KR100434069B1 - Dehumidifying operation control method for air conditioner - Google Patents

Abstract

The present invention relates to a dehumidifying operation method of the air conditioner, by controlling the speed of the vane moving in the upper inlet direction faster than the speed of the vane moving in the downward direction to generate the vortex so that the discharged humid air is sucked back to dehumidification It is. To this end, the present invention provides an air conditioner, comprising: a first process of selecting, by a user, a dehumidification mode; If the dehumidification mode is selected, the second step of moving the cooling air near the discharge port in the direction of the suction port by controlling the rising speed and the lowering speed of the up and down wind vane differently while operating the cooling capacity to the minimum; In the second process, a third process of inhaling and dehumidifying the cold air moved in the direction of the suction port is performed.

Description

Dehumidification operation method of air conditioner {DEHUMIDIFYING OPERATION CONTROL METHOD FOR AIR CONDITIONER}

The present invention relates to a dehumidifying operation method of an air conditioner, and in particular, in the dehumidification mode, the humid air discharged by generating a vortex by controlling the speed of the vane moving in the direction of the upper suction port faster than the speed of the vane moving in the downward direction is generated again. It relates to a dehumidification operation method of the air conditioner inhaled to be dehumidified.

In general, an air conditioner includes a cooling device for cooling indoor hot air and supplying it to the room, and a heating device for supplying indoor cooling air to the room.

Recently, an air conditioner having a constant temperature dehumidification function as well as the above cooling and heating functions has been developed and marketed. The air conditioner having the constant temperature dehumidification function will be described with reference to the accompanying drawings.

1 is a schematic view showing a configuration of a general air conditioner, as shown in the compressor to make a high-temperature, high-pressure steam by sucking and compressing the low-temperature, low-pressure refrigerant vapor discharged from the indoor heat exchanger (1) )Wow; An outdoor heat exchanger (2) for dissipating heat of the high-temperature, high-pressure refrigerant vapor discharged from the compressor (1) into water or air, and converting it into a high-pressure saturated liquid; An indoor heat exchanger (3) for sucking the high pressure saturated liquid discharged from the outdoor heat exchanger (2) into a refrigerant having a low temperature and a low pressure through an expansion device (4) and evaporating it to a saturated steam without liquid content; Four sides (8) for controlling the flow of the refrigerant in accordance with the heating mode or cooling mode; At the time of constant temperature dehumidification, it consists of an anisotropic side (B1) for discharging the high-pressure refrigerant as it is to the indoor heat exchanger (3).

The indoor heat exchanger (3) comprises: a first heat exchanger (3-1) for discharging a high pressure liquid by sucking a refrigerant mixed with a high pressure liquid and a gas during constant temperature dehumidification; An expansion device (5) for dropping the high pressure liquid of the first heat exchanger (3-1) to a low pressure liquid; A second heat exchanger (3-2) which sucks the refrigerant mixed with the low pressure liquid and the gas through the expansion device 5 and evaporates it to discharge the low temperature / low pressure refrigerant having no liquid content; At the time of constant temperature dehumidification, it consists of an anisotropic side (B2) that blocks the high-pressure liquid discharged from the first heat exchanger (3-1) directly discharged to the second heat exchanger (3-2), Describe the operation.

First, in the heating mode, the high temperature and high pressure refrigerant compressed by the compressor (1) flows through the four sides (8) to the indoor heat exchanger (3) to condense, and then passes through the expansion device (4), the low temperature and low pressure refrigerant It becomes

At this time, the indoor air sucked by the indoor fan 7 is heat-exchanged while passing through the surface of the indoor heat exchanger 3 to blow out the hot air into the room, thereby raising the temperature of the room.

Here, the indoor heat exchanger (3) opens the anisotropic side (B2) between the first heat exchanger (3-1) and the second heat exchanger (3-2) so that the indoor heat exchanger (3) operates as a condenser. do.

