KR19980033362A - Air conditioning system - Google Patents

Abstract

The phase between the gas phase and the liquid phase can be changed by the difference in specific gravity between the gas phase and the liquid phase between the heat source side machine and a plurality of user side machines disposed at least half under the heat source side machine so that each user side machine is cooled. An air conditioning system for circulating a fluid to perform an operation, each user side machine includes a flow control valve for controlling the volume of the fluid supplied to the heat exchanger, a blowing means for supplying air conditioning air to the room through the heat exchanger, And a physical value detecting means for detecting a physical value related to an air conditioning load such as temperature, and a signal control means for operating the detection portion. The heat source side machine sends a control signal to the flow control valve of the user side machine. And control means for outputting and communicating with the signal control means. . Thus, even if the cooling load is the same, the opening ratio of the flow control valve of the user side machine mounted on the higher floor can be controlled to be larger than that of the user side machine mounted on the lower floor. According to the above structure, in the air conditioning system which is naturally circulated and basically controlled, the air conditioning system characteristics which are difficult to operate the air conditioning system due to the difficulty of supplying fluid to the user side machine mounted on the higher floor can be improved. Can be.

Description

Air conditioning system

The present invention relates to an air conditioning system, and more particularly to liquid and gas between a heating source side machine and a plurality of user side machines disposed below the heat source side machine so that each user side machine can at least perform cooling. A system for circulating a fluid that changes a phase between a gaseous phase and a liquid phase by the specific gravity difference therebetween.

The prior art includes a system as shown in FIG. 8 as an air conditioning system that does not require power to transfer a variable fluid, for example a fluid that varies the stage between liquid and gas phase by outputting or inputting latent heat. do. In this system, the heat source side machine 1 acting as a condenser is installed at a high position in the building, and the liquid pipe 6 and the gaseous pipe 7 are installed at a lower side of the heat source side machine. The heat exchanger 5 of the machine 4 and the heat source side machine are connected. This system heats the heat source side machine 1 to the heat exchanger of the user side machine 4 through the liquid pipe 6 to supply the condensed liquid by its own weight, and to the warm air of the room from the user side machine 4. By heat-exchanging, the heat condensed and condensed gas is returned to the heat source side machine 1 through the gas phase pipe 7 to allow circulation. Therefore, there is an advantage that the operating cost at the time of cooling performance can be reduced without the transfer power which is an electric pump. In this case, reference numeral 8 denotes a flow control valve and reference numeral 9 denotes a blower.

In addition, an air conditioning system as shown in FIG. 9 is disclosed in Japanese Patent Laid-Open No. 7-151359. In the air conditioning system having the above structure, the heat source side machine 1 disposed at a high position supplies condensed or evaporated refrigerant, reference numeral 30 denotes an electronic pump and reference numerals 31 to 34 Indicates an on-off valve. These elements are connected by the liquid pipe 6 and the gas phase pipe 7 as shown in the figure to form a closed circuit 3. The phase variable fluid sealed in the closed circuit 3 circulates between the heat source side machine 1 and the user side machine 4 so that the user side machine 4 performs cooling or heating. In this case reference numeral 35 denotes a liquid level sensor disposed on the side of the heat source side machine 1, which is adapted to make the cooling fluid stored in the heat source side machine 1 constant during heating. To control.

Therefore, in the air conditioning system capable of performing the cooling operation and the heating operation as shown in FIG. 9, when the temperature of the room where the user side machine 4 is installed is high at the state of the pump 30 stopped, the opening / closing valve 31, 32 is closed, the shut-off valves 33 and 34 are opened, and the flow control valve 8 is opened. Therefore, when the refrigerant sealed in the closed circuit 3 is condensed and cooled in the heat source side machine 1, the refrigerant fluid condensed in the heat source side machine 1 falls to the liquid pipe 6 by its own weight to open / close a valve. (33, 34) and flow control valve (8) flows into the heat exchanger (5).

Then, the refrigerant fluid flowing into the heat exchanger 5 absorbs heat from the indoor air through the pipe wall of the heat exchanger to perform a cooling operation, and the refrigerant vaporizes and flows into the gas phase pipe 7, whereby the pressure of the refrigerant It recycles to the heat source side machine 1 which becomes low by condensation, and forms a natural circulation. Therefore, since power for driving the electric pump 30 is not needed in the summer when the power consumption is the maximum during the year, there is an advantage that the operating consumption can be reduced.

In addition, the flow control valve 8 is also opened and the closing circuit 3 in the state where the shutoff valves 31 and 34 are closed and the shutoff valves 32 and 33 are open, and also when the electric pump 30 is driven. The refrigerant fluid condensed in the heat source side machine 1 drops in the liquid pipe 6 due to its own weight and the discharge force of the electric pump 30 while the sealed refrigerant therein is condensed and cooled by the heat source side machine 1. It flows into the heat exchanger 5 through the flow control valve 8, thereby forcibly circulating the refrigerant for performing the cooling operation.

As described above, when the cooling operation is performed by driving the electric pump 30, a sufficient amount of the refrigerant fluid is supplied to the heat exchanger 5 installed in the high bed corresponding to the position just below the heat source side machine 1. It can be an advantage.

On the contrary, in the case where the room temperature where the user side machine 4 is installed is low when the on-off valves 32 and 33 are closed and the on-off valves 31 and 34 are opened and the flow control valve 8 is opened, and the closed circuit In the case where the electric pump is driven when the refrigerant sealed in (3) is heated and vaporized by the heat source side machine 1, the refrigerant gas vaporized in the heat source side machine 1 passes through the gas phase pipe 7. (5) flows into.

Then, the refrigerant gas flowing into the heat exchanger (5) releases heat to the indoor air through the pipe wall of the heat exchanger to perform a heating operation, and the refrigerant itself condenses and flows into the liquid pipe (6), whereby the electric pump ( 30 is recycled to the heat source side machine 1 via the on / off valves 34 and 31. Thus, the heating by the user side machine 4 can continue.

However, in the air conditioning system as shown in Fig. 8, all the weight stored in the liquid pipe by condensing by dissipating heat in the heat source side machine acts as a pressure to the heat exchanger of the user side machine installed on the low fluid bed. Therefore, the fluid can be easily supplied to the heat exchanger of the user side machine installed on the higher layer, and since the weight of the fluid stored in the liquid pipe disposed above this portion acts as a pressure, the more difficult it is to supply the fluid, the more the user side machine The layer on which this is installed tends to be high, resulting in insufficient cooling performance.

In order to solve this problem, the volume of the flow control valve of the user side machine mounted on the floor which is higher than the volume of the flow control valve of the user side machine installed on the low floor is made, so that It is possible to easily supply the flow control valve. However, in this structure, it is necessary to prepare a user side machine having various kinds of volumes, which makes the control at the operating site complicated and the cost increased. Therefore, even when using a user side machine having the same volume, it is necessary to provide a system capable of performing optimum flow circulation in the air conditioning system that basically performs the natural circulation of the variable flow fluid.

In addition, in this type of air conditioning system, the liquid, which is discharged from the heat source side machine and condensed, is supplied to the heat exchanger of the user side machine by its own weight, so that when the sudden heating action occurs at the start of cooling, the fluid has a short time. In the heat exchanger of the user side machine and the pressure in the gas phase pipe is increased, making it difficult for the fluid to flow into the heat exchanger, and the fluid flows behind the flow control valve (8) to stop the heat absorption and evaporation in the heat exchanger. The cooling operation cannot be performed.

In addition, in the air conditioning system as shown in Fig. 9, since the refrigerant gas generated by heating in the heat source side machine is supplied to the heat exchanger of the user side machine by the heated gas pressure, a sudden heating action occurs at the start of heating. In this case, the supply of the refrigerant gas becomes insufficient so that a so-called sleeping phenomenon coolant is generated, that is, a condensed refrigerant stored in the heat exchanger of the user side machine is generated to blow the unheated wind in the room. Since the amount of refrigerant sealed in the closed circuit is constant, it is considered that the electric pump is not stopped or refrigerant from the user side machine is not returned to the heat source side machine. Thus, there is a problem that the pressure in the closed circuit increases locally more than necessary.

