WO 2008/047968 PCT/KR2006/004615 Description SIMULTANEOUS COOLING-HEATING MULTIPLE TYPE AIR CONDITIONER Technical Field [1] The present invention relates to a multiple type air conditioner, and more par ticularly to a simultaneous cooling-heating multiple type air conditioner capable of si multaneously cooling and heating. Background Art [2] Generally, an air conditioner is an appliance for cooling and heating an indoor space, such as a residential interior space, a restaurant and an office. In order to ef fectively cool and heat an indoor space divided into a plurality of rooms, multiple type air conditioners which can cool and heat independently respective rooms have been developed. In particular, a multiple type air conditioner is configured in such a manner that a plurality of indoor units is connected to a single outdoor unit, and the indoor units are installed in respective rooms. Each indoor unit operates in either a cooling mode or in a heating mode, and conditions air of an indoor space. [3] However, the conventional multiple type air conditioners are controlled to cool or heat all the rooms in one indoor space at the same time, so that they can not meet the demand of conditioning respective rooms differently. In order to solve such a problem, a multiple type air conditioner in which some indoor units operate to cool air and the other indoor units operate to heat air at the same time has been researched and developed. [4] The conventional multiple type air conditioner for simultaneous cooling-heating operation is controlled based on a target discharge pressure and a target suction pressure set for simultaneous cooling-heating operation of a compressor. In this instance, depending on cooling to heating operation ratio of the indoor units operating in cooling mode or in heating mode, the simultaneous cooling-heating multiple type air conditioner performs a cooling-initiative simultaneous cooling and heating operation or a heating-initiative simultaneous cooling and heating operation. Accordingly, since the multiple type air conditioner for simultaneous cooling and heating operations is controlled case by case based on the operation ratio of the indoor units, indoor temperature and outdoor temperature, there is a no-controlled zone in which operation of the air conditioner can not be controlled by the target discharge pressure and the target suction pressure. [5] Further, the conventional multiple type air conditioner performing simultaneous cooling and heating operations has a disadvantageous effect in that it cannot respond to 1 WO 2008/047968 PCT/KR2006/004615 a variety of design specifications, a variety range of indoor temperatures and a variety range of outdoor temperatures. Accordingly, since the conventional multiple type air conditioner performing simultaneous cooling and heating operations does not have optimum operation efficiency, it cannot sufficiently cool and heat an indoor space. Still further, since the control scheme of the conventional multiple type air conditioner performing simultaneous cooling and heating operations is very complicated, an operation mode switching time between the cooling-initiative simultaneous cooling and heating operation and the heating-initiative simultaneous cooling and heating operation is increased by 5 through 15 minutes, and a noisy occurs during the operation mode switching time. Yet further, a damage is caused to a compressor when trying to reduce the mode switching noise. Disclosure of Invention Technical Problem [6] It is an object of the present invention to provide a simultaneous cooling-heating multiple type air conditioner that can be steadily controlled in a simultaneous cooling and heating operation period. Technical Solution [7] In order to achieve the above objects and advantageous effects, according to one aspect of the present invention, there is provided a simultaneous cooling-heating multiple type air conditioner controlled with an operation domain including a plurality of operation zones which are divided based on a refrigerant suction pressure and a re frigerant discharge pressure of a compressor, in which the operation domain includes a first operation zone in which a cooling-initiative simultaneous cooling and heating operation mode is switched to a heating-initiative simultaneous cooling and heating operation mode, a second operation zone in which a mode switching between the cooling-initiative simultaneous cooling and heating operation mode and the heating initiative simultaneous cooling heating operation does not occur, and a third operation zone in which the heating-initiative simultaneous cooling and heating operation mode is switched to the cooling-initiative