KR100555801B1 - Control method of airconditioner - Google Patents

Abstract

The present invention relates to an operation control method of an air conditioner in which an air conditioner having two compressors can variably control the operation conditions of the compressor according to the current load state to reduce power consumption of the product. The present invention performs a more efficient and energy-saving control by controlling the operating conditions of the compressor in accordance with the current load state of the product at room temperature control. To this end, the present invention includes two compressors, and performs control of driving both compressors or driving only one compressor. Therefore, the present invention can be controlled to drive two or one compressor in accordance with the load state of the product, it is possible to obtain an effect that can significantly reduce the power consumption of the product.

Air conditioner, compressor, room temperature control, heating operation, power saving

Description

Control method of air conditioner {Control method of airconditioner}             

1 is a control block diagram of a conventional air conditioner having one compressor;

2 is an operation state of the compressor and the fan when controlling the heating operation in the conventional air conditioner,

3 is a control block diagram of an air conditioner having two compressors according to the present invention;

4 is an operation flowchart according to a heating operation control process in the air conditioner of the present invention.

Explanation of symbols on the main parts of the drawings

1,57: Indoor suction temperature sensor 3,71: Signal input unit

5,55 control unit 7,67 electromagnetic expansion valve drive unit

9,51,53: Compressor drive part 11,69: Fan drive part

59: indoor piping temperature sensor 61: outdoor suction temperature sensor

63: outdoor compressor suction temperature sensor 65: outdoor piping temperature sensor

The present invention relates to an operation control method of an air conditioner, and more particularly, in an air conditioner having two compressors, an operation control of an air conditioner which variably controls the operating conditions of the compressor according to the current load state to reduce power consumption of the product. It is about a method.

In air-conditioning and heating-related products such as air conditioners, the heat exchange operation generates the required cold or warmth in the product. An operation of compressing a refrigerant at high temperature and high pressure is necessary for the heat exchange operation, and the operation is performed in a compressor.

The compressor is configured in various ways according to the kind, characteristic, capacity, etc. of the product to be used, but the characteristics, capacity, and the like are generally determined according to the kind of the product to be used. In addition, the compressor is one of the most important components in the air conditioner to determine the performance of the air conditioner. Thus, smoothing the operating state of the compressor and extending its life is directly related to the extended life and operating state of the product.

The general air conditioners used so far are configured to perform the cooling and heating operation required inside the product by using one compressor suitable for the capacity of the product. Therefore, when the capacity of the product is large, a compressor having a capacity proportional thereto is provided, and when the product is small, the capacity of the compressor is similarly configured.

1 shows a control configuration of an air conditioner having one compressor in the related art.

As shown in the drawing, conventional air conditioners include an indoor suction temperature sensor 1 for detecting an indoor temperature of an air conditioning space in which an air conditioning environment is created by an air conditioner, various control signals for operating the air conditioner by user selection, and an air conditioner. And a signal input unit 3 for inputting a control signal such as an operation signal, a set temperature, a wind volume, and a wind speed.

The conventional air conditioner is provided with a control unit 5 which recognizes the signal input from the signal input unit 3 and controls the operation of the necessary air conditioner. The indoor temperature detected by the indoor suction temperature sensor 1 is also input to the controller 5, and the controller 5 recognizes the indoor temperature based on the value detected by the indoor suction temperature sensor 1.

The electronic expansion valve driving unit 7 for controlling the amount of refrigerant supplied to the heat exchanger (not shown) is driven by the control of the control unit 5 according to the difference between the current room temperature and the set temperature. In addition, a compressor driver 9 driven under the control of the controller 5, and a fan driver 11 for driving the indoor fan and the outdoor fan are included.

The conventional air conditioner configured as described above is configured such that one compressor is operated by the compressor driving unit 9. The compressor is configured to control the operation / stop (on / off) in conjunction with the operation operation of the air conditioner.

