KR20190073138A - Air conditioner - Google Patents

Abstract

The present invention relates to an air conditioner. According to an embodiment of the present invention, the air conditioner comprises: a power source unit connected to at least one of a generator power source or a commercial power source, receiving a current power source, and supplying the received current power source by switching the same into a direct current power source; a first voltage sensing unit sensing first voltage of the received current power source; a second voltage sensing unit sensing second voltage of the direct current power source; and a control unit calculating whether or not the power source unit is connected to the generator power source based on the first voltage and the second voltage. Accordingly, it is possible to automatically recognize whether or not the air conditioner is connected to the generator power source.

Description

Air conditioner

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner, and more particularly, to an air conditioner capable of automatically recognizing whether or not the air conditioner is connected to a generator power source.

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.

In such an air conditioner, since the refrigerant is circulated by the driving of the compressor and the cold air is discharged through the heat exchange of the refrigerant, stable driving of the compressor is important.

On the other hand, the air conditioner is driven using a commercial power supply or a generator power supply in an environment with a limited receiving capacity. Particularly, when the air conditioner is driven by using the generator power, the air conditioner can ensure the continuous operation by limiting the power consumption.

However, in the prior art, the total harmonic distortion ratio (THD) of the input power source is used in order to automatically detect whether or not the power source is connected to the generator, There is a problem in that it is difficult to implement it.

Further, in the prior art, in the environment where the commercial power supply is not stably supplied, a calculation error of the full harmonic distortion due to the application of the low voltage may occur.

An object of the present invention is to provide an air conditioner capable of automatically recognizing whether or not a generator power source is connected based on a voltage of an input AC power source and a voltage magnitude of a DC power source.

In order to achieve the above object, an air conditioner according to an embodiment of the present invention includes: a power unit connected to at least one of a generator power supply and a commercial power supply for receiving an AC power supply and converting an input AC power supply to a DC power supply; A first voltage sensing unit sensing a first voltage of the input AC power source; a second voltage sensing unit sensing a second voltage of the DC power source; Or not.

The air conditioner according to the embodiment of the present invention can automatically recognize whether or not the generator power is connected based on the first voltage of the input AC power and the second voltage of the DC power.

Further, the air conditioner has an advantage that it can be implemented by only voltage sensing means for sensing the voltage of the input power source and the DC power source without complicated circuit configuration.

Further, since the air conditioner recognizes whether or not the generator is connected to the power supply with only a simple voltage sensing means, the manufacturing cost is reduced.

Further, since the air conditioner recognizes whether or not the generator power is connected based on the magnitudes of the first voltage and the second voltage, the input power can be calculated more accurately even in an environment in which the commercial power is not stably supplied.

Further, since the air conditioner computes whether or not the generator is connected to the power source before the compressor is driven (first calculation) and after the compressor is driven, whether or not the generator is connected to the power source is re-computed (second computation) .

Further, since the air conditioner provides a reliable connection result, it is possible to prevent unnecessary compressor operation frequency limitation under a commercial power supply.

Further, since the air conditioner can variably set the predetermined value in the second calculation in accordance with the load state of the generator power source, it is possible to flexibly detect the generator power source in accordance with the load state of the generator power source.

Further, the air conditioner can detect the connection with the generator power supply, automatically change the operation mode to the generator mode, and can ensure the stable operation of the air conditioner by controlling the operation frequency of the compressor in the generator mode operation .

Further, the air conditioner senses the connection with the generator power source and can automatically change the operation mode to the generator mode. When the generator mode operation is performed, the air conditioner detects whether the generator power is overloaded and controls the operation thereof, Convenience can be provided.

Further, the air conditioner senses the connection with the generator power supply, and can automatically change the operation mode to the generator mode. In the generator mode operation, the air conditioner senses whether the generator power is no load and controls the operation thereof to prevent damage to the product .

1 is a view showing a configuration of an air conditioner according to the present invention.
2 is a view showing an air conditioner and a power supply according to the present invention.
3 is a block diagram showing the control arrangement of the air conditioner according to the present invention.
4 is a block diagram showing a configuration according to an operation control of the air conditioner according to the present invention.
5 is a flowchart showing an operation method of the air conditioner according to the embodiment of the present invention.
6 is a diagram referred to in the description of the operation method of Fig.
7 is a flowchart showing an operation method of power consumption control in generator mode operation according to the present invention.
8 is a diagram referred to in the description of Fig.
9 is a diagram referred to in the description of Fig.
10 is a flowchart showing an operation method of the generator overload control in the generator mode operation according to the present invention.
11 is a diagram referred to in the explanation of the operation method of Fig.
12 is a flowchart showing an operation method of the generator no-load control in the generator mode operation according to the present invention.
13 is a diagram referred to in the explanation of the operation method 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 view showing a configuration of an air conditioner according to the present invention.

Referring to the drawings, the air conditioner includes an indoor unit 1, an outdoor unit 2, and a remote controller 3 for inputting control commands to the indoor unit 1. [

In addition, in the room where the air conditioner is installed, other home appliances other than the air conditioner are provided. For example, in the case of a home, a washer, a light, a refrigerator, and a television. And a household electric appliance such as a fan.

At this time, the household appliances and the air conditioner operate by receiving either the power delivered from the power plants 21, 22, or 23, that is, the commercial power 20 and the power generated from the generator.

In addition, when a plurality of household appliances are provided and connected to a power source, particularly, when a plurality of household appliances are connected to the generator, a switch 30 for selecting a predetermined household appliance and supplying power to some household appliances . In this case, since the capacity of the generator is limited, when the connected load, that is, the number of household appliances, is plural, it can not supply power to all household appliances. In some cases, the switch 30 may select one of the commercial power supply and the generator power to be supplied to the household appliance as well as select the load.

On the other hand, the air conditioner can automatically recognize the generator power. Further, the air conditioner can automatically recognize the generator power and change the operation mode to the generator mode.

When the air conditioner operates in the generator mode, the air conditioner can control the operating frequency of the compressor so that the power consumption does not exceed the reference power consumption for the generator mode.

On the other hand, the type of household appliance or the number of household appliances that can be connected to the generator varies depending on the capacity thereof. For example, generators for household use have a small capacity of about 600 to 1 Kwh.

The generator may be overloaded when the air conditioner is connected or a plurality of household appliances are connected and operated at the same time.

When the air conditioner operates in the generator mode, the air conditioner can reduce the power consumption to the generator by reducing the power consumption corresponding to the voltage of the power source supplied from the generator.

On the other hand, in the operation stop state of the air conditioner, when the other device is not connected to the generator or all other connected devices are stopped, the generator may be in a no-load state.

