KR20190012520A - Air conditioner - Google Patents

Abstract

The present invention relates to an air conditioner. According to an embodiment of the present invention, the air conditioner includes: an indoor unit including a first power terminal, a first communication terminal, and a first neutral terminal; and an outdoor unit including a second power terminal, a second communication terminal, and a second neutral terminal connected with the first power terminal, the first communication terminal, and the first neutral terminal, respectively. The indoor unit includes: a first relay connected between the first power terminal and the first communication terminal; a wrong wiring sensing circuit connected among the first power terminal, the first neutral terminal, and the first relay to sense a wrong wiring of the indoor unit or the outdoor unit based on a voltage between the first power terminal and the first neutral terminal and to output a wrong wiring sensing signal; and a control unit to control an on/off state of the first relay based on the wrong wiring sensing signal. Accordingly, the wrong wiring of the indoor unit or the outdoor unit may be sensed, thereby preventing parts from being burnt due to the short of a circuit.

Description

Air conditioner

The present invention relates to an air conditioner, and more particularly, to an air conditioner capable of detecting miswiring between an indoor unit and an outdoor unit, thereby preventing component burnout due to a short circuit.

The air conditioner is installed to provide a comfortable indoor environment for humans by discharging cold air to the room to adjust the room temperature and purify the room air to create a pleasant indoor environment.

In the air conditioner, the outdoor unit and the indoor unit are connected to each other through a refrigerant pipe, the refrigerant compressed from the compressor of the outdoor unit is supplied to the heat exchanger of the indoor unit through the refrigerant pipe, and the refrigerant heat-exchanged by the heat exchanger of the indoor unit is again supplied to the outdoor unit And flows into the compressor. Accordingly, the indoor unit discharges the cold air into the room through the heat exchange using the refrigerant.

On the other hand, when the air conditioner is installed for the first time, the installer needs to pay utmost care to prevent mis-wiring in connecting the communication line, the power line, and the refrigerant pipe between the indoor unit and the outdoor unit. However, The wiring may have a complicated wiring characteristic, so that miswiring may occur.

Therefore, a technique for protecting the air conditioner from miswiring between the indoor unit and the outdoor unit will be required.

An object of the present invention is to provide an air conditioner that can detect miswiring between an indoor unit and an outdoor unit and prevent component burnout due to a short circuit.

In order to achieve the above object, an air conditioner according to an embodiment of the present invention includes an indoor unit having a first power source terminal, a first communication terminal, a first neutral terminal, and a first power source terminal, a first communication terminal, A second communication terminal, and an outdoor unit having a second neutral terminal, wherein the indoor unit includes a first relay connected between the first power terminal and the first communication terminal, and a first power terminal connected between the first power terminal and the first communication terminal, And a second neutral terminal connected between the first neutral terminal and the first relay for detecting a faulty connection between the indoor unit and the outdoor unit based on the voltage between the first power supply terminal and the first neutral terminal, And a relay control unit for controlling on / off of the first relay based on the circuit part and the erroneous wire detection signal.

The air conditioner according to the embodiment of the present invention detects miswiring between the indoor unit and the outdoor unit and controls the on / off of the relay, thereby preventing component burnout due to short circuit.

Further, in the case of a faulty connection between the indoor unit and the outdoor unit, the air conditioner cuts off the power applied to the indoor unit and the outdoor unit, so that the stability of the air conditioner is improved.

Further, since the air conditioner includes a resistance element that divides the voltage between the power supply terminal and the neutral terminal, the effect of reducing heat generation can be expected.

Further, since the air conditioner includes the photo-coupler for insulating the first power supply terminal, the first neutral terminal, and the relay control unit, the standby power of the indoor unit is reduced in the standby mode.

Further, since the air conditioner includes a buffer, the impedance of the miswiring detection signal or the relay control signal can be lowered and the noise can be reduced.

Further, the air conditioner may control the first relay, the second relay, and the third relay to reduce the power consumption of the outdoor unit in the standby mode.

Further, since the air conditioner is supplied with the power via the second relay, which is the start relay, the third relay is turned on after the second relay is turned off, and the AC power is supplied through the third relay, When connecting, quick, AC power supply becomes possible.

1 is a diagram illustrating a configuration of an air conditioner according to an embodiment of the present invention.
Fig. 2 is a schematic view of the outdoor unit and the indoor unit of Fig. 1. Fig.
3 is a simplified internal block diagram of the air conditioner of Fig.
4 is an example of a circuit diagram of the compressor driving unit of Fig.
5A is an internal block diagram of the inverter control unit of FIG.
FIG. 5B is an internal block diagram of the converter control section of FIG. 4; FIG.
Fig. 6 is a diagram illustrating the power connection between the indoor unit and the outdoor unit.
Fig. 7 is an example of a conventional internal circuit diagram of an air conditioner.
8 is an example of an internal circuit diagram of an air conditioner according to an embodiment of the present invention.
9A to 9B are diagrams referred to in the description of the operation of FIG.
10A and 10B are diagrams referred to in the description of the operation of FIG.

Hereinafter, the present invention will be described in detail with reference to the drawings.

The suffix " module " and " part " for components used in the following description are given merely for convenience of description, and do not give special significance or role in themselves. Accordingly, the terms " module " and " part " may be used interchangeably.

Terms including ordinals, such as first, second, etc., may be used to describe various elements, but the elements are not limited to these terms. The terms are used only for the purpose of distinguishing one component from another.

In the present application, the terms "comprises", "having", and the like are used to specify that a feature, a number, a step, an operation, an element, a component, And does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

1 is a diagram illustrating a configuration of an air conditioner according to an embodiment of the present invention.

The air conditioner 100 according to the present invention may include an indoor unit 21 and an outdoor unit 31 connected to the indoor unit 21 as shown in FIG.

The indoor unit 21 of the air conditioner may be any of a stand-type air conditioner, a wall-mounted air conditioner, and a ceiling-type air conditioner, but the stand type indoor unit 21 is exemplified in the figure.

Meanwhile, the air conditioner 100 may further include at least one of a ventilator, an air purifier, a humidifier, and a heater, and may operate in conjunction with the operation of the indoor unit and the outdoor unit.

The outdoor unit 31 includes a compressor (not shown) for receiving and compressing the refrigerant, an outdoor heat exchanger (not shown) for exchanging heat between the refrigerant and the outdoor air, an accumulator for extracting the gas refrigerant from the refrigerant supplied to the compressor, And a four-way valve (not shown) for selecting the flow path of the refrigerant according to the heating operation. In addition, a number of sensors, valves, oil recovery devices, and the like are further included, but a description thereof will be omitted below.

The outdoor unit (31) operates the compressor and the outdoor heat exchanger to compress or heat-exchange the refrigerant according to the setting to supply the refrigerant to the indoor unit (21). The outdoor unit (31) can be driven by a demand of a remote controller (not shown) or the indoor unit (21). At this time, as the cooling / heating capacity is changed corresponding to the indoor unit to be driven, the number of operation of the outdoor unit and the number of operation of the compressor installed in the outdoor unit can be varied.

At this time, the outdoor unit (31) supplies the compressed refrigerant to the connected indoor unit (21).

