KR20040022670A - Air-flow structure of outerior parts for casement window type airconditioner - Google Patents

Abstract

PURPOSE: A structure of an outdoor side air flow of a window type air conditioner is provided to transmit air for heat exchange to a whole outdoor heat exchanger. CONSTITUTION: An outdoor heat exchanger is installed at a rear end of a cabinet for exchanging heat of an operating fluid of a heat exchange cycle with air sucked from the outside, wherein a height of the outdoor heat exchanger is higher than a width. A shroud(140) is installed in the cabinet, having a through hole part(141) guiding the air to the outdoor heat exchanger. An inner surface of the shroud corresponding to the upper part of the through hole part has a gap with the outdoor heat exchanger, which becomes narrower as the gap goes to the upper part. An outdoor fan unit(150) is installed in the through hole part for sucking the air in for passing the air through the outdoor heat exchanger to transmit the air to the outside.

Description

Air-flow structure of outerior parts for casement window type airconditioner

The present invention relates to a window type air conditioner, and more particularly, to an outdoor air flow structure of an air conditioner having a height larger than the left and right widths when viewed from the front.

The window type air conditioner is to be installed and used in the window frame in one piece in which all components are provided in one casing. Such a window type air conditioner may be divided into types depending on the type of window to be installed. For example, a window type air conditioner used for a casement window is formed to have a height greater than the left and right widths when viewed from the front. Thus, the configuration of the window type air conditioner mainly used for the casement window is shown in FIG.

According to FIG. 1, in the prior art, the base fan 1 forms the bottom surface of the air conditioner, and the cabinet 3 cooperates with the base fan 1 to form an exterior to form a space where components are installed therein. Form. The cabinet 3 is formed relatively higher in height than the left and right width thereof. The cabinet 3 forms an upper surface and both side surfaces of the air conditioner, so that the space formed by the base fan 1 and the cabinet 3 is open at the front and the rear. Reference numeral 4 is an intake louver in which outdoor air is sucked to the outdoor side of the air conditioner.

The front panel 5 is installed on the front surface of the cabinet 3 to form the exterior of the air conditioner. The front panel 5 is provided with a suction part 5i through which air in the space for meat conditioning is sucked into the indoor side of the air conditioner. A control unit through hole 5e is formed at an upper end of the suction unit 5i, and a discharge through hole 5c through which air heat-exchanged inside the air conditioner is discharged into a space for air conditioning is disposed above the front panel 5. Is formed. Reference numeral 7 denotes a filter for purifying air passing through the suction part 5i.

The barrier 8 divides the internal space formed inside the cabinet 3 into the indoor side and the outdoor side. The barrier 8 has its lower end seated on the base pan 1 and its upper end touches the ceiling of the cabinet 3. Both ends of the barrier 8 are bent toward the front panel 5 to have a 'c' shape when viewed in plan view. The barrier 8 is provided with an insulation plate 9 for insulation between the indoor side and the outdoor side.

An indoor side fan 10 is installed in a space formed by the barrier 8. A sirocco fan is used as the indoor fan 10, and the indoor fan 10 provides a driving force for air flow in the indoor side. On the other hand, the indoor heat exchanger 11 is installed behind the filter (7). The indoor heat exchanger 11 performs heat exchange between the working fluid and the air. An orifice 13 is installed at the front end of the barrier 8 corresponding to the rear of the indoor heat exchanger 11. The orifice 13 is perforated with an orifice hole 15 for guiding the air passing through the indoor heat exchanger 11 to the indoor side fan 10.

Next, the discharge guide 17 is installed in the upper portion of the space formed by the barrier (8). The discharge guide 17 has a discharge passage 18 in communication with a space formed between the barrier 8 and the air guide 13. The discharge passage 18 and the discharge through hole 5e are connected by a connection duct 19.

On the other hand, the control unit 20 is provided between the lower portion of the connection duct 19 and the upper end of the indoor heat exchanger (11). The control unit 20 includes various parts for controlling the air conditioner. The front of the control unit 20 is provided with a control panel 21. The control panel 21 is located in the control part through hole 5e formed in the front panel 5. Reference numeral 22 denotes an operation lever. A discharge louver 25 is installed in the discharge through hole 5c which communicates with the discharge flow path 18. The discharge louvers 25 serve to control the direction of air discharged through the discharge through holes 5c.

