JP2017138057A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner which detects an operation of a compressor or a heater with a simple structure.SOLUTION: An air conditioner includes: a compressor; a tank for storing water; a float which vertically moves according to a water level in the tank; a magnet provided at the float; an electric wire which supplies electric power to the compressor; an anisotropic-magneto-resistance (AMR) sensor which detects a magnetic field of the magnet and a magnetic filed formed by an electric current flowing through the electric wire; and a control part which detects the water level of the tank and an operation of the compressor or the heater on the basis of a detection result of the AMR sensor.SELECTED DRAWING: Figure 9

Description

  The present invention relates to an air conditioner such as a dehumidifier, and more particularly to an air conditioner having an operation detection function of a compressor or a heater.

  A dehumidifier which is an example of an air conditioner is provided with a device to which power is supplied, such as a compressor and a heater. Power supply to these devices is controlled through a switch such as a relay. For example, if a switch fails due to welding of a relay, the compressor or the like is always energized, and the dehumidifier may break down.

  Here, for example, Patent Literature 1 discloses a device that detects a switch failure from ON / OFF of a plurality of switches and the temperature of a heater and notifies a user of the failure.

JP 2008-188512 A

  The technique of Patent Document 1 is premised on having a plurality of switches. For this reason, there are problems that the number of parts increases, the device configuration becomes complicated, and the cost increases.

  The present invention has been made in consideration of such circumstances, and an object thereof is to provide an air conditioner that can detect the operation of a compressor or a heater with a simple structure.

  In order to solve the above-described problems, an air conditioner according to the present invention is provided with a compressor or a heater, a tank for storing water, a float that moves up and down according to the water level in the tank, and the float. A magnet, an electric wire for supplying electric power to the compressor or heater, an AMR (Anisotropic-Magneto-Resistance) sensor for detecting a magnetic field formed by the magnetic field of the magnet and a current flowing through the electric wire, and detection of the AMR sensor A control unit that detects the water level of the tank and the operation of the compressor or the heater based on the result is provided.

  In the air conditioner according to the present invention, the operation of the compressor or the heater can be detected with a simple structure.

The external appearance perspective view of the dehumidifier in this embodiment. The disassembled perspective view of a dehumidifier. The longitudinal cross-sectional view of a dehumidifier. The schematic functional block diagram which shows the function structure of a dehumidifier. The perspective view which looked at the drain tank from the upper part. It is a figure which shows especially the floating accommodation part in which the floating seen from the inside of a drain tank was accommodated, (A) is a longitudinal cross-sectional view of a floating accommodation part, (B) shows the floating accommodation part when a float is inserted. The longitudinal cross-sectional view of a drain tank, (C) is a longitudinal cross-sectional view of a drain tank when the float of FIG. 6 (B) raises. The longitudinal cross-sectional view of the dehumidifier which demonstrates a full water detection unit especially. (A) is an external perspective view seen from the surface of the float, (B) is an external perspective view seen from the back surface of the float, and (C) is a vertical cross-sectional view of the float. The flowchart explaining the failure determination process performed by the dehumidifier in this embodiment. Explanatory drawing explaining the positional relationship of an AMR sensor and the electric wire of a compressor. The wave form diagram for demonstrating the output of the AMR sensor in the time of normal. The wave form diagram for demonstrating the output of the AMR sensor at the time of failure of a relay.

  An embodiment of an air conditioner according to the present invention will be described with reference to the accompanying drawings. In the present embodiment, the air conditioner of the present invention will be described as applied to a compressor type dehumidifier that uses a vapor compression refrigeration cycle to dehumidify moisture contained in the air.

FIG. 1 is an external perspective view of a dehumidifier 1 in the present embodiment.
FIG. 2 is an exploded perspective view of the dehumidifier 1.
FIG. 3 is a longitudinal sectional view of the dehumidifier 1.
FIG. 4 is a schematic functional block diagram showing a functional configuration of the dehumidifier 1.

