KR102208111B1 - control method of an outdoor unit of an air conditioning system - Google Patents

Abstract

The present invention relates to a method for controlling an air conditioning system, and more particularly, to a method for controlling an outdoor unit.
According to an embodiment of the present invention, in a method of controlling an outdoor unit having a first fan and a second fan, before power is applied to the outdoor unit and the first fan is started, a current RPM of the first fan and a predetermined value are determined. A first headwind detection step of comparing RPMs to detect headwinds; A control holding step of suspending starting of the first fan when the current RPM is higher than a predetermined RPM in the first headwind detection step; And a fan control step of starting the first fan and controlling to sequentially start the second fan when the current RPM is less than a predetermined RPM in the headwind detection step, wherein the first fan and the second fan are independently A method of controlling the outdoor unit to be controlled may be provided.

Description

Control method of an outdoor unit of an air conditioning system

The present invention relates to a method for controlling an air conditioning system, and more particularly, to a method for controlling an outdoor unit.

In general, an air conditioner performs a function of cooling or/and heating an indoor space according to a process of compressing, condensing, expanding, and evaporating a refrigerant.

1 is a conceptual diagram showing a general air conditioner.

Referring to FIG. 1, the air conditioner 1 may include an outdoor unit O and a plurality of indoor units I: I11 to I19 connected to the outdoor unit O. In addition, it may include a remote control 10 connected to each indoor unit to control the operation of the indoor unit and display the operation state. The remote control 10 may be a wired remote control connected to an indoor unit or a wireless remote control. A remote controller RC for remotely controlling the outdoor unit O and the indoor units I: I11 to I19 may be included.

In addition, it may include a central controller 20 connected to the outdoor unit to centrally control the operation of the indoor unit and the outdoor unit.

For indoor cooling, the indoor unit sucks hot air in the room through a heat exchanger and supplies cold air back to the room. Accordingly, the heat exchanger of the indoor unit functions as an evaporator. In addition, the outdoor unit sucks outdoor air through a heat exchanger and discharges hot air to the outside again. Accordingly, the heat exchanger of the outdoor unit functions as a condenser.

In particular, for sufficient heat exchange in the outdoor unit O, it is necessary to provide a sufficient flow rate of air from a fan provided in the outdoor unit to the heat exchanger of the outdoor unit. Therefore, in general, the RPM of the fan is variably controlled in response to the cooling capacity. That is, when the cooling capacity is large, the target RPM of the fan is increased to increase the air flow rate, and when the cooling capacity is small, the target RPM of the fan is lowered to reduce the air flow rate.

As shown in FIG. 1, in recent years, cooling or heating is often performed by matching a plurality of indoor units to one outdoor unit. Accordingly, the capacity of the outdoor unit O itself tends to increase, and an outdoor unit provided with two fans to enable sufficient heat exchanger in one outdoor unit is provided.

The outdoor unit is generally installed on the exterior wall or roof of a building. Therefore, in many cases, the rotational axis of the fan of the outdoor unit may be level with the ground. Due to the position of the fan, there is a possibility that the rotation of the outdoor unit fan may be interfered with by draft.

FIG. 2 shows an example of an outdoor unit in which two fans are mounted and the fans discharge air in a direction substantially horizontal to the ground.

Inside the outdoor unit housing 100, a heat exchanger 110, fans 131 and 141 for flowing air for heat exchange in the heat exchanger, and fan motors 130 and 140 for driving the fan may be provided. . Control of such fan driving may be performed by the controller 120.

When the power supply voltage Vcc is applied by the control unit 120, the motor input current Idc is applied to the fan motors 130 and 140. Here, the motor driving voltage Vdc may be determined according to the power voltage Vcc. The motor input current Idc is determined according to the motor driving voltage Vdc, and the control unit 120 may control the power voltage Vcc and the motor driving voltage Vdc.

The controller 120 applies a target RPM signal Vsp to the fan motors 130 and 140. This target RPM signal may be determined according to the current cooling load or heating load. Accordingly, the target RPM signal Vsp may be controllable by the controller 120.

The fan motors 130 and 140 transmit the current RPM signal to the controller 120 with respect to the target RPM signal Vsp. Accordingly, the control unit 120 performs feedback control so that the current RPM reaches the target RPM. That is, by controlling the motor driving voltage Vdc and varying the motor input Idc applied to the motor, the current RPM is controlled to follow the target RPM.

