KR102140951B1 - Power supply apparatus and air conditioner including the same - Google Patents

Abstract

Provided is a power supply device capable of dynamically controlling EMI noise or heat loss by varying circuit constants and the like according to the surrounding situation according to the present invention. The power supply device includes a switching power supply circuit (SMPS) for supplying power in the form of a switching signal to a load, and a snubber circuit configured to reduce a noise level caused by the switching signal from the SMPS. . At this time, the resistance value connected between both terminals of the snubber circuit is configured to vary according to the current consumed by the load of the power supply, and the switching speed and the noise level of the switching signal are changed by the variable resistance value. Can be. Accordingly, when the EMI noise is severe, the rise time of the switching signal is slowed to reduce the EMI noise, and when the EMI noise is weak, the rise time of the switching signal is increased to reduce heat loss.

Description

Power supply device and air conditioner including the same{POWER SUPPLY APPARATUS AND AIR CONDITIONER INCLUDING THE SAME}

The present invention relates to a power supply device, and more particularly, to a power conversion device for reducing electric noise and an air conditioner comprising the same.

In general, home appliances including air conditioners require a power supply. In particular, a household appliance having a switching power supply circuit (SMPS) may include a snubber circuit to reduce the electrical noise level caused by the switching signal.

On the other hand, in relation to such a snubber circuit, in the snubber circuit of Korean Patent Publication No. 10-1986-0008621, GTO thyristor, the snubber circuit shows a configuration in which a thyristor and a diode are combined.

Specifically, when the voltage applied to the snubber circuit is low by connecting the thyristor gate and the resistor, the thyristor is turned off so that the snubber circuit does not operate. Therefore, it is designed to actively operate in dangerous conditions including overvoltage.

However, the main purpose of this patent is that the snubber circuit is designed to operate when in a dangerous state such as overvoltage. Accordingly, according to such a configuration, there is a problem that small ripples occurring in the power supply device cannot be prevented. Accordingly, there is a problem that it is not possible to reduce the EMI noise that normally occurs in the switching power supply circuit (SMPS).

In addition, since a fixed type snubber circuit is used, there is a problem in that it is not possible to dynamically control EMI noise or heat loss by varying circuit constants and the like according to the surroundings of a home appliance including an air conditioner.

Accordingly, there is a need for a power supply device capable of dynamically controlling EMI noise or heat loss by varying circuit constants and the like according to the surroundings of a home appliance including an air conditioner.

The present invention is to provide a power conversion device for reducing electric noise and reducing heat generation and an air conditioner including the same.

In addition, the technical problem of the present invention is to provide a power conversion device and an air conditioner including the same, which dynamically reduce electric noise and reduce heat generation according to surrounding conditions through a circuit configuration of the power conversion device.

In order to solve the above problems, a power supply device capable of dynamically controlling EMI noise or heat loss by varying circuit constants and the like according to the surrounding situation according to the present invention is provided. The power supply device includes a switching power supply circuit (SMPS) for supplying power in the form of a switching signal to a load, and a snubber circuit configured to reduce a noise level caused by the switching signal from the SMPS. . At this time, the resistance value connected between both terminals of the snubber circuit is configured to vary according to the current consumed by the load of the power supply, and the switching speed and the noise level of the switching signal are changed by the variable resistance value. Can be. Accordingly, when the EMI noise is severe, the rise time of the switching signal is slowed to reduce the EMI noise, and when the EMI noise is weak, the rise time of the switching signal is increased to reduce heat loss.

In one embodiment, the resistance value of the snubber circuit is configured to vary according to a heating mode or a cooling mode of an air conditioner supplied with power by the power supply device. At this time, when the resistance value increases, electromagnetic interference (EMI) decreases, and when the resistance value decreases, heat generation in the load of the air conditioner may decrease.

In one embodiment, when the air conditioner is operated in the heating mode, the snubber circuit may be configured to reduce EMI by increasing the resistance value. On the other hand, when the air conditioner operates in the cooling mode, the snubber circuit may be configured such that the resistance value decreases and heat generation decreases.