On the outdoor side partitioned by the barrier 8, a motor 27 for driving the indoor side fan 10 and driving the outdoor side fan 29 is installed. The motor 27 is provided with a rotation shaft in both directions to simultaneously drive the indoor fan 10 and the outdoor fan (29).

The outdoor heat exchanger 30 is installed in the outdoor space of the air conditioner to be exposed to the rear of the cabinet 3, and the outdoor heat exchanger 30 is surrounded by the shroud 28 and the cabinet 5. . A through hole 28 ′ is formed in the shroud 28 to guide air sucked through the suction louver 4 of the cabinet 3 to the outdoor heat exchanger 30. At this time, the outdoor side fan 29 serves to guide the outdoor heat exchanger 30 by sucking outdoor air. Reference numeral 31 is a compressor bracket on which a compressor is mounted.

In the related art having the above configuration, when the motor 27 is driven, the indoor side fan 10 and the outdoor side fan 29 are rotated, and the air and the outdoor air of the space for air conditioning are respectively sucked into the air conditioner. To make it flow.

In the indoor side, the air sucked in the room is transferred to the indoor side fan 10 through the suction unit 5i, the indoor heat exchanger 11, the orifice hole 15 by driving the indoor side fan 10, and the indoor side. The air discharged from the side fan 10 passes through the discharge guide 17, the connection duct 19, and the discharge through hole 5e and is discharged into a space for air conditioning. At this time, in the indoor heat exchanger (8), the air becomes a relatively low temperature in the cooling operation by heat exchange between the air and the working fluid.

On the outdoor side, outdoor air is sucked into the inside through the intake louver 4 by the driving of the outdoor side fan 29, and heat exchanged through the outdoor heat exchanger 30 through the through hole 28 ′ to the outside. Discharged.

However, the prior art as described above has the following problems.

As described above, in the air conditioner in which the height is relatively higher than the left and right widths, the outdoor heat exchanger 30 is also formed to have a height higher than the left and right widths, and the shroud 28 guides the air to the outdoor heat exchanger 30. ) Also formed higher than the left and right width

All. The diameter of the through hole 28 ′ of the shroud 28 in which the outdoor side fan 29 is installed is determined by the left and right widths of the shroud 28.

Therefore, the through hole 28 ′ does not cover the entire height direction of the shroud 28, and the shroud 28 is relatively dependent on the installation position of the motor 27 driving the outdoor fan 29. Is formed at the bottom of the In addition, the shroud 28 is formed in a straight line from the lower end to the upper end so that the spacing between the shroud 28 and the outdoor heat exchanger 30 is kept constant from the lower end to the upper end of the shroud 28. .

By such a configuration, since the air is not properly transferred to the upper end of the outdoor heat exchanger 30 corresponding to the upper end of the shroud 28, the heat exchange efficiency is reduced while the heat exchange is not performed properly. As a result, the power consumption increases as a whole.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to deliver air for heat exchange from the air conditioner having a height higher than the left and right widths to the entire outdoor heat exchanger.

1 is an exploded perspective view showing the configuration of a window type air conditioner according to the prior art.

Figure 2 is an exploded perspective view showing the configuration of an air conditioner having an outdoor side air flow adjustment of the preferred embodiment of the present invention.

Figure 3 is a perspective view showing the configuration of the cabinet, the front grill and the indoor heat exchanger removed from the air conditioner provided with an embodiment of the present invention.

Figure 4 is an exploded perspective view showing the configuration of the shroud and the outdoor side fan constituting the embodiment of the present invention.

5 is a cross-sectional view showing the main portion of the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

50: base fan 55: cabinet

66: control unit through 70: air guide

71: side wall 72: flow space

76: support rib 80: indoor heat exchanger

90: orifice 92: euro fence

100: turbo fan 110: discharge guide

111: discharge passage 113: partition plate

130: drive motor 135: compressor

140: shroud 141: through hole

143: upper fastening part 143 ': lower fastening part

144: upper portion inner surface 147: escape

150: outdoor fan 155: brace

160: heat exchanger 164: channel

According to a feature of the present invention for achieving the object as described above, the present invention is a window type air conditioner, the height of which is formed relatively higher than the left and right width of the cabinet constituting the appearance, is installed in the rear end of the cabinet and sucked from the outside And an outdoor heat exchanger configured to perform heat exchange between the supplied air and the working fluid of the heat exchange cycle, and having a height higher than the left and right widths, and a through hole installed inside the cabinet and guiding air to the outdoor heat exchanger. The inner surface corresponding to the upper portion of the shroud formed to narrow the gap with the outdoor heat exchanger toward the upper portion, and is installed in the through-hole formed in the shroud to suck air from the outside of the cabinet to pass through the outdoor heat exchanger to the outside It is configured to include an outdoor fan unit for transmitting.