  The dehumidifier 1 has a right frame 2, a left frame 3, a decorative board 4, and a base 5 that constitute the appearance of the dehumidifier 1. The upper end portion where the right frame 2 and the left frame 3 fit together forms a handle 10. The right frame 2 has a suction port 11 having a plurality of slits. The suction port 11 has a filter 13 and a filter case 14 on the outer surface 12 side. The filter 13 is made of a resin net or non-woven fabric, and removes dust, odorous components and the like mixed in the intake air. The filter case 14 attaches the filter 13 to the suction port 11. Further, the right frame 2 has a tank insertion port 16 to / from which the drain tank 15 is attached / detached at the lower portion of the suction port 11.

  The left frame 3 has an air outlet 20 having a plurality of slits in the upper part. The blower outlet 20 has the wind direction board 21 which can control the blowing direction of dry air from diagonally upward to a horizontal direction. The wind direction plate 21 is driven by a wind direction plate motor 22.

  The decorative board 4 has an operation unit 25 on the upper side. As shown in FIG. 2, the operation unit 25 includes an upper surface 26 of the decorative plate 4, an operation unit case 27, and an operation unit 28. The operation unit 25 includes, for example, switches 29 such as an operation switch, a timer switch, and an operation mode selection switch, and lamps 30 such as an operation lamp.

  The dehumidifier 1 includes a sirocco fan 31, a fan motor 32, a refrigeration apparatus, a drain tank 15, a control unit 34, and a full water detection mechanism as main internal components.

  The sirocco fan 31 has a rotational center that is coaxial with the rotational axis of the fan motor 32. The sirocco fan 31 forms an air path that sucks air from the suction port 11 and blows it out from the air outlet 20. The sirocco fan 31 and the fan motor 32 are attached to a fan case 36.

  The refrigeration apparatus includes a compressor 40, a condenser 41, a decompression device 42, an evaporator 43, and an accumulator 44 in the order in which the refrigerant flows. When the refrigerant flows through the evaporator 43, the refrigerant removes heat from the air passing outside the evaporator 43 and evaporates. Thereby, the surface of the evaporator 43 is cooled below the dew point temperature, and moisture in the air passing therethrough is condensed on the surface of the evaporator 43. Based on this principle, the dehumidifier 1 dehumidifies by removing moisture from the air.

  The compressor 40 is fixed on the base 5 and connected to the evaporator 43 and the condenser 41 via a pipe 45. The evaporator 43 and the condenser 41 are constituted by a first heat exchanger 48 and a second heat exchanger 49, respectively. The 1st heat exchanger 48 and the 2nd heat exchanger 49 are fin tube type heat exchangers, respectively, in the same air passage from the upstream side in the order of the 1st heat exchanger 48 and the 2nd heat exchanger 49. Has been placed. The evaporator 43 and the condenser 41 are fixed via a drain pan 50 on the surface of the fan case 36 opposite to the surface on which the sirocco fan 31 is fixed. The drain pan 50 receives the condensed water generated in the evaporator 43 and guides the condensed water from the drain port 51 to the drain tank 15.

  The compressor 40 is driven by a built-in AC motor (not shown), and has an electric wire 95 (FIG. 10) and a relay 96 (FIG. 4) provided on the electric wire 95. ing. The electric wire 95 supplies an AC voltage supplied from a commercial power supply via a power plug to the AC motor of the compressor 40. The relay 96 is turned on or off based on the control of the control unit 34 to turn on or off the supply of power to the compressor 40.

  With the above configuration, the air sucked from the suction port 11 is subjected to removal of dust and odor components by the filter 13, moisture is removed by the evaporator 43, further passes through the condenser 41, and is sirocco fan 31. It blows out from the blower outlet 20.

  The drain tank (tank) 15 stores the generated drain water drained from the drain port 51 of the drain pan 50. The drain tank 15 is attached to and detached from the fan case 36 through the tank insertion port 16 by sliding in the horizontal direction. The drain tank 15 is mounted in a tank chamber 52 (FIG. 3) formed by the fan case 36.

