KR100929875B1 - Air conditioner with noise reduction structure - Google Patents

Abstract

The present invention relates to an air conditioner having a noise reduction structure. More specifically, in an air conditioner employing a heat pump method, a separate noise reduction chamber is provided to an air supply and an exhaust unit, and a noise of the air conditioner can be significantly reduced. In addition, it is possible to implement a defrost function, which is a problem of the heat pump by mixing a part of the air supply with the outside air, and a two-row structure or "<" or ">" which can increase the heat exchange cross-sectional area of the outdoor unit coil of the exhaust unit. The present invention relates to an air conditioner having a noise reduction structure capable of greatly improving the thermal efficiency of an air conditioner by configuring the type.

Description

Air conditioner having a noise reduction structure

1 is a schematic diagram showing an air conditioner according to the prior art.

Fig. 2 is a front view showing the overall configuration of an air conditioner having a noise reduction structure according to a first embodiment of the present invention.

3 is a plan view showing the overall configuration of an air conditioner having a noise reduction structure according to a first embodiment of the present invention.

4 is a plan view showing the overall configuration of an air conditioner having a noise reduction structure according to a second embodiment of the present invention.

5 is a functional diagram illustrating an initial operation mode of an air conditioner having a noise reduction structure according to the present invention.

6 is a functional diagram showing a cooling operation mode of an air conditioner having a noise reduction structure according to the present invention.

7 is a functional diagram illustrating a heating operation mode of an air conditioner having a noise reduction structure according to the present invention.

Explanation of symbols on the main parts of the drawings

100: air supply unit

200: exhaust unit

120: air supply rescue room

220: exhaust structure chamber

130: air supply noise reduction room

230: exhaust noise reduction chamber

The present invention relates to an air conditioner having a noise reduction structure. More specifically, in an air conditioner employing a heat pump method, a separate noise reduction chamber is provided to an air supply and an exhaust unit, and a noise of the air conditioner can be significantly reduced. In addition, it is possible to implement a defrost function, which is a problem of the heat pump by mixing a part of the air supply with the outside air, and a two-row structure or "<" or ">" which can increase the heat exchange cross-sectional area of the outdoor unit coil of the exhaust unit. The present invention relates to an air conditioner having a noise reduction structure capable of greatly improving the thermal efficiency of an air conditioner by configuring the type.

In general, an air conditioner employing a heat pump type is a steam compression refrigeration cycle in which a compressor, a first heat exchanger (condenser or evaporator), an expansion valve, and a second heat exchanger (evaporator or condenser) are sequentially connected to each other to form a closed circuit. (Commonly referred to as a "freezing cycle" or "refrigerant circulation circuit") is a cooling and heating system that can perform both cooling and heating by switching the circulation direction of the refrigerant. As a switching means for switching the circulation direction of the refrigerant in the heat pump, four directions are usually used, and each heat exchanger functions as a condenser that emits latent heat of condensation or an evaporator that absorbs latent heat of evaporation depending on the refrigerant circulation direction. .

Referring to Figure 1 will be described the structure and problems of the air conditioner employing such a general heat pump method as follows.

As shown in FIG. 1, the air conditioner employing the conventional heat pump system is generally provided to the case 20, the heat exchanger 10, the internal chamber 3, the damper 4, and the external air inlet 50. It is composed.

Here, the case 20 is formed so as to be in communication with the room (R) and the circulation duct 21, is configured to form a trajectory to the indoor air is purified, the heat exchange device 10 of the case 20 It consists of a heat exchanger 11 for implementing an evaporator and a condenser on both sides of the inside, a circulation fan 12 installed on each outside of the heat exchanger 11, and an exhaust fan 13 for exhausting outside air. It is.

The heat exchanger unit 10 includes a configuration such as a compressor, a receiver, a valve, an oil separator, a liquid separator, etc. for circulating a refrigerant to the heat exchangers 11 on both sides.

The bet chamber 30 is formed in the case 20, spaced apart from the inside of the heat and ventilation 11 on both sides of the partition wall 31 is installed, the space between the partition wall 31 is a circulating duct circulating bet In communication with (21).

