KR100329472B1 - Multi-air conditioner for cooling and heating - Google Patents

Abstract

PURPOSE: A multi-air conditioner for cooling or heating is provided to improve cooling or heating efficiency regardless of change of operation condition by regulating the flow rate of heat exchange medium according to outdoor temperature. CONSTITUTION: A multi-air conditioner for cooling and heating includes a compressor, an outdoor heat exchanger(120), a couple of indoor heat exchangers, a four-way valve, an auxiliary tank(182), a temperature detecting sensor and a couple of motor expansion valves(132,132'). The auxiliary tank restricts overload and heat exchange media from being supplied to the indoor heat exchanger excessively by storing remaining heat exchange media from the compressor in using the single indoor heat exchanger during cooling. Motor expansion valves are installed in a circulating pipe between indoor and outdoor heat exchangers to regulate flow of heat exchange media. The flow rate is regulated with adjusting the opening degree of motor expansion valves according to outdoor temperature.

Description

Multi-air conditioner for cooling and heating

The present invention relates to a combined air-conditioning multi-air conditioner connected to one compressor and two or more indoor heat exchangers. More specifically, the present invention relates to a multi-air conditioner for both air conditioning and heating, by which a flow rate of a heat exchange medium is adjusted according to a change in operating conditions, thereby obtaining high air conditioning efficiency.

In general, the air conditioner is a device for controlling the indoor environment to a comfortable state, and includes a compressor, an outdoor heat exchanger, a capillary tube, and an indoor heat exchanger.

Recently, by connecting a plurality of indoor heat exchangers installed in different rooms in parallel to one compressor, a multi-air conditioner capable of obtaining higher efficiency at a lower cost has been provided.

This multi-air conditioner will be briefly described through an example shown in FIG. 1.

The illustrated multi air conditioner includes two compressors 11, 12, one outdoor heat exchanger 20, three capillaries 31, 32, 32 ′, and three indoor heat exchangers 41, 42, 42 ′. It is a combined air-conditioning and multi air conditioner.

The independent compressor 11 drives only one independent indoor heat exchanger 41, and the multi-side compressor 12 drives a pair of multi-side indoor heat exchangers 42, 42 ′.

The outdoor heat exchanger 20 has an independent side circulation passage 21 and a multi side circulation passage 22 to circulate the heat exchange medium discharged from the independent side compressor 11 and the multi side compressor 12.

Solenoid valves 62a, 62'a, 62b, 62'b for controlling the driving of each indoor heat exchanger are provided on both sides of the pair of multi-side indoor heat exchangers 42 and 42 '.

In addition, the 4-way valves 51 and 52 serve to change the circulation direction of the heat exchange medium discharged from the compressors 11 and 12.

In this way, the air-conditioning combined air conditioner has an independent indoor heat exchanger 41 driven by the independent compressor 11, and a pair of indoor heat exchangers 42, 42 'driven by the multi-side compressor 12. ) Operates with separate circulation cycles from each other.

In addition, the circulation direction of the heat exchange medium is switched by the operation of the four-way valves 51 and 52 connected to the respective compressors 11 and 12, whereby the heating and cooling operation of the indoor heat exchangers 41, 42 and 42 'is performed. This is determined. That is, when the 4-way valves 51 and 52 are set so that the heat exchange medium discharged from the compressors 11 and 12 passes through the outdoor heat exchanger 20 first, the indoor heat exchangers 41, 42 and 42 'are set. Is a cooling action, and the indoor heat exchanger (41, 42, 42 ') when the 4-way valve (51, 52) is set such that the heat exchange medium first passes through the indoor heat exchanger (41, 42, 42'). Heats up.

Further, by opening and closing the solenoid valves 62a, 62'a, 62b, 62'b provided on both sides of the pair of multi-side indoor heat exchangers 42, 42 ', the pair of indoor heat exchangers 42, 42 ') can both be activated or only one can be operated as required. At this time, the solenoid valves 62a and 62'a installed on the capillary tubes 32 and 32 are used to determine whether the indoor heat exchangers 42 and 42 'are operated at the time of cooling, and are installed on the multi-side compressor 12 side. The solenoid valves 62b and 62'b are for determining whether to operate when heating.

However, such a conventional air-conditioning combined multi-air conditioner is determined based on the case where the heat exchange medium discharged amount of the multi-side compressor is operated simultaneously by a pair of multi-side indoor heat exchangers. Thus, when only one of a pair of multi-side indoor heat exchangers is operated, an excessive amount of heat exchange medium is supplied to the indoor heat exchanger. This causes overheating of the indoor heat exchanger and the compressor, thereby increasing power consumption and reducing the reliability of the compressor.

