KR200146103Y1 - Evaporator of indoor machine in airconditioner - Google Patents

Abstract

An evaporator of an indoor unit for an air conditioner according to the present invention includes a plurality of refrigerant inlet and outlet tubes for introducing and discharging a refrigerant into an evaporator, wherein the outdoor unit is connected to an outdoor unit along a refrigerant inlet and an outlet pipe. Evaporated water generated by the temperature difference of the air in the evaporator 70 at the same time as the refrigerant flowing out through the plurality of refrigerant outlet pipes 76 connected to 70 to collect in one place to the refrigerant flow pipe 78 The present invention is characterized in that the distributor 79 is provided at the vertical bottom of the refrigerant inlet and outlet pipes 75 and 76 of the evaporator 70 so that the W is dropped toward the evaporator 80. There is an effect of preventing the electrical leakage caused by the immersion of other parts by.

Description

Evaporator of indoor unit for air conditioner

The present invention relates to an evaporator of an indoor unit for an air conditioner, and in particular, to collect the evaporated water generated from the evaporator in one place and drain it to the evaporative water receiver to prevent the leakage of other parts by the evaporated water. It relates to an evaporator of an indoor unit.

In general, air conditioners are classified into various types according to their function or configuration of the unit. In the classification by function, the air conditioners can be classified into cooling only, cooling and dehumidification only, and cooling and heating. And an integrated air conditioner integrated with a heat dissipation function and installed in a window or the like, and a separate type air conditioner for separately installing a cooling device on an indoor side and a heat radiating and pressing device on an outdoor side.

The air-conditioning combined air conditioner is an indoor unit installed indoors and an outdoor unit installed outdoors, and can be heated and cooled as needed.

As shown in FIG. 1 and FIG. 2, generally, the indoor unit 10 for the air conditioner is combined with the front panel 20 and the rear panel 30 to form an exterior thereof.

On the front of the front panel 20, the front grill 40, which can be opened and closed to facilitate the exchange and repair of parts in the indoor unit 10, is formed by forming a plurality of inlets 41, and the front panel ( The lower portion of the 20 is formed with a discharge port 50 for the indoor air is heat-exchanged in the indoor unit 10 to discharge the cold air back to the room.

In addition, the inside of the indoor unit 10 and the air filter 60 for filtering the foreign matter floating in the indoor air sucked through the inlet 41 of the front grill 40 and the air filter 60, An evaporator 70 for heat-exchanging the filtered indoor air with cold air, an evaporator receiving 80 collecting the evaporated water generated from the evaporator 70 at a lower portion of the evaporator 70 and draining it to the outside; It is bound to the lower end of the evaporation receiver 80 to power the wind direction left and right and up and down control member 90, 91 to adjust the wind direction to the left and right and up and down respectively when discharging the air introduced through the suction port 41 The indoor air is sucked through the inlet port 41 at the rear side of the evaporator 70 while providing the motor 92 and the cold air heat-exchanged by the evaporator 70 through the discharge port 50. Rotated by the fan motor 101 to be discharged to The blower fan 100 and the front of the evaporator 70 are supplied with high pressure electricity from the high pressure generator 130 to adsorb and remove finely ionized dust that is decomposed finely by high-pressure discharge waves while carrying a charge. The dust collector fixing member 110 for inserting the dust collector 120 is installed.

As shown in FIG. 3 and FIG. 4, the evaporator 70 maintains a predetermined interval on both sides thereof and is mounted on the rear panel 30 via mounting holes 71a formed at one side thereof. Two brackets 71, a plurality of heat transfer fins 72 arranged in parallel at regular intervals between the two brackets 71, and a coolant flows therein and at the same time A plurality of refrigerant pipes 73 inserted and arranged in a vertical zigzag direction perpendicular to the bracket 71 and the plurality of heating fins 72 so that a temperature is conducted to the plurality of heating fins 72, and the bracket ( A return bend tube 74 which is fixed to one end of each of the two refrigerant tubes 73 in pairs so as to connect the plurality of refrigerant tubes 73 protruding out of the 71 into one passage; With respect to the bracket 71 and the plurality of heat transfer fins 72 so that the Refrigerant inlet pipe (75) arranged in the upper portion of the return bend pipe (74) while being inserted in each direction and flow direction downward, and the bracket 71 and the plurality of heat transfer fins 72 so that the refrigerant flows out And a refrigerant outlet pipe 76 arranged at an upper portion of the return bend tube 74 having an airflow direction flowing therein while being inserted in a direction perpendicular to the direction, so that refrigerant flows into the refrigerant inlet pipe 75 from an outdoor unit (not shown). The connected refrigerant inlet pipe 77 and the refrigerant introduced through the refrigerant inlet pipe 75 flow through the plurality of refrigerant tubes 73 and the return bend tube 74 to exchange heat with indoor air, and the refrigerant outlet tube 76 It is composed of a refrigerant outflow pipe (78) connected to be introduced again to the outdoor unit through).

