JP2012177492A - Open type burning heating apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique to prevent false detection caused by inflow of outdoor air into the room, in an open type burning heating apparatus for detecting a malfunction by a gas sensor such as a CO sensor and an Osensor.SOLUTION: The open type burning heating apparatus burns a fuel by a burner to heat inside of a room. The open type burning heating apparatus includes: a CO sensor for detecting CO concentration in the air in a room; a room temperature sensor for detecting the air temperature in the room; and a burner controller for terminating burning of the burner when the CO concentration detected by the CO sensor exceeds a first CO concentration threshold during burning of the burner. The burner controller continues burning of the burner when the CO concentration detected by the CO sensor exceeds the first CO concentration threshold and the temperature detected by the room temperature sensor decreases.

Description

  The present invention relates to an open type combustion heating apparatus.

  Patent Document 1 discloses an open type combustion heating apparatus including a CO sensor. In the open-type combustion heating apparatus, when the increase in the CO concentration is detected by the CO sensor, the burner combustion is automatically terminated, and the burner combustion is prohibited until the CO concentration is lowered to a low level again. According to the technique of Patent Document 1, even when the burner causes incomplete combustion, the operation of the open-type combustion heating device can be automatically stopped to ensure the safety of the user.

JP 2010-164213 A

  Opening doors and windows while using open-type combustion heating equipment will cause outside air to enter the room from the outside. The outside air may contain a small amount of CO due to automobile exhaust gas or cigarette smoke, and the CO sensor may detect an increase in CO concentration due to the inflow of outside air from the outside. In particular, when an open-type combustion heating device is arranged near a door or window, outside air that has flowed in from the outside comes into contact with the CO sensor without substantially mixing with indoor air, and temporarily has a high concentration. CO may be detected. If the operation of the open-type combustion heating device is stopped up to such a case, the user's comfort is impaired.

A similar problem occurs when an O ₂ sensor is used in place of the CO sensor to detect incomplete combustion of the burner. In general, if the indoor ventilation is not sufficient and the O ₂ concentration in the indoor air is reduced as a whole, the burner may cause incomplete combustion. For this reason, in order to ensure the safety of the user, it is preferable to stop the operation of the open-type combustion heating appliance when a decrease in O ₂ concentration is detected by the O ₂ sensor. However, it enters outside air contaminated from outside the chamber by the smoke of the exhaust gas and tobacco automotive and flows outside air comes into contact with the O ₂ sensor, there is a case where the O ₂ concentration detected by the O ₂ sensor is reduced . If the operation of the open-type combustion heating device is stopped up to such a case, the user's comfort is impaired.

The present invention was created in view of the above-described circumstances, and in an open type combustion heating apparatus that detects an abnormality with a gas sensor such as a CO sensor or an O ₂ sensor, erroneous detection due to an inflow of outside air into the room is detected. Provide technology to prevent.

  The open type combustion heating apparatus of the present invention heats a room by burning fuel with a burner. The open-type combustion heating apparatus includes a CO sensor that detects the CO concentration of indoor air, a room temperature sensor that detects the temperature of indoor air, and the CO concentration detected by the CO sensor during combustion of the burner is the first CO. Burner control means is provided for terminating burner combustion when the concentration threshold value is exceeded. The burner control means is characterized in that combustion of the burner is continued when the CO concentration detected by the CO sensor exceeds the first CO concentration threshold value and the temperature detected by the room temperature sensor decreases. To do.

  While the open-type combustion heating device is heating the room, the temperature of the room air does not drop so much unless cold air flows from the outside. The same applies if the burner burns incompletely. However, when cold air flows from the outside into the room, the temperature of the room air decreases. In the above open type combustion heating equipment, the burner is incomplete when the CO concentration detected by the CO sensor exceeds the first CO concentration threshold in a situation where the temperature detected by the room temperature sensor has not decreased. Since there is a possibility of causing combustion, the burner combustion is automatically terminated. By adopting such a configuration, it is possible to ensure the safety of the user even when the burner has caused incomplete combustion. Further, in the above-described open-type combustion heating appliance, when the temperature detected by the room temperature sensor is low and the CO concentration detected by the CO sensor exceeds the first CO concentration threshold value, Since it is considered that outside air containing CO has flowed in, the combustion of the burner is continued as it is. With such a configuration, when a door or window is opened and outside air flows into the room from the outside, and the CO sensor detects CO contained in the exhaust gas of an automobile or tobacco smoke in the outside air, Heating of the room can be continued without terminating the combustion. User comfort can be ensured.