When the air conditioner operates in the generator mode, the air conditioner computes the no-load state of the generator so that a new load is applied to the generator power.

2 is a view showing an air conditioner and a power supply according to the present invention.

Referring to the drawings, the air conditioner includes an indoor unit 1 for discharging air into the room and an outdoor unit 2 for supplying the refrigerant, and a remote controller 3 for transmitting a control command to the indoor unit 1 is provided . At this time, not only the indoor unit and the outdoor unit are connected by the refrigerant piping but also by the communication line and the power line.

The air conditioner can be connected to the commercial power supply 20 (A) or connected to the generator (B). When the switch 30 is provided, it can be connected to either the commercial power supply 20 or the power supply of the generator through a switch operation, and the connected power supply can be switched. When the indoor unit or the outdoor unit is connected to the power source, the air conditioner is supplied power to the other unit through the connected power source line.

The indoor unit 1 is connected to the outdoor unit 2 and the indoor unit 1 is connected to the outdoor unit 2. The indoor unit 1 can be connected to the outdoor unit 2 in a plurality of ways, It can be divided into a ceiling type, a stand type, and a wall type depending on the form. In addition, the outdoor unit 2 and the indoor unit 1 may be combined to form a single body. The figure shows that the air conditioner is not limited to the form of the air conditioner.

The indoor unit 1 includes an expansion valve (not shown) for expanding the refrigerant supplied from the outdoor unit 2, an indoor heat exchanger (not shown), indoor air introduced into the indoor heat exchanger, (Not shown), a plurality of sensors (not shown), and control means (not shown) for controlling the operation of the indoor unit. The indoor unit 1 includes a discharge port (not shown) for discharging the heat-exchanged air, and the discharge port is provided with a wind direction adjusting unit (not shown) for opening and closing the discharge port and controlling the direction of the discharged air. The indoor unit 1 controls the intake air and the air to be discharged by controlling the rotational speed of the indoor fan, and adjusts the air flow rate. In addition, the indoor unit 1 may further include human body sensing means for sensing a human body present in the indoor space.

The outdoor unit (2) operates in a cooling mode or a heating mode according to the demand of the connected indoor unit (1) to supply the refrigerant to the indoor unit.

The outdoor unit 2 includes at least one compressor (not shown) for compressing the refrigerant introduced therein and discharging the gas refrigerant at a high pressure, a gas cooler for separating the gas refrigerant and the liquid refrigerant from the refrigerant, An oil separator (not shown) for recovering oil from the refrigerant discharged from the compressor, an outdoor heat exchanger (not shown) for condensing or evaporating the refrigerant by heat exchange with the outside air, an outdoor heat exchanger An outdoor fan (not shown) for introducing air into the outdoor heat exchanger and discharging heat-exchanged air to the outside, a four-way valve (not shown) for changing the flow path of the refrigerant according to the operation mode of the outdoor unit 2, At least one temperature sensor (not shown) for measuring the temperature, at least one pressure sensor (not shown) for measuring the temperature. The outdoor unit 2 further includes sensors, valves, supercooling units, and the like, but a description thereof will be omitted below.

The remote controller 3 includes input means such as at least one button, a switch, and a touch pad, and transmits data on the operation settings of the air conditioner to the indoor unit 1. [ At this time, the remote controller 3 transmits data through a wireless communication method, and may be wired through a communication line as the case may be.

As the input means is operated, the remote controller 3 transmits the input data to the indoor unit, and displays the operation information set in the indoor unit. Further, the remote controller 3 can measure and display the room temperature.

3 is a block diagram showing the control arrangement of the air conditioner according to the present invention.

The air conditioner includes a power supply unit 120, a driving unit 130, a voltage sensing unit 140, a sensing unit 150, a data unit 160, an input unit 170, a display unit 180, A control unit 110 and a flag setting unit 200.

This control arrangement of the air conditioner can be applied jointly to both the indoor unit 1 and the outdoor unit 2. 4) and the outdoor fan (192 in Fig. 4) are driven by the driving unit 130 in the case of the outdoor unit 2 and the indoor unit 1 is driven by the driving unit 130 193 of FIG. In some cases, the operation power may be supplied to either the outdoor unit 2 or the indoor unit 1, converted by the power unit 120, and then supplied through the power line. Furthermore, the indoor unit 1 may further include a communication unit (not shown) for receiving data from the remote control 3.

The communication unit (not shown) receives data on the operation setting from the remote control 3 and applies the data to the control unit 110. [ At this time, depending on the type of the remote control 3 or the communication method, the communication unit (not shown) not only receives the data of the remote control 3 but also can transmit data to the remote control 3 in accordance with the control command of the control unit 110 .

The power supply unit 120 is connected to either the generator power supply or the commercial power supply, receives the AC power, and converts the input AC power to DC power.

To this end, the power supply unit 120 can rectify the input AC power of three phases, smooth it, and convert it into DC power.

The voltage sensing unit 140 measures an input voltage supplied from the power supply unit 120 and inputs the measured input voltage to the control unit 110. For this, the voltage sensing unit 140 may include a resistance element, an amplifier, and the like.

More specifically, the voltage sensing unit 140 is connected to at least one of the generator power supply 10 and the commercial power supply, receives the AC power, and converts the input AC power to DC power.

The voltage sensing unit 140 may include a first voltage sensing unit 141 and a second voltage sensing unit 142.

The first voltage sensing unit 141 may sense the first voltage (V1 in FIG. 4) of the input AC power. The second voltage sensing unit 142 may sense the second voltage (V2 in FIG. 4) of the smoothed DC power. The first voltage sensing unit 141 and the second voltage sensing unit 142 may transmit the first voltage V1 and the second voltage V2 to the controller 110, respectively.

4), the outdoor fan (192 in FIG. 4), and the indoor fan (193 in FIG. 4), and supplies the electric power to the compressor ).

The driving unit 130 may include a compressor driving unit (not shown) and an outdoor fan driving unit (not shown) of the outdoor unit 2 and an indoor fan driving unit (not shown) .

The sensing unit 150 includes a plurality of sensors installed inside or outside the air conditioner. The sensing unit 150 may include a sensor for measuring temperature, pressure, voltage, current, and rotation speed, and may input measured data to the control unit 110.

The input unit 170 may include at least one predetermined input means such as a button, a switch, and a touch pad. When the input unit 170 has a mutual layer structure with the display unit of the output unit 185, which will be described later, this may be referred to as a touch screen.

