KR100904796B1 - Air conditioner - Google Patents

Abstract

An object of the present invention is to provide an air conditioner capable of exhibiting an electrostatic atomization function with no water supply under various conditions. Moreover, it aims at providing the air conditioner which can exhibit the electrostatic atomization function by maintenance free.

An air conditioner that achieves an electrostatic atomization function using a Peltier element, comprising a cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element, and a room temperature thermistor for detecting room temperature, and based on the detected value of the room temperature thermistor. Control the number of revolutions.

Air conditioner, room temperature thermistor, cooling fan, electrostatic atomizer, casing

Description

Air conditioner {AIR CONDITIONER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner having an air cleaning function for deodorizing and damping indoor air and for cleaning air.

BACKGROUND ART An air conditioner capable of obtaining water required for electrostatic atomization from the air and deodorizing indoor air by electrostatic atomization and deodorization of deposits such as an interior wall surface with unspecified water is known.

[Document 1] Japanese Unexamined Patent Publication No. 2006-149538

However, if it is water free, it is considered that water for electrostatic atomization is insufficient or water is not produced. It is also contemplated that excess water is produced. These problems can be basically solved by making the cooling surface of the Peltier element below the dew point temperature so as not to lower the temperature excessively. However, it is not necessarily solved by controlling the driving power supply of the Peltier element. In particular, the following three conditions are considered when the operating conditions, that is, room temperature, humidity, and the like are variously changed.

First, conditions under which water is unlikely to be produced are considered. For example, it is an operating condition such as lack of generation of water occurring at low temperature and low humidity, lack of generation of water due to lack of heat radiation at high temperature. In low temperature and low humidity, since the dew point temperature is also low, there exists a problem that the cooling surface of a Peltier element falls to the dew point temperature. On the contrary, since the temperature of a heat dissipation surface becomes difficult to fall in high temperature conditions with high room temperature, there exists a problem of the cooling surface of a Peltier element falling to dew point temperature. These are all the conditions under which the Peltier device lacks the heat absorbing ability, that is, water cannot be produced due to the characteristics of the Peltier device.

Secondly, as the freezing surface of the Peltier device freezes, the condition that the room temperature is low is considered. At low temperatures, since the temperature of the cooling surface tends to be lowered and the dew point temperature may also be below zero, freezing may result in the formation of water.

Third, the condition that humidity is very high and excess quantity is produced is considered. This may cause the electrostatic atomizer to be flooded, and water may overflow inside the air conditioner. Further, water leakage from the air conditioner into the room is also considered.

Therefore, an object of the present invention is to provide an air conditioner capable of exhibiting an electrostatic atomization function with no water supply under various conditions. Moreover, it aims at providing the air conditioner which can exhibit the electrostatic atomization function by maintenance free.

The purpose is

Air conditioner to achieve the electrostatic atomization function using the 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 rotation speed of the cooling fan based on the detected value of the room temperature thermistor.

In addition, the above object,

Air conditioner to achieve the electrostatic atomization function using the Peltier element,

A cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element,

It is equipped with the indoor humidity sensor which detects humidity in a room,

This is achieved by controlling the rotation speed of the cooling fan based on the detected value of the indoor humidity sensor.

In addition, the above object,

An outdoor unit having an outside air temperature thermistor for detecting outdoor temperature,

Is an air conditioner connected by the outdoor unit and a communication cord and having an indoor unit having a Peltier element, to achieve the electrostatic atomization function,

The indoor unit is provided with a cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element,

This is achieved by controlling the rotation speed of the cooling fan based on the detected value of the outside air temperature thermistor.

In addition, the above object,

An outdoor unit having an outdoor humidity sensor for detecting outdoor humidity,

Is an air conditioner connected by the outdoor unit and a communication cord and having an indoor unit having a Peltier element, to achieve the electrostatic atomization function,

The indoor unit is provided with a cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element,

This is achieved by controlling the rotation speed of the cooling fan based on the detected value of the outdoor humidity sensor.

In addition, the above object,

An outdoor unit having an outside air temperature thermistor for detecting outdoor temperature,

Is an air conditioner having an indoor unit having a Peltier element and a room temperature thermistor detecting room temperature, connected by the outdoor unit and a communication cord, and achieving an electrostatic atomization function,

The indoor unit is provided with a cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element,

This is achieved by controlling the rotation speed of the cooling fan based on the difference between the detected value of the room temperature thermistor and the detected value of the outside air temperature thermistor.

