KR20110029579A - Heat pump dryer and heat pump dryer control method - Google Patents

Abstract

PURPOSE: A drying machine using a heat pump and a control method thereof are provided to rapidly increase the refrigerant condensation temperature of a condenser and the refrigerant evaporation temperature of an evaporator. CONSTITUTION: A drying machine using a heat pump comprises a drum(100), a duct(300), a heat pump(400), and a wind distribution unit. The drum comprises a drying chamber. The duct is connected to the drying chamber and guides air circulating by a blower. The heat pump is installed in the duct and comprises an evaporator, a compressor, and a condenser. The wind distribution unit selectively circulates air, passing through the condenser, to the drying chamber or the evaporator.

Description

Drying machine of use heat pump and method of controlling the same}

The present invention relates to a heat pump type dryer and a heat pump type dryer control method for rapidly increasing a refrigerant condensation temperature of a condenser and a refrigerant evaporation temperature of an evaporator at an initial startup of a dryer.

The heat pump type clothes dryer (Korean Patent No. 737006), which performs dehumidification and heating of circulating air using a conventional heat pump, installs an electric heater between the condenser and the drum for drying clothes, By using the second evaporator to circulate and the method of supplying the required amount of heat by controlling the refrigerant switching between the first evaporator and the second evaporator, the temperature of the air radiated from the condenser reaches a predetermined temperature (45 to 65 ° C.). Be sure to

However, in the related art, the cost has increased due to the increase in the number of evaporators, and if the outside air is low, the temperature is entirely dependent on the heat transfer heater, so there is a problem that a fire, a cost increase, and an additional controller for controlling the same are required.

In addition, when the outside air temperature decreases, the design temperature of the condenser and the evaporator (high temperature low required for drying clothes) is reduced by the amount of heat transferred through the dry matter contained in the drum, cold water penetrated between the fiber of the dry matter, and the inner area in contact with the circulating air. There was a problem in that the formation of wet air) is delayed or is not possible at all.

The present invention is to solve the above-mentioned problems, to provide a heat pump type dryer and a heat pump type control method for controlling the refrigerant condenser temperature and the evaporator refrigerant evaporation temperature of the condenser at a rapid time during the initial startup of the dryer. There is a purpose.

In order to achieve the above object, the heat pump type dryer of the present invention comprises a drum provided with a drying chamber; A duct communicating with the drying chamber and guiding air circulated by a blower; A heat pump installed on the duct, the heat pump including an evaporator, a compressor for compressing a refrigerant passing through the evaporator, and a condenser for dissipating heat of the refrigerant passing through the compressor; And an air volume distribution mechanism for selectively circulating air passing through the condenser to the drying chamber or the evaporator.

In addition, in the heat pump type dryer of the present invention, the air volume distribution mechanism, the bypass duct for branching the duct; And a valve for regulating the amount of air introduced into the bypass duct.

According to this structure, the high temperature dry air which passed the condenser of the heat pump is circulated to the evaporator without passing through the drying chamber.

On the other hand, in the heat pump type dryer control method of the present invention, the amount of air flowing into the evaporator through the bypass duct branching the duct is larger than the amount of air in the duct after passing through the condenser. Controlling; Determining whether the refrigerant evaporation temperature and the refrigerant condensation temperature of the heat pump have reached the first design temperature; And controlling the amount of air flowing into the evaporator through the bypass duct when the refrigerant evaporation temperature and the refrigerant condensation temperature of the heat pump reach the first design temperature.

In addition, the heat pump type dryer control method of the present invention, the temperature sensing step of sensing the temperature of the air entering the drying chamber; Entering into the evaporator via the bypass duct in inverse proportion to the difference between the second design temperature and the air temperature detected in the temperature sensing step until the temperature of the air sensed in the temperature sensing step reaches a second design temperature. And controlling to reduce the amount of air that is made.

As described above, the heat pump type dryer and the heat pump type dryer control method have the following advantages.

During the initial start-up of the dryer, the hot and dry air that has passed through the condenser of the heat pump can be circulated directly to the evaporator without passing through the drying chamber, thereby increasing the refrigerant condensation temperature of the condenser and the refrigerant evaporation temperature of the evaporator in a short time. It can provide stable dry air volume and temperature after time.

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

For reference, among the configurations of the present invention to be described below, the same configuration as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

The heat pump type dryer of the present invention includes a drum 100 having a drying chamber 110, a duct 300 communicating with the drying chamber 110 and guiding air circulated by the blower 200, and the duct. Is installed on the 300, the evaporator 410, a compressor 420 for compressing the refrigerant passing through the evaporator 410, and a condenser 430 for radiating heat of the refrigerant passing through the compressor 420 It comprises a heat pump 400 and a air flow distribution mechanism for selectively circulating the air passing through the condenser 430 to the drying chamber 110 or the evaporator 410.