The input unit 170 may input a predetermined signal to the control unit 110 as the input means is operated. The control unit 110 allows the input unit 170 to set the operation of the air conditioner according to the operation of the input means, and allows the air conditioner to start or end the operation. In some cases, the input unit 170 is provided with an operation mode setting key to input data according to the generator mode setting.

The display unit 180 may include display means for outputting numbers, letters, special characters or images. The display unit 180 outputs the operation setting for the operation mode, the temperature, the air volume, and the like of the air conditioner, and outputs the operation state of the air conditioner. Also, the display unit 180 displays the current temperature measured through the sensing unit 150.

In addition, the air conditioner may include a speaker or a buzzer for outputting a predetermined sound effect or a warning sound in addition to the display unit, and may include at least one lamp that displays various status conditions according to whether there is light emission, color, or blinking status.

The data unit 160 stores control data for controlling the operation of the air conditioner and data for operating the air conditioner, and data measured through the operation sensing unit 150 is stored. The data section 160 stores not only the operation setting but also the data on the operation mode, the reference power consumption value set in the generator mode, and the like.

In particular, the data unit 160 may store the first voltage V1 and the second voltage V2 sensed by the voltage sensing unit 140. In addition, the data unit 160 may store information on a connection flag, which is a connection status value with the generator power.

The data unit 160 may store predetermined information on the difference of the second voltage V2 before and after the compressor 191 is driven.

The control unit 110 sets and controls the operation so that the air conditioner operates according to the data input through the remote controller 3 or the input unit 170 and outputs the operation status through the display unit 180. [

In particular, the control unit 110 may calculate whether the power supply unit 120 is connected to the generator power supply, based on the first voltage V1 and the second voltage V2 sensed by the voltage sensing unit 140. [ Further, the controller 110 can set the air conditioner to the generator mode when the calculation is performed by connection to the generator power supply.

That is, the control unit 110 can automatically determine whether or not the generator power is connected based on the first voltage V1 and the second voltage V2, and set the air conditioner to the generator mode.

Here, the generator mode is a mode in which the air conditioner is set to be operable even with an unstable input power source when the power supplied to the air conditioner is low, when the voltage fluctuation is large, or when the capacity of the generator is low.

On the other hand, the flag setting unit 200 can set a connection flag, which is a connection state value with the generator power supply 10. [ The flag setting unit 200 may be provided in the control unit 110.

The control unit 110 sets the connection flag (flag = 1) when the power source unit 120 is operated with the generator power connection, and when the power source unit 120 is operated with the commercial power source, = 0).

When the control unit 110 automatically recognizes the generator power and automatically sets the air conditioner to the generator mode, the controller 110 consumes about 60% to 80% of the maximum power consumption value of the air conditioner It is possible to set the reference power consumption value of the power and control so that the power consumption of the air conditioner does not exceed the reference power consumption. At this time, the reference power consumption can be varied according to the capacity of the air conditioner and the maximum power consumption value.

Specifically, when the generator mode is automatically set, the controller 110 controls the operation of the air conditioner 140 according to the capacity and load of the air conditioner, corresponding to the second voltage V2 input through the voltage sensing unit 140. [ It is possible to calculate the amount of power consumed in the air conditioner and compare the calculated amount of power with a preset reference power consumption value so that the power consumption of the air conditioner does not exceed the predetermined reference power consumption value.

When the calculated power consumption rises, the controller 110 controls the driving unit 130 so as to reduce the operating frequency of the compressor to limit the increase of the power consumption. If the power consumption decreases, the operation frequency of the compressor increases, .

The controller 110 changes the maximum value of the operation frequency of the compressor, that is, the maximum operable frequency so that the compressor is prevented from operating at a frequency higher than the maximum operation frequency. For example, when the maximum operating frequency of the compressor is 100 Hz, the controller 110 sets 50 Hz as the maximum operating frequency so that the compressor can not operate in excess of 50 Hz. At this time, the maximum operating frequency is set in the operating frequency range such that the calculated power consumption does not exceed the reference power consumption value.

Meanwhile, in the generator mode, the controller 110 may control the operation by determining the load state of the power supplied according to the voltage value sensed and inputted from the voltage sensing unit 140.

Specifically, the control unit 110 calculates whether or not the generator power supply 10 is overloaded in response to the second voltage V2, and when the generator power supply 10 is overloaded, the operation frequency of the compressor 191 decreases .

Alternatively, the control unit 110 may calculate whether or not the generator power supply 10 is no-load corresponding to the second voltage V2. If the generator power supply 10 is unloaded, the controller 191 or the indoor fan 193, And so on.

4 is a block diagram showing a configuration according to an operation control of the air conditioner according to the present invention.

The power supply unit 120 may include a power input unit 121, a rectifying unit 122, and a DC link unit 123.

The power input unit 121 is connected to the generator power supply 10 and the commercial power supply 20 to receive AC power.

The power input unit 121 may further include a switch (not shown), and the controller 110 may control a switch (not shown) to operate the air conditioner in a generator mode or a commercial power mode.

The rectifying section 122 may include a converter (not shown). The converter (not shown) is made up of a diode or the like without a switching element, and can perform a rectifying operation without a separate switching operation. For example, in the case of a single-phase AC power source, four diodes may be used in the form of a bridge, and in the case of a three-phase AC power source, six diodes may be used in the form of a bridge.

Alternatively, a converter (not shown) may be, for example, a half-bridge type converter in which two switching elements and four diodes are connected. When three-phase AC power is input, six switching elements and six diodes Can be used.

The rectifying unit 122 can rectify the input AC power. When the rectifying section 122 includes a switching element, the boosting operation, the power factor correction, and the DC power conversion can be performed by the switching operation of the switching element.

The DC link unit 123 can smoothly store the power rectified by the converter (not shown).

To this end, the DC link portion 123 may include a capacitor element (not shown) connected to both ends of the dc stage. A plurality of capacitor elements may be provided to secure element stability.

That is, the generator power supply 10 or the commercial power supply 20 is rectified by the rectifying unit 122 and smoothed by the DC link unit 123 so that the input AC power is converted into DC power, Lt; / RTI >

The driving unit 130 may include an inverter 131 for driving the compressor 191. In addition, it may include first and second fan driving units for driving the outdoor fan 192 or the indoor fan 193. At this time, the compressor 191, the outdoor fan 192, and the indoor fan 193 can act as a load to a power source.

The inverter 131 includes a plurality of inverter switching elements and can convert the smoothed direct current power to an alternating current power by the on / off operation of the switching element and output the converted direct current power to the motor for driving the compressor 191 . At this time, the control unit 110 may function as an inverter control unit for controlling the inverter 131. [

The outdoor fan 192 is connected to the driving unit 130 and rotates as the motor is operated by the first fan driving unit. The outdoor fan (192) discharges the heat-exchanged air from the outdoor heat exchanger (194) to the outside.