Next, the operation control process of the conventional air conditioner having the above configuration will be described. Hereinafter, the heating operation of the air conditioner will be described as an example.

When the user inputs the operation signal or the stop signal of the air conditioner through the signal input unit 3, the input signals are applied to the control unit 5. The control part 5 recognizes a user command signal by an input signal at this time. The controller 5 performs control in accordance with the user command signal.

When the user inputs the heating operation signal of the air conditioner, the controller 5 controls the refrigerant circulation cycle provided in the product to be formed in the heating cycle state. The operation is performed through a four-sided switching unit (not shown).

The control section 5 then operates the compressor and fan via the compressor drive 9 and fan drive 11. The compressor driver 9 operates the compressor by controlling one compressor installed in the product to the maximum capacity, and the fan driver 11 operates the outdoor fan and the indoor fan in an on state.

Before the operation is made, the controller 5 detects the indoor temperature through the indoor suction temperature sensor 1. If the detected room temperature is higher than the set temperature, it is not necessary to perform the heating operation. However, when the detected room temperature is lower than the set temperature, heating operation according to the compressor and the fan drive is performed.

When the compressor and the outdoor fan are operated in this way, the refrigerant compressed in the compressor is supplied to an indoor and outdoor heat exchanger (not shown). When the compressed refrigerant is supplied to the indoor / external heat exchanger, the heat exchange operation occurs in the indoor / external heat exchanger, the warm wind is discharged to the indoor side, and the cold wind is discharged to the outdoor side, thereby creating the necessary air conditioning environment inside the air conditioning space. It is done. At this time, the indoor fan and the outdoor fan, serves to facilitate the heat exchange operation generated in the indoor and outdoor heat exchanger more smoothly.

On the other hand, the conventional air conditioner controls the operation state of the compressor and the fan as shown in FIG. 2 in association with the operation operation state of the air conditioner.

That is, based on the desired temperature, which is the user or heating operation set temperature, when the indoor temperature is lower than the desired temperature (T1, T3, T5 in FIG. 2), the compressor and the outdoor fan are turned on to perform the heating operation. It was. However, when the indoor temperature is higher than the desired temperature (T2, T4, T6 section in Figure 2), the compressor and the outdoor fan are controlled to the off state.

Therefore, in the conventional air conditioner, when the indoor temperature is lower than the desired temperature, the compressor and the outdoor fan are operated. When the indoor temperature is higher than the desired temperature, the compressor and the outdoor fan are stopped. When the compressor and the outdoor fan operate in the operation process, the air conditioner is in an operating state, and when the compressor and the outdoor fan are in a stop state, the air conditioner is in a pause state. At this time, the compressor always generates 100% operating capacity in the operating state.

As described above, in the conventional air conditioner, the compressor is turned on during the operation of the air conditioner (in this case, the compressor is at 100% driving capability), and the control is performed to turn off the compressor when the air conditioner is stopped. Since one compressor is used in the conventional air conditioner, only the on / off operation control of the compressor can be performed by comparing the room temperature with the desired temperature during the heating operation.

Therefore, the conventional air conditioner has no choice but to keep the compressor in a 100% operating state when the air conditioner is operated. This control state, a problem that must be controlled in the same way even if it is not necessary to control the operating state of the compressor to 100% state in accordance with the current room temperature.

This problem, as a result, causes unnecessary driving of the compressor, and also causes problems such as an increase in power consumption due to excessive use of the compressor, shortening the service life of the compressor, and the like.

In addition, since many countries have recently emphasized the eco-friendly part of most electronic products, it is very important that the air conditioner is implemented to improve energy use efficiency and reduce energy consumption. However, the conventional air conditioner, there is no part that can complement the environmentally friendly part, and eventually caused a problem of lowering the satisfaction of the product and lowering the reliability of the product.

Accordingly, an object of the present invention is to provide an operation control method of an air conditioner in which an air conditioner using two compressors reduces power consumption by adjusting an operation state of a compressor according to a current load state.