The hardware and flow for controlling the fan motors 130 and 140 through the controller 120 of the outdoor unit are general, and thus detailed descriptions thereof will be omitted.

However, such a control flow may cause many problems depending on the external environment of the outdoor unit O.

As shown in FIG. 2, the heat exchanger 110 may be provided up and down inside the rear of the housing 100, and the fan may be provided up and down inside the front of the housing 100. That is, the fan includes an upper fan 131 and a lower fan 141, and an upper fan motor 130 and a lower fan motor 140 driving each of them may be provided.

As the fan rotates in a clockwise direction, for example, the air inside the outdoor unit may be discharged to the outside. At this time, the air outside the outdoor unit is introduced into the outdoor unit. That is, as the fan rotates, air is introduced into the outdoor unit and heat-exchanged in the heat exchanger, and the heat exchanged air is discharged to the outside through the fan. In Fig. 2, the direction of air flow in this normal state is shown by arrows.

However, there is a possibility that a headwind (headwind) may be generated for the fans 131 and 141 due to an external environment such as a typhoon. That is, there is a possibility that external air flows into the outdoor unit through the fans 131 and 141 through the headwind.

This headwind generates a force that rotates the fan in the opposite direction (eg counterclockwise). Therefore, when a headwind is generated, a rush current may be generated due to a back electromotive force when the fan is started. That is, the motors 130 and 140 that drive the fans by the headwind are operated as a generator, so that inrush current due to the reverse electromotive force may be generated.

Due to such an inrush current, there may be a concern about damage to the fan motors 130 and 140, and normal fan RPM control may not be possible, resulting in a problem of reducing cooling or heating capacity. This is because the load of the fan motor increases due to the occurrence of the headwind, and the actual RPM of the fan is bound to rotate at a lower RPM than the target RPM. Therefore, it is necessary to solve the problem caused by headwind when the fans 131 and 141 are started.

On the other hand, as shown in FIG. 2, in the case of a heat exchanger having two fans, there is a concern that counter wind is applied to the other fan due to one fan when the fan is started. In particular, this problem can occur in many cases when two fans are controlled to start at the same time.

When two fans are controlled to start at the same time, the two fans may start with a deviation due to various reasons, such as the location between the fans, the surrounding environment, and the slight differences between the components constituting the fan or the fan motor. That is, when one fan (the first fan) is started and the RPM approaches the target RPM, there is a possibility that the other fan (the second fan) starts rotating. In this case, the air discharged from the first fan may be introduced into the outdoor unit through the second fan, which may be referred to as headwind from the viewpoint of the second fan.

For example, when the lower fan 141 first rotates, air discharged from the lower fan 141 may be headwind from the position of the upper fan 131. This is because the air discharged to the lower fan 141 may be introduced into the outdoor unit O through the upper fan 131.

Accordingly, not only headwinds caused by external environments such as typhoons, but also headwinds caused by nearby fans may occur. The same problem as described above may also occur through the latter headwind.

The present invention basically aims to solve the problem of the conventional outdoor unit described above.

Through an embodiment of the present invention, when a headwind occurs due to the operation of a nearby fan as well as headwind caused by external environments such as typhoons, an outdoor unit with improved reliability by preventing overload of the fan motor and an air conditioner including the same is provided. I want to.

An object of the present invention is to provide an outdoor unit capable of exerting a target cooling or heating performance even when a headwind occurs, and an air conditioner including the same.

Through an embodiment of the present invention, it is intended to provide an outdoor unit capable of easily responding to headwind from a control point of view without major changes in conventional outdoor unit hardware, and an air conditioner including the same.

In order to achieve the above object, according to an embodiment of the present invention, in a method for controlling an outdoor unit having a first fan and a second fan, before power is applied to the outdoor unit and the first fan is started, the A first headwind detection step of detecting a headwind by comparing the current RPM of the first fan with a predetermined RPM; A control holding step of suspending starting of the first fan when the current RPM is higher than a predetermined RPM in the first headwind detection step; And a fan control step of starting the first fan and controlling to sequentially start the second fan when the current RPM is less than a predetermined RPM in the headwind detection step, wherein the first fan and the second fan are independently A method of controlling the outdoor unit to be controlled may be provided.

