KR200363318Y1 - Air blower for unit cooler - Google Patents

Abstract

The present invention relates to a blower of the unit cooler, the blower duct is installed in the front of the housing of the unit cooler to force the cold air generated from the radiator in the forward configuration of the duct in the shape of a square cylinder, the blowing duct The inner circumferential surface of the unit maximizes the blowing area by fixing a separate cylindrical blowing guide indirectly so that most of the cool air generated from the radiator inside the housing is blown forward to maximize the cooling efficiency per unit time. It is to minimize the formation of frost on the inner wall surface of the cooler and the radiator.

The blower of the unit cooler according to the present invention has a width and height and length of a predetermined size, and the outside of the front end and the rear end of the square tube shape blower duct formed with a fastening hole; A cylindrical blowing guide fixed and installed in an inscribed state on an inner circumferential surface of the blowing duct; A bracket fixed and installed inside the rear end of the blowing duct corresponding to a position outside the rear end of the blowing guide; A motor installed on the bracket, the motor being rotated in a predetermined direction by application of current; And a blower fan which is located inside the cylindrical blower guide and is rotated in a state of being fixed and coupled to the rotation axis end of the motor.

Description

Blower of unit cooler {AIR BLOWER FOR UNIT COOLER}

The present invention relates to a blower of a unit cooler, and more particularly, the blower duct is installed in the front of the housing of the unit cooler to force the cold air generated from the radiator to the front. It is configured in a shape, and the inner circumferential surface of the blower duct maximizes the blower area by internally fixing a separate cylindrical blower guide, so that most of the cold air generated from the radiator inside the housing is blown forward, thereby cooling efficiency per unit time And a blower of the unit cooler to minimize the formation of frost on the inner wall surface and the radiator of the housing of the unit cooler.

In general, the unit cooler 10 is applied to a refrigeration apparatus for home or commercial use has a predetermined size, as shown in Figure 1, the housing 12 is formed with a circular through hole 11 in a predetermined position on the front, It is installed inside the housing 12, the refrigerant circulation pipe is built in a closed loop form, the outer end is composed of a radiator 13 is provided with a plurality of heat absorbing fins with excellent heat transfer efficiency.

In the unit cooler 10, the refrigerant is forcedly forced through the refrigerant circulation pipe built into the radiator 13 together with the compressed air generated from the conventional compressor, and when the forced refrigerant passes through the portion where the endothermic fin is installed. As the heat exchange is performed between the heat absorbing fin cooled by the refrigerant and the surrounding air, the temperature around the radiator 13 is rapidly lowered.

On the other hand, the through hole 11 formed in the front surface of the housing 12 of the unit cooler 10 is provided with a blower 14 for blowing the cold air generated from the radiator 13 to the front.

1 is an exploded perspective view showing a partial cross-sectional view showing a blower applied to a conventional unit cooler, Figure 2 is a front view of a blower applied to a conventional unit cooler.

Referring to this, the blower 14 of the conventional unit cooler has a fastening flange 15 is formed at the front and rear ends, respectively, and is coupled to the edge of the through hole 11 on the housing 12 of the unit cooler 10. Fixed to the front end of the cylindrical blower duct 16 having a size of and the motor 18 and the shaft 18a of the motor 18 provided on the bracket 17 provided inside the blower duct 16. It consists of a blowing fan 19 is rotated in place.

When the electric current is applied by the user's switch operation, the blower 14 rotates the motor 18 and the blower fan 19 in a predetermined direction, and the cold air generated from the radiator 13 inside the housing 12 is blown through the blower duct. Guided by (16) is to be blown forward.

In the blower device 14 applied to the conventional unit cooler 10 as described above, the blower duct 16 has a cylindrical shape, and the radiator 13 inside the housing 12 has an installation direction of the blower duct 16. Since the air is installed in the direction perpendicular to each other, the cool air generated in the radiator 13 near the installation position of the blower duct 16 is blown outwardly through the blower duct 16.

However, the cool air generated in the radiator 13 at a position relatively far from the installation position of the blower duct 16 is not blown by the front inner wall of the housing 12, and the operating time gradually increases in this state. If it passes, frost is formed in the front inner wall of the housing 12 and the radiator 13, and there exists a problem that the cooling efficiency per unit time falls significantly.

In addition, when the cylindrical blower duct 16 is applied as described above, since the cool air around the through hole 11 is blocked by the front wall of the housing 12 and is not properly blown forward, the radiator 13 is inevitably housed. There is a problem that the size of the entire unit cooler 10 becomes larger as it is installed at a position relatively far away from the front wall of the rear part 12 to occupy more installation space.

In addition, when the frost is formed on the inner wall surface or the radiator 13 of the housing 12 of the unit cooler 10, since a separate frost removing heater must be installed, the productivity is lowered and the production cost of the product is increased. There is a problem that the competitiveness is lowered.

The present invention is to solve such a conventional problem, the purpose is to install a blower duct in a rectangular cylindrical shape in the blower installed in the front of the housing of the unit cooler for forced cooling of the cold air generated from the radiator inside In addition, the inner circumferential surface of the blower duct maximizes the blower area by internally fixing a separate cylindrical blower guide so that most of the cool air generated from the radiator is blown forward to maximize the cooling efficiency per unit time. In order to minimize the formation of frost on the inner wall of the unit cooler and the radiator, a new unit cooler blower is provided.

1 is an exploded perspective view showing a partial cross section showing a blower applied to a conventional unit cooler,

2 is a front view of a blower applied to a conventional unit cooler,

Figure 3 is an exploded perspective view showing a blower of the unit cooler according to the present invention,

Figure 4 is a side cross-sectional view showing a coupling state of the blower of the unit cooler according to the present invention,

5 is a front view of the installation state of the blower of the unit cooler according to the present invention.