Under various conditions, it is possible to realize an air conditioner capable of exhibiting an electrostatic atomization function with no water supply. Moreover, the air conditioner which can exhibit the electrostatic atomization function by maintenance free can be implement | achieved.

EMBODIMENT OF THE INVENTION Below, embodiment of this invention is described.

The air conditioner 1 shown in FIG. 1 is composed of an indoor unit 10 and an outdoor unit 13. The indoor unit 10 and the outdoor unit 13 are connected by a power supply and communication cable 11 and a pipe 12 for transferring a refrigerant. The indoor unit 10 is constituted by its casing 4, and the casing 4 is provided with an air intake port 2 and an air blowout port 3. In the casing 4, a heat exchanger 5, a filter 6 sputtered with metal, a blower fan 7 that blows air out of the air outlet 3, and indoor and outdoor air are ventilated. A ventilation fan 8 is arranged. In addition, the filter 6 is arranged between the air inlet 2 and the heat exchanger 5, and only the approximate position where the ventilation fan 8 is arranged is shown in FIG. In addition, the ventilation hose 9 comes out from the indoor unit 10.

Next, as a configuration in the present invention, the configuration diagram of the electrostatic atomizer in FIGS. 2 and 3, the external structure of the electrostatic atomizer in FIGS. 4, 5, and 6, the circuit configuration in FIGS. 9, a control example is shown.

In the indoor unit 10, the electrostatic atomization device 14 shown in FIG. 2 is provided. The electrostatic atomization device 14 is comprised by the water guide means 18, the high voltage generator 19 etc. which generate a high voltage of about -6 kV. The water guide means 18 includes a rod-shaped mist ion discharge electrode 15 made of a porous material, a water storage unit 16 for supplying water to the mist ion discharge electrode 15, and a water retaining material 17. Equipped. The water holding material 17 is arrange | positioned between the water storage part 16 and the discharge electrode for mist ions, and is comprised with the thing like the sponge which sucks up and hold | maintains the water stored in the water storage part 16. As shown in FIG.

Here, the discharge electrode 15 for mist ions is absorbent like the pen tip of a felt pen, and sucks water from the water holding material 17 by capillary phenomenon. In this way, the high voltage generator 19 applies a high voltage to the discharge electrode 15 for mist ions in the state containing the absorbed water. Then, water of the charged fine particles is discharged from the discharge electrode for mist ions 15 to generate dew ions (mist ions). This mist ion has the effect of deodorization and disinfection. The mist ions are burned by the wind from the air blower outlet 3 and diffused into the room.

At this time, since mist ions are discharged from the mist-ion discharge electrode 15 and water is consumed, it is necessary to supply water to the water guide means 18 in order to operate the electrostatic atomization device 14. That is, it is necessary for the mist ion discharge electrode 15 to suck up water from the water holding material 17 even until water is stored or not stored in the water storage unit 16. However, since the indoor unit 10 is usually installed on a wall near the ceiling of the room, it takes a very long time for the user to supply water. Thus, the water is stored in the water storage unit 16 from the moisture in the air so as to be completed without supplying water by the user, thereby producing water to be maintained in the water retaining material 17. For this reason, the water generating device 28 uses a Peltier element like the document 1, in order to generate the water supplied to the water guide means 18. The Peltier element 23 is an element whose surface temperature is divided into a cooling surface and a heat radiation surface when it is energized. Therefore, when electricity is supplied to the Peltier element 23 and the cooling surface is set to the dew point temperature (also referred to as dew point) or lower, and the cooling surface is condensed, water can be generated.

The water generator 28 includes the Peltier element 23, silicon grease 27 for reducing the contact heat resistance between the Peltier element 23 on the cooling surface side of the Peltier element 23, the insulating sheet 26 and And a metallic cooling plate 24. The insulating sheet 26 is disposed to prevent a short circuit from the high voltage generator 19 to the Peltier element 23. Although the high voltage generated by the high voltage generator 19 may be applied from the water path (hereinafter referred to as converter) to the Peltier element 23 via the discharge electrode for mist ions 15 and the water retaining material 17, the insulating sheet 26 Application of the voltage 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 converter.