In addition, the indoor fan 193 rotates according to the operation of the motor by the second fan driving unit 133, and the heat-exchanged air in the indoor heat exchanger 195 is discharged into the room.

The first voltage sensing unit 141 may be connected between the power input unit 121 and the rectifying unit 122 to sense the first voltage V1 of the input AC power. The first voltage sensing unit 141 may transmit information on the first voltage V1 to the controller 110. [

The second voltage sensing unit 142 may be connected to the output terminal of the DC link unit to sense the second voltage V2 of the DC power source. The second voltage sensing unit 142 may transmit information on the second voltage V2 to the controller 110. [

On the other hand, the DC link unit 123 of the present invention can use a low-capacity dc single capacitor of several tens uF or less. For example, the low-capacity dc single capacitor may be a film capacitor, not an electrolytic capacitor.

When the capacitor of a low capacity is used, the change of the dc terminal voltage is increased and pulsated. Therefore, the controller 110 may calculate the rms value (rms) information of the second voltage V2 pulsating.

The first voltage sensing unit 141 and the second voltage sensing unit 142 may include a resistance element, an amplifier, and the like in order to sense a voltage.

The control unit 110 can calculate whether or not the power supply unit 120 is connected to the generator power supply based on the first voltage V1 and the second voltage V2.

Specifically, when the compressor 191 is driven, since the power factor of the load including the compressor 191 is the ground power factor, the transmission current becomes a ground current whose phase is lower than the transmission voltage.

When the ground current is applied, the first voltage V1 sensed by the first voltage sensing unit 141 is measured to be greater than the second voltage V2 sensed by the second voltage sensing unit 142. [

On the other hand, when the compressor 191 is stopped, because the power factor of the load including the compressor 191 is the fast phase power factor due to the ferranti phenomenon or the like, the transmission current becomes the phase current ahead of the transmission voltage.

The second voltage V2 sensed by the second voltage sensing unit 142 is measured to be larger than the first voltage V1 sensed by the first voltage sensing unit 141. [

Accordingly, when the second voltage V2 is greater than the rms value (rms) of the first voltage V1 in the state where the compressor 191 is stopped, can do.

On the other hand, when the compressor 191 is driven, the control unit 110 determines whether or not the generator unit 10 is connected to the generator power supply 10 based on the difference in the second voltage V2 before and after the compressor 191 Can be calculated.

Specifically, when the compressor 191 is driven, the input AC power can be reduced by the capacity of the generator power supply 10 or the like. Further, the DC voltage of the DC link portion 123 can be reduced by a load such as a motor or the like. In particular, the second voltage V2, which is the DC voltage, is abruptly reduced by driving the compressor 191.

 Therefore, when the difference between the second voltage V2 before and after driving the compressor 191 is equal to or greater than a predetermined value in a state where the compressor 191 is driven, the control unit 110 calculates .

If the difference of the second voltage V2 is less than the predetermined value, the control unit 110 may determine that the generator power detection error has occurred, and calculate the power of the power supply unit 120 based on the commercial power connection.

The control unit 110 controls the compressor 191 by applying a control command to the inverter 131 of the driving unit 130 in response to the amount of power calculated according to the voltage when the generator mode is set, Limit. The driving unit 130 changes the operating frequency of the compressor 191 in response to a control command of the controller 110 and causes the compressor to operate at a set operating frequency.

At this time, the inverter 131 controls the compressor 191 to operate at the initial operating frequency during the operation of the air conditioner, and controls the operation frequency to rise as the load increases. When the generator mode is set, the inverter 131 controls the operation frequency of the compressor not to increase further according to the control command of the controller 110, even if the load of the air conditioner increases.

The control unit 110 controls the operation frequency of the compressor to be changed according to the amount of power to be calculated and applies the control command to the driving unit 130 so that the operation frequency of the compressor is maintained when the amount of power is within the predetermined value range.

The control unit 110 determines the load state of the power source 10 or 20 corresponding to the voltage 202 of the DC link unit 123 while controlling the power consumption to not exceed the reference power consumption, The operation frequency of the compressor 191 acting as a load with respect to the power source is controlled, or the outdoor fan 192 or the indoor fan 193 is controlled (204) (205) to adjust the load.

When the voltage of the DC link unit 123 decreases to a set voltage or lower, the control unit 110 determines that the power supply is overloaded so that the operation frequency of the compressor 191 is reduced so that the load on the power supply is reduced, And controls the operation frequency of the compressor 191 to be increased when the voltage of the DC link unit 123 increases due to the load reduction.

On the other hand, when the load factor of the load including the compressor 191 is unloaded, the transmission current can be a phase leading current 90 degrees ahead of the transmission voltage and rise above the set voltage.

The controller 110 determines that the power source is in a no-load state when the voltage of the DC link unit 123 rises above the set voltage, and controls the driving unit 130 to generate a load on the power source.

5 is a flowchart showing an operation method of the air conditioner according to the embodiment of the present invention.

Referring to the drawings, the control unit 110 can calculate whether or not the compressor 191 is stopped (S510).

The stop state of the compressor 191 includes a no-load state of the generator power supply 10. The controller 110 automatically recognizes the generator power supply 10 through a process to be described later in a no-load state, After setting the generator mode to the generator mode, the steps following FIG. 12 can be performed.

The controller 110 may calculate the rms value of the first voltage V1 and the magnitude of the second voltage V2 in a state where the compressor 191 is stopped.

As described above, the rms value of the first voltage V1 may be smaller than the second voltage V2 in the state where the compressor 191 is stopped, due to the feranti phenomenon or the like.

The control unit 110 may compute whether the power supply unit 120 is connected to the generator power supply 10 by comparing the rms value of the first voltage V1 with the magnitude of the second voltage V2 (S540).

The control unit 110 may compare the rms value rms of the second voltage V2 with the rms value rms of the first voltage V1 when the voltage of the DC link unit 123 pulsates . To this end, the control unit 110 may include an effective value calculation unit (not shown) for calculating the effective value of the second voltage V2.

On the other hand, the flag setting unit 200 can set a connection flag, which is a connection state value with the generator power supply 10. [

The flag setting unit 200 may set the connection flag to '1' if the rms value rms of the second voltage V2 is greater than the rms value rms of the first voltage V1 (flag = 1) (S550).

Alternatively, when the rms value rms of the second voltage V2 is smaller than the rms value rms of the first voltage V1, the flag setting unit 200 sets the connection flag to '0' (cancel or initialize) (Flag = 0) (S541).