In addition, when the outside air temperature is low, many of the variable flow fluids condense in the pipe so that a so-called sleeping phenomenon occurs.

Therefore, it is necessary to overfill the pipe in consideration of the sleeping phenomenon. If no excessive filling is provided, the circulation amount is insufficient and sufficient heating performance cannot be obtained.

Moreover, the power consumption can be reduced in summer when power is maximized when the cooling operation is performed by naturally circulating the refrigerant in the stopped state of the electric pump, so that the operating cost is reduced. However, it is difficult to supply a sufficient amount of refrigerant to a user side machine mounted on a higher floor having a somewhat different level from where the heat source side machine is mounted. In addition, even if the user side machine is mounted on the same floor, it is difficult to control the room temperature stably because the coolant may be easily supplied and the coolant may be difficult to be supplied, depending on other aspects of pipe length and arrangement angle. .

Conversely, when the electric pump is driven, a sufficient amount of refrigerant can be supplied to the user side machine mounted in the higher floor to ensure the required cooling. However, in this case power is needed to drive the pump. Moreover, the electric pump required in this case is a large pump having the capability of transferring the refrigerant fluid condensed in the user side machine when heating to the heat source side machine mounted thereon, thus requiring more power consumption. Therefore, there is a need to solve these problems.

1 illustrates an air conditioning system configured only to perform cooling;

2 illustrates an air conditioning system configured to perform cooling and heating;

3 is a flowchart showing an embodiment of controlling the flow control valve at the start of heating;

4 is a flowchart showing an embodiment of controlling a flow rate control valve when performing cooling;

FIG. 5 is a flowchart showing an embodiment of controlling the flow rate control valve when performing heating; FIG.

6 illustrates another air conditioning system configured for performing cooling and heating;

FIG. 7 is a flowchart showing an embodiment of controlling an on / off valve of the air conditioning system shown in FIG. 6;

8 illustrates a prior art;

9 is a view for explaining another conventional technique.

It is an object of the present invention to provide an air conditioning system for solving the above problems.

According to the present invention, the phase between the gas phase and the liquid phase can be changed by the specific gravity difference between the gas phase and the liquid phase between the heat source side machine and a plurality of user side machines disposed at least half under the heat source side machine. The side machine is an air conditioning system for circulating fluid, which performs cooling, and each user side machine is a heat exchanger, a flow control valve for controlling the volume of fluid supplied to the heat exchanger, and air conditioning air in the room through the heat exchanger. Blower means for supplying air, physical value detection means for detecting a physical value related to an air conditioning load such as temperature, and signal control means for heat exchanger, flow control valve, blower means and physical value detection means, The heat source side machine outputs a control signal to the flow control valve of the user side machine. No. it provided with a ventilation system equipped with the control means and the control means for communication.

According to the present invention described in claim 2, the control means is provided with an air conditioning system having a function of determining the set opening ratio in consideration of the signal output from the height and the physical value detecting means.

According to the present invention as set forth in claim 3, the control means is provided with an air conditioning system having a function of determining a higher set opening ratio of the flow control valve as the user side machine is mounted on a higher floor.

According to the present invention as set forth in claim 4, the control means is provided with an air conditioning system having a function of maintaining the opening ratio of the flow rate control valve at a predetermined small opening ratio for a predetermined period when cooling starts.

According to the present invention as set forth in claim 5, the control means has air having a function of maintaining the opening ratio of the flow control valve at a smaller opening ratio as the user side machine is mounted on a higher floor for a predetermined period of time when cooling starts. It is equipped with a harmonic system.

According to the present invention as set forth in claim 6, the flow passage switching mechanism and the pump are provided in the liquid pipe through which the liquid fluid flows, and absorb heat from the heat source side machine and introduce the evaporated fluid into the user side machine to release and condense the heat. And the condensed fluid is returned to the heat source side machine by the discharge force of the pump so that heating is carried out at each user side machine and the control means is provided with the flow control valve at a predetermined large opening ratio for a predetermined period of time when heating is started. It is equipped with an air conditioning system with a function of maintaining the open ratio.

According to the present invention as set forth in claim 7, the control means is provided with air having the function of maintaining the opening ratio of the flow control valve at a larger opening ratio as the user side machine is mounted on the lower floor for a predetermined period of time when heating is started. It is equipped with a harmonic system.

According to the present invention as set forth in claim 8, the flow passage switching mechanism and the pump are provided in the liquid pipe through which the liquid fluid flows, and absorb heat from the heat source side machine and introduce the evaporated fluid into the user side machine to release and condense the heat. The condensed fluid is returned to the heat source side machine by the discharge force of the pump so that heating is performed at each user side machine and the control means detects an insufficiency in the amount of circulation of the fluid during heating. It is equipped with an air conditioning system with the function of opening the door almost completely.

According to the present invention as set forth in claim 9, the liquid pipe in which the liquid fluid flows and the gas pipe in which the gas fluid flows are divided from the main pipe connected to the heat source side machine, respectively, and the end of the split pipe connected to each user exchange is It is connected to each other via an on-off valve, and the control means has an air conditioning system having a function of opening the on-off valve in response to the full opening action of the flow control valve in an interlocking manner.

According to the present invention described in claim 10, the control means is provided with an air conditioning system having a function of opening the on-off valve once when starting heating.

According to the present invention as set forth in claim 11, the effective operation of the user side machine in which the difference in the physical value caused by the temperature or the temperature difference of the inlet or the outlet of the fluid flowing in the effective operation of the user side machine is continued for a predetermined period of time. In comparison, when the physical value detecting means recognizes an important state, the control means is adapted to adjust the flow control valves of a plurality of different user side machines in a direction to determine the important state of the user side machine. It is equipped with a harmonic system.

According to the present invention as set forth in claim 12, the effective operation of the user side machine, which is different from the difference in physical values caused by the temperature or the temperature difference of the inlet or the outlet of the fluid flowing in the effective operation of the user side machine, is continued for a predetermined period of time. In comparison, when the physical value detecting means recognizes an important state, the control means is provided with an air conditioning system having a function of adjusting the flow control valve of the user side machine in the direction of determining the important state.

An embodiment according to the present invention will be described below with reference to FIGS. 1 to 7. In this case, in order to easily understand the structure, the same reference numerals are attached to the parts having the same functions as those described in FIGS. 8 and 9.

1 shows an embodiment of an air conditioning system according to the present invention, wherein reference numeral 1 denotes a user side machine composed of, for example, an absorption type refrigerator having a cooling function (see USP No. 5,224,352). The user side machine 1 is for example installed in a machine room arranged on a building roof and can vary the phase between the gas phase and the liquid phase and is arranged in the evaporator by means of a fluid sealed in the sealing circuit 3, for example. When the pressure decreases through the heat exchanger (2), heat is exchanged by the refrigerant (R-134a) that can easily evaporate even at low temperatures.

Reference numeral 5 denotes a heat exchanger of the user side machine 4 installed in each room in the building. The heat source side machine 1 and the heat exchanger of the plurality of user side machines 4 are connected by a supply liquid pipe 6, a return gaseous phase pipe 7 and a flow control valve 8 to close the circuit 3. To form.

Reference numeral 9 denotes a blower for blowing indoor air and returning the indoor air to the heat exchanger 5, and reference numerals 10 and 11 denote an input of the heat exchanger 5 for detecting the temperature of the refrigerant R-134a. Indicates the temperature sensor provided at the exit. The larger the air conditioning load is, the larger the temperature difference between the temperature sensor 10 at the inlet end and the temperature sensor 11 at the outlet end is, and the smaller the air conditioning load is, the smaller the temperature difference is.

