KR101274512B1 - Bldc motor type air conditioner control unit - Google Patents

Abstract

The present invention relates to an air conditioner fan coil control unit including a fan coil for heat exchange and having a motor for supplying air to the fan coil, wherein the motor is configured of a BLDC motor, and the BLDC motor is set in an air conditioner. In the initial operation to approach the room temperature is rotated at high speed, and when the room temperature is reached, the low-speed operation or the operation is stopped to be repeated, characterized in that to maintain a uniform room temperature,
By adopting BLC motor, it provides air conditioner and coil control unit, but when the room temperature is reached, the BLC motor is intermittently driven and stopped, and the wind speed and air volume can be adjusted in real time to maximize thermal efficiency. The present invention relates to a heating and cooling fan coil control unit using BCD motor that can be expected to be effective.

Description

Air-conditioner fan coil control unit using BCD motors {BLDC MOTOR TYPE AIR CONDITIONER CONTROL UNIT}

The present invention relates to a control unit of a fin coil applied to an air conditioner, and in detail, adopts a motor that allows heat to be exchanged by passing air to the fin coil side as a BLDC motor, the flow rate of the refrigerant flowing in the fin coil and By controlling the flow rate of the air passing through the coil to be linked proportionally by comparing the room temperature with the set temperature value, until the room temperature reaches the set temperature, the rotational ratio of the BLDC motor increases and the flow rate of the refrigerant flowing to the coil side. The opening angle of the modulating water valve is increased so as to increase, and from the moment the room temperature reaches the set temperature, the rotation ratio of the BLDC motor is shifted and decelerated, and the opening of the modulating water valve to control the flow rate of the refrigerant while controlling the air flow rate. By reducing the angle, the room temperature is always maintained without large displacement near the set temperature value. The present invention relates to a heating and cooling fan coil control unit using a BCD motor, which enables an increase in heat exchange efficiency and energy efficiency.

In general, an air conditioner is divided into a separate air conditioner separately installed in the indoor and outdoor spaces by separating the indoor unit and the outdoor unit, and an integrated air conditioner installed through the window or the wall by combining the indoor unit and the outdoor unit as a single device. As the cooling / heating capacity increases, the size of the indoor unit and the outdoor unit increases, and as the vibration generated by the outdoor unit increases as the compressor included in the outdoor unit operates, a large number of separate air conditioners are used.

The separate type air conditioner is installed indoors to allow heat exchange between the low temperature and low pressure gas refrigerant and the air to supply hot or cold air into the air conditioning space, and is installed outdoors to provide sufficient heat exchange operation in the indoor unit. It consists of an outdoor unit for compressing, condensing, and expanding the refrigerant to be made, the indoor unit and the outdoor unit has a conventional structure that is installed to be connected to each other by the refrigerant pipe.

Here, the indoor unit is an inner case formed with an inlet and an outlet for indoor air intake and discharge, and an evaporator installed inside the indoor case to allow heat exchange with air as the low temperature and low pressure gas refrigerant passes, and is installed on one side of the evaporator. The air is passed through the evaporator and consists of a coil and a motor to discharge the cold air back to the indoor side.

In the case of the motor, an AC motor is generally used. When the indoor temperature reaches a predetermined temperature, that is, the set temperature, the AC motor stops operating. When the temperature is out of the set temperature, the AC motor is operated again. The air sucked into the inlet is allowed to exchange heat through the evaporator.

As such, the AC motor repeats the operation on / off periodically or according to the variable speed of the room temperature, and the drive and stop are repeated to supply air to the coil side, and the room temperature is adjusted to the set temperature value. In this temperature change, as shown in FIG. 3, the temperature change is inevitably formed with a waveform.

Therefore, it has been pointed out that the waveform shape caused by the temperature variation causes not only an increase in driving power of the AC motor, but also a decrease in energy efficiency, and a problem in which noise is generated by driving the AC motor.