According to the configuration as described above, the bet chamber 30 is the partition wall 31 is installed between the circulation duct 21 on the side flowing into the case 20 after the bet is carried out air-conditioning in the room, both sides The space between the partition wall 31 and each heat exchanger 11 is formed of a circulating mixing chamber 33 and an exhaust mixing chamber 34 for mixing the inside and the outside air to be described later.

The dampers 40 are installed on both side walls 31 of the bet chamber 30, respectively, and the dampers 40 perform passage / blocking of air by separate driving means (not shown).

The damper 40 may set a rate at which air is branched to both sides depending on the degree of open space for air to pass therethrough.

In the prior art, the outside air inlet 50 includes an outside air inlet duct 51, a branch duct 52, and a branch damper 53.

The outside air inlet duct 5 is formed to communicate with each other so that outside air flows into the exhaust mixing chamber 34 inside the case 20, and the branch duct 52 is branched from the outside air inlet duct 51 to circulate the mixing chamber. It is configured to communicate with (33).

The branch duct 53 is introduced into the outside air inlet duct 51 into the branch duct 52 so as to set the degree of branching of the outside air, the branch duct 52 or the branch duct 52 and the outside air inlet duct 51 It is configured to be coupled to a branch point.

In the above configuration, the outside air inlet duct 51 and the branch duct 53 of the outside air inlet 50 have an angle orthogonal to the direction in which the bet proceeds through the bet chamber 30 or has a predetermined angle. This is to allow the mixing of the outside air to be mixed more efficiently with respect to the direction of proceeding of the bet.

An air conditioner employing a heat pump system according to the related art having the above configuration has the following problems.

In general, in the cooling operation mode by a heat pump, as the refrigerant releases sufficient latent heat of condensation in the condenser, a high efficiency refrigerant condensation can be obtained. As a result, the supercooling degree of the high-pressure refrigerant is increased, thereby reducing the temperature and pressure in the expansion valve. Done. Accordingly, the absorption amount of latent heat of evaporation in the evaporator is increased, thereby improving the freezing effect. In the heating operation mode by the heat pump, the latent heat of the refrigerant is sufficiently absorbed by the air, so that the evaporation action occurs more effectively. As a result, the high saturation or superheat of the low pressure refrigerant is increased, which results in a high efficiency of compression in the compressor. Is done. When the compressor is well compressed, the compression load is reduced and the power consumption is low, the specific volume of the suction refrigerant in the condenser is reduced, and consequently, the amount of heat generated for condensation is increased.

However, in the case of the air conditioner employing the heat pump method according to the prior art described above, although the air flow rate on the condenser side is about twice as large as the air flow rate on the evaporator side, the size of the evaporator and condenser is limited by the size in the air conditioner. The flow rate on the evaporator side is maintained at 2.5m / sec, but the flow rate on the condenser side is maintained at 4.5 to 5m / sec, and the air velocity is too fast to absorb the latent heat of refrigerant. There is a problem that the condenser does not have a sufficient heat dissipation effect of the outdoor unit in the summer season, so the condensation action is not smooth. In addition, in the heat cycle, the discharge pressure of the compressor is excessively increased due to the problem of the condenser as described above, which causes a problem of increasing power consumption and maintenance costs.

In the heating operation of the winter season in the air conditioner employing the heat pump as in the prior art, condensation occurs in the indoor unit, and evaporation occurs in the outdoor unit. In such a case, since there is a problem that sufficient latent heat of evaporation cannot be obtained around the evaporator of the outdoor unit, the desired evaporation effect cannot be obtained. Therefore, the cold weather has a problem that the desired heating effect in the air conditioner system can not be obtained due to the above problems.

In addition, since a general air conditioner is installed indoors or outdoors, high noise is generated due to the strong discharge pressure and suction pressure generated by the action of the air supply or exhaust fan. In particular, when the air conditioner according to the prior art is installed indoors, the user is complaining a lot of pain due to the noise due to the high noise.

Therefore, an air conditioner having a noise reduction structure according to the present invention has been invented to overcome the above problems.