  In the open-type combustion heating apparatus, the burner control means causes the burner to burn when the CO concentration detected by the CO sensor exceeds the first CO concentration threshold and the temperature detected by the room temperature sensor decreases. Even if it is continued, it is preferable to end the burner combustion when the CO concentration detected by the CO sensor exceeds the second CO concentration threshold.

  Even if the increase in the CO concentration detected by the CO sensor is caused by the inflow of outside air from the outdoors, if a considerably high CO concentration is detected, the burner burns in consideration of user safety. It is better to stop. According to said open type combustion heating apparatus, a user's safety | security can be ensured more highly.

  In the open-type combustion heating apparatus, the burner control means causes the burner to burn when the CO concentration detected by the CO sensor exceeds the first CO concentration threshold and the temperature detected by the room temperature sensor decreases. Even if it is continued, the burner combustion may be terminated if the CO concentration detected by the CO sensor does not decrease even after a predetermined time has elapsed after exceeding the first CO concentration threshold. preferable.

  Even if the increase in CO concentration detected by the CO sensor is due to the inflow of outside air from the outside, if high CO concentration is detected over a long period of time, the user's safety is considered. It is better to stop the combustion of the burner. According to said open type combustion heating apparatus, a user's safety | security can be ensured more highly.

Even when incomplete combustion of the burner is detected using an O ₂ sensor instead of the CO sensor, erroneous detection due to inflow of outside air into the room can be prevented based on the same concept. Another open-type combustion heating device of the present invention heats a room by burning fuel with a burner. Its open combustion heating device, and O ₂ sensor for detecting the O ₂ concentration in the indoor air, a temperature sensor for detecting the temperature of the room air, during combustion of the burner, O ₂ detected by the O ₂ sensor When the concentration falls below the first O ₂ concentration threshold, burner control means is provided for terminating burner combustion. The burner control means continues burning of the burner when the O ₂ concentration detected by the O ₂ sensor falls below the first O ₂ concentration threshold and the temperature detected by the room temperature sensor decreases. It is characterized by.

In the open-type combustion heating appliance, the burner control means is configured such that the O ₂ concentration detected by the O ₂ sensor falls below the first O ₂ concentration threshold value, and the temperature detected by the room temperature sensor is lowered. Even when the combustion is continued, it is preferable to terminate the burner combustion when the O ₂ concentration detected by the O ₂ sensor falls below the _second O ₂ concentration threshold.

In the open-type combustion heating appliance, the burner control means is configured such that the O ₂ concentration detected by the O ₂ sensor falls below the first O ₂ concentration threshold value, and the temperature detected by the room temperature sensor is lowered. Even when the combustion of the burner is continued, if the O ₂ concentration detected by the O ₂ sensor does not rise even after a predetermined time has elapsed after falling below the first O ₂ concentration threshold, End combustion.

According to the open type combustion heating apparatus of the present invention, it is possible to prevent erroneous detection due to the inflow of outside air into the room when performing abnormality detection using a gas sensor such as a CO sensor or an O ₂ sensor.

It is a longitudinal cross-sectional view which shows the structure of the gas fan heaters 2 and 50 of Example 1,2. It is a control block diagram of the gas fan heater 2 of Example 1. FIG. 3 is a flowchart illustrating a control operation of the gas fan heater 2 according to the first embodiment. It is a control block diagram of the gas fan heater 50 of Example 2. FIG. It is a flowchart which shows the control operation of the gas fan heater 50 of Example 2. FIG.

Example 1
A gas fan heater 2 according to an embodiment of an open type combustion heating apparatus will be described with reference to FIG. The gas fan heater 2 sucks air through the air supply port 4 on the back surface, burns the fuel gas using the sucked air as combustion air, and blows out the air heated by the combustion of the fuel gas from the air outlet 6 on the front surface. Then, heat the room.

  The gas fan heater 2 sucks indoor air from a gas supply pipe 8 that supplies fuel gas, a burner 10 that burns fuel gas from the gas supply pipe 8, and an air supply port 4, and blows out the heated air 6 includes a blower fan 12 that blows into the room, a control unit 14 that controls the operation of the gas fan heater 2, an operation unit 16 that allows the user to operate the gas fan heater 2, and a casing 18 that houses these. ing.

