KR20070014323A - Method for controlling inverter compressor of air conditioner - Google Patents

Abstract

A method for controlling an inverter compressor of an air conditioner is provided to vary rpm of the compressor gradually for preventing rapid change thereof, thereby improving durability of the compressor. A method for controlling an inverter compressor of an air conditioner includes the steps of initiating a motor part of the compressor in the initiation of the air conditioner for increasing rpm thereof gradually to the initial rpm(S1,S2), calculating the target rpm of the compressor corresponding to a set temperature during the first step(S3), and varying the rpm of the compressor gradually to the calculated target rpm as the initial rpm is realized through the first step. The set temperature is calculated differently according to the set temperature, a current room temperature, and cooling/heating mode. The variation of the rpm is carried out by a level difference between the target rpm and the initial rpm(S4-S8).

Description

Control method of variable compressor of air conditioner {Method for controlling inverter compressor of air conditioner}

1 is a control block diagram of a conventional inverter type air conditioner,

2 is a flow chart for explaining the operation control method of the conventional inverter type air conditioner,

3 is a graph showing a change in compressor rotation speed according to a compressor operation operation of a conventional inverter type air conditioner;

4 is a flowchart illustrating a variable compressor control method of an air conditioner according to the present invention;

5 is a view illustrating a change in rotation speed of a compressor according to the control method of FIG. 4;

6 is another embodiment illustrating a change in rotation speed of a compressor according to the control method of FIG. 4.

The present invention relates to a method of controlling a variable compressor of an air conditioner, and more particularly, by varying the rotational speed of the variable compressor step by step according to the set temperature at the start of the air conditioner to prevent sudden changes in the rotational speed of the system The present invention relates to a variable compressor control method of an air conditioner.

In general, an air conditioner is a machine for the purpose of air conditioning in a room. The air conditioning and heating function of the room serves as a main function and additionally provides functions such as dehumidification and cleanliness.

Such an air conditioner is usually provided with a refrigeration cycle system consisting of an evaporator, a capillary tube, an expansion valve, a compressor, and a condenser. Among these, a compressor is a device for compressing a refrigerant and adjusts the rotation speed of the compressor according to the frequency of the power applied to the compressor. As a result, the refrigerant flow rate is changed freely.

A compressor capable of changing the frequency of the compressor by changing the frequency as described above is called an inverter or a variable compressor.

1 is a control block diagram of a conventional inverter type air conditioner.

As shown in FIG. 1, the indoor unit 10 includes an indoor temperature sensor 11, an indoor fan motor 12, a microcomputer 13, a remote controller receiver 14, a data communication unit 16, and a remote controller 15. do. The outdoor unit 20 has an outdoor temperature sensor 21, a current detection sensor 22, an outdoor fan motor 23, a microcomputer 24, a data communication unit 25, a converter 26, an inverter 27, and a driving unit. 28, and the compressor 29.

At this time, the remote controller 15 inputs a user's command and transmits it to the remote controller receiver 14, the remote controller receiver 14 applies the input signal to the microcomputer 13, and the microcomputer 13 receives the remote controller 14. In accordance with the signal input from the drive fan of the indoor fan motor 12, the outdoor fan motor 23 and the compressor 29 to be described later, and the corresponding control signal to the outdoor unit 20 through the data communication unit 16 Send.

In addition, the indoor temperature sensor 11 detects the temperature of the room and applies it to the microcomputer 13 on the indoor unit 10 side. Accordingly, the microcomputer 13 adjusts the cooling / heating operation state according to the detected room temperature. do.

On the other hand, the outdoor temperature sensor 21 of the outdoor unit 20 senses the outdoor temperature, the current detection sensor 22 detects the current according to the drive of the compressor 29 and applies it to the microcomputer 24, the microcomputer ( 24 determines the overload state of the compressor 29 according to the detected temperature and current change. And the microcomputer 24 inputs the signal of the indoor unit 10 side received from the data communication part 25, and functions to drive the outdoor fan motor 23 and the compressor 29 accordingly.

In addition, the converter 26 receives a commercial power source (AC) and converts it into a direct current to rectify from a commercial frequency to a direct current (DC), and the inverter 27 reconverts the direct current to a voltage / frequency of the corresponding alternating current. In addition, the driving unit 28 functions to drive the compressor 29 by using an alternating current frequency converted by the inverter 27.

The conventional inverter type air conditioner configured as described above is operated in the manner as shown in Figs.

2 is a flowchart illustrating an operation control method of a conventional inverter type air conditioner, and FIG. 3 is a graph showing a change in compressor rotation speed according to a compressor operation operation of a conventional inverter type air conditioner.