In one embodiment, the snubber circuit is connected to a capacitor connected to any one of both terminals of the internal transistor, and connected to the capacitor in series, and to the other terminal of the capacitor and both terminals of the internal transistor. And a first resistor having a first resistance value. Further, the snubber circuit is connected in series with the capacitor, connected in parallel with the first resistor, and connected to the other terminal of both terminals of the internal transistor, and further includes a second resistor having a second resistance value. It can contain.

In one embodiment, the first resistor may be a negative temperature coefficient (NTC) thermistor (NTC) in which the first resistance value decreases as the ambient temperature increases.

In one embodiment, when the air conditioner supplied with power by the power supply operates in a heating mode, the first resistance value of the NTC thermistor increases. Accordingly, EMI may decrease as the equivalent resistance value of the NTC thermistor and the second resistor increases. On the other hand, when the air conditioner operates in a cooling mode, the second resistance value of the NTC thermistor decreases. Accordingly, as the equivalent resistance value due to the NTC thermistor and the second resistor decreases, the time constant decreases and the switching speed increases.

In one embodiment, the air conditioner may further include a control unit for controlling the driving state. At this time, the controller may reduce the EMI by increasing the rise time t _r of the switching signal when EMI is higher than a certain level through the EMI detection filter provided in the air conditioner.

Meanwhile, in the present invention, EMI noise reduction and heat generation reduction may be dynamically performed in a home appliance such as an air conditioner according to a surrounding situation, for example, ambient temperature. On the other hand, when the EMI noise level is large, EMI noise reduction may be preferentially performed regardless of surrounding conditions, that is, an operation mode.

In one embodiment, even when the air conditioner operates in the cooling mode and the first resistance value of the NTC thermistor decreases, the control unit increases the rise time t _r of the switching signal when EMI is above a certain level. To reduce EMI.

In one embodiment, as the ambient temperature increases as the air conditioner continues to operate in the heating mode, even when the first resistance value of the NTC thermistor decreases, the rise time t _r of the switching signal is increased to increase EMI Can be reduced.

The effects of the power conversion device and the air conditioner including the same will be described as follows.

According to at least one embodiment of the present invention, when the EMI noise is severe, the rise time of the switching signal is slowed to reduce the EMI noise, and when the EMI noise is weak, the rise time of the switching signal can be increased to reduce heat loss. There are advantages.

In addition, according to at least one embodiment of the present invention, since an NTC whose resistance value is changed according to the surrounding environment is used, the RC snubber circuit has an optimal circuit constant (time constant) for each situation to optimize power signal characteristics. It has the advantage of being able to.

Further scope of applicability of the present invention will become apparent from the following detailed description. However, various changes and modifications within the spirit and scope of the present invention may be clearly understood by those skilled in the art, and thus, it should be understood that specific embodiments such as detailed description and preferred embodiments of the present invention are given by way of illustration only.

1 is an embodiment of an air conditioner control device according to the present invention.
2 shows a detailed configuration of the power supply device of the present invention.
3 shows a circuit configuration connected to both terminals of a switching power supply circuit according to an embodiment of the present invention and a change in resistance value according to temperature.
4 shows the power spectrum according to the frequency when the RC circuit is not applied to the snubber circuit according to the present invention.
5 shows a power spectrum according to frequency when an RC circuit is applied to a snubber circuit according to the present invention.
6 shows a representation in a time and frequency domain of a power signal of a switching form according to the present invention.
7 shows a voltage and current signal type and a switching loss for a power signal of a switching type according to the present invention.
8 is a conceptual diagram showing a time domain representation of a switching type power signal according to the present invention and loss due to switching.

Hereinafter, exemplary embodiments disclosed herein will be described in detail with reference to the accompanying drawings, but technical terms used in the specification are only used to describe specific embodiments, and are intended to limit the spirit of the technologies disclosed herein. It should be noted that it is not. In addition, technical terms used in this specification should be interpreted as meanings generally understood by a person having ordinary knowledge in the field to which the technology disclosed in this specification belongs, unless defined otherwise. It should not be interpreted as a comprehensive meaning or an excessively reduced meaning.