simultaneous cooling and heating operation mode. [8] According to a further aspect of the present invention, there is provided a si multaneous cooling-heating multiple type air conditioner including a plurality of cooling-heating combined-use indoor units, each having an indoor heat exchanger, a cooling-heating combined-use outdoor unit including a compressor, an outdoor heat exchanger, and a refrigerant switching part installed at a discharge side of the compressor for switching flow of refrigerant based on operation conditions such as cooling-only operation, heating-only operation, cooling-initiative simultaneous cooling and heating operation, and heating-initiative simultaneous cooling and heating 2 WO 2008/047968 PCT/KR2006/004615 operation, and a distributor installed between the cooling-heating combined-use indoor units and the cooling-heating combined-use outdoor unit for distributing the refrigerant into passages of the cooling-heating combined-use indoor units based on the operation conditions such as such as cooling-only operation, heating-only operation, cooling initiative simultaneous cooling and heating operation, and heating-initiative si multaneous cooling and heating operation, wherein the air conditioner is controlled with an operation domain including a plurality of operation zones which are divided according to a refrigerant suction pressure and a refrigerant discharge pressure of the compressor, in which the operation zone domain comprises a first operation zone in which a cooling-initiative simultaneous cooling and heating operation mode is switched to a heating-initiative simultaneous cooling and heating operation mode, a second operation zone in which a mode switching between the cooling-initiative si multaneous cooling and heating operation mode and the heating-initiative si multaneous cooling and heating operation does not occur, and a third operation zone in which the heating-initiative simultaneous cooling and heating operation mode is switched to the cooling-initiative simultaneous cooling and heating operation mode. [9] The suction pressure of the compressor is less than a first suction pressure, a discharge pressure of the compressor is less than a first discharge pressure in the first operation zone; the suction pressure of the compressor ranges from the first suction pressure to a second suction pressure wherein the second suction pressure is greater than the first suction pressure and the discharge pressure of the compressor ranges from the first discharge pressure to a second discharge pressure wherein the second discharge pressure is greater than the first discharge pressure in the second operation zone; and the suction pressure of the compressor may be greater than the second suction pressure and the discharge pressure of the compressor may be greater than the second discharge pressure. In this instance, the air conditioner can be controlled in a manner such that the first operation zone and the third operation zone are switched by varying discharge flow rate of refrigerant discharged from the compressor or the number of revolutions of the outdoor fan. [10] The distributor may include a liquid header, a low pressure gas header, and a high pressure gas header. The simultaneous cooling-heating multi-air conditioner according to the present invention may further include a liquid refrigerant pipe for connecting the cooling-heating outdoor unit to the liquid header, a low pressure gas pipe for connecting the cooling-heating outdoor unit to the low pressure gas header, and a high pressure gas pipe for connecting the cooling-heating outdoor unit to the high pressure gas header. Brief Description of the Drawings 3 WO 2008/047968 PCT/KR2006/004615 [11] FIG 1 is a schematic view illustrating a simultaneous cooling-heating multiple type air conditioner according to one embodiment of the present invention; [12] FIG 2 is a view illustrating the operation status of the simultaneous cooling-heating multiple type air conditioner shown in FIG 1, which operates in a cooling-only operation mode; [13] FIG 3 is a view illustrating the operation status of the simultaneous cooling-heating multiple type air conditioner shown in FIG 1, which operates in a heating-only operation mode; [14] FIG 4 is a view illustrating the operation status of the simultaneous cooling-heating multiple type air conditioner shown in FIG 1, which operates in a cooling-initiative si multaneous cooling-heating operation mode; [15] FIG 5 is a view illustrating the operation status of the simultaneous cooling-heating multiple type air conditioner shown in FIG 1, which operates in a heating-initiative si multaneous cooling-heating operation mode; and [16] FIG 6 is a view illustrating the entire operation domain of the simultaneous cooling heating multiple type air conditioner shown in FIG 1, which is controlled to perform a simultaneous cooling-heating operation. Best Mode for Carrying Out the Invention [17] Hereinafter, a simultaneous cooling-heating multiple type air conditioner according to embodiments of the present invention will be described with reference to the ac companying drawings. [18] FIG 1 illustrates a simultaneous cooling-heating multiple type air conditioner 100. The simultaneous cooling-heating multiple type air conditioner 100 includes a first, a second, a third and a fourth cooling-heating combined-use indoor units B1, B2, B3 and B4, a cooling-heating combined-use outdoor unit A, and a distributor C. [19] The cooling-heating combined-use outdoor unit A includes a first and a second compressor 53 and 54, an outdoor heat exchanger 51, an outdoor heat exchanger fan 61 and a switching part. The switching part includes a four-way valve 62. Suction parts of the first and second compressors 53 and 54 are connected to each other through a combined-use accumulator 52. The first compressor 53 is an inverter compressor that can vary compression capacity of refrigerant, and the second compressor 54 is a constant-speed compressor having constant compression capacity of refrigerant. [20] A first discharge pipe 55 and a second discharge pipe 56 are connected to respective discharge sides of the first and second compressors 53 and 54, and bridged by a bridging part 57. The first and second discharge pipes 55 and 56 are further re spectively connected to a first and a second oil separator 53 and 54 in order to recover oil from refrigerant discharged from the first and second compressors 58 and 59. The 4 WO 2008/047968 PCT/KR2006/004615 first and second oil separators 58 and 59 are respectively connected to a first and a second recovery pipe 30 and 31 in order to guide the separated oil to respective suction sides of the first and second compressors 53 and 54. [21] The bridging part 57 is connected to a high pressure gas pipe 63 in order to make refrigerant discharged from the first and second compressors 53 and 54 bypass the four-way valve 62. The bridging part 57 is connected to the four-way valve 57 and a third discharge pipe 68. [22] An outdoor heat exchanger 51 is connected to the four-way valve 62 via a first connection pipe 71. In the outdoor heat exchanger 51, refrigerant condenses or evaporates by exchanging heat with outdoor air. In order to facilitate heat exchanging, an outdoor fan 61 blows air into the outdoor heat exchanger 51. The outdoor heat exchanger 51 serves as a condenser during a cooling-only operation period or a cooling-initiative simultaneous cooling-heating operation period, but serves as an evaporator during a heating-only operation period or a heating-initiative simultaneous cooling-heating operation period. [23] An outdoor electronic expansion valve 65 and an overcooling device 66 are installed in the middle of the liquid pipe 72 connected between the outdoor heat exchanger 51 and the distributor C. The outdoor electronic expansion valve 65 expands refrigerant upon the heating-only operation and the heating-initiative simultaneous cooling-heating operation. The overcooling device 66 cools the refrigerant moving to the distributor upon the cooling-only operation and the cooling-initiative simultaneous cooling-hating operation. The outdoor electronic expansion valve 74 expands the re frigerant condensed in the first through fourth indoor heat exchangers 11, 21, 31 and 41 during the heating-only operation period or the heating-initiative simultaneous cooling-heating operation period before the refrigerant is introduced into the outdoor heat exchanger 51. The overcooling device 66 includes a overcooler 66a installed in such a manner that it surrounds a part of the liquid pipe 72, a bypass pipe 66b installed between the overcooler 66a and the distributor C in order to make a portion of the re frigerant moving to the distributor bypass the distributor so as to be introduced into the overcooler 66a, an electronic expansion valve 66c installed in a part of the bypass pipe 66b, and a recovery pipe 66d connected between the overcooler 66a and a third discharge pipe 64. [24] The distributor C is installed between the cooling-heating combined-use outdoor unit A and the first through fourth cooling-heating combined-use indoor units B1, B2, B3 and B4 and distributes the refrigerant to the first, second, third and fourth cooling heating combined-use indoor units B1, B2, B3 and B4 based on the operation conditions such as cooling-only operation, heating-only