KR100509050B1 - Air-flow guiding structure of Airconditioner in interior part - Google Patents

Abstract

The present invention relates to the internal structure during the indoor air oil of an integrated air conditioner. In the present invention, the interior of the air conditioner is divided into a barrier 110 to the indoor side and the outdoor side, and the indoor fan 130 is installed between the end side walls 114 and 114 'provided at both ends of the barrier 110. Both ends of the indoor fan 130 are supported by the end side walls 114 and 114 ', and a predetermined gap C is formed between both ends of the indoor fan 130 and the end side walls 114 and 114'. An auxiliary air guide member 140 is installed on the end side walls 114 and 114 ′ to correspond to both ends of the indoor fan 130. The auxiliary air guide member 140 is configured to shield the gap C, and includes a concave curved surface 142 having a curvature corresponding to both ends of the indoor fan 130, and thus, both ends of the indoor fan 130. The air discharged in the vicinity is blocked from being transferred to the gap C. According to the present invention, the air discharged from the indoor fan 130 is guided more accurately toward the air conditioner discharge port 174 to increase the air volume, and the indoor fan (between the both ends of the indoor fan 130 and the end side walls 114 and 114 '). The air discharged from 130 may be prevented from flowing.

Description

Air-flow guiding structure of airconditioner in interior part of integrated air conditioner

The present invention relates to an integrated air conditioner, and more particularly to an internal structure during air oil for guiding the flow of air formed on the indoor side of the air conditioner by an indoor fan.

In the integrated air conditioner, all the parts constituting the air conditioner are provided in one case, and examples thereof include window type air conditioners and wall-mounted air conditioners. Such a window type air conditioner and a wall-mounted air conditioner are located between a space for air conditioning and an external space so that the front end side of the air conditioner is exposed to the space for air conditioning and the rear end side of the air conditioner is exposed to the external space.

In particular, the wall-mounted air conditioner is installed through the wall of the space for air conditioning. The front end side of the air conditioner is exposed to the space for air conditioning, and the rear end side is exposed to the outside space, so that the inside of the air conditioner is exposed. The outdoor air is configured to enter and exit the outdoor side. The configuration of a conventional wall-mounted air conditioner having such a configuration is shown in FIGS. 1 and 2.

As shown in these figures, the base fan 1 forms the bottom surface of the air conditioner, and various components constituting the air conditioner are seated on the base fan 1. The base fan 1 is formed in a long rectangular shape to the left and right, the barrier 3 is installed across the transverse direction. The barrier 3 serves to partition the interior of the air conditioner into an indoor side and an outdoor side. The end side walls 5 and 5 'are provided at both ends of the barrier 3 so as to be bent and extended toward the front of the air conditioner, and the partition side walls 6 are arranged between the end side walls 5 and 5'. It is provided. The partition side wall 6 is formed and mounted separately from the barrier 3, and partitions the indoor side partitioned by the barrier 3 into a part where air flow is made and a part which is not, and which will be described below. A motor 19 for driving the fan 17 is provided. Reference numeral 7 is a ventilation hole formed in the barrier (3).

The condensate receiver 9 is installed at the front end of the base fan 1. The indoor heat exchanger 11 is installed on the condensate receiver 9. The indoor heat exchanger 11 performs heat exchange between the working fluid of the heat exchange cycle and the air sucked in the space for air conditioning. The upper end of the indoor heat exchanger 11 is shielded by a heat exchanger cover 13. Both ends of the heat exchanger cover 13 are supported by the end side wall 5 and the partition side wall 6 of the barrier 3, respectively. The heat exchanger cover 13 is provided with a heater 15 extending downward, and the heater 15 is seated at a position corresponding to the rear surface of the indoor heat exchanger 11. Reference numeral 15 'is a heater frame.

An indoor fan 17 is installed at the rear of the indoor heat exchanger 11. Both ends of the indoor fan 17 are supported between the end side wall 5 and the partition side wall 6 of the barrier 3. The indoor fan 17 provides a driving force for the air flow in the indoor side of the air conditioner. One end of the indoor fan 17 is supported by an auxiliary plate 18 provided on the end side wall 5 of the barrier 3, and the other end is installed in a mounting hole 6 ′ formed in the partition side wall 6. Connected to the motor 19 is rotated.