In addition, the heat source side machine 1 is provided as the heat source control apparatus 12, and the user side machine 4 is provided as the user control apparatus 13. As shown in FIG. In addition, the user control device 13 can convert the valve opening ratio of the flow control valve 8 and the temperature information detected by the temperature sensors 10 and 11 into a communication signal, and converts a communication signal received from the outside into a predetermined signal. It is provided with a signal converter (not shown) that can be converted to a control signal. The heat source control device 12 and the user control device 13 are connected by a communication line 14, and a control output signal output from the heat source control device 12 is received by the user control device 13 so that the flow rate control valve 8 Control the opening ratio. Also provided correspondingly to each of the user side machines 4 are remote controllers 15 which are capable of communicating with the user control device 13 and capable of performing the start and stop operation of cooling, the selection intensity of the blowing intensity and the temperature selection operation. do.

First, the circulation cycle of the refrigerant R-134a sealed in the closed circuit 3 will be described below. Since the refrigerant R-134a is cooled by the cooling function of the heat source side machine 1 through the pipe wall of the heat exchanger 2, the refrigerant R-134a is condensed and stored in the downstream liquid pipe 6. And are supplied to each of the heat exchangers 5 through the flow control valve 8 of the user side machine 4.

On the contrary, since the warm air in the room is forcedly supplied by the blower 9 in each of the heat exchangers 5, the refrigerant R-134a absorbs heat from the room air and evaporates to perform cooling.

Then, the refrigerant (R-134a) is condensed and cooled to become a liquid, and natural refrigerant passes the refrigerant (R-134a) to the heat exchanger (2) of the heat source side machine (1) having a low pressure through the gas phase pipe (7). It is generated by returning.

However, as described above, the larger the amount of the refrigerant R-134a supplied to the heat exchanger 5 through the flow control valve 8, the lower and lower the amount of the layer on which the user side machine 4 is mounted. The fewer, the higher the floor on which the user side machine is mounted.

Thus, when the temperature information detected by the temperature sensors 10 and 11 is the same, when the opening ratio is controlled by outputting a control signal to the flow control valve 8, the appropriate amount of the refrigerant R-134a is cooled. Since it cannot be supplied in accordance with the operation, the heat source control device 12 is a predetermined control program that outputs different control signals according to the floor on which the user side machine 4 is mounted, that is, a user side machine installed on a higher floor ( It is provided with the program which greatly opens the opening ratio of the flow control valve 8 of 4). For example, in the case of an air conditioning system in which the user side machine 4 is installed separately on the 10th floor, the correction factor of the user side machine 4 installed on the lowest floor is set to 1, and the value of 0.1 plus 1 is The correction factor of the next higher layer is set and in this way the next layer is also set continuously. In this state, when no correction is first given, the opening ratio of the flow control valve 8 is determined by the normal equation on the basis of the temperature information detected by the temperature sensors 10, 11. In addition, the opening ratio of the flow control valve 8 output to the user side machine 4 is determined by integrating a predetermined correction coefficient to the opening ratio. The opening ratio of the flow control valve 8 of the user side machine 4 is adjusted to the opening ratio determined in this manner.

When the heat source control device 12 receives the temperature information detected by the temperature sensors 10 and 11 from the user control device 13 via the communication circuit 14, the heat source control device 12 first transmits a signal. The floor on which the user side machine 4 is installed is checked to determine which floor and the correction coefficient is determined. In consideration of the correction coefficient determined in this manner, the opening ratio of the flow control valve 8 is calculated by a predetermined program, and the predetermined control signal is output to the corresponding user control device 13 through the communication circuit 14. And the opening ratio of the flow control valve 8 is adjusted to the opening ratio corresponding to the floor in which the user side machine is installed.

As described above, if a sudden heat load is generated at the start of cooling, the refrigerant R-134a is evaporated in the heat exchanger 3 of the user side machine 4 for a short time, so that the internal pressure of the gas phase pipe 7 is reduced. Is increased. Therefore, it is difficult for the refrigerant R-134a to flow into the heat exchanger 5 so that the gas of the refrigerant R-134a returns from the flow control valve 8 to stop the absorption and evaporation in the heat exchanger 5. Let's do it. As a result, there is a risk that cooling will not be performed.

Therefore, the control signal output from the heat source control device 12 to the respective user control devices 13 through the communication line 14 at the start of cooling lowers the opening ratio of the flow rate control valve 8 to a constant low level, for example. For example a setting ratio of 25% of the full opening ratio for a predetermined time, for example 30 seconds.

Therefore, even when the air conditioning load is large at the start of cooling and the refrigerant R-134a evaporates in the heat exchanger 5 for a short time, the amount of the refrigerant R-134a supplied through the flow control valve 8 is small. Pressure increase is limited. Therefore, the disadvantage that the refrigerant R-134a returns from the flow rate control valve 8 and cooling is not performed is avoided.

In this case, the self-weight of the refrigerant R-134a flowing out of the heat exchanger 2 of the heat source side machine 1 and condensing and flowing into the heat exchanger 5 of the user side machine 4 has a working weight. The larger the larger, the lower the floor on which the user side machine 4 is installed, thus acting on the user side machine 4, making it difficult for the refrigerant R-134a to return from the flow rate control valve 8.

In this case, in the air conditioning system according to the present invention, as shown in FIG. 1 as a broken line, the receiving tank 16 and the electric pump 17 may be provided.

In this structure, since the conveying force by the electric pump is added to the specific gravity difference between the liquid and the gas of the refrigerant R-134a, the correction ratio in determining the opening ratio of the flow control valve 8 can be made small. In addition, the air conditioning system can be constructed by using a flow control valve 8 having a smaller total capacity. Part of the user side machine 4 may also be installed on the same floor or higher than the floor on which the heat source side machine 1 is mounted. In addition, since it is difficult for the refrigerant R-134a to flow backward from the flow control valve 8 at the start of cooling, the opening ratio of the flow control valve 8 held for a predetermined time is increased to improve the air conditioning start characteristic. Let's do it.

In this case, the electric pump 17 ensures circulation of the refrigerant R-134a which can be circulated by the difference in specific gravity between the liquid and the gas, so that the pump is compared with the electric pump for heating which will be mentioned below. It can be made remarkably compact and requires the ability to convey the liquid of the refrigerant R-134a to the heat source side machine 1 mounted on a higher floor. Therefore, even when the electric pump 17 is driven to perform the cooling operation, power consumption is reduced in comparison with the conventional air conditioning system shown in FIG.

An embodiment of an air conditioning system capable of carrying out the freezing operation and the heating operation will then be described with reference to FIG. 2. In this case, the heat source side machine 1 includes an absorption type refrigerator having a freezing function and a heating function. Reference numeral 18 denotes a fuel control valve of the burner 19 provided to the regenerator (not shown), and reference numeral 20 denotes a cooling / heating switching valve (opening / closing) provided to the common portion 6A of the liquid pipe 6. Reference numeral 6B denotes a bypass pipe connected to the common part 6A of the liquid-phase pipe 6A to bypass the cooling / heating switching valve 20, and reference numerals 21 and 22 The heating electric pump provided in the receiver tank and the bypass pipe 6B is shown.

In this case, for example, the absorption type refrigerator disclosed in Japanese Patent Laid-Open No. 7-318189 can be used as an absorption type refrigerator having a cooling function and a heating function derived from a heat exchanger provided in an evaporator.

In practice, for example, in the heat source side machine 1, when the opening ratio of the fuel control valve 19 is increased at the time of performing heating and the heating power is increased by increasing the fuel supplied to the burner 19, the regenerator ( The amount of refrigerant evaporated and separated from the absorbing liquid in (not shown) is increased. In order to evaporate and separate the refrigerant, the increased refrigerant gas and the heat absorbing liquid are supplied around the heat exchanger 2 to discharge heat to the refrigerant R-134a flowing in the heat exchanger 2. The function of heating the refrigerant R-134a is enhanced to increase the temperature, so long as the flow rate is the same. On the contrary, when the opening ratio of the fuel control valve 18 is reduced and the heating power of the burner 19 is reduced, the function of heating the refrigerant R-134a flowing in the heat exchanger 2 is weakened to increase the temperature. The degree to which this is done is reduced.