The indoor unit (21) receives the refrigerant from the outdoor unit (31) and discharges cold air to the room. The indoor unit 21 includes an indoor heat exchanger (not shown), an indoor unit fan (not shown), an expansion valve (not shown) in which the supplied refrigerant expands, and a plurality of sensors (not shown).

At this time, the outdoor unit 31 and the indoor unit 21 are connected to each other via a communication line to transmit and receive data, and the outdoor unit and the indoor unit are connected to a remote controller (not shown) by wire or wireless, can do.

A remote controller (not shown) is connected to the indoor unit 21, and inputs a control command of the user to the indoor unit, and receives and displays the status information of the indoor unit. At this time, the remote controller can communicate by wire or wireless according to the connection form with the indoor unit.

Fig. 2 is a schematic view of the outdoor unit and the indoor unit of Fig. 1. Fig.

Referring to the drawings, the air conditioner 100 is roughly divided into an indoor unit 21 and an outdoor unit 31.

The outdoor unit 31 includes a compressor 102 for compressing the refrigerant, a compressor 102b for driving the compressor, an outdoor heat exchanger 104 serving to dissipate the compressed refrigerant, An outdoor fan 105 which is disposed at one side of the heat exchanger 104 and includes an outdoor fan 105a for accelerating the heat radiation of the refrigerant and a motor 250 for rotating the outdoor fan 105a and an outdoor fan 105 for expanding the condensed refrigerant Heating / switching valve or a four-way valve 110 for switching the flow path of the compressed refrigerant, and a controller for temporarily storing the gasified refrigerant to remove moisture and foreign substances, And an accumulator 103 for supplying the exhaust gas.

The indoor unit 21 includes an indoor heat exchanger 109 disposed inside the room and performing a cooling / heating function, an indoor fan 109a disposed at one side of the indoor heat exchanger 109 for promoting heat radiation of the refrigerant, And an indoor air blower 109 composed of an electric motor 109b for rotating the fan 109a.

At least one indoor heat exchanger 109 may be installed. At least one of an inverter compressor and a constant speed compressor may be used as the compressor 102. [

Further, the air conditioner 100 may be constituted by a cooling unit that cools the room, or a heat pump that cools or heats the room.

The outdoor fan 105a in the outdoor unit 31 may be driven by the outdoor fan driving unit 200 that drives the motor 250. [ Hereinafter, the outdoor fan drive unit 200 may be referred to as an outdoor fan drive unit.

On the other hand, the compressor 102 in the outdoor unit 31 can be driven by a compressor motor driving unit (113 in Fig. 3) that drives a compressor motor (not shown).

On the other hand, the indoor fan 109a in the indoor unit 21 can be driven by the indoor fan driving unit 300 that drives the indoor fan motor 109b.

3 is a simplified internal block diagram of the air conditioner of FIG.

3, the air conditioner 100 includes a compressor 102, an outdoor fan 105a, an indoor fan 109a, a controller 170, a discharge temperature sensor 118, an outdoor temperature sensor A sensing unit 138, an indoor temperature sensing unit 158, and a memory 140. The air conditioner 100 includes a compressor driving unit 113, an outdoor fan driving unit 200, an indoor fan driving unit 300, a switching valve 110, an expansion valve 106, a display unit 130, 120).

The compressor 102, the outdoor fan 105a, and the indoor fan 109a are described with reference to FIG.

The input unit 120 includes a plurality of operation buttons, and transmits a signal indicating an operation target temperature of the input air conditioner to the controller 170.

The display unit 130 can display the operation state of the air conditioner 100. [ For example, the display unit 130 may include display means for outputting the operating state of the indoor unit 21, so that the operating state and the error can be displayed.

The display unit 130 may display the connection state of the indoor unit 21 and the outdoor unit 31. [ For example, the display unit 130 may include a light emitting diode (LED), and the light emitting diode (LED) is turned on when the connection state of the communication line and / or the power line is normal, It can be turned off when the connection state of the power line is abnormal.

The memory 140 may store data necessary for the operation of the air conditioner 100.

The discharge temperature sensing unit 118 may sense the refrigerant discharge temperature Tc in the compressor 102 and may transmit a signal regarding the sensed refrigerant discharge temperature Tc to the controller 170. [

The outdoor temperature sensing unit 138 can sense the outdoor temperature To which is the temperature around the outdoor unit 31 of the air conditioner 100 and outputs a signal regarding the sensed outdoor temperature To to the controller 170 ). ≪ / RTI >

The room temperature sensing unit 158 can sense the room temperature Ti which is the temperature around the indoor unit 21 of the air conditioner 100 and transmits a signal regarding the sensed room temperature Ti to the controller 170 ). ≪ / RTI >

The control unit 170 controls the air conditioner 100 based on at least one of the sensed refrigerant discharge temperature Tc, the sensed outdoor temperature To, the sensed room temperature Ti, Can be controlled to operate. For example, the final target superheat degree may be calculated to control the air conditioner 100 to operate.

The control unit 170 controls the operation of the compressor 102, the indoor fan 109a and the outdoor fan 105a by controlling the compressor driving unit 113, the outdoor fan driving unit 200 , And the indoor fan driving unit 300 can be controlled.

For example, the control unit 170 may output a corresponding speed command value signal to the compressor driving unit 113, the outdoor fan driving unit 200, or the indoor fan driving unit 300, respectively, based on the target temperature.

Based on the respective speed command value signals, the compressor motor (not shown), the motor 250, and the indoor fan motor 109b can be operated at the target rotation speed, respectively.

The control unit 170 may control the overall operation of the air conditioner 100 in addition to the control of the compressor driving unit 113, the outdoor fan driving unit 200, and the indoor fan driving unit 300.

For example, the control unit 170 may control the operation of the cooling / heating switching valve or the four-way valve 110. Alternatively, the control unit 170 can control the operation of the expansion mechanism or the expansion valve 106. [

4 is an example of a circuit diagram of the compressor driving unit of Fig.

Referring to the drawing, the compressor driving unit 113 includes an inverter 220 for outputting a three-phase AC current to the compressor motor 250, an inverter control unit 230 for controlling the inverter 220, A converter 210 for supplying power, a converter controller 215 for controlling the converter 210, and a dc capacitor C between the converter 210 and the inverter 220.

The compressor driving unit 113 may further include a dc voltage detection unit B, an input voltage detection unit A, an input current detection unit D, and an output current detection unit E.

The motor drive apparatus 200 receives the AC power from the system, converts the power, and supplies the converted power to the motor 250. Accordingly, the motor drive apparatus 200 may be referred to as a power conversion apparatus.

The converter 210 converts the input AC power supply to DC power supply. The converter 210 may include only a rectifying part (not shown), or may include a rectifying part and a switching element.

The rectifying unit (not shown) can rectify the received single-phase AC power source 201 and output rectified power.

To this end, the rectifying part (not shown) is composed of a pair of upper and lower arm diode elements D'a and D'b connected in series to each other, and two pairs of upper and lower arm diode elements are connected in parallel to each other . That is, they can be connected to each other in the form of a bridge.

