JP2009270819A - Air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a maintenance-free air conditioner for demonstrating an electrostatic atomization function, without water supply under various conditions. <P>SOLUTION: The air conditioner using a Peltier element accomplishes the electrostatic atomization function. The air conditioner includes a cooling fan for promoting heat radiation of the Peltier element on a radiating surface and a room-temperature thermistor for detecting the room temperature and controls rotation frequency of the cooling fan based on a detection value of the room-temperature thermistor. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an air conditioner having an air cleaning function for deodorizing and dusting indoor air and purifying air.

  There is known an air conditioner that obtains water necessary for electrostatic atomization from the air and can deodorize indoor air and deodorize deposits such as an indoor wall surface by electrostatic atomization without supplying water.

JP 2006-149538 A

  However, if water is not supplied, water for electrostatic atomization may be insufficient or water may not be generated. Furthermore, it is thought that excessive water will be produced | generated. Basically, these problems may be achieved by setting the cooling surface of the Peltier element below the dew point temperature so as not to reduce the temperature excessively, but it is not always solved by controlling the drive power supply of the Peltier element. In particular, the following three conditions are conceivable when the operating conditions, that is, the room temperature, the humidity, and the like change variously.

  First, conditions that make it difficult to produce water are conceivable. For example, operating conditions such as insufficient water generation that occurs at low temperatures and low humidity, and insufficient water generation due to insufficient heat dissipation at high temperatures. Since the dew point temperature is low at low temperature and low humidity, there is a problem that the cooling surface of the Peltier element does not fall to the dew point temperature. On the other hand, since the temperature of the heat radiating surface is hardly lowered under a high temperature condition where the room temperature is high, there is a problem that the cooling surface of the Peltier element does not fall to the dew point temperature. All of these are insufficient heat absorption capability of the Peltier element, that is, there is a condition that water cannot be generated due to the characteristics of the Peltier element.

  Secondly, the room temperature is so low that the cooling surface of the Peltier element freezes. At low temperatures, the temperature of the cooling surface is likely to drop, and the dew point temperature may be below freezing.

  Thirdly, it can be considered that the humidity is very high and an excessive amount of water is generated. In this case, there is a possibility that the vicinity of the electrostatic atomizer may be submerged, and water may overflow inside the air conditioner. As a result, water may leak from the air conditioner into the room.

  Then, an object of this invention is to provide the air conditioner which can exhibit an electrostatic atomization function with no water supply on various conditions. Moreover, it aims at providing the air conditioner which can exhibit an electrostatic atomization function without a maintenance.

The above purpose is
An air conditioner that achieves an electrostatic atomization function using a Peltier element,
A cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element;
A room temperature thermistor for detecting room temperature,
This is achieved by controlling the number of revolutions of the cooling fan based on the detected value of the room temperature thermistor.

The above purpose is
An air conditioner that achieves an electrostatic atomization function using a Peltier element,
A cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element;
An indoor humidity sensor for detecting indoor humidity,
This is achieved by controlling the number of rotations of the cooling fan based on the detection value of the indoor humidity sensor.

The above purpose is
An outdoor unit equipped with an outdoor temperature thermistor for detecting the outdoor temperature;
An air conditioner that is connected to the outdoor unit by a communication cord and has an indoor unit that includes a Peltier element, and that achieves an electrostatic atomization function,
This is achieved by providing the indoor unit with a cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element, and controlling the number of revolutions of the cooling fan based on the detected value of the outside temperature thermistor.

The above purpose is
An outdoor unit equipped with an outdoor humidity sensor for detecting outdoor humidity;
An air conditioner that is connected to the outdoor unit by a communication cord and has an indoor unit that includes a Peltier element, and that achieves an electrostatic atomization function,
This is achieved by providing the indoor unit with a cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element, and controlling the number of revolutions of the cooling fan based on a detection value of the outdoor humidity sensor.

The above purpose is
An outdoor unit equipped with an outdoor temperature thermistor for detecting the outdoor temperature;
An air conditioner that is connected to the outdoor unit by a communication cord, has an Peltier element, and an indoor unit that includes a room temperature thermistor that detects a room temperature, and achieves an electrostatic atomization function,
The indoor unit includes a cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element, and the number of rotations of the cooling fan is determined based on a difference between a detected value of the room temperature thermistor and a detected value of the outside temperature thermistor. This is achieved by controlling.

