JP2007113883A - Refrigerant supply system and computer program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a refrigerant supply system for supplying water of a temperature requested by a prescribed facility while correctly and quickly controlling its flow rate. <P>SOLUTION: A pump has a capacity of several times or more the flow rate requested by the prescribed facility (test facility). A flowmeter comprises a flowmeter of small quantity, measuring the flow rate when the flow rate requested by the prescribed facility is small, and a flowmeter of an intermediate quantity capable of measuring the flow rate of a range over the flow rate measured by the flowmeter of a small quantity. The excess flow after adjustment by an adjusting valve is returned to a refrigerant supply tank. The flow rate is adjusted on the basis of the relationship of the temperature and flow rate requested by the prescribed facility by inputting at least two of three kinds of parameters of inlet temperature, outlet temperature and flow rate. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a technique for accurately controlling and supplying a flow rate of a desired water temperature when performing a performance test of an artificial environment device, for example, hot water supply / air conditioning. For example, the present invention relates to a system and layout for flow rate stabilization and flow rate densification in predetermined facilities for hot water supply and air conditioning.

In a performance test of a hot water supply facility, the required water temperature differs depending on the content of the test. The water flow that is the water temperature required for the test content is supplied from the heat source tank. Further, the water stored in the heat source tank is provided with a cooling device and a heating device, adjusted to a desired temperature, and then provided to a desired facility.
Here, the cooling device generally includes a cold heat tank that stores a refrigerant having a temperature lower than that of the refrigerant in the heat source tank, and a heat exchanger that performs heat exchange with the refrigerant in the cold heat tank.
In addition, what was extracted as a related patent is, for example, the technique described in Patent Document 1.

Japanese Patent Application Laid-Open No. 2004-232977

  Patent Document 1 discloses a technique for improving the detection accuracy and control performance of the operating state in consideration of individual differences inherent in the components constituting the water heater.

In order to maintain the test accuracy at a high level, the desired water temperature and the amount of water required require considerable accuracy.
If the desired flow rate and the flow rate supplying it are different, adjustment is necessary. When the flow rate to be supplied is larger than the desired flow rate, the supply amount may be reduced, and the adjustment is relatively easy.

  However, when the flow rate supplied relative to the desired flow rate is small, adjustment in a short time is difficult. It must be supplied after ensuring the desired water temperature. Therefore, when the amount of water that can ensure the desired water temperature is not abundant, it is necessary to increase the amount of water at the desired water temperature, and it is difficult to achieve this in a short time.

This invention makes it a solution subject to provide the technique which can stabilize the flow volume of the refrigerant | coolant requested | required from the hot water supply / air-conditioning predetermined equipment, for example, and can improve flow volume precision.
An object of the invention described in claims 1 to 7 is to provide a refrigerant supply system capable of stabilizing the flow rate of refrigerant required from predetermined facilities for hot water supply and air conditioning and improving the flow rate accuracy.
An object of the invention described in claims 8 to 10 is to provide a refrigerant supply program capable of stabilizing the flow rate of refrigerant required from predetermined facilities for hot water supply and air conditioning and improving the flow rate accuracy.

(Claim 1)
The invention according to claim 1 is a heat source tank for supplying a refrigerant having a temperature and a flow rate required by a predetermined facility, a pump for sending the refrigerant in the heat source tank to the predetermined facility, and a flow rate of the refrigerant sent by the pump The present invention relates to a refrigerant supply system comprising a flow meter for detecting the flow rate, an adjustment valve for adjusting the flow rate required from predetermined equipment, and a flow rate control device for controlling the flow rate of refrigerant required from the predetermined equipment.
The pump has a capacity several times or more the flow rate required from a predetermined facility. In addition, the flow meter can measure the flow rate when the flow rate required from a given facility is small, and the flow rate when the flow rate for the small amount exceeds the measurable range. And a medium flow meter.

(Glossary)
The “predetermined equipment” is, for example, a test room or experimental equipment used for measurement or performance test.
The capacity of the “pump” is secured several times, preferably about 10 times the flow rate required from a predetermined facility.
It should be noted that the heat source tank secures a sufficient volume capable of stably sending the flow rate according to the capacity of the pump. For example, when the flow rate required from the facility is 10 liters / h, the heat source tank has an effective capacity of 1620 liters, which is 15 times or more.
The “flow meter” needs to be a flow meter that can ensure high accuracy. For example, a positive displacement flow meter.