1, an embodiment of the air conditioner control apparatus 100 according to the present invention is described. For reference, the air conditioner control device 100 disclosed in the present invention may be applied to various types of air conditioners. In addition, the air conditioner having the air conditioner control device 100 disclosed in the present invention may operate in a heating mode or a cooling mode.

Referring to FIG. 1, the air conditioner control device 100 includes a communication circuit control unit 110, a power circuit control unit 120, a fan/valve drive circuit control unit 130, a sensor control unit 140, and a compressor drive circuit control unit ( 150 ), an output unit 160, an input unit 170, a control unit 180, and a communication unit 190.

The communication circuit control unit 110 may control performing communication with a preset protocol between the indoor unit and the outdoor unit of the air conditioner.

The power circuit controller 120 may control power supply by the power supply device of the air conditioner and a power supply circuit related thereto.

The fan/valve drive circuit control unit 130 may control the fan and/or valve of the air conditioner. In this regard, the valve driving circuit of the PCB of the air conditioner for controlling the valve for adjusting the flow rate of the refrigerant in the refrigerant flow path included in the air conditioner can be controlled. In addition, it is possible to control the operation of the outdoor fan of the air conditioner and the fan motor for rotating the outdoor fan.

The sensor control unit 140 may control various sensors installed in the air conditioner and determine whether or not a failure occurs. On the other hand, in the power supply device according to the present invention, the noise (noise) or electromagnetic interference (EMI: Electro-Magnetic Interference) to reduce the level of the EMI sensor can be controlled to detect the EMI level.

The compressor driving circuit controller 150 may control the operation of the compressor included in the air conditioner. To this end, it is possible to check whether the compressor driving circuit of the air conditioner PCB is operating normally.

The output unit 160 is controlled by the communication circuit control unit 110, the power circuit control unit 120, the fan/valve drive circuit control unit 130, the sensor control unit 140, and the compressor drive circuit control unit 150. It can output the status information and / or control status. In addition, information related to the control result and/or the inspection result according to the control may be output.

In one embodiment, the output unit 160 is formed of a plurality of light emitting elements, and may output information related to a control result and/or an inspection result according to such control.

In another embodiment, the output unit 160 may be formed as a display unit to output the state of the air conditioner. Alternatively, it may be formed as a display unit to output a screen of an application for performing status diagnosis. In this case, as the application mounted on the controller 180 is performed, the output unit 160 may output a screen corresponding to the application.

In one example, the output unit 160 is formed as a touch screen, and outputs the screen, and may receive a user input for performing control and/or status diagnosis of the air conditioner. In this case, the output unit 160 may be integrally formed with the input unit 170.

The touch screen may function as a user input unit that provides an input interface between the air conditioner control device 100 and a user, and at the same time, provide an output interface between the air conditioner control device 100 and a user.

The input unit 170 may receive a user input for performing control of the air conditioner. The input unit 170 may receive a user input for receiving a command related to state control and power control of the air conditioner. The controller 180 may control some circuits and/or software modules of the controller performing the corresponding function based on the authorized user input.

In one embodiment, the input unit 170 may be formed of a dip switch, and according to a user's switch operation, the communication circuit control unit 110, the power circuit control unit 120, and the fan/valve drive circuit control unit 130 , One of the sensor control unit 140 and the compressor driving circuit control unit 150 may be activated.

In another embodiment, the input unit 170 may receive a user input for controlling on/off of the air conditioner control device 100 or a user input for controlling the operation of the air conditioner failure diagnosis device 100. It may also include a plurality of buttons.

The communication unit 190 may receive a signal related to the operation state of the air conditioner from the PCB of the air conditioner, or transmit a signal for power supply and/or power control of the air conditioner to the PCB. The communication unit 190 may use a protocol corresponding to communication performed between the indoor unit and the outdoor unit of the air conditioner or circuits performing the corresponding functions.