In contrast, the amount of refrigerant evaporated and separated from the absorbing liquid (not shown) when the opening ratio of the fuel control valve 18 is increased at the time of performing cooling and the heating power is increased by increasing the fuel supplied to the burner 19. Is increased. When heat is released in the condenser to condense the increased refrigerant gas and becomes liquid and is supplied around the heat exchanger 2 to absorb heat from the refrigerant R-138 flowing in the heat exchanger 2 and then evaporate, The function of cooling the refrigerant R-134a flowing in the vessel 2 is enhanced so that the degree of increasing the temperature is increased as long as the flow rate is the same. On the contrary, when the opening ratio of the fuel control valve 18 is reduced and the heating power of the burner is reduced, the cooling function of the refrigerant R-134a flowing in the heat exchanger 2 is weakened and the degree of temperature decrease is reduced. do.

In the air conditioning system having the above structure, the cooling / heating switching valve 20 is closed while maintaining the use of the heating function of the heat source side machine 1, and the closing circuit 3 when the electric pump 22 is driven. When the refrigerant (R-134a) in the heating medium is heated by the use of the heating function of the heat source side machine through the pipe wall of the heat exchanger (2), the refrigerant (R0-134a) is evaporated and flows into the gaseous pipe (7). The heat exchanger 5 in each side machine 4 is supplied.

In each heat exchanger (5), low temperature air in the room is forcibly supplied by the blower (9), and the refrigerant (R-134a) discharges heat to the air in the room so as to condense and performs heating.

The condensed, further liquefied refrigerant (R-134a) then enters through the flow control valve (8) into the receiver tank (21) disposed at the lower portion and by means of an electric pump (22) the heat exchanger (2) of the heat source side machine. Return to to continue the circulation for heating.

In the circulation of the refrigerant R-134a, the heating load in a certain user side machine 4 is increased (or decreased) and the refrigerant R-134a detected by the temperature sensor 10 in the user side machine 4. When the temperature decreases (or rises), the rate of improvement of the corresponding flow control valve 8 is increased by receiving the control signal from the user control device 13 in a manner to determine the temperature drop (or temperature rise) and increase the heating load. The amount of refrigerant R-134a flowing into the heat exchanger 5 of the user side machine 4 to increase (or decrease) is increased (or decreased). Therefore, the temperature drop (or rise) of the refrigerant R-134a detected by the temperature sensor 10 is determined long ago.

When the amount of the refrigerant R-134a flowing into the heat source side machine 1 or the amount of the refrigerant R-134a flowing into the heat source side machine 1 changes due to the change in the heating load, the temperature sensor ( When the temperature of the refrigerant R-134a detected by 24 or 25 is changed, the heat source control device 12 controls the opening ratio of the fuel control valve 18 in a manner to determine the change.

Furthermore, at the cooling time when the cooling / heating switching valve 20 is opened and the electric pump 22 is stopped, the cooling function of the heat source side machine 1 is used in this manner and the refrigerant R-134a is a liquid pipe ( 6) Cooled by the use of the cooling function through the pipe wall of the heat exchanger 2 to condense and discharge to the user side machine (3) through the cooling / heating switching valve 20 and the flow control valve 8 at a predetermined low temperature. 4) is supplied.

In each of the user side machines 4, since the high temperature indoor container is forcibly supplied by the blower 9, the refrigerant R-134a in the state of the low temperature liquid supplied from the heat source side machine 1 is It absorbs heat from the air in the room and evaporates and performs cooling. The gasified refrigerant (R-134a) is cooled, condensed and liquefied, and flows into the heat exchanger (2) of the heat source side machine (1) with low pressure through the gaseous pipe (7) to generate a natural circulation.

In the circulation of the refrigerant R-134a, the cooling load of a certain user side machine 4 is increased (or decreased) and the refrigerant R-134a detected by the temperature sensor 11 in the user side machine 4. When the temperature of the temperature rises (or falls), the opening ratio of the corresponding flow control valve 8 increases (or decreases) by receiving the control signal to the user control device 13 in such a manner as to determine the temperature rise (or the temperature decrease). The amount of refrigerant R-134a flowing into the heat exchanger 5 of the user side machine 4, which increases the cooling load, is increased (or decreased). Therefore, the temperature rise (or drop) of the refrigerant R-134a detected by the temperature is determined long ago.

The flow rate of the coolant R-134a flowing into the heat source side machine 1 or into the heat source side machine 1 is converted into a change in the heating rod. When the temperature of the refrigerant R-134a detected by 24 or 25 is changed, the heat source control device 12 controls the opening ratio of the fuel control valve 18 in a manner to determine the change.

In practice, the heat source control device 12 of the heat source side machine is evaporated and gaseous by accepting the temperature of the refrigerant R-134a detected by the temperature sensor 24, i.e., the heating effect in the heat exchanger 2 during heating. A function of controlling the degree of the fuel control valve 18 in such a manner that the temperature of the refrigerant R-134a discharged to the pipe 6 becomes a predetermined temperature, for example, 55 ° C, and detected by, for example, the temperature sensor 25 during cooling. The temperature of the refrigerant R-134a which is condensed by receiving the cooling effect in the heat exchanger 2 and discharged to the gaseous pipe 6 to a predetermined temperature, for example, 7 ° C. This has the function of controlling the degree of the fuel control valve 18. Further, the user control device 13 condenses and lowers the temperature by performing the heating effect through the heat exchanger 5, i.e., the temperature of the refrigerant R-134a detected by the temperature sensor 10 during heating. 6) a function of controlling the degree of the flow control valve 8 in such a manner that the temperature of the refrigerant R-134a discharged to a predetermined temperature, for example, 50 ° C, and the refrigerant detected by the temperature sensor 11 during cooling ( The temperature of R-134a, that is, the temperature of the refrigerant R-134a evaporated by performing the cooling effect through the heat exchanger 5, raising its temperature and discharged to the gaseous pipe 7, is a predetermined temperature, for example, 12 ° C. It has a function of controlling the degree of the flow control valve 8 in such a way that.

However, as described above, if a sudden heat load occurs when heating starts, supply of the refrigerant R-134a evaporated in the heat source side machine 1 to the heat exchanger 5 of the user side machine 4 is sufficient. Instead, the so-called sluffing of the refrigerant, that is, condensation in which the refrigerant R-134a is stored in the heat exchanger 5 occurs, and the cooled air flows into the room. Furthermore, since the amount of the refrigerant R-134a sealed in the closed circuit 3 is constant, the electric pump 22 is stopped or the refrigerant R-134a from the user side machine 4 is the heat source side machine 1. Does not return to). Therefore, there is a problem that the pressure in the closed circuit 3 is locally increased more than necessary. Therefore, when it starts to heat, the control signal output from the heat source control device to the respective user control device 13 through the communication line 14 sets the opening ratio of the flow control valve 8 at a fixed level, such as a predetermined period of time, for example, 30 seconds. Is set at an open rate of 75% of full open.

Therefore, if the air conditioning system load suddenly increases when the heating starts to heat and the discharge amount of the refrigerant R-134a in the heat exchanger 5 increases suddenly, the amount of the refrigerant R-134a that is empty from the heat source side machine becomes large. The disadvantage that the refrigerant R-134a is condensed at the inlet of the heat exchanger 5 and the cooled air flows into the room can be avoided.

In this case, there is a smaller level difference between the liquid of the refrigerant R-134a condensed in the heat exchanger 5 and the bottom bottom on which the receiver tank 21 heat exchanger is mounted, so that the lower liquid is contained in the receiver tank 21. ) It is hard to be released to the end. Furthermore, since the low pressure of the refrigerant R-134a evaporated in the heat exchanger 2 of the heat source side machine 1 acts on the lower floor on which the heat exchanger 5 is mounted, the liquid of the refrigerant R-134a As the heat exchanger 5 is disposed on the bottom floor, it is difficult to be discharged. Therefore, the heat exchanger 5 may be mounted on the lower floor so that the larger opening ratio of the flow control valve 8 is opened to start heating.