  An air conditioner that can exhibit an electrostatic atomization function without water supply under various conditions can be realized. Moreover, the air conditioner which can perform an electrostatic atomization function without maintenance is realizable.

The structural example of the air conditioner in the Example of this invention is shown. The structural example of the electrostatic atomizer in the Example of this invention is shown. The structural example of the water generator in the Example of this invention is shown. The external appearance structure of the electrostatic atomizer in the Example of this invention is shown. The external appearance structure of the electrostatic atomizer in the Example of this invention is shown. The external appearance structure of the electrostatic atomizer in the Example of this invention is shown. An example of a circuit configuration in an embodiment of the present invention will be shown. An example of a circuit configuration in an embodiment of the present invention will be shown. The example of control by the temperature detection value in the Example of this invention is shown. The example of control by the humidity detection value in the Example of this invention is shown.

  Embodiments of the present invention will be described below.

  The air conditioner 1 shown in FIG. 1 includes an indoor unit 10 and an outdoor unit 13. The indoor unit 10 and the outdoor unit 13 are connected by a power supply / communication cable 11 and a pipe 12 for sending a refrigerant. The exterior of the indoor unit 10 is configured by the housing 4, and the housing 4 includes an air inlet 2 and an air outlet 3. In addition, a heat exchanger 5, a metal-sputtered filter 6, a blower fan 7 that blows out air from the air outlet 3, and a ventilation fan 8 that ventilates indoor and outdoor air are provided in the housing 4. It is arranged. In addition, the filter 6 is arrange | positioned between the air suction inlet 2 and the heat exchanger 5, and only the approximate position in which the ventilation fan 8 is arrange | positioned is shown by FIG. Further, a ventilation hose 9 comes out from the indoor unit 10.

  Next, as a configuration in the present invention, FIG. 2 and FIG. 3 are configuration diagrams of the electrostatic atomizer, FIG. 4, FIG. 5 and FIG. FIG. 9 and FIG. 10 show control examples.

  In the indoor unit 10, the electrostatic atomizer 14 shown in FIG. 2 is provided. The electrostatic atomizer 14 includes a water guide 18 and a high voltage generator 19 that generates a high voltage of about −6 kV. The water guide means 18 includes a rod-like discharge electrode 15 for a mist ion made of a porous material, a water reservoir 16 for supplying water to the discharge electrode 15 for a mist ion, and a water retaining material 17. The water retaining material 17 is disposed between the water reservoir 16 and the mist ion discharge electrode 15, and is configured by a sponge or the like that sucks up and holds the water accumulated in the water reservoir 16.

  Here, the mist ion discharge electrode 15 has water absorption like a pen tip of a felt pen, and sucks water from the water retaining material 17 by capillary action. In this way, a high voltage is applied by the high voltage generator 19 to the mist ion discharge electrode 15 that has absorbed water and contains water. Then, fine water particles charged are discharged from the discharge electrode 15 for mist ions, and mist ions (mist ions) are generated. This mist ion has a deodorizing and sterilizing effect. This mist ion is diffused in the room on the wind from the air outlet 3.

  At this time, since mist ions are discharged from the discharge electrode 15 for mist ions and water is consumed, it is necessary to supply water to the water guide means 18 in order to operate the electrostatic atomizer 14. That is, it is necessary that the mist ion discharge electrode 15 can suck up water from the water retaining material 17 even if water is stored in the water reservoir 16 or not. However, since the indoor unit 10 is usually installed on the wall near the ceiling of the room, it takes much time for the user to supply water. Therefore, the water stored in the water reservoir 16 is generated from the moisture in the air so that the user does not have to replenish water by himself, and the water retained in the water retaining material 17 is generated. For this reason, the water generator 28 uses a Peltier element as in Patent Document 1 to generate water to be supplied to the water guiding means 18. The Peltier element 23 is an element whose surface temperature is divided into a cooling surface and a heat dissipation surface when energized. Therefore, water can be generated when the Peltier element 23 is energized and the cooling surface is dew point temperature (also referred to as dew point) or less and the cooling surface is condensed.