operation, cooling-initiative si multaneous cooling-heating operation and heating-initiative simultaneous cooling 5 WO 2008/047968 PCT/KR2006/004615 heating operation. The distributor C includes a high pressure gas header 81, a low pressure gas header 82, a liquid header 83 and control valves (not shown). [25] The first, second, third and fourth cooling-heating combined-use indoor units B1, B2, B3 and B4 includes respective first, second, third and fourth electronic expansion valves 12, 22, 32 and 42, and respective first, second, third and fourth indoor fans 15, 2 5, 35 and 45. The first, second, third and fourth electronic expansion valves 12, 22, 32 and 43 are installed on respective first, second, third and fourth connection pipes 13, 23, 33 and 43 connected between the first, second, third and fourth indoor heat exchangers 11, 21, 31 and 41 and the high pressure gas header 81. [26] The high pressure gas header 81 is connected to the high pressure gas pipe 63 of the bridging part 57, and respective sides of the first, second, third and fourth indoor heat exchangers 11, 21, 31 and 41. The low pressure gas header 82 is connected to the lower pressure gas pipe 75 via the suction pipe 64, and connected to respective the other sides of the first, second, third and fourth heat exchangers 11, 21, 31, and 41. The high pressure gas header 81, the low pressure gas header 82 and the liquid header 83 can be respectively connected to a high pressure gas pipe 63', a low pressure gas pipe 75' and a liquid pipe 72' of a different outdoor unit (not shown). [27] Referring to FIG 2 through FIG 5, the operation statuses of the simultaneous cooling-heating multiple type air conditioner shown in FIG 1 and flow of refrigerant according to the operation methods will be described below. [28] FIG 2 illustrates the operation status of the simultaneous cooling-heating multiple type air conditioner and the flow of refrigerant upon a cooling-only operation. The re frigerant at a high pressure gas state discharged from the first and second compressors 53 and 54 pass through the first and second discharge pipes 55 and 56, and finally flow into the outdoor heat exchanger 51 through the third discharge valve 68 and the four way valve 62. High pressure liquid refrigerant which is obtained as the high pressure gas refrigerant is condensed by the outdoor heat exchanger 51 is introduced into the liquid header 83 via the overcooling device 66. The refrigerant discharged from the liquid header 83 through the first, second, third and fourth indoor connection pipes 13, 23, 33 and 43 is expanded by the first, second, third and fourth electronic expansion valves 12, 22, 32 and 42, then evaporated by the first, second, third and fourth indoor heat exchangers 11, 21, 31 and 41, and finally introduced into the low pressure gas header 82. Low pressure gas refrigerant discharged from the low pressure gas header 82 is introduced into the suction and discharge pipe 64 and then sucked into the first and second compressors 53 and 54 via the accumulator 52. [29] FIG 3 illustrates the operation status of the simultaneous cooling-heating multiple type air conditioner 100 and the flow of refrigerant in the air conditioner 100 upon the heating-only operation. The high pressure gas refrigerant discharged from the first and 6 WO 2008/047968 PCT/KR2006/004615 second compressors 53 and 54 pass through the first and second discharge pipes 55 and 56, then pass through the bridging part 57 and the high pressure gas pipe 63 and is finally introduced into the high pressure gas header 81 without passing by way of the four-way valve 62. The refrigerant discharged from the high pressure gas header 81 via fifth, sixth, seventh and eighth indoor connection pipes 14, 24, 34 and 44 is condensed in the first, second, third and fourth indoor heat exchangers 11, 21, 31 and 41. After that, the refrigerant is introduced into the liquid header 83, next discharged through the liquid pipe 72, then expanded by the outdoor electronic expansion valve 65, and finally evaporated in the outdoor heat exchanger 51. The low pressure gas refrigerant flows to the suction pipe 64 via the four-way valve 62, and then is introduced into the first and second compressors 53 and 54 via the accumulator 52. [30] FIG 4 illustrates the operation status of the simultaneous cooling-heating multiple type air conditioner 100 and the flow of refrigerant in the air conditioner 100 upon the cooling-initiative simultaneous cooling and heating operation. For convenience's sake of explanation, it is assumed that the first, second, and third indoor units B 1, B2 and B3 operate in a cooling mode and the fourth indoor unit B4 operates in a heating mode. The