That is, the communication unit 190 may receive information related to an operation state of the air conditioner by performing communication with the PCB of the corresponding controller based on a protocol used by the air conditioner. Also, the communication unit 190 may transmit a control command for controlling the operation of the air conditioner to the PCB.

The controller 180 may drive an application program stored in the controller 180 or a memory (not shown) to perform an operation of the air conditioner control device 100.

The controller 180 controls the overall operation of the air conditioner control device 100, in addition to the operations related to the application program. The controller 180 may provide or process appropriate information or functions to the user by processing signals, data, information, etc. input or output through the above-described components or driving an application program stored in the memory.

The controller 180 may generate signals generated by the compressor, fan motor, valve motor, and communication module, which are the objects controlled by the PCB of the air conditioner.

Specifically, the controller 180 of the control device 100 may receive a control command that the PCB of the air conditioner transmits to a component of the air conditioner, and the component outputs the control command in response to the control command. A response signal can be generated and transmitted to the PCB.

The memory (not shown) of the control device 100 may store information related to the operation algorithm of the air conditioner to be diagnosed, and the controller 180 may control control commands received from the PCB based on the algorithm information stored in the memory. In response, the response signal may be generated.

Accordingly, when the PCB operates components of an air conditioner such as a power circuit, a compressor, a fan motor, a valve motor, and a communication module, information exchanged with the components can be exchanged with the control device 100. have.

While transmitting and receiving information related to the operation of the PCB and the air conditioner, the controller 180 may compare information related to the operation of the air conditioner received from the PCB and operation information of a preset normal condition. In addition, it is possible to determine whether or not a specific circuit portion of the PCB operates normally according to the comparison result.

Meanwhile, the control unit 180 may check whether the circuits of the control unit performing the corresponding function are operating normally based on the information received through the communication unit 190.

On the other hand, according to the power supply device of the present invention, the controller 180 can detect the operation mode of the air conditioner. In this way, the switching speed of the power supply circuit can be changed to change the noise level such as EMI interference according to the operation mode. Alternatively, the noise level such as EMI interference may be automatically changed according to the ambient temperature associated with the operation mode without detecting the operation mode.

The power supply device according to the present invention may be used in an air conditioner, but is not limited thereto, and may also be used in a home appliance that controls a power supply and/or power supply circuit. On the other hand, the air conditioner is provided with a switching power supply circuit (SMPS) for supplying power. However, since the SMPS device switches at a high speed, it generates a lot of EMI noise. To reduce this noise, a snubber circuit can be used. However, when such a snubber circuit is used, heat is generated because the switching speed is slowed down.

Therefore, when developing an air conditioner, one of two disadvantages is inevitably selected. On the other hand, in the case of an air conditioner capable of both cooling and heating, the operating environment of the two functions is different. On the other hand, according to the present invention, in the heating mode that consumes a lot of current, it is possible to reduce EMI noise by increasing the resistance of the snubber circuit. On the other hand, in the cooling mode, which consumes less current than the heating mode, heat generation can be reduced by reducing the resistance of the snubber circuit. The operation mode and the resulting EMI noise reduction or heat generation reduction will be described in detail below.

On the other hand, Figure 2 shows the detailed configuration of the power supply of the present invention. The power supply device of FIG. 2 may be used for an air conditioner, but is not limited thereto, and may also be used for a home appliance that controls a power supply and/or power circuit.

2, the power supply device includes a switching power supply circuit (SMPS, 200) and a snubber (snubber) circuit 300. The switching power supply circuit 200 supplies power in the form of a switching signal to the load. At this time, it may be supplied with power from an external power supply unit to convert to a switching signal type, or may generate power in the form of a switching signal itself.

Meanwhile, the snubber circuit 300 is connected to the switching power supply circuit 200 and is configured to reduce a noise level caused by a switching signal from the switching power supply circuit 200. Specifically, the resistance value connected between both terminals of the snubber circuit 300 may be configured to vary according to the current consumed by the load of the power supply. Accordingly, the switching speed and noise level of the switching signal may be changed by the variable resistance value.