  The air supply port 4 is formed on the upper side of the back surface of the casing 18, and the air outlet 6 is formed on the lower side of the front surface of the casing 18. Inside the casing 18, an internal air passage that supplies a part of the air flowing in from the air supply port 4 as combustion air to the burner 10 and leads the remaining air to the outlet 6 while being mixed with the combustion gas of the burner 10. 20 is formed. The blower fan 12 is disposed in the vicinity of the air outlet 6 in the internal air passage 20. The air supply port 4 is provided with an air filter 22 that suppresses entry of dust and the like.

  The gas supply pipe 8 is provided with an electromagnetic on-off valve 24 that opens and closes the gas supply pipe 8 and a proportional valve 26 that adjusts the flow rate of the gas flowing through the gas supply pipe 8. The gas supply pipe 8 is supplied with city gas (for example, gas mainly composed of methane gas (CH 4) such as 13A) from the outside of the gas fan heater 2. The burner 10 is provided with an igniter 28 above the flame opening.

  A room temperature sensor 30 and a CO sensor 32 are provided on the back surface of the casing 18. The room temperature sensor 30 detects the temperature of indoor air sucked into the casing 18 from the air supply port 4. As the room temperature sensor 30, various types such as a thermocouple and a thermistor can be used.

  The CO sensor 32 detects the CO concentration in the indoor air sucked into the casing 18 from the air supply port 4. As the CO sensor 32, various types such as a semiconductor type, a catalytic combustion type, and an electrochemical type can be used.

  As shown in FIG. 2, the operation unit 16 includes an operation switch 34 that instructs the user to start and stop the operation of the gas fan heater 2, an abnormality notification buzzer 36 that notifies the user of the occurrence of an abnormality, and a heating target temperature. A temperature setting unit 38 to be set, a display unit 40 for displaying various information such as a heating target temperature and a room temperature are provided. The operation switch 34 is configured to alternately instruct the control unit 14 to start and stop operation each time the pressing operation is repeated.

  The control unit 14 controls operations of the blower fan 12, the on-off valve 24, the proportional valve 26, the igniter 28, and the like. When the user operates the operation switch 34 and the operation start of the gas fan heater 2 is instructed, the control unit 14 rotates the blower fan 12 to supply combustion air to the burner 10. Further, the control unit 14 opens the on-off valve 24, supplies gas to the burner 10 from the gas supply pipe 8, and ignites the igniter 28 to start combustion of the burner 10. During combustion of the burner 10, the controller 14 controls the opening of the proportional valve 26 and the air flow so that the temperature of the indoor air detected by the room temperature sensor 30 quickly approaches the heating target temperature set by the temperature setting unit 38. The rotational speed of the fan 12 is adjusted. When the user operates the operation switch 34 during the operation of the gas fan heater 2 and is instructed to stop the operation of the gas fan heater 2, the control unit 14 closes the on-off valve 24 and opens the burner 10 from the gas supply pipe 8. The combustion of the burner 10 is terminated by shutting off the supply of gas. Further, the control unit 14 stops the rotation of the blower fan 12.

  When the gas fan heater 2 starts operation, the control unit 14 performs a CO concentration abnormality detection process shown in FIG. The control unit 14 includes a memory 42 and a timer 44 for a CO concentration abnormality detection process to be described later.

  In step S302, sampling at room temperature is started. In the gas fan heater 2 of the present embodiment, the detection value of the room temperature sensor 30 is fetched every 15 seconds, and the time series of room temperature for the past 2 minutes is stored in the memory 42.

  In step S304, it is determined whether or not the CO concentration Cx detected by the CO sensor 32 exceeds the first CO concentration threshold C1. The first CO concentration threshold C1 is set to a value (for example, 5 ppm) that is higher than the CO concentration detected in a normal room. When the CO concentration Cx detected by the CO sensor 32 is equal to or lower than the first CO concentration threshold C1 (NO in step S304), the CO concentration in the indoor air is low, and it is considered that there is no abnormality. Monitoring of the CO concentration Cx is continued in step S304 without proceeding to step S306 and subsequent steps. If the CO concentration Cx detected by the CO sensor 32 exceeds the first CO concentration threshold C1 (YES in step S304), the process proceeds to step S306.