It is a first object of the present invention to provide an air conditioner having a noise reduction structure that can significantly reduce the high noise generated due to the operation of the air supply fan and the exhaust fan and the resulting discharge air pressure in the air conditioner.

The second object of the present invention is to provide an air conditioner with a noise reduction structure that can improve the thermal efficiency by significantly increasing the heat exchange cross-sectional area by configuring the outdoor unit coil structure in a two-row system or "<" or ">" shape. To provide a harmonic.

It is a third object of the present invention to provide an air conditioner having a noise reduction structure capable of providing a sufficient cooling effect at low cost even in a cold or cold season by providing a two-row structure or a coil of "<" or ">" shape. .

It is a fourth object of the present invention to provide an air conditioner having a noise reduction structure capable of providing a comfortable indoor environment by providing a suitable humidity in a room by employing a humidifier between a heat exchanger and an air supply fan.

The fifth object of the present invention is to adopt an air filter and an intermediate filter between the indoor mixing chamber and the indoor unit heat exchanger at the same time to implement an antibacterial and odor removing function to provide a more comfortable indoor environment air conditioner having a noise reduction structure To provide.

The sixth object of the present invention is to form a separate air supply noise reduction chamber in the upper part of the air supply structure chamber in which the indoor unit coil and the air supply fan is installed, most of the cooling / heating air discharged from the air supply fan is supplied to the room, some of which It is to provide an air conditioner having a noise reduction structure that can significantly increase the thermal efficiency of the air conditioner by being mixed with the outside air through the indoor mixing chamber and supplied to the room again through the indoor unit coil.

In order to achieve the above object, the air supply unit 100 and the exhaust unit 200 is installed to be connected in communication with each other up and down or left and right, or installed to be connected to communicate with each other at a predetermined angle, the building of the building to be installed In the general air conditioner installed at the same time or separated from each other indoors or outdoors according to the structure, the air supply unit 100 includes an internal mixing chamber 110 for sucking and mixing air from the interior and exterior; The air supply structure chamber installed in communication with the air mixing chamber 110 and constituting the prefilter 121, the indoor unit coil 124, the emergency heater 125, the humidifier 126, and the air supply fan 120 ( 120); It is connected in communication with the air supply structure chamber 120, to reduce the vibration noise generated from the air supply fan 120 itself, and the discharge noise generated when the air is discharged from the air supply fan 120, A part of the air discharged from the air supply fan 120 is guided to the room, and a part of the air supply noise reduction chamber 130 for circulating back to the internal air mixing chamber 110, the air supply unit 100 The bet unit 200 is configured to be in communication with each other the outside air mixing chamber 210 for sucking and mixing air from the inside and outside; An outdoor unit coil installed to be in communication with the outside air mixing chamber 210 and configured of a first coil part 224-1 and a second coil part 224-1 interconnected by a connection part 224-3. 224 and an exhaust structure chamber 220 composed of an exhaust fan 222; It is configured to be connected in communication with the exhaust structure chamber 220, to reduce the vibration noise generated from the exhaust fan 220 itself, and the discharge noise generated when the air is discharged from the exhaust fan 220, A part of the air discharged from the exhaust fan 220 is guided to the room, and part of the exhaust noise reduction chamber 230 for circulating back to the exhaust mixing chamber 210 is characterized in that it is configured.

Referring to the configuration of the air conditioner having a noise reduction structure according to the present invention with reference to the accompanying drawings as follows.

Fig. 2 is a front view showing the overall configuration of an air conditioner having a noise reduction structure according to a first embodiment of the present invention. 3 is a plan view showing the overall configuration of an air conditioner having a noise reduction structure according to a first embodiment of the present invention. 4 is a plan view showing the overall configuration of an air conditioner having a noise reduction structure according to a second embodiment of the present invention. 5 is a functional diagram illustrating an initial operation mode of an air conditioner having a noise reduction structure according to the present invention. 6 is a functional diagram showing a cooling operation mode of an air conditioner having a noise reduction structure according to the present invention. 7 is a functional diagram illustrating a heating operation mode of an air conditioner having a noise reduction structure according to the present invention.

