JP6819344B2 - Environmental monitoring device - Google Patents

Description

The present invention relates to an environmental monitoring device.

As an environmental monitoring device, an outdoor unit and an indoor unit are provided, and the outdoor unit and the indoor unit are connected by piping to detect leakage of the refrigerant inside the outdoor unit in a heat pump system using a flammable refrigerant as the refrigerant. Those equipped with a gas sensor are known. It is also known that low-concentration gas detection is possible by using a semiconductor gas sensor as the gas sensor (see, for example, Patent Document 1).

JP-A-2002-115939

However, when a semiconductor gas sensor is used as the gas sensor in the environmental monitoring device as shown in Patent Document 1, as described in Patent Document 1, a metal oxide is used to make the refrigerant detectable. It is necessary to preheat (gas sensor material). Therefore, if the sensor continues to be able to detect the refrigerant for a long period of time, the gas-sensitive material that has been continuously heated to a high temperature is altered by oxidation or miscellaneous gas such as silicon, and the accuracy and reliability of the sensor deteriorate. There is a possibility that it will end up. As a result, the life of the sensor is shortened, and the frequency of sensor replacement increases. On the other hand, if the heating of the sensor can be stopped, there is a risk of forgetting to restart the heating of the sensor when it is necessary to keep the sensor running.

The present invention has been made to solve such a problem. The purpose is to enable the sensor to detect the refrigerant when necessary in an environmental monitoring device using a sensor that needs to supply electric power to the sensor in order to make the refrigerant detectable. The purpose of the present invention is to obtain an environmental monitoring device capable of extending the life of the sensor and suppressing the frequent replacement of the sensor unit.

The environmental monitoring device according to the present invention includes a sensor unit for detecting a refrigerant, a power supply unit for supplying sensor driving power for enabling the sensor unit to detect the refrigerant, and the sensor. The sensor position detecting means includes a sensor position detecting means for detecting that the unit is in a preset sensor effective position, and the power supply unit detects that the sensor unit is in the sensor effective position. When the sensor drive power is supplied to the sensor unit, and when the sensor position detecting means does not detect that the sensor unit is in the sensor effective position, the sensor drive power is supplied to the sensor unit. It doesn't.

The environmental monitoring device according to the present invention uses a sensor that needs to supply electric power to the sensor in order to make the refrigerant in a detectable state, and the sensor can detect the refrigerant when necessary. In addition to this, the life of the sensor can be extended, and it is possible to suppress an increase in the frequency of replacement of the sensor unit.

It is sectional drawing which shows typically the structure of the room to which the environment monitoring apparatus which concerns on Embodiment 1 of this invention is applied. It is a figure which shows typically the state which the sensor part of the environment monitoring apparatus which concerns on Embodiment 1 of this invention is in a sensor effective position. It is a figure which shows typically the state which the sensor part of the environment monitoring apparatus which concerns on Embodiment 1 of this invention is not in a sensor effective position. It is a figure which shows typically the structure of the filter of the environment monitoring apparatus which concerns on Embodiment 1 of this invention. It is a figure which shows typically the structure of the environment monitoring apparatus which concerns on Embodiment 2 of this invention. It is a figure which shows typically the state which the sensor part of the environment monitoring apparatus which concerns on Embodiment 3 of this invention is not in a sensor effective position. It is a figure which shows typically the state which the sensor part of the environment monitoring apparatus which concerns on Embodiment 3 of this invention is in a sensor effective position. It is a figure which shows typically the state which the sensor part of the environment monitoring apparatus which concerns on Embodiment 4 of this invention is not in a sensor effective position. It is a figure which shows typically the state which the sensor part of the environment monitoring apparatus which concerns on Embodiment 4 of this invention is in a sensor effective position. It is a figure which shows typically the state which the sensor part of the environment monitoring apparatus which concerns on Embodiment 5 of this invention is not in a sensor effective position. It is a figure which shows typically the state which the sensor part of the environment monitoring apparatus which concerns on Embodiment 5 of this invention is in a sensor effective position. It is a figure which shows typically the state in which the sensor part of the environment monitoring apparatus which concerns on Embodiment 5 of this invention is in the process of entering and exiting a sensor effective position.

A mode for carrying out the present invention will be described with reference to the accompanying drawings. In each figure, the same or corresponding parts are designated by the same reference numerals, and duplicate description will be appropriately simplified or omitted. The present invention is not limited to the following embodiments, and various modifications can be made without departing from the spirit of the present invention.

Embodiment 1.
1 to 4 relate to the first embodiment of the present invention, FIG. 1 is a cross-sectional view schematically showing a configuration of a room to which an environmental monitoring device is applied, and FIG. 2 shows a sensor unit of the environmental monitoring device. A diagram schematically showing a state in which the sensor is in an effective position, FIG. 3 is a diagram schematically showing a state in which the sensor unit of the environment monitoring device is not in the sensor effective position, and FIG. 4 is a diagram schematically showing a filter configuration of the environment monitoring device. It is a figure which shows.

As shown in FIG. 1, an outdoor unit 20 and an indoor unit 30 of an air conditioner are installed in a room 10 to which the environmental monitoring device according to the first embodiment of the present invention is applied. The outdoor unit 20 is installed outside the outer wall 11 of the room 10. The indoor unit 30 is fixed at a position closer to the upper side of, for example, the inner wall 12 of the room 10. In this way, the indoor unit 30 is installed inside the room 10 to be air-conditioned, and the outdoor unit 20 is installed outside the room.

The outdoor unit 20 includes an outdoor unit heat exchanger 21, an outdoor unit fan 22, and a compressor 23. The indoor unit 30 includes an indoor unit heat exchanger 31 and an indoor unit fan 32. The indoor unit 30 and the outdoor unit 20 are connected by a refrigerant pipe 40. The refrigerant pipe 40 is provided so as to circulate between the indoor unit heat exchanger 31 and the outdoor unit heat exchanger 21. Refrigerant is sealed in the refrigerant pipe 40.

From the viewpoint of protecting the global environment, it is desirable to use a refrigerant having a small global warming potential (GWP) as the refrigerant sealed in the refrigerant pipe 40. The refrigerant sealed in the refrigerant pipe 40 is a flammable gas. This refrigerant has a larger average molecular weight than air (specific gravity to air is larger than 1), and has the property of sinking downward in the direction of gravity in air.