  The water generator 28 includes a Peltier element 23, a silicon grease 27 for reducing the contact thermal resistance between the Peltier element 23 and the insulating sheet 26 on the cooling surface side of the Peltier element 23, a metallic cooling plate. 24. The insulating sheet 26 is disposed in order to prevent electric leakage from the high voltage generator 19 to the Peltier element 23. A high voltage generated by the high voltage generator 19 may be applied from the water path (referred to as an electric circuit) to the Peltier element 23 through the mist ion discharge electrode 15 and the water retaining material 17. By providing the insulating sheet 26, voltage application to the Peltier element 23 is prevented. Therefore, the insulating sheet 26 may be provided between the Peltier element 23 and the mist ion discharge electrode 15 on the electric circuit.

  As a principle of generating water in the water generator 28, the Peltier element 23 is energized, the temperature of the cooling surface is lowered, and the temperature of the cooling plate 24 is lowered below the dew point. Thereby, the air around the cooling plate 24 is cooled, condensation occurs on the surface of the cooling plate 24, and water is generated. At this time, the water reservoir 16 may be disposed at a position where water droplets hang from the cooling plate 24 and accumulate. Alternatively, the water may be directly absorbed by the water retaining material 17. By keeping the cooling surface of the Peltier element 23 below the dew point as described above, water can be stored in the water reservoir 16. Or even if it does not accumulate, the discharge electrode 15 for mist ions can suck up water from the water retaining material 17.

  Further, the water generator 28 includes a metal heat dissipating plate 25 attached on the heat dissipating surface side of the Peltier element 23 in order to promote heat dissipation of the Peltier element 23. The Peltier element 23 has a characteristic that the temperature of the cooling surface is unlikely to decrease unless the temperature of the heat dissipation surface decreases. In other words, there is a characteristic that when the temperature of the heat radiating surface is lowered, the temperature of the cooling surface is easily lowered. Therefore, the heat radiating plate 25 is provided so as to improve the characteristics as much as possible. In addition, a cooling fan is provided to promote heat dissipation of the heat radiating plate 25. This cooling fan promotes the heat radiation of the heat radiating plate 25, and thus promotes the temperature of the heat radiating surface to be lowered. Note that the ventilation fan 8 is used as a cooling fan, and a part of the ventilation path of the ventilation fan 8 and the heat radiating plate 25 are integrated so that heat radiation can be promoted. If the integral structure is difficult, the wall of the ventilation path and the heat radiating plate 25 may be brought into thermal contact.

  The ventilation fan 8 is provided in the indoor unit 10, and is configured by a sirocco fan or a propeller fan. A ventilation hose 9 is connected to the ventilation fan 8, and the ventilation hose 9 goes out of the room together with the pipe 12. By turning the ventilation fan 8, outdoor air can be taken into the room (supplying air), and the air can be discharged outside the room by switching the air path (exhaust). The switching between the air supply operation, the exhaust operation, and the supply / exhaust operation stop may be configured so that the user can perform the operation manually. In this embodiment, a part of the ventilation path (for example, 25 in FIG. 3) connected to the ventilation hose 9 from the ventilation fan 8 is integrated with the heat radiating plate 25, so that the air passing through the ventilation path at the time of air supply and exhaust is supplied. The heat sink is forcibly cooled by the flow.

  In addition to the mist ion discharge electrode 15, a needle-shaped dust collection discharge electrode 22 made of a conductor is configured to be conductive in the high voltage generator 19. By applying a high voltage here, corona discharge occurs from the tip of the discharge electrode 22 for dust collection, and dust in the space can be charged. The dust thus charged can be easily adsorbed by giving a potential to the filter 6 sputtered with metal, and the dust collection effect can be enhanced.

  A resin cover 20 is provided for safety so that the user does not touch the electrodes (15, 22) to which a high voltage is applied. The earth 21 is connected to the heat exchanger 5 and is configured to be grounded from the heat exchanger 5 through the pipe 12, from the pipe 12 through the outdoor unit 13, and from the outdoor unit 13 to the ground.

  Since the high voltage is applied to the discharge electrode 15 for mist ions and the discharge electrode 22 for dust collection and negative ions are released, the resin cover 20 itself may be charged, and the user touches the cover. It is assumed that you will feel static electricity. Moreover, excessive dew condensation occurs on the surface of the resin cover 20 due to the cooling of the Peltier element 23, and in the unlikely event that an electric circuit is formed and an electric leakage occurs, it may cause an electric shock. In preparation for this, a ground 21 is attached to the resin cover 20. As a result, the battery is discharged to reduce the voltage to the ground potential, thereby ensuring safety.