The inner surface corresponding to the upper portion of the through hole of the shroud is formed to be rounded up and down.

According to the present invention having such a configuration, the flow resistance of the airflow delivered to the upper portion of the outdoor heat exchanger is canceled from the shroud of the air conditioner having a height higher than the left and right widths so that the heat exchange efficiency of the outdoor heat exchanger is relatively increased. There is an advantage.

Hereinafter, a preferred embodiment of an outdoor air flow structure of a window type air conditioner according to the present invention will be described in detail with reference to the accompanying drawings.

According to the drawings, the base fan 50 forms the bottom surface of the air conditioner. Various components are installed on the base fan 50. The base fan 50 has a relatively long width before and after the left and right width when viewed from the front of the air conditioner.

Cabinet 55 is installed to be fastened to both ends of the base fan 50. The cabinet 55 constitutes both sides and an upper appearance of the air conditioner, and the front, the rear, and the bottom are opened to form a space on the base fan 50. The cabinet 55 is formed relatively higher in height than the left and right width thereof. On both sides of the cabinet 55 and the rear end of the upper surface, a suction louver 57 is formed to suck outside air to the outdoor side of the air conditioner.

The front panel 60 is installed on the front surface of the cabinet 55. The front panel 60 forms a front appearance of the air conditioner, and the left and right widths of the front panel 60 are relatively small compared to the height so as to shield the front surface of the cabinet 55. The suction part 62 is formed in an area of the most part except the upper end of the front panel 60. The suction part 62 is a passage through which air in a space for air conditioning is sucked into the air conditioner. A discharge part through hole 64 is formed at the upper end of the suction part 62 so that the heat exchanged air from the indoor side of the air conditioner is discharged back into the space for air conditioning. The control part through-hole 66 is formed at the upper end of the discharge part through-hole 64. The control unit through-hole 66 is installed so that the control panel 122 to be described below to be exposed to the front of the front panel 60.

The inner space formed by the base fan 50 and the cabinet 55 is partitioned into an indoor side and an outdoor side by an air guide 70. The air guide 70 serves to guide the air flow of the indoor side is seated on the base fan 50.

The air guide 70 is composed of a base 70 'which is seated on an upper surface of the base fan 50 and a side wall 71 which is formed upright on the base 70'. The side wall 71 forms a flow space 72 that forms both side surfaces and a rear surface of the air guide 70 and is opened forward (in the direction toward the front panel 60). The height of the side wall 71 is formed to be relatively lower than the height of the cabinet 55. A fastening portion 73 ′ for fastening the brace 155 to be described below is formed at an upper end of the rear surface of the side wall 71. Reference numeral 75 is a drain and 76 is a support rib.

An indoor heat exchanger 80 is installed at the drain 75 of the air guide 70. The indoor heat exchanger (80) is installed at the rear of the front panel (60), and its size is formed to correspond to the suction part (62). The indoor heat exchanger 80 is a portion in which the working fluid flowing therein and the air sucked in the space for air conditioning exchange heat.

An orifice 90 is installed between the indoor heat exchanger 80 and the front end of the flow space 72 of the air guide 70. The orifice 90 has an orifice 91 which guides the air passing through the indoor heat exchanger 80 to the turbofan 100 installed in the flow space 72 at the center thereof. The orifice 90 has a substantially rectangular plate shape and at both ends thereof is formed a flow path 92 which is coupled to the side wall 71 of the air guide 70 and forms a flow path between both ends of the indoor heat exchanger 80.

The turbo fan 100 is installed in the flow space 72. The turbo fan 100 is to provide a driving force for the air flow in the room side, to suck the air in the space for air conditioning, passing through the indoor heat exchanger 80 and the orifice hole 91 and will be described below Through the discharge guide 110 to be delivered back to the space for air conditioning.