Specific examples of such a refrigerant include difluoromethane (CH2F2: R32), tetrafluoropropane (CF3CF = CH2: HFO-1234yf), propane (R290), propylene (R1270), ethane (R170), and butane (R600). ), Isobutane (R600a), 1.1.1.2-Tetrafluoroethane (C2H2F4: R134a), Pentafluoroethane (C2HF5: R125), 1.3.3.3-Tetrafluoro-1-propene (CF3-). A (mixed) refrigerant composed of one or more refrigerants selected from CH = CHF: HFO-1234ze) and the like can be used.

The compressor 23 is provided on one side of the refrigerant circulation path between the indoor unit heat exchanger 31 and the outdoor unit heat exchanger 21. The compressor 23 is a device that compresses the supplied refrigerant to increase the pressure and temperature of the refrigerant. Although not shown here, an expansion valve is provided on the other side of the circulation path. The expansion valve expands the inflowing refrigerant and reduces the pressure of the refrigerant. Then, the refrigerant circulation path formed by the refrigerant pipe 40 and the indoor unit heat exchanger 31, the outdoor unit heat exchanger 21, the four-way valve, the compressor 23 and the expansion connected by the refrigerant pipe 40 on the circulation path. A refrigeration cycle (refrigerant circuit) is configured by the valves.

The refrigeration cycle configured in this way is between the indoor unit 30 and the outdoor unit 20 by exchanging heat between the refrigerant and the air in each of the indoor unit heat exchanger 31 and the outdoor unit heat exchanger 21. Works as a heat pump to transfer heat. At this time, by switching the four-way valve, the circulation direction of the refrigerant in the refrigeration cycle can be reversed to switch between the cooling operation and the heating operation.

The environment monitoring device main body 100 is installed in the room 10 in which the indoor unit 30 of the air conditioner is installed. The configuration of the environment monitoring device main body 100 will be described with reference to FIGS. 2 and 3. The environment monitoring device main body 100 includes a sensor unit 110 and a power supply unit 120. The sensor unit 110 is for detecting the refrigerant.

The sensor unit 110 outputs a detection signal according to the concentration of the same type of refrigerant as that enclosed in the refrigerant pipe 40. Specifically, for example, the sensor unit 110 outputs a detection signal of a voltage proportional to the concentration of the refrigerant. Alternatively, the sensor unit 110 outputs a detection signal when the concentration of the refrigerant is equal to or higher than a predetermined reference value. The detection signal output from the sensor unit 110 is transmitted to, for example, the environment monitoring device main body 100 by a wired method or a wireless method.

Here, the sensor unit 110 is, for example, a semiconductor type sensor. The sensor unit 110, which is a semiconductor sensor, includes a gas-sensitive material such as tin oxide provided on an insulating substrate such as alumina. Further, the sensor unit 110 further includes a heater provided on the lower surface of the insulating substrate. These gas-sensitive materials and heaters are housed in the sensor case 111 of the sensor unit 110. In order for the sensor unit 110 to be able to detect the refrigerant, it is necessary to energize the heater to heat the gas-sensitive material to 300 ° C. to 450 ° C.

The power supply unit 120 is for supplying electric power to energize the heater of the sensor unit 110. The power supply unit 120 and the sensor unit 110 are electrically connected by a power supply line 121. The electric power supplied from the power supply unit 120 to the sensor unit 110 through the power supply line 121 is energized to the heater of the sensor unit 110. When the heater is energized, the gas-sensitive material of the sensor unit 110 is heated, and the sensor unit 110 is in a state where it can detect the refrigerant. In this way, the power supply unit 120 supplies the sensor drive power to the sensor unit 110 so that the sensor unit 110 can detect the refrigerant.

A sensor accommodating portion 101 is formed in the housing of the environment monitoring device main body 100. The sensor accommodating unit 101 accommodates the sensor unit 110 so that it can be taken in and out.

A contact portion 131 is provided in the middle portion of the power line 121. The contact portion 131 can take two states, a closed state and an open state. When the contact portion 131 is closed, power is supplied from the power supply unit 120 to the sensor unit 110 through the power supply line 121. When the contact unit 131 is open, the power supply from the power supply unit 120 to the sensor unit 110 is stopped.

The contact portion 131 is configured such that, for example, the contact portion 131 itself is made of a leaf spring and is normally closed by the urging force of the leaf spring. That is, the contact portion 131 is a normally closed contact. Therefore, as shown in FIG. 2, the contact portion 131 is closed when the sensor portion 110 is not accommodated in the sensor accommodating portion 101. Therefore, at this time, power is supplied from the power supply unit 120 to the sensor unit 110.

On the other hand, as shown in FIG. 3, when the sensor unit 110 is housed in the sensor housing unit 101, a part of the sensor unit 110, for example, the terminal portion to which the power supply line 121 is connected is the urging force of the spring of the contact portion 131. The contact portion 131 is pushed against the above. When the contact portion 131 is pushed, the contact portion 131 is opened. Therefore, when the sensor unit 110 is housed in the sensor housing unit 101, power is not supplied from the power supply unit 120 to the sensor unit 110.

In the example described in the first embodiment, the region outside the sensor accommodating portion 101 is set to the sensor effective position. Therefore, in the state of FIG. 2 in which the sensor unit 110 is not housed in the sensor housing unit 101, the sensor unit 110 is in the sensor effective position. Then, when the sensor unit 110 is in the sensor effective position, the power supply unit 120 supplies the sensor drive power to the sensor unit 110. Therefore, when the sensor unit 110 is in the sensor effective position, the sensor unit 110 is in a state where the refrigerant can be detected.

On the other hand, in the state of FIG. 3 in which the sensor unit 110 is housed in the sensor housing unit 101, the sensor unit 110 is not in the sensor effective position. Then, when the sensor unit 110 is not in the sensor effective position, the power supply unit 120 does not supply the sensor drive power to the sensor unit 110. Therefore, when the sensor unit 110 is not in the effective position of the sensor, the sensor unit 110 is not in a state where the refrigerant can be detected.