On the other hand, when the converter 210 includes a switching element, for example, a boost converter may be provided. That is, an inductor and a diode connected in series with each other, and a switching element connected between the inductor and the diode may be provided between the rectifying part (not shown) and the inverter 220. [

The converter control unit 215 can control the turn-on timing of the switching element when the converter has a switching element. Thus, the converter switching control signal Scc for the turn-on timing of the switching element can be output.

To this end, the converter control unit 215 can receive the input voltage Vs and the input current Is from the input voltage detection unit A and the input current detection unit D, respectively.

The input voltage detecting section A can detect the input voltage Vs from the input AC power supply 201. [ For example, at the front end of the rectifying part (not shown).

The input voltage detecting unit A may include a resistance element, an OP AMP, or the like for voltage detection. The detected input voltage Vs can be applied to the converter control unit 215 for generation of the converter switching control signal Scc as a discrete signal in the form of a pulse.

On the other hand, the input voltage detecting section A can also detect the zero crossing point of the input voltage.

Next, the input current detection section D can detect the input current Is from the input AC power source 201. [ Specifically, it can be positioned at the front end of the rectifying section (not shown).

The input current detection unit D may include a current sensor, a current transformer (CT), a shunt resistor, or the like, for current detection. The detected input voltage can be applied to the converter control unit 215 for generation of the converter switching control signal Scc as a discrete signal in the form of a pulse.

The dc voltage detecting section B detects the dc voltage Vdc of the dc short-circuit capacitor C. For power detection, a resistance element, OP AMP, or the like can be used. The detected voltage Vdc of the dc short-circuit capacitor C may be applied to the inverter control unit 230 as a discrete signal in the form of a pulse and may be supplied to the DC voltage Vdc of the dc- The inverter switching control signal Sic can be generated.

Further, the detected dc voltage is applied to the converter control section 215, and the converter switching control signal Scc may be used for generation.

The inverter 220 includes a plurality of inverter switching elements and converts the smoothed direct current power supply Vdc into a three-phase alternating current power having a predetermined frequency by the on / off operation of the switching element, .

Accordingly, the inverter 220 can supply the inverter power to the motor 250 as a load. The inverter power at this time can follow the required target power as the power required by the motor 250 as the load.

More specifically, the inverter 220 may include a plurality of switching elements. For example, the upper arm switching elements Sa, Sb, Sc and the lower arm switching elements S'a, S'b, S'c are connected in series to each other and a total of three pairs of upper and lower arm switching elements Can be connected to each other in parallel (Sa & S'a, Sb & S'b, Sc & S'c). Diodes may be connected in anti-parallel to each switching element Sa, S'a, Sb, S'b, Sc, S'c.

The inverter control unit 230 can output the inverter switching control signal Sic to the inverter 220 in order to control the switching operation of the inverter 220. [ The inverter switching control signal Sic is a switching control signal of the pulse width modulation method PWM and is based on the output current io which is a three-phase current flowing to the motor 250 and the dc voltage Vdc across the dc- , And can be generated and output. The three-phase output current io at this time can be detected from the output current detection section E and the dc short voltage Vdc can be detected from the dc short voltage detection section B. [

The output current detection section E can detect the output current io flowing between the inverter 220 and the motor 250. [ That is, the current flowing in the motor 250 is detected. The output current detection unit E can detect all of the output currents ia, ib, ic of each phase or can detect the output currents of two phases using the three-phase balance.

The output current detector E may be located between the inverter 220 and the motor 250. For current detection, a current transformer (CT), a shunt resistor, or the like may be used.

On the other hand, the output inverter switching control signal Sic can be converted into a gate driving signal in a gate driver (not shown) and input to the gate of each switching element in the inverter 220. As a result, the switching elements Sa, S'a, Sb, S'b, Sc, and S'c in the inverter 220 perform the switching operation.

5A is an internal block diagram of the inverter control unit of FIG.

5A, the inverter control unit 230 includes an axis conversion unit 310, a speed calculation unit 320, a current command generation unit 330, a voltage command generation unit 340, an axis conversion unit 350, And a switching control signal output unit 360.

The axial conversion unit 310 receives the three-phase output currents ia, ib, ic detected by the output current detection unit E and converts the three-phase output currents ia, ib, ic into the two-phase currents iα, iβ in the stationary coordinate system.

On the other hand, the axis converting unit 310 can convert the two-phase current i ?, i? Of the still coordinate system into the two-phase current id, iq of the rotating coordinate system.

)와 연산된 속도(

)를 출력할 수 있다.Based on the two-phase current (i?, I?) Of the stationary coordinate system changed in the axis by the axis converting unit 310, the speed calculating unit 320 calculates the speed

) And the calculated speed (

Can be output.

)와 속도 지령치(ω^* _r)에 기초하여, 전류 지령치(i^* _q)를 생성한다. 예를 들어, 전류 지령 생성부(330)는, 연산 속도(

)와 속도 지령치(ω^* _r)의 차이에 기초하여, PI 제어기(335)에서 PI 제어를 수행하며, 전류 지령치(i^* _q)를 생성할 수 있다. 도면에서는, 전류 지령치로, q축 전류 지령치(i^* _q)를 예시하나, 도면과 달리, d축 전류 지령치(i^* _d)를 함께 생성하는 것도 가능하다. 한편, d축 전류 지령치(i^* _d)의 값은 0으로 설정될 수도 있다. On the other hand, the current command generation unit 330 generates the current command

(I ^* _q ) on the basis of the speed command value? ^* _R and the speed command value? ^* _R. For example, the current command generation section 330 generates the current command

The PI controller 335 performs the PI control based on the difference between the speed command value? ^* _R and the speed command value? ^* _R , and generates the current command value i ^* _q . In the figure, the q-axis current command value (i ^* _q ) is exemplified by the current command value, but it is also possible to generate the d-axis current command value (i ^* _d ) unlike the figure. On the other hand, the value of the d-axis current command value i ^* _d may be set to zero.

On the other hand, the current command generation section 330 may further include a limiter (not shown) for limiting the current command value (i ^* _q ) so that the current command value (i ^* _q ) does not exceed the allowable range.

Next, the voltage command generating unit 340 generates the voltage command generating unit 340 with the d-axis and q-axis currents (i _d , i _q ) axially transformed into the two-phase rotational coordinate system in the axial converting unit and the current command value based on ^{_{i * d, i * q)}} , and generates a d-axis, q-axis voltage command value ^{_{(v * d, v * q}} ). For example, the voltage command generation unit 340 performs PI control in the PI controller 344 based on the difference between the q-axis current (i _q ) and the q-axis current command value (i ^* _q ) It is possible to generate the axial voltage command value v ^* _q . The voltage command generation unit 340 performs PI control in the PI controller 348 based on the difference between the d-axis current i _d and the d-axis current command value i ^* _d , It is possible to generate the command value v ^* _d . The voltage command generator 340 may further include a limiter (not shown) for limiting the level of the d-axis and q-axis voltage command values v ^* _d and v ^* _q so as not to exceed the permissible range .

On the other hand, the generated d-axis and q-axis voltage command values (v ^* _d and v ^* _q ) are input to the axial conversion unit 350.