  The power source of the Peltier element 23 is created by stepping down the voltage by the DC / DC converter 33 from the control voltage of the microcomputer 32 or the like insulated from the commercial power source 31 by the insulating switching transformer 30 (FIG. 7). As shown in FIG. 8, the power source of the Peltier element 23 is the same as the control voltage of the microcomputer 32 or the like that is insulated from the commercial power source 31 by the insulation type switching transformer 30, but the output of the dedicated output winding 43 provided separately from the control voltage. The voltage may be reduced by the DC converter 33.

The output of the DC / DC converter 33, that is, the applied voltage of the Peltier element 23 is configured so that the output can be switched to a plurality of stages by the output switching circuit 34. For example, as shown in FIGS. 9 and 10, it is configured to be switchable between V ₁ and V ₂ (V ₂ > V ₁ ). When the heat absorption capability of the Peltier element 23 is low, the temperature of the cooling surface of the Peltier element 23 can be lowered by increasing the voltage from V ₁ to V ₂ . Thereby, it can adjust so that the cooling plate 24 may fall to dew point temperature. Further, the voltage is controlled from V ₂ to V ₁ so that the temperature is not excessively lowered and water is not generated excessively.

The indoor unit 10 includes a room temperature thermistor 35 that can detect room temperature and an indoor humidity sensor 36 that can detect indoor humidity. These are attached to the suction port of the indoor unit. In other words, it detects the temperature and humidity of the air before passing through the heat exchanger. The detection value detected by the room temperature thermistor 35 or the indoor humidity sensor 36 is compared with an arbitrarily set value stored in the memory 44 by the microcomputer 32 to control the air volume of the ventilation fan 8.
As a result, the optimum air volume necessary for heat radiation of the heat radiating plate 25 is set to control the heat radiation, and the temperature of the cooling plate 24 is set to be equal to or lower than the dew point. Further, the temperature of the cooling plate 24 is kept at an appropriate temperature so that freezing due to overcooling does not occur.

  The amount of air sent out by the cooling fan, that is, the number of rotations of the cooling fan is controlled based on the detection value of the room temperature thermistor 35 that detects the indoor air temperature mounted in the indoor unit 10 or the detection value of the indoor humidity sensor 36 that detects the indoor humidity. Is done. Then, by changing the number of rotations of the cooling fan, it is possible to promote heat dissipation and obtain a stable dew point temperature. Further, when there is a margin when the dew point temperature is set, the fan rotational speed is suppressed. Considering the user's comfort, when it is not necessary, the number of revolutions is lowered to reduce the noise, thereby reducing the noise.

  At this time, if the rotation speed of the fan is controlled based on the detection value of the room temperature thermistor 35, that is, the room temperature, the heat radiation amount of the heat radiating plate 25 can be kept optimal, and the temperature of the cooling plate 24 is kept optimal. be able to. Therefore, it is possible to prevent icing due to overcooling and to prevent water shortage due to insufficient cooling. Thus, since the temperature of the cooling plate 24 can be controlled appropriately below the dew point, the amount of water can be secured stably.

  The rotation speed of the fan can also be controlled based on the detection value of the indoor humidity sensor 36, that is, the indoor humidity. Since the dew point temperature is high under high humidity conditions, it is relatively easy to maintain the dew point temperature or less even if the heat absorption amount of the Peltier element 23 is small. Therefore, under high humidity conditions, the rotation speed of the fan is lowered to prevent excessive water generation. Lowering the fan speed can reduce noise and improve user comfort.

  Further, under extreme high humidity conditions such as 80% or more, for example, there may be dew dripping or leakage due to excessive water collection, so the fan is stopped and the heat absorption amount of the Peltier element 23 is reduced. . Furthermore, the electrostatic atomizer 14 is stopped to prevent problems such as dripping and leakage. Stopping the electrostatic atomizer 14 does not apply a voltage to the discharge electrode 15 for mist ions in addition to stopping the energization to the Peltier element 23.

  On the other hand, since the dew point temperature is low under low humidity conditions, the amount of heat absorbed by the Peltier element 23 must be increased. At this time, if the number of rotations of the fan is increased, the heat radiation amount of the heat radiating plate 25 can be increased, so that the temperature of the cooling plate 24 can be kept below the dew point, and water is stably supplied to the discharge electrode 15 for mist ions. Can be supplied.