Furthermore, the amount of more refrigerant (R-134a) discharged from the heat exchanger (5) through the flow control valve (8) is the upper floor on which the user side machine (4) is mounted and the smaller amount is the user side machine (4). The bottom is mounted. Thus, in normal operation without a start time in heating, even when the temperature information detected by the temperature sensors 10 and 11 is the same, the heat source control device 12 corresponds to the floor on which the user side machine 4 is mounted. A predetermined control program for outputting different control signals, i.e., a program for opening the flow rate control valve 8 of the user side machine 4 mounted on the lower floor having a larger opening ratio. For example, in the case of an air conditioning system in which the user side machine 4 is detachably mounted on ten floors, for example, the correction factor of the user side machine 4 mounted on the highest floor is set to 1 and is 0.05. The value plus 1 is set to the next higher correction factor of the bottom, which continues on the next floor. In this state, when the correction is not determined, the opening ratio of the flow control valve 8 is determined based on the temperature information detected by the temperature sensors 10 and 11. Moreover, the opening ratio of the flow rate control valve 8 substantially output to the user side machine 4 is determined by multiplying the desired correction coefficient by the opening ratio. The opening ratio of the flow control valve 8 of the user side machine 4 is adjusted to the opening ratio determined in this manner. The opening ratio of each flow control valve 8 of the user side machine 4 is controlled by a control program. When the heat source control device 12 receives the temperature information detected by the temperature sensors 10 and 11 from the user control device 13 through the communication line 14, first, the heat source control device 12 transmits a signal. The floor on which the user side machine 4 is mounted is checked and the correction coefficient is determined. In consideration of the correction coefficient determined in this manner, the opening ratio of the flow control valve is calculated by a predetermined program, and the preferred control signal is output to the corresponding user control device 13 through the communication line 14, and the flow control valve The opening ratio of (8) is adjusted to the opening ratio corresponding to the floor on which the user side machine is mounted. In the air conditioning system capable of performing the cooling operation and the heating operation shown in FIG. 2 by providing the receiver tank 16 and the electric pump 17 as shown by the broken line, the refrigerant R-134a is the user side. Even when a part of the machine 4 is placed on the same floor as the part of the heat source side machine 1 or on a higher floor than the part of the heat source side machine 1, it can be reliably circulated for cooling. In this case, the bypass pipe 6C having the cooling / heating switching valves (opening and closing valves) which are opened when performing heating and closed when performing cooling, shows a liquid pipe common portion 6A in the manner shown by the broken line. Is preferably connected.

Moreover, when starting to heat, a larger amount of the refrigerant R-134a is condensed in the cooled closed circuit 3 and the circulation of the refrigerant R-134a is insufficient so often that sufficient heating is not performed. . During operation, the refrigerant R-134a is condensed in the cooled portion of the closed circuit 3 and the circulation of the refrigerant R-134a is often insufficient so that sufficient heating is not performed. Thus, the opening ratio of the flow control valve 8 can be controlled by the heat source control device 12, for example, in the manner shown in FIG.

In fact, when heating is commanded, the flow control valves 8 in all the user side machines 4 are completely opened in step S1. Subsequently, when the step advances to step S2, the amount of the refrigerant R-134a stored in the receiver tank 21 is detected by the liquid level sensor 26. Next, in step S3, it is determined whether or not the amount of the refrigerant R-134a stored in the reservoir tank 21 is sufficient. If it is determined that the amount is sufficient in the step, the step proceeds to step S4 and the opening ratio of the flow control valve 8 is clearly determined by the temperature sensor 10 based on the heating load of the refrigerant R-134a. To control the temperature. If the amount is insufficient at this step, the step proceeds to step S5 to determine whether or not the flow rate control valve 8 is completely open. Then, if the flow control valve 8 is fully open, the step returns to step S2 and if the flow control valve 8 is not fully open, the step returns to step S1 and the flow control valve 8 is completely Open.

Since the flow control valve 8 is controlled by the heat source control device 12 in this manner, when the larger amount of the refrigerant R-134a is condensed in the closed circuit to start sleeping or sleeping, the condensed liquid is contained in the receiver. The flow control valve 8 is heated by the heat exchanger 2 of the heat source side machine 1 to be stored in the tank 21 and completely opened as needed by the gas pressure of the gasified refrigerant R-134a. It is pressurized through the liquid pipe 6 and then returned to the heat source side machine 1 by means of an electric pump 22. Therefore, the amount of circulating refrigerant R-134a is immediately increased, so that the heating performance is quickly returned.

Furthermore, as described above, when the user side machine 4 is mounted on the lower floor, it dissipates heat in the heat exchanger 2 and condenses upon cooling and into the heat exchanger 5 of the user side machine 4. More self weight of the flowing refrigerant (R-134a) is mounted on the user side machine (4), and when the user side machine (4) is mounted on a higher floor, the smaller itself weight is placed on the user side machine (4). Act on Therefore, even when the opening ratio is the same, when the user side machine is mounted on the lower floor, the amount of refrigerant (R-134a) supplied to the heat exchanger 5 through the flow control valve 8 is higher, When the user side machine 4 is mounted, the amount of refrigerant becomes smaller. Moreover, even when the user side machine 4 is mounted on the same floor, the refrigerant R-134a is easier than the user side machine 4 disposed away from the heat source side machine 1 in view of the resistance of the flow path. This flows into the user side machine 4 disposed near the heat source side machine 1. The degree of difficulty in flow of the refrigerant R-134a is affected by the difference in the inner diameter of the pipe and the curvature of the pipe arrangement.

In addition, there is resistance due to boiling of the refrigerant R-134a in the liquid pipe 6, so that even when the opening ratio of the flow control valve 8 is corrected and controlled on the basis of the position of the device, until the temperature is stable. It takes a long time. Since the boiling of the refrigerant R-134a in the liquid pipe 6 is affected by the amount of circulation, the state changes continuously.

For example, in the user side machine 4 having a large resistance due to bubble mixing caused by boiling, even when the flow rate control valve 8 is no longer opened because the amount of circulation of the refrigerant R-134a is small, the temperature difference is not reduced. It may not. In this case, the amount of circulation of the refrigerant R-134a to this portion is reduced by slightly closing the flow control valve 8 of the other user side machine 4 at its opening ratio, thereby reducing the user side machine ( The amount of circulation of the refrigerant R-134a to 4) is increased to prevent the refrigerant R-134a from boiling and thus controlled in such a manner as to return the resistance to the original level.

In fact, upon receiving the temperature information detected by the temperature sensors 10 and 11 in all the user side machines 4 operating through the communication line 14 from the user control device 13 of the user control system 12, , user control device 12, a temperature sensor 11, the temperature (t ₁₎ is detected by the T ₁ and △, △ T _2, △ T _3, T ₄ △ △ .... T _n all user side, such as The difference | t ₁ -t ₀ | between the temperature t ₀ detected by the temperature sensor 10 for the machine 4 is determined. ΔT _i corresponding to the maximum value of | t ₁ -t ₀ | is then selected every 10 seconds, for example, and when the time period at which ΔT _i becomes maximum reaches a predetermined time (eg 30 seconds), The following adjustments are performed in the corresponding user side machine and another user side machine.

In practice, when the difference t ₁ -t ₀ is a predetermined value such as 3 or more, as the first forced adjustment, the flow rate control valve 8 of the selected user side machine 4 and the other user side machine 4 is closed. Control signal for forcibly operating each stepping motor 8M which executes adjustment of the opening ratio of the flow rate control valve 8 in a predetermined step to each user control device 13 through the communication line 14. Output, thereby forcibly controlling the opening ratio (K) of each flow control valve (8).

Further, when the difference t ₁ -t ₀ is equal to or less than a predetermined value, for example, -3 ° C. for a predetermined time period, the second forced adjustment of the selected user side machine 4 and the other user side machine 4 is performed. A control signal forcing each of the stepping motors 8M in a predetermined step in the direction in which the flow rate control valve 8 is opened is output to each of the user control devices 13 through the communication line 14 so that each flow rate The opening ratio K of the control valve 8 is forcibly controlled.