Operation control method of the air conditioner according to the present invention for achieving the above object is, in the air conditioner having two or more compressors having different capacities, the first room temperature control step of performing the indoor temperature control by driving all the compressors and ; A load determination step of determining an indoor temperature load by comparing the operation time of the compressor with a predetermined predetermined time in the first indoor temperature control step; And a second indoor temperature control step of selectively controlling the compressors individually based on the indoor temperature and the desired temperature when the indoor temperature load is small in the load determination step. When the room temperature load is high, the control state of the first room temperature control step is maintained.

The first and second indoor temperature control steps are characterized in that the indoor temperature control process according to the heating operation.

When the indoor temperature control by the second indoor temperature control step is performed, it further comprises a determination step of determining whether the indoor temperature control is possible under the current compressor operating conditions, and if it is determined that the indoor temperature control is difficult, the first indoor temperature And returning to the control step.

The determining step is characterized in that it is determined whether the room temperature lasts for a predetermined time which is preset as a predetermined lower than the desired temperature.

The second indoor temperature control step may include: checking whether the indoor temperature is lower than a desired temperature by driving all the compressors; Limiting the driving compressor to a part when the room temperature is not below a predetermined temperature in the checking step; Performing control to maintain the current operating state, stop the operation of the compressor, or increase the operating conditions of the compressor based on the difference between the room temperature and the desired temperature while performing indoor temperature control with the limited compressor. do.

Hereinafter, an operation control method of an air conditioner according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a control block diagram of an air conditioner having two compressors according to the present invention.

The air conditioner of this invention is equipped with two compressors. The compressor is configured to be controlled by different driving units, and for this purpose, the compressor includes two compressor driving units. In the illustrated embodiment, the compressor driver includes a 60% compressor driver 51 and a 40% compressor driver 53. This indicates that the 60% compressor driver 51 controls a compressor capable of generating an output capacity of about 60%, based on the maximum output capacity (100%) of the product. In addition, the 40% compressor driver 53 controls the compressor to generate an output capacity of about 40% at the maximum output capacity (100%) of the product. However, the output capacity of the compressor driver does not need to be limited as described above. It is only necessary that the sum of the distributed output capacities equal the maximum output capacity of the product (100%). The compressor driving units are operated under the control of the controller 55 to be described later.

The air conditioner of the present invention includes an indoor suction temperature sensor 57 for detecting an indoor temperature of an air conditioning space in which an air conditioning environment is created by an air conditioner, various control signals for operating the air conditioner by user selection, an air conditioner operation signal, And a signal input unit 71 for inputting control signals such as set temperature, air volume, and wind speed.

The air conditioner of the present invention is provided with a control unit 55 for recognizing the signal input from the signal input unit 71 and controlling the operation of the necessary air conditioner. The indoor temperature detected by the indoor suction temperature sensor 57 is also input to the controller 55, and the controller 55 recognizes the indoor temperature based on the value detected by the indoor suction temperature sensor 57.

In addition, the electronic expansion valve driver 67 for controlling the amount of refrigerant supplied to the heat exchanger (not shown) according to the difference between the current room temperature and the set temperature is driven by the control of the controller 55. Further, under the control of the controller 55, a fan driver 69 for driving the indoor fan and the outdoor fan is included.

In addition to the above configuration, in the air conditioner of the present invention, an indoor piping temperature sensor 59 for detecting a temperature of a pipe passing through an indoor heat exchanger, an outdoor suction temperature sensor 61 for detecting a temperature of outdoor air, and an outdoor heat exchanger The outdoor piping temperature sensor 65 which detects the temperature of piping is provided. Reference numeral 63 denotes an outdoor compressor suction temperature sensor. The outdoor compressor suction temperature sensor 63 is a sensor for monitoring a compressor overload or the like.