)와, d축, q축 전압 지령치(v^* _d,v^* _q)를 입력받아, 축변환을 수행한다.The axis transforming unit 350 transforms the position calculated by the velocity calculating unit 320

) And the d-axis and q-axis voltage command values (v ^* _d , v ^* _q ).

)가 사용될 수 있다.First, the axis converting unit 350 performs conversion from a two-phase rotating coordinate system to a two-phase stationary coordinate system. At this time, the position calculated by the speed calculator 320 (

) Can be used.

Then, the axial conversion unit 350 performs conversion from the two-phase stationary coordinate system to the three-phase stationary coordinate system. Through this conversion, the axial conversion unit 1050 outputs the three-phase output voltage instruction values v ^* a, v ^* b, v ^* c.

The switching control signal output section 360 generates the switching control signal Sic for inverter according to the pulse width modulation (PWM) method based on the three-phase output voltage instruction values v ^* a, v ^* b and v ^* And outputs it.

The output inverter switching control signal Sic can be converted into a gate driving signal at the gate driver (820a, 820b, etc. in Fig. 8A or 8B) and input to the gate of each switching element in the inverter 220. [ As a result, the switching elements Sa, S'a, Sb, S'b, Sc, and S'c in the inverter 220 perform the switching operation.

5B is an example of an internal block diagram of the converter control unit of FIG.

The converter control unit 215 may include a current command generation unit 410, a voltage command generation unit 420, and a switching control signal output unit 430.

Based on the dc terminal voltage (Vdc) and the dc terminal voltage command value (V ^* dc) detected by the output voltage detecting section (B), that is, the dc terminal voltage detecting section (B), the current command generating section (410) The q-axis current command value (i ^* _d , i ^* _q ) can be generated.

The voltage command generation section 420 generates d and q commands through a PI controller based on the d and q axis current command values i ^* _d and i ^* _q and the input current is detected by the input current detection section A, Axis voltage command value (v ^* _d , v ^* _q ).

The switching control signal output section 430 outputs a converter switching control signal Scc for driving the switching elements in the converter 210 of Fig. 4 based on the d, q-axis voltage command values v ^* _d and v ^* _q Converter 210 as shown in FIG.

Fig. 6 is a diagram illustrating the power connection between the indoor unit and the outdoor unit.

6A is a view illustrating an example of the power connection of the power supply plug 605 to the indoor connection unit 610 and the power supply plug 605 is connected to the outdoor connection unit 615 FIG. 1 is a diagram illustrating a power connection of an outdoor entry-and-connection system to be connected; FIG.

6A, the indoor unit 21 includes an indoor connection unit 610 connected to the indoor circuit unit 620, and the outdoor unit 31 includes an outdoor connection unit (not shown) connected to the outdoor circuit unit 625 615).

The indoor connection unit 610 may include a first power supply terminal L1, a second power supply terminal L2, a first neutral terminal N1, a second neutral terminal N2, and a communication terminal C.

The outdoor connection unit 615 may include a power supply terminal L, a communication terminal C, and a neutral terminal N. [

The second power supply terminal L2 and the second neutral terminal N2 and the communication terminal C of the indoor connection unit 610 are connected to the power supply terminal L, the neutral terminal N, Can be connected to the communication terminal (C).

The power input from the outside can be applied to the indoor unit 21 and / or the outdoor unit 31 through the power line connected between the second power terminal L2 and the power terminal L. On the other hand,

The indoor unit 21 and the outdoor unit 31 can exchange operation state information by exchanging data or mutual communication via a communication line connected to each communication terminal C. [ In addition, power may be transmitted through a communication line.

6B, the outdoor unit 31 includes an outdoor connection unit 615 connected to the outdoor circuit unit 625, and the indoor unit 21 includes an indoor connection unit 610 connected to the indoor circuit unit 620.

The outdoor connection unit 615 may include a first power supply terminal L1, a second power supply terminal L2, a first neutral terminal N1, a second neutral terminal N2, and a communication terminal C. [

The indoor connection unit 610 may include a power supply terminal L, a communication terminal C, and a neutral terminal N. [

The second power supply terminal L2 and the second neutral terminal N2 and the communication terminal C of the outdoor connection part 615 are connected to the power supply terminal L, the neutral terminal N, Can be connected to the communication terminal (C).

The power input from the outside may be applied to the indoor unit 21 and / or the outdoor unit 31 through a power line connected between the second power terminal L2 and the AC power terminal L.

The indoor unit 21 and the outdoor unit 31 can exchange operation state information by exchanging data or mutual communication via a communication line connected to each communication terminal C. [ In addition, power may be transmitted through a communication line.

On the other hand, when connecting the indoor unit 21 and the outdoor unit 31 and the power supply line with each other, the utmost care is required. However, since there is a very complicated wiring characteristic between the indoor unit 21 and the outdoor unit 31, May occur.

Fig. 7 is an example of a conventional internal circuit diagram of an air conditioner.

The indoor unit 21 includes a first power supply terminal L1, a first communication terminal C1, a first neutral terminal N1, a first power supply terminal L1, And a first relay Ry1 connected between the first communication terminal L1 and the first communication terminal C1.

The conventional air conditioner, particularly, the outdoor unit 31 is connected to the first power supply terminal L1, the first communication terminal C1, and the first neutral terminal N1 of the indoor unit 21, A second relay terminal Ry2 to which a terminal a is connected to the second communication terminal C2 and a second relay terminal Ry2 to which a terminal a is connected to the second communication terminal C2, And a third relay Ry3 whose one end is connected to the second relay Ry2.

On the other hand, the second power supply terminal L2, the second communication terminal C2, and the second neutral terminal N2 are connected to the first power supply terminal L1, the first communication terminal C1, the first neutral terminal N1, The AC power is transmitted from the first power supply terminal L1 to the first communication unit 720 and the second communication terminal C2 via the first communication terminal C1.

The second control unit 215 controls on and off of the second relay Ry2 and the third relay Ry3 to switch the AC power applied to the second communication terminal C2 to the voltage down unit 213 And the converter 210. [0033]

The voltage step-down unit 213 and the converter 210 operate normally based on the applied AC power.

On the other hand, the second power supply terminal L2 is connected to the first power supply terminal L1, the second neutral terminal N2 is connected to the first communication terminal C1, the second neutral terminal N1 is connected to the second power supply terminal L2, In the case of a misconnect, to which the communication terminal C2 is connected, the power supplied via the first power supply line Li1 is transmitted to the first relay Ry1 via the first power supply terminal L1.

Since the conventional air conditioner does not include a miswiring detection circuit portion 740 for detecting miswiring and a relay control portion 770 for controlling the first relay Ry1, the power supplied to the first relay Ry1 is , And is applied to the power plug 701 via the second power line Li2 via the first communication terminal. In the figure, an eleventh current path (Path 11) is illustrated.

As described above, the conventional air conditioner has a problem that there is a risk of short-circuiting in the case of miswiring, and it is not free from the risk of fire due to short-circuiting, parts burning due to short-circuit, and the like.