* Description of the symbols for the main parts of the drawings *

42: ventilation duct 44: ventilation guide

46: motor 48: blowing fan

54 bracket 58 space

60: unit cooler.

In order to achieve the above object, the air blower of the unit cooler according to the present invention has a width and height and length of a predetermined size, and the outer side of the front end and the rear end of the square tube-shaped blower duct formed with a fastening hole; A cylindrical blowing guide fixed and installed in an inscribed state on an inner circumferential surface of the blowing duct; A bracket fixed and installed inside the rear end of the blowing duct corresponding to a position outside the rear end of the blowing guide; A motor installed on the bracket, the motor being rotated in a predetermined direction by application of current; And a blower fan which is located inside the cylindrical blower guide and is rotated in a state of being fixed and coupled to the rotation axis end of the motor.

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

Figure 3 is an exploded perspective view showing a blower of the unit cooler according to the present invention, Figure 4 is a side cross-sectional view showing a coupling state of the blower of the unit cooler according to the present invention.

In addition, Figure 4 is a front view of the installation state of the blower of the unit cooler according to the present invention.

Referring to this, the blower 40 of the unit cooler according to the present invention is configured to maximize the blowing area of the cold air generated from the radiator installed inside the housing of the unit cooler.

To this end, the blower device 40 of the unit cooler according to the present invention has a rectangular cylindrical blower duct 42 having a predetermined width and height, and a cylindrical blower installed to be inscribed on the inner circumferential surface of the blower duct 42. The guide 44, the motor 46, and the blowing fan 48 are basic components.

In the present invention, the blower duct 42 has a rectangular cylindrical shape having a width, a height, and a length of a predetermined size, and a flange 52 having a fastening hole 50 is provided at the outside of the front end and the rear end. Has

The blowing guide 44 is formed in a cylindrical shape having a predetermined length, the outer peripheral surface is fixed and installed in an inscribed state on the inner peripheral surface of the blowing duct 42.

The bracket 54 is fixed and installed inside the rear end of the blowing duct 42 corresponding to the position beyond the rear end of the blowing guide 44, and the bracket 54 is rotated in a predetermined direction by application of current. The motor 46 is fixedly installed.

A wire guide hole 56 into which a wire connected to the motor 46 is inserted is formed at a predetermined position at the rear end of the blower duct 42 corresponding to the installation position of the motor 46.

The blowing fan 48 is fixed and coupled to the front end of the rotation shaft 46a of the motor 46, and the blowing fan 48 is configured to be located concentrically inside the cylindrical blowing guide 44.

In addition, a general grill (not shown) may be installed on the front surface of the blowing duct 42 to adjust the blowing direction of cold air.

The operation of the present invention made as described above is as follows.

3 to 5, the blower device 40 according to the present invention operates the unit cooler 60 in a state where it is installed at the edge of the through hole 64 formed on the front surface of the housing 62 of the unit cooler 60. In this case, the refrigerant begins to circulate in the radiator 66 installed in the housing 62 of the unit cooler 60.

At the same time, the motor 46 constituting the blower 40 of the present invention starts to be driven.

As described above, when the refrigerant begins to circulate in the radiator 66 installed inside the housing 62 of the unit cooler 60, the cool air is generated while the temperature of the surrounding air is lowered. By the blowing action of the blowing fan 48 in accordance with the driving of) is forcedly blown forward through the blowing guide 44 in the blowing duct (42).

When the cold air is blown through the cylindrical blow guide 44 as described above, as illustrated in FIG. 5, a blower duct in which the cold air around the cool air in the cylindrical blow guide 44 has a rectangular cylindrical shape is formed. Since the air is sucked forward through the space portion 58 formed by the outer circumferential surface of each of the corners and the cylindrical air blowing guide 42, the air blowing area of the cold air is greatly expanded.

Therefore, the cooling efficiency is significantly improved per unit time, and the amount of cool air remaining inside the housing 62 of the unit cooler 60 is reduced, thereby minimizing frost formation on the inner wall surface of the housing 62 and around the radiator 66. Will be.

In addition, when the cold air formed between the front wall of the housing 62 and the radiator 66 is sucked out by the blowing pressure forcedly blown through the air blowing guide 44 as in the present invention, the radiator is not necessarily disposed far away from the rear of the housing. Since there is no need to reduce the front and rear width of the unit cooler, the slimness is possible.

According to the present invention, the ventilation duct is formed in a rectangular cylindrical shape, and the cylindrical air guiding guide is installed in the inner side of the air duct between the inner periphery of the air duct and between the outer circumferential surface of the air duct guide made of the cylindrical shape Since a separate space is formed in the cooling air blowing area is maximized, the cooling efficiency per unit time is significantly improved.

In addition, since the cool air remaining inside the housing is minimized when the unit cooler is operated according to the maximization of the cold air blower area, frost is not formed on the inner wall surface of the housing and around the radiator. As a result, a heater for removing the frost is removed. No installation is required or installation of the heater can be minimized, increasing productivity and reducing costs.

In addition, since the radiator does not have to be disposed far to the rear of the housing, the front and rear widths of the unit coolers can be reduced, resulting in a slimmer body.

Claims (1)

A blowing fan duct 42 having a width, a height, and a length of a predetermined size, and having a flange having a fastening hole formed at an outer side of the front end and the rear end; A cylindrical air blowing guide 44 fixed and installed in an inner circumferential surface of the air blowing duct; A bracket (54) fixed and installed inside the rear end of the blowing duct corresponding to a position outside the rear end of the blowing guide; A motor 46 fixed on the bracket and driven to rotate in a predetermined direction by application of an electric current; And a blower fan (48) positioned and rotated inside the cylindrical blower guide in a state of being fixed and coupled to the end of the rotating shaft of the motor.