First, when a user operates the remote controller 15 for cooling or heating operation, the remote controller receiver 14 of the indoor unit 10 receives an operation signal and applies it to the microcomputer 13. Therefore, the microcomputer 13 of the indoor unit 10 determines whether it is a start command, and when the start command is driven, drives the indoor fan motor 12 and the outdoor fan motor 23 installed in the outdoor unit 20. The control signal for driving the compressor 29 is applied to the data communication unit 16. In addition, the microcomputer 24 of the outdoor unit 20 inputs a signal of the indoor unit 10 side received from the data communication unit 25 and accordingly drives the outdoor fan motor 23 and the compressor 29 to cool or heat. Perform the operation (S101 ~ S104).

Subsequently, when the cooling or heating operation is performed, the microcomputer 24 of the outdoor unit 20 detects the outdoor temperature through the outdoor temperature sensor 21 and compares / determines whether the outdoor temperature is greater than the overload temperature (S105, S106). ).

At this time, when the outdoor temperature is more than the overload temperature, by turning off the compressor 29 to protect the compressor 29 and other electrical equipment from the overload (S107).

In addition, the microcomputer 13 of the indoor unit 10 detects the indoor temperature through the indoor temperature sensor 11, and when the indoor temperature reaches the desired temperature preset by the user, the outdoor fan motor 23, the indoor fan motor The cooling or heating operation is terminated by stopping the loads of the 12 and the compressor 29 (S108 to S111).

As described above, the inverter compressor 29 of the air conditioner changes the cooling or heating capability of the air conditioner by increasing or decreasing the rotation frequency (or rotation speed), as shown in FIG. 3. Up to (P) step by step in a predetermined pattern, and then linearly increases or decreases the number of revolutions to change directly to the target number of revolutions of the set temperature according to heating and cooling.

By the way, the variable compressor of the conventional air conditioner that operates as described above rapidly increases or decreases the rotational speed of the compressor at the initial rotational speed at the initial rotational speed when the target rotational speed is much different from the initial rotational speed level. Therefore, there is a problem in that the overload of the compressor and damage to the components occur accordingly.

Accordingly, the present invention has been made to solve the above-described problem, and the variable compressor control method of the air conditioner to prevent the load in the system by varying the rotational speed of the variable compressor in accordance with the set temperature at the time of starting the air conditioner The purpose is to provide.

In order to achieve the above object, the present invention provides a method for controlling the operation of an air conditioner that provides a cooling and heating function by varying the rotational speed of a variable compressor. A first step of increasing in multiple stages; A second step of calculating a target rotational speed of the compressor corresponding to a set temperature while performing the first step; And a third step of varying the target rotational speed in multiple stages when the initial rotational speed is reached through the first step.

At this time, the target rotational speed in the second step is characterized in that it is calculated differently according to the set temperature, the current room temperature and the cooling and heating mode.

In the third step, the level difference between the target rotational speed and the initial rotational speed may be calculated to vary in multiple stages by the level difference from the initial rotational speed.

If the level difference is more than 1000 [rpm] when the initial rotational speed is 2500 [rpm], first increase the number of steps by 500 [rpm] two times, and finally increase the remaining level difference by subtracting 1000 [rpm]. On the other hand, if the level difference is less than 1000 [rpm], it is first increased by 500 [rpm], and then multiplied by the remaining level difference minus the 500 [rpm].

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention;

4 is a flowchart illustrating a method of controlling a variable compressor of an air conditioner according to the present invention, FIG. 5 is an embodiment illustrating a change in rotation speed of a compressor according to the control method of FIG. 4, and FIG. 6 is of FIG. 4. Another embodiment showing a change in the rotational speed of the compressor according to the control method.

First, referring to Figure 4, the variable compressor control method of the air conditioner according to the present invention is a step of increasing the initial rotational speed in a predetermined pattern, and the initial rotational speed after reaching the initial rotational speed by the above process The main point is that it consists of two steps of increasing or decreasing the target speed of the desired temperature in multiple stages.

First, when the power is supplied and the desired temperature is set by the user's operation and the air conditioning operation of the air conditioner is started, the motor unit of the compressor is started to operate the compressor (S1).

Initially, the number of revolutions of the compressor is increased step by step until the initial speed corresponding to the reference starting pressure (S2).

At the same time, the target rotational speed corresponding to the desired temperature is predicted, which depends on the desired temperature, the present room temperature, and the heating / cooling mode (S3).

That is, in the case of cooling, Equation 1 below.

Estimated Target Speed = (Current Room Temperature-Desired Room Temperature) × Cooling Constant + Minimum Speed

In addition, in the case of heating, it can predict by the formula shown in following formula (2).

Expected target rotational speed = (desired room temperature-current room temperature) × heating constant + minimum rotational speed

At this time, the minimum rotational speed is usually 1000 RPM, and when the expected target rotational speed is greater than the maximum rotational speed of the compressor according to the indoor and outdoor load, the maximum rotational speed of the compressor is defined as the expected target rotational speed.