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 further, the temperature of the cooling plate 24 is lowered to below the dew point. As a result, air around the cooling plate 24 is cooled, condensation occurs on the surface of the cooling plate 24, and water is generated. In this case, the water storage unit 16 may be disposed at a position where water droplets are collected from the cooling plate 24. Alternatively, the water may be directly absorbed into the water holding material 17. As described above, water is stored in the water storage unit 16 by keeping the cooling surface of the Peltier element 23 below the dew point. Alternatively, the discharge electrode for mist ions 15 may suck up water from the water retaining material 17 until it is not stored.

In addition, the water generator 28 includes a metal heat sink 25 provided on the heat dissipation surface side of the Peltier element 23 to promote heat dissipation of the Peltier element 23. The Peltier element 23 has a characteristic that it is difficult to lower the temperature of the cooling surface unless the temperature of the heat dissipation surface is lowered. In other words, when the temperature of the heat dissipation surface decreases, the temperature of the cooling surface tends to decrease. Therefore, the heat sink 25 is provided so that even a little characteristic may become favorable. In addition, a cooling fan for promoting heat dissipation of the heat sink 25 is provided. This cooling fan promotes heat dissipation of the heat dissipation plate 25, and further promotes lowering the temperature of the heat dissipation surface. In addition, the ventilation fan 8 is useful as a cooling fan, and a part of the ventilation path of the ventilation fan 8 and the heat sink 25 are structured so that heat dissipation can be promoted. If the integral structure is difficult, the wall of the ventilation path and the heat sink 25 may be thermally contacted.

The ventilation fan 8 is provided in the indoor unit 10, and is comprised by a siloco fan or a propeller fan. A ventilation hose 9 is connected to the ventilation fan 8, and the ventilation hose 9 comes out together with the pipe 12. By rotating the ventilation fan 8, outdoor air can be blown into the room (air supply), or the air path can be switched to discharge (exhaust) the indoor air to the outside. The switching of the air supply operation, the exhaust operation, and the supply / exhaust operation stop may be configured so that the user can also perform it manually. In the present embodiment, a part of the ventilation path (for example, reference numeral 25 in FIG. 3) connected to the ventilation hose 9 from the ventilation fan 8 is integrally formed with the heat sink 25, so that the air supply and the exhaust air are exhausted. The heat sink is forcibly cooled by the flow of air passing through the ventilation path.

Apart from the mist ion discharge electrode 15, the high voltage generator 19 is configured such that the needle-shaped dust-collecting discharge electrode 22 made of a conductor can be conductive. By applying a high voltage thereto, corona discharge occurs from the distal end of the dust discharge electrode 22, so that dust in the space can be charged. The dust charged in this way is easily adsorbed by giving electric potential to the filter 6 sputtered with metal, and the dust collection effect can be improved.

The resin covers 20 are installed on the electrodes 15 and 22 to which the high voltage is applied for safety so that the user does not directly contact them. The earth 21 is connected to the heat exchanger 5, passes through the pipe 12 from the heat exchanger 5, passes through the outdoor unit 13 from the pipe 12, and is grounded from the outdoor unit 13 to the ground. It consists.

Since the high voltage is applied to the mist discharge electrode 15 and the dust discharge electrode 22 to discharge negative ions, the resin cover 20 itself may be charged, and the user may feel static electricity when the user contacts the cover. It is assumed. In addition, the cooling of the Peltier element 23 may cause excessive condensation on the surface of the resin cover 20, and may cause electric shock if a short circuit is formed. In contrast, the earth 21 is provided in the resin cover 20. This discharges the voltage to a ground potential, thereby ensuring safety.

The power supply of the Peltier element 23 is generated by stepping down the DC / DC converter 33 from control voltages such as the microcomputer 32 insulated from the commercial power supply 31 by the insulating switching transformer 30 (Fig. 7). In addition, as shown in FIG. 8, the power supply of the Peltier element 23 is a dedicated output provided separately from the control voltage of the microcomputer 32 or the like which is insulated from the commercial power supply 31 by the insulating switching transformer 30. The output of the winding line 43 may be produced by stepping down the DC / DC converter 33.