Therefore, the present invention has been made to solve the above problems, such as adopting a motor for supplying air to the heat exchanger side adopted in air-conditioners, such as an air conditioner as a BLDC motor, but the high speed of the motor until close to the indoor set temperature By increasing the flow of air by the rotation, and controlling the rotational speed of the motor when the room temperature reaches the set temperature, the low-speed rotation and the flow of the refrigerant flowing into the fan coil is also controlled to increase energy efficiency. Of course, the aim is to significantly reduce the noise of the air conditioners.

According to an aspect of the present invention,
In the air conditioner fan coil control unit including a fan coil for heat exchange and having a BLDC motor for supplying air to the fan coil,
The BLDC motor is to be rotated at high speed during the initial operation to approach the room temperature set in the air conditioner, and when the room temperature is reached, the low-speed operation or the state in which the operation is stopped is repeated to maintain a uniform room temperature. Including,
The refrigerant flowing in the shock coil and the rotational speed of the BLDC motor supplying air to the shock coil side are set to be proportional to each other.

The modulating water valve for controlling the flow rate of the refrigerant inside the coil coil is a room temperature read by the temperature sensor for measuring the room temperature is transmitted to the control unit, and then the control unit compares and analyzes the set temperature value and the room temperature, the set temperature It provides a heating and cooling fan coil control unit using a BLC motor, characterized in that the control of the opening angle of the modulating water valve to reach the value, and at the same time control the rotation ratio of the BLDC motor.

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According to the present invention, by adopting the BCD motor to provide a heating and cooling fan coil control unit, when the temperature reaches the indoor set temperature, the BLC motor is intermittently made and the wind speed and air volume can be adjusted in real time, so that the heat efficiency You can expect the effect to maximize the.

1 is a flowchart illustrating the present invention.
Figure 2 is a block diagram showing the flow between the configuration of the present invention
3 is a graph showing the displacement between the setting set temperature and the room temperature at the time of driving by an AC motor;
Figure 4 is a graph showing the displacement between the set setting temperature and the room temperature at the time of driving by the BLDC motor in the present invention

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The present invention, as shown in the drawing, adopts a general AC motor adopted in the air conditioner as a BLDC motor, configured to enable the control of the operation and stop of the BLDC motor, as well as the amount of air supplied to the coil side at the same time And to control the wind speed.

A normal air conditioner is provided with a fan coil for heat exchange, and has a circulation form in which air circulated from the room is introduced to the fan coil side and then supplied.

In addition, the present invention is to have a correlation between the modulating water valve 130 for controlling the flow of the refrigerant flowing through the BLDC motor 110 and shock coil 120 in the present invention.

For example, when the flow rate of the refrigerant flowing to the coil coil 120 is controlled to be small, the amount of air supplied from the BLDC motor 110 is controlled to be small, and the flow rate of the refrigerant flowing to the coil coil 120 is controlled. If the control to a large amount, it is preferable to control to increase the amount of air supplied from the BLDC motor 110.

As a variable for validating such a correlation, the sensing value of the temperature sensor 140 for measuring indoor temperature in real time is used as data.

The set temperature value T1 set by the user is input to the temperature sensor 140, and the temperature value of the room temperature T2 becomes a comparison value to be compared by the real-time temperature sensor 140.

As described above, the indoor temperature T2 monitors whether the set temperature value T1 is less than or equal to an abnormality while checking by the real-time temperature sensor 140, and transmits the comparison value to the controller 150, and receives the comparison value. One controller 150 controls the flow rate of the refrigerant flowing into the coil coil 120 by adjusting the opening angle of the modulating water valve 130.

Therefore, by adjusting the opening angle of the modulating water valve 130, it is possible to control the flow rate of the refrigerant flowing through the modulating water valve 130 to the coil coil 120 side.