7, the second power supply terminal L2 is connected to the first power supply terminal L1, the second neutral terminal N2 is connected to the first communication terminal C1, The second communication terminal C2 is connected to the first power terminal L1 and the second communication terminal C2 is connected to the first communication terminal C1. The second power supply terminal L2 is connected to the first neutral terminal N1 and the second neutral terminal N2 is connected to the first neutral terminal N1.

8 is an example of an internal circuit diagram of an air conditioner according to an embodiment of the present invention.

The indoor unit 21 according to the embodiment of the present invention includes a first power supply terminal L1, a first communication terminal C1, and a first connection terminal N1 having a first neutral terminal N1. A first relay Ry1 connected between the first power supply terminal L1 and the first communication terminal C1 and a first communication section 720 connected to the first communication terminal C1, A miswiring detecting circuit unit 740 for detecting miswiring of the indoor unit 21 and the outdoor unit 31 and outputting a miswiring detection signal, a relay control unit 770 for controlling on / off of the first relay, And a first control unit 790 for outputting an operation signal for the operation of the operation unit 21.

The miswiring detection circuit unit 740 is connected between the first power supply terminal L1 and the first neutral terminal N1 and the first relay Ry1 and is connected between the first power supply terminal L1 and the first neutral terminal N1 The indoor unit 21 and the outdoor unit 31 can be detected and the erroneous wiring detection signal can be outputted based on the voltage between the indoor unit 21 and the outdoor unit 31. [

More specifically, the miswiring sensing circuit portion 740 can output a miswiring signal when the voltage between the first power supply terminal L1 and the first neutral terminal N1 is equal to or lower than a predetermined voltage.

On the other hand, when the erroneous detection circuit portion 740 includes the Zener diode Z1, the predetermined voltage may be the breakdown voltage of the Zener diode Z1. The Zener diode Z1 can be appropriately selected in consideration of the voltage between the first power supply terminal L1 and the first neutral terminal N1 and the rated power consumption of the indoor unit 21, the maximum allowable current, the voltage, .

The erroneous wiring detection circuit unit 740 is connected in series between the first power supply terminal L1 and the first neutral terminal N1 and supplies a voltage between the first power supply terminal L1 and the first neutral terminal N1 And may include a first resistor element R1 and a second resistor element R2 for dividing the voltage.

In the figure, the first resistor element R1 and the second resistor element R2 are connected in series, one end of the first resistor element R1 is connected to the first power supply terminal L1 (c-node) And the other end of the resistance element R2 is connected to the first neutral terminal N1 (node d).

In this manner, the miswiring detection circuit unit 740 divides the voltage between the first power supply terminal L1 and the first neutral terminal N1 to prevent the misfiring of the indoor unit 21 and the outdoor unit 31, There is an effect of reducing the heat generation due to the overvoltage between the power supply terminal L1 and the first neutral terminal N1.

The miswiring detection circuit unit 740 includes a diode D1 for rectifying the voltage between the first power supply terminal L1 and the first neutral terminal N1 and a diode D1 for rectifying the voltage between the diode D1 and the first neutral terminal N1 And a capacitor element C1 connected and smoothing the rectified voltage.

In the figure, the anode terminal of the diode D1 is connected to the node n1 between the first resistor element R1 and the second resistor element R2, and the cathode terminal of the diode D1 Is connected to one end of the capacitor element C1 and the other end of the capacitor element C1 is connected to the first neutral terminal.

In this way, the miswiring detection circuit unit 740 detects the voltage between the first power supply terminal L1 and the first neutral terminal N1 or the voltage between the first power supply terminal L1 and the first neutral terminal N1 The AC power can be converted into the DC power. On the other hand, such DC voltage is converted to output a false detection signal.

The miswiring detection circuit unit 740 may further include a zener diode Z1 that cuts off current at a predetermined voltage or lower.

In the figure, it is illustrated that an anode end of a zener diode Z1 is connected to one end of a capacitor element C1 and a cathode end of a diode D1.

The zener diode Z1 can cut off the current flowing in the conductor under a predetermined voltage or lower. The predetermined voltage may be the breakdown voltage of the Zener diode Z1.

The miswiring detection circuit portion 740 may include a photocoupler 730. The photocoupler 730 may include a light emitting diode 731 and a light receiving transistor 732.

In the figure, the anode terminal of the light emitting diode 731 is connected to the node n2.

In this way, the miswiring detection circuit unit 740 reduces the standby power of the indoor unit 21 in the standby mode by using the photocoupler 730 that insulates the first power terminal, the first neutral terminal, and the relay control unit It is effective.

The indoor unit 21 may further include a first control unit 790 for outputting an operation signal 791 for operating the indoor unit 21 and the erroneous detection circuit unit 740 may include a mis- And an AND gate 750 for performing an AND operation on the operation signal 791 and the relay control signal 753.

For example, the indoor unit 21 can receive an operation command for driving the indoor unit 21, and the first control unit 790 receives the operation signal 791 for the operation of the indoor unit 21 Can be output. At this time, the operation signal 791 may be a signal of a high level (for example, 5V).

Also, the miswiring detection circuit portion 740 may output the miswiring detection signal 741. At this time, the miswiring detection signal 741 may be a miswiring signal (low level, for example, 0 V) Signal (high level, for example, 5 V).

The AND gate 750 can output the relay control signal 753 by performing an AND operation on the miswiring detection signal 741 and the operation signal 791. [ The relay control signal 753 may be either a high level (for example, 5V) or a low level (for example, 0V) by an AND operation.

On the other hand, the relay control unit 770 can control ON / OFF of the first relay Ry1 based on the relay control signal 753. [

In the figure, the emitter terminal of the light-receiving transistor 732 is connected to the first input terminal 751 of the AND gate. On the other hand, the emitter terminal of the light receiving transistor 732 may be directly connected to the relay control unit 770. [ That is, it is also possible that the miswiring detection signal of the miswiring detection circuit unit 740 is input directly to the relay control unit 770.

For example, the miswiring detection circuit portion 740 may output the miswiring detection signal 741, and the miswiring detection signal 741 may be a miswiring signal (low level, for example, 0 V) or And a normal connection signal (high level, for example, 5 V).

At this time, the relay control unit 770 can control ON / OFF of the first relay Ry1 based on the miswiring detection signal 741. [

The miswiring detection circuit unit 740 may further include a third resistance element R3 connected in series to a cathode terminal of the light emitting diode 731. [

The figure illustrates that the third resistor element R3 is connected between the cathode terminal of the light emitting diode 731 and the cathode terminal of the Zener diode Z1.

The erroneous wiring detection circuit unit 740 may further include a fourth resistive element R4 connected in series to an emitter terminal of the light receiving transistor 732. [

In the figure, a fourth resistive element R4 is connected between the n3 node and the ground terminal.

As described above, the relay control unit 770 can control ON / OFF of the first relay Ry1 based on the miswiring detection signal 741 output from the miswiring detection circuit unit 740. [ The relay control unit 770 can also control ON and OFF of the first relay Ry1 based on the relay control signal 753 output from the AND gate 750. [

For example, if the voltage between the first power supply terminal L1 and the first neutral terminal N1 is lower than a predetermined voltage, the miswiring detection circuit unit 740 can output a miswiring signal and the relay control unit 770 can turn off the first relay Ry1 based on the erroneous wiring signal.