In addition, the output of the DC / DC converter 33, that is, the voltage applied to the Peltier element 23 is configured so that the output can be switched in multiple stages by the output switching circuit 34. For example, Figure 9, configured to be switched to V ₁ and _{V 2 (V 2> V 1} ) , as shown in Fig. When the heat absorbing ability 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. In addition, the voltage is controlled from V ₂ to V ₁ so that the excess furnace temperature is lowered excessively so that water is not generated excessively.

The indoor unit 10 is provided with a room temperature thermistor 35 capable of detecting room temperature, and an indoor humidity sensor 36 capable of detecting indoor humidity. These are installed in the suction port of the indoor unit. That is, the temperature and humidity of the air before passing through the heat exchanger are detected. A comparison value is processed by the microcomputer 32 with an arbitrary set value that stores the detected value detected by the room temperature thermistor 35 or the indoor humidity sensor 36 in the memory 442 to determine the air volume of the ventilation fan 8. To control. As a result, the heat dissipation is controlled by the optimum amount of air required for the heat dissipation of the heat dissipation plate 25, and the temperature of the cooling plate 24 is set to be below the dew point. In addition, the temperature of the cooling plate 24 is maintained at an appropriate temperature so that freezing by supercooling does not occur.

The amount of air blown out by the cooling fan, that is, the rotation speed of the cooling fan is determined by the detected value of the room temperature thermistor 35 for detecting the temperature of the room mounted on the indoor unit 10 or the indoor humidity sensor 36 for detecting the humidity of the room. It is controlled based on the detected value. Then, by varying the rotation speed of the cooling fan, it is possible to promote heat dissipation and achieve a stable dew point temperature. Moreover, when there is a margin at the dew point temperature, it is comprised so that fan rotation speed may be suppressed. If there is no need in consideration of the user's comfort, the number of revolutions is lowered and the noise is suppressed to be quiet.

At this time, if the rotation speed of the fan is controlled based on the detected value of the room temperature thermistor 35, that is, the room temperature, the heat dissipation amount of the heat sink 25 can be optimally maintained, and further, the temperature of the cooling plate 24 is optimally maintained. I can keep it. Therefore, it is possible to prevent freezing by overcooling and to prevent water shortage due to insufficient cooling. Thus, since the temperature of the cooling plate 24 can be controlled suitably below the dew point, quantity can be secured stably.

In addition, the rotation speed of the fan can be controlled even on the basis of 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 below the dew point temperature even if the endothermic amount of the Peltier element 23 is small. Therefore, in high humidity conditions, the rotation speed of a fan is made low and the production | generation of excess water is prevented. Lower fan speed reduces noise and improves user comfort.

In addition, under extreme high humidity conditions, such as 80% or more, for example, dew drop, leakage, or the like due to excessive water collection is considered, the fan is stopped and the endothermic amount of the Peltier element 23 is reduced. In addition, the electrostatic atomization device 14 is stopped to prevent problems such as dew dropping and electric leakage. The stop of the electrostatic atomizing device 14 does not apply a voltage to the discharge electrode 15 for mist ions in addition to stopping supply of electricity to the Peltier element 23.

On the other hand, in low humidity conditions, since the dew point temperature is low, the endothermic amount of the Peltier element 23 must be increased. At this time, if the rotation speed of the fan is increased, the heat dissipation amount of the heat sink 25 can be increased, so that the temperature of the cooling plate 24 can be kept below the dew point, and water can be stably supplied to the discharge electrode 15 for mist ions. have.

In addition, if the rotation speed of the fan is optimally controlled on the basis of room temperature and humidity, the electrostatic atomization function can be stably operated by supplying water to the electrode more stably.

In addition, the amount of air blown out by the cooling fan, that is, the number of revolutions of the cooling fan is measured by the outdoor temperature thermistor 37 that detects the outdoor temperature mounted in the outdoor unit 13 or the outdoor humidity sensor 38 that detects the outdoor humidity. Control may also be performed based on the detected value of. The outdoor unit 13 is provided with an outdoor temperature thermistor 37 capable of detecting outdoor temperature, and an outdoor humidity sensor 38 capable of detecting outdoor humidity. The detected value detected by the outside air temperature thermistor 37 or the outdoor humidity sensor 38 is processed by the microcomputer 39 for the outdoor unit, passed through a cable, communicated by the communication circuit 41, and provided in the indoor unit 10. The predetermined setting value stored in the memory 44 and the microcomputer 32 perform comparative calculation processing to control the air volume of the ventilation fan 8. As a result, the heat dissipation is controlled by the optimum amount of air required for the heat dissipation of the heat dissipation plate 25, and the temperature of the cooling plate 24 is set to be below the dew point. In addition, the temperature of the cooling plate 24 is maintained at an appropriate temperature so that freezing by supercooling does not occur.