(Function)
First, the flow rate data is input to the flow rate control device among the data related to the temperature and the flow rate related to the refrigerant required from the predetermined equipment. Thereby, the flow control device controls the pump and the regulating valve to supply the refrigerant to a predetermined facility. Since there is a margin in the capacity of the pump, a flow rate with a margin relative to the flow rate required from a predetermined facility is fed.
When the flow rate supplied to a predetermined facility is small, a small amount of flow meter measures the flow rate. When the flow rate when the small amount flow meter exceeds the measurable region is required, the medium amount flow meter measures the flow rate. This ensures accuracy with respect to flow rate measurement.
The measured flow rate is input to the flow control device and used for recontrol of the pump and the regulating valve.

(Claim 2)
Invention of Claim 2 limited the refrigerant | coolant supply system of Claim 1,
A return path for returning the excess flow rate adjusted by the adjustment valve to the heat source tank is provided.

(Function)
The regulating valve regulates the flow rate, sends the flow rate required from the predetermined equipment to the equipment, and returns the adjusted flow rate to the heat source tank via the return path.
Since the surplus flow rate is returned to the heat source tank, the temperature-controlled refrigerant can be used effectively. Moreover, the capacity | capacitance of a heat source tank will ensure a substantially large capacity | capacitance.

(Claim 3)
The invention according to claim 3 limits the refrigerant supply system according to claim 1 or claim 2.
That is, an inlet thermometer for measuring an inlet temperature of the refrigerant supplied to the predetermined facility at the predetermined facility, and an outlet temperature of the refrigerant supplied to the predetermined facility and used. An outlet thermometer to measure, and the flow rate control device includes at least two of three parameters of an inlet temperature measured by the inlet thermometer, an outlet temperature measured by the outlet thermometer, and a flow rate measured by the flow meter. This is a refrigerant supply system in which the flow rate is adjusted based on the relationship between the temperature and the flow rate required by predetermined equipment.

(Function)
Regarding the flow rate control, it is reasonable to select and control two of the three types of parameters of the inlet temperature, the outlet temperature, and the flow rate. That is, any combination of the inlet temperature and outlet temperature, the inlet temperature and flow rate, or the outlet temperature and flow rate is measured, and control relating to the desired amount of water is performed.
It is also possible to acquire all three parameters, calculate each separately according to the combination of the two parameters, and fine-tune using the calculation results.

(Claim 4)
Invention of Claim 4 limited the refrigerant | coolant supply system in any one of Claims 1-3,
The heat source tank is located higher than the predetermined facility.

(Function)
Since the heat source tank is positioned higher than the predetermined equipment, when the required flow rate is sent to the equipment, a further margin of the conveyance pressure can be provided in the pump.

(Claim 5)
The invention according to claim 5 limits the refrigerant supply system according to any one of claims 1 to 4.
That is, when there are two types of refrigerant temperatures required from a predetermined facility, an auxiliary heat source tank is provided separately from the heat source tank to supply a type of refrigerant that is not supplied by the heat source tank. Like the heat source tank, the auxiliary heat source tank includes a pump that sends the refrigerant to a predetermined facility, a flow meter that detects the flow rate of the refrigerant sent by the pump, and an adjustment valve that adjusts the flow rate required by the predetermined facility. And a flow rate control device for controlling the flow rate of the refrigerant required from a predetermined facility.

(Function)
If there is an auxiliary heat source tank, it is possible to cope with the case where there are two types of refrigerant temperatures required from a predetermined facility.
In addition, when the flow rate of refrigerant required from a given facility is large, the capacity of the main tank may not be sufficient. In this case, the auxiliary heat source tank sets the temperature of the refrigerant to be supplied to that of the heat source tank. It functions as a buffer for the refrigerant supply capacity in the heat source tank.

(Claim 6)
The invention described in claim 6 limits the refrigerant supply system according to any one of claims 1 to 5.
That is, the refrigerant supply system is characterized in that the refrigerant of the cold heat tank is ethylene glycol, and the refrigerant that the heat source tank supplies to predetermined equipment is water.

(Glossary)
The refrigerant in the cold tank is cooled by, for example, a Blainchler unit. The “brinchler unit” generally refers to a heat source device that adjusts a refrigerant to a predetermined temperature.

(Function)
By using ethylene glycol as the refrigerant in the cold heat tank, the refrigerant close to zero degrees Celsius can be supplied to the heat source tank.
If the refrigerant in the heat source tank is ethylene glycol instead of water, the subzero refrigerant can be supplied to a predetermined facility.