The control unit 110 can calculate whether or not the power supply unit 120 is connected to the generator power supply, based on the connection flag.

Specifically, when the connection flag is '1', the control unit 110 can calculate the connection of the power supply unit 120 with the generator power supply 10 (S560).

Alternatively, when the connection flag is '0', the control unit 110 can calculate the connection by connecting the commercial power supply 20 of the power supply unit 120 (S543).

If the power source unit 120 is connected to the generator power source 10, the controller 110 may automatically sense the generator power source 10 and set the air conditioner to the generator mode at step S570.

On the other hand, conventionally, the generator power source 10 is sensed by using the total harmonic distortion (THD) of the input power source. However, this method requires additional configuration such as a full harmonic distortion detection circuit and the like, .

Further, in the prior art, in the environment where the commercial power supply is not stably supplied, a calculation error of the full harmonic distortion due to the application of the low voltage may occur.

However, according to the present invention, it is possible to detect the generator power supply 10 by detecting the input voltage and the direct current voltage with only a simple resistance element without adding a complicated circuit such as a full harmonic distortion (THD) It will be automatically detected.

In addition, the air conditioner of the present invention recognizes whether or not the generator power is connected with only a simple voltage sensing means, thereby reducing manufacturing cost.

Further, since the air conditioner of the present invention recognizes whether or not the generator power is connected based on the relative magnitudes of the first voltage (V1) and the second voltage (V1), even in an environment where the commercial power is not stably supplied, Can be calculated more accurately.

After the compressor 191 is driven, the control unit 110 may calculate whether or not the power source unit 120 is connected to the generator power source 10.

Specifically, the control unit 110 can calculate whether or not to set the connection flag in a state in which the compressor 191 is driven (S511).

When the connection flag is not set, that is, when the connection flag is '0', the control unit 110 can calculate the connection with the commercial power connection of the power supply unit 120.

The control unit 110 can calculate whether the power supply unit 120 is connected to the generator power supply 10 based on the difference in the second voltage before and after the compressor 191 is driven when the connection flag is set at S513.

As described above, when the compressor 191 is driven, the first voltage V1 and the second voltage V2 can be reduced. In particular, by driving the compressor 191, the second voltage V2 is abruptly reduced.

When the difference between the second voltage V2 before and after the driving of the compressor 191 is equal to or greater than a predetermined value in a state in which the compressor 191 is driven and the connection flag is set, Generator power supply 10 (S560).

That is, since the connection flag has already been set, the control unit 110 can calculate the connection with the generator power supply 10 of the power supply unit 120 without setting the connection flag again.

Meanwhile, the controller 110 may automatically detect the generator power source 10 and set the air conditioner to the generator mode (S570).

When the control unit 110 automatically sets the air conditioner to the generator mode, the control unit 110 can perform the operations of the power consumption control of Fig. 7, the generator overload control of Fig. 11, and the generator no- load control of Fig.

On the other hand, when the difference between the second voltage (V2) before and after the driving of the compressor (191) is less than a predetermined value while the compressor (191) is driven and the connection flag is set, the control unit (S515). That is, the control unit 110 can initialize the connection flag that has already been set.

When the connection flag is released, the control unit 110 can calculate the connection using the connection of the commercial power supply 20 (S514).

On the other hand, the predetermined value can be variably set corresponding to the load state of the generator power supply 10. [ For example, the control section 110 can be set such that the larger the load of the generator power supply 10, the smaller the predetermined value.

The air conditioner according to the present invention variably sets the predetermined value according to the load state of the generator power supply 10, so that it is possible to detect the flexible generator power supply 10 in response to the load state of the generator power supply 10.

6 is a diagram referred to in the description of the operation method of Fig.

Referring to the drawing, a commercial power supply 20 is connected to the power supply unit 120 in a period from 0 to T1, and the effective value S11 of the first voltage is measured to be higher than the effective value S12 of the second voltage .

The air conditioner is connected to the generator power supply 10 and the effective value S11 of the first voltage is changed to the effective value of the second voltage in the period T1 to T2 when the compressor 191 is stopped, S12).

For example, in the interval T1 to T2, the effective value S11 of the first voltage may be 240 (Vrms), while the effective value S12 of the second voltage may gradually decrease at 350 (Vrms).

In particular, the second voltage V2 in the no-load state of the generator power supply 10 sharply rises after the time T11 as shown in FIG.

The air conditioner of the present invention calculates whether or not the generator power supply 10 is connected based on the first voltage V1 and the second voltage V2 in the stopped state (including no load state) of the compressor 191 (First calculation).

More specifically, in a state where the compressor 191 is stopped, when the effective value S12 of the second voltage is larger than the effective value S11 of the first voltage V1, The connection flag can be set to '1'.

When the effective value S12 of the second voltage is larger than the effective value S11 of the first voltage V1 in a state where the compressor 191 is stopped, the controller 110 controls the generator power source 10, The first operation of the connection can be performed.

6, the effective value S12 of the second voltage is 350 (Vrms) and the effective value S11 of the first voltage is 240 (Vrms) in the interval T1 to T2 when the air conditioner is connected to the generator power source 10. [ Vrms). Therefore, since the effective value S12 of the second voltage is larger than the effective value Vrms of the first voltage, the flag setting unit 200 sets the flag to '1', and the control unit 110 determines that the air conditioner Generator 10 is connected to the generator power supply 10.

The air conditioner is connected to the generator power supply 10 and the effective value S12 of the second voltage can be drastically reduced by driving the compressor 191 in the section after T2 in which the compressor 191 is driven .

For example, in the period after T2, the effective value S12 of the second voltage may be drastically reduced at 350 (Vrms) to become Vr (Vrms).

The air conditioner of the present invention can calculate (second calculation) whether or not the generator power supply 10 is connected based on the second voltage V2 before and after driving the compressor 191 while the compressor 191 is driven .

More specifically, when the compressor 191 is driven and the connection flag is set, the effective value S12 of the second voltage before and after the driving of the compressor 191 is equal to or larger than the predetermined value D1 The second calculation of the connection of the generator power supply 10 can be performed.

The predetermined value D1 can be variably set corresponding to the load state of the generator power supply 10. [ For example, the control section 110 can be set so that the predetermined value D1 becomes smaller as the load of the generator power source 10 increases. The default setting value of the predetermined value D1 may be 80 (Vrms).

In FIG. 6, the effective value S12 of the second voltage dropped from about 346 (Vrms) to 260 (Vrms) based on the T2 period. Therefore, since the difference between the effective value S12 of the second voltage is equal to or greater than 80 (Vrms), the control unit 110 can perform the second calculation that the air conditioner is connected to the generator power supply 10.

