JP2006112646A - Fan-forced heating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve safety and usability in abnormal overheating during using a fan-forced heater. <P>SOLUTION: A first overheat-prevention thermistor 16 is mounted on an upper part of a combustion chamber 3, a second overheat-prevention thermistor 17 is independently mounted near an air suction opening 4 at an upper rear part of the combustion chamber 3, and the combustion is stopped when one of the overheat prevention thermistors 16, 17 is over a temperature detection level. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a hot air heater that blows out hot air to heat a room.

Conventionally, as a safety device for preventing overheating of this type of hot air heater, as shown in FIGS. 8 and 9, a double structure of a thermistor for preventing overheating at the upper portion of the combustion chamber and a thermal fuse at the rear of the upper portion of the combustion chamber. It was due to. As shown in FIG. 10, the basic sequence is generally a double safety control sequence using a thermistor for preventing overheating and a thermal fuse for preventing overheating (see, for example, Patent Document 1).
Japanese Patent Laid-Open No. 9-210468

  However, in the conventional configuration, the temperature detection speed of the temperature heats is slower than the temperature rise detection speed of the overheat prevention thermistor. For example, in the event of abnormal overheating such as a fan lock during combustion, the combustion is stopped by blowing the temperature fuse. However, there was a problem that it took time.

  Also, once the thermal fuse is blown, the problem is that during service, the thermal fuse must be replaced with a normal one (not blown) to investigate the cause. was there.

  In order to solve the above-described conventional problem, the warm air heater of the present invention is provided with a first overheating prevention thermistor at the upper part of the combustion chamber, and a second overheating at the rear of the upper part of the combustion chamber and in the vicinity of the air suction port. The thermistors for prevention are provided independently, and the combustion is stopped when one of the overheat prevention thermistors exceeds the temperature detection level.

  According to the present invention, an abnormal overheat state is detected by a double overheat prevention thermistor, and the temperature detection level is set independently, so that an appropriate overheat prevention thermistor mounting position can be obtained. The detection temperature can be set, and the detection temperature corresponding to the abnormal overheat state peculiar to the device can be set, so that the safety when the device is abnormally overheated can be further improved.

  The hot air heater of the present invention can detect an abnormal overheating state in a double configuration, can set an appropriate detection temperature corresponding to the mounting position of the overheat prevention thermistor, and It is possible to set the detection temperature corresponding to the abnormal overheating state peculiar to the device, and the safety when the device is abnormally overheated can be further increased.

  According to a first aspect of the present invention, there is provided a burner, a combustion chamber for mixing combustion gas from the burner and room air taken in from an air suction port on the back of the apparatus, a convection fan for sending warm air, and blowing hot air. In the hot air heating air conditioner composed of the hot air outlet and the convection filter at the air inlet, a first overheat prevention thermistor is provided at the upper part of the combustion chamber, and at the upper rear of the combustion chamber. And the 2nd overheat prevention thermistor was provided independently in the vicinity of the air suction inlet, respectively.

  According to the present invention, an abnormal overheat state is detected by a double overheat prevention thermistor, and the temperature detection level is set independently, so that an appropriate overheat prevention thermistor mounting position can be obtained. The detection temperature can be set, and the detection temperature corresponding to the abnormal overheat state peculiar to the device can be set, so that the safety when the device is abnormally overheated can be further improved.

  In the warm air heater according to the first aspect of the present invention, the warm air heater control sequence is set independently for the first overheat prevention thermistor and the second overheat prevention thermistor. A temperature detection level is provided, and when either the overheat prevention thermistor exceeds the temperature detection level, combustion is stopped, and when the second overheat prevention thermistor exceeds the temperature detection level, the temperature decreases. However, it is characterized by the fact that re-operation is impossible.

  According to the present invention, it becomes possible to detect an abnormal overheat state at an appropriate detection temperature corresponding to the mounting position of the overheat prevention thermistor, and to quickly detect an abnormal overheat state specific to the device. Furthermore, when a specific overheat prevention thermistor detects an abnormal overheat state, it cannot be re-operated, thereby providing a hot air heater that achieves both usability and safety.

  According to a third aspect of the present invention, in the warm air heater according to the first or second aspect, as a warm air heating control sequence, when the combustion is stopped exceeding the temperature detection level of the second overheating prevention thermistor, The stop state is memorized and the memorized state can be released by operating a dedicated memory release switch provided on the control board. To do.