For example, when the temperature of the air entering the user side machine 4 by the blower 9 and blown to the heat exchanger 5, that is, the room temperature, is higher than or equal to the set temperature by the remote controller 15, ΔT _tgt = 1 is set. Otherwise _,? T _tgt = 3 is set. Then, the forced adjustment control at the time of performing cooling is performed by the temperature t ₁ of the coolant R-134a detected by the temperature sensor 11 and the coolant R-134a detected by the temperature sensor 10. It is executed by controlling the opening ratio K of each flow control valve 8 in such a manner that the temperature difference ΔT between the temperatures t ₀ becomes ΔT _tgt . An example of this forced adjustment control will be described with reference to FIG. 4.

In step S11, it is first judged in each user side machine 4 whether room temperature is more than a preset temperature. If the step is Yes, the step proceeds to step S12, and? T _tgt = 1 is set. If the step is No, the step proceeds to step S13, and DELTA T _tgt = 3 is set.

In step S14, it is determined whether or not the temperature difference ΔT is equal to or greater than zero. If the step is Yes, the step proceeds to step S15 to determine whether or not? T≥? T _tgt . If the step is No, the step proceeds to step S16, and DELTA K1 = 0 is set. If step S15 is Yes, the step proceeds to step S17, where DELTA K1 = (DELTA T- DELTA T _tgt ) / 4 is set.

When the step determines no, the step proceeds to step S18 where, for example,? K1 = -α (e.g., α is determined within the range of 0.2 to 2.4 when the air conditioning system is mounted in a state where power is considered. Is set).

In step S19, it is determined whether the forced adjustment command has been output from the heat source control device 12. When the step determines yes, the step goes to step S20 and ΔK2 = β (β is -2, for example, when performing the first forced adjustment, and +2 when performing the second forced adjustment. Is set). When the step determines no, the step advances to step S21 and DELTA K2 = O is set.

Thereafter, in step S22, the opening ratio K of the flow control valve 8 is controlled to K + DELTA K1 + DELTA K2, and this control is repeated every 10 seconds by the step S23.

Therefore, in the case of the user side machine 4 in which the resistance is increased by mixing of bubbles caused by boiling, the flow rate control valve 8 is completely opened to allow the refrigerant R to exit and inlet of the heat exchanger 5. Even when the temperature difference of -134a does not decrease, the flow rate of the refrigerant R-134a does not increase, and the opening ratio of the flow rate control valve 8 of another user side machine 4 in normal operation is determined by the heat source control device ( The amount of refrigerant (R-134a) flowing to the user side machine (4) which is lightly closed based on the forced adjustment command outputted by 12) is reduced and the flow amount is reduced to the user side machine (4). The distribution amount of the coolant R-134a is reduced to prevent boiling. Therefore, the resistance is returned to the normal level and the same air conditioning performance as that of the other user side machine 4 can be secured quickly.

Further, even when the refrigerant R-134a flows easily for some reason and the user side machine 4 having the heat exchanger 5 is abnormally overcooled, the flow rate of another user side machine 4 which is normally operated is normal. The opening ratio of the control valve 8 is slightly increased based on the forced adjustment command output by the heat source control device 12, and the amount of the refrigerant R-134a flowing to the user side machine 4 in normal operation is increased. And the amount of distribution of the refrigerant R-134a to the user side machine 4 in which the flow amount is increased is reduced so that the air conditioning performance is limited to the level of another user side machine 4.

Furthermore, the heat source control device 12 can control the opening ratio of the flow control valve 8 in the following manner. That is, when the user control device 12 receives temperature information detected by the temperature sensors 10 and 11 in all the user side machines 4 operated from the user control device 13 via the communication line 14. In the beginning, the user control device 12 is configured to apply? T ₁ ,? T ₂ ,? T ₃ ,? T ₄ ,. The difference between the temperature t ₁ detected by the temperature sensor 11 and the temperature t ₀ detected by the temperature sensor 10 for all the user side machines 4, as described above, is t ₁ -t. ₀ ), and then the average temperature difference (ΔT _M ) is determined.

Thereafter, each of the temperature difference (△ T _i) and the mean temperature difference _{(△ T M) (= (} △ T 1 + △ T 2 + △ T 3 + ... + △ T n) / n) difference (△ T _i between - ΔT _M ) is determined every 10 seconds. When the difference is greater than or equal to a predetermined value of, for example, 2 ° C by the first forced adjustment, a control signal forcibly operating the stepping motor 8M in a predetermined step in the direction in which the flow rate control valve 8 of the corresponding user side machine 4 opens is communicated. It outputs to the corresponding user control apparatus 13 through the circuit 14, thereby forcibly controlling the opening ratio K of the flow control valve 8. As shown in FIG.

Further, when the difference ΔT _i -ΔT _M is equal to or less than a predetermined value of, for example, -2 ° C. during the predetermined interval of time by the second forced adjustment, the flow rate control valve 8 of the corresponding user side machine 4 is closed. A control signal for forcibly operating the stepping motor 8M in a predetermined step in a direction to be outputted is output to the corresponding user control device 13 through the communication circuit 14, whereby the opening ratio K of the flow control valve 8 Forcibly).

For example, when the temperature of the air taken into the user side machine 4 by the blower 9 and blown to the heat exchanger 5, that is, the room temperature is above the temperature set by the remote controller 15, ΔT _tgt = 1 is set, otherwise T _Dgt = 3 is set. Subsequently, when performing cooling, the forced adjustment control includes the temperature t ₁ of the refrigerant R-134a detected by the temperature sensor 11 and the temperature of the refrigerant R-134a detected by the temperature sensor 10. It is carried out by controlling the opening ratio K of each flow control valve 8 in such a way that the temperature difference ΔT between t ₀ becomes ΔT _tgt . Therefore, by performing forced adjustment control based on the same flowchart as in Fig. 4, in the user side machine 4, the temperature difference of the refrigerant R-134a at the outlet and the inlet of the user side machine 4 is significantly different from the average temperature difference. The flow rate control valve 8 is forcibly adjusted based on the forced adjustment command output by the heat source control device 12 so that the same air conditioning performance can be ensured in all the user side machines 4.

Furthermore, the temperature information detected by the temperature sensors 10 and 11 in all the user side machines 4 operated when the user control device 12 is heated from the user control device 13 through the communication line 14 is obtained. At the time of accommodating, the user control device 12 initially displays? T ₁ ,? T ₂ ,? T ₃ ,? T ₄ ,. The difference between the temperature t ₁ detected by the temperature sensor 11 and the temperature t ₀ detected by the temperature sensor 10 for all user side machines 4, such as ΔT _n (t ₁ −). t ₀ ). Then, when ΔT _i corresponding to the maximum value of (t ₁ -t ₀ ) is selected for example every 10 seconds and the time interval at which ΔT _i is maximum reaches a predetermined time (for example 30 seconds), Subsequent adjustments are made on a different user side machine than the corresponding user side machine.

When the difference t ₁ -t ₀ is equal to or greater than a predetermined value of 3 ° C. by the pressure adjustment, for example, the predetermined flow rate control valve 8 of the user side machine different from the selected user side machine 4 is closed in a predetermined direction. The control signal forcibly operating each stepping motor 8M at the step is outputted to the respective user control device 13 through the communication circuit 14, and accordingly, the opening ratio K of each flow control valve 8 Forcibly).

For example, when the temperature of the air taken into the user side machine 4 by the blower 9 and blown to the heat exchanger 5, ie, the room temperature is below the temperature set by the remote controller 15, ΔT _tgt = 1 is set, otherwise T _Dgt = 3 is set. Subsequently, when performing cooling, the forced adjustment control includes the temperature t ₁ of the refrigerant R-134a detected by the temperature sensor 11 and the temperature of the refrigerant R-134a detected by the temperature sensor 10. It is carried out by controlling the opening ratio K of each flow control valve 8 in such a way that the temperature difference ΔT between t ₀ becomes ΔT _tgt . An example of such forced adjustment control is described below with reference to FIG.

In step S31, it is first determined in each user side machine 4 whether the room temperature is below the set temperature. When the step determines yes, the step goes to step S32, and ΔT _tgt = 1 is set. When the step determines no, the step advances to step S33 and ΔT _tgt = 3 is set.

In step S34, it is determined whether or not the temperature difference ΔT is equal to or greater than zero. When the step determines yes, the step goes to step S35 and it is determined whether ΔT≥ΔT _tgt . When the step determines no, the step advances to step S36 and ΔK1 = 0 is set.