  Furthermore, if the rotation speed of the fan is optimally controlled based on room temperature and humidity, water can be supplied to the electrode more stably, and the electrostatic atomization function can be stably operated.

  The amount of air sent out by the cooling fan, that is, the number of rotations of the cooling fan is set to the detection value of the outdoor temperature thermistor 37 that detects the outdoor temperature mounted on the outdoor unit 13 or the detection value of the outdoor humidity sensor 38 that detects the outdoor humidity. It is also possible to control based on this. The outdoor unit 13 includes an outdoor temperature thermistor 37 that can detect the outdoor temperature, and an outdoor humidity sensor 38 that can detect the outdoor humidity. The detected value detected by the outdoor temperature thermistor 37 or the outdoor humidity sensor 38 is processed by the outdoor unit microcomputer 39, communicated by the communication circuit 41 through the cable, and stored in the memory 44 provided in the indoor unit 10. The microcomputer 32 compares the set arbitrary value and the microcomputer 32 to control the air volume of the ventilation fan 8. As a result, the optimum air volume necessary for heat radiation of the heat radiating plate 25 is set to control the heat radiation, and the temperature of the cooling plate 24 is set to be equal to or lower than the dew point. Further, the temperature of the cooling plate 24 is kept at an appropriate temperature so that freezing due to overcooling does not occur.

  The DC / DC converter 33 is provided with a current detection circuit 42. Therefore, the current value of the current flowing in the Peltier element 23 detected by the current detection circuit 42 is compared with the current value in the normal range stored in advance in the microcomputer 32 and the like. If it is, the energization to the Peltier element 23 is immediately cut off. Moreover, you may make it notify abnormality to a user with a lamp | ramp or a buzzer etc. with the display part 40 attached to the indoor unit 10 with interruption | blocking of electricity supply. That is, the interruption of energization to the Peltier element 23 is controlled based on the detection value of the current detection circuit 42 that detects the current flowing through the Peltier element 23.

  Further, when the current value is out of the range as described above, that is, when there is an abnormality in the current detection circuit 42, the ventilation fan 8 and the high voltage generator 19 are immediately stopped. .

  The high voltage generator 19 is provided with an abnormal current detection circuit 45. Since a high voltage such as -6 kV is applied to the discharge electrode 15 for mist ions and the discharge electrode 22 for dust collection, if conductive foreign matter such as dust adheres, it is possible to leak and ignite the foreign matter by sparking. It can be considered as sex. Therefore, an abnormal current detection circuit 45 for detecting an abnormal current that flows due to electric leakage is provided inside the high voltage generator 19, and when an abnormal current is detected, the output voltage of the high voltage generator 19 is immediately cut off.

  The electric current to the mist ion discharge electrode 15 and the dust collection discharge electrode 22 is cut off to prevent sparks caused by electric leakage, and in principle, ignition of conductive foreign matters such as dust is prevented. The abnormal current detection circuit 45 cuts off the output voltage and simultaneously transmits an abnormal signal to the microcomputer 32. The microcomputer 32 recognizes the system abnormality by receiving the abnormality signal, and stops the ventilation fan 8 and the DC / DC converter 33. Here, the display unit 40 can notify the user of an abnormality with a lamp (for example, an LED lamp) or a buzzer. Notification of abnormality can prompt cleaning and repair of the electrode.

  In the above, the temperature of the cooling surface is controlled while passing a current through the Peltier element 23. The Peltier element 23 has a characteristic that the amount of cooling on the cooling surface increases and the amount of heat generated on the heat radiating surface increases by passing a large amount of current. For this reason, the voltage applied to the Peltier element 23 is configured to be variable, and the cooling plate is configured so as not to cause overcooling or undercooling corresponding to room temperature, outdoor temperature, indoor humidity, outdoor humidity, or a combination thereof. The temperature of 24 can be controlled. Thus, since the temperature of the cooling plate 24 can be controlled appropriately below the dew point, the amount of water can be secured stably.

  When the air conditioner 1 is switched between operation modes such as cooling operation, heating operation, dehumidification operation, etc., the heat exchange with the detected value of the room temperature thermistor 35 or the detected value of the indoor humidity sensor 36 during the cooling operation or the dehumidifying operation. The detection value of the heat exchanger temperature detection thermistor 43 that is attached to the heat exchanger 5 and detects the temperature of the heat exchanger 5 is subjected to a comparison calculation process by the microcomputer 32. At this time, when the temperature of the heat exchanger 5 is equal to or lower than the dew point and water can be generated, this water can be used for electrostatic atomization.