In this way, the contact portion 131 in the first embodiment constitutes a sensor position detecting means for detecting that the sensor portion 110 is in the preset effective sensor position. Then, the power supply unit 120 supplies the sensor drive power to the sensor unit 110 when the sensor position detecting means detects that the sensor unit 110 is in the sensor effective position. Further, when the sensor position detecting means does not detect that the sensor unit 110 is in the sensor effective position, the power supply unit 120 does not supply the sensor driving power to the sensor unit 110.

When using the air conditioner including the outdoor unit 20 and the indoor unit 30 in the environment monitoring device configured as described above, the user uses the sensor unit 101 to the sensor unit 110 of the environment monitoring device main body 100. Take it out. Then, the user arranges the taken-out sensor unit 110 at a position suitable for detecting the refrigerant leaked from the refrigerant pipe 40 of the outdoor unit 20 or the indoor unit 30. That is, the sensor unit 110 is moved to the sensor effective position.

Then, as described above, the power supply unit 120 supplies the sensor drive power to the sensor unit 110. Therefore, the user can bring the sensor unit 110 out of the sensor accommodating unit 101 and place it at a desired position so that the sensor unit 110 can detect the refrigerant. When the specific gravity of the refrigerant with respect to air is larger than 1, the leaked refrigerant flows downward from the indoor unit 30. Therefore, it is preferable to arrange the sensor unit 110 vertically below the indoor unit 30.

On the other hand, when it is not necessary to keep the sensor unit 110 in operation, for example, when the air conditioner is not used for a long period of time, the user accommodates the sensor unit 110 in the sensor accommodating unit 101 of the environment monitoring device main body 100. .. That is, the sensor unit 110 is moved to a place other than the effective sensor position. Then, as described above, the power supply unit 120 stops the supply of the sensor drive power to the sensor unit 110.

As described above, when a semiconductor sensor is used for the sensor unit 110, it is necessary to heat the gas-sensitive material to 300 ° C. to 450 ° C. with a heater in order to make the refrigerant detectable. Therefore, if the sensor unit 110 continues to be able to detect the refrigerant for a long period of time, the gas-sensitive material that has been continuously heated to a high temperature is altered by oxidation or miscellaneous gas such as silicon, and the accuracy and reliability of the sensor are lowered. There is a possibility that it will be done. As a result, the life of the sensor unit 110 is shortened, and the frequency of replacement of the sensor unit 110 is increased.

On the other hand, in the environment monitoring device configured as described above, when it is not necessary to keep the sensor unit 110 in operation, the sensor unit 110 is moved to a place other than the sensor effective position, that is, the sensor unit 110 is moved. By accommodating in the sensor accommodating unit 101, the energization of the sensor unit 110 is automatically stopped. Therefore, the life of the sensor unit 110 can be extended, and it is possible to prevent the sensor unit 110 from being replaced frequently. Further, since it is not necessary to put out the sensor unit 110 in the room 10, the scenery in the room 10 can be improved.

Then, when it is necessary to keep the sensor unit 110 in operation, the sensor unit 110 is moved to the sensor effective position, that is, the sensor unit 110 is taken out from the sensor accommodating unit 101 to automatically move to the sensor unit 110. Energization is started. Therefore, when it is necessary to keep the sensor unit 110 in operation, it is possible to ensure that the sensor unit 110 can detect the refrigerant without forgetting to supply the sensor drive power to the sensor unit 110. Is.

As shown in FIG. 4, the environment monitoring device main body 100 may be provided with the filter 102. Here, the filter 102 is provided inside the sensor accommodating portion 101 of the environment monitoring device main body 100. The filter 102 has a function of adsorbing a solvent such as alcohol and a miscellaneous gas component such as silicon. The filter 102 attracts and removes these substances that have entered the sensor accommodating unit 101 from the outside, and prevents these substances from reaching the sensor unit 110 housed in the sensor accommodating unit 101.

By doing so, it is possible to prevent the sensor unit 110 housed in the sensor housing unit 101 from coming into contact with the solvent and miscellaneous gas. Therefore, it can be expected that the life of the sensor unit 110 will be further extended.

The power supply unit 120 secures the sensor drive power to be supplied to the sensor unit 110 from, for example, a commercial power source. Alternatively, a battery may be built in the power supply unit 120, and the sensor drive power may be secured from the built-in battery.

As described above, the sensor unit 110 outputs a detection signal according to the concentration of the refrigerant. Then, the environment monitoring device main body 100 drives, for example, the indoor unit fan 32 of the indoor unit 30 in response to the detection signal from the sensor unit 110. Specifically, when the detection signal from the sensor unit 110 indicates the detection of the leakage of the refrigerant, the indoor unit 30 drives the indoor unit fan 32. In particular, as described above, when the specific gravity of the refrigerant with respect to air is larger than 1, the refrigerant leaked into the room 10 tends to accumulate vertically downward and a portion having a high refrigerant concentration is likely to occur.

Therefore, in the environment monitoring device according to the first embodiment of the present invention, the indoor unit fan 32 is driven in response to the detection signal from the sensor unit 110 to generate an air flow inside the room 10 to generate a refrigerant. It is possible to prevent the accumulation of air and the occurrence of a portion having a high concentration.

Here, the case where the detection signal from the sensor unit 110 indicates the leakage occurrence detection of the refrigerant specifically means that, for example, if the sensor unit 110 outputs a detection signal of a voltage proportional to the concentration of the refrigerant, the detection signal. Corresponds to the case where the voltage becomes higher than the preset reference value. Alternatively, if the detection signal is output from the sensor unit 110 when the concentration of the refrigerant is equal to or higher than a predetermined reference value, the detection signal from the sensor unit 110 is when the detection signal is output from the sensor unit 110. Corresponds to the case where the leakage occurrence detection of the refrigerant is indicated.

In the above, an example in which the refrigeration cycle device to which the environmental monitoring device according to the present invention is applied is an air conditioner has been described. However, the refrigeration cycle device to which the environmental monitoring device according to the present invention is applied is not limited to the air conditioner. Any device provided with a refrigeration cycle using a sealed refrigerant can be applied, and may be, for example, a water heater, a showcase, a refrigerator, or the like.