In the first calculation, the air conditioner of the present invention easily calculates whether or not the generator power source 10 is sensed by using the difference in the relative magnitudes of the first voltage (V1) and the second voltage (V2) , It is possible to accurately detect whether or not the generator power supply 10 is connected by using the absolute difference in magnitude of the second voltage V2 in the second calculation.

The air conditioner computes (first computation) whether or not the generator power supply 10 is connected before driving the compressor 191 and re-computes (second computation) whether or not the generator power supply 10 is connected after the compressor is driven. And provides reliability of the generator power connection result.

Further, since the air conditioner provides a reliable connection result, it is possible to prevent unnecessary power consumption limitation under the commercial power supply 20.

7 is a flowchart showing an operation method of power consumption control in generator mode operation according to the present invention.

Referring to the drawings, the controller 110 can automatically detect the generator power source 10 and set the air conditioner to the generator mode.

When the generator mode is set, the control unit 110 can set a first reference consumption power for limiting power consumption (S710).

In this case, the reference power consumption is set based on the maximum power consumption of the air conditioner, and may be varied according to the capacity of the air conditioner and the capacity of the generator connected to the air conditioner. The control unit 110 sets a reference value in a range of 60 to 80% of the maximum power consumption of the air conditioner. For example, when the capacity of the air conditioner is 1 KW, the controller 110 can set the reference value to 600 W. [ In addition to the first reference consumption power, the controller 110 may set a second reference consumption power that is set to a value lower than the first reference consumption power. Thus, region B in Fig. 8 can be formed. The control unit 110 may perform the operation control based on the second reference consumption power lower than the first reference consumption power so as to control the power consumption to not exceed the first reference consumption power.

The control unit 110 may start the operation of the air conditioner according to the input setting (S720). According to the setting, the compressor 191 of the drive unit of the outdoor unit 2 operates, and the heat-exchanged air in the heat exchanger is discharged into the room.

The voltage sensing unit 140 may measure the voltage from the power supply unit 120 (S350). The voltage sensing unit 140 may measure the first voltage V1 or the second voltage V2 of the power supply unit 120 and apply the measured voltage to the control unit 110. [

The control unit 110 can calculate the power consumption of the air conditioner corresponding to the voltage measured by the voltage sensing unit 140 (S740). The control unit 110 can compare the calculated power consumption with the reference power consumption.

The control unit 110 can compare the second reference consumption power with the calculated power consumption, which is set to be lower than the first reference consumption power and form the region B in Fig. 8 (S750). If the calculated power consumption is less than the second reference power consumption, the control unit 110 may control the driving unit 130 to increase the operating frequency of the compressor 191 by applying a control command to the driving unit 130 (S751).

On the other hand, if the calculated power consumption is equal to or greater than the second reference consumption power, the controller 110 can compare the power consumption with the first reference power consumption (S760). If the calculated power consumption is equal to or higher than the second reference consumption power and lower than the first reference consumption power, the control unit 110 can apply a control command to the driving unit 130 so that the operating frequency of the compressor 191 is maintained at the current value (S770).

If the calculated power consumption exceeds the first reference consumption power, the control unit 110 may apply a control command to the driving unit 130 so that the operating frequency of the compressor 191 decreases (S761). At this time, the controller 110 controls the power consumption of the air conditioner so as not to exceed the first reference power consumption. If the power consumption exceeds the first reference power consumption, the controller 110 immediately decreases the operating frequency of the compressor 191 .

The control unit 110 periodically receives the first voltage V1 or the second voltage V2 from the voltage sensing unit 140 to calculate the power consumption until the operation stop command is input at step S780, (Operation S730 to S770). When the operation stop command is inputted, the control unit 110 can stop the operation (S790).

Accordingly, the air conditioner operates while controlling the power consumption so as not to exceed the set reference power consumption, so that the connected power source, that is, the generator is prevented from being overloaded, and continuous operation becomes possible.

8 is a diagram referred to in the description of Fig.

Referring to the drawings, the controller 110 can set the first reference consumption power for the power consumption based on the maximum power consumption of the air conditioner when the generator mode is set. For example, in the case of an air conditioner of 1 KW, the controller 110 can set 600 W to the first reference consumption power TG1.

The control unit 110 may compare the set first reference consumption power TG1 with the calculated power consumption so that the power consumption does not exceed 600 W which is the reference consumption power. At this time, the controller 110 may separately set the second reference consumption power TG2. When the first reference consumption power TG1 described above is 600W, the second reference consumption power TG2 can be set to about 500W.

The control unit 110 can increase the operating frequency of the compressor 191 without any limitation when the power consumption to be calculated is included in the first region A having the second reference consumption power TG2 or lower. When the operating frequency of the compressor 191 increases, the power consumption of the air conditioner can also be increased accordingly (S21).

The control unit 110 calculates power consumption corresponding to the measured voltage and applies a control command to the driving unit 130 so that the compressor 191 is controlled when the calculated power consumption reaches the second reference consumption power TG2 . At this time, the driving unit 130 may limit the operation frequency of the compressor to no longer increase according to the control command of the control unit 110. [

The driving unit 130 can maintain the operating frequency of the compressor 191 when the power consumption is included in the second region B between the first reference power consumption TG1 and the second reference power consumption TG2 . On the other hand, when the power consumption is the first reference power consumption TG1 or more, the operation frequency of the compressor 191 is decreased so that the amount of power consumed can be reduced (S22).

When the power consumption of the compressor 191 is reduced to reduce the power consumption, the cooling capacity also decreases, so that when the power consumption falls within the first area A, .

At this time, the control unit 110 may limit the maximum value of the operation frequency of the compressor 191, that is, the maximum operation frequency that can be operated, so that the compressor 191 can not operate at a frequency higher than the maximum operation frequency. Accordingly, the control unit 110 can prevent the power consumption of the air conditioning from exceeding the first reference power consumption.

9 is a diagram referred to in the description of Fig.

Referring to the drawings, the operating frequency S31 of the compressor 191 may increase when the air conditioner automatically detects the generator power source 10 and operates in the generator mode. Accordingly, the power consumption S32 of the air conditioner can also be increased.

The controller 110 can set the first reference consumption power S33 for the power consumption as the generator mode is set. At this time, the first reference consumption power S33 may be set at about 60 to 80% based on the maximum power consumption of the air conditioner.

The controller 110 calculates the power consumption of the air conditioner corresponding to the first voltage V1 and the second voltage V2 measured during operation and controls the calculated power consumption so as not to exceed the reference value .