In the air conditioner of the present invention configured as described above, two compressors are provided, and the two compressors are configured to be individually controlled by two compressor driving units 51 and 53. Therefore, the air conditioner of the present invention detects various temperatures required for the control of the air conditioner through a temperature sensor for sensing the temperature of the indoor and outdoor main parts, and determines the load state of the current product based on the detected temperature. Then, the driving conditions of the compressor are determined to control the two compressors to be selectively driven.

Next, the operation control process of the air conditioner according to the present invention having the above configuration will be described.

The air conditioner of the present invention is configured to generate a maximum output capacity (100%) by using two compressors. And the compressor drive part for driving the two compressors is comprised separately. Therefore, it is possible to adjust to 100% operation of the compressor, 60% operation of the compressor or 40% operation of the compressor, depending on the current load condition of the product. In the present invention, the operation condition of the compressor is controlled by driving both compressors (100% operation) or driving only one compressor (60% operation or 40% operation). Is done.

Hereinafter, the process of adjusting the operating conditions of the compressor according to the load state of the current product will be described in more detail. And in the embodiment of the present invention will be described with reference to Figure 4 showing an example of the control process of the heating operation of the air conditioner.

When the user selects a heating operation signal of the product, the heating operation signal is input to the control unit 55 through the signal input unit 71. The controller 55 recognizes that the input signal is a signal for requesting the heating operation, and then performs the heating operation control.

The controller 55 outputs an operation signal to the 60% compressor driver 51 and the 40% compressor driver 53. In addition, an operation signal is also output to the fan driver 69. At this time, the two compressor driving units 51 and 53 are driven by the operation signal, and the two compressors are operated. The heating operation of the air conditioner is started while the outdoor fan and the indoor fan are started by the operation of the fan driving unit 69. (100th step).

In the initial operation control process of the air conditioner according to step 100, both compressor driving units are in an operating state. That is, the air conditioner is driven at the maximum output capacity provided in the product.

When the two compressors and the outdoor fan are operated in this way, the refrigerant compressed in the compressor is supplied to an indoor and outdoor heat exchanger (not shown). When the compressed refrigerant is supplied to the indoor / external heat exchanger, the heat exchange operation occurs in the indoor / external heat exchanger, the warm wind is discharged to the indoor side, and the cold wind is discharged to the outdoor side, thereby creating the necessary air conditioning environment inside the air conditioning space. It is done. At this time, the indoor fan and the outdoor fan, serves to facilitate the heat exchange operation generated in the indoor and outdoor heat exchanger more smoothly.

When the heating operation is started by the above process, as shown in Figure 4, the control unit 55 performs a control to variably adjust the operating conditions of the compressor according to the current load state of the product.

In order to perform the above process, the controller 55 first determines a load state required for driving the current product. Step 103 is a judgment condition for performing the first control.

In step 103, after the heating operation is started, the two compressors are driven to control the product to 100% output capacity, and then the operating time of the compressor according to the indoor temperature control is determined. That is, when the heating operation is started, the controller 55 detects the indoor temperature through the indoor suction temperature sensor 57. The detected indoor temperature is compared with the desired temperature (the temperature set by the user or the temperature set during heating operation preset by the product itself). At this time, if the indoor temperature is higher than the desired temperature by about a predetermined temperature (about 0.5 degrees), the control is performed to stop the compressor, and when the indoor temperature is lower by the predetermined temperature (about 0.5 degrees), the control to operate the compressor. Perform When performing such control, the compressor (100%) is controlled on / off according to the difference between the room temperature and the desired temperature, and the compressor is operated when the on / off operation state of the compressor (100%) is twice. If the time (on time) is less than a certain time, it is determined that the room temperature load is small. The constant time, which is a reference value for determining the operation time of the compressor, is a predetermined value based on an experimental value.