Here, it is preferable that the first fan and the second fan sequentially apply a motor input current to the fan motors that drive each fan so that they are sequentially started. For example, if a motor input current is first applied to the first fan motor to start the first fan, and it is determined that a typhoon or a headwind caused by the first fan is not detected or is determined, the motor input current to the second fan motor It is preferable to apply.

It is preferable that the predetermined RPM is a target RPM.

The fan control step includes: a first fan control step of starting the first fan to control the first fan at a target RPM; In addition, during the first fan control step, a second headwind detection step of detecting a headwind by checking the current RPM of the second fan may be included.

It is preferable that the starting control mode of the second fan is changed according to the current RPM of the second fan checked in the second headwind detection step.

Specifically, the second headwind detection step may be a step of determining whether the current RPM is larger or smaller than the minimum RPM controllable by the second fan. Alternatively, the second headwind detection step may be a step of checking whether the current RPM is generated and sensed.

When a headwind is detected in the second headwind detection step, it is preferable that the second fan is controlled in a maximum starting mode in which the second fan is started at a controllable maximum RPM. That is, it is desirable to minimize the influence of the headwind generated by the first fan when the second fan is started. After performing the maximum starting mode, it is preferable that a second fan control step of controlling the second fan at a target RPM is performed. It is preferable that the second fan is controlled to gradually lower the RPM from the maximum RPM to the target RPM.

If the headwind is not detected in the second headwind detection step, it is preferable that the second fan is controlled in a minimum start mode in which the second fan is started with a controllable minimum RPM. In addition, after performing the minimum starting mode, it is preferable that a second fan control step of controlling the second fan at a target RPM is performed. It is preferable that the second fan is controlled to increase the RPM to the target RPM step by step from the minimum RPM.

When a headwind is detected in the second headwind detection step, the first fan may be controlled with an RPM smaller than the target RPM in the first fan control step. That is, it is desirable to reduce the headwind generated by the first fan.

In the first fan control step, the RPM may be gradually decreased until no headwind is detected in the second headwind detection step.

When a headwind is not detected in the second headwind detection step, the second fan may be controlled to start. In other words, when it is determined that headwind by the first fan is not generated, the second fan may be controlled to start.

In the first fan control step, the RPM may be gradually increased to reach a target RPM. The stepwise increase of the RPM may be performed until a headwind is detected in the second headwind detection step. Accordingly, it is possible to prevent the occurrence of headwind due to starting of the first fan from the beginning.

In order to achieve the above object, according to an embodiment of the present invention, before power is applied to the outdoor unit and the first fan and the second fan are started, at least one of the first fan and the second fan is A first headwind detection step of detecting headwind through the current RPM; A first fan control step of starting the first fan when a headwind is not detected in the first headwind detection step; A control holding step of suspending the execution of the first fan control step when a headwind is detected in the first headwind detection step; A second headwind detection step of detecting headwind through the current RPM of the second fan after starting the first fan; In addition, when the headwind is not detected in the second headwind detection step, a control method of the indoor unit including a second fan control step of starting the second fan may be provided.

Accordingly, starting of the first fan is controlled in consideration of the headwind caused by the typhoon, and when the first fan is started, the starting of the second fan is controlled in consideration of the headwind by the first fan. Through this, a motor input current may be applied to the fan motors so that the first fan and the second fan are sequentially started.

In the first headwind detection step, when the current RPM is greater than a target RPM, it is determined that headwind is detected, and the control hold step may be performed.

In order to achieve the above object, according to an embodiment of the present invention, in a method for controlling an outdoor unit having a first fan and a second fan, power is applied to the outdoor unit and the first fan and the second fan are started. A first headwind detection step of detecting a headwind through a current RPM of at least one of the first fan and the second fan; A first fan control step of starting the first fan when a headwind is not detected in the first headwind detection step; A control holding step of suspending the execution of the first fan control step when a headwind is detected in the first headwind detection step; A second headwind detection step of detecting headwind through the current RPM of the second fan after starting the first fan; And when the headwind is sensed in the second headwind detection step, a second fan control step of starting the second fan after removing the headwind by reducing the RPM of the first fan is provided. Can be.