flow of refrigerant in the first, second and third indoor units B1, B2 and B3 operating in the cooling mode are the same as that shown in the cooling-only operation. The operation shown in FIG 4 will be described below, mainly referring to difference between FIG 2 and FIG 4. [31] A portion of the high pressure gas refrigerant discharged from the first and second compressors 53 and 54 passes through the high pressure gas pipe 63 via the bridging part 57, and is then introduced into the high pressure gas header 81. The refrigerant flowing out of the high pressure gas header 81 passes through the eighth indoor connection pipe 44, is then condensed in the fourth indoor heat exchanger 41, and is finally introduced into the liquid header 83. The refrigerant passing out the fourth indoor unit B4 and the refrigerant passing out the outdoor heat exchanger 51, which will be introduced into respective first, second and third indoor units B1, B2 and B3, will be introduced into the liquid header 83. [32] FIG 5 illustrates the operation status of the simultaneous cooling-heating multiple type air conditioner 100 and the flow of refrigerant in the air conditioner 100 upon the heating-initiative simultaneous cooling and heating operation. For convenience's sake of explanation, it is assumed that the first, second, and third indoor units B 1, B2 and B3 operate in a heating mode and the fourth indoor unit B4 operates in a cooling mode. The flow of refrigerant in the first, second and third indoor units B1, B2 and B3 operating in the heating mode are the same as that shown in the heating-only operation shown in FIG 3. The refrigerant in the fourth indoor unit B4 flows differently. High pressure liquid refrigerant is introduced into the fourth indoor unit B4, passing through 7 WO 2008/047968 PCT/KR2006/004615 the fourth connection pipe 43 from the liquid header 83, is then expanded in the fourth indoor electronic expansion valve 42, is next evaporated in the fourth indoor heat exchanger 41, and is introduced into the low pressure gas header 82. After that, the re frigerant passes through the low pressure gas pipe 75, and flows into the third discharge pipe 64 so that it is mixed with the refrigerant evaporated by the outdoor heat exchanger 51. [33] FIG 6 illustrates the operation domain 150 of the simultaneous cooling-heating operation of the first, second, third and fourth cooling-heating combined-use indoor units B1, B2, B3 and B4. The operation domain 150 is divided into a plurality of operation zones, depending on refrigerant suction pressures and refrigerant discharge pressures of the first and second compressors 53 and 54. The refrigerant discharge pressure may be set by a value measured by pressure sensors installed to the discharge pipes of the first and second compressors 53 and 54, or set by a value measured by a pressure sensor installed to the third discharge pipe. [34] The operation domain is divided in a matrix form and includes a first operation zone R1, a second operation zone R2 and a third operation zone R3. In the first operation zone R1, the suction pressure of the first and second compressors 53 and 54 is less than a first suction pressure P1, and the discharge pressure of the first and second compressors 53 and 54 is less than a first discharge pressure P3. In the second operation zone R2, the suction pressure of the first and second compressors 53 and 54 is the first suction pressure P1 or more and is a second suction pressure P2 or less, wherein the second suction pressure P2 is greater than the first suction pressure P1 (P2 >P1), and the discharge pressure of the first and second compressors 53 and 54 is the first discharge pressure P3 or more and is a second discharge pressure P4 or less, wherein the second discharge pressure P4 is greater than the first discharge pressure P3 (P4>P3). In the third operation zone R3, the suction pressure of the first and second compressors 53 and 54 is greater than the second suction pressure P2 and the discharge pressure of the first and second compressors 53 and 54 is greater than the second discharge pressure P4. For example, the first suction pressure P1 is 725kPa (gauge pressure), the second suction pressure P2 is 987 kPa (gauge pressure), the first discharge pressure P3 is 2565 kPa (gauge pressure) and the second discharge pressure P4 is 2985 kPa (gauge pressure). [35] The simultaneous cooling-heating multiple type air conditioner 100 switches the cooling-initiative simultaneous cooling and heating operation mode to the heating only operation mode in the first operation zone R1. That is, the simultaneous cooling heating multiple type air conditioner 100 performs the cooling-initiative