In order to solve this problem, in the " multi-air conditioner for both air conditioning and heating having a bypass unit for controlling the amount of heat exchange medium " filed by the present applicant as the same applicant, only one of the pair of indoor heat exchangers is discharged from the compressor. A multi-air conditioner for both heating and cooling has been proposed that prevents overload by sending a portion of the heat exchange medium back to the compressor through the bypass unit.

However, since the capillary tube has a standard set according to the standard operating conditions, the air-conditioning combined air-conditioning multi-air conditioner also cannot adjust the flow rate of the heat exchange medium flowing into the indoor heat exchanger according to the change of the operating conditions such as the change of the outdoor temperature. There was this.

Therefore, when the operating condition is close to the set standard conditions, the maximum cooling and heating efficiency is exhibited, but otherwise, the cooling and heating efficiency is inferior.

In addition, the conventional air-conditioning combined multi-air conditioner has a disadvantage in that a large number of parts for controlling the flow of heat exchange medium such as capillary tubes and solenoid valves increases the size of the product and takes up a lot of installation space.

An object of the present invention is to enable a flow rate adjustment of a heat exchange medium according to a change in operating conditions so that high cooling and heating efficiency can be obtained regardless of operating conditions.

Another object of the present invention is to reduce the installation space by simplifying the structure for controlling the flow rate of the heat exchange medium and reducing its size.

1 is a configuration diagram showing an example of a conventional air-conditioning combined multi-air conditioner,

2 is a view showing the configuration of a multi-air conditioner for both heating and cooling according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

111; Independent compressor 112; Multi-side compressor

120; Outdoor heat exchangers 121; Independent circulation passage

122; Multi-sided circulation passage 131; capillary

132, 132 '; Electric expansion valve 141; Freestanding indoor heat exchanger

142, 142 '; Multi-side indoor heat exchanger 151; Independent side 4-way valve

152; Multi-side four-way valve 182; Auxiliary tank

In order to achieve these objects, a multi-air conditioner for both heating and cooling according to the present invention includes a compressor, an outdoor heat exchanger, a pair of indoor heat exchangers, a four-way valve, an auxiliary tank, a temperature sensor, and a pair of electric motors. An expansion valve.

A pair of indoor heat exchangers are connected in parallel between the compressor and the outdoor heat exchanger. The four-way valve controls the circulation direction so that the heat exchange medium circulating in the compressor, the outdoor heat exchanger and the indoor heat exchanger in turn is circulated in the forward or reverse direction.

The auxiliary tank is installed between the four-way valve and the indoor heat exchanger, and when only one indoor heat exchanger is operated when cooling, it stores extra heat exchange medium discharged from the compressor so that an excessive amount of heat exchange medium is stored in the indoor heat exchanger. To prevent supply to Therefore, overloading of the indoor heat exchanger can be prevented.

In addition, a pair of motorized expansion valves are respectively installed on circulation pipes connecting the outdoor heat exchanger and the pair of indoor heat exchangers to interrupt the flow of heat exchange medium flowing to each indoor heat exchanger. When the electric expansion valve is opened, its opening degree is adjusted according to the outdoor temperature detected by the temperature sensor. In addition, when only one of the indoor heat exchangers is activated during heating, the electric expansion valve installed on the inoperative indoor heat exchanger side is finely opened to allow a minute amount of heat exchange medium to be circulated to the inoperative indoor heat exchanger. At this time, the opening degree of the electric expansion valve is suited to one hundred and two hundredths.

According to the present invention as described above, the flow rate of the heat exchange medium is adjusted by changing the opening degree of the electric expansion valve according to the outdoor temperature, so that high cooling and heating efficiency can be obtained regardless of the change in the operating conditions.

In addition, when using one indoor heat exchanger for cooling, the extra heat exchange medium discharged from the compressor is stored in the auxiliary tank. Therefore, an excessive amount of heat exchange medium is supplied to the indoor heat exchanger on the side used to prevent overloading.

In addition, by using the electric expansion valve as a means for adjusting the flow rate of the heat exchange medium, the number of parts is reduced compared to the conventional capillary tube and solenoid valve, thereby reducing the size of the product.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

The configuration of a multi-air conditioner for both heating and cooling according to an embodiment of the present invention is shown in FIG. 2.

In the drawing, reference numeral 120 denotes an outdoor heat exchanger, which has an independent side circulation passage 121 and a multi side circulation passage 122.

