KR20030032582A - Air bypass apparatus for air conditioner - Google Patents

Abstract

PURPOSE: An air bypass apparatus of an integral type air conditioner is provided to normally execute operation under overload. CONSTITUTION: An apparatus includes a partitioning member, an air guide(50) forming an air channel in an indoor side of an air conditioner, partitioning the indoor side and an outdoor side of the air conditioner; a damper(60) selectively making air flow between the indoor side and the outdoor side through a flowing port(64) formed on the partitioning member; and a driving motor(62) driving the damper.

Description

Air bypass apparatus for integrated air conditioner

The present invention relates to an air conditioner, and more particularly, to an air flow apparatus of an integrated air conditioner in which an air can be selectively transferred between an indoor side and an outdoor side in an integrated air conditioner.

1 is an exploded perspective view showing a main configuration of an integrated air conditioner according to the prior art. Looking at the internal structure of the integrated air conditioner with reference to this, the base fan (1) forms the bottom of the air conditioner. The front panel 3 is installed on the indoor front surface of the base fan 1.

In the front panel 3, a suction part 3i, which is a passage through which air in the room is introduced, is formed at a lower side thereof, and an upper part of the front panel 3 has a discharge grill 3e for discharging the air heat-exchanged inside the air conditioner back into the room. Is formed. Although not shown in the drawings, a suction grill (not shown) is installed in the suction unit 3i, and a filter (not shown) is installed between the suction grill and the suction unit 3i.

An indoor heat exchanger 5 is installed inside the front panel 3. The indoor heat exchanger (5) is for heat exchange between the air sucked through the suction unit (3i) and the working fluid of the air conditioning cycle, more precisely installed in the air guide (7) to be described below.

An air guide 7 is installed on the base fan 1 at the rear of the indoor heat exchanger 5. The air guide 7 serves to partition the air conditioner into the indoor side and the outdoor side as a whole. Therefore, the indoor side and the outdoor side are blocked by the air guide 7 to block the flow of air therebetween.

A scroll 9 is installed inside the air guide 7. The scroll 9 has a flow guide surface 9g formed therein with a predetermined curvature from one side to the other side.

An orifice 11 is installed to correspond to the front surface of the scroll 9, that is, the indoor heat exchanger 5. The orifice 11 is perforated with an orifice hole 12 which guides the air flowing through the indoor heat exchanger 5 to the sirocco fan 13 which will be described below. A discharge guide 11e for guiding the air heat-exchanged with the discharge grill 3e is integrally formed at the upper end of the orifice 11.

Meanwhile, an indoor side fan 13 is installed inside the scroll 9 to allow indoor air to flow through the suction unit 3i, the indoor heat exchanger 5, and the orifice hole 12. The indoor fan 13 sucks air through the orifice hole 12 and blows it in the centrifugal direction. The blown air is guided along the flow guide surface 9g to the discharge guide 11e. Flows. Sirocco fans were used as such indoor fans, but recently turbo fans are mainly used.

The part described so far is the indoor side of the integrated air conditioner, and now describes the configuration of the outdoor side partitioned from the indoor side by the air guide 7.

On the outdoor side of the air guide 7 is mounted a motor 15 for rotating the indoor fan 13 and the outdoor fan 17 to be described below. The motor 15 protrudes in a direction in which the rotation shafts face each other. One side of the rotating shaft extends to the center of the scroll (9) through the air guide (7) to rotate the indoor fan (13).

In addition, an outdoor fan 17 is installed on the outdoor rotation shaft of the motor 15. The outdoor fan 17 serves to exchange heat by sucking outside air to the outdoor side of the air conditioner and passing the outdoor heat exchanger 19 to be described below. The outdoor fan 17 is provided with a ring 17r that connects the wing tip thereof.