The discharge guide 110 is installed on the upper end of the air guide 70. The discharge guide 110 serves to guide the air discharged from the turbo fan 100 into the flow space 72 to the space for air conditioning through the discharge hole 64 of the front panel 60. . The discharge guide 111 is formed in the discharge guide to communicate with the flow space 72 and to open toward the front of the front panel 60. The discharge passage 111 is formed to have a shape that gradually expands from the upstream portion to the downstream portion as shown in FIG. 2. The downstream portion of the discharge passage 111 has a cross-sectional area corresponding to the discharge hole (64) of the front panel 60.

A partition plate 113 is formed at the rear end of the discharge guide 110 to be upright.

The partition plate 113 is formed to extend from the rear end of the discharge guide 110, the height is designed so that the upper end is in contact with the ceiling of the cabinet (55). The partition plate 113 serves to partition the indoor side and the outdoor side together with the sidewall 71 of the air guide 70.

An upper fastening part 114 for fastening the brace 155 to be described below is formed on the rear surface of the partition plate 113. Reference numeral 119 denotes a discharge louver, 120 denotes a control unit, 122 denotes a control panel, 123 denotes an operation lever, and 124 denotes a control box.

The driving motor 130 is mounted on the rear surface of the side wall 71 of the air guide 70. The drive motor 130 is provided with rotation shafts 132 and 133 at both ends thereof, and one rotation shaft 132 penetrates the side wall 71 of the air guide 70 to protrude into the flow space 72. The turbo fan 100 is installed at its tip. The other rotation shaft 133 is formed to be relatively long and extends into the shroud 140 to be described below.

The compressor 135 is installed in a space formed between the rear of the air guide 70 and the shroud 140 to be described below. The compressor 135 compresses the working fluid passing through the indoor heat exchanger 80 and delivers the compressed working fluid to the outdoor heat exchanger 160. Reference numeral 136 denotes an accumulator and 137 denotes a connecting pipe.

The shroud 140 is installed in the outdoor side of the space formed by the base fan 50 and the cabinet 55. The shroud 140 is designed so that its lower end is seated on the base pan 50, and its upper end touches the ceiling of the cabinet 55. Therefore, the shroud 140 is formed relatively higher than the left and right width.

The shroud 140 is formed with a through-hole 141 so that the rotation shaft 133 of the drive motor 130 is in the center. The through hole 141 is a passage through which the air sucked from the outside through the suction louver 57 of the cabinet 55 is sucked into the shroud 140. An outdoor side fan 150 is installed inside the shroud 140 corresponding to the center of the through hole 141. The outdoor fan 150 is installed at the tip of the rotation shaft 133.

A support 142 is formed on the top of the shroud 140 in contact with the ceiling of the cabinet 55. The shroud 140 has a lower fastening portion 143 'formed at a position corresponding to the lower fastening portion 73' of the air guide 70, and an upper fastening portion 114 of the discharge guide 110. The upper fastening portion 143 is formed at a position corresponding to the upper end portion 143. Such fastening portions 143 and 143 ′ are for fastening the brace 155.

Meanwhile, since the shroud 140 has a height higher than the left and right widths, the through hole 141 has a diameter determined by the left and right widths of the shroud 140. Therefore, the through-hole 141 is formed to extend to both ends in the left and right directions of the shroud 140, but the portion is not formed in the vertical direction. In particular, according to the mounting height of the motor 130, the through part 141 is not formed in the upper end of the shroud 140 in this embodiment. At this time, the upper end side of the shroud 140, the through-hole 141 is not formed so that the interval between the inner surface 144 and the outdoor heat exchanger 160 to be described below gradually becomes narrower toward the top. The shape of the inner surface 144 is most preferably rounded up and down, as shown in Figure 5 of the present embodiment.

The sidewall 145 forming the side surface of the shroud 140 is formed with an escape portion 147 to avoid interference with the outdoor side fan 150. The escaping part 147 is formed to protrude relatively outwardly than the side wall 145 to form a space inside the shroud 140, and the shroud 140 corresponding to the distance between the side walls 145. In order to be able to use the outdoor side fan 150 that is larger than the width of both ends of the). Such an escape portion 147 is formed to be open toward the rear of the cabinet 55.

In addition, a sealing piece 148 is provided at the tip of the escape portion 147. The sealing piece 148 is rotatably connected to the escape portion 147. That is, the connecting portion of the sealing piece 148 and the escape portion 147 is formed relatively thin, so that the sealing piece 148 is rotatably formed with respect to the escape portion 147. The sealing piece 148 seals the open portion of the escape portion 147 while the outdoor fan 150 is installed inside the shroud 140. Reference numeral 149 denotes a seating step for fastening with the outdoor heat exchanger 160, and 149 'is a fastening protrusion.