A scroll 21 is provided inside the barrier 3 in which the indoor fan 17 is installed. The scroll 21 serves to guide the airflow formed by the indoor fan 17.

On the other hand, the front panel 23 forms the interior appearance of the air conditioner. The front panel 23 is provided with a suction grill 24, which is a passage through which the air of the space for air conditioning is sucked into the inside of the air conditioner on its front surface, and at an upper end of the front panel inclined toward the front upper portion. 24 ') is provided.

The discharge part 24 ′ is provided with a discharge guide member 27 to direct air guided by the scroll 21 to a desired direction of a space for air conditioning. The discharge guide member 27 is installed in the discharge part 24 ′ corresponding to the upper end of the heat exchanger cover 13, and includes a louver for controlling the direction of air discharged from the discharge part 24 ′ ( 29).

The barrier 3 is provided with a ventilation hole 30 to selectively communicate the outdoor side and the indoor side partitioned by the barrier 3 so as to send fresh air from the outdoor side to the space for air conditioning. The ventilation hole 30 is provided with a filter 32 for filtering foreign matter mixed in the air, the ventilation hole 30 is installed in the ventilation hole 30 to open and close the ventilation hole (30).

Then, the sleeve 36 forms an exterior including a part of the outdoor side and the indoor side of the air conditioner. The sleeve 36 is formed in a rectangular cylindrical shape to form both sides and the upper and lower surfaces of the air conditioner.

The outdoor heat exchanger 38 is installed on the outdoor side of the air conditioner. The outdoor heat exchanger 38 discharges heat of the space for air conditioning to the outside through heat exchange between the working fluid of the heat exchange cycle and the outdoor air. A shroud 40 is installed on the base fan 1 to surround the outdoor heat exchanger 38. The shroud 40 guides the outdoor air sucked through the rear end of the sleeve 36 to evenly pass through the outdoor heat exchanger 38.

Inside the shroud 40 is provided with an outdoor fan 42 for producing a flow of air flowing in the outdoor side of the air conditioner. The outdoor fan 42 is installed and driven on a rotation shaft of the motor 46 mounted on the motor mount 44 installed on the base fan 1.

A compressor 48 constituting a heat exchange cycle is installed at the outdoor side of the base fan 1, and the barrier 3 and the shroud 40 are connected by a brace 49. In the figure, reference numeral 21 'is a top plate.

According to the prior art having the configuration as described above, the integrated air conditioner is operated as follows. Here, the explanation is based on the cooling operation.

When the air conditioner is driven, the indoor fan 17 and the outdoor fan 42 are driven to form an airflow flowing into and out of the air conditioner. First, in the indoor side, the air of the space for air conditioning is sucked into the interior through the suction grille 24 by the driving of the indoor fan 17, and the air passing through the suction grille 24 is the indoor heat exchanger ( Heat is passed through 11) to reach a relatively low temperature. Air passing through the indoor heat exchanger 11 is sucked into the indoor fan 17, discharged from the indoor fan 17, and guided by the scroll 21. The air guided along the scroll 21 is determined by the louver 29 while passing through the discharge part 27 and is discharged into a space for air conditioning.

In the outdoor side, external air is sucked through the rear portion of the sleeve 36 by the driving of the outdoor fan 42 and guided between the shroud 40 and the barrier 3. Air flowing between the shroud 40 and the barrier 3 is sucked into the outdoor fan 42, discharged from the outdoor fan 42, and passes through the outdoor heat exchanger 38. The outdoor heat exchanger 38 exchanges heat with the working fluid of the heat exchange cycle while the air discharged from the outdoor fan 42 passes, thereby dissipating the heat of the space for air conditioning to the outdoor.

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

That is, the indoor fan 17 is rotated by the motor 19 in a state where both ends are supported on the end side wall 5 and the partition side wall 6 of the barrier 3 so as to operate the indoor heat exchanger 11. It sucks the air passing through and sends it to the discharge part 24 '. However, between both ends of the indoor fan 17 and the end side wall 5 and the partition side wall 6, there is a predetermined clearance C as shown in FIG. In the direction toward the discharge portion 24 ′ in the gap C and the gap C, air discharged near both ends of the indoor fan 17 flows as shown by arrows.