(Claim 7)
The invention described in claim 7 limits the refrigerant supply system according to any one of claims 1 to 6.
That is, the heat source tank is provided with an electric heater for heating the refrigerant.

(Function)
When the refrigerant temperature in the heat source tank is lower than the refrigerant temperature required from a predetermined facility, the temperature can be adjusted accurately and quickly by the electric heater.
The cold heat tank may also be provided with an electric heater. For example, if the refrigerant temperature in the cold heat tank is considerably lower than the refrigerant temperature required from a predetermined facility, the facility refrigerant in the heat source tank may be overcooled. In that case, the refrigerant temperature in the cold heat tank can be supplied to the heat exchanger after the temperature of the refrigerant is raised by the electric heater.

(Claim 8)
The invention described in claim 8 requires a heat source tank for supplying a refrigerant having a temperature and a flow rate required from a predetermined facility, a pump for sending the refrigerant in the heat source tank to the predetermined facility, and a predetermined facility. An adjustment valve for adjusting the flow rate of the refrigerant, an inlet thermometer for measuring an inlet temperature of the refrigerant supplied to the predetermined equipment at the predetermined equipment, and the predetermined refrigerant of the used refrigerant supplied to the predetermined equipment. The present invention relates to a control program for a refrigerant supply system that includes an outlet thermometer that measures an outlet temperature in equipment.
The control program includes a required refrigerant data input procedure for inputting required refrigerant data related to the temperature and flow rate of refrigerant required from a predetermined facility, an inlet temperature data input procedure for inputting inlet temperature data measured by an inlet thermometer, An outlet temperature data input procedure for inputting outlet temperature data measured by the outlet thermometer, a temperature calculation procedure for calculating the temperature of the refrigerant to be supplied from the inlet temperature data, the outlet temperature data, and the required refrigerant data, and the temperature calculation procedure A control program for a refrigerant supply system for causing a computer to execute a control command output procedure for outputting a control command for adjusting the temperature of a refrigerant supplied to a predetermined facility based on the calculated temperature calculated in .

(Claim 9)
The invention described in claim 9 also includes a heat source tank for supplying a refrigerant having a temperature and a flow rate required from a predetermined facility, a pump for sending the refrigerant in the heat source tank to the predetermined facility, and a request from the predetermined facility. A regulating valve that adjusts the flow rate of the refrigerant, an inlet thermometer that measures an inlet temperature of the refrigerant supplied to the predetermined equipment at the predetermined equipment, and the predetermined refrigerant that has been used after being supplied to the predetermined equipment The control program of a refrigerant | coolant supply system provided with the exit | outlet thermometer which measures the exit | outlet temperature in the installation of this.
The control program includes a required refrigerant data input procedure for inputting required refrigerant data related to the temperature and flow rate of refrigerant required from a predetermined facility, an inlet temperature data input procedure for inputting inlet temperature data measured by an inlet thermometer, The flow rate data input procedure for inputting the flow rate data measured by the flow meter, the temperature calculation procedure for calculating the temperature of the refrigerant to be supplied from the inlet temperature data, the flow rate data, and the required refrigerant data, and the temperature calculation procedure are used. A control program for a refrigerant supply system for causing a computer to execute a control command output procedure for outputting a control command for adjusting the temperature of the refrigerant supplied to a predetermined facility based on the calculated temperature.

(Claim 10)
The invention described in claim 10 also includes a heat source tank for supplying a refrigerant having a temperature and a flow rate required from a predetermined facility, a pump for sending the refrigerant in the heat source tank to the predetermined facility, and a request from the predetermined facility. A regulating valve that adjusts the flow rate of the refrigerant, an inlet thermometer that measures an inlet temperature of the refrigerant supplied to the predetermined equipment at the predetermined equipment, and the predetermined refrigerant that has been used after being supplied to the predetermined equipment The control program of a refrigerant | coolant supply system provided with the exit | outlet thermometer which measures the exit | outlet temperature in the installation of this.
The control program includes a required refrigerant data input procedure for inputting required refrigerant data related to the temperature and flow rate of refrigerant required from a predetermined facility, an outlet temperature data input procedure for inputting outlet temperature data measured by the outlet thermometer, The flow rate data input procedure for inputting the flow rate data measured by the flow meter, the temperature calculation procedure for calculating the temperature of the refrigerant to be supplied from the outlet temperature data, the flow rate data and the required refrigerant data, and the temperature calculation procedure are used. A control program for a refrigerant supply system for causing a computer to execute a control command output procedure for outputting a control command for adjusting the temperature of the refrigerant supplied to a predetermined facility based on the calculated temperature.