One side of the independent side circulation passage 121 is connected to the independent side compressor 111 through the independent side 4-way valve 151, and the other side thereof is connected to the independent side indoor heat exchanger 141 through the capillary tube 131. . The independent side indoor heat exchanger 141 is connected to the independent side compressor 111 again through the 4-way valve 151.

In addition, the multi-side circulation passage 122 is connected to the multi-side compressor 112, one side of which is connected to the multi-side compressor 112 through the multi-side four-way valve 152, the other side of the pair through a circulation pipe 101 divided into two branches It is connected to the multi-side indoor heat exchanger (142, 142 '). On the bifurcated circulation pipe 101, motorized expansion valves 132 and 132 'are provided, respectively. The pair of multi-sided indoor heat exchangers 142, 142 ′ are connected to the multi-side four way valve 152 via a circulating pipe 102 that is merged into one.

An auxiliary tank 182 is installed on the circulation pipe 102 connecting the multi-side indoor heat exchangers 142, 142 ′ and the multi-side 4-way valve 152.

And, there is provided a temperature sensor 161 for sensing the outdoor temperature.

Combined multi-air conditioner according to an embodiment of the present invention having such a configuration is divided into independent cycles and multi-side cycles are operated independently of each other, as follows.

First, the independent cycle passes through the compressor 111, the 4-way valve 151, the independent side circulation passage 121 of the outdoor heat exchanger 120, the capillary 131, and the independent side outdoor heat exchanger 141, and then again. The cooling effect of lowering the temperature of the room in the independent indoor heat exchanger 141 is achieved by a circulation cycle returning to the independent compressor 111 through the 4-way valve 151.

By operation of the four-way valve 151, circulation of the heat exchange medium is reversed, that is, independent side circulation passage 121 of the indoor heat exchanger 141, the capillary 131, and the outdoor heat exchanger 120 from the compressor 111. In the direction of returning back to the independent compressor (111), the independent indoor heat exchanger (141) increases the temperature of the room by the high temperature and high pressure heat exchange medium discharged from the compressor (111). This is done.

In addition, the multi-side compressor 112, the multi-side 4-way valve 152, the multi-side circulation passage 122 of the outdoor heat exchanger 120, the electric expansion valves (132, 132 ') and the multi-side indoor heat exchanger 142 , 142 ') is made in the same way as the independent side cycle.

However, in this multi-side cycle, cooling or heating can be effected for two places through a pair of multi-side indoor heat exchangers 142 and 142 '.

In addition, in this multi-side cycle, the electric expansion valves 132 and 132 'play the role of the capillary 131 of the independent cycle. That is, the opening degree of the motor expansion valves 132 and 132 ′ is adjusted according to the outdoor temperature detected by the temperature sensor 161. Accordingly, the flow rate of the heat exchange medium transferred to the multi-side indoor heat exchangers 142 and 142 'during cooling and the flow rate of the heat exchange medium transferred to the multi-side circulation passage 122 of the off-site heat exchanger 120 during heating are controlled. Will be. Therefore, high cooling and heating efficiency can be obtained regardless of the temperature change in the outdoor.

In addition, when one of the pair of multi-side indoor heat exchangers 142 and 142 'is not used, the electric expansion valve 132' installed on the indoor heat exchanger 142 'side is closed. . Therefore, the heat exchange medium cannot be circulated through the indoor heat exchanger 142 '.

By the way, preferably, the electric expansion valve 132 'is completely closed during cooling when the indoor heat exchanger 142' connected thereto is not used, and approximately one hundred to three hundredths (1/2) when heating. 200-3 / 200). More preferably, this motor expansion valve 132 ′ opens approximately one hundredth (1/100).

By finely opening the electric expansion valve 132 ′ on the side which is not used for heating, the indoor heat exchanger 142 and the electric expansion valve on the side used when the heating action is performed in a state where the outdoor temperature is low ( The low temperature heat exchange medium passing through 132 and the high temperature heat exchange medium passing through the indoor heat exchanger 142 'on the unused side are mixed. Therefore, it is possible to prevent a decrease in heating efficiency due to freezing of the outdoor heat exchanger 120.

In addition, the auxiliary tank 181 stores the excess heat exchange medium therein when only one of the pair of multi-side indoor heat exchangers is used, so that an appropriate level of heat exchange medium is supplied to the indoor heat exchanger on the used side. Can be. Therefore, it is possible to prevent the multi-side indoor heat exchanger and the compressor from being overloaded by circulating an excessive amount of heat exchange medium.

According to the present invention as described above, the opening degree of the electric expansion valve is changed in accordance with the outdoor temperature change, thereby adjusting the flow rate of the heat exchange medium to obtain a high cooling and heating efficiency regardless of the operating conditions. In addition, even when only one indoor heat exchanger is used for heating, the electric expansion valve on the unused side can be finely opened to prevent a decrease in heating efficiency due to freezing of the outdoor heat exchanger when the outdoor temperature is low.