As described above, when the power consumption calculated by setting the second reference consumption power lower than the first reference consumption power exceeds the second reference consumption power, the control unit 110 applies a control command to the driving unit 130, It is possible to control the operation frequency of the motor 191.

When the power consumption is equal to or greater than the second reference consumption power and is less than the first reference consumption power, the driving unit 130 can maintain the current operating frequency of the compressor 191 because it belongs to the second region B of FIG.

Accordingly, the operation frequency of the compressor 191 is maintained at a constant value, and the power consumption does not exceed the set first reference consumption power although the value thereof is fluctuated due to the variation of the input voltage or the load.

Therefore, the air conditioner can be operated for a long time without stopping the operation, and the constant cooling ability can be maintained.

10 is a flowchart showing an operation method of the generator overload control in the generator mode operation according to the present invention.

Referring to the drawings, the controller 110 can automatically detect the generator power source 10 and set the air conditioner to the generator mode.

The voltage sensing unit 140 may measure the second voltage V2 of the DC link unit 123 and may input the measured voltage to the control unit 110 (S1010).

The controller 110 may control the operation of the compressor 191 by comparing the measured second voltage V2 with the set voltage.

The control unit 110 may apply the control command to the driving unit 130 so that the operating frequency of the compressor 191 is reduced if the measured voltage is less than the first set voltage (setting value) (S1020).

On the other hand, if the measured voltage is equal to or higher than the first set voltage and is lower than the second set voltage (S1040), the controller 110 can maintain the operating frequency of the compressor 191. (S1050). At this time, the second set voltage may be set to be larger than the first set voltage.

If the measured voltage is equal to or higher than the second set voltage, the controller 110 may apply a control command to the driving unit 130 to increase the operating frequency of the compressor 191 (S1060).

However, the control unit 110 may increase the operating frequency of the compressor 191 within a range where the power consumption is less than the first reference consumption power. When the power consumption reaches the first reference consumption power, the controller 110 can control the operation frequency of the compressor 191 to be reduced.

The control unit 110 increases or decreases the operating frequency of the compressor 191 in response to a change in the voltage of the DC link unit 123 measured by the voltage sensing unit 140 , Or to maintain the voltage of the DC link unit 123 not to be lower than the first set voltage while the voltage of the DC link unit 123 rises to increase the operating frequency so as to increase the cooling capacity S1010 to S1060).

When the operation stop command is inputted (S1070), the control unit 110 can stop the operation of the air conditioner (S1080).

11 is a diagram referred to in the explanation of the operation method of Fig.

11A is a diagram showing changes in voltage and compressor operating frequency over time when the air conditioner is connected to a generator and in a normal operation, and FIG. 11B is a graph showing changes in the operating frequency according to the second voltage V2 The voltage and the operation frequency of the compressor are shown in Fig.

11A, when the air conditioner automatically detects the generator power source 10 and operates in the generator mode, the operating frequency S41 of the compressor 191 increases, The power consumption (S42) of the battery can be increased. At this time, as the power consumption increases, the second voltage S43 has a limit on the capacity of the generator, so that the voltage decreases. When the voltage of the DC link unit 123 is reduced to 200 V or less because the generator is overloaded due to the limitation of the capacity of the generator due to an increase in the operating frequency of the compressor 191 and an increase in power consumption, do. When the air conditioner stops operating, the voltage of the second voltage S43 rises again because the load of the generator decreases.

In the air conditioner, the operation of the air conditioner is stopped by the operation of the protection circuit, and the air conditioner is restarted after a predetermined time, but stopped again, and the operation and stop are repeated.

In Fig. 11B, in the generator mode, when the air conditioner starts to operate, the operating frequency S51 of the compressor 191 increases and accordingly the power consumption S52 also increases. At this time, the voltage of the voltage S53 of the DC link unit 123 decreases. As described above, when the voltage reaches the set voltage, the controller 110 determines that the generator is overloaded and the operation frequency of the compressor 191 is It can be controlled not to increase any more.

When the voltage of the DC link unit 123 is maintained above the set voltage and the voltage is kept constant, the control unit 110 controls the operation frequency of the compressor 191 to increase so as to increase the cooling capacity, It is possible to repeat control so that the operating frequency of the compressor 191 is decreased again so as not to decrease to the set voltage or lower when the voltage of the compressor 123 decreases again.

Accordingly, the air conditioner continuously operates for a long time while eliminating the overload problem of the generator.

12 is a flowchart showing an operation method of the no-load generator control in the generator mode operation according to the present invention.

Referring to the drawings, the controller 110 can automatically detect the generator power source 10 and set the air conditioner to the generator mode.

The voltage sensing unit 140 may measure the second voltage V2 of the DC link unit 123 in step S1210 and input the measured voltage to the controller 110 in the state where the generator mode is set.

The control unit 110 can determine the load state with respect to the power supply of the generator in accordance with the measured voltage. If the measured voltage is equal to or higher than the predetermined third set voltage (S1220), the controller 110 determines that the input power source is in a no-load state, and otherwise determines the normal load state.

The control unit 110 determines the load state so that the voltage does not rise any more at the time when a voltage that can be received by the capacitor of the DC link unit 123 is applied and controls the operation of the air conditioner Can be controlled.

The control unit 110 applies a control command to the driving unit 130 and the driving unit 130 operates the outdoor fan 192 in response to the control command when it is determined that the generator power source 10 is in a no- (S1230). The air conditioner allows only the outdoor fan 192 to operate in a state in which the compressor 191 is not operated and can control the compressor 191 or the indoor fan 193 in some cases. When only the indoor fan 193 is operated, the fan operates in the blowing mode.

At this time, the control unit 110 can control the operation within a range in which the power consumption calculated according to the voltage does not exceed the reference value for the generator mode.

The voltage sensing unit 140 periodically measures the voltage of the DC link unit 123 and inputs the measured voltage to the control unit 110 (S1240).

The control unit 110 may count the time the outdoor fan 192 is operated and determine whether the outdoor fan 192 has operated for more than the set time at operation S1250.

When the set time has elapsed after the operation of the outdoor fan 192, the control unit 110 may apply a control command to the driving unit 130 so that the outdoor fan 192 may stop operation (S1270).

If the voltage of the DC link unit 123 does not decrease below the third set voltage even after the outdoor fan 192 operates, the controller 110 may damage the power supply unit 120, It is judged that there is an abnormality and an error is outputted.