  The inventions according to claims 8 to 10 can be stored in a recording medium and provided to another refrigerant supply system, or can be provided to another refrigerant supply system via communication means.

Claims 8 to 10 can be summarized as the following inventions.
That is, a request data input procedure for inputting request data regarding the temperature and flow rate of the refrigerant required from the predetermined equipment, and a control for outputting a control command for adjusting the temperature of the refrigerant calculated from the request data A control program for a refrigerant supply system for causing a computer to execute a command output procedure.

According to the invention described in claims 1 to 7, it is possible to provide a refrigerant supply system capable of stabilizing the flow rate of refrigerant required from predetermined hot water supply / air-conditioning equipment and improving the flow rate accuracy. .
According to the invention described in claims 8 to 10, it is possible to provide a refrigerant supply program capable of stabilizing the flow rate of refrigerant required from predetermined hot water supply / air conditioning facilities and improving the flow rate accuracy. .

Fine adjustment of the flow rate required from the test room can be performed easily and in a short time. This is because the flow rate that can be supplied has a large margin.
Accurate measurement of the flow rate is also possible. This is because the flow meter can be switched between a small amount and a medium amount.
In addition, since the heat source tank is higher than the test room, potential energy can be used and the pump performance is assisted. Furthermore, the layout relating to the chilling unit that is preferably installed outdoors is efficient because the relationship with the cold heat tank is taken into consideration.

  The present invention will be described in more detail with reference to embodiments and drawings. The drawings used here are FIGS. 1 to 4. 1 and 2 are simplified model views of the present invention, and FIGS. 3 and 4 are flowcharts.

(Figure 1)
FIG. 1 shows a heat source tank for supplying a facility refrigerant having a temperature and flow rate required by a test facility, and the refrigerant having a temperature lower than the refrigerant temperature accumulated in the heat source tank is accumulated and accumulated. The cooling tank that can supply the cooled refrigerant to the heat source tank, the air-cooled blownler unit for lowering the temperature of the refrigerant accumulated in the cooling tank, and the temperature of the refrigerant for the equipment in the heat source tank using the refrigerant in the cold tank And a heat exchanger for lowering the temperature.

  As the heat source tank and the cold heat tank, a tank capable of securing a sufficient capacity several times the flow rate required from a predetermined facility is adopted. Specifically, it has an effective capacity of 1680 liters.

In the heat source tank and the cold heat tank, a stirrer for stirring the refrigerant in the tank and an electric heater capable of raising the temperature of the refrigerant are provided.
This electric heater is highly instantaneous and can be performed quickly and accurately when the refrigerant temperature is increased by electric control. Fine adjustment of the refrigerant temperature is also possible.
This electric heater is provided not only in the heat source tank but also in the cold heat tank. For example, when the temperature of the refrigerant to be secured in the heat source tank is higher than the refrigerant temperature in the cold heat tank, the refrigerant temperature in the cold heat tank is raised by this electric heater, and then the heat source is passed through the heat exchanger. It will be supplied to the tank.

The heat source tank includes a stirrer for stirring the facility refrigerant in the heat source tank, and a coolant supply port for supplying the facility coolant to the test facility at a position close to the electric heater. In addition, a cooling refrigerant return port for returning the facility refrigerant cooled by the heat exchanger into the heat source tank at a position away from the refrigerant supply port.
Furthermore, an incomplete partition that prevents the refrigerant in the heat source tank from being completely freely stirred is provided between the cooling refrigerant return port and the electric heater. When the side where the electric heater partitioned by this incomplete partition exists is the heating region, and the side where the cooling refrigerant return port is present is the cooling region, the refrigerant supply port is positioned in the heating region. Become.

The partition (incomplete partition) is installed so that the lower end thereof is located above the bottom surface of the heat source tank, so that the clearance between the lower end of the incomplete partition and the bottom surface of the heat source tank is secured. The refrigerant is located between the heating area and the cooling area. Note that the upper end of the partition is positioned above the water surface in the cold / hot water tank.
Moreover, this partition is provided also in the cold tank with the same structure.