As shown in Figure 2, the air conditioner having a noise reduction structure according to the present invention is composed of an air supply unit 100 and an exhaust unit 200.

First, the configuration of the air supply unit 100 will be described with reference to FIG. 2.

The air supply unit 100 has a structure of a rectangular hexahedron shape.

The air supply mixing chamber 110 is formed on the right side of the air supply unit, an air supply structure chamber 120 is formed on the left side of the air supply mixing chamber, and an air supply noise reduction chamber 130 is disposed on the air supply structure chamber 120. This is composed.

The upper end of the bet mixing chamber 110 is provided with an indoor air suction port 111 for sucking the indoor air, and the lower air suction port 112 for suctioning the outside air is formed.

At the rightmost side of the air supply structure chamber 120 that is spatially interconnected with the air mixing chamber 110, a preheater 121 for purifying and sterilizing air mixed and sucked from the air mixing chamber 110 is provided. The intermediate filter 122 is installed side by side vertically. In addition, an air supply fan 123 for supplying air to the room is provided at the leftmost side of the live air supply structure chamber 120. An indoor unit coil 124, an emergency heater 125, and a humidifier 126 are sequentially installed vertically between the preheater 121, the intermediate filter 122, and the air supply fan 123. Here, the indoor unit coil 124 is a heat exchanger for heat exchange, the emergency heater 125 is installed in order to heat the air supply for emergency use such as cold weather or to defrost the frost that may occur in the special case, the humidifier 126 ) Provides the appropriate amount of moisture to the air supplied to the room and is installed to create a comfortable indoor environment.

An air supply noise reduction chamber 130 for reducing noise generated in the air supply strongly discharged from the air supply fan 123 is installed in the upper portion of the air supply structure chamber 120. The air supply structure chamber 120 and the noise reduction chamber 130 are spatially connected to each other through the air supply duct 127. The air supply noise reduction chamber 130 is made of a face-like structure that is configured as a whole transversely, the inside is formed hollow. At the leftmost end of the air supply noise reduction chamber 130, a guide member 131 is formed in which an inner surface thereof is concave with a predetermined curvature so as to guide the strong discharge air discharged from the air supply duct 127. In addition, a predetermined sound absorbing material (not shown) is attached to the entire inner surface of the air supply noise reduction chamber 130 to view vibration noise transmitted from the air supply fan 123 and discharge noise from the air supply fan 123. It can absorb sound effectively.

In the right direction from the guide member 131, a plurality of noise reduction members 132 protruding from the upper and lower surfaces of the air supply noise reduction chamber 130 in the lower direction and the upper direction are respectively provided. have. The noise reduction member 132 is formed in a rectangular plate shape having a predetermined thickness as a whole. In more detail, the plurality of noise reduction members 132 are formed to be suspended vertically from the inner upper surface of the air supply noise reduction chamber 130 at predetermined intervals from each other, and the plurality of noise reduction members 132. ) Are installed in a shape projecting vertically from the inner lower surface of the air supply noise reduction chamber 130 at a predetermined interval from each other. The noise reduction member 132 provided on the upper surface and the noise reduction member 132 protruding upward from the lower surface thereof are provided in a mutually staggered structure. Therefore, a predetermined space is formed between the noise reduction members 132. On the upper right side of the air supply noise reduction chamber 130, a bet feed port 133 is spatially connected to the room is installed. Here, the internal air mixing chamber 110 and the air supply noise reduction chamber 130 are spatially connected to each other through a damper described later. Sound absorbing material (not shown) attached to the entire inner surface of the air supply noise reduction chamber 130 while passing through the spaces formed between the noise reduction members 132 in the air supply noise reduction chamber 130 according to the above configuration. In accordance with the interaction of the vibration noise transmitted from the air supply fan 123, and the air discharge noise is reduced.

The configuration of the exhaust unit 200 which is installed in parallel with the air supply unit 100 described above in parallel with one another will be described with reference to FIG. 2.