The outdoor heat exchanger 160 is installed inside the shroud 140. The outdoor heat exchanger 160 is exposed to the rear of the air conditioner through the open rear of the cabinet 55. Of course, in order to minimize the access from the outside to the outdoor heat exchanger (160) it may be installed to configure the wire in a grid shape.

The outdoor heat exchanger 160 is such that the air sucked to the outdoor side by the outdoor fan 150 is guided by the shroud 140 to pass through the working fluid. The outdoor heat exchanger 160 is bent a plurality of times to form a heat dissipation fin 162 and both ends that are fitted to the pipe 161 and the outer peripheral surface of the pipe 161 is formed to be alternately moved left and right to increase the contact area with air Channel 164. The channel 164 forms both ends of the outdoor heat exchanger 160 and has a configuration for fastening to the shroud 140. The outdoor heat exchanger 160 is formed to be relatively high in height than the left and right width. An interference avoiding portion 166 is formed in the channel 164. The interference avoiding part 166 is for avoiding interference with a handle part (not shown) of the sealing piece 148. Reference numeral 167 denotes a fastening hole to which the fastening protrusion 149 'is fastened.

Hereinafter, the operation of the outdoor air flow structure of the window type air conditioner according to the present invention having the configuration as described above will be described.

In the embodiment of the present invention looks at the air flow in the outdoor side of the air conditioner. When the air conditioner is driven, the driving motor 130 is operated to simultaneously drive the indoor fan 100 and the outdoor fan 150. Outdoor air is sucked into the outdoor side of the air conditioner through the suction louver 57 of the cabinet 55 by driving the outdoor side fan 150. The air sucked to the outdoor side is transferred to the space between the shroud 140 and the outdoor heat exchanger 160 through the through-hole 141 by the outdoor side fan 150.

The air delivered to the inside of the shroud 140 exchanges heat with the working fluid of the heat exchange cycle while passing through the outdoor heat exchanger 160. Meanwhile, some of the air delivered to the space between the shroud 140 and the outdoor heat exchanger 160 is shrouded through the space between the inner surface 144 of the shroud 140 and the outdoor heat exchanger 160. Move to the inner top of 140.

In particular, the inner surface 144 of the upper end of the shroud 140 toward the upper side and the gap between the outdoor heat exchanger 160 is narrowed to allow the air to pass evenly to the upper end of the outdoor heat exchanger 160. In this case, the inner surface 144 of the upper part of the shroud 140 is formed to be curved toward the upper and lower parts, so that the flow resistance of the air is relatively small, and in particular, the gap between the outdoor heat exchanger 160 becomes narrower toward the upper part. The air is smoothly guided to the outdoor heat exchanger 160.

As a result, the air distribution passing through the entire outdoor heat exchanger 160 may be relatively even, and the heat distribution in the outdoor heat exchanger 160 may be more efficiently performed by the uniform air distribution.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and various changes and modifications can be made by those skilled in the art within the scope of the claims. It is self-evident.

In the outdoor air flow structure of the window type air conditioner according to the present invention as described in detail above, the inner surface of the upper end of the shroud is supplied to supply the air relatively uniformly to the entire outdoor heat exchanger whose height is relatively higher than the left and right widths. In order to be curved in the vertical direction, the gap between the outdoor heat exchanger is narrowed toward the upper portion.

Therefore, the air formed by the outdoor side fan and sucked into the shroud is transferred to the entire outdoor heat exchanger, so that the heat exchange performance of the outdoor heat exchanger is improved.

Claims (2)

In the window air conditioner, the height is formed relatively higher than the left and right width of the cabinet constituting the appearance, An outdoor heat exchanger installed at a rear end of the cabinet to perform heat exchange between the air sucked from the outside and the working fluid of the heat exchange cycle, and having a height higher than the left and right widths; A shroud installed in the cabinet and provided with a through part configured to guide air to the outdoor heat exchanger, and an inner surface corresponding to an upper part of the through part is formed to have a narrower distance from the outdoor heat exchanger as the upper part thereof goes upward; And an outdoor fan unit installed in the through hole formed in the shroud to suck air from the outside of the cabinet and pass the outdoor heat exchanger to the outside. The outdoor airflow structure of claim 1, wherein an inner surface corresponding to an upper portion of the through hole of the shroud is rounded upward and downward.