KR101077422B1 - Flow rate control system - Google Patents

Abstract

It is an object of the present invention to quantitatively determine whether there is a problem in terms of energy efficiency or to actively cope with energy saving.

The actual flow rate QR of the fluid flowing through the conduit 13 is measured by the actual flow rate measurement unit 25B. The excess flow rate integration part 25D accumulates the excess amount ΔQ of the actual flow rate QR from the design flow rate QD for each excess period in which the actual flow rate QR of the fluid exceeds the design flow rate QD. The accumulated value ΣΔQ of this excess flow rate is stored in the excess flow accumulated value storage unit 21 and displayed on the display unit 17. By referring to the integrated value ΣΔQ of the excess flow rate, it is possible to quantitatively know how much the system is operating as designed, how far away from the design, and so on. Further, by analyzing the integrated value ΣΔQ of the excess flow rate, it is possible to verify how much energy the system is wasting, or not an abnormality has occurred.

Description

Flow control system {FLOW RATE CONTROL SYSTEM}

The present invention relates to a flow rate control system for controlling the flow rate of the fluid flowing through the flow path.

Conventionally, as this kind of flow control system, there exists an air conditioning control system which controls the flow volume of the heat medium (cold and hot water) to an air conditioner (for example, refer patent document 1, 2). When constructing such an air conditioning control system, the maximum amount of air conditioning load (maximum air conditioning load) in the control target region for supplying the air conditioning air from the air conditioner is approximated, and the maximum air conditioning load is eliminated. As a facility which can be performed, the flow control valve which controls the supply amount of cold / hot water from a heat source apparatus, an air conditioner, a heat source apparatus to an air conditioner, etc. should be selected, for example.

In this case, if the capacity suitable for the maximum air conditioning load is selected as the design capability, the maximum capacity is less than the design capability required for performance verification after the air conditioning control system is built, or after the operation of the air conditioning control system, There exists a possibility that the problem that the air conditioning load of an area | region increases increases and exceeds the maximum air conditioning load at the time of design. Therefore, in consideration of safety, a facility having a maximum capacity is selected with a margin rather than the required design capability.

[Patent Document 1] Japanese Patent Application Laid-Open No. 11-211191

[Patent Document 2] Japanese Unexamined Patent Application Publication No. 06-272935

However, the conventional air conditioner control system described above has a problem in terms of energy efficiency because it selects a facility having a maximum capacity with a margin more than the required design capability. For example, if the capacity of the flow control valve is allowed to remain, when the opening degree of the flow control valve is controlled, a maximum flow rate more than the design flow rate flows at full opening, resulting in a problem that energy is wasted. In the related art, there is no means for quantitatively knowing such waste of energy, and it is impossible to determine whether there is a problem in terms of energy efficiency, and thus, countermeasures for energy saving have been hindered.

The present invention has been made to solve such a problem, and an object thereof is to provide a flow control system capable of quantitatively determining whether there is a problem in terms of energy efficiency or actively coping with energy saving. It is in doing it.

In order to achieve the above object, the present invention provides a valve body for controlling an opening and closing amount of a flow path through which a fluid flows, and an operating design flow rate determined as a value smaller than the flow rate of the fluid flowing through the flow path when the opening degree of the valve body is maximum. The design flow rate storage means to store, the flow rate measurement means which measures the flow rate of the fluid which flows through the flow path, and the flow rate measured by this flow rate measurement means and the design flow rate stored in the design flow rate storage means, A period in which the actual flow rate exceeds the design flow rate is an excess period of the actual flow rate, and an excess flow rate integration means for integrating an excess of the actual flow rate from the design flow rate for each of the excess periods is provided.

According to the present invention, the actual flow rate of the fluid flowing through the conduit is measured, and an excess of the actual flow rate from the design flow rate for each excess period in which the actual flow rate of the fluid flowing through this flow path exceeds the design flow rate is accumulated. In the present invention, by referring to the integrated value of the excess flow rate, it is possible to quantitatively know how much the system is operating as designed, how far away from the design, and so on. In addition, by analyzing the integrated value of the excess flow rate, it is possible to verify how much energy the system wastes, whether or not an abnormality has occurred.