  In order to use this, it is necessary to connect the front or rear dew tray (50a, 50b) to the water reservoir 16. Alternatively, it is sufficient that the water retaining material 17 is in contact with the dew trays (50a, 50b) and can absorb water. In the present embodiment, the electrostatic atomizer 14 including the water guiding means 18 is located as indicated by reference numeral 8 in FIG. 1 and is disposed adjacent to the ventilation passage. Therefore, it is easy to configure the dew trays (50a, 50b) and the water reservoir 16 to communicate with each other. Moreover, you may make it connect these via the water holding material 17, even if it does not communicate directly. By configuring as described above, water generated in the heat exchanger 5 can be diverted during the cooling operation or the dehumidifying operation.

  Next, switching control of the applied voltage to the Peltier element 23 and switching control of the number of rotations of the cooling fan (ventilation fan 8) will be described with reference to FIGS. The voltage applied to the Peltier element 23 and the rotational speed of the fan are controlled so as to change depending on the detected values of the room temperature thermistor 35, the indoor humidity sensor 36, the outdoor air temperature thermistor 37, and the outdoor humidity sensor 38.

  Further, the microcomputer 32 compares the value detected by the room temperature thermistor 35 or the room humidity sensor 36 with the arbitrarily set value stored in the memory 44, and outputs the DC / DC converter 33, that is, the Peltier element. The temperature of the cooling plate 24 is controlled by controlling the voltage applied to 23. When the microcomputer 32 determines that the environment is likely to cause dew condensation, it is possible to secure water by dew condensation even if the voltage applied to the Peltier element 23 is reduced, thus saving power consumption. Can do.

  Among the above, when controlling the applied voltage to the Peltier element based on the room temperature, if it is determined that the temperature is high, the applied voltage is increased to increase the heat absorption capability of the Peltier element 23, and the cooling plate 24. The temperature is controlled to be lowered. Further, since the heat dissipation efficiency of the heat radiating plate 25 is poor under a high temperature environment, control is performed so as to increase the ventilation rate by increasing the rotational speed of the fan to promote heat dissipation.

  Among the above, when controlling the voltage applied to the Peltier element based on the indoor humidity, when it is determined that the environment is a high humidity environment, the temperature of the cooling plate 24 is set because the dew point temperature is high. It can be easily lowered to the dew point temperature, and there is a possibility of dew dripping due to excessive collection of water. For this reason, control is performed to keep the applied voltage to the Peltier element 23 low and to reduce the rotational speed of the fan. Thereby, excessive collection of water can be prevented. Also at this time, the temperature of the cooling plate 24 is kept below the dew point.

  Further, the value detected by the outside air temperature thermistor 37 or the outdoor humidity sensor 38 is communicated by the communication circuit 41, and the arbitrarily set value stored in the memory 44 is compared with the microcomputer 32, and the DC / The temperature of the cooling plate 24 can also be controlled by controlling the output of the DC converter 33, that is, the voltage applied to the Peltier element 23.

  In addition, it is conceivable to store in the memory 44 in advance a condition (for example, a high temperature and high humidity condition) that is a temperature and humidity that are easily lowered to the dew point and that allows a large amount of water to be generated. These conditions and the value obtained from the room temperature thermistor 35 or the value obtained from the indoor humidity sensor 36 are compared with an arbitrary set value stored in the memory 44 by the microcomputer 32, and the result is sent to the Peltier device 23. May be controlled such that the applied voltage is allowed for a certain period of time and then energization is stopped for a certain period of time, or energization is prohibited. Alternatively, the energization of the Peltier element 23 may be limited as described above, and the operation of the ventilation fan 8 may be stopped.

  In other words, it is an operation to stop the generation of water on the assumption that water has accumulated sufficiently. In addition, for example, if excessive dew condensation occurs on the resin cover 20 covering the periphery of the dust collection discharge electrode 22 and the mist ion discharge electrode 15, an electric circuit may be generated to cause electric leakage. Therefore, it may be controlled such that the time for energizing the Peltier element 23 is T1 (for example, 3 hours) and the time for de-energizing is T2 (for example, 1 hour). Of course, T may be set arbitrarily such as 30 minutes, 45 minutes, 60 minutes, and the like. Also at this time, since water is in the water reservoir 16 and the water retaining material 17, the electrostatic atomization function can be exhibited by energizing the electrodes (15, 22).