  In step S306, it is determined whether or not the room temperature has rapidly decreased. In general, the CO concentration detected by the CO sensor 32 rises not only when the burner 10 causes incomplete combustion, but also when outside air containing CO flows into the room. When the burner 10 undergoes incomplete combustion, the CO concentration increases, but the room temperature does not vary greatly. On the other hand, when outside air containing CO flows into the room, cold outside air is mixed into the room air being heated, and the room temperature rapidly decreases as the CO concentration increases. Therefore, in the gas fan heater 2 of the present embodiment, when the CO concentration detected by the CO sensor 32 increases and the room temperature detected by the room temperature sensor 30 rapidly decreases, the burner 10 causes incomplete combustion. Instead, it is determined that the outside air containing CO has flowed into the room, and the operation is continued without immediately stopping the operation due to the abnormality detection. When the CO concentration detected by the CO sensor 32 increases and the room temperature detected by the room temperature sensor 30 does not drop rapidly, the burner 10 may be incompletely burned. 2 stops operation due to abnormality detection.

  The determination in step S306 as to whether or not the room temperature has suddenly decreased is made based on the time series of the room temperature stored in the memory 42. In the present embodiment, when the latest room temperature T1 stored in the memory 42 is lower than a temperature obtained by subtracting a predetermined temperature range (for example, 2 ° C.) from the room temperature T0 two minutes before that, the room temperature rapidly decreases. Judge. In other words, when the rate of change of room temperature with respect to time is below a predetermined temperature change rate, it is determined that the room temperature has rapidly dropped. If it is determined in step S306 that the room temperature has not suddenly decreased (in the case of NO), the process proceeds to step S318, and operation is stopped due to detection of abnormal CO concentration. If it is determined in step S306 that the room temperature has suddenly decreased (YES), the process proceeds to step S308.

  In step S308, the timer 44 starts counting. In this embodiment, the count time by the timer 44 is set to 2 minutes.

  In step S310, the user is notified that high-concentration CO has been detected. The control unit 14 causes the display unit 40 to display that high-concentration CO has been detected, and causes the abnormality notification buzzer 36 to output a sound indicating that high-concentration CO has been detected. In step S310, the user is only notified that high-concentration CO has been detected, and the operation of the gas fan heater 2 is continued.

  In step S312, it is determined whether or not the CO concentration Cx detected by the CO sensor 32 exceeds the second CO concentration threshold C2. The second CO concentration threshold C2 is set to a value (for example, 50 ppm) higher than the first CO concentration threshold C1. When the CO concentration Cx exceeds the second CO concentration threshold value C2 (in the case of YES), in order to ensure the safety of the user, the process proceeds to step S318, and the operation is stopped by detecting the abnormality of the CO concentration. If the CO concentration is less than or equal to the second CO concentration threshold C2 (NO in step S312), the process proceeds to step S314.

  In step S314, it is determined whether or not the CO concentration Cx detected by the CO sensor 32 is lower than the third CO concentration threshold C3. The third CO concentration threshold C3 is set to a value (for example, 3 ppm) lower than the first CO concentration threshold C1. When the CO concentration Cx is lower than the third CO concentration threshold C3 (in the case of YES), although a high CO concentration is once detected in step S304, the CO concentration returns to a low level again after that, so that it is used. It is determined that the safety of the person is secured, and the process returns to step S304. If the CO concentration Cx is equal to or greater than the third CO concentration threshold C3 (NO in step S314), the process proceeds to step S316.

  In step S316, it is determined whether the timer 44 has finished counting. In step S316, it is determined that the timer 44 has finished counting because the CO concentration Cx does not fall below the third CO concentration threshold C3 after the CO concentration Cx exceeds the first CO concentration threshold C1. This is a case where the count time set to 44 (2 minutes in this embodiment) has elapsed. If the timer 44 has not finished counting (NO in step S316), the process returns to step S312. When the count of the timer 44 is completed in step S316 (in the case of YES), in order to ensure the safety of the user, the process proceeds to step S318, and the operation is stopped by detecting the abnormal CO concentration.

  In step S318, an operation stop process is performed by detecting an abnormality in the CO concentration. The control unit 14 closes the on-off valve 24 to end the combustion of the burner 10 and stops the rotation of the blower fan 12. In addition, the control unit 14 causes the display unit 40 to display that the operation has been stopped due to the abnormal detection of the CO concentration, and causes the abnormality notification buzzer 36 to output a sound indicating that the operation has been stopped due to the abnormal detection of the CO concentration. .