In the present invention, whenever the actual flow rate exceeds the design flow rate, the excess portion of the actual flow rate from the design flow rate while the actual flow rate exceeds the design flow rate is accumulated as a continuous excess flow rate, and the integrated value of the continuous excess flow rate is determined in advance. When the alarm is output when the threshold value is exceeded, the occurrence of an abnormal state of the excess flow rate can be immediately confirmed, and the countermeasure can be taken promptly. In this case, when the alarm is output, the opening degree of the valve body is forcibly changed to the closing direction, and the flow rate of the fluid flowing through the flow path is reduced (for example, the design flow rate is reduced). Energy saving can be achieved.

The flow rate control system of the present invention may be a system for controlling the flow rate of a fluid using a valve body, and is not limited to being applied to an air conditioner control system for controlling the flow rate of a heat medium supplied to an air conditioner. By applying the present invention to an air conditioning control system, it is possible to notify that waste of energy and abnormal excess flow rate occur in the operation of the air conditioning control system, or to prevent abnormal excess flow rate, thereby preserving the air conditioning control system. It helps.

In addition, when applied to an air conditioning control system, the design flow rate for cold water and the design flow rate for hot water are memorize | stored in the design flow rate storage means, and when cooling using an air conditioner, the design flow rate for cold water is selected as a design flow rate, In the case of heating using an air conditioner, a design flow rate for hot water may be selected and used as the design flow rate. In the case of cooling and heating, the design flow rate may be different, and the design flow rate can be prepared by selecting two types of design flow rates for cold water and design water for hot water so that the excess flow can be appropriately monitored during cooling and heating. Alarms and responses are possible.

According to the present invention, since the actual flow rate of the fluid flowing through the conduit is measured, the excess flow rate from the design flow rate for each excess period in which the flow rate of the fluid flowing through this flow path exceeds the design flow rate is accumulated. By referring to the integrated value of, it is possible to quantitatively know how much the system is operating as designed, how far away from the design, and so on. In addition, by analyzing the integrated value of the excess flow rate, it becomes possible to verify how much energy the system is wasting, whether or not an abnormality is occurring, and the like.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail based on drawing. 1 is an instrumentation diagram showing an example of an air conditioning control system to which a flow rate control system according to the present invention is applied.

In FIG. 1, 1 is a heat source group for generating cold and hot water, 2 is a pump for conveying cold and hot water generated by the heat source group 1, and 3 is a water supply for mixing cold and hot water from the plurality of heat source groups 1. Header, 4 is a water supply line, 5 is an air conditioner receiving cold and hot water from the water supply header 3 through the water supply line 4, 6 is a return line, and 7 is a heat exchanger in the air conditioner 5 Return flow header returning the hot and cold water sent through (6), 8 is a flow control valve for controlling the flow rate of the hot and cold water returned from the air conditioner (5) to the return header (7), 9 is from the air conditioner (5) The air supply temperature sensor which measures the temperature of the air supply air sent, 10 is an air conditioning control device, 11 is a coil of the air conditioner 5, 12 is a blower.

In this air conditioning control system, the cold and hot water pumped from the pump 2 and added to the heat amount by the heat source 1 are mixed in the water supply header 3, and the air conditioner 5 is supplied through the water supply line 4. ), Passes through the air conditioner (5), reaches the return header (7) as return by the return line (6), and is again pushed by the pump (2) to circulate the above path. For example, in the cooling operation, the cold water is generated in the heat source 1, and the cold water circulates. In the heating operation, hot water is generated in the heat source 1, and the hot water circulates.

The air conditioner 5 cools or heats the mixture of air (ventilation) and outside air returned from the control target region to the air conditioning control system by the coil 11 through which hot and cold water passes, and thus, Cooled or heated air is sent as the air supply through the blower 12 to the controlled area. The air conditioner 5 is a single type air conditioner using the common coil 11 in a cooling operation and a heating operation.