Next, a shroud 18 for guiding the air flow formed by the outdoor side fan 17 is installed on the base fan 1. The shroud 18 is formed with a through hole 18 ′ for forming an air flow in accordance with the rotation of the outdoor fan 17 flowing with the outdoor heat exchanger 19 so that the outdoor fan 17 is located. The shroud 18 guides the air sucked from the outside by the outdoor fan 17 and serves to flow to the entire outdoor heat exchanger 19 to be described below.

The outdoor heat exchanger 19 is installed on the outdoor side of the base fan 1 so as to face the shroud 18. The outdoor heat exchanger 19 allows the air sucked from the outside and the working fluid of the air conditioning cycle to exchange heat. Although not shown in the drawings, the outdoor side is provided with a compressor, an expansion valve, and the like that are components of an air conditioning cycle.

Finally, the outer case 20 shields the various parts forming the air conditioner as described above from the outside. The outcase 20 as described above constitutes the appearance of the air conditioner.

In the integrated air conditioner having such a configuration, air flows during the cooling operation will be described with reference to FIG. 2. First, as indicated by arrow A, air in the space for air conditioning is sucked through the suction part 3i to the indoor side. The air becomes air of a relatively low temperature by heat exchange in the indoor heat exchanger 5, and is again driven through the discharge portion 3e by the driving force of the indoor side fan 13, as indicated by the arrow B. It is discharged into the space for air conditioning.

On the outdoor side, air is sucked by the drive of the outdoor fan 17 as indicated by the arrow C through the vent hole formed in the cabinet 20. The air sucked in this way is guided along the shroud 18 to be heat exchanged while passing through the outdoor side heat exchanger 19 through the through hole 18 '. Here, the air receives heat from the working fluid. And the air passing through the outdoor side heat exchanger 19 is discharged to the outside through the back of the air conditioner.

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

In other words, the integrated air conditioner of the prior art is clearly distinguished between the indoor side and the outdoor side, and almost closed between them. In the cooling operation, the indoor side is a relatively low temperature, but the outdoor side is a relatively high temperature.

At this time, for example, if the air conditioner is continuously operated when the temperature is very high, the compressor takes a lot of load, and the compressor becomes crowded and the power consumption increases relatively.

In addition, when the air conditioner is operated as described above, the heat generated from the compressor is not properly released as the temperature of the outdoor side is relatively increased, so that the compressor may be stopped by the protection operation against the load. The condensation temperature in the device 19 also increases, which also causes a problem of increased power consumption.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, to selectively flow the indoor side and the outdoor side in the integrated air conditioner so that the operation during overload can be performed normally.

Another object of the present invention is to lower the power consumption of the integrated air conditioner.

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

Figure 2 is a perspective view showing the appearance and the air flow of the integrated air conditioner according to the prior art.

Figure 3 is a plan sectional view showing the configuration of an integrated air conditioner employed in the preferred embodiment of the air flow apparatus according to the present invention.

Figure 4 is a partial perspective view showing the main configuration of the embodiment shown in FIG.

Figure 5 is an operating state showing the air flow path in the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

40: base fan 42: front panel

43: suction part 45: discharge part

50: air guide 52: indoor heat exchanger

53: channel 54: orifice

56: indoor fan 58: discharge flow path

60: damper 62: drive motor

64: flow port 70: motor

72: outdoor fan 74: shroud

75: through hole 76: outdoor heat exchanger

78: compressor 80: cabinet

According to a feature of the present invention for achieving the object as described above, the present invention is an integrated air conditioner installed on the indoor side and the outdoor side in which the parts constituting the heat exchange cycle are respectively partitioned, the indoor side and the outdoor side And a partition member for partitioning, a damper for selectively allowing air to flow between the indoor side and the outdoor side through a flow hole formed in the partition member, and a drive motor for driving the damper.

The partition member is an air guide forming an air passage on the indoor side and partitioning the indoor side and the outdoor side.

The damper is rotated by a predetermined angle by the driving motor, and forms a flow path to pass a portion of the heat-exchanged air to the outdoor side through the flow port while passing through the indoor side heat exchanger constituting the heat exchange cycle.

The damper is controlled in accordance with the working fluid temperature in the outdoor components of the components constituting the heat exchange cycle.

