KR100359179B1 - Air conditioner - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to an air conditioner that corrects the operation capability of a compressor so as not to exceed a preset maximum current value.

2. The technical problem that the invention is trying to solve

An object of the present invention is to provide an air conditioner for saving power consumption.

3. Summary of Solution to Invention

A control unit that automatically adjusts the operating capacity of the compressor 26 so that the room temperature reaches the set temperature based on the freezing cycle configured by the compressor 26, the condenser, the pressure reducing device, the evaporator, and the room temperature and the set temperature of the operation chamber. In the air conditioner having the control unit, the control unit includes a first correction mechanism for correcting the operation capability of the compressor 26 to the side so that the current flowing through the compressor 26 or the air conditioner does not exceed a predetermined maximum current value. And a second correction mechanism for correcting the maximum current value to the negative side in response to a control signal at the same time and for correcting the set temperature to the side at which the operating capacity of the compressor 26 decreases. to be.

4. Important use of the invention

The present invention relates to an air conditioner for correcting the operation capability of a compressor.

Description

Air conditioner

The present invention relates to an air conditioner, and more particularly, to an air conditioner having a refrigeration cycle for circulating a refrigerant and correcting the operation capability of the compressor so as not to exceed a preset maximum current value.

BACKGROUND ART Conventionally, an air conditioner has a refrigerant cycle including an indoor side heat exchanger through which refrigerant flows, an outdoor side heat exchanger, a compressor for compressing the refrigerant, and a four-way valve for switching the flow direction of the refrigerant.

The air conditioner detects the room temperature and calculates the difference between the detected room temperature and the preset set temperature, and calculates the amount of change per unit time of the difference obtained at the same time, according to the difference and the amount of change per unit time of the difference. The frequency increase / decrease amount is obtained by the fuzzy inference method, and an inverter is controlled according to the frequency increase / decrease amount to control the frequency of the compressor.

As a result, the amount of refrigerant flowing to the indoor heat exchanger is controlled, and the air is blown into the room via the indoor side heat exchanger so that the indoor temperature becomes the set temperature.

In addition, the maximum current value of the current supplied to the inverter that controls the energization of the compressor is set in advance, and the air conditioner controls the operation capability of the compressor so as not to exceed the set maximum current value even when overloaded.

However, for example, when the air conditioner is heating the room temperature to the set temperature, for example, when using another heater such as a hot carpet, the indoor head is cold and the feet are hot. If you think about it, setting the room temperature to a temperature lower than the set temperature does not impair comfort.

However, even if other equipment is used, the air conditioner consumes electric power unnecessarily because it continues heating operation which makes room temperature become set temperature.

In order not to consume such power unnecessarily, the set temperature must be set to a new set temperature lower than the set temperature.

Such an operation may be complicated and the new set temperature may be set higher than a temperature which does not impair comfort, and even in this case, power is unnecessarily consumed as described above.

In the case of using both the above-described air conditioner and other equipment, when the set temperature is changed and a new set temperature lower than the set temperature is set, the frequency increase or decrease of the compressor is calculated accordingly, and the inverter according to the frequency increase or decrease is obtained. To control the frequency of the compressor.

In this case, since the indoor temperature is set to the temperature before or near the newly set temperature, it is not necessary to operate the compressor at full capacity.

The present invention has been made in view of the above-described fact, and an object thereof is to provide an air conditioner which aims to save power consumption.

In order to achieve the above object, the invention described in claim 1 relates to a refrigeration cycle constructed using a compressor, a condenser, a decompression device, an evaporator, and the like so that the room temperature reaches the set temperature based on the room temperature and the set temperature of the operation chamber. In the air conditioner having a control unit for automatically adjusting the driving capability, the control unit includes a first correction for correcting the driving capability of the compressor to the negative side so that the current flowing through the compressor or the air conditioning unit does not exceed a predetermined maximum current value. A second correction mechanism is provided for correcting the maximum current value on the negative side in response to the control signal and at the same time on the side where the operating capacity of the compressor decreases in response to the control signal.

In the invention according to claim 2, in the invention according to claim 1, the second correction mechanism described above corrects the maximum current value to the negative side, and then corrects the set temperature to the side at which the operation capability of the compressor decreases.