In addition, when using one indoor heat exchanger for cooling, extra heat exchange medium is stored in the auxiliary tank. Thus, an appropriate level of heat exchange medium is always supplied to the indoor heat exchanger on the side used to prevent overloading.

Moreover, the use of an electric expansion valve reduces the number of parts, and thus has the advantage of reducing the size of the product and occupying less installation space.

In the above, certain preferred embodiments of the present invention have been illustrated and described. However, the present invention is not limited to the above-described embodiments, and various modifications can be made by those skilled in the art without departing from the gist of the present invention as claimed in the claims. .

Claims (4)

One compressor for compressing the heat exchange medium; One outdoor heat exchanger for exchanging heat exchange medium and indoor air; A pair of indoor heat exchangers connected in parallel between the outdoor heat exchanger and the compressor to heat exchange the heat exchange medium and the indoor air; 4 installed on a heat exchange medium circulation pipe connecting the compressor and the outdoor heat exchanger to control the circulation direction such that the heat exchange medium circulating the compressor, the outdoor heat exchanger and the pair of indoor heat exchangers is circulated in the forward or reverse direction. Way valve; An outdoor temperature sensor installed at one side of the outdoor heat exchanger to detect an outdoor temperature; Respectively installed on circulation pipes connecting the outdoor heat exchanger and the pair of indoor heat exchangers to control the flow of the heat exchange medium, and when opened, the degree of opening is adjusted according to the outdoor temperature detected by the outdoor temperature sensor. A pair of electric expansion valves, When the heat exchange medium is circulated in the reverse direction passing through the compressor, the pair of indoor heat exchanger and the outdoor heat exchanger in turn and only one of the pair of indoor heat exchangers is operated, the electric motor installed on the other indoor heat exchanger side Combined with the air-conditioning valve is opened so that the minute amount of heat exchange medium is circulated through the other one of the indoor heat exchanger circulating air-conditioning combined multi air conditioner. According to claim 1, The fine opening of the electric expansion valve is a multi-air conditioner for both heating and heating, characterized in that the opening degree of two hundredths to three hundredths. One independent side compressor and one multi-side compressor for compressing the heat exchange medium; An outdoor heat exchanger having an independent side circulation passage and a multi side circulation passage; An independent side indoor heat exchanger positioned between the independent side circulation passage of the outdoor heat exchanger and the independent side compressor; A capillary tube positioned between the independent side circulation passage of the outdoor heat exchanger and the independent indoor heat exchanger; The independent compressor and the outdoor heat exchanger for controlling the circulation direction such that the independent circulation passage of the independent compressor and the outdoor heat exchanger, and the heat exchange medium circulating in a capillary tube and the independent indoor heat exchanger, are circulated in the forward or reverse direction. Independent side 4-way valve is installed on the heat exchange medium circulation pipe connecting the independent side circulation passage of the; A pair of multi-side indoor heat exchangers connected in parallel between the multi-side circulation passage of the outdoor heat exchanger and the multi-side compressor; The multi-side compressor and the outdoor unit for controlling the circulation direction such that the multi-side circulation passage of the multi-side compressor and the outdoor heat exchanger and the heat exchange medium circulating in the pair of the multi-side indoor heat exchanger are sequentially circulated in the forward or reverse direction. A 4-way valve installed on a heat exchange medium circulation pipe connecting the heat exchanger; An outdoor temperature sensor installed at one side of the outdoor heat exchanger to detect an outdoor temperature; Installed on the circulation pipe connecting the multi-side circulation passage of the outdoor heat exchanger and the pair of multi-side indoor heat exchangers, respectively, to regulate the flow of the heat exchange medium, and when opened, the outdoor sensed by the outdoor temperature sensor A pair of electric expansion valves whose opening degree is adjusted according to temperature, When the heat exchange medium is circulated in a reverse direction passing through the multi-side compressor, a pair of multi-side indoor heat exchangers, an outdoor heat exchanger, etc. and only one of the pair of multi-side indoor heat exchangers is operated, the other multi The air-conditioning combined multi-air conditioner, characterized in that a minute amount of heat exchange medium is circulated through the remaining one of the multi-side indoor heat exchanger is operated so that the electric expansion valve installed on the side indoor heat exchanger side. According to claim 3, The fine opening of the electric expansion valve is a multi-air conditioner for both air conditioning and heating, characterized in that the opening degree of two hundredths to three hundredths.