The drain tank 15 has a tank lid 53, and the condensed water from the drain outlet 51 falls into the drain tank 15 from the tank lid 53. The drain tank 15 has a floating accommodating portion 54 that accommodates a floating 80 that is inserted with the vertically downward direction as an insertion direction.
Here, FIG. 5 is a perspective view of the drain tank 15 as viewed from above.

  6A and 6B are views particularly showing the floating accommodating portion 54 in which the floating 80 is accommodated when viewed from the inside of the drain tank 15. FIG. 6A is a longitudinal sectional view of the floating accommodating portion 54, and FIG. FIG. 6C is a longitudinal sectional view of the drain tank 15 showing the floating housing portion 54 when it is done, and FIG. 8C is a longitudinal sectional view of the drain tank 15 when the float 80 of FIG.

  The floating housing portion 54 is provided on the back side in the drain tank 15 mounting direction and at a position facing an AMR sensor 82 described later. The floating housing portion 54 includes a slit 55, an insertion guide 56, a rising portion 57, and a drop prevention pin 58. The slit 55 is provided in the vertical direction from the upper end 60 to the lower end 61 of the floating storage unit, and allows the drain water in the drain tank 15 to enter the floating storage unit 54. The slit 55 guides the protrusion 87 in the insertion direction of the float 80. The insertion guide 56 is formed to rise from the side surface 62 of the floating housing portion 54. The height of the insertion guide 56 rising from the left and right side surfaces 62 to the floating 80 side changes. As a result, the wide area 63 and the narrow area 64 (FIG. 6C) are formed in the space in which the float 80 is accommodated from the front side to the back side in the insertion direction of the float 80 with respect to the float accommodating portion 54.

  The rising portion 57 is two members that vertically rise from the bottom surface 65 of the floating housing portion 54 and the end of the slit 55 toward the inside of the floating housing portion 54. The insertion guide 56 and the rising portion 57 are in line contact with the inserted float 80 and support the float 80, so that the side surface 62 and the bottom surface 65 of the float accommodating portion 54 and the float 80 are in surface contact and are stuck by surface tension. To prevent it. The removal prevention pin 58 is detachably provided at the upper end of the floating accommodating portion 54 and supports the floating 80 so that the floating 80 does not fall out of the floating accommodating portion 54.

  The control unit 34 (control unit) shown in FIG. 4 controls the operation of the dehumidifier 1 by electrically controlling the wind direction plate motor 22, the fan motor 32, the relay 96 and the like based on instructions from the switches 29. To do. The control unit 34 has a storage unit 70 and a timer 71. The storage unit 70 stores operation programs for the wind direction plate motor 22, the fan motor 32, the relay 96, and the lamps 30 that are executed based on instructions received from the switches 29. The timer 71 performs time measurement for the timer operation of the dehumidifier 1 and the like. The temperature sensor 75 and the humidity sensor 76 are provided at predetermined positions of the main body of the dehumidifier 1, measure the ambient temperature and humidity of the dehumidifier 1, and the control unit 34 uses the values obtained as necessary for control. The notification unit 78 notifies an alarm for notifying the user of the situation based on an instruction from the control unit 34.

The control unit 34 detects the water level (full water) of the drain tank 15 and the operation (failure) of the compressor 40 based on the detection result of the AMR sensor 82. Hereinafter, details of the full water detection unit including the AMR sensor 82 will be described.
FIG. 7 is a longitudinal sectional view of the dehumidifier 1 that particularly explains the full water detection unit.

  The full water detection unit includes a float 80, a magnet 81 provided on the float 80, and an AMR sensor 82 that detects the magnetic field of the magnet 81.

  8A is an external perspective view seen from the surface 88 of the float 80, FIG. 8B is an external perspective view seen from the back surface 86 of the float 80, and FIG. 8C is a longitudinal sectional view of the float 80. FIG.