In the invention according to claim 1, the air conditioner includes a refrigeration cycle configured by using a compressor, a condenser, a pressure reducing device, an evaporator, and the like.

The control unit automatically adjusts the operating capacity of the compressor so that the room temperature reaches the set temperature based on the room temperature and the set temperature of the operation chamber.

Here, the first correction mechanism of the control unit corrects the operation capability of the compressor to the side so that the current flowing through the compressor or the air conditioner does not exceed a predetermined maximum current value.

The second correction mechanism corrects the maximum current value to the negative side in response to the control signal, and corrects the set temperature to the side at which the operation capability of the compressor decreases.

In addition, in the invention described in claim 2, the second correction mechanism corrects the maximum current value on the negative side, and then corrects the set temperature to the side on which the operation capability of the compressor decreases.

In this case, in response to a control signal, for example, when used in combination with another heating device such as a hot car fit, it receives a predetermined signal from a remote control device (e.g., a remote controller) and receives the predetermined signal. And a response to a control signal output to the controller by simply receiving a predetermined signal from the remote control device and receiving the predetermined signal.

In addition, there is a case in which the above-mentioned other heating device is detected whether or not it is used and responds to a control signal that is a detection signal that another heating device is used.

As a method of correcting the set temperature of the second correction mechanism to the side where the operation capacity of the compressor decreases, for example, in the case of heating operation, the set temperature is lowered every predetermined time until a predetermined time elapses and the cooling operation is performed. If so, increase the set temperature by a predetermined temperature.

In this case, when the heating operation is performed, the predetermined temperature is lowered every predetermined time until the predetermined time elapses. When the heating operation is performed, the set temperature is lowered so that even if the indoor temperature decreases, it is difficult for a human to feel this. It is to save power consumption without damaging the comfort by lowering the temperature of the room within the difficult range.

In the case of the cooling operation, the set temperature is increased to a predetermined temperature only. In the case of the cooling operation, if the setting temperature is increased and the indoor temperature rises, it is easy for humans to feel the temperature. In this case, it is easy to impair comfort, and therefore, to increase the set temperature to a predetermined temperature, thereby saving power consumption without compromising comfort.

In the case of heating operation, if the set temperature is lowered every predetermined time until a predetermined time elapses, and if the set temperature is raised to a predetermined temperature in the case of refrigeration operation, unnecessary power is required depending on the operation mode of the air conditioner. Consumption can be eliminated, thereby saving power consumption without compromising comfort in the operation mode.

As described above, the present invention corrects the maximum current value to the negative side by correcting the maximum current value of the current flowing to a predetermined compressor or air conditioner on the negative side in response to a control signal, and correcting the set temperature to the side where the compressor operating capacity decreases. As a result of correcting the set temperature and the set temperature to the side where the operation capacity of the compressor decreases, unnecessary power consumption can be excluded and power consumption can be saved.

EXAMPLE

Next, embodiments of the present invention will be described in detail with reference to the drawings.

In addition, the numerical value used in a present Example is an example and does not limit the present invention at all.

As shown in FIG. 1, the air conditioner of the present embodiment includes an indoor device 10 and an outdoor device 12, and at the same time, a remote control device 14 that transmits various operation signals to remotely operate the air conditioner. Equipped.

As shown in FIG. 2, the air conditioner of the present embodiment is provided with a refrigerant circulation path for circulating refrigerant in the indoor device 10 and the outdoor device 12. As shown in FIG.

The indoor device 10 is provided with an indoor heat exchanger (16).

In the vicinity of the indoor heat exchanger 16, a fan 70f driven by a fan motor 70E to be described later for passing the indoor heat exchanger 16 to blow air is provided.

The indoor heat exchanger (16) is connected to the valve (20) of the outdoor device (12) via a refrigerant pipe (18) consisting of a thick tube.

The valve 20 is connected to the four-way valve 36 via the muffler 22.

The four-way valve 36 is connected to the outdoor heat exchanger 28 via a pressure regulator 24, a compressor 26, a muffler 38, and a four-way valve 36.

The outdoor heat exchanger 28 is connected to the valve 32 via the capillary tube 30 and the strainer 42 and is connected between the muffler 38 and the four-way valve 36 via the solenoid valve 40. have.