If the preset time does not pass after the operation of the outdoor fan 192, the control unit 110 may determine whether the voltage input from the voltage sensing unit 140 is less than the fourth set voltage (S1260). At this time, the fourth set voltage is set to be lower than the third set voltage, and may be set to a voltage such that the air conditioner can maintain operation.

If the measured voltage is lower than the fourth set voltage before the set time has elapsed, the control unit 110 may apply a control command to the driving unit 130 to stop the outdoor fan 192 from operating (S1270).

When the voltage of the DC link unit 123 decreases due to the operation of the outdoor fan 192, the voltage of the DC link unit 123 decreases and the air conditioner can not operate. The operation can be stopped even if it is not operated for the set time. In addition, when the power consumption calculated according to the voltage rises, the operation of the outdoor fan 192 can be controlled so as not to exceed the reference consumption power.

After the outdoor fan 192 stops, the controller 110 periodically receives the voltage from the voltage sensing unit 140. When the voltage exceeds the third reference voltage, the controller 110 determines that the power source is in a no-load state, So that the voltage of the DC link unit 123 is reduced and the outdoor fan 192 is repeatedly stopped after the set time operation.

In this manner, the air conditioner measures the voltage of the DC link unit 123, determines the load state of the generator, and when the voltage becomes equal to or higher than the set voltage in order to prevent a high voltage from being applied to the air conditioner, 192 to operate to reduce the voltage of the DC link unit 123 and stop the operation when the outdoor fan 192 is operated for a predetermined time,

13 is a diagram referred to in the description of Fig.

Referring to the drawings, when the generator power source 10 is in a no-load state, a high voltage may be applied to the power source unit 120 of the air conditioner, as described above.

The control unit 110 sets the generator mode and receives the voltage of the DC link unit 123 from the voltage sensing unit 140 and compares the received voltage with the set voltage to determine the load state of the generator power source 10. [

When the voltage S71 of the DC link unit 123 rises and becomes equal to or higher than the third set voltage T12, the control unit 110 applies a control command to the driving unit 130 to control the outdoor fan 192, Can be operated. For example, the third set voltage may be about 440V.

When the outdoor fan 192 is operated (T12), the voltage S62 of the outdoor fan rises and the generator power supply 10 can maintain a constant voltage. Since the operation of the outdoor fan 192 acts as a load to the generator power supply 10, the voltage S61 of the DC link portion 123 can be reduced. Also, since the outdoor fan 192 acts as a load of a predetermined size, the voltage of the DC link unit 123 can be kept constant during the operation of the outdoor fan after the predetermined voltage is reduced.

The driving unit 130 may stop the operation after the outdoor fan 192 has been operated for a set time according to the control command of the control unit 110 (T13). At this time, when the outdoor fan 192 stops operating (T13), the voltage applied to the outdoor fan 192 decreases and the generator power supply 10 is again in a no-load state, and the voltage of the DC link unit 123 Can rise.

The control unit 110 may apply a control command to the driving unit 130 to cause the outdoor fan 192 to operate again when the voltage of the DC link unit 123 rises to reach the third set voltage T14.

The control unit 110 determines the load state of the generator power supply 10 according to the magnitude of the voltage applied to the DC link unit 123 of the power supply unit 120 and operates the outdoor fan 192 for a predetermined time, Is applied to the generator power supply 10, it is possible to prevent the voltage of the DC link unit 123 from rising.

The control unit 110 can repeat the no-load determination of the generator power supply 10 and the operation control operation of the outdoor fan 192 accordingly.

Accordingly, the air conditioner determines the load state of the connected generator, and the load of a predetermined size is applied to the generator in response to the load, thereby preventing damage to the product due to a high voltage unnecessarily applied to the generator.

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.

10: Generator power
20: Commercial power supply
110:
120:
141: first voltage sensing unit
142: a second voltage sensing unit
191: Compressor
192: Outdoor fan
193: Indoor fans
200: flag setting unit

Claims (12)

A power supply unit connected to at least one of a generator power supply and a commercial power supply for receiving an AC power supply and converting the input AC power supply to a DC power supply;
A first voltage sensing unit sensing a first voltage of the input AC power supply;
A second voltage sensing unit for sensing a second voltage of the DC power supply; And
And a controller for calculating whether the power supply unit is connected to a generator power supply based on the first voltage and the second voltage. The method according to claim 1,
Wherein,
Wherein when the second voltage is greater than an effective value (rms) of the first voltage in a state in which the compressor is stopped, the generator is connected to the generator power connection of the power supply. The method according to claim 1,
And a flag setting unit for setting a connection flag which is a connection state value with the generator power supply,
Wherein,
Wherein the connection flag is set when the power source unit is operated with the generator power connection, and the connection flag is released when the power source unit is operated with the commercial power connection. The method according to claim 1,
And a driving unit for driving the compressor,
Wherein,
Wherein the controller determines whether or not the power supply unit is connected to the generator power supply based on a difference between the first voltage and the second voltage before and after the compressor is driven. 5. The method of claim 4,
Wherein,
Wherein when the connection flag is set in a state in which the compressor is driven, whether or not the power supply unit is connected to the power supply of the generator is calculated. 5. The method of claim 4,
Wherein,
Wherein when the difference between the first voltage and the second voltage before and after the compressor drive is equal to or greater than a predetermined value, the generator is connected to the generator power supply of the power supply. The method according to claim 6,
Wherein,
Wherein the predetermined value is set variable according to a load state of the generator power source. The method according to claim 1,
The power supply unit,
A power input unit to which power of either the generator power or the commercial power is input;
A rectifying unit for rectifying the input power source;
And a DC link portion for smoothing the rectified power supply,
The first voltage sensing unit includes:
And measures the first voltage between the power input unit and the rectifying unit and inputs the measured first voltage to the control unit. 9. The method of claim 8,
The second voltage sensing unit includes:
And the second voltage of the DC link unit is measured and input to the control unit. The method according to claim 1,
Wherein,
Wherein the power mode of the air conditioner calculated from the first voltage or the second voltage at the time of the generator mode operation is changed to the power mode of the generator mode, Wherein the operation frequency of the compressor is controlled so as not to exceed the reference consumption power for the compressor. The method according to claim 1,
Wherein,
Wherein the control unit detects the connection with the generator power supply to change the operation mode to the generator mode and calculates whether the generator power is overloaded in response to the second voltage when the generator mode is in operation, The control means controls the operation frequency of the compressor to be reduced. The method according to claim 1,
Wherein,
Wherein the control unit detects the connection with the generator power supply to change the operation mode to the generator mode and calculates whether the generator power is no load in response to the second voltage in the generator mode operation, Wherein the controller controls the compressor or the outdoor fan to operate.

Images