The exhaust unit 200 is manufactured to have almost the same shape as the external shape of the air supply unit 100 as a whole.

The innermost left side of the exhaust unit 200 is configured with an outside air mixing chamber 210 for supplying a mixture of inside and outside air. An exhaust structure chamber 220 is installed on the right side spatially connected to the outside air mixing chamber 210. An upper part of the exhaust structure chamber 220 is provided with an exhaust noise reduction chamber 230 for reducing the noise discharged from the exhaust fan described later.

In the outside air mixing chamber 210, an exhaust inlet 211 for sucking circulated air is installed at an upper end thereof, and an outside air inlet 212 for sucking outside air from the outside is installed at an inner lower end thereof. .

The exhaust structure chamber 220 is configured to have a hexahedral shape in which the exhaust structure chamber 220 has a hollow inside on the right side of the external air mixing chamber 210. The leftmost end of the exhaust structure chamber 220 is provided with a filter 221 for filtering the air sucked from the interior and the outside, and the air sucked in the rightmost end of the exhaust structure chamber 220 An exhaust fan 222 is installed to exhaust the gas. The outdoor unit coil 224 is installed between the filter 221 and the exhaust fan 222. An exhaust duct 225 is provided at an upper right side of the exhaust structure chamber 220. Here, the outdoor unit coil 240 is installed in an overall N shape when viewed from above. The structure of the outdoor unit coil 224 will be described in detail with reference to FIGS. 2 and 3 as follows.

The general coil is configured in the shape of a flat plate, but the outdoor unit coil 224 according to the present invention has a double structure to increase the cross-sectional area where actual heat exchange occurs. That is, the outdoor unit coil 224 according to the present invention is provided with a first coil part 224-1 and a second coil part 224-2, and the first and second coil parts 224-1 and 224. Between -2), the connection part 224-3 of a square plate shape is provided. That is, when the coupling structure of the said 1st and 2nd coil parts 224-1 and 224-2 and the said connection part 224-3 is seen from the top as a whole, the cross section is made into the shape of an N (N). Therefore, there is an advantage that the heat exchange can be more efficiently from the air sucked from the outside air mixing chamber 210.

An exhaust noise reduction chamber 230 for reducing noise generated from the exhaust fan 222 and discharge noise of air discharged from the exhaust duct 225 is provided at the upper portion of the exhaust structure chamber 220. . The exhaust noise reduction chamber 230 has the same configuration and structure as the air supply noise reduction chamber 130 of the air supply unit 100 described above. That is, the exhaust noise reduction chamber 230 includes a guide member 231, a plurality of noise reduction members 232, and an exhaust supply port 233.

The configuration of the exhaust noise reduction chamber 230 will now be described in detail.

At the rightmost end of the exhaust noise reduction chamber 230, a guide member 231 is formed in which an inner surface thereof is concave with a predetermined curvature so as to guide the strong discharge air discharged from the exhaust duct 225. A predetermined sound absorbing material (not shown) is attached to the entire inner surface of the exhaust noise reduction chamber 230. The vibration noise transmitted from the exhaust fan 222 and the discharge noise from the exhaust fan 222 may be absorbed more effectively.

In the left direction from the guide member 231, a plurality of noise reduction members 232 protruding from the upper and lower surfaces of the exhaust noise reduction chamber 230 in the lower direction and the upper direction are respectively provided. have. The noise reduction member 232 is formed in a rectangular plate shape having a predetermined thickness as a whole. More specifically, the plurality of noise reduction members 232 are formed to be suspended vertically from the inner upper surface of the exhaust noise reduction chamber 230 at a predetermined interval from each other, and the plurality of noise reduction members 232. ) Are installed in a shape that protrudes vertically from an inner lower surface of the exhaust noise reduction chamber 230 at a predetermined interval from each other. The noise reduction member 232 provided on the upper surface and the noise reduction member 232 protruding upward from the lower surface thereof are provided in a mutually staggered structure. Therefore, a predetermined space is formed between the noise reduction members 232. An exhaust supply port 233 is spatially connected to the room at the upper left surface of the exhaust noise reduction chamber 230. Here, the outside air mixing chamber 210 and the exhaust noise reduction chamber 230 are spatially connected to each other through a damper described later. Sound absorbing material (not shown) attached to the entire inner surface of the exhaust noise reduction chamber 230 while passing through the spaces formed between the noise reduction members 232 in the exhaust noise reduction chamber 230 according to the above configuration. In accordance with the interaction of the vibration noise transmitted from the exhaust fan 222, and the air discharge noise is reduced.