simultaneous cooling and heating operation first and then switches its operation mode so as to perform the heating-only operation when the suction pressure or the discharge pressure 8 WO 2008/047968 PCT/KR2006/004615 of the first and second compressors 53 and 54 decreases and it comes into in the range of the first operation zone R1. [36] However, in the third operation zone R3, the simultaneous cooling-heating multiple type air conditioner 100 switches it's operation mode from the heating-only operation to the cooling-initiative simultaneous cooling and heating operation. That is, the si multaneous cooling-heating multiple type air conditioner 100 performs the heating only operation first and then performs the cooling-initiative simultaneous cooling and heating operation when the suction pressure or the discharge pressure of the first and second compressors 53 and 54 increases and it comes into the third operation zone R3. [37] The second operation zone R2 is a normal operation zone, so that operation mode switching does not occur in this operation zone. That is, the simultaneous cooling heating multiple type air conditioner 100 performs the heating-only operation in the first operation zone R1 and keeps the heating-only operation even if the suction pressure or the discharge pressure of the first and second compressors 53 and 54 increases and it comes into the second operation region R2. For an alternative example, the simultaneous cooling-heating multiple type air conditioner 100 performs the cooling-initiative simultaneous cooling and heating operation in the third operation zone R3 first, and then keeps the cooling-initiative simultaneous cooling and heating operation even if the suction pressure or the discharge pressure of the first and second compressors 53 and 54 decreases and it comes into the second operation zone R2. [38] The simultaneous cooling-heating multiple type air conditioner 100 is controlled to switch from the first operation zone R1 and the third operation zone R3 to the second operation zone R2. There can be a variety of control methods. For example, the re frigerant discharge flow of the first and second compressors 53 and 54 can be controlled. That is, frequency of the first compressor 53 may be varied or the re frigerant discharge flow can be varied by on/off control of the second compressor 54. Further, the number of rotation of the outdoor fan 61 can be varied. For example, when the simultaneous cooling-heating multiple type air conditioner 100 performs the cooling-initiative simultaneous cooling and heating operation in the third operation zone R3, if the refrigerant discharge flow of the first and second compressors 53 and 54 is increased or the number of rotation of the outdoor fan 61 is increased, operation of the simultaneous cooling-heating multiple type air conditioner 100 moves to the second operation zone R2. The time it takes that the first operation zone R1 or the third operation zone R3 moves to second operation zone R2 can be greatly reduced, for example, to 3 minutes or less while conventional operation zone switching time is about 5 to 15 minutes. Accordingly, since the time when the simultaneous cooling heating multiple type air conditioner 100 steadily operate in the second operation zone R2 is increased, optimum air conditioning cycle efficiency can be realized and the 9 WO 2008/047968 PCT/KR2006/004615 control scheme can be simplified. [39] Since the simultaneous cooling-heating multiple type air conditioner according to the present invention switches its operation modes in an operation domain divided into a plurality of operation zones based on the refrigerant suction pressure and the re frigerant discharge pressure of the compressor, it can be steadily operated and controlled during the simultaneous cooling and heating operation period. [40] The present invention is explained above, referring to embodiments, but the present invention is not limited to the above-stated embodiments. In concluding the detailed description, those skilled in the art will appreciate that many variations and modi fications can be made to the preferred embodiments without substantially departing from the principles of the present invention. Therefore, it is readily understood that those variations and modifications to the preferred embodiment will be within the scope of the present invention. Industrial Applicability [41] The simultaneous cooling-heating multiple type air conditioner according to the present invention can meet the demands for simultaneous cooling and heating operation of respective indoor units and can be steadily controlled during even the si multaneous cooling and heating operation period. [42] 10