In addition to driving the indoor unit fan 32 in response to the detection signal from the sensor unit 110, for example, driving a ventilation system such as a ventilation fan provided in the room 10 or a window provided in the room 10. May be opened.

Embodiment 2.
FIG. 5 relates to the second embodiment of the present invention, and is a diagram schematically showing the configuration of an environmental monitoring device.

In the second embodiment described here, in the configuration of the first embodiment described above, the sensor unit is a card type, and the remote controller of the air conditioner is provided with the sensor accommodating unit. Hereinafter, the environment monitoring device according to the second embodiment will be described focusing on the differences from the first embodiment.

As shown in FIG. 5, in the second embodiment, the environment monitoring device main body 100 installed in the room 10 is also a remote controller 50 of the air conditioner. The environment monitoring device main body 100 and remote controller 50 are attached to, for example, the inner wall 12 of the room 10. A display unit 51 is provided on the front surface of the remote controller 50.

The display unit 51 includes, for example, a touch panel or the like. By operating the buttons and the like displayed on the touch panel of the display unit 51 of the remote controller 50, the user can set the power ON / OFF of the air conditioner, the wind direction, the air volume, and the like. Further, various information such as the operating status of the air conditioner is displayed to the user on the display unit 51 of the remote controller 50.

The sensor unit 110 includes a sensor case 111. A semiconductor-type refrigerant sensor is housed inside the sensor case 111 as in the first embodiment. The sensor case 111 presents a card shape here. That is, the sensor case 111 has a thin flat plate shape. By making the sensor case 111 a card type, it is possible to improve the aesthetic appearance and design when the sensor unit 110 is arranged at the sensor effective position in the room 10. In addition, it does not get in the way because it has few protrusions.

A sensor accommodating portion 101 is provided below the remote controller 50. The sensor accommodating unit 101 accommodates the card-type sensor unit 110 so that it can be taken in and out. A power supply unit 120 is housed inside the remote controller 50. The power supply unit 120 and the sensor unit 110 inside the remote controller 50 are electrically connected by a power supply line 121.

The sensor unit 110 is provided with a connector unit 132. A terminal (not shown) that can be electrically connected to the connector portion 132 is provided in the sensor accommodating portion 101 of the remote controller 50. When the sensor unit 110 is housed in the sensor housing part 101, the connector part 132 and the terminals in the sensor housing part 101 are electrically connected.

If the connector unit 132 is not connected to the terminal in the sensor accommodating unit 101, power is supplied from the power supply unit 120 to the sensor unit 110 through the power supply line 121. When the connector unit 132 is connected to the terminal in the sensor accommodating unit 101, the power supply from the power supply unit 120 to the sensor unit 110 is stopped.

In the example described in the second embodiment, the region outside the sensor accommodating portion 101 is set to the sensor effective position as in the first embodiment described above. When the sensor unit 110 is not housed in the sensor housing unit 101, the sensor unit 110 is in the sensor effective position. When the sensor unit 110 is in the sensor effective position, the connector unit 132 is not connected to the terminal in the sensor accommodating unit 101, so that the power supply unit 120 supplies the sensor drive power to the sensor unit 110. Therefore, when the sensor unit 110 is in the sensor effective position, the sensor unit 110 is in a state where the refrigerant can be detected.

On the other hand, in the state where the sensor unit 110 is housed in the sensor housing unit 101, the sensor unit 110 is not in the sensor effective position. When the sensor unit 110 is not in the sensor effective position, the connector unit 132 is connected to the terminal in the sensor accommodating unit 101, and the power supply unit 120 does not supply the sensor drive power to the sensor unit 110. Therefore, when the sensor unit 110 is not in the effective position of the sensor, the sensor unit 110 is not in a state where the refrigerant can be detected.

In this way, the terminals in the connector unit 132 and the sensor accommodating unit 101 in the second embodiment constitute the sensor position detecting means for detecting that the sensor unit 110 is in the preset effective sensor position. .. Then, the power supply unit 120 supplies the sensor drive power to the sensor unit 110 when the sensor position detecting means detects that the sensor unit 110 is in the sensor effective position. Further, when the sensor position detecting means does not detect that the sensor unit 110 is in the sensor effective position, the power supply unit 120 does not supply the sensor driving power to the sensor unit 110.

Therefore, even in the environment monitoring device according to the second embodiment configured as described above, the sensor unit 110 is effective as a sensor when it is not necessary to keep the sensor unit 110 in operation as in the first embodiment. By moving the sensor unit 110 to a place other than the position, that is, by accommodating the sensor unit 110 in the sensor accommodating unit 101, the energization of the sensor unit 110 is automatically stopped. Therefore, the life of the sensor unit 110 can be extended, and it is possible to prevent the sensor unit 110 from being replaced frequently. Further, since it is not necessary to put out the sensor unit 110 in the room 10, the scenery in the room 10 can be improved.

Then, when it is necessary to keep the sensor unit 110 in operation, the sensor unit 110 is moved to the sensor effective position, that is, the sensor unit 110 is taken out from the sensor accommodating unit 101 to automatically move to the sensor unit 110. Energization is started. Therefore, when it is necessary to keep the sensor unit 110 in operation, it is possible to ensure that the sensor unit 110 can detect the refrigerant without forgetting to supply the sensor drive power to the sensor unit 110. Is.

The electric power for driving the display unit 51 of the remote controller 50 is supplied from, for example, the indoor unit 30 of the air conditioner. Then, in the second embodiment, since the power supply unit 120 is built in the remote controller 50, the sensor drive power supplied from the power supply unit 120 to the sensor unit 110 is combined with the power for driving the display unit 51. , The air conditioner may be supplied from, for example, the indoor unit 30.
Other configurations and the like are the same as those in the first embodiment, and the description thereof will be omitted here.

Embodiment 3.
6 and 7 relate to the third embodiment of the present invention, FIG. 6 is a diagram schematically showing a state in which the sensor unit of the environmental monitoring device is not in the effective position of the sensor, and FIG. 7 is a diagram showing the sensor of the environmental monitoring device. It is a figure which shows typically the state which the part is in a sensor effective position.