In addition, the air supply unit 100 and the exhaust unit 200 are provided with a plurality of dampers (D1 to D9), the specific configuration thereof is as follows.

Damper D1 connects the indoor and internal air mixing chamber 110, damper D2 connects the internal air mixing chamber 110 and the outdoor air mixing chamber 210, and the damper D3 connects the outdoor and internal air mixing chamber 110, The damper D4 connects the indoor and air supply noise reduction chamber 130, and the damper D5 connects the air supply noise reduction chamber 130 and the internal air mixing chamber 110, and the damper D6 connects the indoor and outdoor air mixing chamber 210. The damper D7 connects the outdoor and outdoor air mixing chamber 210, and the damper D8 connects the outside air and the exhaust noise reduction chamber 230, and the damper D9 connects the exhaust noise reduction chamber 230 and the outdoor air mixing chamber 210. Connect Here, each damper performs a unique function of the damper.

Referring to Figure 4 describes the structure of an air conditioner having a noise reduction structure according to a second embodiment of the present invention.

In the configuration of the air conditioner having the noise reduction structure according to the second embodiment of the present invention, the structure and structure are the same as those in the first embodiment, but in the second embodiment the yen (N) is the first embodiment. It differs only that the outdoor unit coil 224 which was comprised in the shape is comprised by the "<" or ">" type. That is, in the second embodiment of the present invention, the outdoor unit coil 224 ′ is composed of a first coil unit 224-1 ′ and a second coil unit 224-2 ′. One side part of the coil part 224-1 'and 224-2' is mutually contact | connected, and is comprised in the "<" or ">" form. By configuring as described above, there is an advantage that the heat exchange efficiency in a limited space can be further increased due to the increase in the cross-sectional area where actual heat exchange occurs.

Referring to the accompanying drawings, the operation and effects of the air conditioner having the noise reduction structure configured as described above are as follows.

5 is a functional diagram illustrating an initial operation mode of an air conditioner having a noise reduction structure according to the present invention. 6 is a functional diagram showing a cooling operation mode of an air conditioner having a noise reduction structure according to the present invention. 7 is a functional diagram illustrating a heating operation mode of an air conditioner having a noise reduction structure according to the present invention.

As shown, when the system is turned on, the system operates in the initial operation mode. 5 is a diagram illustrating an initial operation mode of the system.

In the initial operation mode as described above, all dampers are blocked in the indoor unit 100 and the outdoor unit 200, but the dampers D5 and D9 are operated in the open state. In the above configuration, air flows in the indoor unit 100 in the order of arrows A1 to A5, and air flows in the order of B1 to B5 in the outdoor unit 200.

Referring to the operation during the cooling and heating operation of the air conditioner having a noise reduction structure of the present invention as follows.

First, the process of the cooling operation will be described with reference to FIG. 6. In the air conditioner of the present invention, the indoor unit coil 124 serves as an evaporator. That is, as the refrigerant, which has been hot compressed by the compressor according to a known cooling cycle, flows into the indoor unit coil 124 and circulates, the heat is removed from the air passing through the indoor unit coil. As described above, according to the evaporation action of the indoor unit coil 124, the surrounding air is cooled coolly and is forcibly supplied to the room by the air supply fan 123.

That is, when the initial operation mode is completed, the flow of air starts with all dampers of the indoor unit 100 and the outdoor unit 200 being opened according to a predetermined control signal.