  According to the gas fan heater 2 of the present embodiment, when the CO concentration detected by the CO sensor 32 is increased in a situation where the room temperature detected by the room temperature sensor 30 is not rapidly decreasing, the user is informed of the CO concentration. Abnormality detection is notified, combustion of the burner 10 is automatically terminated, and the operation of the gas fan heater 2 is automatically stopped. By adopting such a configuration, even if the burner 10 has caused incomplete combustion, the safety of the user can be ensured.

  According to the gas fan heater 2 of the present embodiment, in a situation where the room temperature detected by the room temperature sensor 30 is rapidly decreasing, if the CO concentration detected by the CO sensor 32 increases, a high concentration is given to the user. However, the operation of the gas fan heater 2 is continued as it is. With such a configuration, when the door or window is opened and outside air flows from the outside into the room, and the CO sensor 32 detects CO contained in the exhaust gas or cigarette smoke in the outside air, Indoor heating can be continued without stopping the operation of the gas fan heater 2. User comfort can be ensured.

  According to the gas fan heater 2 of the present embodiment, the CO concentration detected by the CO sensor 32 is increased, and the room temperature detected by the room temperature sensor 30 is rapidly decreased, so that the operation of the gas fan heater 2 is stopped. If the CO concentration does not decrease even after a predetermined time has elapsed, the user is notified of the abnormal detection of the CO concentration and the combustion of the burner 10 is automatically terminated. The operation of the gas fan heater 2 is automatically stopped. With such a configuration, the safety of the user can be ensured.

  According to the gas fan heater 2 of the present embodiment, the CO concentration detected by the CO sensor 32 is increased, and the room temperature detected by the room temperature sensor 30 is rapidly decreased, so that the operation of the gas fan heater 2 is stopped. Even if the operation is continued as it is, if a very high concentration of CO exceeding the second CO concentration threshold C2 is detected, the user is notified of the abnormal detection of the CO concentration and the burner 10 is automatically burned. The operation of the gas fan heater 2 is automatically stopped. With such a configuration, the safety of the user can be ensured.

  Note that the determination of whether or not the room temperature has suddenly decreased in step S306 can also be determined by other methods. For example, after a certain amount of time has elapsed since the gas fan heater 2 started operation, the indoor air is warmed to the heating target temperature. Therefore, after a certain amount of time has elapsed since the gas fan heater 2 started operation, the latest room temperature T1 stored in the memory 42 (or the room temperature sensor 30 at the time of step S306) is detected in step S306. Control unit 14 so as to determine that the room temperature has suddenly decreased when the predetermined temperature width (for example, 2 ° C.) is subtracted from the heating target temperature set by the temperature setting unit 38. May be configured. Alternatively, the room temperature when the gas fan heater 2 starts operation (that is, the temperature of indoor air that has not been heated yet and is as cold as the outside) is detected by the room temperature sensor 30 and stored in the memory 42. If the room temperature detected by the room temperature sensor 30 is lower than a temperature obtained by adding a predetermined temperature range (for example, 2 ° C.) to the room temperature at the start of operation of the gas fan heater 2, the room temperature has suddenly decreased. The control unit 14 may be configured to determine.

(Example 2)
The gas fan heater 50 of the present embodiment has substantially the same configuration as the gas fan heater 2 of the first embodiment shown in FIG. The gas fan heater 50 includes an O ₂ sensor 52 instead of the CO sensor 32 in the gas fan heater 2 of the first embodiment.

The O ₂ sensor 52 is provided on the back surface of the casing 18 and detects the O ₂ concentration in the indoor air sucked into the casing 18 from the air supply port 4. As the O ₂ sensor 52, various types such as a galvanic cell type, a polar cell type, and a diffusion current type can be used.

When the gas fan heater 2 starts operation, the controller 14 performs an O ₂ concentration abnormality detection process. Hereinafter, the O ₂ concentration abnormality detection process will be described with reference to FIG.

  In step S502, sampling at room temperature is started. In the gas fan heater 50 of the present embodiment, the detection value of the room temperature sensor 30 is taken every 15 seconds, and the time series of the room temperature for the past 2 minutes is stored in the memory 42.