Accordingly, in step 103, both the compressors are driven to perform indoor temperature control in a state in which the output capacity of the product is 100%. At this time, the operating temperature of the compressor is determined. I think it is small. However, if the operating time of the compressor is longer than a predetermined time, it is determined that the room temperature load is high, and maintains the current control state (100% output state) as it is (step 106).

If it is determined in step 103 that the indoor temperature load is low, a second control is performed.

In the second control, first, the compressor is controlled to a 100% operating state (step 109). In the step 109, the control unit 55 controls both the 60% compressor driving unit 51 and the 40% compressor driving unit 53 in the driving state, thereby controlling both compressors in the operating state. After performing step 109, a process of comparing the indoor temperature detected through the indoor suction temperature sensor 57 with a desired temperature is performed (step 112). That is, steps 109 and 112 represent a section for confirming the first control process.

If the room temperature is higher than the desired temperature in the checking process in the step 112, the control to adjust the operating conditions of the compressor is performed, otherwise it maintains the 100% driving state (the state of driving both compressors). In this case, the load state according to the indoor temperature control is determined using the preset time and control is performed according to the control operation (step 115). In step 115, while the duration for the operation of the compressor does not reach A minutes, it is returned. The return process represents an operation state in which the operation state of the current compressor (100% drive state) is maintained.

When the condition of the step 112 is satisfied, the control unit 55 controls only the 60% compressor driving unit 51 in the driving state (step 118). At this time, the 40% compressor drive unit 53 is in a stopped state. That is, only one compressor is in operation.

That is, in the step 118, it is determined that the current load is low in the room temperature control and the operating conditions of the compressor are adjusted low. In the previous stage, the compressor was 100% operational. However, in step 118, the compressor was lowered to 60% operation. This determines that sufficient heating operation can be achieved with only one compressor, and stops the other compressor.

After the operation condition of the compressor is adjusted by the step 118, the controller 55 continuously monitors the room temperature. The indoor temperature is detected by the indoor suction temperature sensor (57). That is, the controller 55 continuously detects the indoor temperature through the indoor suction temperature sensor 57 while the heating operation is performed, and compares the detected indoor temperature with the desired temperature to determine the load state according to the indoor temperature control. do.

If, after the operation condition of the compressor is adjusted by the step 118, the detected indoor temperature is lower than the desired temperature (indoor temperature ≤ desired temperature -0.5), if it is determined that the need to control the compressor to 100% driving state is determined 55 returns to step 109 (step 121).

However, if the indoor temperature detected in step 121 is higher than the desired temperature (desired temperature -0.5 ≤ indoor temperature <desired temperature +1), it is returned to maintain the operating conditions of the current compressor. The return operation indicates that the operation condition of the current compressor (compressor operation 60%) is maintained.
On the contrary, if the indoor temperature detected in step 121 is higher than the desired temperature (room temperature ≥ desired temperature + 1), and the condition is to be stopped, the compressor is controlled to be stopped (step 124). .

Then, the third control of the present invention is made. That is, the third control of the present invention is a section in which the compressor is controlled by turning on / off the compressor according to the room temperature in a state in which the operation condition of the compressor is reduced. In this case, if the indoor temperature control is sufficiently performed, the current compressor operating condition is maintained, but if it is determined that the indoor temperature control is difficult with the current compressor operating condition, the control is performed to increase the compressor operating condition.

Therefore, in the step 124, the stop state control of the compressor is performed when the room temperature is higher than the desired temperature by a predetermined amount. When the room temperature is lower than the desired temperature again, the compressor is controlled to the on state. At this time, the controller 55 generates the driving force of the required product while controlling only the 60% compressor driving unit 51 in the operating state or the stopped state (step 127).

In performing the control of the step 127, the controller 55 monitors the room temperature. When the room temperature is maintained at a predetermined level lower than the desired temperature for more than a predetermined time, the control is performed again to increase the driving capability of the compressor (step 130).

