KR20020082262A - Heat-exchanger mounting structure for air conditioner - Google Patents

Abstract

PURPOSE: A structure for installing heat exchanger of multi-split type air conditioner is provided to simplify installation structure of the heat exchanger in an indoor unit of the air conditioner. CONSTITUTION: A structure includes a heat exchanger(60) where heat exchange is executed between air in a space to be air-conditioned and working fluid of a heat exchange cycle; mounting ribs(53) formed on an outside of an orifice hole(52) of an orifice(50) guiding air passing the heat exchanger for an edge of the heat exchanger to be placed therein; coupling ribs(55) formed on an upper end of the orifice on both sides of the mounting ribs for one side of the heat exchanger to be coupled thereto by coupling screws(68); and supports(56) formed on a lower end of the orifice on both sides of the mounting ribs for one side of the heat exchanger to be hooked and supported thereby.

Description

Heat-exchanger mounting structure for air conditioner

The present invention relates to an indoor unit of an air conditioner, and more particularly, to a mounting structure of a heat exchanger that performs heat exchange between air and a refrigerant in a space for air conditioning in an indoor unit of an air conditioner.

1 is a block diagram of an indoor unit of a separate type air conditioner according to the prior art. According to this, the casing 1 forms the exterior of the indoor unit. The casing 1 has a flat rectangular shape, and its length in the vertical and horizontal directions is relatively larger than the width before and after. A suction grill 3 is formed on the front surface of the casing 1, which becomes a passage for sucking air in a space for air conditioning into the casing 1.

The heat exchanger 5 is installed at the rear of the suction grill 3. The heat exchanger 5 is a portion where heat exchange between the refrigerant of the heat exchange cycle and the air sucked in the space for air conditioning through the suction grill 3 is performed. Such a heat exchanger (5) is formed in a square so that the suction grill (3) and its area correspond. In the center of the heat exchanger 5, a through hole 6 is formed in order to avoid interference between the motor 7 and the turbofan 9, which will be described below.

The motor 7 is installed inside the casing 1. The rotation shaft of the motor 7 is installed in the direction from the rear of the casing 1 to the front, and the turbo fan 9 is installed. The turbo fan 9 is a portion that provides a motive force for the flow of air in the interior of the indoor unit, and sucks air in the direction of the rotation axis from the front and blows it in the centrifugal direction.

Upper, lower, left, and right sides of the casing 1 are provided with discharge ports 11 for discharging air blown by the turbo fan 9 into a space for air conditioning. Discharge port vanes 13 are respectively installed in the discharge ports 11 to adjust the direction of air discharged from the discharge ports 11.

Meanwhile, an orifice 15 is installed between the heat exchanger 5 and the turbo fan 9. An orifice hole is formed in the center of the orifice 15 so that the air passing through the heat exchanger 5 is the turbo. Guided to fan 9.

According to the prior art having such a configuration, the indoor unit of the air conditioner is operated as follows.

When the air conditioner is driven, a relatively low temperature refrigerant is transferred to the heat exchanger 5 while the heat exchange cycle is operated. Then, the turbo fan 9 is rotated by the motor 7 to suck air in the space for air conditioning.

That is, when the turbo fan 9 is rotated, air in the space for air conditioning is sucked into the casing 1 through the suction grill 3. The air sucked through the suction grill 3 is heat-exchanged while passing through the heat exchanger 5, and becomes cold air having a relatively low temperature.

The cold air generated by the heat exchanger 5 passes through the orifice hole of the orifice 15 and is sucked into the turbo fan 9 and discharged in the centrifugal direction of the turbo fan 9. The air discharged from the turbo fan 9 is discharged into the space for air conditioning through the discharge holes 11 formed on the upper, lower, left, and right sides of the casing 1. At this time, the discharge port vane 13 of the discharge port 11 is opened to control the discharge direction of the discharged cold air.

However, the indoor unit of the air conditioner according to the prior art as described above has the following problems.