The float 80 is accommodated in the float accommodating portion 54 of the drain tank 15 and moves up and down according to the water level in the drain tank 15. The float 80 is a vertically long rectangular parallelepiped, and is formed of a material having buoyancy such as expanded polystyrene. The float 80 has a wide portion 85 that increases the width at the upper end. The width W ₁ of the wide portion 85 shown in FIG. 8A is larger than the width of the narrow region 64 formed in the floating accommodating portion 54 as shown in FIG. It is smaller than the width. On the other hand, the width W ₂ of the float 80 other than the wide portion 85 is smaller than the width of the narrow region 64. The length of the wide portion 85 (wide region 63) in the insertion direction (X-axis direction in FIG. 7) is not particularly limited, and may be longer or shorter than illustrated in the present embodiment.

  The float 80 has a protrusion 87 on the back surface 86, which is the surface opposite to the surface facing the AMR sensor 82. The protrusion 87 has a dimension that can be inserted into the floating housing portion 54 along the slit 55. The protruding direction (Y-axis direction) of the protrusion 87 is a direction orthogonal to the width direction (Z-axis direction) of the wide portion 85.

The magnet 81 is a thin plate-like vertically long rectangular parallelepiped having a magnetization direction (the position of the N pole and the S pole is not limited) in the horizontal direction (Z-axis direction) on the surface facing the AMR sensor 82. The dimensions of the magnet 81 are, for example, length 15 mm × width 8 mm × thickness 3 mm. The magnet 81 is fitted and disposed in a recess formed in the surface 88 of the float 80 which is the surface facing the AMR sensor 82 so that the center of the magnet 81 in the width direction coincides with the center of the float 80 in the width direction. . Since the width W _{2 of the} float 80 is smaller than the width of the narrow region 64, the float 80 moves in the width direction within the float housing portion 54. Even in this case, the magnet 81 is designed to have such a size that the AMR sensor 82 can detect the magnetic field of the magnet 81.

  An AMR sensor (Anisotropic-Magneto-Resistance, anisotropic magnetoresistive sensor) 82 is mounted on a substrate 90 together with a signal processing circuit and the like so as to detect a horizontal magnetic field parallel to the magnetizing direction of the magnet 81. It is attached to the case 36. Specifically, the AMR sensor 82 is provided at a position opposite to the tank chamber 52 of the fan case 36 and corresponding to the floating storage portion 54 (the floating 80, the magnet 81) of the drain tank 15. That is, the magnet 81 and the AMR sensor 82 face each other in the direction (Y-axis direction) orthogonal to the insertion direction.

  The positional relationship between the AMR sensor 82 and the magnet 81 is such that the AMR sensor 82 detects the magnetic field of the magnet 81 until the water level of the drain tank 15 reaches a specified full water position (detects a magnetic field with a strength greater than a predetermined value), It is defined that a magnetic field is not detected when a full position is reached (a magnetic field with a strength smaller than a predetermined value is detected).

  Further, as shown in FIG. 10 described later, the positional relationship between the AMR sensor 82 and the electric wire 95 of the compressor 40 detects the magnetic field 99 formed by the current 98 flowing through the electric wire 95 during the operation of the compressor 40, and stops. Sometimes it is specified not to detect the magnetic field 99. Specifically, the distance between the electric wire 95 and the AMR sensor 82 is equal to or less than the distance r detectable by the AMR sensor 82, and the direction of the current 98 is the vertical movement direction of the float 80 (x-axis direction in FIG. 7). Are arranged as follows. The electric wire 95 may be disposed on the back surface (surface in contact with the substrate 90) side of the AMR sensor 82.

  Next, the operation of the full water detection unit in this embodiment will be described.

  When the drain tank 15 is mounted in the tank chamber 52, the AMR sensor 82 detects the magnetic field of the magnet 81 having a strength equal to or greater than a predetermined value. The detection result of the AMR sensor 82 is transmitted to the control unit 34, and the control unit 34 determines that the drain tank 15 is attached.