As another example, the miswiring detection circuit unit 740 can output a normal connection signal when the voltage between the first power supply terminal L1 and the first neutral terminal N1 exceeds a predetermined voltage, (770) can turn on the first relay (Ry1) based on the normal connection signal.

The relay control unit 770 may include a buffer. Accordingly, the relay control unit 770 can reduce the impedance of the miswiring sensing signal or the relay control signal, thereby reducing the noise and improving the stability of the system.

Meanwhile, the indoor unit 21 may further include a rectifying unit 712 connected to the first AC power supply terminal L1.

The outdoor unit 31 according to the embodiment of the present invention is connected to the first AC power supply terminal L1, the first communication terminal C1 and the first neutral terminal N1 of the indoor unit 21, A second connecting portion 715 having a second AC power supply terminal L2, a second communication terminal C2 and a second neutral terminal N2 and a second connecting portion 715 having one end a connected to the second communication terminal C2 The second relay Ry2 is connected to the third relay Ry3 whose one end is connected to the AC power supply terminal and the other end b of the second relay Ry2 and the other end b of the third relay Ry3 A voltage step-down unit 213 and a converter 210 connected in parallel with each other and the other end b of the second relay Ry2 and the other end b of the third relay Ry3, And a second communication unit 725 connected between the communication voltage output unit 717 and the second communication terminal C2.

On the other hand, the outdoor unit 31 may further include a second control unit 215 that operates by receiving power from the voltage down unit 213.

The first power supply line Li1 electrically connected to the power plug 701 is connected between the first AC power supply terminal L1 and the second AC power supply terminal L2.

On the other hand, the second power supply line Li2, which is electrically connected to the power plug 701, is connected between the first neutral power supply terminal N1 and the second neutral terminal N2.

The second control unit 215 is connected to the second relay Ry2 and the third relay Ry3 in the outdoor unit 31 and the voltage down unit 213 and the converter 210. The communication voltage output unit 717, On / off control of the communication unit 725, or operation control.

On the other hand, it is preferable that the third relay Ry3 is a dc relay operated by a DC power supply from the control unit 215 or a DC power supply from the voltage down unit 213. [

9A to 9B are views referred to in the description of the operation of FIG.

More specifically, Figs. 9A and 9B are diagrams showing current paths and signal flows at the time of normal connection between the indoor unit 21 and the outdoor unit 31. Fig.

9A, a first power supply terminal L1, a first communication terminal C1, a second power supply terminal L2 and a second communication terminal C2 are connected to a first neutral terminal N1, And the second neutral terminal N2 are respectively connected to the first power supply terminal L1 and the first neutral terminal, the miswiring detection circuit unit 740 detects the misfire detection circuit unit 740 based on the voltage between the first power supply terminal L1 and the first neutral terminal, And the outdoor unit (31). In the figure, the first current path Path1 is illustrated.

The miswiring detection circuit unit 740 can divide the voltage between the first power supply terminal L1 and the first neutral terminal N1 at the c-node. Therefore, the voltage (first voltage) at the node n1 may be a divided voltage, which divides the voltage (second voltage) at the node c.

The miswiring sensing circuit 740 can sense miswiring based on the first voltage or the second voltage (hereinafter referred to as a first voltage).

More specifically, in the case of normal connection, a 220V AC voltage may be applied between the first power supply terminal L1 and the first neutral terminal N1. The applied AC voltage is rectified by the diode D1 and can be smoothed by the capacitor element C1.

Thus, the voltage at node n2 may be a DC voltage of a predetermined magnitude. For example, the voltage at node n2 may be a 10V dc voltage.

On the other hand, the Zener diode Z1 may have a breakdown voltage of a predetermined magnitude. For example, the breakdown voltage may be 5V.

At this time, since the voltage at the node n2 is larger than the breakdown voltage, the current can be conducted by the tunneling phenomenon of the zener diode Z1. The conducted current can flow into the third resistance element R3.

On the other hand, the breakdown voltage of the Zener diode Z1 is preferably set to be smaller than the voltage applied to the node n2 during normal connection.

The light emitting diode 731 can transmit light to the light receiving transistor 732 when power is applied to both ends of the light emitting diode 731.

In this way, in the case of the normal connection, the miswiring detection circuit unit 740 senses the normal connection and can transmit the miswiring detection signal, in particular, the normal connection signal through the light emitting diode 731.

The erroneous wiring detection circuit unit 740 can output the erroneous wiring sensing signal. More specifically, the light-receiving transistor 732 can receive light transmitted from the light-emitting diode 731 and conduct current.

The current flows into the fourth resistance element R4, and the voltage is applied to the fourth resistance element R4. For example, the voltage applied to the fourth resistance element R4 may be 5V.

The AND gate 750 can receive a miswiring detection signal 741, particularly a normal wiring signal, through the first input terminal 751. For example, the normal connection signal may be '5V', 'high level', '1'.

On the other hand, the first control unit 790 can output the operation signal 791 for the operation of the indoor unit 21. [ For example, the operation signal 791 may be '5V', 'high level', or '1'.

 The operation signal 791 (e.g., 5V, high level, 1) may be input to the second input 752 of the AND gate 750.

The AND gate 750 receives a miswiring detection signal 741, particularly a normal connection signal (e.g., 5V, high level, 1) and an operation signal 791 (e.g., 5V, high level, And output the relay control signal 753. [0154] FIG.

For example, when the AND gate 750 receives a normal connection signal (for example, 5V, high level, 1) and an operation signal 791 (for example, 5V, high level, It is possible to output a relay-on signal.

The relay control unit 770 can control ON / OFF of the first relay Ry1 based on the relay control signal 753. For example, when receiving the relay-on signal, the relay control unit 770 can turn on the first relay Ry1 based on the relay-on signal.

Meanwhile, the erroneous wire detection signal 741 may be directly input to the relay control unit 770. For example, due to the voltage applied to the fourth resistance element R4, a miswiring detection signal 741, particularly a normal wiring signal (for example, 5V, high level, 1) is input to the relay control unit 770 And the relay control unit 770 can turn on the first relay Ry1 based on the normal connection signal.

When the first relay Ry1 is turned on while the AC power is being applied through the first power line Li1 connected between the first AC power terminal L1 and the second AC power terminal L2, AC power via the first power supply line Li1 is transmitted from the first AC power supply terminal L1 to the first communication unit 720 and the second communication terminal C2 via the first communication terminal C1 .

Particularly, the second current path Path2 is formed in the first communication section 720 via the first communication terminal C1 in the first AC power supply terminal L1.

On the other hand, when the AC power is supplied through the first power line Li1 connected between the first AC power supply terminal L1 and the second AC power supply terminal L2, the second relay Ry2 is turned on The alternating current power through the first AC power supply terminal L1, the first communication terminal C1 and the second communication terminal C2 is transmitted to the voltage step-down unit 213 and the converter 210, The unit 213 and the converter 210 are operated.