In order to achieve the above object, according to an embodiment of the present invention, before power is applied to the outdoor unit and the first fan and the second fan are started, at least one of the first fan and the second fan is A first headwind detection step of detecting headwind through the current RPM; A first fan control step of starting the first fan when a headwind is not detected in the first headwind detection step; A control holding step of suspending the execution of the first fan control step when a headwind is detected in the first headwind detection step; A second headwind detection step of detecting headwind through the current RPM of the second fan after starting the first fan; In addition, a control method of an indoor unit including a second fan control step of starting the second fan by changing a start control mode of the second fan according to whether a headwind is detected in the second headwind detection step may be provided. .

When a headwind is detected in the second headwind detection step, a maximum start mode in which the second fan is started at a controllable maximum RPM may be performed.

When the headwind is not detected in the second headwind detection step, a minimum start mode in which the second fan is started with a controllable minimum RPM may be performed.

Through an embodiment of the present invention, when a headwind occurs due to the operation of a nearby fan as well as headwind caused by external environments such as typhoons, an outdoor unit with improved reliability by preventing overload of the fan motor and an air conditioner including the same is provided. can do.

Through an embodiment of the present invention, it is possible to provide an outdoor unit capable of exhibiting a target cooling or heating performance even when a headwind occurs, and an air conditioner including the same.

Through an embodiment of the present invention, it is possible to provide an outdoor unit capable of easily responding to headwind from a control point of view without major changes in conventional outdoor unit hardware, and an air conditioner including the same.

1 is a simplified diagram showing the configuration and connection relationship of a general air conditioner;
2 is a simplified cross-sectional view of an outdoor unit applicable to embodiments of the present invention;
3 is a flow chart showing a control flow for an embodiment of the present invention;
4 is a flow chart showing a control flow for another embodiment of the present invention;
5 is a flow chart showing a control flow for another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention for a method of controlling an outdoor unit having a first fan 141 and a second fan 131 as shown in FIG. 2 will be described in detail.

First, a preferred embodiment will be described in detail with reference to FIG. 3.

When the power of the outdoor unit 0 or the air conditioner is turned on (S100), the outdoor unit O may be driven to respond to a required cooling load or heating load. Specifically, a fan motor may be started for heat exchange in the outdoor unit O.

However, in the present embodiment, when the power is turned on, the fan motors do not start immediately, and the step S110 of sensing the first headwind may be performed. That is, in order to start the first fan 141 and the second fan 131, it is determined whether a headwind is generated without inputting the motor input current Idc to each fan motor.

As described above, when the power of the air conditioner is turned on (S100), the target RPM (Vsp) of the fan may be set according to the current cooling load or heating load. In addition, the current RPM (Vfg) from the fan motors 130 and 140 may be transmitted to the controller 120. That is, it is possible to determine whether the fans 131 and 141 are rotating without applying the motor input current Idc to the fan motor. This can be said to determine whether the fan is rotating by the headwind.

This first headwind detection step (S110) may be performed for only one fan, and may be performed for two fans. However, when two fans are provided, the starting order may be determined, and in this embodiment, the first fan set to start the lower fan 141 first may do so.

Accordingly, in this embodiment, the lower fan 141, that is, the first fan is first started, and then the second fan is controlled to be started. For this reason, the first headwind detection step S110 may be performed for the lower fan 141.

Before starting the first fan 141 in the first headwind detection step (S110), the current RPM of the first fan 141 is compared with a predetermined RPM. The predetermined RPM may be referred to as a threshold value for determining whether to start the first fan according to the intensity of the headwind. Accordingly, when the intensity of the headwind exceeds the threshold value, the control hold step S120 of suspending the start of the first fan may be performed.

Specifically, the predetermined RPM may be a target RPM. Accordingly, when the current RPM is greater than or equal to the target RPM, starting of the first fan 141 may be suspended. This means that the current first fan rotates with sufficient RPM by the headwind, which means that sufficient heat exchange is performed in the outdoor unit. This is because, as shown in FIG. 2, there is no significant difference between the heat exchange performance and the air flowing from the front of the outdoor unit to the rest as opposed to the air flowing from the rear to the front of the outdoor unit.

Accordingly, when a headwind is detected in the first headwind detection step (S110), more specifically, when it is determined that the headwind is greater than or equal to a predetermined strength, the start of the first fan 141 is suspended (S120). The start of the first fan 141 is suspended means that the start of the second fan 131 is also suspended. This is because in this embodiment, starting of the second fan is based on starting of the first fan.