In the third embodiment described here, in the configuration of the first or second embodiment described above, as the sensor position detecting means, a light emitting means that emits infrared rays and a light receiving light that receives the infrared rays emitted from the light emitting means are received. It is equipped with means. Hereinafter, the environment monitoring device according to the third embodiment will be described focusing on the differences from the first embodiment, taking as an example a case based on the configuration of the first embodiment.

As shown in FIGS. 6 and 7, a light emitting unit 133 and a light receiving unit 134 are installed in the room 10 to which the environmental monitoring device according to the third embodiment of the present invention is applied. The light emitting unit 133 is a light emitting device (light emitting means) that emits infrared rays. The light receiving unit 134 is a light receiving device (light receiving means) that receives infrared rays emitted from the light emitting unit 133. The light emitting unit 133 and the light receiving unit 134 are arranged in advance so as to face each other. At least a part of the sensor unit 110, for example, the sensor case 111, is made of a material capable of shielding infrared rays emitted from the light emitting unit 133.

When an object that blocks infrared rays emitted from the light emitting unit 133 exists between the light emitting unit 133 and the light receiving unit 134 and the light receiving unit 134 does not receive the infrared rays emitted from the light emitting unit 133, the power supply unit 120 supplies power. Power is supplied to the sensor unit 110 through the wire 121. When there is no object blocking the infrared rays emitted from the light emitting unit 133 between the light emitting unit 133 and the light receiving unit 134, and the light receiving unit 134 receives the infrared rays emitted from the light emitting unit 133, the power supply unit The power supply from the 120 to the sensor unit 110 is stopped. Note that in FIGS. 6 and 7, the power line 121 is not shown.

In the example described in the third embodiment, the existing region of the sensor unit 110 that can block the infrared rays emitted from the light emitting unit 133 by the sensor unit 110 is set at the sensor effective position. As shown in FIG. 7, when the sensor unit 110 is between the light emitting unit 133 and the light receiving unit 134, the sensor unit 110 is in the sensor effective position. When the sensor unit 110 is in the sensor effective position, the infrared rays emitted from the light emitting unit 133 are blocked by the sensor unit 110, and the light receiving unit 134 does not receive the infrared rays. Therefore, the power supply unit 120 drives the sensor unit 110. Supply power. Therefore, when the sensor unit 110 is in the sensor effective position, the sensor unit 110 is in a state where the refrigerant can be detected.

On the other hand, as shown in FIG. 6, when the sensor unit 110 is not between the light emitting unit 133 and the light receiving unit 134, the sensor unit 110 is not in the sensor effective position. When the sensor unit 110 is not in the sensor effective position, the light receiving unit 134 receives infrared rays, so that the power supply unit 120 does not supply the sensor driving power to the sensor unit 110. Therefore, when the sensor unit 110 is not in the effective position of the sensor, the sensor unit 110 is not in a state where the refrigerant can be detected.

In this way, the light emitting unit 133 and the light receiving unit 134 in the third embodiment constitute a sensor position detecting means for detecting that the sensor unit 110 is in a preset sensor effective position. Then, the sensor position detecting means configured in this way does not detect that the sensor unit 110 is in the sensor effective position when the light receiving unit 134 receives infrared rays. Further, when the light receiving unit 134 does not receive infrared rays, the sensor position detecting means detects that the sensor unit 110 is in the sensor effective position.

Then, the power supply unit 120 supplies the sensor drive power to the sensor unit 110 when the sensor position detecting means detects that the sensor unit 110 is in the sensor effective position. Further, when the sensor position detecting means does not detect that the sensor unit 110 is in the sensor effective position, the power supply unit 120 does not supply the sensor driving power to the sensor unit 110.

Therefore, even in the environment monitoring device according to the third embodiment configured as described above, when it is not necessary to keep the sensor unit 110 in operation as in the first and second embodiments, the sensor unit 110 is used. By moving the sensor unit 110 to a location other than the effective position of the sensor, that is, moving the sensor unit 110 to a location other than between the light emitting unit 133 and the light receiving unit 134, the energization of the sensor unit 110 is automatically stopped. Therefore, the life of the sensor unit 110 can be extended, and it is possible to prevent the sensor unit 110 from being replaced frequently.

Then, when it is necessary to keep the sensor unit 110 in operation, the sensor unit 110 is moved to the sensor effective position, that is, the sensor unit 110 is arranged between the light emitting unit 133 and the light receiving unit 134. Energization of the sensor unit 110 is automatically started. Therefore, when it is necessary to keep the sensor unit 110 in operation, it is possible to ensure that the sensor unit 110 can detect the refrigerant without forgetting to supply the sensor drive power to the sensor unit 110. Is.

In the third embodiment, the sensor accommodating portion 101 and the contact portion 131 provided in the first embodiment may not be provided. However, when the sensor accommodating unit 101 and the contact unit 131 are provided, the contact unit 131 is closed, and the light receiving unit 134 does not receive the infrared rays emitted from the light emitting unit 133, the power supply unit 120 is the sensor unit. The sensor drive power may be supplied to the 110. By doing so, even if an object other than the sensor unit 110 blocks the infrared rays emitted from the light emitting unit 133, the sensor driving power is not supplied if the sensor unit 110 is housed in the sensor housing unit 101. Can be done. Therefore, it is possible to prevent the sensor unit 110 from being erroneously detected as being in the effective position of the sensor, and to further extend the life of the sensor unit 110.
Other configurations and the like are the same as those in the first embodiment or the second embodiment, and the description thereof will be omitted here.

Embodiment 4.
8 and 9 relate to the fourth embodiment of the present invention, FIG. 8 is a diagram schematically showing a state in which the sensor unit of the environmental monitoring device is not in the effective position of the sensor, and FIG. 9 is a diagram showing the sensor of the environmental monitoring device. It is a figure which shows typically the state which the part is in a sensor effective position.

The fourth embodiment described here is the configuration of the first embodiment or the second embodiment described above, in which the sensor position detecting means includes a protruding portion protruding from the sensor portion. Hereinafter, the environment monitoring device according to the fourth embodiment will be described focusing on the differences from the first embodiment, taking as an example a case based on the configuration of the first embodiment.