Thereafter, the outdoor heat exchanger (2) sucks the low temperature low pressure refrigerant and evaporates it to discharge the gaseous refrigerant, and the compressor (1) sucks the gaseous refrigerant discharged from the outdoor heat exchanger (3). This is compressed to a high temperature and high pressure refrigerant, heating operation is performed by repeating this operation.

In the cooling mode, the high temperature and high pressure refrigerant compressed by the compressor (1) flows in all directions to the outdoor heat exchanger (2), condenses, passes through the expansion device (4), and becomes a low temperature and low pressure refrigerant.

Thereafter, the indoor heat exchanger (3) sucks the refrigerant at low temperature and low pressure and evaporates it to discharge the refrigerant in the gas state, and the compressor (1) sucks the refrigerant in the gas state discharged from the indoor heat exchanger (3). This is compressed again to a high temperature and high pressure refrigerant.

At this time, the indoor heat exchanger 3 opens the anisotropic side B2 between the first heat exchanger 3-1 and the second heat exchanger 3-2 so that the indoor heat exchanger 3 operates as an evaporator. do.

Here, the indoor air sucked by the indoor fan (7) is heat-exchanged while passing through the cold surface of the indoor heat exchanger (3) to eject cold air into the room, thereby lowering the temperature of the room.

Meanwhile, during constant temperature dehumidification. The high temperature and high pressure refrigerant compressed by the compressor (1) passes through the four sides (8) and flows into the outdoor heat exchanger (2). At this time, the outdoor fan (6) rotates at a small rotational speed so that the high temperature and high pressure refrigerant is hardly cooled. Pass through the anisotropy (B1) in the state it does not flow into the indoor heat exchanger (3).

Thereafter, the indoor heat exchanger 3 cuts off the internal anisotropy B2 and separates the first heat exchanger 3-1 and the second heat exchanger 3-2 from each other.

That is, the first heat exchanger 3-1 inhales cold air mixed with a high pressure liquid and a gas to discharge heat to discharge the high pressure liquid, and the second heat exchanger 3-2 performs the first heat exchanger. The high pressure liquid discharged from (3-1) is sucked into the low pressure liquid through the expansion device 5 and evaporated to discharge the low temperature / low pressure refrigerant having no liquid content.

At this time, after the indoor air sucked by the indoor fan 7 passes through the cold surface of the second heat exchanger 3-2 and the moisture is removed, the dried air is removed from the first air. It is heated while passing through the hot surface of the heat exchanger 3-1, and is ejected to the room.

During the constant temperature dehumidification, the second heat exchanger 3-2 inhales and dehumidifies the cold air discharged through the discharge port. As shown in FIG. 2, the amount of cold air sucked into the suction port through the discharge port is almost constant, and thus, a certain degree or more. There is a problem that does not improve the dehumidification efficiency.

The present invention has been made to solve the above problems, in the dehumidification mode by controlling the speed of the vane moving in the direction of the upper suction port faster than the speed of the vane moving in the downward direction, the dehumidification efficiency by suctioning the discharged humid air again It is an object of the present invention to provide a dehumidifying operation method of the air conditioner to improve the.

1 is a block diagram showing the configuration of a conventional air conditioner.

Figure 2 is a schematic diagram showing the flow of cold air discharged through the discharge port.

Figure 3 is an operation flow chart for a dehumidifying operation method of the air conditioner of the present invention.

Figure 4 is a schematic diagram showing the rise / fall of the up and down wind vane in Figure 3;

Figure 5 is a schematic diagram showing the state of the cold air sucked into the inlet in Figure 3;

** Explanation of symbols for main parts of drawings **

1: compressor 2: outdoor heat exchanger

3: indoor heat exchanger 3-1: first heat exchanger

3-2: second heat exchanger 4, 5: expansion device

6: Outdoor fan 7: Indoor fan

8: Quadrilateral B1, B2: Anisotropic

According to an aspect of the present invention, there is provided an air conditioner, including: a first process of selecting a dehumidifying mode by a user; If the dehumidification mode is selected, the second step of moving the cooling air near the discharge port in the direction of the suction port by controlling the rising speed and the lowering speed of the up and down wind vane differently while operating the cooling capacity to the minimum; And a third process of inhaling and dehumidifying the cold air moved in the direction of the inlet in the second process.