In the first headwind detection step (S110), it may be determined that the headwind is not detected, or that sufficient air flow is not induced even when the headwind is detected. That is, when the current RPM is less than a predetermined RPM, in particular, the fan control step (S130 to S170) may be performed so that the fan is started. In the fan control steps (S130 to S170), the first fan 141 is started (S130), and the second fan 131 is sequentially controlled to start.

The first fan starting (S130) in the fan control step may include controlling the first fan with a target RPM by starting the first fan. That is, a step of controlling the first fan to be driven at a target RPM may be included. During the first fan control step, a second headwind detection step S130 may be performed.

The second headwind detection step S140 may be referred to as a step of detecting whether headwind is generated in the second fan due to the rotation of the first fan.

First, when the first fan is started and the target RPM tracking control is performed, it means that heat exchange is not performed as much as a target in the current outdoor unit. Therefore, this means that heat exchange must also be performed through the second fan. Conversely, when headwind is applied to the second fan, it means that there is a possibility that damage to the second fan motor S130 may occur by starting the second fan.

Therefore, it is preferable that the start control mode of the second fan is changed according to the determination result in the second headwind detection step S140.

Specifically, in the second headwind detection step (S140), as in the first headwind detection step (S110), it may be determined whether the current RPM of the second fan is higher than a predetermined RPM. Here, the predetermined RPM is preferably smaller than the target RPM of the second fan.

However, the current target RPM of the second fan will vary according to the current cooling or heating load. Of course, it was first determined that a headwind such as a typhoon did not occur through the first headwind detection step (S110). Accordingly, in the second headwind detection step (S140), it is necessary to determine whether the headwind caused by the start of the first fan is greater or less than a threshold value to minimize damage to the motor when the second fan is started. As a result, the threshold value, that is, the predetermined RPM in the second headwind detection step S140 may be, for example, a minimum RPM controllable by the second fan. Of course, it will be possible to detect only whether the current RMP occurs. That is, when the current RMP of the second fan is detected in the second headwind detection step S140, it may be determined that headwind is generated.

Accordingly, in the second headwind detection step (S140), it is determined whether the current RPM of the second fan is greater than or equal to the minimum controllable RPM of the second fan or whether the current RPM is detected. As a result of the determination, when the current RPM of the second fan is greater than or equal to the minimum controllable RPM of the second fan, or when the current RPM is detected, it may be determined that headwind is generated in the second fan due to the start of the first fan.

When a headwind is generated, the second fan motor 130 performs a generator function, thereby generating a rush current. Therefore, it is necessary to prevent damage to the motor due to the inrush current by inputting the motor input current Idc greater than the inrush current. Therefore, at this time, it is preferable that the second fan is controlled to be started in the maximum starting mode (S150). That is, it is preferable to be controlled to be started with the maximum controllable RPM. In this case, since the motor input current Idc may be significantly greater than the inrush current, damage to the motor 130 may be prevented.

Meanwhile, when the current RPM of the second fan is determined to be less than the minimum controllable RPM of the second fan in the second headwind detection step (S140), or when the current RPM is not detected, the second fan is started due to the start of the first fan. It can be judged that the headwind does not occur. Therefore, in this case, it is preferable that the second fan is controlled to be started in the minimum starting mode (S160). This is because the second fan can be started by inputting the motor input current Idc to a minimum because there is no inrush current or very small.

In either case, the second fan is started on the premise that the first fan is started, and thereafter, the first fan and the second fan are controlled to operate normally (S170). That is, both can be controlled to operate at the target RPM.

Specifically, after the second fan is started in the maximum starting mode (S150), the RPM can be gradually lowered so that it is gradually driven to the target RPM. Conversely, after starting in the minimum starting mode (S160), the RPM is gradually driven to the target RPM. You can increase the RPM step by step. This may be referred to as the second fan control step. That is, the first fan and the second fan are sequentially started, and both are in normal operation 170 through the first fan control step and the second fan control step, respectively.

Accordingly, it is possible to start the first fan and the second fan more stably in consideration of both the generation of headwinds caused by a typhoon or the like and the generation of headwinds due to other fans.