A pump (not shown in FIGS. 1 and 2) for supplying the required refrigerant to a predetermined facility has a capacity of 10 times or more the required flow rate of the refrigerant. In addition, a return path (not shown in FIGS. 1 and 2) for returning a refrigerant having a flow rate higher than required out of the refrigerant once discharged from the heat source tank to supply to a predetermined facility is provided. Is communicated with the cooling region.
The used refrigerant used in the test facility is also returned from the used refrigerant return port provided in the cooling region of the heat source tank.

  The Blinchler unit is air-cooled and is located outdoors, making it easy to release the exhaust heat from the cold tank.

  The refrigerant in the cold heat tank is ethylene glycol, and the refrigerant in the heat source tank is water. By using ethylene glycol as the refrigerant in the cold tank, water up to zero degrees Celsius can be supplied to the test equipment. Further, when the refrigerant temperature in the heat source tank is lower than the refrigerant temperature required from the test facility, it can be adjusted by an electric heater.

Hereinafter, the operation of the embodiment shown in FIG. 1 will be described.
Low temperature refrigerant is accumulated in both tanks by a heat exchanger provided to supply the cold heat of the cold heat tank to the heat source tank. And the refrigerant | coolant of the temperature and flow volume requested | required from a test facility is ensured in a heat source tank. The stirrer stirs the refrigerant in the heat source tank at all times or as necessary.
When the refrigerant temperature secured by the heat source tank is higher than the refrigerant temperature required from a predetermined facility, the refrigerant whose temperature has decreased is procured from the cooling refrigerant return supply port via the heat exchanger. When the refrigerant temperature secured by the heat source tank is lower than the refrigerant temperature required from the test facility, the refrigerant temperature is raised by the electric heater. Since adjustment is performed by an electric heater, responsiveness is fast.

  Since the cooling refrigerant return port is separated from the electric heater, it is easy to control even when it is necessary to raise the refrigerant temperature again. Usually, the refrigerant temperature in the heat source tank is adjusted to be slightly lower than the refrigerant temperature required by a predetermined facility, and is finely adjusted by heating with an electric heater as necessary. This is because it is easy to adjust the heat acquisition and heat loss from the flow path to the test facility.

(Figure 2)
The embodiment shown in FIG. 2 includes an auxiliary heat source tank (indicated as “heat source tank B” in the figure) that can supply refrigerant to a predetermined facility in the same manner as the heat source tank. Different from 1.

The auxiliary heat source tank (B) communicates with the test equipment without being communicated with the heat source tank (A) (illustrated with a broken line arrow). When there are two types of refrigerant temperatures required by the test facility, the auxiliary heat source tank (B) provided separately from the heat source tank (A) supplies the type of facility refrigerant not supplied by the heat source tank (A). To do.
“When there are two types of refrigerant temperatures required from the test facility” is, for example, an experiment that requires two types of refrigerants, a refrigerant for cooling and a refrigerant for exhaust heat.

  This auxiliary heat source tank (B) can function as a buffer for the refrigerant supply capability when the required flow rate is large, although the temperature of the refrigerant required by the test facility is one kind. That is, when the flow rate of the refrigerant required from the predetermined equipment is large, there is a case where there is no room in the capacity of the heat source tank. In this case, the auxiliary heat source tank (B) is installed in the equipment in the heat source tank (A). It is controlled to the same temperature as the refrigerant for use and assists the required refrigerant supply capacity.

By the way, a flow meter, a water temperature meter, a regulating valve, a pump and the like necessary for providing the temperature and flow rate of the refrigerant required from the test facility are provided. The performance of the pump is 2-20 cubic meters / h.
The heat source tank and the heat source tank are located about 8 meters higher than the test facility, and since the flow rate can be supplied by using the difference in height, the burden on the pump can be reduced. In other words, even when a large flow rate is required, the range that can be handled by the capacity of the pump is extremely wide.

  About the excess flow volume adjusted by the regulating valve, a return path (not shown in FIG. 2) for returning to the cooling area side of the heat source tank is provided. Since the surplus flow rate is returned to the heat source tank, the temperature-controlled refrigerant can be used effectively. Moreover, the capacity | capacitance of a heat source tank will ensure a substantially large capacity | capacitance.