  Further, when the humidity is too high, for example, 80% or more, the operation of the electrostatic atomizer 14 is prohibited in order to prevent the problem of dripping and the electric leakage. At this time, in addition to stopping energization to the Peltier element 23, no voltage is applied to the mist ion discharge electrode 15.

  In addition, a condition that the dew point is below the freezing point, the surface of the cooling plate 24 freezes, and water cannot be generated (for example, a situation where the dew point temperature is low such as when the temperature is low and low humidity) may be stored in the memory 44 in advance. Conceivable. These conditions, the value obtained from the room temperature thermistor 35 or the value of the indoor humidity sensor 36, and the arbitrarily set value stored in the memory 44 are compared and calculated by the microcomputer 32, and applied to the Peltier element 23. The voltage, the output of the high voltage generator 19 and the operation of the ventilation fan 8 are prohibited. That is, when the temperature of the cooling plate 24 does not drop below the dew point and water cannot be generated, or when water cannot be generated due to freezing, mist ions cannot be generated, so the operation of the electrostatic atomizer 14 is automatically stopped.

  In addition, condensation may occur due to a temperature difference when the outside air and indoor air are ventilated. For example, when the air supply operation is performed by the ventilation fan 8 in winter, the outdoor air supplied is cold and the room is warmer. In this case, since a temperature difference is generated between the temperature of the air supplied from outside and the temperature of the indoor ventilation fan 8, dew condensation may occur in the ventilation fan, and dew may come out of the ventilation fan. Therefore, the difference between the value obtained by the room temperature thermistor 35 and the value obtained by the outside air temperature thermistor 37 is compared with the arbitrarily set value stored in the memory 44 and the microcomputer 32, and the ventilation fan 8, The operation of the DC / DC converter 33 and the high voltage generator 19 is prohibited. That is, since dew may come out from the ventilation fan 8, the operation of the electrostatic atomizer 14 is automatically stopped at this time.

  If the temperature is too high, high humidity, low temperature, or low humidity, problems such as excessive collection of water or freezing may occur. Yes.

  In the air conditioner with an electrostatic atomizer in this embodiment, the number of revolutions of the cooling fan is controlled based on the values of the room temperature thermistor and the indoor humidity sensor, and forced cooling is performed to promote heat dissipation on the heat dissipation surface. The temperature on the cooling surface side of the element is controlled. Further, the temperature of the cooling plate can be stably reduced to the dew point or less by combining the switching of the output of the DC / DC converter that is the power source of the Peltier element to a plurality of stages. As a result, water can be generated according to various indoor temperature and humidity conditions. Therefore, the electrostatic atomization function can be exhibited in both cold winter and hot summer. Note that the electrostatic atomization function is stopped when water cannot be generated or when water is excessively generated. As described above, the electrostatic atomization function can be realized without supplying water, and the electrostatic atomization function can be realized without maintenance.

DESCRIPTION OF SYMBOLS 1 Air conditioner 2 Air inlet 3 Air outlet 4 Housing 5 Heat exchanger 6 Filter 7 Blower fan 8 Ventilation fan 9 Ventilation hose 10 Indoor unit 11 Cable 12 Pipe 13 Outdoor unit 14 Electrostatic atomizer 15 Discharge for mist ion Electrode 16 Water reservoir 17 Water retaining material 18 Water guide means 19 High voltage generator 20 Resin cover 21 Ground 22 Dust collection discharge electrode 23 Peltier element 24 Cooling plate 25 Heat sink 26 Insulating sheet 27 Silicon grease 28 Water generator 30 Switching transformer 31 Commercial Power Supply 32 Microcomputer 33 DC / DC Converter 34 Output Switching Circuit 35 Room Temperature Thermistor 36 Indoor Humidity Sensor 37 Outdoor Air Temperature Thermistor 38 Outdoor Humidity Sensor 39 Outdoor Unit Microcomputer 40 Display Unit 41 Communication Circuit 42 Current Detection Circuit 43 Dedicated Output Winding 44 Memory 45 Abnormal current detection circuit 50 Front dew tray 50b after the surface dew saucer