When the water level of the drain water rises, the drain water enters the floating housing portion 54 from the slit 55, and the float 80 gradually rises due to buoyancy. The width W ₂ of the float 80 is smaller than the width of the narrow region 64 in the accommodating space in the float housing portion 54, there is a possibility to move in the width direction. However, the magnet 81 is designed to have such a size that even in such a case, the AMR sensor 82 can detect a magnetic field having a strength higher than a predetermined value. For this reason, even if the float 80 moves in the width direction, the detection accuracy is ensured.

  The shape of the magnet 81 is a vertically long rectangular parallelepiped along the direction of movement (vertical movement) of the float 80, and the magnetization direction is the horizontal direction on the surface facing the AMR sensor 82. Thereby, the magnetic field generated from the magnet 81 generates a magnetic flux widely in the vertical movement direction of the magnet 81, and the horizontal component of the magnetic field can be effectively applied to the AMR sensor 82 in a wide range.

  The AMR sensor 82 continues to detect a magnetic field that is greater than or equal to a predetermined value generated by the magnet 81 until the drain water level reaches a specified full water position. Based on the detection result, the control unit 34 determines that the drain water level has not yet reached the full level.

  When the drain water level reaches the specified full water position, the strength of the magnetic field detected by the AMR sensor 82 changes to be smaller than a predetermined value. Based on the detection result, the control unit 34 determines that the water level of the drain water has reached the full water position. Along with this, the control unit 34 notifies the user of full water via the notification unit 78 or stops the operation of the fan motor 32 and the compressor 40.

  Here, the control unit 34 controls the operation of the compressor 40 by the ON or OFF operation of the relay 96. For this reason, when a failure occurs in the relay 96 such as welding of the contacts, the control unit 34 cannot control the operation of the compressor 40. As a result, the operation of the compressor 40 cannot be stopped even though the drain tank 15 is full, and the dehumidifier 1 may be broken.

  On the other hand, the dehumidifier 1 in this embodiment can detect the failure of the compressor 40 suitably, when the control unit 34 performs a failure determination process together with the water level detection as described below.

FIG. 9 is a flowchart for explaining a failure determination process executed by the dehumidifier 1 in the present embodiment.
FIG. 10 is an explanatory view for explaining the positional relationship between the AMR sensor 82 and the electric wire 95 of the compressor 40. A float 80 having a magnet 81 is disposed on the back side of the AMR sensor 82 so as to be vertically movable. Is.
FIG. 11 is a waveform diagram for explaining the output of the AMR sensor 82 at the normal time.
FIG. 12 is a waveform diagram for explaining the output of the AMR sensor 82 when the relay 96 is faulty.

  11 and 12, the first stage is a waveform diagram of the AC voltage input to the substrate 90, and the second stage is a waveform diagram of the current flowing through the compressor 40. The third stage is a waveform diagram showing the detection level of the AMR sensor 82 based on the magnetic field formed by the magnet 81. The fourth stage is an AMR sensor 82 based on the magnetic field 99 formed by the current 98 flowing through the electric wire 95 of the compressor 40. FIG. 5 is a waveform diagram showing the output of the AMR sensor 82 detected by the control unit 34.

  In step S1, the control unit 34 determines whether or not the output of the AMR sensor 82 is HIGH (HI). When the output is LOW, the AMR sensor 82 is detecting a magnetic field greater than a predetermined value of the magnet 81, that is, a state where the water level of the drain tank 15 is not a prescribed full water position. On the other hand, when the output is HI, the AMR sensor 82 is detecting a magnetic field smaller than a predetermined value of the magnet 81, that is, the water level of the drain tank 15 has reached a specified full water position (AMR shown in FIG. 10). A state in which the distance between the sensor 82 and the magnet 81 is Y).