At this time, a third current path Path3 is formed through the first AC power supply terminal L1, the first communication terminal C1, the second communication terminal C2, and the second relay Ry2.

The second control unit 215 operates in accordance with the operation power supply from the voltage down unit 213 and controls the second relay Ry2 to be turned off and the third relay Ry3 to be turned on.

9B, when the second relay Ry2 is turned off and the third relay Ry3 is turned on after the operation of the voltage down converter 213 and the converter 210, the first power line Li1 is turned on The AC power through the second AC power supply terminal L2 and the third relay Ry3 is transmitted to the voltage down unit 213 and the converter 210. The voltage down unit 213 and the converter 210 .

At this time, a fourth current path Path4 is formed through the first power supply line Li1, the second ac power supply terminal L2, and the third relay Ry3.

On the other hand, the communication voltage output section 717 outputs a communication voltage according to the operation of the voltage down converter 213 and the converter 210, and the communication voltage outputted is outputted from the second communication section 725, (C2) and the first communication terminal (C1) to the first communication unit (720).

In the drawing, a sixth current path (first path) to the first communication unit 720 via the communication voltage output unit 717, the second communication unit 725, the second communication terminal C2 and the first communication terminal C1 Path 6).

On the other hand, the second control unit 215 can control the second relay Ry2 to be turned off and the third relay Ry3 to be turned on in accordance with the operation power supply from the voltage down unit 213. [

Accordingly, as shown in the figure, the AC power source through the first power line Li1 can be transmitted to the rectifying unit 712 through the first AC power terminal L1.

In the figure, a fifth current path (Path 5) through the first power supply line Li1 and the rectifying unit 712 is illustrated.

In this way, when power is supplied to the indoor unit 21 and the outdoor unit 31, unnecessary power consumption does not occur in the standby mode. Particularly, the power consumption of the outdoor unit 31 in the standby mode can be reduced.

The AC power is supplied via the second relay Ry2 which is the start relay and the third relay Ry3 is turned on after the second relay Ry2 is turned off so that the AC power is supplied via the third relay Ry3 Therefore, it is possible to supply the AC power quickly when the plug is connected after the end of the standby mode.

10A to 10B are views referred to in the description of the operation of FIG.

More specifically, Figs. 10A to 10B are diagrams showing the current path and the signal flow when the indoor unit 21 and the outdoor unit 31 are erroneously connected.

10A, a second power supply terminal L2 is connected to a first power supply terminal L1, a second neutral terminal N2 is connected to a first communication terminal C1, In the case of a miswiring in which the second communication terminal C2 is connected to the one neutral terminal N1, the miswiring detection circuit portion 740 detects the miswiring based on the voltage between the first power supply terminal L1 and the first neutral terminal , It is possible to detect miswiring between the indoor unit (21) and the outdoor unit (31). The seventh current path (Path 7) is illustrated in the figure.

The miswiring detection circuit unit 740 can divide the voltage between the first power supply terminal L1 and the first neutral terminal N1 at the c-node. Therefore, the voltage at the node n1 (third voltage) may be a divided voltage obtained by dividing the voltage at the node c (the fourth voltage).

The miswiring detection circuit unit 740 can detect a miswiring based on a third voltage or a fourth voltage (hereinafter referred to as a third voltage).

More specifically, in the case of miswiring, an alternating voltage of 0V or less than a normal voltage may be applied between the first power supply terminal L1 and the first neutral terminal N1. On the other hand, the steady voltage may be a voltage applied between the first power supply terminal L1 and the first neutral terminal N1 during normal connection (for example, 220 V AC voltage).

The AC voltage below the normal voltage can be rectified by the diode D1 and smoothed by the capacitor element C1.

Thus, the voltage at node n2 may be a DC voltage of a predetermined magnitude. For example, the voltage at node n2 may be a 2V dc voltage.

On the other hand, the Zener diode Z1 may have a breakdown voltage of a predetermined magnitude. For example, the breakdown voltage may be 5V.

At this time, since the voltage at the node n2 is smaller than the breakdown voltage, the zener diode Z1 can cut off the current.

On the other hand, the breakdown voltage of the Zener diode Z1 is preferably set to be larger than the voltage applied to the node n2 at the time of miswiring.

When the current is cut off by the Zener diode Z1, there is no current flowing into the third resistance element R3, so the light emitting diode 731 can not transmit light.

The erroneous wiring detection circuit unit 740 can output the erroneous wiring sensing signal. More specifically, in the case of miswiring, the light receiving transistor 732 can block the current since it does not receive light.

On the other hand, since no current flows through the fourth resistance element R4, the voltage applied across the fourth resistance element R4 may be 0V.

The AND gate 750 can receive a miswiring detection signal 741, particularly a miswiring signal, through the first input terminal 751. For example, the miswired signal may be '0V', 'low level', or '0'.

On the other hand, the first control unit 790 can output the operation signal 791 for the operation of the indoor unit 21. [ For example, the operation signal 791 may be '5V', 'high level', or '1'.

The operation signal 791 (e.g., 5V, high level, 1) may be input to the second input 752 of the AND gate 750.

The AND gate 750 receives a miswiring detection signal 741, particularly a miswired signal (e.g., 0V, low level, 0) and an operation signal 791 (e.g., 5V, high level, And output the relay control signal 753. [0154] FIG.

For example, if the AND gate 750 receives an erroneous line signal (e.g., 0V, low level, 0) and an operation signal 791 (e.g., 5V, high level, It is possible to output a relay-off signal.

The relay control unit 770 can control ON / OFF of the first relay Ry1 based on the relay control signal 753. For example, when receiving the relay off signal, the relay control unit 770 can turn off the first relay Ry1 based on the relay off signal.

Meanwhile, the erroneous wire detection signal 741 may be directly input to the relay control unit 770. For example, the relay control unit 770 may receive an erroneous wiring signal (for example, 0V, low level, 0), and the relay control unit 770 may receive the first relay Ry1 Can be turned off.

When the first relay Ry1 is turned off while AC power is being applied through the first power line Li1 connected between the first AC power terminal L1 and the second AC power terminal L2, AC power through the first power supply line Li1 is transferred from the first AC power supply terminal L1 to the first relay Ry1. In the figure, an eighth current path (Path 8) is illustrated.

On the other hand, the first relay Ry1 can prevent the parts from burning due to short-circuiting when the indoor unit 21 and the outdoor unit 31 are connected in a faulty manner by shutting off the AC power.

10B, a second communication terminal C2 is connected to the first power terminal L1, a second power terminal L2 is connected to the first communication terminal C1, The erroneous wiring detection circuit 740 is connected to the first neutral terminal N1 and the second neutral terminal N2 via the second neutral terminal N2 in accordance with the voltage between the first power supply terminal L1 and the first neutral terminal, 21) and the outdoor unit (31). In the figure, a ninth current path (Path 9) is illustrated.

The miswiring detection circuit unit 740 can divide the voltage between the first power supply terminal L1 and the first neutral terminal N1 at the c-node. Therefore, the voltage at the node n1 (third voltage) may be a divided voltage obtained by dividing the voltage at the node c (the fourth voltage).