Meanwhile, FIG. 3 shows a circuit configuration connected to both terminals of a switching power supply circuit according to an embodiment of the present invention and a change in resistance value according to temperature. Referring to FIGS. 2 and 3A, the snubber circuit 300 may include a capacitor C1, a first resistor NTC, and a second resistor R2. At this time, the capacitor C1 may be connected to either terminal of both terminals of the internal transistor. For example, the capacitor C1 may be connected between the emitter terminal of the internal transistor and the first resistor NTC and the second resistor R2.

Meanwhile, the first resistor NTC is connected in series with the capacitor C1, is connected to the other terminal of the capacitor C1 and both terminals of the internal transistor, and may have a first resistance value. For example, the first resistor NTC may be connected to the capacitor C1 and the collector terminal of the internal transistor, and the first resistor value may be a variable value depending on the ambient temperature.

Meanwhile, the second resistor R2 may be connected in series with the capacitor C1, and may be connected in parallel with the first resistor NTC. In addition, the second resistor R2 is connected to the other terminal of both terminals of the internal transistor, and may have a second resistance value. Referring to (b) of FIG. 3, the second resistance value may be the same as the resistance value at a specific temperature of the first resistor NTC, but is not limited thereto. For example, the second resistance value may be 10 Ω, which is the same as the resistance value at a low temperature corresponding to the heating mode, but is not limited thereto.

Meanwhile, the first resistor NTC may be a negative temperature coefficient (NTC) thermistor, in which the first resistance value decreases as the ambient temperature increases. Referring to FIG. 3B, the first resistance value may be 10 Ω at a low temperature corresponding to the heating mode, and the first resistance value may be 3 Ω at a high temperature corresponding to the cooling mode.

In this regard, when the air conditioner supplied with power by the power supply device operates in the heating mode, the first resistance value of the NTC thermistor may increase. For example, at a low temperature corresponding to the heating mode, the first resistance value may increase to 10 Ω. Accordingly, the equivalent resistance value by the NTC thermistor and the second resistor R2 increases. For example, both the NTC thermistor and the second resistor R2 become 10 Ω, and the equivalent resistance value becomes 5 Ω.

On the other hand, when the first resistance value of the NTC thermistor is much larger than 10 Ω at a low temperature corresponding to the heating mode, the equivalent resistance value R _eq increases close to 10 Ω, which is the second resistance value of the second resistance R2. do. Accordingly, the time constant τ = R _eq C1 according to the equivalent resistance value R _eq increases and EMI decreases. That is, when the time constant, that is, the circuit constant increases, the rise time increases in the time domain (switching rate decreases), and spectrum attenuation is rapidly performed in the frequency domain to reduce EMI noise. This will be described in detail below.

On the other hand, when the air conditioner operates in the cooling mode, the first resistance value of the NTC thermistor is reduced, and the equivalent resistance value by the NTC thermistor and the second resistor R2 is reduced. For example, the first resistance value may be reduced to 3 Ω at a high temperature corresponding to the cooling mode. Accordingly, the equivalent resistance value by the NTC thermistor and the second resistor R2 is reduced. For example, if the first resistance value of the NTC thermistor is 3 Ω and the second resistance value of the second resistor R2 is 10 Ω, the equivalent resistance value has a value less than 3 Ω. Depending on the reduced equivalent resistance value, the time constant decreases and the switching speed increases.

On the other hand, the resistance value of the snubber circuit 300 may be varied depending on the heating mode or the cooling mode of the air conditioner supplied with electric power by the power supply device. In this regard, when the resistance value of the snubber circuit 300 increases, electromagnetic interference (EMI) decreases due to a high circuit constant as described above.

In this regard, Table 1 shows the relationship between current consumption, EMI, noise, and RC time constant according to the operation mode (heating mode, cooling mode) in the present invention.