The heat exchanger 5 is seated on the orifice 15, and the heat exchanger 5 must be fastened using a plurality of screws to mount the heat exchanger 5 to the orifice 15. Therefore, there is a problem that the number of parts increases and the workability of the assembly work is inferior.

The heat exchanged while passing through the heat exchanger 5 is transferred to the turbofan 9 through an orifice hole of the orifice 15. However, in order for the air passing through the heat exchanger 5 to be accurately delivered to the turbofan 9, there should be no leakage of air between the orifice 15 and the heat exchanger 5.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, and to simplify the mounting structure of the heat exchanger used in the indoor unit of the air conditioner.

Another object of the present invention is to prevent leakage between the heat exchanger and adjacent peripheral parts.

1 is a side cross-sectional view showing the indoor unit configuration of a separate air conditioner according to the prior art.

Figure 2 is a cross-sectional view of a separate air conditioner employing a heat exchanger mounting structure of the embodiment of the present invention.

Figure 3 is an exploded perspective view showing a heat exchanger mounting structure according to the present invention.

Explanation of symbols on the main parts of the drawings

30: outer case 40: suction grill

42: grille louver 45: filter

50: orifice 52: orifice ball

53: seating rib 54: guide rib

55: tightening rib 57: discharge guide portion

57 ': Reinforcement rib 58: Component seat

58 ': Reinforcement rib 60: Heat exchanger

61: refrigerant pipe 62: heat radiation fin

64: channel 65: fastener

65 ': Fastening hole 68: Fastening screw

70: motor 71: rotating shaft

72: motor bracket 74: turbo fan

80: discharge port 82: discharge port vane

According to a feature of the present invention for achieving the above object, the present invention provides a heat exchanger that performs heat exchange between the air of the space for air conditioning and the working fluid of the heat exchange cycle, and guides the air passing through the heat exchanger A seating rib formed at an outer side of an orifice hole of the orifice such that an edge of the heat exchanger is positioned inwardly; a fastening rib formed at an upper end of an orifice on both sides of the seating rib; and one side of the heat exchanger fastened by a fastener; It is formed on the bottom of the orifice on both sides of the rib and comprises a support that is supported by one side of the heat exchanger.

The part fastened to the fastening rib and supported by the support is a channel forming an end of the heat exchanger.

Secondary seating ribs lower than the height of the seating ribs are formed side by side on the outside of the seating ribs on which the channel is seated.

The channel of the heat exchanger is bent stepwise to closely contact the seating rib and the auxiliary seating rib.

According to the heat exchanger mounting structure according to the present invention having such a configuration, the heat exchanger is mounted in a simpler configuration, and there is an advantage that air flow inside the indoor unit is reliably because no leakage occurs between peripheral components.

Hereinafter, a preferred embodiment of a heat exchanger mounting structure of a separate type air conditioner according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

First, referring to Figure 2 will be described the internal configuration of the separate air conditioner employing the orifice of the embodiment of the present invention.

The outer case 30 forms the exterior of the indoor unit. The outer case 30 is formed in the shape of a flat hexahedron. In addition, the front panel 32 is installed on the front of the outer case 30 to shield a space formed inside the outer case 30.

The suction grill 40 is formed on the front panel 32. The suction grill 40 serves as a passage for sucking the air of the space for air conditioning into the indoor unit. Such a grill grille (40) is provided with a plurality of grill louvers (42). The grill louvers 42 are installed on the front panel 32 to the left and right, and a plurality of grill louvers 42 are disposed up and down, respectively.

And the grill louver 42 is opened so that the front end of the grill louver 42 toward the front upper portion of the outer case (30). This open state is well illustrated in FIG. 2. When the air conditioner is not operated, the tip of the grill louver 42 is seated on the front surface of the outer case 30 so as to close the suction grille 40 so as not to communicate with the outside. A filter 45 for purifying air flowing through the suction grill 40 is installed inside the suction grill 40.