In addition, the DC / DC converter 33 is provided with a current detection circuit 42. Therefore, when the current value of the current flowing through the Peltier element 23 detected by the current detection circuit 42 and the current value in the normal range stored in advance in the microcomputer 32 or the like are compared, and the current value is out of range, The electricity to the Peltier element 23 is cut off immediately. In addition, the display unit 40 installed in the indoor unit 10 may be notified to the user of an abnormality by a lamp or a buzzer with the interruption of energization. That is, the interruption of energization to the Peltier element 23 is controlled based on the detection value of the current detection circuit 42 which detects the current flowing in the Peltier element 23.

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

In addition, the high voltage generator 19 is provided with an abnormal current detection circuit 45. Since high voltages such as -6 kW are applied to the discharge electrode 15 for mist ions and the discharge electrode 22 for dust collection, when the conductive foreign matter such as dust adheres, it is possible to short-circuit and ignite the foreign matter by sparks. do. Therefore, the abnormal current detection circuit 45 for detecting the abnormal current flowing by the short circuit is provided inside the high voltage generator 19, and when the abnormal current is detected, the output voltage of the high voltage generator 19 is cut off immediately.

The electric current is prevented from being discharged to the mist ion discharge electrode 15 and the dust discharge electrode 22 to prevent sparking caused by a short circuit, and in principle, ignition of conductive foreign substances such as dust is prevented. The abnormal current detection circuit 45 cuts the output voltage and transmits an abnormal signal to the microcomputer 32. The microcomputer 32 recognizes the abnormality of the system by receiving the abnormal signal, and stops the ventilation fan 8 and the DC / DC converter 33. Here, the display unit 40 may notify the user of an abnormality by a lamp (for example, an LED lamp) or a buzzer. The above notification can prompt the cleaning and repair of the electrode.

In the above, the temperature of the cooling surface is controlled, flowing a current through the Peltier element 23. This 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 dissipation surface increases by allowing a large amount of current to flow. For this reason, the voltage applied to the Peltier element 23 is configured to be variable, and the temperature of the cooling plate 24 is adjusted to prevent overcooling and lack of cooling in response to room temperature, outside air temperature, indoor humidity or outdoor humidity, or a combination thereof. Can be controlled. Thus, since the temperature of the cooling plate 24 can be controlled suitably below the dew point, quantity can be secured stably.

When the air conditioner 1 switches operation modes such as cooling operation, heating operation, dehumidification operation, and the like, the detected value of the room temperature thermistor 35 or the indoor humidity sensor 36 during the cooling operation or the dehumidification operation. The detection value and the detection value of the heat exchanger temperature detection thermistor 43 which is provided in the heat exchanger 5 and detects the temperature of the heat exchanger 5 are compared and processed by the microcomputer 32. At this time, when the temperature of the heat exchanger 5 was a condition which can generate water below a dew point, this water can be used for electrostatic atomization.

In order to use this, it is necessary to make the dew tray 50a, 50b of the front surface or the back surface communicate with the water storage part 16. FIG. Alternatively, the water retaining material 17 may be in contact with the dew receiving plates 50a and 50b and may be absorbed. In this embodiment, the electrostatic atomization device 14 including the water guide means 18 is indicated by reference numeral 8 in FIG. 1 and is disposed adjacent to the ventilation passage. Therefore, the structure which makes the dew receiving plates 50a and 50b and the water storage part 16 communicate can be performed easily. Moreover, you may make them communicate through the water holding material 17, even if it does not communicate directly. By configuring in this way, the water produced by the heat exchanger 5 at the time of a cooling operation or a dehumidification operation can be useful.

Next, the switching control of the applied voltage to the Peltier element 23 and the rotation control of the cooling fan (ventilation fan 8) are demonstrated using FIG.9, FIG.10. The voltage applied to the Peltier element 23 and the rotation speed of the fan are controlled so as to change in accordance with the detected values of the room temperature thermistor 35, the indoor humidity sensor 36, the outside air temperature thermistor 37, and the outdoor humidity sensor 38. .