As described above, the airflows formed at both ends of the indoor fan 17 do not flow around the gap C and are mixed with the stagnant air to generate vortices, thereby causing airflow noise.

When the air discharged near both ends of the indoor fan 17 flows toward the end side wall 5 and the partition side wall 6, the airflow flowing to the discharge part 24 ′ is diffused. There is also a problem.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to allow the air flow formed by the indoor fan of the air conditioner to flow more smoothly.

Another object of the present invention is to ensure that there is no air flow loss of the air flow formed by the indoor fan of the air conditioner.

According to a feature of the present invention for achieving the object as described above, the present invention comprises a barrier for partitioning the indoor side and the outdoor side in the air conditioner; An indoor fan supporting both ends of the barrier and forming an air flow in the air conditioner; An air guide member for guiding the air discharged from the indoor fan to the outside of the air conditioner; It is installed at a position corresponding to both ends of the indoor fan is mounted on the end side wall provided in the barrier, the portion facing the both ends of the indoor fan is formed with a concave curved surface corresponding to the curvature of the indoor fan, And an auxiliary air guide member for guiding air flow at both ends of the fan.

The indoor fan is a sirocco fan having a long left and right lengths compared to its diameter.

The auxiliary air guide member is configured to surround both upper ends of the indoor fan, and shields a gap between both ends of the indoor fan and both ends of the barrier.

The auxiliary air guide member is mounted to an end side wall provided in the barrier, and portions facing both ends of the indoor fan are formed in a concave indentation surface, and have a curvature corresponding to the curvature of the indoor fan.

In the internal structure of the air conditioner of the air conditioner according to the present invention having such a configuration, the flow of air to the gap side formed between both ends of the indoor fan and the barrier is blocked by the auxiliary air guide member, so that It is possible to maximize the amount of air discharged to the space for air conditioning, there is an advantage that can block the noise caused by the air flow.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the internal structure of an integrated air conditioner according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 4 is an exploded perspective view showing the configuration of an integrated air conditioner employing the internal structure of the air oil during the present invention.

As shown in the figure, the base fan 100 is a rectangular plate shape having a predetermined area as a part on which various components constituting the air conditioner are mounted. The bottom surface of the base fan 100 is formed with irregularities in various ways depending on the type of components to be mounted.

The barrier 110 is installed across the base pan 100 laterally. The barrier 110 serves to partition a space inside the air conditioner into an indoor side and an outdoor side. The rear plate 112 of the barrier 110 is a portion that partitions the indoor side and the outdoor side, and end plates 114 and 114 'are provided at both ends of the rear plate 112, respectively. The end plates 114 and 114 'support the indoor fan 130 to be described below, and at the same time, form a space in which air flow formed by the indoor fan 130 flows. Mounting flanges 114f are formed at the ends of the end side plates 114 and 114 'in the vertical direction. The mounting flange 114f is formed to extend in a predetermined width in the direction facing each other in the front end of the end side plate 114, 114 'in this embodiment, but is not necessarily so, it may be formed to extend in various directions.

The back plate 112 is formed with a ventilation hole 116 to introduce the air from the outdoor side to the indoor side to perform the ventilation of the space for air conditioning. The ventilation hole 116 is provided with a filter 118 for purifying the air passing through the ventilation hole 116. And the ventilation hole 116 is selectively opened and closed by the ventilation door 119.

The control unit barrier 120 is connected to one end of the barrier 110. The control unit barrier 120 serves to partition the indoor side and the outdoor side at a portion corresponding to the control box 122 to be described below. Therefore, the entire space of the air conditioner is partitioned into the indoor side and the outdoor side by the barrier 110 and the control unit barrier 120.

The control unit barrier 120 is provided with a control box 122 is installed to control the operation of the air conditioner. The control box 122 is provided with a control panel 123 to which various dials and buttons are mounted, and the control panel 123 is air-conditioned through the control panel unit 179 of the front panel 170 to be described below. Is exposed to the outside.