An orifice 50 is installed in the inner space of the outer case 30. The orifice 50 is formed in the center of the orifice hole 52, to guide the air sucked through the suction grill 40 to the turbo fan 74 to be described below.

The configuration of such an orifice will be described with reference to FIG. 3. As shown in the figure, the orifice body 51 is a substantially rectangular plate when viewed from the front. An orifice hole 52 is formed in the center of the orifice body 51. The orifice hole 52 serves as a passage for guiding cold air generated by heat exchange in the heat exchanger 60 to the turbo fan 74.

Next, a portion on which the heat exchanger 60 is seated is formed on one surface of the orifice body 51. That is, the mounting ribs 53 are formed to protrude so that the circumference of the heat exchanger 60 to be described below is seated therein. Here, the seating ribs 53 are formed differently according to the shape of the heat exchanger 60. In this embodiment, the seating ribs 53 are formed to correspond to the heat exchanger 60 formed in a quadrangle. Protruding to form a square around.

Meanwhile, auxiliary seating ribs 54 are formed on the outer side of the seating ribs 53 in which both ends of the heat exchanger 60 are seated on the inner side of the seating ribs 53 with a predetermined interval therebetween. . The auxiliary seating ribs 54 are formed to have a lower height than the seating ribs 53.

Next, fastening ribs 55 are formed at upper ends of the auxiliary seating ribs 54, respectively. The fastening rib 55 is a part to which the fastening piece 65 formed in the channel 64 of the heat exchanger 60 to be described below is fastened by the screw 68.

And the support 56 is formed at the lower end of the orifice body 51 corresponding to the lower end of the auxiliary seating rib 54, respectively. The hanger 67 of the heat exchanger 60 is supported by being supported by the support 56.

Discharge guide portions 57 are formed at both sides of the heat exchanger 60. The discharge guide portion 57 serves to guide the cold air from the turbo fan 74 toward the discharge port 80. The discharge guide portion 57 is formed with a reinforcing rib 57 'long to prevent the orifice body 51 from twisting.

Next, the component seating portion 58 is formed at the upper end of the orifice body 51. For example, a control unit may be mounted on the component seat 58. Reinforcing ribs 58 'are also formed long in the component seating portion 58 to prevent the orifice body 51 from twisting.

A heat exchanger 60 is installed between the orifice 50 and the filter 45. The heat exchanger 60 is a portion in which the refrigerant of the heat exchange cycle flows through the inside, and the air sucked through the suction grille 40 passes through the heat exchanger to exchange heat with the refrigerant to allow relatively low temperature cold air.

As shown in FIG. 3, the heat exchanger 60 is formed by inserting a plurality of heat dissipation fins 62 into a refrigerant pipe 61 which is bent zigzag a number of times and flows a refrigerant of a heat exchange cycle therein. The channel 64 is provided at both ends thereof to support the refrigerant pipe 61 to maintain its shape.

The channel 64 is installed by being seated on the auxiliary seating rib 54 and a seating rib 53 formed in parallel with the auxiliary seating rib 54. To this end, the channel 64 is formed by bending a number of times, and the side end thereof is in close contact with the orifice body 51 through the auxiliary seating rib 54.

Fastening pieces 65 are formed at upper ends of the channels 64, respectively. The fastening piece 65 is a part fastened to the fastening rib 55 by a screw 68. Fastening holes 65 'are formed in the fastening pieces 65, respectively. And the hook piece 67 is formed in the lower end part of the said channel 64, respectively. Such a hook piece 67 hangs on the support 56 so that the heat exchanger 60 is supported.

The heat exchanger 60 is formed of a flat hexahedron as a whole and is mounted on the seating ribs 53 of the orifice 50. However, the heat exchanger 60 does not necessarily have to be in a hexahedral form and is configured differently according to design conditions. And accordingly, the shape of the seating rib 53 is also formed differently.