The air volume distribution mechanism includes a bypass duct 500 for branching the duct 300, and a valve 550 for controlling an amount of air flowing into the bypass duct 500.

The duct 300 is installed on one side and the other side of the drum 100 provided with the drying chamber 110 to communicate with each other.

The drying chamber 110 accommodates a dry item such as clothing.

The duct 300 is provided with a blower 200 for circulating air into the duct 300.

On the duct 300, a heat including an evaporator 410, a compressor 420, a condenser 430, an expansion device 440, and a refrigerant passage 450 through which the refrigerant moves by connecting the same. Pump 400 is installed.

On the other hand, the outlet 600 is installed in the evaporator 410 of the heat pump 400, the condensed water formed by condensation of water through the outlet 600 is discharged.

The bypass duct 500 is between the condenser 430 of the heat pump 400 and the duct 300 connecting the drying chamber 110 and the evaporator 410 of the drying chamber 110 and the heat pump 400. It is installed between the duct 300 to connect, branching the duct 300.

At this time, the valve 550 is installed at the intersection of the bypass duct 500 and the duct 300.

Therefore, the air circulating through the duct 300 can be selectively circulated to the drying chamber 110 or the bypass duct 500 by the valve 550.

For example, when the duct 300 is closed by the valve 550, air circulating through the duct 300 flows into the bypass duct 500, and when the bypass duct 500 is closed by the valve 550. Air circulating through the duct 300 is circulated through the drying chamber 110.

In this case, the amount of air circulated to the drying chamber 110 or the bypass duct 500 may be adjusted according to the degree of opening and closing of the valve 550.

The valve 550 is preferably controlled by a separate control unit.

On the other hand, the duct 300 is provided with a temperature sensor 900 for detecting the temperature of the air circulating in the duct 300.

The temperature sensor 900 is preferably installed at the inlet side of the drying chamber 110 to detect the temperature of the air flowing into the drying chamber 110.

On the other hand, the heat pump type dryer control method of the present invention controls the amount of air flowing into the evaporator through the bypass duct branching the duct than the amount of air in the duct after passing through the condenser to the drying chamber. And determining whether the refrigerant evaporation temperature and the refrigerant condensation temperature of the heat pump have reached the first design temperature (S20), and the refrigerant evaporation temperature and the refrigerant condensation temperature of the heat pump are the first design. When the temperature is reached, a step (S30) of controlling to reduce the amount of air flowing into the evaporator through the bypass duct is configured.

By the step S10, the refrigerant evaporation temperature and the refrigerant condensation temperature of the heat pump can be quickly reached to the first design temperature at the initial startup of the dryer.

The first design temperature is a refrigerant evaporation temperature of the evaporator and a refrigerant condensation temperature of the condenser capable of exchanging the air passing through the evaporator and the condenser with high temperature and low humidity air required for drying clothes.

The first design temperature can be determined by experiments, it consists of about 45 ~ 65 ℃.

When the refrigerant evaporation temperature and the refrigerant condensation temperature of the heat pump reach the first design temperature, the amount of air flowing into the evaporator through the bypass duct 500 is reduced to increase the high temperature passing through the evaporator 410 and the condenser 430. Since low-humidity air is circulated to the drying chamber 110, drying of the dry matter contained in the drying chamber 110 is performed very quickly.

On the other hand, the heat pump type dryer control method of the present invention, the temperature sensing step (S40) for detecting the temperature of the air flowing into the drying chamber, and when the temperature of the air detected in the temperature sensing step reaches the second design temperature And controlling to reduce the amount of air introduced into the evaporator through the bypass duct in inverse proportion to the difference between the second design temperature and the detected air temperature in the temperature sensing step (S50). .

That is, when there is a large difference between the temperature detected in the temperature sensing step (S40) and the second design temperature, the amount of air introduced into the evaporator 410 through the bypass duct 500 is reduced, and the air flowing into the drying chamber 110 is reduced. Increasing the amount of, to dry the dry matter accommodated in the drying chamber 110 with high temperature and low humidity air required for drying clothes.

When the difference between the temperature detected in the temperature sensing step (S40) and the second design temperature is small, the amount of air introduced into the evaporator 410 via the bypass duct 500 is increased, and the air introduced into the drying chamber 110. By reducing the amount, the refrigerant evaporation temperature of the evaporator and the refrigerant condensation temperature of the condenser are increased to the first design temperature for heat exchange with the high temperature and low humidity air required for drying clothes.