(Figure 3)
FIG. 3 is a control flowchart after the characteristic test is selected for the test type. In the figure, the cold tank is referred to as a “brine tank”.
First, the heat source is selected as “water heat source” or “air heat source”. If the “water heat source” is selected, then what is the device to be tested is selected.
In the case of a water-cooled packaged air conditioner (PAC), a fan coil unit (FCU) / air handling unit (AHU), or a water heater, a control method is selected. Is it control of inlet temperature and flow rate, control of outlet temperature and inlet temperature, or control of outlet temperature and flow rate?

There are three reasons for the control method as follows. That is, the control of the flow rate is required from the test facility if there are at least two of the three parameters of the inlet temperature measured by the inlet thermometer, the outlet temperature measured by the outlet thermometer, and the flow rate measured by the flow meter. This is because the flow rate can be adjusted from the relationship between temperature and flow rate.
Although not adopted in the present embodiment, all three parameters may be acquired, and each may be calculated and fine-tuned according to a combination of the two parameters.

  When the inlet temperature and flow rate are selected, whether or not to use the flow rate supply device is selected. When using, further select whether to control the outlet temperature or flow rate, and set the test conditions. This test condition can be not only a steady test but also a non-steady test.

When not using the flow rate supply device, use the heat source side supply device and set the test conditions.
Regarding the control method, whether the outlet temperature and flow rate control is selected or the outlet temperature and the inlet temperature are selected, the heat source side supply device is used to set the test conditions.

  When “air heat source” is selected as the heat source, a control method for the indoor test room, that is, temperature control or heat control is selected. After the selection, test conditions are set. This test condition is also possible for not only a steady test but also a non-steady test.

(Fig. 4)
FIG. 4 is a control flowchart after the ability test is selected for the test type. In the figure, the cold tank is referred to as a “brine tank”.
When a room air conditioner (RAC) or packaged air conditioner (PAC) is selected for the equipment under test, operation of the indoor test room, heat source tank, or heat source tank is possible regardless of whether it is a “water heat source” or “air heat source”. And start a steady test as a test mode selection.

  When the test target device in the “air heat source” selects the chilling unit (CHU), the operation of the outdoor test room, the brine tank, and the use side tank is started, and the control method for the use side tank is selected. Is it control of outlet temperature and flow rate, control of outlet temperature and inlet temperature, or control of inlet temperature and flow rate? When the selection is completed, a steady test is started as a test mode selection.

  When the test target device selects the chilling unit (CHU) in the “water heat source”, the control method of the heat source tank or the control method of the use tank is selected. In this case as well, the selection of the control method is the control of the outlet temperature and flow rate, the control of the outlet temperature and inlet temperature, or the control of the inlet temperature and flow rate. When the selection is completed, a steady test is started as a test mode selection.

  The invention of the present application is employed in a situation where refrigerant supply at a predetermined temperature and flow rate is required from a predetermined facility.

It is a conceptual diagram which shows 1st embodiment of this invention. It is a conceptual diagram which shows 2nd embodiment of this invention. It is a control flowchart after selecting a characteristic test about a test kind. It is a control flowchart after selecting a capability test about a test kind.

Claims (10)