As shown in FIGS. 8 and 9, the sensor unit 110 of the environmental monitoring device according to the fourth embodiment of the present invention includes a protruding portion 135. The protruding portion 135 is a rod-shaped member that protrudes downward from, for example, a lower surface portion of the sensor case 111 of the sensor portion 110. The protruding portion 135 is provided so as to be movable with respect to the sensor case 111 so as to change the length of the portion protruding from the sensor case 111. That is, the protruding portion 135 is attached so that it can be pushed toward the sensor case 111 from the state in which it protrudes from the sensor case 111 for the longest time. The protruding portion 135 is configured to be in a state of protruding from the sensor case 111 for the longest time in a normal state by, for example, the urging force of a push spring.

The power supply unit 120 does not supply the sensor drive power to the sensor unit 110 when the protrusion 135 is in the state of protruding from the sensor case 111 for the longest time. On the other hand, when the protruding portion 135 is pushed toward the sensor case 111, the power supply unit 120 supplies the sensor driving power to the sensor unit 110 through the power supply line 121. This can be achieved, for example, by providing a switch that operates when the protrusion 135 is pushed toward the sensor case 111. Note that in FIGS. 8 and 9, the power line 121 is not shown.

In the example described in the fourth embodiment, the existing region of the sensor unit 110 when the tip of the protrusion 135 is in contact with the floor surface of the room 10 and the protrusion 135 is pushed in is set to the sensor effective position. As shown in FIG. 9, when the sensor unit 110 is located at a low position such that the tip of the protrusion 135 is in contact with the floor surface of the room 10 and the protrusion 135 is pushed in, the sensor unit 110 is in the sensor effective position. When the sensor unit 110 is in the sensor effective position, the protrusion 135 is pushed by the floor surface, so that the power supply unit 120 supplies the sensor drive power to the sensor unit 110. Therefore, when the sensor unit 110 is in the sensor effective position, the sensor unit 110 is in a state where the refrigerant can be detected.

On the other hand, as shown in FIG. 8, when the sensor unit 110 is located at a high position such that the tip of the protruding portion 135 does not contact the floor surface of the room 10, the sensor unit 110 is not in the sensor effective position. Then, when the sensor unit 110 is not in the sensor effective position, the power supply unit 120 does not supply the sensor drive power to the sensor unit 110. Therefore, when the sensor unit 110 is not in the effective position of the sensor, the sensor unit 110 is not in a state where the refrigerant can be detected.

In this way, the protruding portion 135 in the fourth embodiment constitutes a sensor position detecting means for detecting that the sensor portion 110 is in the preset effective sensor position. Then, the sensor position detecting means configured in this way detects that the sensor unit 110 is in the sensor effective position when the protruding portion 135 is pushed in.

The power supply unit 120 supplies the sensor drive power to the sensor unit 110 when the sensor position detecting means detects that the sensor unit 110 is in the sensor effective position. Further, when the sensor position detecting means does not detect that the sensor unit 110 is in the sensor effective position, the power supply unit 120 does not supply the sensor driving power to the sensor unit 110.

Therefore, even in the environment monitoring device according to the fourth embodiment configured as described above, when it is not necessary to keep the sensor unit 110 in operation as in the first to third embodiments, the sensor unit 110 is used. By moving the sensor unit 110 to a position other than the sensor effective position, that is, moving the sensor unit 110 to a high position where the protrusion 135 is not pushed by the floor surface of the room 10, the energization of the sensor unit 110 is automatically stopped. To. Therefore, the life of the sensor unit 110 can be extended, and it is possible to prevent the sensor unit 110 from being replaced frequently.

Then, when it is necessary to keep the sensor unit 110 in operation, the sensor unit 110 is moved to the sensor effective position, that is, the sensor unit 110 is moved to a low position such that the protruding portion 135 is pushed by the floor surface of the room 10. By moving the sensor unit 110, energization of the sensor unit 110 is automatically started. Therefore, when it is necessary to keep the sensor unit 110 in operation, it is possible to ensure that the sensor unit 110 can detect the refrigerant without forgetting to supply the sensor drive power to the sensor unit 110. Is.

In the fourth embodiment, the sensor accommodating portion 101 and the contact portion 131 provided in the first embodiment may not be provided. However, when the sensor accommodating portion 101 and the contact portion 131 are provided, the contact portion 131 is closed, and the protruding portion 135 is pushed in, the power supply unit 120 supplies the sensor drive power to the sensor unit 110. You may do so. By doing so, even if the protruding portion 135 is pushed in, the sensor driving power can be prevented from being supplied if the sensor portion 110 is accommodated in the sensor accommodating portion 101. Therefore, it is possible to prevent the sensor unit 110 from being erroneously detected as being in the effective position of the sensor, and to further extend the life of the sensor unit 110.
Other configurations and the like are the same as those in the first embodiment or the second embodiment, and the description thereof will be omitted here.

Embodiment 5.
10 to 12 relate to the fifth embodiment of the present invention, FIG. 10 is a diagram schematically showing a state in which the sensor unit of the environmental monitoring device is not in the sensor effective position, and FIG. 11 is a diagram showing a state in which the sensor of the environmental monitoring device is not in the effective position. FIG. 12 is a diagram schematically showing a state in which the unit is in the sensor effective position, and FIG. 12 is a diagram schematically showing a state in which the sensor unit of the environmental monitoring device is in and out of the sensor effective position.

The fifth embodiment described here includes, in the configuration of the first or second embodiment described above, as a sensor position detecting means, a magnet and a reed switch that is switched on / off by the action of a magnetic force. is there. Hereinafter, the environment monitoring device according to the fifth embodiment will be described focusing on the differences from the first embodiment, taking as an example a case based on the configuration of the first embodiment.

As shown in FIGS. 10 to 12, the environmental monitoring device according to the fifth embodiment of the present invention includes a first reed switch 136, a second reed switch 137, a first magnet 138, and a second magnet 139. I have. The first reed switch 136 and the second reed switch 137 are provided in the sensor unit 110. The first reed switch 136 is provided relatively above the second reed switch 137. Conversely, the second reed switch 137 is provided relatively below the first reed switch 136.