Accordingly, the amount of air introduced into the evaporator 410 through the bypass duct 500 may be controlled according to the difference between the temperature sensed in the temperature sensing step S40 and the second design temperature, thereby stably driving the dryer. have.

The second design temperature is the temperature of the air required for drying the object accommodated in the drying chamber.

The second design temperature can be determined by experiments, and consists of about 45 ~ 65 ℃.

Hereinafter, the operation of the heat pump dryer of the present invention configured as described above will be described.

First, the dry matter is put into a drying chamber 110 of a heat pump type dryer and power is supplied.

When power is supplied, the blower 200 and the heat pump 400 are operated.

When the blower fan 200 operates, the air in the duct 300 circulates through the heat pump 400 and the drying chamber 110.

The high temperature and high pressure refrigerant compressed by the compressor 420 of the heat pump 400 moves to the condenser 430 through the refrigerant pipe 450 to dissipate heat of the refrigerant.

The refrigerant passing through the condenser 430 is reduced in pressure while passing through the expansion device 440.

The refrigerant decompressed through the expansion device 440 moves to the evaporator 410.

The low temperature low pressure refrigerant passing through the evaporator 410 is moved back to the compressor 420.

The high temperature dry air passing through the condenser 430 of the heat pump 400 moves to the drum 100 provided with the drying chamber 110.

The air moved to the drying chamber 110 absorbs moisture of the dry matter.

The hot and humid air absorbing the moisture of the dry matter moves to the evaporator 410 of the heat pump 400.

The air passing through the evaporator 410 is cooled by the evaporator 410 to become low temperature dry air.

At this time, when the temperature of the air is cooled by the evaporator 410, moisture inside the air condenses and condenses on the surface of the evaporator 410.

The condensed water condensed in this way is discharged to the outside through the discharge port 600 installed in the evaporator 410.

Thereafter, the low temperature dry air is recirculated to the drying chamber 110 through the condenser 430 to become high temperature dry air again.

At initial startup of the dryer, the duct 300 is blocked by the valve 550 to reduce the amount of air directed to the drying chamber 110, and the bypass duct 500 is opened to allow the air to flow into the bypass duct 500 relatively. The amount is increased to circulate the hot and dry air passing through the condenser 430 to a portion of the evaporator 410.

As a result, the amount of air circulating between the condenser 430 and the evaporator 410 increases, so that the refrigerant condensation temperature of the condenser and the refrigerant evaporation temperature of the evaporator can be increased in a short time.

By such a configuration, the heat pump type dryer of the present invention can increase the refrigerant condensation temperature of the condenser and the refrigerant evaporation temperature of the evaporator in a short time without a separate heater and additional evaporator for heating the air passing through the condenser 430. Therefore, the configuration can be made very simple, so that the cost can be reduced.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or variations of the present invention without departing from the spirit and scope of the invention described in the claims below Can be carried out.

The present invention can be used in a heat pump type dryer.

Figure 1 schematically shows a heat pump type dryer of the present invention.

2 to 3 is a flow chart showing a heat pump type dryer control method of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: drum 110: drying chamber 200: blower

300: duct 400: heat pump 410: evaporator

420: compressor 430: condenser 440: expansion device

450: refrigerant pipe 500: bypass duct 550: valve

900: temperature sensor

Claims (4)

A drum provided with a drying chamber; A duct communicating with the drying chamber and guiding air circulated by a blower; A heat pump installed on the duct, the heat pump including an evaporator, a compressor for compressing a refrigerant passing through the evaporator, and a condenser for dissipating heat of the refrigerant passing through the compressor; And a air flow rate distribution mechanism for selectively circulating the air passing through the condenser to the drying chamber or the evaporator. The method of claim 1, The air volume distribution mechanism, A bypass duct branching the duct; And a valve for regulating the amount of air introduced into the bypass duct. After passing through the condenser, controlling the amount of air entering the evaporator through the bypass duct branching the duct than the amount of air in the duct to the drying chamber; Determining whether the refrigerant evaporation temperature and the refrigerant condensation temperature of the heat pump have reached the first design temperature; And controlling the amount of air flowing into the evaporator through the bypass duct when the refrigerant evaporation temperature and the refrigerant condensation temperature of the heat pump reach the first design temperature. The method of claim 3, wherein A temperature sensing step of sensing a temperature of air introduced into the drying chamber; Entering into the evaporator via the bypass duct in inverse proportion to the difference between the second design temperature and the air temperature detected in the temperature sensing step until the temperature of the air sensed in the temperature sensing step reaches a second design temperature. And controlling the amount of air to be reduced.

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