firing lock guide 19, the interlocking body 8 will be pushed up via the lock lever 14, and during dry firing, the anti-seismic automatic fire extinguishing system will not be able to operate even if the temperature drops.
Complete dry firing is possible.

In addition, even if you forget to release the dry firing lock knob 18 after the dry firing is completed, if you lower the wick 1 with the operating knob 17, the normal fire extinguishing lock lever 15 that is linked to this will move with the shaft 16 as the fulcrum. direction, and the set dry firing lock knob 18 can be pushed and turned to automatically release it.

Effects of the Invention As described above, according to the present invention, when an open-type combustor such as a kerosene heater is used, the interlocking body can be disengaged from the locking part by the biasing force of the bimetal in an indoor oxygen-deficient condition that is considered to be dangerous. The anti-earthquake automatic fire extinguishing system can be operated properly and responsively using the force of the spring provided in the body.

Furthermore, even during ignition, the bimetal is not stopped by the interlocking body and can smoothly pass over the interlocking body through the one-way opening door.

In addition, when setting the fire extinguishing system in case of oxygen deficiency, the interlocking body should be set with a lock lever.
By simply pushing it up, the reverse-shaped tip of the interlocking body will automatically rotate toward the locking part due to the rotational force of the spring, and can be set in the locking part.

In addition, when normally extinguishing a fire, simply raising the operating knob in the extinguishing direction causes the lock lever to push up the interlocking body and automatically lock the fire extinguishing device in the event of oxygen deficiency, and the fire extinguishing device in the event of oxygen deficiency does not operate during normal fire extinguishing.

In addition, when dry burning the wick, by setting the dry burning lock knob, the lock lever pushes up the interlocking body and fixes the fire extinguishing device in the event of oxygen deficiency, making it impossible to operate, making it possible to completely dry burning. can.

In addition, even if you forget to release the dry firing lock knob, by lowering the wick using the operating knob, the dry firing lock knob can be automatically released using the normal fire extinguishing lock lever, which is beneficial.

[Brief explanation of the drawing]

FIG. 1 is a sectional side view of a main part of a safety device for an open type combustor according to an embodiment of the present invention, and FIG. 2 is a side sectional view of a main part of a safety device for an open type combustor according to an embodiment of the present invention. FIGS. 3 and 4 are perspective views of essential parts of a safety device for an open type combustor according to an embodiment of the present invention. DESCRIPTION OF SYMBOLS 1... Core, 2... Core guide tube, 3... Core outer tube, 5... Heat deformation element, 6... Combustion tube, 7
...Anti-earthquake automatic fire extinguishing system, 8...Interlocking body, 9...
- Operating frame, 13...Locking part, 18...Dry firing lock knob.

Claims (1)

[Claims] A heat deformable element (5) that senses temperature changes during indoor oxygen depletion and displaces inside the core guide tube (2) that guides the core (1) and the combustion tube (6) placed on the core outer tube (3). is provided, and the heat deformable element (
5), an interlocking body (with an inverted L shape at the upper end) via an operating frame (9) that operates the anti-seismic automatic fire extinguishing system (7) in response to
8), and a locking portion (13) that locks the interlocking body (8).
In the safety device for an open type combustor, which is provided near the heat deformable element (5), an operating frame (9) that pushes up the interlocking body (8) and locks it in the locking part (13). The interlocking body (8
), and furthermore, a dry firing lock knob (1) that pushes up and fixes the operating frame (9) toward the interlocking body (8) during dry firing.
8) is provided in conjunction with the operating frame (9).