Hereinafter, with reference to the accompanying drawings, the operation and effects of the dehumidification operation method of the air conditioner according to the present invention will be described in detail.

3 is a flowchart illustrating an operation method of the dehumidification operation of the air conditioner of the present invention, the first process of selecting a dehumidification mode by a user as shown in the drawing; If the dehumidification mode is selected, the second step of moving the cooling air near the discharge port in the direction of the suction port by controlling the rising speed and the lowering speed of the up and down wind vane differently while operating the cooling capacity to the minimum; It consists of a third process of dehumidifying by sucking the cold air moved in the direction of the inlet in the second process, in the description of the operation of the present invention, the general refrigeration cycle is the same as in the prior art and will be omitted.

In the constant temperature dehumidification operation, the present invention provides a short circuit operation in which cold air is sucked back into the inlet port of the second indoor heat exchanger so as to move the ascending speed of the up and down wind vane at a higher speed than the descending speed so as to be lower than before. Control, which will be described in detail with reference to FIG.

First, when the dehumidification mode is selected by the user, the vortex near the discharge port is moved in the direction of the suction port by controlling the rising speed and the lowering speed of the up and down wind vane differently while operating the cooling capacity to the minimum.

Then, while the amount of cold air flowing into the suction port is increased, the amount of cold air discharged into the room is reduced, thereby improving the temperature and dehumidification ability.

In the above, if the suction port is located above the discharge port, as shown in Figure 4 it is controlled to move the rising speed of the up and down wind vane relatively faster than the falling speed.

At this time, the up and down wind vane is moved up by 7 degrees per second and the down speed is moved by 15 degrees per second.

On the other hand, if the suction port is located below the discharge port, it controls to move the descending speed of the up and down wind vane relatively fast.

At this time, the descending speed of the up and down wind vane is moved by 7 degrees per second, the rising speed is moved by 15 degrees per second.

In other words, in the present invention, the vortex is generated by the discharge airflow by varying the rotational speed of the up-and-down wind vane. When the ascending speed is moved at a higher speed than the descending speed, the vortex generated near the discharge port is discharged at the discharge port as shown in FIG. The cold air flow discharged from the discharge port by the vortex becomes longer as it moves upward, and the time for staying near the suction port becomes longer. As the amount of is reduced, the dehumidification efficiency is increased.

As described in detail above, the present invention, in the dehumidification mode, by controlling the speed of the vane moving in the direction of the upper suction port faster than the speed of the vane moving in the downward direction, the amount of cold air discharged into the room is reduced, Increasing the suction amount has the effect of improving the dehumidification efficiency.

Claims (10)

In air conditioners, A first step of selecting, by the user, a dehumidification mode; If the dehumidification mode is selected, the second step of moving the cooling air near the discharge port in the direction of the suction port by controlling the rising speed and the lowering speed of the up and down wind vane differently while operating the cooling capacity to the minimum; The dehumidification operation method of the air conditioner, characterized in that performed in a third process of sucking and dehumidifying the cold air moved in the direction of the inlet in the second process. The dehumidifier of the air conditioner according to claim 1, wherein the ascending speed and the descending speed of the up-and-down wind vane are controlled to be relatively different in speed depending on the positions of the discharge port through which cold air is discharged and the suction port through which the indoor air is sucked. How to operate. The dehumidification operation method of an air conditioner according to claim 1 or 2, wherein the up-and-down wind vane performs a reciprocating motion within a predetermined angle. delete The dehumidification operation method of an air conditioner according to claim 2, wherein when the discharge port is located above the suction port, the descending speed of the up-and-down wind vane is controlled relatively faster than the rising speed. delete delete The dehumidification operation method of an air conditioner according to claim 2, wherein when the discharge port is located below the suction port, the rising speed of the up-and-down wind vane is controlled to be faster than the falling speed. delete delete