The barrier 110 is provided with a scroll 125 for guiding the flow of air formed by the indoor fan 130. The scroll 125 is largely composed of an adiabatic scroll 126 and the scroll cover 128. However, depending on design conditions, the insulating scroll 126 may not be used. The scroll cover 128 has a shape corresponding to the outer surface of the indoor fan 130 to guide the air discharged from the indoor fan 130. Reference numerals 126 ′ and 128 ′ denote ventilation holes corresponding to the ventilation holes 116 of the barrier 110.

An indoor fan 130 is installed inside the barrier 110, more specifically, inside the barrier 110 corresponding to the scroll cover 128. The indoor fan 130 is a driving force for forming a flow of air in the indoor side of the air conditioner. In this embodiment, the indoor fan 130 is a sirocco fan formed long in a cylindrical shape.

Auxiliary air guide members 140 are provided on inner surfaces of the end side plate 114 of the barrier 110 corresponding to both ends of the indoor fan 130. As shown in FIG. 6, the auxiliary air guide member 140 is provided with a concave curved surface 142 having a curvature corresponding to an outer surface of both ends of the indoor fan 130. The concave curved surface 142 is positioned to face each other with the upper surface of both ends of the indoor fan 130, the gap (C) formed between both ends of the indoor fan 130 and the end side plate 114 of the barrier 110. By shielding the air is discharged from the indoor fan 130 is prevented from being dispersed near the inner surface of the end side plate 114 to form a vortex.

The indoor fan 130 is driven by an indoor motor 150 mounted to the one end plate 114 '. The indoor motor 150 is mounted on an outer surface of the end side plate 114 'and its rotating shaft is connected to one end of the indoor fan 130 through the end side plate 114'.

The indoor motor 150 is mounted on the outer surface of the end plate 114 'by the motor bracket 152. The motor bracket 152 has a rear support part 154 corresponding to the rear surface of the indoor motor 150, that is, the opposite side provided with the rotating shaft. The rear support part 154 has an area and a shape at least corresponding to the rear surface of the indoor motor 150, and a through hole 155 is formed through the center thereof. A mounting leg 156 is provided to extend in the longitudinal direction of the indoor motor 150 from the rear support 154. The mounting legs 156 are provided around the rear support 154 at a predetermined interval. A distal end of the mounting leg 156 is fastened to the outer surface of the end side plate 114 'with a screw.

An indoor heat exchanger 160 is installed at the indoor side corresponding to the front of the indoor fan 130. The indoor heat exchanger 160 is a portion in which the working fluid of the heat exchange cycle and the air sucked in the space for air conditioning exchange heat. The indoor heat exchanger 160 is supported by the condensate receiver 162 installed on the base fan 100. The condensate receiver 162 collects condensate generated by the indoor heat exchanger 160 and discharges the condensate to the outdoor side.

The heat exchanger cover 165 is provided at an upper portion of the indoor heat exchanger 160. Both ends of the heat exchanger cover 165 are mounted at an upper end of the mounting flange 114f of the barrier 110 to shield the upper end of the indoor heat exchanger 160. The heat exchanger cover 165 is provided with a heater 168. The heater 168 serves to supply heat to the air in the space for air conditioning when the air conditioner is heated. The heater 168 is located on the rear surface of the indoor heat exchanger 160, that is, the surface facing the indoor fan 130.

A shielding grill 169 is installed to one side of the heat exchanger cover 165. The shielding grill 169 is installed at the heat exchanger cover 165 and the indoor fan 130 outside the air conditioner. ) Serves to block the insertion of foreign objects such as the user's finger. Such shielding grill 169 is configured by connecting a wire having a predetermined thickness in a lattice shape. The shield grill 169 is a position corresponding to the discharge grill 176 to be described below.

On the other hand, the front panel 170 is provided on the front of the air conditioner. The front panel 170 is configured to protrude to the front of the air conditioner, the front grill 172 is provided on the front. The air in the space for air conditioning is sucked into the indoor side of the air conditioner by the driving of the indoor fan 130 through the front grill 172.