In addition, the valve 32 is connected to the indoor heat exchanger 16 via the refrigerant pipe 34 composed of the tubular pipe, thereby forming a sealed refrigerant circulation path, that is, a refrigeration cycle.

In the vicinity of the outdoor heat exchanger 28, a fan 112f driven by a fan motor 112A which will be described later for passing the outdoor heat exchanger 28 and blowing air is provided.

3 shows an electric circuit of the indoor device 10, which has a power supply board 70 and a control board 72. As shown in FIG.

The power supply board 70 has a drive circuit 70A connected to a fan motor 70E (DC brushless motor) for adjusting the air blowing amount into the room, an electric motor power supply circuit 70B for generating electric power for driving the motor, and control. The control circuit power supply circuit 70C for generating electric power for the circuit and the series circuit power supply circuit 70D for generating electric power for the series circuit are provided.

Therefore, by changing the voltage of the direct current power supplied from the motor power supply circuit 70B to the drive circuit 70A, the rotation speed of the fan motor 70E, that is, the blowing amount of the blower device, can be arbitrarily adjusted by the microcomputer.

In this embodiment, for example, the voltage is controlled in 256 steps in the range of 12V to 36V.

The controller board 72 is provided with a series circuit 72A connected to a series circuit power supply circuit 70D, a drive circuit 72B for driving an electric motor, and a microcomputer 72C as a control circuit.

In the driving circuit 72B, the direction of the step motor 74A for the up and down flaps, the step motors 74B and 74C for the left and right flaps for moving the flap up and down, and the direction of the floor sensor for detecting the temperature of the upper surface are changed. Step motor 74D for the floor sensor is connected.

These step motors are controlled by the rotation angle by a signal from the microcomputer 72C.

In addition, the microcomputer 72C is connected with a display LED for displaying an operation mode and the like installed on the display substrate 76 and a receiving circuit for receiving an operation signal from a remote control device. A floor sensor and an optical sensor for detecting temperature are connected.

Again, the microcomputer 72C is connected with a room temperature sensor 80A for detecting room temperature and a temperature sensor 80B for heat exchanger for detecting the temperature of the indoor heat exchanger 16, and at the same time, a self-diagnostic LED provided on the switch substrate 82. The operation changeover switch and the self-diagnosis switch for switching between normal operation and trial operation are connected.

4 shows an electric circuit of the outdoor device 12, which includes a rectifier circuit 100 and a control board 102. As shown in FIG.

In addition, the electric circuit of the outdoor device 12 is connected to the electric circuit of the indoor device 10 of FIG. 2 via a plurality of terminals indicated by 1 to 3.

The control board 102 includes a series circuit 102A connected to the series circuit power supply circuit 70D of the indoor device 10, a noise filter 102B for removing noise, 102C, and a 102D inverter 104. Is provided with a switching power supply circuit 102E and a microcomputer 102F as a control circuit.

The microcomputer 102F supplies alternating current to the compressor based on a control signal transmitted from the serial circuit 72A of the indoor apparatus 10 and the microcomputer 72C of the indoor apparatus 10 via the serial circuit 102A. The frequency of the current (18 Hz to 150 Hz) and the operation of each device are controlled.

The noise filter 102B is provided with a current detector C.T for detecting a current flowing through the compressor 106.

An inverter 104 is connected to the switching power supply circuit 102E, and a compressor 106 for compressing a refrigerant is connected to the inverter 104.

The maximum current consumed by the compressor 106 is set to 15 [A] (I00).

The microcomputer 102F further includes an external air temperature thermometer 110A as an external air temperature sensor for detecting the outdoor air temperature, a coil temperature earth heater 110B as a coil temperature sensor for detecting the temperature of the outdoor heat exchanger 28, A compressor temperature demister 110C as a temperature sensor for detecting the temperature of the compressor is connected.

In addition, a four-way valve 36 and a solenoid valve 40 are connected to the outdoor device 100.

Reference numeral 112A denotes a fan motor, and 112B denotes a driving capacitor for the fan motor.