In addition, the arithmetic processing is performed by the microcomputer 32 with an arbitrary set value which stores the value detected by the room temperature thermistor 35 or the indoor humidity sensor 36 in the memory 44, and the DC / DC converter ( The temperature of the cooling plate 24 is controlled by controlling the output of 33, that is, the voltage applied to the Peltier element 23. In the case where it is determined that the microcomputer 32 is easily condensed, even if the voltage applied to the Peltier element 23 is reduced, water can be condensed to secure water, thereby saving power consumption.

In the case of controlling the voltage applied to the Peltier element on the basis of the room temperature, when it is determined that the environment is a high temperature, the applied voltage is increased to increase the heat absorbing ability of the Peltier element 23, Controlled to lower the temperature. In addition, in a high temperature environment, the heat radiation efficiency of the heat dissipation plate 25 is poor, so that the rotation speed of the fan is increased to increase the amount of ventilation and to control heat dissipation.

In the case of controlling the voltage applied to the Peltier element on the basis of the indoor humidity, the dew point temperature is high when it is determined that the environment is high humidity. Therefore, the temperature of the cooling plate 24 is easily increased to the dew point temperature. It is possible to lower, and furthermore, it is considered that there is a fear of dew drop due to excessive collection of water. For this reason, the control which suppresses the voltage applied to the Peltier element 23 is made low and the rotation speed of a fan is made low. Thereby, excessive collection of water can be prevented. At this time, the temperature of the cooling plate 24 is kept below the dew point.

In addition, the value detected by the outside air temperature thermistor 37 or the outdoor humidity sensor 38 communicates with the communication circuit 41 and the arbitrary setting value stored in the memory 44 by the microcomputer 32. The temperature of the cooling plate 24 can be controlled by performing arithmetic processing to control the output of the DC / DC converter 33, that is, the voltage applied to the Peltier element 23.

In addition, it is conceivable to store in advance the conditions in which the temperature which is easy to fall to the dew point is also humidity, and the conditions under which a large amount of water is produced (for example, a situation of high temperature and high humidity) are stored in the memory 44 in advance. 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 with the microcomputer 32 to perform the Peltier element 23. ) May be allowed to be allowed for a certain time, and then control such as stopping the energization for a predetermined time or prohibiting the energization. Alternatively, the electricity supply to the Peltier element 23 may be restricted in this manner, and the operation of the ventilation fan 8 may be stopped.

In other words, it is determined that the water has been sufficiently stored and stops the generation of the water. In addition, when excessive condensation occurs on the resin cover 20 covering the periphery of the discharge electrode 22 for dust collection and the discharge ion 15 for mist ions, for example, there is a possibility that a converter is generated and a short circuit occurs. Therefore, you may control so that time to energize the Peltier element 23 may be T1 (for example, 3 hours), and time for non-energization may be T2 (for example, 1 hour). Of course, T may be set arbitrarily, such as 30 minutes, 45 minutes, and 60 minutes. At this time, since water is in the water storage part 16 and the water holding material 17, when an electric current is supplied to the electrodes 15 and 22, an electrostatic atomization function can be exhibited.

In addition, in the case of very high humidity, such as 80% or more, for example, the operation of the electrostatic atomizing device 14 is prohibited in order to prevent the problem of dropping dew or the short circuit. At this time, in addition to stopping the energization to the Peltier element 23, no voltage is applied to the discharge electrode 15 for mist ions.

In addition, the memory 44 may store in advance the conditions such as the dew point being below zero and the surface of the cooling plate 24 freezing to generate water (for example, a low dew point temperature such as low temperature and low humidity). Positioning is considered. These conditions, the value obtained from the room temperature thermistor 35, or the value of the indoor humidity sensor 36, and any set value stored in the memory 44 are compared and calculated by the microcomputer 32, so that the Peltier element 23 The voltage applied to the furnace, 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 fall below the dew point, water cannot be generated, or when water cannot be generated by freezing, mist ions cannot be generated. Stops driving.