An upper end of the front panel 170 is formed to be inclined toward the front upper portion, in which a discharge port 174 and a control panel unit 179 are formed. Here, the discharge port 174 occupies a relatively larger area. The discharge grill 176 is seated in the discharge port 174. A filter 178 is installed behind the front grill 172 of the front panel 170. The filter 178 filters the foreign matter in the air sucked through the front grill 172.

Now, the outdoor side configuration of the air conditioner will be described. The outdoor motor 180 is installed at the outdoor side partitioned by the barrier 110. The outdoor motor 180 is mounted to the motor mount 182 seated on the base fan 100. The outdoor fan 184 is installed on the rotation shaft of the outdoor motor 180 and is driven by the outdoor motor 180.

On the other hand, a shroud 186 is installed on the base fan 100 corresponding to the rear end of the outdoor side. A through hole 186 'is formed through the center of the shroud 186, and the outdoor fan 184 is positioned inside the through hole 186'. An outdoor heat exchanger 187 is installed inside the shroud 186. The outdoor heat exchanger 187 is a place where the working fluid of the heat exchange cycle and the air sucked from the outside are heat exchanged. One surface of the outdoor heat exchanger 187 is installed to face the outside through the back of the air conditioner. Reference numeral 188 denotes a compressor constituting a heat exchange cycle, and 189 denotes a brace connecting the shroud 186 and the barrier 110.

The sleeve 190 is a part seated in the through-hole formed in the wall partitioning the space for air conditioning and the outside, the sleeve 190 is formed in a rectangular cylinder shape and a part of the outdoor and indoor side of the air conditioner Wraps. That is, the front end of the sleeve 190 is connected to the front panel 170, the back is open. The sleeve 190 forms an upper surface, both surfaces, and a lower surface of the air conditioner.

A rear portion 192 and a rear grill 194 are installed at the rear end of the sleeve 190. The rear portion 192 provides a smooth flow of air between the outdoor side and the outdoor side of the air conditioner. It serves to shield the outdoor side. The rear grill 194 controls the direction of the air discharged from one end of the outdoor heat exchanger 187 so that the air discharged from the outdoor heat exchanger 187 is not sucked back to the outdoor side of the air conditioner.

On the other hand, between both ends of the sleeve 190 and the outdoor heat exchanger 187 is provided with a passage through which the outside air is sucked to the outdoor side of the air conditioner. The passage is formed by forming the left and right widths of the outdoor heat exchanger 187 smaller than the left and right widths of the sleeve 190.

Hereinafter, the operation of the internal structure during the indoor side air oil of the integrated air conditioner according to the present invention having the configuration as described above will be described in detail.

The air conditioner of the present invention can be operated in the cooling and heating mode, the present specification will be described taking the case of operating in the cooling mode as an example. In the cooling mode, the air conditioner discharges heat from the space for air conditioning to the outside.

To this end, when the air conditioner is driven, the indoor fan 130 is rotated in the indoor side, and the air in the space for air conditioning is sucked into the air conditioner through the front grill 172 of the front panel 170.

The air sucked through the front grill 172 is purified by the filter 178 and heat exchanged with the working fluid of the heat exchange cycle while passing through the indoor heat exchanger 160. Air that passes through the indoor heat exchanger 160 and heats to a relatively low temperature is sucked into the indoor fan 130.

The air sucked into the indoor fan 130 and discharged again flows toward the discharge port 174 while being guided by the scroll 125. In this case, the gap C formed between both ends of the indoor fan 130 and the end side walls 114 and 114 ′ of the barrier 110 is shielded by the auxiliary air guide member 140.

Therefore, the air discharged near both ends of the indoor fan 130 is guided by the auxiliary air guide member 140 to the discharge port 174. At this time, the air guided to the discharge port 174 side maintains a constant value without widening its cross sectional area. Therefore, the air volume of the air delivered to the discharge port 174 becomes relatively large.

On the other hand, since the concave curved surface 142 of the auxiliary air guide member 140 has a curvature corresponding to both ends of the indoor fan 130, between the concave curved surface 142 and both ends of the indoor fan 130; Since the air discharged from both ends of the indoor fan 130 is hardly introduced, no vortex is formed between both ends of the indoor fan 130 and the end side plates 114 and 114 ′ of the barrier 110.