Heating mode Cooling mode Current consumption height lowness EMI noise A lot Less frequently RC time constant Must be big Must be small

Specifically, when the air conditioner operates in a heating mode at a low temperature, the snubber circuit 300 may be configured to reduce EMI by increasing a resistance value as shown in FIG. 3B. In this regard, when the current consumption is large as in the heating mode, since the EMI noise increases, it is necessary to reduce the EMI noise by increasing the resistance value of the snubber circuit 300.

On the other hand, when the resistance value of the snubber circuit 300 decreases, heat generation (or heat loss) in the load of the air conditioner decreases. Specifically, when the air conditioner operates in a cooling mode at a high temperature, the snubber circuit 300 may reduce heat resistance by reducing a resistance value. In this regard, when the current consumption is small, such as in the cooling mode, EMI noise is not a problem, so it is more important to reduce heat generation (heat loss).

Therefore, according to the power supply device and its configuration circuit according to the present invention, when the EMI noise is severe, a high circuit constant is selected to reduce EMI noise, and when the EMI noise is weak, a low circuit constant is selected to reduce heat loss. It has the advantage of being able to do it.

In addition, according to the power supply device and its configuration circuit according to the present invention, the RC snubber circuit has an optimal circuit constant (time constant) for each situation because it uses NTC whose resistance value varies depending on the surrounding environment. It has the advantage that it can be optimized.

Meanwhile, referring to FIG. 1, the controller 180 may control a driving state and an operation mode (cooling mode, heating mode) of the air conditioner. On the other hand, if the EMI is higher than a certain level through the EMI detection filter provided in the air conditioner, the controller 180 may reduce the EMI by increasing the rise time t _r of the switching signal regardless of the operation mode. That is, even in the cooling mode, if the EMI is above a certain level, the EMI may be reduced by increasing the rise time t _r of the switching signal even in the cooling mode.

In this regard, even if the air conditioner operates in a cooling mode and the first resistance value of the NTC thermistor decreases, the controller 180 increases the rise time t _r of the switching signal to reduce EMI when the EMI is higher than a certain level. I can do it.

On the other hand, as the ambient temperature rises as the air conditioner continues to operate in the heating mode, even when the first resistance value of the NTC thermistor decreases, the rise time t _r of the switching signal can be increased to reduce EMI. To this end, a switch connected in series with the NTC thermistor may be further provided. At this time, although the ambient temperature is relatively low, the EMI noise level may be high. Therefore, in order to increase the rise time t _r by increasing the time constant, a switch connected in series with the NTC thermistor can be turned off. Accordingly, the time constant can be determined by the second resistor R2 regardless of the NTC thermistor.

Accordingly, the present invention can reduce EMI or reduce heat loss according to the reduction or increase of the switching speed automatically according to the ambient temperature using the NTC thermistor. In addition, it is a principle to automatically reduce EMI or reduce heat loss according to the ambient temperature, but it is characterized by reducing EMI irrespective of the ambient temperature if it is above a threshold level by directly measuring the EMI level.

On the other hand, in terms of the scope of rights to be protected by the present invention, the present invention has the following technical features.

In this regard, the present invention is characterized by reducing heat generation by resistance and reducing EMI generation by using the fact that the ambient temperature is high in the cooling mode and the ambient temperature is low in the heating mode.

In addition, the present invention is characterized in that the NTC thermistor whose resistance value is changed according to the ambient temperature is used in the snubber circuit to automatically reduce heat generation due to resistance and reduce EMI generation according to the ambient temperature.

In addition, the present invention dynamically adjusts and fixes the maximum value of the equivalent resistance value of the RC snubber circuit by connecting a different resistor to the NTC thermistor, automatically reducing heat generation due to resistance according to the ambient temperature and reducing EMI It is characterized by reducing.

Meanwhile, FIG. 4 shows a power spectrum according to frequency when the RC circuit is not applied to the snubber circuit according to the present invention. On the other hand, Figure 5 shows the power spectrum according to the frequency when the RC circuit is applied to the snubber circuit according to the present invention.