  According to the present invention, when combustion is stopped by a specific overheat prevention thermistor, after the cause is investigated, the operation can be restarted by a predetermined switch operation. It is possible to improve the usability.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiment.

(Embodiment 1)
Embodiment 1 of the present invention will be described below with reference to the drawings.

  FIG. 1 is a front sectional view of a hot air heater according to Embodiment 1 of the present invention, and FIG. 2 is a side sectional view of the hot air heater.

  In the figure, the hot air heater body 1 is provided with a combustion chamber 3 having a burner 2 for burning fuel gas, and the combustion chamber 3 communicates with an air inlet 4 at the rear of the hot air heater body 1. Yes. Further, a convection fan 6 that rotates by driving of a motor 5 is provided at the lower part of the combustion chamber 3, and communicates with a hot air outlet 7 located at the lower part of the entire surface of the hot air heater body 1 on the discharge side of the convection fan 6. is doing.

  In the hot air heater body 1, there are provided an electromagnetic valve 8 that controls the opening and closing of the combustion gas burned by the burner 2, and a proportional valve 9 that controls the amount of combustion gas. The combustion gas which burns in is supplied. When combustion gas is supplied and ignited by the spark plug 12 and burned, room air is sucked into the combustion chamber 3 from the air suction port 4 at the rear of the hot air heater body 1 by the convection fan 6 driven by the motor 5. Combustion gas combusted in the combustion chamber 3 and room air sucked from the air suction port 4 are mixed, and the warm air blowout port 7 at the lower part of the entire surface of the hot air heater body 1 becomes hot air 13 to enter the room. Supplied.

  In the above configuration, the operation is performed by the ON / OFF operation of the operation switch 14 located at the upper part of the hot air heater body 1, and the operation control board 15 b in which the operation switch 14 is disposed in the hot air heater body 1, A main control board 15a for controlling ON / OFF of the electromagnetic valve 8, the degree of opening of the proportional valve 9, the discharge of the spark plug 12, the rotational speed of the motor 5, and the like is provided.

  On the other hand, a first overheating prevention thermistor 16 is provided in the upper part of the combustion chamber 3, and a second overheating prevention thermistor 16 is provided in the vicinity of the air inlet 4 of the hot air heater body 1 at the rear of the combustion chamber 3. A thermistor 17 is provided.

  When the air inlet 4 is closed with gauze or the like during operation by the overheat prevention thermistors 16 and 17 arranged as described above, the first overheat prevention thermistor 16 provided in the upper portion of the combustion chamber 3 When the temperature rises as shown in FIG. 3 and reaches a predetermined temperature detection level, for example, the first operating constant temperature value 18 or more, the electromagnetic valve 8 is closed. At this time, since the second overheat prevention thermistor 17 is located behind the combustion chamber 3 and in the vicinity of the air suction port 4, as shown in FIG. Since the temperature rise characteristic is more gradual than the temperature rise characteristic of 16, the second operating constant temperature value 19 which is independent of the first overheating prevention thermistor 16 is not exceeded.

  Therefore, as shown in the flowchart of FIG. 6, when the cause of the blockage of the air suction port 4 is released and the temperature of the first overheat prevention thermistor 16 becomes equal to or lower than a predetermined first operating constant temperature value 18. The re-operation can be used.

  The important point here is the setting condition of the operating constant temperature value 19 of the second overheat prevention thermistor 17. This value is determined by the first overheat prevention thermistor 16 being blocked by the air inlet 4. When the temperature rises to a value close to the first operating constant temperature value of 18 and the combustion is being used, when the equipment suddenly stops burning due to pulling out of the outlet or power failure (rotation of the convection fan 6 is also stopped) The overshoot due to the hot air in the combustion chamber 3 causes the ambient temperature of the second overheat prevention thermistor 17 to rise abruptly as shown in FIG. 4, resulting in a second operating constant temperature value of 19 or more. As a result, in order to prevent the device from becoming inoperable, the second operating constant temperature value 19 having a margin with respect to the overshoot temperature under such conditions is set.

In addition, when the driving motor 5 stops for some reason during combustion, the rotation of the convection fan 6 stops. In this case, the high-temperature combustion gas burned in the combustion chamber 3 overflows from the air path behind the combustion chamber 3 to the air suction port 4 at a stretch. Accordingly, the ambient temperature of the second overheating prevention thermistor 17 provided in the vicinity of the second temperature rises rapidly, exceeds a predetermined operating constant temperature value 19 after T1 seconds, and T2 seconds after overshoot. Thereafter, the solenoid valve 8 can be quickly closed to stop the combustion.