As described above, the present invention, in the air conditioner having two compressors, when performing the indoor temperature control, the control unit for controlling both compressors in the driving state or all in the stopped state, and driving any one compressor It is controlled by dividing into the section that controls the status or stops. This control is adjusted according to the current load conditions of the product. In other words, by controlling the operating conditions of the compressor in accordance with the current load state of the product at the time of room temperature control, a more efficient and energy saving control is performed. In particular, since the compressor consumes the most power in the product, there is a marked difference in power consumption when comparing two compressors with only one compressor.

In the present invention, the judgment of the load state of the product is judged based on the operation time (on time) of the compressor. However, the present invention is not limited thereto, and may be based on other judgment conditions. For example, it may be based on indoor piping temperature, outdoor piping temperature, and the like.

In addition, although the present invention has been described in the embodiment with two compressors, it is not necessary to limit the two compressors. It is also possible to include a plurality of compressors, and to control the operating state of the compressor in accordance with the output capacity at the time of room temperature control.

And although the compressor drive part of this invention is demonstrated in 60% type and 40% type, it does not need to be limited to this. When the maximum output capacity is 100%, it can be formed in any form by distributing it.

In addition, although the embodiment of the present invention describes the heating operation as an example, the present invention is not limited thereto, and is applicable to any product including two or more compressors and performing heat exchange control while variably controlling the operating conditions of the compressor. .

The air conditioner of the present invention described above can obtain the following effects.

First, in the case of a product having a capacity of a size required by the product as one compressor, the on / off control of the compressor is inevitably made in conjunction with the operation of the product as in the prior art. However, since the present invention includes two compressors, it is possible to control driving both compressors or driving only one compressor. Therefore, the present invention can be controlled to drive two or one compressor in accordance with the load state of the product, it is possible to obtain an effect that can significantly reduce the power consumption of the product.

Second, the present invention includes two compressors, and when controlling the heating room temperature, the compressor can be optimally used by using an optimal algorithm. Therefore, unnecessary use of the compressor can be prevented, and the useful life of the compressor can be extended, thereby increasing the reliability of the product.

Third, the price difference of the large capacity compressor is very high compared to the small capacity compressor. Therefore, a product using two small capacity compressors can reduce the manufacturing cost, and can provide an economic effect on the consumer.

Claims (5)

In an air conditioner having two or more compressors having different capacities, A first room temperature control step of driving all compressors to perform room temperature control; A load determination step of determining an indoor temperature load by comparing the operation time of the compressor with a predetermined predetermined time in the first indoor temperature control step; And a second indoor temperature control step of performing indoor temperature control by selectively driving the compressors individually based on the indoor temperature and the desired temperature when the indoor temperature load is small in the load determination step. And a control state of the first indoor temperature control step when the indoor temperature load is high in the load determination step. The method of claim 1, The first and second indoor temperature control steps, the operation control method of the air conditioner, characterized in that the room temperature control process according to the heating operation. The method according to claim 1 or 2, When the indoor temperature control by the second indoor temperature control step is performed, it further comprises a determination step of determining whether the indoor temperature control is possible under the current compressor operating conditions, and if it is determined that the indoor temperature control is difficult, the first indoor temperature Operation control method of the air conditioner, characterized in that to return to the control step. The method of claim 3, wherein The determining step, the operation control method of the air conditioner, characterized in that it is determined whether the room temperature lasts for a predetermined time or more in a predetermined state lower than the desired temperature. The method of claim 3, wherein The second indoor temperature control step may include: checking whether the indoor temperature is a predetermined temperature or less than the desired temperature by driving all compressors; Limiting a drive compressor to a part when the indoor temperature is not below a predetermined temperature below the desired temperature in the checking step; Performing control to maintain a current operating state, stop the operation of the compressor, or increase the operating conditions of the compressor based on the difference between the indoor temperature and the desired temperature while performing indoor temperature control with the limited compressor. Operation control method of the air conditioner configured.

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