KR20000059889A - Apparatus for preventing an air conditioner from overload - Google Patents

Abstract

PURPOSE: A structure for preventing overload of a compressor of an air conditioner is provided to decrease an internal temperature of the compressor by supplying cool air passing though a scroll partially via an air channel, thereby preventing overload of the compressor. CONSTITUTION: A structure for preventing overload of a compressor of an air conditioner includes an air channel(355) formed at a predetermined position penetrating a wall surface of a scroll(340) corresponding to the compressor(310) for guiding cool air guided by the scroll to the compressor partially, a valve(350) mounted in a central part of the air channel for closing and opening the air channel to supply cool air to the compressor or stopping the supply, and a control part for supplying cool air to the compressor by opening the valve according to a control signal to prevent overload of the compressor in response to a signal applied from a temperature sensor(312) of the compressor if a temperature of the compressor is higher than a predetermined temperature, while closing the valve according to a control signal for conveying cool air along a normal path if lower.

Description

Compressor overload protection structure of air conditioner {APPARATUS FOR PREVENTING AN AIR CONDITIONER FROM OVERLOAD}

The present invention relates to an air conditioner, and more particularly, to a structure for preventing the overload of the compressor by lowering the internal temperature of the compressor by supplying a part of the cold air discharged from the evaporator to the compressor.

In general, an air conditioner is a device for maintaining a temperature and humidity suitable for the human body by conditioning air in a home or office. The air conditioner is operated so that the indoor temperature is approximately 28 ° C., the indoor humidity is approximately 60% to 75% in summer, and the indoor temperature is approximately 18 ° C., and the indoor humidity is approximately 55% to 70% in winter. do.

1 shows the internal structure of such an air conditioner 100. As shown, the air conditioner 100 is a compressor 110 for compressing the refrigerant gas to a high temperature and high pressure inside the main body 105 to perform a cooling cycle, the high temperature and high pressure refrigerant from the compressor 110 A condenser 115 for gradually condensing gas into a liquid phase through heat dissipation, an expansion valve 145 for lowering the pressure of the liquid refrigerant from the condenser 115 to form a low temperature gas-liquid mixed refrigerant, and the Evaporator 120 is provided to evaporate the low temperature gas-liquid mixed refrigerant to absorb ambient heat and to send the evaporated refrigerant back to the compressor 110.

The air conditioner 100 is separated into an outdoor side centered on the condenser 115 and an indoor side centered on the evaporator 120. The outdoor side and the indoor side are partitioned by a barrier wall. The motor assembly 125 having a rotating shaft protruding in both directions is mounted at an intermediate portion of the main body 105.

The fan 130 mounted at one side of the motor assembly 125 sends air to the condenser 115, and the blower 135 mounted at the other side sends air to the evaporator 120. The indoor air passes through the evaporator 120 and becomes low temperature air by heat exchange. The low temperature air is sent back to the room through the scroll 140 to maintain the room temperature at a predetermined temperature.

On the other hand, in the case of the compressor, when the temperature of the room rises above a predetermined temperature, there is a problem that the inside of the compressor becomes an overload state due to the operation over the prescribed temperature.

The present invention has been made to solve the above problems, an object of the present invention is to provide a structure to prevent the overload of the compressor by reducing the temperature of the compressor by supplying a part of the cold air passing through the evaporator to the compressor.

1 is a block diagram of a conventional window air conditioner.

Figure 2 is a structural diagram showing the interior of the air conditioner equipped with a nozzle for cooling the compressor according to the present invention.

<Explanation of symbols for main parts of drawing>

310: compressor 325: motor assembly

340: Scroll 350: 1-way valve

355: air passage

In order to achieve the above object, the present invention is a compressor equipped with a temperature sensor, located in the rear of the evaporator and the air conditioner comprising a scroll for guiding the cold air passing through the evaporator to the room, the wall surface of the scroll It is formed so as to correspond to the compressor by penetrating the wall surface at a predetermined position, and a part of the cold air guided by the scroll is guided to the compressor, and is mounted in the middle of the air flow path, thereby opening and closing the air flow path. A valve for supplying and stopping cold air to the compressor and a signal applied from a temperature sensor of the compressor, when the compressor is above a predetermined temperature, by supplying the cool air to the compressor by opening the valve by a control signal to overload the compressor Control when the compressor is below a predetermined temperature It provides a compressor overload protection structure of the air conditioner provided by the call control unit for sending the cool air to be By closing the valve to its normal path.

According to the invention, the air flow passage is formed to correspond to the upper end of the compressor. The valve is also a one-way valve. The present invention has the advantage of preventing the overload of the compressor by lowering the internal temperature of the compressor when the compressor is overloaded by supplying the cold air passing through the scroll through the air flow path to the compressor.

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

In general, an air conditioner is a device for maintaining a temperature and humidity suitable for the human body by conditioning air in a home or office. The air conditioner is operated so that the indoor temperature is approximately 28 ° C., the indoor humidity is approximately 60% to 75% in summer, and the indoor temperature is approximately 18 ° C., and the indoor humidity is approximately 55% to 70% in winter. do.