According to the air conditioner, the four-way valve 36 is switched while the solenoid valve 40 is turned off, so that the refrigerant flows into the indoor heat exchanger 16, the refrigerant pipe 18, the valve 20, the muffler 22, and the four directions. Valve 36, accumulator 24, compressor 26, muffler 38, four-way valve 36, outdoor heat exchanger 28, capillary tube 30, strainer 42, valve 32, When the refrigerant is circulated in the order of the refrigerant pipe 34 and the indoor heat exchanger 16, the refrigerant is vaporized in the indoor heat exchanger 16 and the refrigerant is condensed in the outdoor heat exchanger 28.

When the four-way valve 36 is switched and the refrigerant is circulated in reverse with the above, the refrigerant condenses in the indoor heat exchanger 16 and the refrigerant evaporates in the outdoor heat exchanger 28, thereby enabling heating of the room.

In addition, the solenoid valve 40 is turned on during the heating operation so that a part of the high temperature refrigerant discharged from the compressor 26 is introduced into the outdoor heat exchanger 28, thereby raising the temperature of the outdoor side heat exchanger 28. This can make it difficult to attach to the castle.

5 shows a schematic external view of the remote control device 14.

The remote control device 14 shown in FIG. 5 has a display unit 142 in which the set temperature is indicated by the number and various buttons 144 to 154 for transmitting various operation signals for operating the air conditioner. Equipped with.

The operation switching button 144 among the buttons 144 to 154 is for selecting the operation mode of the air conditioner in the order of heating mode, drying mode, cooling mode, each time it is pressed.

The energy saving mode selection button 146 is for setting the operation mode of the air conditioner to the energy saving mode for saving power consumption.

The energy saving mode exit button 148 is for terminating the energy saving mode in which the air conditioner is operating.

The temperature increase button 150 is for raising the set temperature by 1 ° C each time it is pressed.

The temperature drop button 152 is for lowering the set temperature by 1 ° C each time it is pressed.

The operation stop button 154 stops when the air conditioner is in operation and starts operation when the air conditioner is in operation.

When the above buttons 144 to 154 are pressed, an operation signal corresponding to the pressed button is transmitted to a receiving circuit provided on the display substrate 76 of the indoor apparatus.

Next, the control routine of the energy saving mode of this embodiment will be described with reference to FIG.

The air conditioner is operated in the heating mode so that the room temperature is set to a set temperature of T0 [eg 30 ° C (T00)], and another device such as a hot car fit is used to operate the remote control device (14 When the energy saving mode selection button 146 of the control panel is pressed and the reception circuit receives an operation signal of a command to start the energy saving mode, the indoor device 10 outputs the received operation signal to the outdoor device 12. .

When the outdoor device 12 inputs an operation signal from the indoor device 10 (step 202), the current value I0-i minus the predetermined current value i from the maximum current value I0 of the inverter 104 set in step 204. Is set as the maximum current value I0 of the inverter 104.

In this embodiment, the predetermined current value i is 5 [A].

For this reason, as described above, since the maximum current value I0 is set to 15 [A], the maximum current value I0 of the inverter 104 is set to 10 [A] by the processing in step 204.

In step 206, it is determined whether S00 hours have elapsed, and when S00 hours has elapsed (or when S00 hours has elapsed since the room temperature has reached approximately the set temperature T0), the air conditioning is detected by detecting the switching state of the four-way valve 36 in step 208. Determine the operation mode of the machine.

As described above, since it is currently operating in the heating mode, it is determined as the heating mode in the processing of step 208. In this case, the temperature (T0-t) obtained by subtracting the predetermined temperature t from the set temperature T0 set in step 210 is set as the set temperature T0. do.

In the present embodiment, the predetermined temperature t is set at 1 ° C.

In this way, the maximum current value I0 of the inverter 104 is set to 10 [A], and the current value detected by the current detector CT does not exceed the maximum current value of the alternating current supplied from the inverter 104 to the compressor 106. Control the frequency.

The indoor device 10 inputs the room temperature detected by the room temperature sensor 80A, calculates the difference between the input room temperature and the preset set temperature, and calculates the amount of change per unit time of the difference obtained at the same time. According to the difference and the amount of change per unit time of the difference, the frequency increase / decrease amount of the compressor 106 is obtained by the fuzzy inference method, and the increase / decrease amount is output to the outdoor device 12.

The outdoor device 12 controls the inverter 104 in accordance with the frequency increase / decrease amount to perform frequency control of the compressor 106.

By this, the amount of refrigerant circulating in the indoor heat exchanger 16 is controlled to the optimum ability to meet the load.