The miswiring detection circuit unit 740 can detect a miswiring based on a third voltage or a fourth voltage (hereinafter referred to as a third voltage).

More specifically, in the case of miswiring, an alternating voltage of 0V or less than a normal voltage may be applied between the first power supply terminal L1 and the first neutral terminal N1. On the other hand, the steady voltage may be a voltage applied between the first power supply terminal L1 and the first neutral terminal N1 during normal connection (for example, 220 V AC voltage).

The AC voltage below the normal voltage can be rectified by the diode D1 and smoothed by the capacitor element C1.

Thus, the voltage at node n2 may be a DC voltage of a predetermined magnitude. For example, the voltage at node n2 may be a 2V dc voltage.

On the other hand, the Zener diode Z1 may have a breakdown voltage of a predetermined magnitude. For example, the breakdown voltage may be 5V.

At this time, since the voltage at the node n2 is smaller than the breakdown voltage, the zener diode Z1 can cut off the current.

On the other hand, the breakdown voltage of the Zener diode Z1 is preferably set to be larger than the voltage applied to the node n2 at the time of miswiring.

When the current is cut off by the Zener diode Z1, there is no current flowing into the third resistance element R3, so the light emitting diode 731 can not transmit light.

The erroneous wiring detection circuit unit 740 can output the erroneous wiring sensing signal. More specifically, in the case of miswiring, the light receiving transistor 732 can block the current since it does not receive light.

On the other hand, since no current flows through the fourth resistance element R4, the voltage applied across the fourth resistance element R4 may be 0V.

The AND gate 750 can receive a miswiring detection signal 741, particularly a miswiring signal, through the first input terminal 751. For example, the miswired signal may be '0V', 'low level', or '0'.

On the other hand, the first control unit 790 can output the operation signal 791 for the operation of the indoor unit 21. [ For example, the operation signal 791 may be '5V', 'high level', or '1'.

The operation signal 791 (e.g., 5V, high level, 1) may be input to the second input 752 of the AND gate 750.

The AND gate 750 receives a miswiring detection signal 741, particularly a miswired signal (e.g., 0V, low level, 0) and an operation signal 791 (e.g., 5V, high level, And output the relay control signal 753. [0154] FIG.

For example, if the AND gate 750 receives an erroneous line signal (e.g., 0V, low level, 0) and an operation signal 791 (e.g., 5V, high level, It is possible to output a relay-off signal.

The relay control unit 770 can control ON / OFF of the first relay Ry1 based on the relay control signal 753. For example, when receiving the relay off signal, the relay control unit 770 can turn off the first relay Ry1 based on the relay off signal.

Meanwhile, the erroneous wire detection signal 741 may be directly input to the relay control unit 770. For example, the relay control unit 770 may receive an erroneous wiring signal (for example, 0V, low level, 0), and the relay control unit 770 may receive the first relay Ry1 Can be turned off.

When the first relay Ry1 is turned off while AC power is being applied through the first power line Li1 connected between the first AC power terminal L1 and the second AC power terminal L2, An AC power source through the first power line Li1 may be transmitted from the first AC power terminal L1 to the first relay Ry1 via the first communication unit 720. [ In the figure, a tenth current path (Path 10) is illustrated.

On the other hand, the first relay Ry1 can prevent the parts from burning due to short-circuiting when the indoor unit 21 and the outdoor unit 31 are connected in a faulty manner by shutting off the AC power.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It should be understood that it includes water and alternatives.

Likewise, although the operations are depicted in the drawings in a particular order, it should be understood that such operations must be performed in that particular order or sequential order shown to obtain the desired result, or that all depicted operations should be performed . In certain cases, multitasking and parallel processing may be advantageous.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It should be understood that various modifications may be made by those skilled in the art without departing from the spirit and scope of the present invention.

21: indoor unit
31: outdoor unit
100: air conditioner
213:
717: Communication voltage output section
720: First communication section
725:
730: Photo coupler
740: Wrong detection circuit
741: Wrong detection signal
750: And the gate
753: Relay control signal
770: Relay controller
790:
791: Operation signal

Claims (13)

An indoor unit having a first power supply terminal, a first communication terminal, and a first neutral terminal; And
And an outdoor unit having a second power supply terminal, a second communication terminal, and a second neutral terminal connected to the first power supply terminal, the first communication terminal, and the first neutral terminal,
The indoor unit includes:
A first relay connected between the first power supply terminal and the first communication terminal;
And a second neutral terminal connected between the first power terminal and the first neutral terminal for detecting a faulty connection between the indoor unit and the outdoor unit based on a voltage between the first power terminal and the first neutral terminal, A miswiring detection circuit for outputting a miswiring detection signal; And
And a relay control unit for controlling on / off of the first relay based on the mis-wiring detection signal. The method according to claim 1,
The erroneous wiring detection circuit unit includes:
When the voltage between the first power supply terminal and the first neutral terminal is equal to or lower than a predetermined voltage,
The relay control unit,
And turns off the first relay based on the erroneous wiring signal. The method according to claim 1,
The erroneous wiring detection circuit unit includes:
And a first resistance element and a second resistance element connected in series between the first power supply terminal and the first neutral terminal and dividing the voltage between the first power supply terminal and the first neutral terminal Characterized by an air conditioner. The method according to claim 1,
The erroneous wiring detection circuit unit includes:
A diode rectifying a voltage between the first power supply terminal and the first neutral terminal; And
And a capacitor element connected between the cathode terminal of the diode and the first neutral terminal for smoothing the rectified voltage. 5. The method of claim 4,
The erroneous wiring detection circuit unit includes:
And an anode terminal connected to the capacitor element. ≪ Desc / Clms Page number 24 > The method according to claim 1,
The erroneous wiring detection circuit unit includes:
An air conditioner comprising a photocoupler including a light emitting diode and a light receiving transistor. The method according to claim 6,
The erroneous wiring detection circuit unit includes:
And a resistance element connected in series to a cathode terminal of the light emitting diode. The method according to claim 6,
The erroneous wiring detection circuit unit includes:
And a resistor element connected in series to an emitter terminal of the light receiving transistor. The method according to claim 1,
The relay control unit,
Wherein the air conditioner comprises a buffer. The method according to claim 1,
The indoor unit includes:
And a control unit for outputting an operation signal for the operation of the indoor unit,
The erroneous wiring detection circuit unit includes:
And an AND gate for performing an AND operation of the erroneous wiring detection signal and the operation signal to output a relay control signal. 11. The method of claim 10,
The relay control unit,
And controls on / off of the first relay based on the relay control signal. The method according to claim 1,
The outdoor unit includes:
A second relay whose one end is connected to the second communication terminal; And
And a third relay having one end connected to the second power supply terminal. 13. The method of claim 12,
The indoor unit includes:
And a first communication unit connected to the first communication terminal,
The outdoor unit includes:
A voltage down unit and a converter to which the other end of the second relay and the other end of the third relay are connected and which are connected in parallel with each other;
A communication voltage output unit connected to the other end of the second relay and the other end of the third relay, for outputting a communication voltage; And
And a second communication unit connected between the communication voltage output unit and the second communication terminal.

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