In the above-described embodiment, first, the second headwind detection step may be performed while the first fan control step is performed. That is, after the first fan is first normally operated, whether to start the second fan, selection of a start mode, etc. may be performed. Accordingly, it is possible to control the fan motor to be started in response to a headwind against a typhoon, and to operate any one fan first in a normal state. Accordingly, it is possible to implement the desired cooling or heating performance for a short time at the initial stage of operation of the outdoor unit.

Hereinafter, another embodiment of the present invention will be described in detail with reference to FIG. 4.

The present embodiment may include the power on (S200), the first headwind detection step (S210), the fan control holding step (S220), and the fan control steps (S230 to S270) as in the above-described embodiment. Specifically, in the present embodiment, the fan control steps S230 to S270 may be different from the fan control steps S130 to S170 in the above-described embodiment.

If it is determined that the headwind is not detected in the first headwind detection step S210, the first fan control step S230 may be similarly performed in this embodiment. In the first fan control step S230, the fan driving is controlled to become a target RMP.

While the first fan control step S230 is being performed, the second headwind detection step S240 is performed, and it is determined whether the second fan is started according to the result of the second headwind detection step S240. That is, in the above-described embodiment, the second fan is started by changing the starting mode according to the result of the second headwind detection step S140, but in this embodiment, whether or not the second fan is started is different.

When the headwind is detected in the second headwind detection step S240, it means that headwind is generated in the second fan by the rotation of the first fan. Therefore, when the current RMP of the second fan is sensed in the second headwind detection step (S240) or if the current RMP of the second fan is sensed above a predetermined RMP, it may be determined that headwind is generated.

When the headwind is detected in the second headwind detection step S240, a step S250 of gradually reducing the RPM of the first fan may be performed. The reduction step (S250) and the second headwind detection step (S240) may be repeatedly performed. That is, it may be performed until it is determined that headwind does not occur in the second fan due to the first fan. Of course, in the reducing step S250, the RPM of the first fan may be reduced to a controllable minimum RPM.

On the other hand, when the headwind is detected in the second headwind detection step (S240), first, the RMP of the first fan is controlled to an RPM smaller than the target RPM, and the RMP of the first fan may be gradually decreased in stages.

If the headwind is not detected in the second headwind detection step S240, a second fan control step S260 of starting the second fan is performed. Accordingly, both the first fan and the second fan are started and driven, and eventually, the first fan and the second fan may be normally operated (S270).

Therefore, in the present embodiment, it can be said that the second fan is started after controlling the RPM of the first fan so that the headwind is not detected in the second headwind detection step S240. Accordingly, in any case, since the second fan is started in a state in which no headwind is generated in the second fan, damage to the second fan can be prevented in advance.

In addition, in the present embodiment, the first fan is first driven at a target RPM at the initial stage of operation, and then the RPM may be gradually decreased in order to prevent the generation of headwind in the second fan. Therefore, it is possible to start the operation close to the target cooling or heating load from the beginning of operation. Thereafter, it can be said that RPM control of the first fan is performed to prevent the occurrence of headwind of the second fan.

Hereinafter, another embodiment of the present invention will be described in detail with reference to FIG. 5.

The present embodiment may include power-on (S300), a first headwind detection step (S310), fan control holding step (S320), and fan control steps (S330 to S370), as in the above-described embodiments. Specifically, in the present embodiment, the fan control steps S330 to S370 may be different from the fan control steps S130 to S170 and S230 to S270 in the above-described embodiment.

If it is determined that the headwind is not detected in the first headwind detection step S310, the first fan control step S330 may be performed similarly in the present embodiment. The first fan control step S330 may be referred to as controlling the first fan to be driven with a controllable minimum RPM. That is, this is to prevent the occurrence of headwind of the second fan due to the first fan before the second fan is started.

Accordingly, when the first fan is started at a controllable minimum RPM, the second headwind detection step (S340) may be performed. If headwind does not occur in the second headwind detection step (S340), the step (S350) of gradually increasing the RPM of the first fan may be performed. That is, until the current RPM of the second fan is greater than or equal to a predetermined RMP or until the RMP of the second fan is detected, the RPM of the first fan may be gradually increased.

Accordingly, the second headwind detection step S340 and the rising step S350 may be repeatedly performed until a headwind is detected.