At this time, when the current detected by the current detector (C.T.) exceeds 10 [A], the frequency is corrected to the negative side.

That is, correct in the direction of decreasing current.

In this way, when the operation is started in the energy saving mode and it is determined whether 5 [min] has elapsed from the time when the new set temperature T0 is set in step 212 and step 210 at the predetermined time SO, in this embodiment 5 [min], the step is performed. In step 214 and step 202, it is determined whether or not the predetermined time S1, 16 [min] has elapsed from the time when the operation signal was input.

If 16 [min] has not elapsed, the process returns to step 210 and the above processes (steps 210 to 214) are repeated.

Thus, the compressor 104 is controlled by controlling the inverter 104 according to the frequency change amount of the compressor 106, which is set at 1 DEG C every 5 [min] until the operation signal is inputted 16 [min]. Frequency control of 106 is performed.

When 16 [min] has elapsed from the time when the operation signal was input in step 202, this processing ends.

In this case, the inverter 104 is controlled so that the set temperature is set to 27 ° C. at 3 ° C. and lowered to 27 ° C., thereby controlling the frequency of the compressor 106.

When the air conditioner is set to the set temperature of T0 [for example, 26 ° C. (T00)] and is operated in the cooling mode such that the set temperature is the set temperature, the energy of the remote control device 14 as described above. If the receiving circuit receives the operation signal of the command to start the energy saving mode and the energy saving mode selection button 146 is pressed, it is determined as the cooling mode in the processing of step 206 for determining the operation mode of the air conditioner. The temperature (T0 + t) obtained by adding the predetermined temperature t to the set temperature T0 set in step 214 is set as the set temperature T0, and the present process ends.

In the present embodiment, the predetermined temperature t is set at 1 ° C.

Therefore, the set temperature is newly set to 27 ° C.

Then, the inverter 104 is controlled in accordance with the frequency change amount of the compressor 106 thus obtained to perform frequency control of the compressor 106.

Next, an interrupt control routine for interrupting the energy saving mode by interrupting when the above-described control routine of the energy saving mode is executed will be described with reference to FIG.

When the control routine (Fig. 6) of the energy saving mode described above is executed, the energy saving mode end button 148 of the remote control device 14 is pressed to receive an operation signal of a command to end the energy saving mode. When the circuit receives the indoor device 10 outputs the received operation signal to the outdoor device (12).

When the outdoor device 12 receives the operation signal from the indoor device 10 (step 302), a process for interrupting the control routine in the energy saving mode and ending the energy saving mode is started.

Here, the current value I0-i obtained by subtracting the correction current value i by the maximum current value I0 of the inverter 104 set in step 204 in the control routine of the energy saving mode is the maximum current value I0 of the inverter 104. Since the new maximum current value I0 is set to the original maximum current value I00 (15 [A] as described above in the present embodiment), the maximum current value I0 is set.

In addition, as described above, since the heating mode is set to a temperature lowered by 3 ° C from the initially set temperature T00, and the cooling mode is set to a temperature rising by 1 ° C from the first set temperature T00, the set temperature T0 is initially set in step 306. Change the setting to and end this process.

As described above, according to this embodiment, when operating in the energy saving mode, the maximum current value set in the inverter is lowered by a predetermined current value, and when operating in the heating mode, the set temperature is set every predetermined time until a predetermined time elapses. When the temperature is lowered by the predetermined temperature and operated in the cooling mode, since the set temperature is lowered by the predetermined temperature, unnecessary power is not consumed and comfort is not impaired.

For this reason, this air conditioner can save power consumption.

In addition, in the above embodiment, since the energy saving mode can be started by pressing the energy saving mode selection button of the remote control device once, it is possible to eliminate the troublesomeness of setting the set temperature to a new set temperature lower than the set temperature. There is.

In the embodiment described above, when operating in the heating mode, the set temperature is lowered by 1 ° C every 5 [min], but is not limited thereto. For example, it is set every 4 [min] or 6 [min]. The change amount for lowering the set temperature every predetermined time may be 2 ° C or the like.

In the above embodiment, the set temperature is increased by 1 ° C when operating in the cooling mode, but the present invention is not limited thereto, and may be, for example, increased by 2 ° C.