For example, when the indoor temperature T2 is checked by the temperature sensor 140 to be lower than the set temperature T1, the signal is immediately transmitted to the controller 150 and the opening angle of the modulating water valve 130 is adjusted to be small. The flow rate of the refrigerant flowing into the coil coil 120 may be reduced, and the flow rate of the flow rate may be relatively decreased, thereby delaying the residence time of the refrigerant in the coil coil 120.

By controlling the flow rate and flow rate of the refrigerant, the residence time in the coil coil 120 is lengthened, and at the same time, as described above, the rotation speed of the BLDC motor 110 is slowly turned to increase the flow rate and flow rate of the air. By lowering, the room temperature T2 is allowed to reach the set temperature T1.

On the other hand, contrary to the above, when the room temperature T2 is higher than the set temperature T1, the signal is transmitted from the temperature sensor 140 to the control unit 150 and the opening angle of the modulating water valve 130 is increased. By adjusting to increase, the flow rate of the flow rate is relatively increased while the flow rate of the refrigerant flowing into the coil coil 120 increases.

At the same time, by controlling the controller 150 to increase the rotational speed of the above-described BLDC motor 110, the flow amount of air is increased.

The above description has been mainly focused on the operation of the air conditioner. Alternatively, the operation of the heater may allow the room temperature T2 to always be approximated to the set temperature T1 by the same operation.

According to the present invention, the BLDC motor 110, the temperature sensor 140, and the modulating water valve 130 are organically coupled to each other by the temperature measurement result of the temperature sensor 140. By controlling the rotation ratio and the opening angle of the modulating water valve 130, the flow rate and flow rate of the fluid flowing in the coil coil 120, that is, the refrigerant, and the flow rate and flow rate of the air passing through the coil coil 120 are active. It will be configured to control.

4 is a graph tracking the variation of temperature represented by such a correlation.

As shown in FIG. 4, during initial operation, the BLDC motor 110 is rapidly operated and the indoor temperature T2 is rapidly operated until the set temperature value T1 is reached, and the room temperature is set to the set temperature value T1 for a quick time. Allow (T2) to be reached.

As described above, when the rotation speed of the BLDC motor 110 is increased, the opening angle of the modulating water valve 130 that controls the flow amount of the refrigerant flowing inside the shock coil 120 is increased as described above. Since the control unit 150 controls the flow rate of the refrigerant, the flow rate of the air passing through the coil coil 120 also increases, so that the room temperature T2 is set within a short time to the set temperature value T2 in the cooling operation. Can be reached.

Thereafter, the control unit 150 controls the BLDC motor 110 to repeat the rotation and stop by sensing the temperature sensor 140 within the upper and lower range of the set temperature value (T1).

In addition, by controlling the rotation ratio of the BLDC motor 110, in addition to the control of the flow rate passing through the coil coil 120, the flow rate of the refrigerant flowing through the coil coil 120 is also linked to control the energy efficiency state having an optimum condition It will be possible to drive in.

100; Air conditioning unit 110; 휀 coil
120; Bitcoil 130; Modulating Water Valve
140; Temperature sensor 150; The control unit
T1; Set temperature value T2; Room temperature

Claims (3)

In the air conditioner fan coil control unit including a fan coil for heat exchange and having a BLDC motor for supplying air to the fan coil,
The BLDC motor is to be rotated at high speed during the initial operation to approach the room temperature set in the air conditioner, and when the room temperature is reached, the low-speed operation or the state in which the operation is stopped is repeated to maintain a uniform room temperature. Including,
The refrigerant flowing in the shock coil and the rotational speed of the BLDC motor supplying air to the shock coil side are set to be proportional to each other.
The modulating water valve for controlling the flow rate of the refrigerant inside the coil coil is a room temperature read by the temperature sensor for measuring the room temperature is transmitted to the control unit, and then the control unit compares and analyzes the set temperature value and the room temperature, the set temperature A heating / cooling fan coil control unit using a BLC motor, characterized by controlling the opening angle of the modulating water valve so as to reach a value, and simultaneously controlling the rotation ratio of the BLDC motor.
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