KR0118782Y1 - Suction resistance repuction device of air con evaporater - Google Patents

Abstract

The present invention relates to an evaporator for an air conditioner, and in particular, a suction grill for sucking indoor air is formed and a discharge grill for discharging cold air is formed to form an exterior of the indoor unit, and the suction grill is sucked through the suction grill of the main body. A filter detachably installed inside the suction grill to filter foreign substances such as dust contained in the indoor air, and upper and lower evaporators for converting the indoor air passing through the filter into cold air by evaporation of the refrigerant; In the upper and lower evaporator, the suction resistance reduction device of the evaporator for an air conditioner comprising a blower fan to generate a blowing force to discharge the cold air converted in the upper and lower evaporator to the room at the same time, the upper The width L2 between the refrigerant pipes of the evaporator is increased to be larger than the width Ll between the refrigerant pipes of the lower evaporator. The diameter (D2) of the refrigerant pipe of the upper evaporator is formed smaller than the diameter (Dl) of the refrigerant pipe of the lower evaporator, the cooling fins of the upper evaporator are arranged in a flat plate shape, the cooling fins of the lower evaporator is S-shaped The present invention relates to a device for reducing suction resistance of an evaporator for an air conditioner, wherein the diameter of the refrigerant pipes of the upper evaporator and the lower evaporator is different so that the width between the refrigerant pipes is different and the shape of the cooling fins is different. The suction wind velocity flowing into the lower evaporator is uniformly distributed to cool the room more efficiently.

Description

Suction resistance reduction device of air conditioner evaporator

The present invention relates to an evaporator for an air conditioner, in which two evaporators separated into upper and lower parts are mounted to an indoor unit to cool the indoor air to cool the room. Particularly, two evaporators are provided at an equal intake air velocity. It is related to the suction resistance reduction device of the evaporator for the air conditioner which can cool the room more efficiently by improving the heat exchange efficiency.

In general, an air conditioner for cooling the room is divided into an integrated air conditioner in which an evaporator and a condenser are built in one body, and a separate air conditioner in which an evaporator is disposed in an indoor unit and a condenser and a compressor disposed in an outdoor unit.

In the separate air conditioner, as shown in FIG. 3, the indoor unit is provided with a suction grill 11 through which indoor air is sucked and a discharge grill 12 through which cold air is discharged, thereby forming the main body of the indoor unit. (10) and a filter (13) detachably installed inside the suction grill (11) to filter foreign substances such as dust contained in the indoor air sucked through the suction grill (11) of the main body (10). And the upper and lower evaporators 30 and 20 for converting the indoor air that has passed through the filter 13 into cold air by the evaporation of the refrigerant, and the upper and lower evaporators 30 and 20. A blower fan 40 is installed on the front of the upper evaporator 30 and a blower fan 40 for generating a blowing force so that the cold air converted by the upper and lower evaporators 30 and 20 is discharged to the room. It consists of an electrostatic precipitating filter 14 for collecting dust.

Such a conventional indoor unit is formed of the same diameter of the refrigerant pipe of the upper and lower evaporator 30, 20 and the same width between the refrigerant pipe and the refrigerant pipe, the blower in the lower evaporator 20 The fan 40 is located.

In addition, since the blower fan 40 is located close to the lower evaporator 20 and the upper evaporator 30 is located far away, suction into the lower evaporator 20 as shown in FIG. The suction wind speed of the indoor air is increased and the suction wind speed sucked into the upper evaporator 30 is lowered.

That is, unbalance was generated in which the heat exchange efficiency was increased in the lower evaporator 20 and the heat exchange efficiency was decreased in the upper evaporator 30.

In addition, when the inside of the room is overcooled and the indoor fan is weakly rotated so that the rotation of the blower fan 40 becomes weak, there is a problem that the upper part of the evaporator 30 may freeze rapidly due to a rapid decrease in the suction wind speed. there was

That is, in the conventional air conditioner evaporator, since the intake air velocity of the indoor air flowing into the indoor unit is not constant, the heat exchange efficiency is lowered in the upper evaporator, and an unbalance occurs in which the heat exchange efficiency is increased in the lower evaporator, thereby cooling the room more efficiently. There was a problem that can not.

The present invention has been made in view of the above-described problems, and an object of the present invention is to make the suction air velocity of the indoor air flowing into the upper and lower evaporators of the indoor unit uniform during cooling, thereby improving the heat exchange efficiency of the indoor air in the upper and lower evaporators. It is to provide a device for reducing the suction resistance of the evaporator for the air conditioner to occur in the same way.