In step S504, it is determined whether the O ₂ concentration Dx detected by the O ₂ sensor 52 is below a first O ₂ concentration threshold D1. The first O ₂ concentration threshold D1 is set to a value (for example, 18%) lower than the O ₂ concentration normally detected in the room. O ₂ when the _{O 2} concentration Dx detected by the sensor 52 of the above first 1O ₂ concentration threshold D1 (NO in step S504), the abnormality is considered not to _{O 2} concentration in the room air Therefore, monitoring of the O ₂ concentration Dx is continued in step S504 without proceeding to step S506 and subsequent steps. _{O 2} concentration Dx detected by the O ₂ sensor 52 in the case below the second 1O ₂ concentration threshold D1 (YES in step S504), the process proceeds to step S506.

In step S506, based on the time series of room temperature stored in the memory 42, it is determined whether or not the room temperature has suddenly decreased. If it is determined in step S506 that the room temperature has not suddenly decreased (in the case of NO), the process proceeds to step S518, and the operation is stopped by detecting an abnormality in the O ₂ concentration. If it is determined in step S506 that the room temperature has suddenly decreased (YES), the process proceeds to step S508.

  In step S508, the timer 44 starts counting. In this embodiment, the count time by the timer 44 is set to 2 minutes.

In step S510, the user is notified that a decrease in O ₂ concentration has been detected. The control unit 14 causes the display unit 40 to display that a decrease in O ₂ concentration has been detected, and causes the abnormality notification buzzer 36 to output a sound indicating that a decrease in O ₂ concentration has been detected. In step S510, the user is only notified that the decrease in O ₂ concentration has been detected, and the operation of the gas fan heater 2 is continued.

In step S512, it is determined whether or not the O ₂ concentration Dx detected by the O ₂ sensor 52 is lower than the _second O ₂ concentration threshold D2. The _second O ₂ concentration threshold D2 is set to a value (for example, 17.5%) lower than the first O ₂ concentration threshold D1. When the O ₂ concentration Dx is lower than the _second O ₂ concentration threshold D2 (in the case of YES), in order to ensure the safety of the user, the process proceeds to step S518, and the operation is stopped due to the abnormal detection of the O ₂ concentration. Do. If the O ₂ concentration is greater than or equal to the _second O ₂ concentration threshold D2 (NO in step S512), the process proceeds to step S514.

In step S514, it is determined whether or not the O ₂ concentration Dx detected by the O ₂ sensor 52 exceeds the third O ₂ concentration threshold value D3. The third O ₂ concentration threshold D3 is set to a value (for example, 18.5%) higher than the first O ₂ concentration threshold D1. If the O ₂ concentration Dx exceeds the first. 3O ₂ concentration threshold D3 (the case of YES), although once low _{O 2} concentration detected in step S504, after which the _{O 2} concentration back to high level again Therefore, it is determined that the safety of the user is ensured, and the process returns to step S504. O ₂ concentration Dx is the case of the following first. 3O ₂ concentration threshold D3 (NO in step S514), the process proceeds to step S516.

In step S516, it is determined whether the timer 44 has finished counting. In step S516, it is determined that the timer 44 has finished counting after the O ₂ concentration Dx exceeds the first O ₂ concentration threshold D1, and the O ₂ concentration Dx falls below the third O ₂ concentration threshold D3. In this case, the count time set in the timer 44 (2 minutes in this embodiment) has elapsed. If the timer 44 has not finished counting (NO in step S516), the process returns to step S512. When the count of the timer 44 is completed in step S516 (in the case of YES), in order to ensure the safety of the user, the process proceeds to step S518, and the operation is stopped by detecting the abnormality in O ₂ concentration.

In step S518, an operation stop process is performed by detecting an abnormality in the O ₂ concentration. The control unit 14 closes the on-off valve 24 to end the combustion of the burner 10 and stops the rotation of the blower fan 12. Further, the control unit 14 causes the display unit 40 to display that the operation has been stopped due to the abnormality detection of the O ₂ concentration, and the abnormality notification buzzer 36 has a sound indicating that the operation has been stopped due to the abnormality detection of the O ₂ concentration. Output.