2, the motor 70 is mounted at the inner center of the outer case 30 corresponding to the rear of the orifice 50. The motor 70 is fixed to the outer case 30 by a motor bracket 72. In addition, a turbo fan 74 is installed on the rotation shaft 71 of the motor 70. The turbo fan 74 sucks air from its tip and discharges it laterally. That is, air is sucked in the rear end direction from the tip of the rotary shaft 71 and discharged in the centrifugal direction of the turbo fan 74.

Next, a plurality of discharge ports 80 are formed in the outer case 30. The discharge port 80 is formed in each of the right side, left side and the bottom surface of the outer case 30, respectively, when viewed from the front of the indoor unit. The discharge port 80 is a portion in which the cold air discharged from the turbo fan 74 is discharged into a space for air conditioning, and the discharge port vanes 82 are installed to be opened and closed.

Hereinafter will be described in detail the operation of the embodiment of the present invention having the configuration as described above.

First, it will be described that the heat exchanger 60 is fastened to the orifice body 51 of the orifice 50. The heat exchanger 60 is seated in the seating rib 53, while the hook pieces 67 of the channels 64, which are installed at both ends of the heat exchanger 60, respectively hang on the support 56. do.

At this time, the portion consisting of the refrigerant pipe 61 and the heat dissipation fins 62 is accommodated inside the seating ribs 53, and the channel 64 is disposed on the seating ribs 53 and the auxiliary seating ribs 54. Seated and positioned.

The fastening hole 65 'of the fastening piece 65 at the upper end of the channel 64 corresponds to the fastening rib 55, and the screw 68 is fastened through the fastening hole 65'. The heat exchanger 60 is fixed to the orifice body 51 by fastening to the rib 55.

When the heat exchanger 60 is installed as described above, the heat exchanger 60 is seated in a space formed inside the seating rib 53, and upper and lower ends thereof are mounted on the seating ribs 53 at the upper and lower ends, respectively. Both ends are shielded by the channel 64 being installed in close contact with the seating ribs 53 and the auxiliary seating ribs 54.

Therefore, the air heat-exchanged while passing through the heat exchanger 60 flows only through the orifice hole 52 of the orifice 50 to the turbo fan 74 and does not leak out of the seating rib 53. . By doing so, the flow of air inside the indoor unit is made as designed and leakage to other parts is prevented.

In the heat exchanger mounting structure of the air conditioner according to the present invention as described in detail above, the lower end of the heat exchanger is fastened to one side of the orifice body and the upper end is fastened to the orifice body using a screw. Therefore, the mounting of the heat exchanger is made simpler.

In addition, since the heat exchanger is mounted on the orifice, it is seated in a space formed inside the seating rib of the orifice, thereby preventing the leakage of air passing through the heat exchanger. Thus, the airflow inside the indoor unit is smoothly made, thereby increasing the efficiency of the air conditioner. .

Claims (4)

A heat exchanger performing heat exchange between the air in the space for air conditioning and the working fluid of the heat exchange cycle; Seating ribs are formed so that the edge of the heat exchanger is located in the outer side of the orifice hole of the orifice for guiding the air passing through the heat exchanger, A fastening rib formed at an upper end of an orifice on both sides of the seating rib and fastened to one side of the heat exchanger by a fastener; Heat exchanger mounting structure of the separate air conditioner, characterized in that formed on the lower side of the orifice on both sides of the seating rib and comprises a support that is supported by one side of the heat exchanger. The heat exchanger mounting structure of a separate air conditioner according to claim 1, wherein the part fastened to the fastening rib and supported on the support is a channel forming an end of the heat exchanger. The heat exchanger mounting structure of a separate air conditioner according to claim 1 or 2, wherein an auxiliary seating rib lower than a height of the seating rib is formed side by side on an outer side of the seating rib on which the channel is seated. The heat exchanger mounting structure of claim 3, wherein the channel of the heat exchanger is bent stepwise to closely contact the seating rib and the auxiliary seating rib.