The present invention having such a configuration has an advantage in that the condenser and the compressor operate normally by partially guiding indoor air to the outdoor side when the air conditioner is overloaded so that the power consumption is relatively reduced.

Hereinafter, the configuration of a preferred embodiment of the air flow apparatus of the integrated air conditioner according to the present invention as described above will be described in detail with reference to the accompanying drawings.

3 is a plan sectional view showing a configuration of a preferred embodiment of the present invention, Figure 4 is a partial perspective view showing the main configuration of the embodiment of the present invention.

As shown in these figures, on the base fan 40 constituting the bottom surface of the air conditioner, the parts are partitioned into the indoor side and the outdoor side. First, the front panel 42 is installed at the innermost end of the room. The front panel 42 is formed with a suction part 43, which is a passage for sucking air in a space for air conditioning to the indoor side of the air conditioner, and on one side of the suction part 43, the heat-exchanged air is re-aired. The discharge part 45 which discharges to the space for coordination is formed. The discharge part 45 may be formed on the side or above the suction part 43.

An air guide 50 is installed on the base fan 40 to divide the indoor side and the outdoor side and to guide the air flow in the indoor side. Of course, in addition to the air guide 50, a scroll or barrier may partition the indoor side and the outdoor side. An indoor heat exchanger 52 is installed at one end of the air guide 50 at a position corresponding to the rear side of the suction part 43. The indoor heat exchanger 52 is a place where the working fluid of the heat exchange cycle heat exchanges with the air sucked in the space for air conditioning. Channels 53 are provided at both ends of the indoor heat exchanger 52.

An orifice 54 is installed on the air guide 50 corresponding to the rear surface of the indoor heat exchanger 52. The orifice 54 serves to guide the air heat exchanged in the indoor heat exchanger 52. An indoor fan 56 is installed inside the air guide 50 to provide a driving force for air flow in the indoor side. On one side of the air guide 50, a discharge passage 58 for guiding the air discharged from the indoor fan 56 to the discharge unit 45 is formed on one side.

Next, a damper 60 is installed at one side of the air guide 50. The damper 60 is installed between one end of the air guide 50 and a channel 53 forming one end of the indoor heat exchanger 52. The damper 60 is driven by the drive motor 62, the drive motor 62 may be directly connected to the center of rotation of the damper 60, or may be connected through a separate power transmission mechanism.

The damper 60 serves to guide a part of the air passing through the indoor heat exchanger 52 to one side of the air guide 50 instead of the indoor fan 56. That is, the front end portion is operated to be selectively positioned on one surface of the channel 53 or the indoor heat exchanger (52).

On the other hand, a flow port 64 for guiding the air flow by the damper 60 to the outdoor side is formed on one side of the air guide 50. The flow port 64 is formed at a position adjacent to the damper 60, preferably should be formed to face the portion opened and closed by the damper 60.

Next, the motor 70 is installed on the outdoor side of the air conditioner. The motor 70 may be directly mounted on the rear surface of the air guide 50 or supported on a separate bracket. The motor 70 is provided with both ends of the rotation shaft, one of which is provided with an indoor side fan 56, the other is provided with an outdoor side fan 72.

The shroud 74 guides the air flow in the outdoor side. The outdoor fan 72 is installed in the through hole 75 of the shroud 74, and an outdoor heat exchanger 76 is provided at a rear end of the base fan 40 corresponding to the inside of the shroud 74. Is installed. The outdoor heat exchanger (76) serves to discharge the heat of the room to the outside when the operating fluid of the heat exchange cycle and the air sucked from the outside to heat exchange, when the air conditioner cooling operation.

On the other hand, a compressor 78 constituting a heat exchange cycle is installed on the base fan 40 on the outdoor side. The compressor 78 is connected to the indoor heat exchanger 52 and the outdoor heat exchanger 76, respectively. The installation position of the compressor 78 is between the air guide 50 and the shroud 74, most preferably adjacent to the flow port (64).