According to the gas fan heater 50 of the present embodiment, when the O ₂ concentration detected by the O ₂ sensor 52 is reduced in a situation where the room temperature detected by the room temperature sensor 30 is not rapidly decreasing, the user is notified of O _{The two-} concentration abnormality detection is notified, the combustion of the burner 10 is automatically terminated, and the operation of the gas fan heater 2 is automatically stopped. By adopting such a configuration, even if the burner 10 has caused incomplete combustion, the safety of the user can be ensured.

According to the gas fan heater 2 of the present embodiment, when the O ₂ concentration detected by the O ₂ sensor 52 decreases in a situation where the room temperature detected by the room temperature sensor 30 is rapidly decreasing, the user is notified. The operation of the gas fan heater 2 is continued as it is although it is notified that the decrease in the O ₂ concentration has been detected. With such a configuration, outside air contaminated with automobile exhaust gas or cigarette smoke enters the room from the outside, and the inflowing outside air contacts the O ₂ sensor, and a decrease in O ₂ concentration is detected. In some cases, the room heating can be continued without stopping the operation of the gas fan heater 2. User comfort can be ensured.

  Specific examples of the present invention have been described in detail above, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above.

  For example, in the above-described embodiment, the gas fan heater is illustrated as an embodiment of the open type combustion heating apparatus. There may be.

  The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology illustrated in the present specification or the drawings achieves a plurality of objects at the same time, and has technical utility by achieving one of the objects.

2,50 Gas fan heater; 4 Air supply port; 6 Air outlet; 8 Gas supply pipe; 10 Burner; 12 Blower fan; 14 Control unit; 16 Operation unit; 18 Casing; 20 Internal air passage; 22 Air filter; 26 Proportional valve; 28 Igniter; 30 Room temperature sensor; 32 CO sensor; 34 Operation switch; 36 Abnormal alarm buzzer; 38 Temperature setting section; 40 Display section; 42 Memory; 44 Timer; 52 O ₂ sensor

Claims (6)

An open type combustion heating device that heats the room by burning fuel with a burner,
A CO sensor for detecting the CO concentration of indoor air;
A room temperature sensor for detecting the temperature of indoor air;
Burner control means for terminating burner combustion when the CO concentration detected by the CO sensor exceeds the first CO concentration threshold during combustion of the burner,
The burner control means continues burning of the burner when the CO concentration detected by the CO sensor exceeds a first CO concentration threshold value and the temperature detected by the room temperature sensor decreases. Open-type combustion heating equipment.   In the case where the burner control means continues the combustion of the burner when the CO concentration detected by the CO sensor exceeds the first CO concentration threshold value and the temperature detected by the room temperature sensor decreases. The open-type combustion heating appliance according to claim 1, wherein when the CO concentration detected by the CO sensor exceeds a second CO concentration threshold value, combustion of the burner is terminated.   In the case where the burner control means continues the combustion of the burner when the CO concentration detected by the CO sensor exceeds the first CO concentration threshold value and the temperature detected by the room temperature sensor decreases. The combustion of the burner is terminated when the CO concentration detected by the CO sensor does not decrease even if a predetermined time elapses after the first CO concentration threshold value is exceeded. Open type combustion heating equipment. An open type combustion heating device that heats the room by burning fuel with a burner,
An O ₂ sensor for detecting the O ₂ concentration of indoor air;
A temperature sensor for detecting the temperature of indoor air;
Burner control means for terminating burner combustion when the O ₂ concentration detected by the O ₂ sensor falls below the first O ₂ concentration threshold during combustion of the burner;
The burner control means continues burning of the burner when the O ₂ concentration detected by the O ₂ sensor falls below the first O ₂ concentration threshold and the temperature detected by the room temperature sensor decreases. An open-type combustion heating device. When the burner control means continues the combustion of the burner when the O ₂ concentration detected by the O ₂ sensor falls below the first O ₂ concentration threshold and the temperature detected by the room temperature sensor has dropped. Even so, when the O ₂ concentration detected by the O ₂ sensor falls below the _second O ₂ concentration threshold, combustion of the burner is terminated. When the burner control means continues the combustion of the burner when the O ₂ concentration detected by the O ₂ sensor falls below the first O ₂ concentration threshold and the temperature detected by the room temperature sensor has dropped. However, the burner combustion is terminated when the O ₂ concentration detected by the O ₂ sensor does not increase even after a predetermined period of time has passed after the first O ₂ concentration threshold value has fallen below. The open-type combustion heating equipment according to claim 4 or 5.

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