However, the evaporator of the indoor unit for the air conditioner configured as described above forms water droplets on the outer circumferential surfaces of the refrigerant inlet and outlet tubes 75 and 76 of the evaporator 70 by the evaporation action, and the water droplets are transferred to the evaporation receiver 80. Although it is supposed to be drained, the evaporated water (W) is not all drained into the evaporator 80, there is a problem that the electric leakage phenomenon occurs to fall to the lower part of the evaporator (70).

Therefore, the present invention has been devised to solve the above problems, an object of the present invention is for an air conditioner for inserting a distributor into the refrigerant outlet pipe of the evaporator so that the evaporated water generated in the evaporator is easily drained into the evaporator It is to provide an evaporator of the indoor unit.

In order to achieve the above object, the evaporator of the indoor unit for an air conditioner according to the present invention, the air is configured such that a plurality of refrigerant inlet and outlet pipes for introducing and exiting the refrigerant in the evaporator is connected to the outdoor unit along the refrigerant inlet and outlet pipe In the indoor unit for the conditioner, the refrigerant flowing out through the plurality of refrigerant outlet pipes connected to the evaporator is collected in one place to be discharged into the refrigerant outlet pipe, and at the same time, the evaporated water generated by the temperature difference of the air in the evaporator receives the evaporated water receiver. Distributor is provided at the vertical bottom of the refrigerant inlet and outlet of the evaporator to fall toward.

1 is an external perspective view showing an indoor unit for an air conditioner.

2 is an exploded perspective view showing a conventional indoor unit for an air conditioner.

3 is a perspective view showing an evaporator of a conventional indoor unit.

Figure 4 is a side view showing a refrigerant pipe connection structure of the evaporator according to the present invention.

5 is a side view showing a refrigerant pipe connection structure of the evaporator according to the present invention.

* Explanation of symbols for main parts of the drawings

10: indoor unit 20: front panel

70: evaporator 71: bracket

75: refrigerant inlet pipe 76: refrigerant outlet pipe

77: refrigerant flow pipe 78: refrigerant flow pipe

79 divider

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

In the drawings, the same parts as in the conventional construction are denoted by the same reference numerals and detailed description thereof will be omitted.

As shown in FIG. 5, the coolant inlet pipe 75 and the coolant outlet pipe 76 of the evaporator 70 flow out through a plurality of coolant outlet pipes 76 connected to the evaporator 70. At the same time, the refrigerant is collected and discharged into the refrigerant outlet pipe 78, and at the same time, the evaporator W generated by the temperature difference of the air in the evaporator 70 drops toward the evaporator receiver 80. 79) is inserted.

The distributor 79 is inclined to receive the evaporated water W formed on the surfaces of the coolant inlet pipe 75 and the coolant outlet pipe 76 to face the evaporated water receiver 80 by capillary action.

Next, the operation by the present invention configured as described above will be described.

The refrigerant condensed from the outdoor unit (not shown) flows into the evaporator 70 through the refrigerant inlet pipe 75 connected through the refrigerant inlet pipe 77 and flows in a zigzag manner, thereby plural refrigerant outlet pipes 76 Are collected into the dispenser (79). This refrigerant is sent to the outdoor unit along the refrigerant outlet pipe 78 connected to one end of the distributor 79. In this process, the evaporator 70 exchanges heat with hot and humid indoor air and the evaporated water W is formed on the surfaces of the refrigerant inlet tube 75 and the refrigerant outlet tube 76 of the evaporator 70 due to the temperature difference of the air. This evaporated water (W) is a part of which falls along the bracket (71) to the evaporative water receiving unit 80 installed at the bottom of the evaporator 70 by capillary action, the other part of the plurality of refrigerant inflow and Falling to the distributor 79 is installed in the vertical bottom of the outlet pipe (75, 76) and flows down to the evaporated water receiving 80 while flowing down to the bottom by the capillary phenomenon on the surface of the distributor (79).

As described above, according to the evaporator of the indoor unit for an air conditioner according to the present invention, the refrigerant of the plurality of refrigerant outlet pipes are gathered in one place at the vertical bottom of the refrigerant inlet and outlet pipes and at the same time the surface of the refrigerant inlet and outlet pipes. Since the distributor is installed to guide the evaporated water to fall into the evaporation tray, it is effective to prevent the electrical short circuit caused by the immersion of other parts by the evaporated water.

Claims (2)

In the indoor unit for an air conditioner configured to connect a plurality of refrigerant inflow and outflow pipes into and out of a refrigerant in an evaporator so that outdoor units are connected along the refrigerant inflow and outflow pipes, a plurality of refrigerant outlet pipes 76 connected to the evaporator 70. By collecting the refrigerant flowing out through one place to the refrigerant outflow pipe 78 and at the same time the evaporated water (W) generated by the temperature difference of the air in the evaporator 70 falls toward the evaporated water receiver (80). The evaporator of the indoor unit for the air conditioner, characterized in that the distributor 79 is provided at the vertical bottom of the refrigerant inlet and outlet pipe (75) (76) of the evaporator (70). According to claim 1, The distributor 79 receives the evaporated water (W) formed on the surface of the refrigerant inlet pipe 75 and the refrigerant outlet pipe 76 directed to the evaporation water receiving unit 80 by the capillary phenomenon. Evaporator of the indoor unit for an air conditioner, characterized in that the inclined so as to.