The cabinet 80 forms the upper surface and both side surfaces of the air conditioner as described above. The cabinet 80 is to shield the components and to form an air flow path inside the air conditioner.

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

It will be described with reference to Figure 5 that the air conditioner of the present invention is operated in the cooling mode. When the air conditioner is driven, the motor 70 is operated to rotate the indoor fan 56 and the outdoor fan 72. In addition, the compressor 78 is driven so that the working fluid circulates the heat exchange cycle.

By driving the indoor fan 56, air in the space for air conditioning is sucked through the suction part 43 and passes through the indoor heat exchanger 52. The heat exchanged in the indoor heat exchanger (52) to a relatively low temperature is sucked into the indoor fan (56) and discharged in the circumferential direction thereof. Air discharged in this way is guided by the air guide 50 is delivered to the discharge flow path (58). The air delivered to the discharge passage 58 is discharged to the space for air conditioning through the discharge unit 45.

Next, outdoor air is sucked into the indoor side by driving the outdoor side fan 72. The air sucked into the indoor side is guided by the shroud 74 to be sucked into the outdoor side fan 72, and the air discharged from the outdoor side fan 72 passes through the outdoor heat exchanger 76, thereby exchanging heat. Heat exchange with the working fluid of. At this time, heat is transferred from the working fluid to the air, and heat of the room is released to the outside.

On the other hand, if an overload is detected by a sensor (not shown) and delivers a relatively low temperature air of the indoor side to the outdoor side. That is, the operation of the damper 60 is determined by sensing the temperature of the working fluid at the outlet of the compressor 78 or the temperature of the center of the outdoor heat exchanger 76.

If it is determined that the overload is applied, the drive motor 62 operates the damper 60 to transfer air of a relatively low temperature of the indoor side to the outdoor side through a path as indicated by a dotted line in FIG. 5.

That is, when the tip of the damper 60 is located in the channel 53 of the indoor heat exchanger 52 as shown in FIG. 3 or FIG. 4, the indoor air is transferred to the outdoor side through the flow port 64. It doesn't work. However, when the damper 60 is driven by the drive motor 62 and the front end thereof is located at the rear surface of the indoor heat exchanger 52 as shown in FIG. 5, the damper 60 passes through the indoor heat exchanger 52. A portion of the heat-exchanged air flows through the open portion of the damper 60 to the flow port 64, and is transferred to the outdoor side through the flow port 64.

As such, the relatively low temperature air delivered to the outdoor side lowers the temperature of the compressor 78 and is transferred to the outdoor heat exchanger 76 by the outdoor side fan 72 to exchange heat with the working fluid and discharge the outdoor 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.

The air flow apparatus of the air conditioner according to the present invention as described in detail above to improve the operating characteristics of the heat exchange cycle components installed in the outdoor side by selectively transferring the air from the indoor side to the outdoor side in the integrated air conditioner. Therefore, the air conditioner is prevented from being continuously loaded, thereby minimizing power consumption and allowing each component to operate normally.

Claims (4)

In the integrated air conditioner installed on the indoor side and the outdoor side, each of the components constituting the heat exchange cycle, A partition member for partitioning the indoor side and the outdoor side; A damper for selectively allowing air to flow between the indoor side and the outdoor side through a flow hole formed in the partition member; An air flow apparatus of an integrated air conditioner, characterized in that it comprises a drive motor for driving the damper. The airflow apparatus of claim 1, wherein the partition member is an air guide forming an air passage on the indoor side and partitioning the indoor side and the outdoor side. The flow path of claim 1 or 2, wherein the damper is rotated by a predetermined angle by the driving motor to pass a portion of the heat-exchanged air to the outdoor side through the flow port while passing through the indoor side heat exchanger constituting the heat exchange cycle. Air flow device of an integrated air conditioner, characterized in that forming. 4. The airflow apparatus of claim 3, wherein the damper is controlled according to a working fluid temperature in an outdoor component of the components constituting the heat exchange cycle.