4 and 5, QUASIPEAK measures the amount of change in time at a frequency, and numerically expresses various characteristics of dynamic time. That is, the peak power value at one frequency is averaged over a period of time. In this regard, it is because from the EMI point of view, it has a continuous cycle rather than a single PEAK value from the product, and frequent electromagnetic waves affect the product more. Therefore, measuring the QUASIPEAK value rather than the PEAK value is more advantageous from the EMI measurement point of view.

On the other hand, CISPR AVERAGE corresponds to the average of the standard (CISPR) values defined by IEC (INTERNATIONAL ELECTROTECHNICAL COMMISSION).

In relation to these QUASIPEAK and CISPR AVERAGE, the value according to the frequency must be below the corresponding straight line to satisfy the regulation. Referring to FIG. 4, it can be seen that if the RC circuit is not applied to the snubber circuit, the corresponding regulation is not satisfied in the low frequency band. Accordingly, when a snubber circuit (300 Hz) without an RC circuit is applied, it is impossible to effectively reduce EMI noise mainly generated in a low frequency band.

On the other hand, referring to FIG. 5, when applying the snubber circuit 300 to which the RC circuit is added, it has an advantage of effectively reducing EMI noise mainly generated in a low frequency band. On the other hand, referring to Figure 4 (b) and 5 (b), the peak-to-peak level according to the switching in the switching power supply signal is reduced by the snubber circuit 300 to which the RC circuit is added Can be seen. In this regard, the peak-to-peak level in FIG. 4B is high because the EMI noise increased with a fast rise time tr. On the other hand, the peak-to-peak level in FIG. 5(b) is low and the pulse shape is gentle because EMI noise is reduced according to the gentle rise time tr. Regarding the level of EMI noise reduction, compared to the snubber circuit 300 가 without the RC circuit, the snubber circuit 300 with the RC circuit added has an effect of improving about 13 dB at a specific frequency, for example, 33 MHz.

On the other hand, Figure 6 shows the representation in the time and frequency domain of the power signal of the switching form according to the present invention. 6(a) shows a time domain representation of a switching type power signal. In this regard, the switching cycle T may correspond to the reciprocal of the carrier frequency fc. In addition, the rise time tr may correspond to the rate of change dV/dt over time of the voltage. As described above, when the rise time is increased, attenuation according to the frequency of the voltage spectrum increases, and EMI noise can be reduced.

On the other hand, Fig. 6 (b) and (c) shows the frequency domain representation of the switching power supply signal. For example, if the rise time tr is 50 ns, the corresponding frequency f2 is determined. Accordingly, as the rise time tr increases, that is, as the switching signal becomes gentle, the corresponding frequency f2 decreases in the switch voltage spectrum. Therefore, as the corresponding frequency f2 decreases, the bandwidth (BANDWIDTH) of the switch voltage spectrum is reduced to -40 dB/dec above the f2 frequency, thereby reducing EMI noise.

On the other hand, Figure 7 shows the form and switching loss of the voltage and current signal for the power supply signal of the switching form according to the present invention. Referring to FIG. 7, it can be seen that switching loss occurs according to ON/OFF of the switching power signal. In this regard, increasing the rise time tr means that switching occurs slowly, and accordingly, Switching On Loss and Switching Off Loss increase.

On the other hand, Figure 8 is a conceptual diagram showing the time domain representation of the switching type power signal according to the present invention and loss due to switching. Referring to FIG. 8, it is possible to infer the loss through the calculation of Vds*Id*time (t) of the voltage Vds and the current Id in the oscilloscope. For example, Switching On Loss according to switch-on may be 13.3uJ, which is the product of Vds*Id=131.7W and 101ns. Therefore, if EMI noise is not a significant problem, reducing switching time can reduce switching on loss.