  During operation of the compressor 40, the AMR sensor 82 detects the magnetic field 99 formed by the current 98 as a pulse signal synchronized with the current 98. Specifically, the AMR sensor 82 outputs LOW when there is a magnetic field 99 and HI when there is no magnetic field 99. For this reason, the control unit 34 uses the output of the zero-cross point (timing at which the magnetic field 99 is not formed) of the input voltage to the substrate 90 in order to make a full water determination based only on the output based on the magnetic field of the magnet 81. Step 1 is determined.

  In step S1 for determining whether the water is full, the control unit 34 may use the signal output from the AMR sensor 82 as a pulse signal and determine that a predetermined period (for example, two periods) has been detected. In other words, the control unit 34 performs the determination using the signal output from the AMR sensor 82 as it is (without using the output of the zero cross point).

  If the control unit 34 determines that the output is not HI (NO in step S1), that is, if the water level has not yet reached the full water position and the output is LOW, the control unit 34 waits until the output is determined to be HI. On the other hand, when the control unit 34 determines that the output is HI (YES in step S1), that is, when the water level reaches the full water position, the operation of the compressor 40 is stopped by turning off the relay 96 in step S2. To do. 11 and 12, the control unit 34 detects that the water is full (determined as an output HI in step S1) when it detects HI twice.

  In step S3, the control unit 34 determines whether or not the output of the AMR sensor 82 is a pulse signal having a predetermined period. That is, the control unit 34 determines whether or not the magnetic field 99 is formed by the current 98 flowing through the electric wire 95 even though the compressor 40 is stopped in step S2. Here, the control unit 34 determines whether or not the pulse signal has a cycle (same as the power frequency) synchronized with the power frequency (50 Hz or 60 Hz). The control unit 34 determines whether the cycle of the pulse signal is the same as the power supply frequency based on the cycle of the zero cross point of the input voltage to the substrate 90. This is to eliminate the signal detected by the vertical movement of the magnet 81 based on the shaking of the water surface of the drain tank 15. In step S3, the control unit 34 makes a determination using the signal output from the AMR sensor 82 as it is (without using the output of the zero cross point).

  When the control unit 34 determines that the output is not a pulse signal having a predetermined cycle (NO in step S3), the control unit 34 notifies the user of full water via the notification unit 78 in step S4. That is, as shown in FIG. 11, as a result of the compressor 40 stopping normally and the AMR sensor 82 not detecting the magnetic field 99, the control unit 34 detects HI.

  On the other hand, when the control unit 34 determines that the output is a pulse signal having a predetermined cycle (YES in step S3), the control unit 34 notifies the user of the failure by an alarm or the like in step S4. That is, as shown in FIG. 12, the operation of the compressor 40 is not stopped due to a failure due to welding of the relay 96 or the like, and as a result of the AMR sensor 82 detecting the magnetic field 99, the control unit 34 detects a pulse signal. . Thereby, the user can take a measure of stopping the compressor 40 by unplugging the power cord of the dehumidifier 1 or the like.

  Since the dehumidifier 1 in this embodiment has a full water detection unit using the AMR sensor 82, the water level can be detected with high accuracy and the structure can be simplified.

  That is, when a float having a rotating shaft is used for the full water detection unit, the structure of the float is complicated, and it is necessary to provide a structure for supporting the rotating shaft in the drain tank. This reduces manufacturability with the complexity of the structure, and also reduces usability and cleanability for the user. In addition, when a reed switch or a micro switch is used to detect a magnetic field, there is a possibility that deterioration may occur due to a mechanical operation at the contact point, resulting in lack of reliability. In addition, these switches are inevitably increased in size due to the detection mechanism. Furthermore, although it is conceivable to use a Hall IC that is a semiconductor magnetic sensor similar to the AMR sensor 82, the Hall IC has a characteristic of detecting a magnetic field in the vertical direction, so that the detection range is limited, and the limitation in the dehumidifier is not possible. The degree of freedom in designing the arrangement of magnets and Hall ICs in the space is greatly reduced.