Claims (20)

An air conditioner that achieves an electrostatic atomization function using a Peltier element,
A cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element;
A room temperature thermistor for detecting room temperature,
An air conditioner that controls the number of rotations of the cooling fan based on a detection value of the room temperature thermistor. In claim 1,
An air conditioner that controls a voltage applied to the Peltier element based on a detection value of the room temperature thermistor. An air conditioner that achieves an electrostatic atomization function using a Peltier element,
A cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element;
An indoor humidity sensor for detecting indoor humidity,
An air conditioner that controls the number of rotations of the cooling fan based on a detection value of the indoor humidity sensor. In any of Claims 3,
An air conditioner that controls a voltage applied to the Peltier element based on a detection value of the indoor humidity sensor. In any one of Claims 1 thru | or 4,
The cooling fan is a ventilation fan used for ventilation between the room and the outside,
An air conditioner characterized in that a part of the ventilation path of the ventilation fan and the heat radiating plate are integrally formed. In claim 1 or 3,
Using a DC / DC converter as a power source for the Peltier element,
An air conditioner characterized in that the output of the DC / DC converter can be changed in a plurality of stages. In claim 6,
The air conditioner according to claim 1, wherein the power source of the Peltier element is created by stepping down the control voltage of a microcomputer or the like with the DC / DC converter. In claim 6,
An air conditioner characterized in that the power source of the Peltier element can be stepped down from a dedicated voltage insulated from a commercial power source by the DC / DC converter and adjusted to an arbitrary voltage. In claim 1,
A discharge electrode for generating water generated by the Peltier element as mist ions;
A voltage generator for generating mist ions by applying a voltage to the discharge electrode;
An air conditioner comprising an earth for grounding the voltage from the voltage generator to the ground. In claim 9,
An air conditioner comprising a discharge electrode made of a needle-like conductor to which a voltage is applied from the voltage generation unit. An outdoor unit equipped with an outdoor temperature thermistor for detecting the outdoor temperature;
An air conditioner that is connected to the outdoor unit by a communication cord and has an indoor unit that includes a Peltier element, and that achieves an electrostatic atomization function,
An air conditioner that includes a cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element in the indoor unit, and that controls the number of rotations of the cooling fan based on a detected value of the outside temperature thermistor. In claim 11,
An air conditioner that controls a voltage applied to the Peltier element based on a detection value of the outside temperature thermistor. An outdoor unit equipped with an outdoor humidity sensor for detecting outdoor humidity;
An air conditioner that is connected to the outdoor unit by a communication cord and has an indoor unit that includes a Peltier element, and that achieves an electrostatic atomization function,
An air conditioner that includes a cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element in the indoor unit, and that controls the number of rotations of the cooling fan based on a detection value of the outdoor humidity sensor. In claim 13,
An air conditioner that controls a voltage applied to the Peltier element based on a detection value of the outdoor humidity sensor. An outdoor unit equipped with an outdoor temperature thermistor for detecting the outdoor temperature;
An air conditioner that is connected to the outdoor unit by a communication cord, has an Peltier element, and an indoor unit that includes a room temperature thermistor that detects a room temperature, and achieves an electrostatic atomization function,
The indoor unit includes a cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element, and the number of rotations of the cooling fan is determined based on a difference between a detected value of the room temperature thermistor and a detected value of the outside temperature thermistor. Air conditioner to control. In claim 15,
An air conditioner that controls a voltage applied to the Peltier element based on a difference between a detected value of the room temperature thermistor and a detected value of the outside temperature thermistor. In claim 1,
An air conditioner characterized in that a current detection circuit that flows through the Peltier element is provided, and the number of rotations of the cooling fan and / or the voltage applied to the Peltier element is controlled by the obtained current value. In claim 17,
An air conditioner characterized in that when an abnormal current is detected by the current detection circuit, the power supply of the cooling fan and / or the Peltier element is stopped. In claim 1,
A discharge electrode for generating water generated by the Peltier element as mist ions;
A voltage generator for generating mist ions by applying a voltage to the discharge electrode;
An abnormal current detection circuit for determining an abnormality of the applied voltage,
The air conditioner characterized by shutting off the output of the voltage generator when an abnormal current flows through the discharge electrode. In claim 19,
An air conditioner comprising an insulating sheet between the Peltier element and the discharge electrode.

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