In addition, condensation may occur due to a temperature difference when the outside air and the indoor air are ventilated. For example, when the air supply is driven by the ventilation fan 8 in winter, the outdoor air that has been supplied is cold, and the room is warm. In this case, since a temperature difference occurs between the temperature of the air supplied from the 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 an arbitrary set value stored in the memory 44 with the microcomputer 32 for ventilation. Operation of the fan 8, the DC / DC converter 33, and the high voltage generator 19 is prohibited. That is, since dew may come out of the ventilation fan 8, the operation | movement of the electrostatic atomizer 14 is stopped automatically at this time.

In conditions of very high temperature, high humidity, low temperature, and low humidity, problems such as excessive collection of water, freezing, etc. may occur. Thus, the control is performed such as to limit the energization time as described above.

In the air conditioner with an electrostatic atomizer according to the present embodiment, the Peltier element is controlled by controlling the rotation speed of the cooling fan based on the values of the room temperature thermistor and the indoor humidity sensor, and performing forced cooling to prompt heat dissipation of the heat dissipation surface. The temperature on the cooling surface side of is controlled. In addition, the temperature of the cooling plate can be stably lower than the dew point by combining the switching of the output of the DC / DC converter, which is the power source of the Peltier element, into multiple stages. As a result, water can be generated in accordance with various indoor temperature and humidity conditions. Therefore, the electrostatic atomization function can be exhibited even in cold winter and hot summer. In addition, when the water cannot be produced or when the water is excessively generated, the electrostatic atomization function is stopped. As described above, the electrostatic atomization function can be realized with no water supply, and the electrostatic atomization function can be realized with maintenance-free.

1 is a diagram showing a configuration example of an air conditioner in an embodiment of the present invention.

Fig. 2 is a diagram showing a configuration example of an electrostatic atomizing device in the embodiment of the present invention.

Fig. 3 is a diagram showing an example of the configuration of a water generator in the embodiment of the present invention.

Fig. 4 is a diagram showing the external structure of the electrostatic atomization device in the embodiment of the present invention.

Fig. 5 shows the external structure of the electrostatic atomizing device in the embodiment of the present invention.

Fig. 6 is a diagram showing the external structure of the electrostatic atomization device in the embodiment of the present invention.

7 is a diagram showing an example of a circuit configuration in an embodiment of the present invention.

8 is a diagram showing an example of a circuit configuration in an embodiment of the present invention.

Fig. 9 is a diagram showing an example of control by the temperature detection value in the embodiment of the present invention.

Fig. 10 is a diagram showing an example of control by the humidity detection value in the embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

1: air conditioner

2: air intake

3: air outlet

4: casing

5: heat exchanger

6: filter

7: blower fan

8: ventilation fan

9: ventilation hose

10: indoor unit

11: cable

12: piping

13: outdoor unit

14: electrostatic atomization device

15: discharge electrode for mist ions

16: water storage unit

17: repair

18: water guide means

19: high voltage generator

20: resin cover

21: Earth

22: discharge electrode for dust collection

23: Peltier element

24: cold plate

25: heat sink

26: insulation sheet

27 siliconless

28: water generator

30: switching transformer

31: commercial power

32: microcomputer

33: DC / DC converter

34: output switching circuit

35: room temperature thermistor

36: indoor humidity sensor

37: Outer temperature thermistor

38: outdoor humidity sensor

39: microcomputer for outdoor unit

40: display unit

41: communication circuit

42: current detection circuit

43: dedicated output winding

44: memory

45: abnormal current detection circuit

50a: front dew tray

50b: rear dew tray

Claims (1)

To achieve the electrostatic atomization function using the Peltier element, A cooling fan for promoting heat dissipation of the heat dissipation surface of the Peltier element, a room temperature thermistor for detecting the temperature of the room, and an indoor humidity sensor for detecting the humidity of the room, An air conditioner that controls the rotation speed of the cooling fan and the voltage applied to the Peltier element based on the detected values of the room temperature thermistor and the indoor humidity sensor, When the detected values of the room temperature thermistor and the indoor humidity sensor are equal to or less than a predetermined value, the application of voltage to the cooling fan and the Peltier element is stopped, And when the detected value of the indoor humidity sensor is equal to or greater than a predetermined value, the rotation speed of the cooling fan and the applied voltage of the Peltier element are lowered than when the indoor humidity sensor is smaller than the predetermined value.

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