In order to achieve the above object, the suction resistance reducing device of an evaporator for an air conditioner according to the present invention includes a main body for forming an exterior of the indoor unit by forming a suction grill for sucking indoor air and a discharge grill for discharging cold air; A filter detachably installed inside the suction grill so as to filter foreign substances such as dust contained in the indoor air sucked through the suction grill of the main body, and the indoor air passing through the filter by cold evaporation of the refrigerant. Of an evaporator for an air conditioner comprising an upper / lower evaporator for converting the air into the upper and lower evaporators, and a blower fan that generates air blown to allow the indoor air to flow into the upper and lower evaporators and to discharge cold air converted from the upper and lower evaporators to the room In the suction resistance reducing device, the width (La) between the refrigerant pipe of the upper evaporator is the width of the lower evaporator The diameter D2 of the refrigerant pipe of the upper evaporator is formed to be smaller than the diameter Dl of the refrigerant pipe of the lower evaporator so as to be larger than the width Ll between the refrigerant pipes, and the cooling fins of the upper evaporator are arranged in a flat plate shape. And, the cooling fin of the lower evaporator is characterized in that it is arranged in an S-shape.

According to the device for reducing the suction resistance of an evaporator for an air conditioner according to the present invention, the diameter of the refrigerant pipes of the upper evaporator and the lower evaporator is different so that the width between the refrigerant pipes is different and the shape of the cooling fins is different. The intake air velocity flowing into the evaporator and the lower evaporator is uniformly distributed to cool the room more efficiently.

1 is a structural diagram schematically showing an internal configuration of an indoor unit applied to the present invention.

Figure 2 (a) is a front view showing a part of the upper evaporator applied to the present invention.

Figure 2 (b) is a front view showing a part of the lower evaporator applied to the present invention.

3 is a structural diagram schematically showing an internal configuration of an indoor unit applied to a conventional example.

Figure 4 (a) is a suction wind velocity distribution diagram of the suction air sucked into the indoor unit applied to the present invention.

4 (b) is a suction wind velocity distribution diagram of the suction air sucked into the indoor unit applied to the conventional example

* Explanation of symbols on the main parts of the drawings

100: main body 101: suction grill

102: discharge grill 103: filter

104: electrostatic precipitating filter 110: lower evaporator

111: refrigerant pipe 112: cooling fin

120: upper evaporator 121: refrigerant pipe

122: cooling fin 130: blower fan

Hereinafter, with reference to the accompanying drawings an embodiment of the suction resistance reduction device of the evaporator for an air conditioner according to the present invention will be described in detail.

1 is a structural diagram schematically showing the internal configuration of the indoor unit applied to the present invention, Figure 2 (a) is a front view showing a part of the upper evaporator applied to the present invention, Figure 2 (b) is 4 is a front view showing a part of the lower evaporator applied to the present invention, and FIG. 4 (a) is an intake air velocity distribution diagram of the intake air sucked into the indoor unit according to the present invention. In (a), 100 is a main body for forming the appearance of the indoor unit, the suction grill 101 is formed on the front side to suck the indoor air, and the cold air converted from the upper and lower evaporators, which will be described later, is discharged. The discharge grill 102 is formed.

In addition, inside the suction grill 101 of the main body 100, a filter 103 for filtering foreign matter such as dust containing indoor air sucked through the suction grill 101 is detachably mounted. The rear part of the filter 103 is equipped with upper and lower evaporators 120 and 110 for converting the indoor air passing through the filter 103 into cold air by the evaporation of the refrigerant.

In addition, the rear side of the lower evaporator 110 allows the indoor air to flow into the upper and lower evaporators 120 and 110 and simultaneously discharges the cold air converted by the upper and lower evaporators 120 and 110 into the room. The blower fan 130 for generating a blowing force is disposed, and the electrostatic precipitating filter 104 for collecting dust and the like contained in the indoor air is disposed on the front surface of the upper evaporator 120.

On the other hand, the present invention is provided with a suction resistance reducing means (1) so that the suction air velocity of the indoor air introduced into the upper and lower evaporator (120, 110) is sucked into the suction grill (101).

That is, as shown in FIG. 2, the suction resistance reducing means 1 changes the diameter D2 of the refrigerant pipe 121 of the lower evaporator 120 to the refrigerant pipe 111 of the lower evaporator 110. The width L2 between the refrigerant pipes 121 of the upper evaporator 120 is made larger than the width L1 between the refrigerant pipes 111 of the lower evaporator 110. .

That is, the diameter D2 of the coolant tube 121 of the upper evaporator 120 is smaller than the diameter D1 of the coolant tube 111 of the lower evaporator 110, so that the coolant tube of the upper evaporator 120 ( Since the width L2 between 121 is increased than the width L1 between the refrigerant pipes 111 of the lower evaporator 110, the suction resistance of the suction wind velocity of the upper evaporator 120 is reduced.