When step S35 determines yes, the step goes to step S37, for example, DELTA K1 = (DELTA T- DELTA T _tgt ) / 4. When the step determines no, the step goes to the stem S38 and, for example,? K1 = -α (e.g., in the range of 0.2 to 2.4 when the air conditioning system is mounted with the power considered) Is set).

In step S39, it is determined whether the forced adjustment is output from the heat source control device 12. When the step determines yes, the step advances to step S40, and DELTA K2 = 2 is set. When the step determines no, the step advances to step S41, and DELTA K2 = 0 is set.

Thereafter, in step S42, the opening ratio K of the flow rate control valve 8 is controlled to K + DELTA K1 + DELTA K2, and this control is repeated every 10 seconds by the step S43.

Thus, in the case of the user side machine 4 in which the resistance is increased by mixing of bubbles caused by boiling when heating is performed, the flow rate control valve 8 is fully opened to open the outlet of the heat exchanger 5 and Even when the temperature difference of the coolant R-134a does not decrease at the inlet, the flow rate of the coolant R-134a does not increase, and the flow control valve 8 of another user side machine 4 that is normally operated opens. The ratio is slightly reduced based on the forced adjustment command output by the heat source control device 12, and the amount of refrigerant (R-134a) flowing to the normally operated user side machine 4 is reduced and the amount of flow is reduced. The amount of distribution of the refrigerant R-134a to the machine 4 is reduced. Therefore, the same air-conditioning performance as another user side machine 4 can be secured quickly.

Furthermore, the heat source control device 12 can control the opening ratio of the flow control valve 8 when heating is performed in the following manner. That is, when the user control device 12 receives temperature information detected by the temperature sensors 10 and 11 in all the user side machines 4 operated from the user control device 13 via the communication line 14. In the beginning, the user control device 12 is configured to apply? T ₁ ,? T ₂ ,? T ₃ ,? T ₄ ,. The difference between the temperature t ₁ detected by the temperature sensor 11 and the temperature t ₀ detected by the temperature sensor 10 for all the user side machines 4, as described above, is t ₁ -t. ₀ ), and then the average temperature difference (ΔT _M ) is determined.

Thereafter, each of the temperature difference (△ T _i) and the mean temperature difference _{(△ T M) (= (} △ T 1 + △ T 2 + △ T 3 + ... + △ T n) / n) difference (△ T _i between - ΔT _M ) is determined every 10 seconds. When the difference is greater than or equal to a predetermined value of, for example, 2 ° C by the first forced adjustment, a control signal forcibly operating the stepping motor 8M in a predetermined step in the direction in which the flow rate control valve 8 of the corresponding user side machine 4 opens is communicated. It outputs to the corresponding user control apparatus 13 through the circuit 14, thereby forcibly controlling the opening ratio K of the flow control valve 8. As shown in FIG.

Further, when the difference ΔT _i -ΔT _M is equal to or less than a predetermined value of, for example, -2 ° C. during the predetermined interval of time by the second forced adjustment, the flow rate control valve 8 of the corresponding user side machine 4 is closed. A control signal for forcibly operating the stepping motor 8M in a predetermined step in a direction to be outputted is output to the corresponding user control device 13 through the communication circuit 14, whereby the opening ratio K of the flow control valve 8 Forcibly).

For example, when the temperature of the air taken into the user side machine 4 by the blower 9 and blown to the heat exchanger 5, ie, the room temperature is below the temperature set by the remote controller 15, ΔT _tgt = 1 is set, otherwise T _Dgt = 3 is set. Subsequently, when performing cooling, the forced adjustment control includes the temperature t ₁ of the refrigerant R-134a detected by the temperature sensor 11 and the temperature of the refrigerant R-134a detected by the temperature sensor 10. It is carried out by controlling the opening ratio K of each flow control valve 8 in such a way that the temperature difference ΔT between t ₀ becomes ΔT _tgt . Therefore, on the basis of the same flowchart as in Fig. 5, when ΔK in step S40 performs the first forced adjustment, it is +2, and when ΔK in step S40 performs the second forced adjustment. By carrying out a two-force adjustment control, in the user side machine 4 where the temperature difference of the refrigerant R-134a at the outlet and inlet of the user side machine 4 is significantly different from the average temperature difference, the flow rate control valve 8 is It is forcibly adjusted based on the forced adjustment command output by the heat source control device 12 so that the same air conditioning performance is ensured in all the user side machines 4.

In this case, when forcibly changing the opening ratio of the flow control valve 8, the mean temperature difference ΔT _M corresponding to the criterion is not only an arithmetic mean but also a geometric mean. Furthermore, intermediate water may be used. Furthermore, when the average value or the median number among the plurality of selected numbers, i.e., the number of the user side machines 4 is 10, the selected 5 to 10 user side machines or five when the number of the user side machines is 10 or more. Half average or median may be used.

6, the air conditioning system shown in FIG. 6 is constructed, and as shown by the broken line in FIG. 2, the receiving tank 16 and the electric pump 17 are provided, and the discharge end of the electric pump 22 is opened and closed. 27 is connected to the inlet end of the receiving tank 16 in a horizontally separated manner from a thick vertical pipe which acts as a main pipe extending in the vertical direction of the liquid pipe 6 and the gaseous pipe 7. The ends of the horizontally extending pipes of the liquid phase pipe 6 and the gas phase pipe 7 which respectively extend are connected via open and closed balances 28, respectively. In this structure, heating is performed by closing the cooling / heating switching valve 20, opening the opening and closing valve 27, stopping the electric pump 17, and driving the electric pump 22, and cooling is performed. By opening the cooling / heating switching valve 20, closing the opening and closing valve 27, stopping the electric pump 22, and driving the electric pump 17. Therefore, during heating and cooling, when the opening and closing valves 28 are closed, the refrigerant R-134a in the closing circuit 3 is circulated in the same manner as in the case of the air conditioning system shown in FIG.

In the air conditioning system having the above structure, since the refrigerant R-134a carried by the electric pump 22 toward the heat source side machine 1 does not pass through the electric pump 17, the transport resistance is There is an advantage that the transport resistance of the air conditioning system having the structure shown in Figure 2 becomes smaller.

Furthermore, upon heating of the air conditioning system having the above structure, the open and close valves 28 are controlled, for example, in the manner shown in FIG.

That is, when the heating is commanded, all the open and close valves 28 are completely opened in step S51. Subsequently, the step advances to step S52, and the amount of R-134a stored in the storage tank 21 is detected by the liquid level sensor 26. After that, in step S53, it is determined whether or not the amount of the coolant R-134a stored in the storage tank 21 is sufficient. When the step determines that the amount is sufficient, the step proceeds to step S54, and the open and close valves 28 are closed. When the step determines that the amount is insufficient, the step proceeds to step S55 to determine whether the open and close valves 28 are to be opened. Then, when the opening and closing valve 28 is opened, the step goes back to step S52, and when the flow control valve 8 is closed, the step goes back to step S51.

Due to the control of the open and close valves 28, when a large amount of refrigerant R-134a is condensed in the closing circuit 3 to start or sleep, the condensed liquid is stored in the receiving tank 21 so as to be stored. Pushed into the liquid pipe 6 via open and closed valves 28, which are opened as necessary by the gas pressure of the refrigerant R-134a heated and vaporized by the heat exchanger 2 of the side machine 1, and then The electric pump 22 returns to the heat source side machine 1. Therefore, the amount of circulating the refrigerant R-134a is immediately increased, so that the heating performance is recovered early.

The present invention is not limited to the above embodiments, and various kinds of modifications are possible within the scope of the invention mentioned in the claims.

For example, the temperature sensors 10 and 11 may be provided in a manner of detecting a temperature change of indoor air blown through the heat exchanger 5. Pressure sensors for detecting the pressure difference of the refrigerant (R-134a) in the inlet and outlet of the heat exchanger may be provided in place of the temperature sensors (10, 11), and thus the heat source control device 12 of the air conditioning Output the load.