A heat source tank for supplying a refrigerant having a temperature and a flow rate required from a predetermined facility;
A pump that sends the refrigerant in the heat source tank to a predetermined facility;
A flow meter for detecting the flow rate of the refrigerant for equipment sent by the pump;
An adjustment valve that adjusts the flow rate required by a given facility;
A refrigerant supply system comprising a flow rate control device for controlling a flow rate of refrigerant required from a predetermined facility,
The pump has a capacity more than several times the flow rate required from a given facility,
A flow meter consists of a small amount of flow meter that measures the flow rate when the flow rate required by a given facility is small, and a medium amount that can measure the flow rate when the small amount of flow meter exceeds the measurable range. A refrigerant supply system comprising a flow meter for use.   The refrigerant supply system according to claim 1, further comprising a return path for returning the excess flow rate adjusted by the adjustment valve to the heat source tank. An inlet thermometer for measuring an inlet temperature of the refrigerant supplied to the predetermined facility in the predetermined facility;
An outlet thermometer that measures the outlet temperature of the refrigerant supplied to the predetermined facility and used in the predetermined facility;
The flow rate control device inputs at least two of the three types of parameters of the inlet temperature measured by the inlet thermometer, the outlet temperature measured by the outlet thermometer, and the flow rate measured by the flow meter, and is requested from a predetermined facility. The refrigerant supply system according to claim 1, wherein the flow rate is adjusted based on a relationship between the temperature and the flow rate.   The refrigerant supply system according to any one of claims 1 to 3, wherein the heat source tank is positioned higher than the predetermined facility. When there are two types of refrigerant temperatures required from a given facility, an auxiliary heat source tank is provided separately from the heat source tank to supply a type of refrigerant that the heat source tank does not supply,
The auxiliary heat source tank includes a pump that sends the refrigerant of the auxiliary heat source tank to a predetermined facility,
A flow meter for detecting the flow rate of the refrigerant sent by the pump;
An adjustment valve that adjusts the flow rate required by a given facility;
The refrigerant supply system according to any one of claims 1 to 4, further comprising a flow rate control device that controls a flow rate of the refrigerant required from a predetermined facility. The refrigerant supply system according to any one of claims 1 to 5, wherein the refrigerant of the cold heat tank is ethylene glycol, and the refrigerant that the heat source tank supplies to predetermined equipment is water. The refrigerant supply system according to any one of claims 1 to 6, wherein the heat source tank includes an electric heater for heating the refrigerant. A heat source tank for supplying a refrigerant having a temperature and a flow rate required from a predetermined facility;
A pump that sends the refrigerant in the heat source tank to a predetermined facility;
An adjustment valve that adjusts the flow rate required by a given facility;
An inlet thermometer for measuring an inlet temperature of the refrigerant supplied to the predetermined facility at the predetermined facility;
A control program for a refrigerant supply system comprising an outlet thermometer for measuring an outlet temperature of the refrigerant supplied to a predetermined facility and used by the predetermined facility;
Requested refrigerant data input procedure for inputting required refrigerant data related to the temperature and flow rate of refrigerant required from a predetermined facility;
Inlet temperature data input procedure for inputting the inlet temperature data measured by the inlet thermometer,
An outlet temperature data input procedure for inputting outlet temperature data measured by the outlet thermometer,
A temperature calculation procedure for calculating the temperature of the refrigerant to be supplied from the inlet temperature data and the outlet temperature data and the required refrigerant data;
A refrigerant supply system for causing a computer to execute a control command output procedure for outputting a control command for adjusting the temperature of the refrigerant supplied to a predetermined facility based on the calculated temperature calculated in the temperature calculation procedure Control program. A heat source tank for supplying a refrigerant having a temperature and a flow rate required from a predetermined facility;
A pump that sends the refrigerant in the heat source tank to a predetermined facility;
A flow meter for detecting the flow rate of the refrigerant sent by the pump;
An adjustment valve that adjusts the flow rate required by a given facility;
A control program for a refrigerant supply system comprising an inlet thermometer for measuring an inlet temperature of the refrigerant supplied to the predetermined equipment at the predetermined equipment,
Requested refrigerant data input procedure for inputting required refrigerant data related to the temperature and flow rate of refrigerant required from a predetermined facility;
Inlet temperature data input procedure for inputting the inlet temperature data measured by the inlet thermometer,
Flow rate data input procedure to input flow rate data measured by the flow meter,
A temperature calculation procedure for calculating the temperature of the refrigerant to be supplied from the inlet temperature data and flow rate data and the required refrigerant data;
A refrigerant supply system for causing a computer to execute a control command output procedure for outputting a control command for adjusting the temperature of the refrigerant supplied to a predetermined facility based on the calculated temperature calculated in the temperature calculation procedure Control program. A heat source tank for supplying a refrigerant having a temperature and a flow rate required from a predetermined facility;
A pump that sends the refrigerant in the heat source tank to a predetermined facility;
A flow meter for detecting the flow rate of the refrigerant sent by the pump;
An adjustment valve that adjusts the flow rate required by a given facility;
A control program for a refrigerant supply system comprising an outlet thermometer for measuring an outlet temperature of the refrigerant supplied to a predetermined facility and used by the predetermined facility;
Requested refrigerant data input procedure for inputting required refrigerant data related to the temperature and flow rate of refrigerant required from a predetermined facility;
An outlet temperature data input procedure for inputting outlet temperature data measured by the outlet thermometer,
Flow rate data input procedure to input flow rate data measured by the flow meter,
A temperature calculation procedure for calculating the temperature of the refrigerant to be supplied from the outlet temperature data and the flow rate data and the required refrigerant data;
A refrigerant supply system for causing a computer to execute a control command output procedure for outputting a control command for adjusting the temperature of the refrigerant supplied to a predetermined facility based on the calculated temperature calculated in the temperature calculation procedure Control program.

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