  In this case, as shown in FIG. 7, in the case of the conventional thermal fuse 22 instead of the second overheating prevention thermistor 17 of the present invention, there is a time delay with respect to the fusing operation temperature. However, even when the temperature heats fusing temperature T0 (= T1) or higher, there is a disadvantage that a time delay T3 occurs in the fusing and the overshoot time becomes long.

  Therefore, as shown in FIG. 5, when a fan lock occurs for some reason during combustion, in the case of the configuration of the second overheat prevention thermistor 17 of the present invention, compared to the case of the conventional thermal fuse 22, The effect is obtained that combustion can be stopped earlier by (T3-T2) seconds.

  Next, as shown in FIG. 5, the second overheat prevention thermistor 17 detects an abnormality such as a fan lock and the combustion is stopped after T2 seconds after exceeding a predetermined operating constant temperature value 19. After that, even if the ambient temperature decreases and becomes the above-mentioned operating constant temperature value 19 or less after T4 seconds, the second overheating prevention thermistor 17 has a certain operating constant temperature value 19 or more. The fact that the temperature has been reached is stored in the microcomputer 20 on the control board 15a, and in such a case, combustion cannot be resumed by an ON / OFF operation at the operation switch 14. The above operation is shown in the flowchart of FIG.

  Further, as shown in FIG. 1, a memory release switch 21 is provided on the control board 15a for releasing the memory of the combustion stop due to the temperature abnormality of the second overheat prevention switch 17, and this memory is stored at the time of inspection or the like. If the release switch 21 is pressed, the combustion stop mode based on the abnormal temperature rise detection of the second overheat prevention thermistor 17 can be released. This release operation is shown in the flowchart of FIG.

  Therefore, the second operation constant temperature value or more is stored, and the memory release switch 14 on the control board 15 is operated even when the combustion cannot be used in the same way as when the conventional thermal fuse 22 is blown during re-operation. Above all, after removing the cause, it has the effect of making it easy to reuse.

  As described above, the hot air heater of the present invention is capable of detecting an abnormal overheating state with a double configuration and setting an appropriate detection temperature corresponding to the mounting position of the overheat prevention thermistor. It is possible to set the detection temperature corresponding to the abnormal overheating condition peculiar to the equipment, and the safety at the time of abnormal overheating of the equipment can be further enhanced, so the room air is sucked in by the fan and blown out as hot air The present invention can be applied to all devices having such a configuration.

Front sectional drawing of the warm air heater in Embodiment 1 of this invention Side sectional view of the same hot air heater The figure which shows the relationship of the temperature rise characteristic of the thermistor for overheating prevention of the same warm air heater The figure which shows the relationship of the temperature rise characteristic of the thermistor for overheating prevention of the same warm air heater Diagram showing comparison of temperature rise characteristics between overheat prevention thermistor and thermal fuse Flow chart showing the operation of the hot air heater Flow chart showing other operations of the hot air heater Front sectional view of a conventional hot air heater Side sectional view of a conventional hot air heater Flow chart showing the operation of a conventional hot air heater

Explanation of symbols

2 Burner 3 Combustion chamber 4 Air inlet 6 Convection fan 7 Hot air outlet 16 First overheat prevention thermistor 17 Second overheat prevention thermistor

Claims (3)

A burner, a combustion chamber for mixing combustion gas from the burner and room air taken in from an air suction port on the back of the device, a convection fan for sending warm air, and a hot air outlet for blowing warm air In the hot air heating air conditioner configured with a convection filter at the air suction port, the first overheat prevention thermistor is provided at the upper portion of the combustion chamber, and at the rear of the combustion chamber upper portion and in the vicinity of the air suction port. And a second thermistor for preventing overheating provided independently. In the hot air heating control sequence, the first overheat prevention thermistor and the second overheat prevention thermistor are each provided with a temperature detection level that is set independently. 2. The combustion is stopped when the detection level is exceeded, and when the second overheat prevention thermistor exceeds the temperature detection level, re-operation is impossible even if the temperature drops. Warm air heating device. In the hot air heating control sequence, when combustion is stopped exceeding the temperature detection level of the second overheat prevention thermistor, the combustion stop state is memorized and the operation of the dedicated memory release switch provided on the control board is operated. The warm air heating apparatus according to claim 1 or 2, further comprising a control unit configured to control the storage state so that the normal sequence operation can be performed after the cancellation.

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