Subsequently, it is determined whether or not the predicted target rotational speed is greater than the level of the initial rotational speed as described above, and the degree of level difference between the target rotational speed and the initial rotational speed is determined (S4).

As a result of the determination, when the target rotational speed is greater than the initial rotational speed, a difference value between the target rotational speed and the initial rotational speed is calculated, and increased in multiple stages by the calculated differential value (S5 to S6).

Alternatively, when the target rotational speed is smaller than the initial rotational speed, the differential value between the target rotational speed and the initial rotational speed is calculated, and then reduced by multiple steps instead of a linear decrease by the calculated differential value (S7 to S8).

For example, assuming that the initial rotational speed P1 is 2500 [RPM] and the target rotational speed S1 is 4000 [RPM] as shown in FIG. 5 as an embodiment, the initial rotational speed P1 is reached. Until it is to increase the step by step of the predetermined pattern by adjusting the rotation speed of the motor for about 180 seconds. After reaching the initial rotational speed P1 from this, the differential value ΔN1 between the initial rotational speed P1 and the target rotational speed S1 is calculated, and the minimum rotational speed 1000 [RPM as the differential value ΔN1 as the reference value is calculated. If greater than], increase 500 [RPM] by dividing twice for 50 seconds and finally increase the total number of revolutions remaining.

That is, 1500 [RPM], which is the difference value ΔN1 between the initial rotational speed P1 and the target rotational speed S1, is calculated, and 1000 [RPM] (Δn11 + Δn12) is 180 to 280 seconds from the calculated differential value. 500 [RPM] of the remaining difference value (DELTA) n13 is gradually raised for 300 minutes from 280 seconds to 300 seconds, and a compressor is controlled to operate according to a predetermined pattern for 3 minutes.

Next, referring to FIG. 6, as another embodiment, assuming that the initial rotational speed P2 is 2500 [RPM] and the target rotational speed S2 is 3300 [RPM], the initial rotational speed P2 and the target rotational speed S2 are described. ), The difference value DELTA N2 becomes 800 [RPM].

Therefore, until the initial rotational speed P2 is reached for the first time, the rotational speed of the motor unit is adjusted for about 180 seconds, thereby increasing in steps of the preset pattern method, and after reaching the initial rotational speed P2, the differential value ΔN2 is reached. Drive 500 [RPM] (Δn21) for 180 seconds to 250 seconds, then multiply it by increasing the differential value (Δn22) 300 [RPM] minus 500 [RPM] for 250 seconds to 300 seconds. . That is, when the differential value ΔN 2 is smaller than 1000 [RPM], first, 500 [RPM] is driven for a predetermined time, and then, the differential value is increased by the remaining differential value to start the target rotational speed S2.

Here, the above-described time (seconds) is not limited to this as an example according to the embodiment, and may be changed according to the driving time of the compressor, and in the case of reducing the rotation speed of the compressor in addition to the increase in the rotation speed, It is preferable to start in multiple stages.

As such, when the air conditioner starts up, the first initial rotational speed is increased in a predetermined pattern to the first initial rotational speed, and then the rotational speed is linearly increased or decreased in a different pattern manner according to the difference value between the target rotational speed and the initial rotational speed. The problem caused by the rapid change can be solved.

As described above, according to the present invention, by varying the rotational speed of the compressor in multiple stages to prevent a sudden change in the rotational speed, it is possible to improve the durability of the compressor, to prevent the load in the system to achieve stability.

Claims (7)

In the operation control method of the air conditioner to provide a cooling and heating function by varying the rotational speed of the variable compressor, A first step of operating the motor unit of the compressor at the start of the air conditioner to increase the engine speed in multiple stages; A second step of calculating a target rotational speed of the compressor corresponding to a set temperature while performing the first step; And A third step of varying the target rotational speed in multiple stages when the initial rotational speed is reached through the first step; Variable compressor control method of an air conditioner comprising a. The method of claim 1, The initial rotational speed is 2500 [rpm] variable compressor control method of the air conditioner, characterized in that. The method of claim 1, The target rotation speed in the second step is The variable compressor control method of the air conditioner, characterized in that calculated differently according to the set temperature, the current room temperature and the heating and cooling mode. The method of claim 1, The third step is And calculating a level difference between the target rotational speed and the initial rotational speed, and varying the initial rotational speed in multiple stages by the level difference. The method according to claim 1 or 4, The variable variable control compressor of the air conditioner, characterized in that the increase or decrease. The method according to claim 2 or 4, If the level difference is more than 1000 [rpm], first variable by 500 [rpm] step by step twice, and finally by increasing the remaining level difference minus 1000 [rpm] variable compressor control method of the air conditioner . The method according to claim 2 or 4, If the level difference is less than 1000 [rpm], first increase by 500 [rpm], and then increase by multiple stages by the remaining level difference minus the 500 [rpm] variable compressor control method of the air conditioner.

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