In the above embodiment, the maximum current value of the inverter is set to 15 [A], and in the case of the operation of the energy saving mode, the example of resetting the maximum current value to 5 [A] or 10 [A] has been described. It may be applied to the maximum current value set to another value, for example, 20 [A], and in this case, for energy saving mode operation, for example, 6 [A] to 14 [A]. .

In the above embodiment, an interrupt control routine for interrupting the energy saving mode when the control routine in the energy saving mode is executed by pressing the energy saving mode exit button of the remote control device is pressed. Although the present invention is not limited thereto, for example, the operation stop button of the remote control device may be pressed, so that the execution can be performed.

In this case, the operation of the air conditioner is stopped after executing the interrupt control routine.

In addition, the above-described embodiment has described an example in which the operation signal is transmitted to the indoor device by the remote control device. However, the present invention is not limited thereto, and the air conditioner includes a device connected to the indoor device that outputs the operation signal to the indoor device. The energy saving mode described above may be executed when another device is used by judging whether another device is being used or connected to another device.

In the above-described embodiment, the present invention is limited to the case where the battery is used in combination with other equipment. However, the present invention is not limited thereto, and the energy saving mode may be executed even when the apparatus is not used in combination with other equipment.

In other words, when the operation signal of the command to operate in the energy saving mode from the remote control device is transmitted to the indoor device or when the operation signal is input from the device connected to the indoor device when it is not used together with other equipment. It is also possible to run the saving mode.

In the above embodiment, the energy saving mode of the air conditioner that can be operated in the heating mode and the cooling mode has been described, but the present invention is not limited thereto. In the air conditioner which can be operated in the mode of operating in the heating mode when the temperature is lower than the set temperature after the operation, the energy saving mode may be executed.

That is, for example, when the room temperature is lower than the set temperature and operated in the heating mode, when the room temperature is close to the set temperature (eg, -2 ° C), or when the room temperature is higher than the set temperature and the cooling mode, and the room temperature is set to the set temperature ( + 1 ° C) may be configured to output a control signal that automatically reaches the energy saving mode when in close proximity.

In addition, the energy saving mode may be executed in the air conditioner which can be operated in only one of the heating mode and the cooling mode.

As described above, the present invention corrects the maximum current value to the negative side by correcting the maximum current value of the current flowing through a predetermined compressor or air conditioner on the negative side in response to a control signal, and correcting the set temperature to the side where the compressor operating capacity decreases. By one minute and by adjusting the set temperature to the side where the compressor's operating capacity decreases, unnecessary power consumption can be excluded and power consumption can be reduced.

1 is a block diagram of this embodiment

2 is a view showing a refrigerant circulation path for circulating a refrigerant in indoor and outdoor devices of the air conditioner of the present embodiment.

3 is an electric circuit diagram of the indoor device of the air conditioner of the present embodiment.

4 is an electric circuit diagram of an outdoor device of the air conditioner of the present embodiment.

5 is a schematic external view of a remote control device of this embodiment

6 is a flowchart showing the energy saving mode control routine of this embodiment.

7 is a flowchart showing an interrupt control routine for terminating an interrupt routine in the energy saving mode control routine of this embodiment.

* Explanation of symbols for main parts of the drawings

10. Indoor device

12. Outdoor device

14. Remote control unit

26. Compressor

144. Driving switch

146. Energy saving mode selection button

148. Energy saving mode exit button

150. Temperature Up Button

152. Temperature down button

154. Stop Button

Claims (2)

A control unit that automatically adjusts the operating capacity of the compressor 26 so that the room temperature reaches the set temperature based on the freezing cycle configured by the compressor 26, the condenser, the pressure reducing device, the evaporator, and the room temperature and the set temperature of the operation chamber. In the air conditioner having the control unit, the control unit includes a first correction mechanism for correcting the operation capability of the compressor 26 to the side so that the current flowing through the compressor 26 or the air conditioner does not exceed a predetermined maximum current value. And a second correction mechanism for correcting the maximum current value to the negative side in response to a control signal at the same time and for correcting the set temperature to the side at which the operating capacity of the compressor 26 decreases. . The method of claim 1, And the second correcting mechanism corrects the maximum current value on the negative side, and then corrects the set temperature to the side on which the operating capacity of the compressor (26) decreases.