Furthermore, a refrigerant (R-134a, R-407c, R-404a, R-410c, etc.) that can be moved by latent heat into a fluid which is sealed in the closed circuit 3 and which can change phase can be used.

As described above, in the air conditioning system according to the present invention, the user side machine is supplied to a heat exchanger, a heat exchanger, and supplies air in a room to a flow control valve and a heat exchanger for controlling the amount of fluid that can change a phase. Blower means, a physical value detection means for detecting a physical value such as temperature, and a signal control means connected to the actuation and detection means, wherein the heat source side machine is used for communicating with the signal control means and as a flow rate control valve. Since the control means for outputting the control signal is provided, even if the cooling load is the same, the opening ratio of the flow control valve of the user side machine mounted on the higher floor is higher than that of the user side machine mounted on the lower floor. Can be controlled to be large. According to the above structure, the air conditioning characteristic in the air conditioning system which is basically controlled by the natural circulation is that it is difficult to supply the fluid to the user side machine mounted on the higher floor, so that the air conditioning operation is difficult to be improved.

Furthermore, in an air conditioning system in which the opening ratio of the flow control valve is maintained at a predetermined small opening ratio for a predetermined time interval when starting cooling, when the cooling load at the start is large and the fluid evaporates in the user side machine for a short time. Even the amount of fluid supplied to the user side machine through the flow control valve is small. Therefore, the degree of increase in pressure is limited, and the disadvantage that the cooling cannot be performed by returning the fluid into the flow control valve at the start of cooling can be avoided.

Furthermore, in an air conditioning system in which the opening ratio of the flow control valve is maintained at a predetermined large opening ratio for a predetermined time interval at the start of heating, even when the heating load is suddenly increased at the start, the fluid supply amount is sufficient. . Therefore, the amount of fluid supply can be avoided from condensing at the inlet of the heat exchanger of the user side machine so that the cool air is blown into the room as in the prior art.

When the heating detects that the circulating amount of the fluid is insufficient, the air-conditioning system in which the opening ratio of the flow control valve is fully opened, or heating so that a large amount of fluid capable of changing the phase starts dormant or dormant upon operation. In an air conditioning system in which open and closed valves, which connect the ends of pipes which are separated from each other when condensed in a closed circuit at the start, are opened, the condensed liquid is heated by a heat source side machine and through an open and closed valve or flow control valve It is pushed into the liquid phase pipe, and thus is returned to the heat source side machine by the electric pump provided in the liquid phase pipe. Thus, the amount of circulating fluid is immediately increased, so that the heating performance is recovered early. As a result, there is no need to fill a closed circuit with a large amount of fluid in consideration of sleep as in the conventional case.

Furthermore, the inlet or outlet temperature of the fluid flowing in the user side machine in which the physical value detecting means is influenced by the temperature difference or in the efficiently operated user side machine is compared with a plurality of other efficiently operated user side machines. In an air conditioning system that continues for a predetermined time interval when recognized as important, the flow rate control of another user side machine in normal operation, even when fluid flows easily for some reason so that the user side machine is abnormally overcooled. The opening ratio of the valve is slightly opened based on the forced adjustment command output by the heat source side machine, and the amount of fluid flowing to the user side machine in normal operation is increased so that the flow rate of the fluid to the user side machine is increased. Reduced air conditioning performance of another user side machine (4). It is limited to the level of the bath performance.

Furthermore, the inlet or outlet temperature of the fluid flowing in the user side machine in which the physical value detecting means is influenced by the temperature difference or in the efficient operation of the user side machine is compared with a plurality of other efficient user side machines. In an air conditioning system that continues for a predetermined time interval when it is recognized that it is important, the flow control valve of the user side machine is adjusted in a direction to solve the critical condition, and the flow of fluid which can change phase at the outlet and the opening. The temperature difference is circulated and supplied to the user side machine, and the opening ratio of the flow rate control valve corresponding to the user side machine is forcibly adjusted, so that the same air conditioning performance can be ensured in all the user side machines.

Further, as shown in the embodiment, in an air conditioning system in which an absorption cooling and heating device having a heating function and a cooling function by burning a gas or oil is used as a heat source side machine, driving or controlling an auxiliary pump for cooling. The power controlling the device is only used for power when performing cooling, so that the power can be effectively reduced in summer when the amount causing power is maximum.

Claims (12)

The phase between the gas phase and the liquid phase can be changed by the specific gravity difference between the gas phase and the liquid phase between the heat source side machine and a plurality of user side machines disposed at least half under the heat source side machine so that each user side machine is cooled. In an air conditioning system for circulating fluid, each user side machine supplies air conditioning air to a room through a heat exchanger, a flow control valve for controlling the volume of the fluid supplied to the heat exchanger, and a heat exchanger. Blower means for detecting, physical value detecting means for detecting a physical value related to an air conditioning load such as temperature, and signal control means for heat exchanger, flow control valve, blower means and physical value detecting means, The side machine outputs a control signal to the flow rate control valve of the user side machine and An air conditioning system, comprising: control means for communicating with a signal control means. The air conditioning system according to claim 1, wherein the control means has a function of determining a set opening ratio in consideration of a height and a signal output from the physical value detecting means. 3. An air conditioning system according to claim 2, wherein said control means has a function of determining a higher set opening ratio of said flow control valve as the user side machine is mounted on a higher floor. The air conditioning system according to claim 1, wherein said control means has a function of maintaining the opening ratio of said flow control valve at a predetermined small opening ratio for a predetermined period when cooling starts. 5. The control according to claim 4, characterized in that the control means has a function of maintaining the opening ratio of the flow control valve at a smaller opening ratio as the user side machine is mounted on a higher floor for a predetermined period of time when cooling starts. Air conditioning system. The flow path switching mechanism and the pump are provided in a liquid pipe through which the liquid fluid flows, and absorb the heat in the heat source side machine and the evaporated fluid is introduced into the user side machine to discharge and condense the heat. Fluid is returned to the heat source side machine by the discharge force of the pump so that heating is performed at each user side machine and the control means opens the flow control valve at a predetermined large opening ratio for a predetermined period when heating is started. Air conditioning system characterized in that it has a function to maintain the ratio. 7. The flow control apparatus according to claim 6, wherein the control means has a function of maintaining the opening ratio of the flow control valve at a larger opening ratio as the user side machine is mounted on the lower floor for a predetermined period of time when heating is started. Air conditioning system. The flow path switching mechanism and the pump are provided in a liquid pipe through which the liquid fluid flows, and absorb the heat in the heat source side machine and the evaporated fluid is introduced into the user side machine to discharge and condense the heat. Fluid is returned to the heat source side machine by the discharge force of the pump so that heating is performed at each user side machine and the control means detects an insufficiency in the amount of circulation of the fluid during the heating rate of the flow control valve. Air conditioning system, characterized in that with the function to open almost completely. 9. The liquid pipe according to claim 8, wherein the liquid pipe in which the liquid fluid flows and the gas pipe in which the gas fluid flows are respectively divided from the main pipe connected to the heat source side machine, and the end of the split pipe connected to each user exchanger is connected through an on / off valve. And the control means have a function of opening and closing the valve in response to the full opening of the flow control valve in an interlocking manner. 10. The air conditioning system according to claim 9, wherein said control means has a function of opening said on-off valve once when starting heating. 2. A condition as claimed in claim 1, wherein the difference in physical values caused by the temperature or temperature difference of the inlet or outlet of the fluid flowing in the effectively operated user side machine is significant compared to other effectively operated user side machines continuing for a predetermined period of time. When the physical value detecting means recognizes, the control means has a function of adjusting the flow rate control valves of a plurality of different user side machines in the direction of determining the important state of the user side machine in an important state. Air conditioning system. 2. A condition as claimed in claim 1, wherein the difference in physical values caused by the temperature or temperature difference of the inlet or outlet of the fluid flowing in the effectively operated user side machine is significant compared to other effectively operated user side machines continuing for a predetermined period of time. And the control means has a function of adjusting the flow control valve of the user side machine in the direction of determining the critical state when the physical value detecting means recognizes.