On the other hand, Switching Off Loss due to switch-off may be 5.6uJ, which is the product of Vds*Id=30W and 188ns. In addition, the loss in the conduction state in the switched-on state can be inferred through the calculation of the resistance Rds and the current Id Rds*Id ² *time (t). Here, the resistance Rds may be mainly an equivalent resistance of an internal resistance and a resistance connected in parallel with the NTC thermistor. For example, Rds*Id ² *time(t) = 5.8*(288mA) ² *920ns = 0.4uJ. Therefore, it can be seen that the loss of conduction state is very small compared to Switching On Loss and Switching Off Loss. Therefore, it can be seen that it is important to reduce the switching loss in the switching power supply circuit (SMPS) that supplies the switching power supply signal according to the present invention. In addition, it is very important to reduce EMI noise while reducing switching loss, and it is very important that such switching loss reduction and EMI noise reduction are automatically performed. In addition, the present invention has an advantage in that switching loss reduction and EMI noise reduction are automatically performed through an ambient temperature-based operation mode, but can be reduced regardless of the mode when the EMI noise level is high.

In the above, the power supply device according to the present invention and the air conditioner having the same have been described. On the other hand, the technical effects of the power supply device according to the present invention and the air conditioner having the same are as follows.

According to at least one embodiment of the present invention, when the EMI noise is severe, the rise time of the switching signal is slowed to reduce the EMI noise, and when the EMI noise is weak, the rise time of the switching signal is increased to reduce the heat loss. There are advantages.

In addition, according to at least one embodiment of the present invention, since an NTC whose resistance value is changed according to the surrounding environment is used, the RC snubber circuit has an optimal circuit constant (time constant) for each situation to optimize power signal characteristics. It has the advantage of being able to.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit and essential features of the present invention. Accordingly, the above detailed description should not be construed as limiting in all respects, but should be considered illustrative. The scope of the invention should be determined by rational interpretation of the appended claims, and all changes within the equivalent scope of the invention are included in the scope of the invention.

Claims (10)

In the power supply,
A switching power supply circuit (SMPS) for supplying power in the form of a switching signal to a load; And
And a snubber circuit configured to reduce a noise level caused by the switching signal from the SMPS,
The resistance value connected between both terminals of the snubber circuit is configured to vary according to a heating mode or a cooling mode of an air conditioner supplied with power by the power supply device,
When the resistance value increases, electromagnetic interference (EMI) decreases, and when the resistance value decreases, heat generation decreases in the load of the air conditioner,
Further comprising a control unit for controlling the driving state of the air conditioner,
The control unit is characterized in that to reduce the EMI by increasing the rise time (rise time) t _r of the switching signal, if the EMI is above a certain level through the EMI detection filter provided in the air conditioner, power supply. delete According to claim 1,
When the air conditioner is operated in the heating mode, the snubber circuit is configured to reduce the EMI by increasing the resistance value,
When the air conditioner operates in the cooling mode, the snubber circuit is configured to reduce heat generation by reducing the resistance value. According to claim 1,
The snubber circuit,
A capacitor connected to either terminal of both terminals of the internal transistor;
A first resistor connected in series with the capacitor, connected to the other terminal of both terminals of the capacitor and the internal transistor, and having a first resistance value; And
And a second resistor connected in series with the capacitor, connected to the first resistor in parallel to the other terminal of both terminals of the internal transistor, and having a second resistance value. According to claim 4,
The first resistor is an NTC (Negative temperature coefficient) thermistor (thermistor), wherein the first resistance value decreases as the ambient temperature increases. The method of claim 5,
When the air conditioner supplied by the power supply device operates in a heating mode, the first resistance value of the NTC thermistor increases, and as the equivalent resistance value of the NTC thermistor and the second resistance increases, EMI Is decreasing,
When the air conditioner operates in a cooling mode, the time constant decreases and the switching speed increases as the second resistance value of the NTC thermistor decreases and the equivalent resistance value of the NTC thermistor and the second resistance decreases. Characterized in that, the power supply. delete The method of claim 5,
Even when the air conditioner operates in the cooling mode and the first resistance value of the NTC thermistor decreases, the control unit increases the rise time t _r of the switching signal to reduce EMI if the EMI is above a certain level. Characterized in that, the power supply. The method of claim 5,
The air conditioner continues to operate in the heating mode, and as the ambient temperature rises, even when the first resistance value of the NTC thermistor decreases, the rise time t _r of the switching signal is increased to reduce EMI. The power supply. delete

Images