If it is determined in the second headwind detection step S340 that headwind is generated in the second fan, a second fan control step S360 of starting the second fan may be performed. At this time, the RMP of the first fan is reduced to the RMP just before the headwind is detected. Accordingly, it is possible to control the second fan to start in a state in which headwind to the second fan is removed.

Thereafter, the first fan and the second fan may be operated normally (S370).

In the above embodiments, it is preferable that the first fan S141 and the second fan S131 are independently controlled. In other words, it is preferable that the starting of the first fan and the second fan can be independently controlled.

Accordingly, first, when a headwind such as a typhoon occurs, it is possible to prevent both the first fan and the second fan from starting. In addition, it may be determined whether or not the other fan is started due to the activation of one fan. Through this, it is possible to prevent damage due to inrush current in the other fan.

100: outdoor unit (outdoor unit housing) 110: heat exchanger
120: control unit 130: fan motor (second fan motor)
131: fan (upper fan, second fan) 140: fan motor (second fan motor)
141: fan (lower fan, first fan)

Claims (23)

In the control method of an outdoor unit having a first fan and a second fan disposed above the first fan based on the ground,
A first headwind detection step of detecting headwind by comparing a current RPM of the first fan with a predetermined RPM before power is applied to the outdoor unit and starting the first fan and the second fan;
A control holding step of suspending starting of the first fan when the current RPM is higher than a predetermined RPM in the first headwind detection step; And
Including, a fan control step of starting the first fan and controlling to sequentially start the second fan when the current RPM is less than a predetermined RPM in the first headwind detection step; including, the first fan and the second fan Control independently,
The fan control step,
And a second headwind detection step of detecting a headwind for rotating the second fan by checking the current RPM of the second fan before starting the first fan and starting the second fan. How to control the outdoor unit. The method of claim 1,
The predetermined RPM is a control method of an outdoor unit, characterized in that the target RPM. The method of claim 2,
The fan control step,
And a first fan control step of controlling the first fan at a target RPM by starting the first fan. The method of claim 3,
The control method of an outdoor unit, wherein the starting control mode of the second fan is changed according to the current RPM of the second fan checked in the second headwind detection step. The method of claim 4,
The second headwind detection step is a step of checking whether a current RPM of the second fan is larger or smaller than a minimum RPM controllable by the second fan. The method of claim 4,
The second headwind detection step is a step of checking whether the current RPM of the second fan is generated and detected. The method according to any one of claims 3 to 6,
When a headwind is detected in the second headwind detection step, the second fan is controlled in a maximum start mode in which the second fan is started at a controllable maximum RPM. The method of claim 7,
After performing the maximum starting mode, a second fan control step of controlling the second fan with a target RPM of the second fan is performed. The method of claim 8,
And the second fan is controlled to gradually lower the RPM from the maximum RPM to the target RPM. The method according to any one of claims 3 to 6,
If a headwind is not detected in the second headwind detection step,
The second fan,
The control method of an outdoor unit, characterized in that the second fan is controlled in a minimum starting mode in which the second fan is started with a controllable minimum RPM. The method of claim 10,
And a second fan control step of controlling the second fan with a target RPM of the second fan after the second fan is performed in the minimum start mode. The method of claim 11,
The second fan is controlled to increase the RPM of the second fan to a target RPM of the second fan step by step from the minimum RPM of the second fan. The method according to any one of claims 3 to 6,
When a headwind is detected in the second headwind detection step, the first fan control step controls the first fan with an RPM smaller than a target RPM of the first fan. The method of claim 13,
In the first fan control step, the RPM is gradually decreased until no headwind is detected in the second headwind detection step. The method of claim 14,
And controlling to start the second fan when the headwind is not detected in the second headwind detection step. The method according to any one of claims 3 to 6,
In the first fan control step, the RPM of the first fan is gradually increased to reach a target RPM of the first fan. The method of claim 16,
The stepwise increase of the RPM of the first fan is performed before the headwind is detected in the second headwind detection step. The method of claim 17,
And controlling to start the second fan when the headwind is not detected in the second headwind detection step. The method of claim 18,
In the first headwind detection step, when the current RPM of the first fan is greater than the target RPM of the first fan, it is determined that headwind is detected, and the control hold step is performed. delete delete delete delete

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