That is, the outside air is sucked through the outside air inlet 112 and at the same time the air in the room is introduced through the inside air inlet 111 to cause mutual mixing in the inside air mixing chamber 110. The mixed air is cooled while passing through the indoor unit coil 124 through an antibacterial, deodorizing and sterilizing process through the prefilters and the intermediate filters 121 and 122. The air cooled as described above is supplied with the predetermined moisture while passing through the humidifier 126, and is forcibly supplied by the air supply fan 123. Cooling air passing through the air supply fan 123 is supplied to the room through the air supply duct 127 through the air supply noise reduction chamber 130 and through the internal air supply port 133, some of which is preferably About 10% of the cooling air supplied to the room is introduced into the bet mixing chamber 110 again through the damper D5 and mixed with the outside air to repeat the above process.

At this time, as the cooled air passes through the air supply fan 123, not only a considerable level of cooling air discharge noise is generated due to the strong discharge pressure, but also the vibration noise generated from the air supply fan 123 itself is different from that of the cooling air. The same medium is supplied to the room. In the present invention, in order to greatly reduce the noise as described above, in the air conditioner according to the present invention, an air supply noise reduction chamber 130 is formed on the air supply structure chamber 120.

That is, the noise generated as described above is primarily changed by the guide member installed in the air supply noise reduction chamber 130 to smoothly change a plurality of noise reduction members 132 spaced apart at predetermined intervals. It is greatly reduced by passing over each. As described above, about 90% of the cooling air is supplied to the room through the damper D4 and the bet supply port 133, and the remaining about 10% is fed back to the bet mixing chamber 110 through the damper D5. And then go through the purification process again.

Cooled air introduced into the room is supplied to the room to perform the cooling action. In addition, the indoor air sucked through a plurality of dampers (not shown) installed in the room is introduced back into the air conditioner through the air intake 111 and the damper D1 and the air intake 211 and the damper D6. The indoor air sucked through the indoor air suction port 111 and the damper D1 is mixed with the air sucked through the cooling air circulated through the damper D5 and the outdoor air suction port 112 and then recirculated in the internal air mixing chamber 110 and described above. You will go through the process. Thus, a predetermined cooling action is performed.

In addition, the indoor air sucked into the outside air mixing chamber 212 through the air inlet 211 and the damper D6 is mixed with the outside air sucked through the outside air inlet 212, filtered through the filter 221, and the outdoor unit coil 224. Inhaled). The refrigerant in the outdoor unit coil 224 is fluidized by the condensation action by the indoor air sucked into the outdoor unit coil 2240, and circulates the cooling cycle again. The air passing through the outdoor unit coil 224 is an exhaust fan. Passed through the exhaust duct 225 and the exhaust noise reduction chamber 230 through the exhaust 222 is discharged to the outside through the exhaust supply port 233 in a state of reduced noise in the exhaust noise reduction chamber 230 Noise reduction action is the same as the action in the air supply noise reduction chamber 130 of the air supply unit 100, the detailed description thereof will be omitted.

7 is a functional diagram showing a heating operation mode of an air conditioner having a noise reduction structure according to the present invention.

As shown in the drawing, the operation of the air conditioner having the noise reduction structure according to the present invention in the heating operation mode in winter is as follows.

In the winter heating operation mode, the indoor unit coil 124 acts as a condenser, so that the refrigerant heated to high temperature passes through the indoor unit coil 124 according to the refrigeration cycle by the compressor (not shown) and the four-way valve (not shown). By the heat exchange action with the cold air, the surrounding cold air is heated and supplied to the room through the air supply fan 123. Similarly, as the outdoor unit coil 224 of the exhaust unit 200 performs the role of an evaporator, a cycle opposite to the summer cooling operation mode is performed.

As described above, the air conditioner having the noise reduction structure according to the present invention has an advantage of significantly reducing the high noise generated due to the operation of the air supply fan and the exhaust fan and the resulting discharge air pressure, thereby improving the structure of the outdoor unit coil. By constructing a two-row system or a "<" or ">" shape, there is an advantage that the heat efficiency can be improved by greatly increasing the heat exchange cross-sectional area.