  On the other hand, when the AMR sensor 82 is used, the component dimensions can be reduced as compared with the above method. Further, the AMR sensor 82 has a high degree of design freedom with respect to the arrangement because of the sensor characteristic that it can detect a horizontal magnetic field.

  Furthermore, the magnet 81 is a thin plate-like vertically long rectangular parallelepiped having a magnetization direction in the horizontal direction on the surface facing the AMR sensor 82 in consideration of the moving range of the float 80. For this reason, water level detection is performed with high accuracy in a wide range. For example, when the shape of the magnet is circular, for example, if the AMR sensor 82 detects a magnetic field within the same range as the magnet 81 in the present embodiment, the diameter of the circular magnet is the height dimension of the magnet 81 ( For example, it must be larger than 15 mm). As the magnet becomes larger, the float 80 needs more buoyancy, so the volume of the float 80 becomes larger. As a result, the size of the full water detection unit becomes large, or care must be taken to level the magnetization direction during assembly work. Also in this respect, the shape of the magnet 81 in the present embodiment can realize downsizing of the full water detection unit, and thus the dehumidifier 1.

  Furthermore, the dehumidifier 1 can detect a failure (operation) of the compressor 40 with a simple structure by using the AMR sensor 82 for detecting the water level in combination.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  For example, the air conditioner according to the present invention includes, in addition to the dehumidifier 1, an air conditioner, a humidifier, a dryer, and other tanks that require water level detection, and also have a compressor or (and) a heater. Can be applied. In particular, the present invention can also be applied to a desiccant-type dehumidifier equipped with a desiccant heated by a heater and a humidifier equipped with a heater. When applied to a device having a heater, the positions of the electric wire that supplies power to the heater and the AMR sensor may be defined similarly to the dehumidifier 1 in the present embodiment.

  Further, in the pulse signal determination step S3 of the failure determination process of FIG. 9, the “predetermined period” is preferably a power supply frequency. Further, it may be determined whether or not the pulse signal is detected a plurality of times continuously for a predetermined time.

DESCRIPTION OF SYMBOLS 1 Dehumidifier 15 Drain tank 16 Tank insertion port 34 Control unit 36 Fan case 40 Compressor 41 Condenser 43 Evaporator 52 Tank chamber 53 Tank lid 54 Floating storage part 80 Floating 81 Magnet 82 AMR sensor 90 Substrate 95 Electric wire 96 Relay 98 Current 99 magnetic field

Claims (8)

A compressor or heater;
A tank for storing water,
A float that moves up and down according to the water level in the tank;
A magnet provided on the float;
An electric wire for supplying electric power to the compressor or the heater;
An AMR (Anisotropic-Magneto-Resistance) sensor for detecting the magnetic field of the magnet and the magnetic field formed by the current flowing through the wire;
An air conditioner comprising: a control unit that detects a water level of the tank and an operation of the compressor or the heater based on a detection result of the AMR sensor.   The air conditioner according to claim 1, wherein the control unit detects the operation of the compressor or the heater when the pulse signal is detected from the AMR sensor after stopping the compressor or the heater.   The air according to claim 2, wherein the control unit detects the operation of the compressor or the heater when the pulse signal having the same cycle as the power supply frequency is detected or when the pulse signal is detected continuously for a predetermined time. Harmony machine.   The air conditioner according to any one of claims 1 to 3, wherein the air conditioner is a compressor type dehumidifier including the compressor.   The air conditioner according to any one of claims 1 to 3, wherein the air conditioner is a desiccant-type dehumidifier having a desiccant heated by the heater.   The air conditioner according to any one of claims 1 to 3, wherein the air conditioner is a humidifier including the heater. The magnet is a vertically long rectangular parallelepiped having a magnetization direction in a horizontal direction on a surface facing the AMR sensor,
The air conditioner according to any one of claims 1 to 6, wherein the AMR sensor detects a magnetic field parallel to the magnetization direction.   The air conditioner according to any one of claims 1 to 7, wherein the electric wire is arranged so that a direction of current is along a vertical movement direction of the float.

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