In addition, since the diameter (D2) of the refrigerant pipe 121 of the upper evaporator 120 is small, the flow rate of the refrigerant is increased, so that the indoor air flowing into the upper evaporator 120 is smoothly heat exchanged, thereby deteriorating heat exchange efficiency. There will be no.

That is, the suction resistance of the indoor air sucked into the upper evaporator 120 is lower than the suction resistance of the indoor air sucked into the lower evaporator 110 and the refrigerant flows into the refrigerant pipe 121 of the upper evaporator 120. As the flow rate is increased, the suction air velocity of the indoor air flowing into the main body 100 is uniformly made as shown in FIG. 4 (a) and the heat exchange efficiency of the upper heat exchanger 120 is not deteriorated. In the evaporator 120 and the lower evaporator 110, the indoor air is heat-exchanged smoothly, thereby cooling the room more efficiently.

On the other hand, the cooling fin 122 of the upper evaporator 120 is maintained perpendicular to the refrigerant pipe 121, the cooling fin 112 of the lower evaporator 110 is S with respect to the refrigerant pipe 111 It is kept in shape.

That is, the lower evaporator 110 is the cooling fin 112 is located in the S-shape so that the indoor air introduced into the lower evaporator 110 by the blowing force of the blower fan 130 is the refrigerant pipe 111 Heat exchange efficiency is improved by the maximum contact, and the cooling fin 122 of the upper evaporator 120 is located in the flat plate to the indoor air introduced into the upper evaporator 120 by the blowing force of the blower fan 130 Will flow smoothly.

Next, the effect of the suction resistance reduction device of the evaporator for an air conditioner according to the present invention configured as described above will be described.

First, the diameter D2 of the coolant tube 121 of the upper evaporator 120 is smaller than the diameter Dl of the coolant tube 111 of the lower evaporator 110 so that the coolant tube of the upper evaporator 120 ( The width L2 between 121 is greater than the width Ll between the refrigerant pipes 111 of the lower evaporator 110, and the cooling fin 122 of the upper evaporator 120 is positioned as a flat plate and the lower evaporator. Since the cooling fin 112 of the 110 is located in an S-shape, the flow rate of the refrigerant flowing into the refrigerant pipe 121 of the upper evaporator 120 is increased and suction of indoor air flows into the upper evaporator 120. The resistance is reduced and the indoor air flowing into the lower evaporator 110 is brought into maximum contact with the refrigerant pipe 111 by the shape of the cooling fin 112, so that the upper evaporator 120 and the lower evaporator The heat exchange efficiency of 110 is made substantially the same.

That is, since the suction air velocity of the indoor air flowing into the upper evaporator 120 and the lower evaporator 110 is uniformly made as shown in FIG. 4 (a), a smooth heat exchange occurs so that the room can be cooled more efficiently. Will be.

As described above, according to the device for reducing the suction resistance of an evaporator for an air conditioner, the diameter of the refrigerant pipe of the upper evaporator and the lower evaporator is different so that the width between the refrigerant pipes is different and the shape of the cooling fins is different. Therefore, there is a very practical effect that the intake air velocity flowing into the upper and lower evaporators is uniformly distributed to cool the room more efficiently.

Claims (1)

A suction grill 101 for sucking indoor air is formed and a discharge grill 102 for discharging cold air is formed to form an exterior of the indoor unit, and a suction grill 101 of the main body 100. A filter 103 detachably installed inside the suction grill 101 to filter foreign substances such as dust contained in the indoor air sucked through the air, and the indoor air passing through the filter 103 evaporates the refrigerant. The upper and lower evaporators (120, 110) and the upper and lower evaporators (120, 110) to be converted into cold air by the indoor air at the same time while the upper and lower evaporators (120, 110) In the suction resistance reduction device of the evaporator for an air conditioner comprising a blower fan 130 for generating a blowing force so that the converted cold air is discharged into the room, the width (L2) between the refrigerant pipe 121 of the upper evaporator 120 is Width Ll between the refrigerant pipe 111 of the lower evaporator 110 The diameter Da of the coolant tube 121 of the upper evaporator 120 is formed to be smaller than the diameter Dl of the coolant tube 111 of the lower evaporator 110, so that the upper portion of the upper evaporator 120 may be increased. Cooling fins 122 are arranged in a flat plate shape, the cooling fins 112 of the lower evaporator 110 is suction resistance reduction device of the air conditioner evaporator, characterized in that arranged in the S-shape.