In addition, the air flowing through the discharge port 174 is discharged into the space for air conditioning through the discharge grill 176, and circulates inside the space for air conditioning to increase the temperature, and then the front grill 172 again. Through the air conditioner.

Next, the working fluid which receives the heat from the indoor heat exchanger 160 is transferred to the outdoor heat exchanger 187 of the outdoor side to exchange heat with the air sucked from the outside to discharge the heat to the outside.

That is, when the outdoor fan 184 is driven and rotated by the outdoor motor 180, outdoor air is sucked to the outdoor side of the air conditioner through the rear grill 194, and the shroud 186 and the barrier It flows through between 110 and 120. Air guided between the shroud 186 and the barriers 110 and 120 is sucked into the outdoor fan 184 and flows to the outdoor heat exchanger 187.

As air passes through the outdoor heat exchanger 187, it exchanges heat with the working fluid of the heat exchange cycle. Therefore, since the air is in the cooling mode, the air is discharged through the rear part 192 of the air conditioner by receiving heat from the working fluid.

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

In the interior air oil internal structure of the integrated air conditioner according to the present invention as described in detail above, the auxiliary air guide member shields a gap formed between both ends of the indoor fan and the barrier, which is configured to have a cylindrical shape.

Therefore, the gap formed between both ends of the indoor fan and the barrier is shielded by the auxiliary air guide member, and at the same time, the air discharged from both ends of the indoor fan is guided by the auxiliary air guide member, so that the air is discharged through the outlet of the air conditioner. The amount of air flow becomes relatively large.

In addition, since the air is hardly delivered to the gap between the air barriers discharged from both ends of the indoor fan and the both ends of the indoor fan, the air stagnated in the gap between the barrier and the indoor fan does not interfere with the flow of the air discharged from the indoor fan. Thus, airflow noise can be minimized.

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

Figure 2 is a cross-sectional view showing the configuration of an integrated air conditioner according to the prior art.

Figure 3 is a schematic cross-sectional view showing the relationship between the indoor fan and the barrier of the integrated air conditioner according to the prior art.

Figure 4 is an exploded perspective view showing the configuration of an integrated air conditioner having a preferred embodiment of the interior air oil inside structure according to the present invention.

Figure 5 is a perspective view showing that the auxiliary air guide member constituting the embodiment of the present invention is mounted on the barrier.

Figure 6 is a perspective view showing a detailed configuration of the auxiliary air guide member constituting an embodiment of the present invention.

7 is an operation state in which the air discharged from the indoor fan is guided by the auxiliary air guide member in the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: base fan 110: barrier

112: back plate 114, 114 ': end side plate

116: ventilator 118: filter

119: ventilation door 120: control unit barrier

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122: control box 123: control panel

125: scroll 126: insulation scroll

128: scroll cover 130: indoor fan

140: auxiliary air guide member 150: indoor motor

152: motor bracket 160: indoor heat exchanger

162: condensate receiver 165: heat exchanger cover

168: heater 170: front panel

172: front grill 174: discharge port

176: discharge grill 179: control panel

180: outdoor motor 184: outdoor fan

186: shroud 187: outdoor heat exchanger

188: compressor 190: sleeve

192: back

Claims (4)

A barrier partitioning the indoor side and the outdoor side in the air conditioner; An indoor fan supporting both ends of the barrier and forming an air flow in the air conditioner; An air guide member for guiding the air discharged from the indoor fan to the outside of the air conditioner; It is installed at a position corresponding to both ends of the indoor fan is mounted on the end side wall provided in the barrier, the portion facing the both ends of the indoor fan is formed with a concave curved surface corresponding to the curvature of the indoor fan, The auxiliary air guide member for guiding the air flow at both ends of the fan; internal structure during the interior air oil of the integrated air conditioner comprising a. The internal structure of the air conditioner of claim 1, wherein the indoor fan is a sirocco fan which is formed to have a long right and left length in relation to its diameter. The indoor side of the integrated air conditioner of claim 2, wherein the auxiliary air guide member surrounds an upper end of both ends of the indoor fan, and shields a gap between both ends of the indoor fan and both ends of the barrier. Internal structure during air oil. delete