The first reed switch 136 is a normally open contact. Then, when the magnetic force of the first magnet 138 or the second magnet 139 acts on the first reed switch 136, the first reed switch 136 is closed. That is, the first reed switch 136 is switched ON / OFF by the magnetic force of the first magnet 138 or the second magnet 139.

The second reed switch 137 is a normally closed contact. Then, when the magnetic force of the first magnet 138 or the second magnet 139 acts on the second reed switch 137, the second reed switch 137 is opened. That is, the second reed switch 137 is switched ON / OFF by the magnetic force of the first magnet 138 or the second magnet 139.

The first magnet 138 and the second magnet 139 are installed on the inner wall 12 of the room 10. The first magnet 138 is provided relatively above the second magnet 139. Conversely, the second magnet 139 is provided relatively below the first magnet 138.

In the state shown in FIG. 10, the sensor unit 110 is separated from the wall surface on which the first magnet 138 and the second magnet 139 are installed. Therefore, neither the magnetic force of the first magnet 138 nor the magnetic force of the second magnet 139 acts on the first reed switch 136. Therefore, the first reed switch 136 is open. Further, neither the magnetic force of the first magnet 138 nor the magnetic force of the second magnet 139 acts on the second reed switch 137. Therefore, the second reed switch 137 is closed. When the first reed switch 136 is open and the second reed switch 137 is closed, the first switch signal 141 is output from the sensor unit 110 to the environment monitoring device main body 100.

In the state shown in FIG. 11, the sensor unit 110 is close to the wall surface on which the first magnet 138 and the second magnet 139 are installed. The first reed switch 136 faces the first magnet 138. At the same time, the second reed switch 137 faces the second magnet 139. Therefore, the magnetic force of the first magnet 138 acts on the first reed switch 136. Therefore, the first reed switch 136 is closed. Further, the magnetic force of the second magnet 139 acts on the second reed switch 137. Therefore, the second reed switch 137 is open. When the first reed switch 136 is closed and the second reed switch 137 is open, the second switch signal 142 is output from the sensor unit 110 to the environment monitoring device main body 100.

When the first switch signal 141 output from the sensor unit 110 is input to the environment monitoring device main body 100, the power supply unit 120 does not supply the sensor drive power to the sensor unit 110. On the other hand, in a state where the second switch signal 142 output from the sensor unit 110 is input to the environment monitoring device main body 100, the power supply unit 120 supplies the sensor drive power to the sensor unit 110 through the power supply line 121. .. Note that, in FIGS. 10 and 11, the power line 121 is not shown.

In the example described in the fifth embodiment, at least one of the magnetic forces of the first magnet 138 and the second magnet 139 acts on both the first reed switch 136 and the second reed switch 137. The existing area of the sensor unit 110 when it is possible is set to the sensor effective position. For example, as shown in FIG. 11, the sensor is located at a position where the magnetic force of the first magnet 138 acts on the first reed switch 136 and the magnetic force of the second magnet 139 acts on the second reed switch 137. When there is a unit 110, the sensor unit 110 is in the sensor effective position. Then, when the sensor unit 110 is in the sensor effective position, the second switch signal 142 is output from the sensor unit 110, so that the power supply unit 120 supplies the sensor drive power to the sensor unit 110. Therefore, when the sensor unit 110 is in the sensor effective position, the sensor unit 110 is in a state where the refrigerant can be detected.

On the other hand, as shown in FIG. 11, for example, neither the magnetic force of the first magnet 138 nor the magnetic force of the second magnet 139 acts on the first reed switch 136, and the first reed switch 137 is first. When the sensor unit 110 is located at a position where neither the magnet 138 nor the second magnet 139 of the above magnet acts, the sensor unit 110 is not at the sensor effective position. Then, when the sensor unit 110 is not in the sensor effective position, the power supply unit 120 does not supply the sensor drive power to the sensor unit 110. Therefore, when the sensor unit 110 is not in the effective position of the sensor, the sensor unit 110 is not in a state where the refrigerant can be detected.

In this way, the first reed switch 136, the second reed switch 137, the first magnet 138, and the second magnet 139 in the fifth embodiment are placed in the sensor effective positions in which the sensor unit 110 is preset. It constitutes a sensor position detecting means for detecting the presence. Then, in the sensor position detecting means configured in this way, whether or not the sensor unit 110 is in the sensor effective position based on the ON / OFF state of each of the first reed switch 136 and the second reed switch 137. Is detected.

The power supply unit 120 supplies the sensor drive power to the sensor unit 110 when the sensor position detecting means detects that the sensor unit 110 is in the sensor effective position. Further, when the sensor position detecting means does not detect that the sensor unit 110 is in the sensor effective position, the power supply unit 120 does not supply the sensor driving power to the sensor unit 110.

Therefore, even in the environment monitoring device according to the fifth embodiment configured as described above, when it is not necessary to keep the sensor unit 110 in operation as in the first to fourth embodiments, the sensor unit 110 is used. By moving the sensor unit 110 to a position other than the sensor effective position, that is, moving the sensor unit 110 to a high position where the protruding portion 135 is not pushed by the floor surface of the room 10, the energization of the sensor unit 110 is automatically stopped. To. Therefore, the life of the sensor unit 110 can be extended, and it is possible to prevent the sensor unit 110 from being replaced frequently.

Then, when it is necessary to keep the sensor unit 110 in operation, the sensor unit 110 is moved to the sensor effective position, that is, the sensor unit 110 is moved to a low position such that the protruding portion 135 is pushed by the floor surface of the room 10. By moving the sensor unit 110, energization of the sensor unit 110 is automatically started. Therefore, when it is necessary to keep the sensor unit 110 in operation, it is possible to ensure that the sensor unit 110 can detect the refrigerant without forgetting to supply the sensor drive power to the sensor unit 110. Is.

In the fifth embodiment, the sensor accommodating portion 101 and the contact portion 131 provided in the first embodiment may not be provided. However, when the sensor accommodating unit 101 and the contact unit 131 are provided, the contact unit 131 is closed, and the second switch signal 142 is output from the sensor unit 110, the power supply unit 120 is the sensor unit 110. The sensor drive power may be supplied to the sensor. By doing so, even if the second switch signal 142 is output from the sensor unit 110 due to the influence of the magnetic field not derived from the first magnet 138 and the second magnet 139, the sensor unit 110 accommodates the sensor. If it is housed in the unit 101, the sensor drive power can be prevented from being supplied. Therefore, it is possible to prevent the sensor unit 110 from being erroneously detected as being in the effective position of the sensor, and to further extend the life of the sensor unit 110.