In addition, by providing a two-row structure or "<" or ">" shaped coil to obtain a sufficient cooling effect even in the cold or cold weather at a low cost, by using a humidifier between the heat exchanger and the air supply fan to the room without additional power There is an advantage that can provide a comfortable indoor environment by providing adequate moisture.

Furthermore, a separate air supply noise reduction chamber is formed above the air supply structure chamber where the indoor unit coil and the air supply fan are installed, so that most of the cooling / heating air discharged from the air supply fan is supplied to the room, and some of the air mixing chambers By mixing with the outside air to be supplied back to the room through the indoor unit coil can significantly increase the thermal efficiency of the air conditioner.

Claims (8)

The air supply unit 100 and the exhaust unit 200 are installed to be connected in communication with each other up and down or from side to side, or are connected to each other at a predetermined angle so as to communicate with each other, and simultaneously installed indoors or outdoors depending on the structure of the building to be installed. Or in an air conditioner installed separately from each other, The air supply unit 100, An internal mixing chamber 110 for sucking and mixing air from inside and outside; The air supply structure chamber installed in communication with the air mixing chamber 110 and constituting the prefilter 121, the indoor unit coil 124, the emergency heater 125, the humidifier 126, and the air supply fan 123 ( 120); It is connected in communication with the air supply structure chamber 120, to reduce the vibration noise generated from the air supply fan 123 itself, and the discharge noise generated when the air is discharged from the air supply fan 123, A part of the air discharged from the air supply fan 123 is guided to the room, and a part of the air supply noise reduction chamber 130 for circulating back to the internal air mixing chamber 110, The exhaust unit 200 configured to be in communication with the air supply unit 100, An outdoor air mixing chamber 210 for sucking and mixing air from inside and outside; An outdoor unit coil installed to be in communication with the outside air mixing chamber 210 and configured of a first coil unit 224-1 and a second coil unit 224-2 interconnected by a connection unit 224-3. 224 and an exhaust structure chamber 220 composed of an exhaust fan 222; It is connected in communication with the exhaust structure chamber 220, to reduce the vibration noise generated from the exhaust fan 222 itself, and the discharge noise generated when the air is discharged from the exhaust fan 222, A part of the air discharged from the exhaust fan 222 is guided to the room, and some of the air conditioning, characterized in that composed of an exhaust noise reduction chamber 230 for circulating back to the outside air mixing chamber 210 group. The guide member 131 of claim 1, wherein the air supply noise reduction chamber 130 is concave in a circular shape with a predetermined curvature so as to guide the strong air discharged from the air supply fan 123 in a predetermined direction at one end thereof. )Wow; Some of them are suspended vertically from the inner upper surface of the air supply noise reduction chamber 130 at predetermined intervals from each other, and others are upwardly from the inner lower surface of the air supply noise reduction chamber 130 at predetermined intervals from each other. A plurality of square plate-shaped noise reduction members 132 for projecting the vertically protruding shapes to guide noise reduction of the air guided from the guide member 131; An upper portion of the other end of the interior of the noise reduction chamber 130 is connected to the room, and another portion of the other end of the interior is provided with a damper (D5) in communication with the bet mixing chamber 110, characterized in that . The plurality of noise reduction members 132 extending from the inner upper surface of the air supply noise reduction chamber 130 at predetermined intervals from each other, and the plurality of noise reduction members extending from the inner lower surface to the upper predetermined intervals. Two noise reduction members 132 are configured to shift from each other, and a predetermined space is formed between each neighboring noise reduction member 132, and the vibration noise transmitted from the air supply fan 123 and the discharged air discharged therefrom. An air conditioner, wherein noise is reduced by sound absorption of the space. delete delete delete The first coil part 224-1 and the second coil part 224-2 of the outdoor unit coil 224 configured in the exhaust unit 200 are connected to each other at one end thereof. An air conditioner characterized by being configured in a " " or " " shape when viewed from the top of the connection structure of the first and second coil portions 224-1 and 224-2. The air conditioner according to claim 1, wherein the entire inner surface of the air supply noise reduction chamber (130) and the entire inner surface of the exhaust noise reduction chamber (230) are attached with a predetermined sound absorbing material.

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