2 is a structural diagram showing the interior of an air conditioner equipped with a nozzle for cooling a compressor according to the present invention.

As shown, the air conditioner 300 heats the high temperature and high pressure refrigerant gas from the compressor 310 and the compressor 310 for compressing the refrigerant gas to the high temperature and high pressure in the body to perform a cooling cycle. A condenser 315 for gradually condensing into the liquid phase through discharge, an expansion valve 345 for lowering the pressure of the liquid refrigerant from the condenser 315 to form a low temperature gas-liquid mixed refrigerant, and the low temperature gas -An evaporator 320 which evaporates the liquid mixed refrigerant to absorb ambient heat and sends the evaporated refrigerant back to the compressor 310.

The air conditioner 300 is separated into an outdoor side centered on the condenser 315 and an indoor side centered on the evaporator 320. The outdoor side and the indoor side are partitioned by a barrier wall. The motor assembly 325 having a rotating shaft protruding in both directions is mounted at the middle of the main body.

The fan 330 mounted at one side of the motor assembly 325 sends air to the condenser 315, and the blower 335 mounted at the other side sends air to the evaporator 320. The indoor air passes through the evaporator 320 and becomes cold air by heat exchange. The cold air is sent back to the room through the scroll 340 to maintain the room temperature at a predetermined temperature.

The scroll 340 is disposed at the rear of the evaporator 320 to guide the cold air supplied to the room through the evaporator 320 by a blower.

On the other hand, the compressor 310 sucks the refrigerant of low temperature and low pressure, compresses it to a state of high temperature and high pressure by a piston and supplies it to the condenser 315. The outlet side of the compressor 310, that is, the upper portion of the compressor 310 is in a high temperature state. Therefore, when an overload occurs in the compressor 310 and the temperature therein rises above a predetermined temperature, it is necessary to appropriately lower the internal temperature of the compressor 310. The temperature sensor 312 for checking the internal temperature of the compressor 310 is mounted on the compressor 310. The temperature sensor is connected to a control unit (not shown) of the air conditioner 300.

Since the compressor 310 is disposed at the rear of the scroll 340, the compressor 310 is supplied by supplying a part of the cold air passing through the scroll 340 to the surface of the compressor 310 so that the compressor 310 is not overheated. The temperature of the 310 is prevented from rising above the predetermined temperature.

An air flow passage 355 penetrating the wall of the scroll 340 is formed. The air passage 355 is preferably formed at a position corresponding to the upper portion of the compressor 310. The 1-way valve 350 is mounted in the middle of the air passage 355. The one-way valve 350 opens and closes the air passage 355 to supply cool air from the scroll 340 to the compressor 310.

Since the air passing through the scroll 340 is in a low temperature state while passing through the evaporator 320, the compressor 310 may be cooled.

When the temperature of the compressor 310 is determined to be higher than or equal to a predetermined temperature by a signal applied from the temperature sensor of the compressor 310 by the control unit of the air conditioner 300, the control unit may control the one-way valve 350. To open. Thus, the cold air passing through the scroll 340 is supplied to the upper roll of the compressor 310 through the air flow passage 355. The upper end of the compressor 310 may be cooled to a predetermined temperature by the cold air. Therefore, since the internal temperature of the compressor 310 is lowered, the overload of the compressor 310 is also prevented.

On the other hand, when the temperature of the compressor 310 is normal, the control unit closes the one-way valve 350. When the one-way valve 350 is closed, the supply of cold air supplied to the compressor 310 through the air flow passage 355 is stopped. Thus, cold air is supplied to the room through the normal path.

As described above, there is an advantage of preventing the overload of the compressor by lowering the internal temperature of the compressor when the compressor is overloaded by supplying the cool air passing through the scroll to the compressor through the air flow path.

Although the present invention has been described based on the preferred embodiments, various modifications and improvements can be made within the scope of the technical idea of the present invention, and those skilled in the art will recognize that such variations and improvements also belong to the present invention. .

Claims (3)

In the air conditioner comprising a compressor equipped with a temperature sensor, located on the rear of the evaporator and a scroll for guiding the cold air passing through the evaporator to be sent to the room, An air passage formed to correspond to the compressor by penetrating the wall at a predetermined position of the wall surface of the scroll, and a part of the cold air guided by the scroll being guided to the compressor; A valve mounted to an intermediate portion of the air passage, for supplying and stopping cold air to the compressor by opening and closing the air passage; When the compressor is above a predetermined temperature by a signal applied from the temperature sensor of the compressor, by supplying cool air to the compressor by opening the valve by a control signal to prevent overload of the compressor, when the compressor is below a predetermined temperature Compressor overload protection structure of the air conditioner, characterized in that it comprises a control unit for discharging the cool air in a normal path by closing the valve by a control signal. The compressor overload protection structure of an air conditioner of claim 1, wherein the air flow path is formed to correspond to an upper end of the compressor. 3. The compressor overload protection structure of claim 2, wherein the valve is a one-way valve.