In the fifth embodiment, the sensor is driven from the power supply unit 120 when only one of the ON / OFF state of the first reed switch 136 and the ON / OFF state of the second reed switch 137 is switched. The start or stop of the power supply may be notified.

Specifically, for example, in the state shown in FIG. 12, the sensor unit 110 is close to the wall surface on which the first magnet 138 and the second magnet 139 are installed. The second reed switch 137 faces the first magnet 138. On the other hand, the first reed switch 136 does not face either the first magnet 138 or the second magnet 139. Therefore, neither the magnetic force of the first magnet 138 nor the magnetic force of the second magnet 139 acts on the first reed switch 136. Therefore, the first reed switch 136 is open. Then, the magnetic force of the first magnet 138 acts on the second reed switch 137. Therefore, the second reed switch 137 is open. When the first reed switch 136 is open and the second reed switch 137 is open, the third switch signal 143 is output from the sensor unit 110 to the environment monitoring device main body 100.

In this state, the sensor unit 110 is about to enter the sensor effective position, or the sensor unit 110 is about to exit the sensor effective position. Therefore, the environment monitoring device main body 100 to which the third switch signal 143 output from the sensor unit 110 is input can start or stop the supply of the sensor drive power from the power supply unit 120 to the user, for example, by voice or the like. Notify.

By doing so, the user can know whether the sensor unit 110 is approaching the sensor effective position or the sensor unit 110 is about to move away from the sensor effective position. Then, the sensor unit 110 can be smoothly and easily arranged at the sensor effective position or removed from the sensor effective position.

In the above, a configuration example in which two sets of magnets and reed switches are provided has been described. However, the number of sets of magnets and reed switches is not limited to two. If at least the first magnet 138 and the first reed switch 136 whose ON / OFF is switched by the magnetic force of the first magnet 138 are provided, the first reed switch 136 can be turned ON / OFF. Based on this, it is possible to detect whether or not the sensor unit 110 is in the effective position of the sensor.
Other configurations and the like are the same as those in the first embodiment or the second embodiment, and the description thereof will be omitted here.

In the third to fifth embodiments described above, when the specific gravity of the refrigerant with respect to air is larger than 1, the effective position of the sensor is preferably set vertically below the indoor unit 30. This is because when the specific gravity of the refrigerant with respect to air is larger than 1, the leaked refrigerant flows downward from the indoor unit 30.

10 Room 11 Outer wall 12 Inner wall 20 Outdoor unit 21 Outdoor unit heat exchanger 22 Outdoor unit fan 23 Compressor 30 Indoor unit 31 Indoor unit heat exchanger 32 Indoor unit fan 40 Refrigerant piping 50 Remote control 51 Display unit 100 Environmental monitoring device Main unit 101 Sensor Accommodating part 102 Filter 110 Sensor part 111 Sensor case 120 Power supply part 121 Power supply line 131 Contact part 132 Connector part 133 Light emitting part 134 Light receiving part 135 Protruding part 136 First reed switch 137 Second reed switch 138 First magnet 139 2nd magnet 141 1st switch signal 142 2nd switch signal 143 3rd switch signal

Claims (10)

A sensor unit for detecting the refrigerant and
A power supply unit that supplies sensor drive power to the sensor unit so that the sensor unit can detect the refrigerant, and
A sensor position detecting means for detecting that the sensor unit is in a preset effective sensor position is provided.
The power supply unit
When the sensor position detecting means detects that the sensor unit is in the effective position of the sensor, the sensor driving power is supplied to the sensor unit.
An environment monitoring device that does not supply sensor drive power to the sensor unit when the sensor position detecting means has not detected that the sensor unit is in the sensor effective position. Further provided with a sensor accommodating portion for accommodating the sensor unit so that it can be taken in and out
The sensor position detecting means is
When the sensor unit is housed in the sensor housing unit, it is not detected that the sensor unit is in the sensor effective position, and the sensor unit is not detected.
The environmental monitoring device according to claim 1, wherein when the sensor unit is not housed in the sensor housing unit, the sensor unit detects that the sensor unit is in the sensor effective position. The environmental monitoring device according to claim 2, wherein the sensor accommodating portion is provided on the remote controller of the air conditioner. The environmental monitoring device according to claim 3, wherein the power supply unit is provided on the remote controller. The sensor position detecting means is
Light emitting means that emits infrared rays and
A light receiving means for receiving infrared rays emitted from the light emitting means is provided.
When the light receiving means receives infrared rays, the sensor unit does not detect that the sensor is in the effective position of the sensor.
The environmental monitoring device according to claim 1, wherein the sensor unit detects that the sensor unit is in the effective position of the sensor when the light receiving means does not receive infrared rays. The sensor position detecting means is
A protrusion protruding from the sensor portion is provided.
The environmental monitoring device according to claim 1, wherein the sensor unit detects that the sensor unit is in the effective position of the sensor when the protruding portion is pushed in. The sensor position detecting means is
The first magnet and
A first reed switch that is switched ON / OFF by the magnetic force of the first magnet is provided.
The environmental monitoring device according to claim 1, wherein the sensor unit detects whether or not the sensor unit is in the effective position of the sensor based on the ON / OFF state of the first reed switch. The sensor position detecting means is
With the second magnet
A second reed switch that is switched ON / OFF by the magnetic force of the first magnet or the second magnet is further provided.
The first reed switch is switched ON / OFF by the magnetic force of the first magnet or the second magnet.
When only one of the ON / OFF state of the first reed switch and the ON / OFF state of the second reed switch is switched, the supply of the sensor drive power from the power supply unit is started or stopped. The environmental monitoring device according to claim 7, which is notified. The environmental monitoring device according to any one of claims 5 to 8, wherein the power supply unit is provided on the remote controller of the air conditioner. The environmental monitoring device according to any one of claims 1 to 9, wherein the sensor unit includes a sensor case having a card shape.

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