FIG. 2 is a diagram showing an essential part of the flow control valve 8 in the air conditioning control system. The flow rate control valve 8 adjusts the conduit 13 which forms a flow path through which the hot and cold water which has passed through the air conditioner 5 flows, and the flow rate (opening and closing amount of the flow path) of the fluid which flows through this conduit 13. The valve body 14, the motor 15 driving the valve body 14, the valve opening degree detector 16 for detecting the actual opening degree of the valve body 14 as the valve opening degree θpv, Communication interface 18, 19 which mediates communication between the display part 17, the air conditioning control apparatus 10, and a monitoring apparatus (not shown), the design flow volume storage part 20, and the excess flow integrated value Primary pressure sensor 23 for detecting the fluid pressure upstream of the valve body 14 in the storage unit 21, the abnormality threshold storage unit 22, and the conduit 13 as the primary pressure P1. ), A secondary side pressure sensor 24 for detecting the fluid pressure downstream of the valve body 14 in the pipeline 13 as the secondary pressure P2, and a processing unit 25.

The processing unit 25 includes the valve control unit 25A, the actual flow rate measurement unit 25B, the design flow rate excess notification unit 25C, the excess flow rate integration unit 25D, the continuous excess flow rate integration unit 25E, The continuous excess flow integrated value abnormality warning part 25F and the design flow rate reading part 25G are provided. The valve control unit 25A, the actual flow rate measuring unit 25B, the design flow rate exceeding notification unit 25C, the excess flow rate accumulating unit 25D, the continuous excess flow rate accumulating unit 25E, and the continuous excess flow rate in the processing unit 25. The integrated value abnormality warning section 25F and the design flow rate reading section 25G are realized as processing functions of the CPU according to the program.

In this embodiment, the design flow rate storage unit 20 stores the design flow rate QDC for cold water and the design flow rate QDH for hot water as operational design flow rates. The design flow rate QDC for cold water and the design flow rate QDH for hot water are determined as values smaller than the flow rate of the fluid which flows through the conduit 13 when the valve body 14 has the maximum opening degree. The design flow rate QDC for cold water and the design flow rate QDH for hot water are basically determined as different values, but in some cases, the same value may be taken. The abnormality threshold value storage section 22 also stores, as an abnormality threshold Cth, a threshold value for determining whether or not it is abnormal with respect to the integrated value ΣΔQC of the continuous excess flow rate described later.

Hereinafter, the characteristic processing operation | movement in this flow control valve 8 is demonstrated, based on the function of each part in the process part 25. FIG. In this example, it is assumed that a cooling signal is being performed, and a mode signal for notifying the flow rate control valve 8 of performing cooling operation from the air conditioning control device 10 is provided. In addition, a control set command value esp (command value of valve opening degree (0 to 100%)) is provided from the air conditioning controller 10 to the flow rate control valve 8 so as to maintain the temperature of the control target region at the set temperature. We shall become.

In the flow rate control valve 8, the mode signal for notifying cooling from the air conditioning control device 10 is sent to the design flow rate reading unit 25G through the communication interface 18. The design flow rate reading part 25G receives the mode signal informing of the cooling from the air conditioning control device 10, reads the design flow rate QDC for cold water stored in the design flow rate storage part 20, and design The flow rate QD is provided to the design flow rate excess notification part 25C, the excess flow rate integration part 25D, and the continuous excess flow rate integration part 25E.

In the flow rate control valve 8, the control setting command value esp from the air conditioning control device 10 is provided to the valve control unit 25A via the communication interface 18. The valve control unit 25A receives the control setting command value θsp from the air conditioning control device 10, and the valve opening degree epv from the valve opening degree detector 16 indicating the actual opening degree of the valve body 14. The drive command is sent to the motor 15 to control the opening degree of the valve body 14 so that the control coincides with the control set command value esp.

During the control of the opening degree of the valve body 14, the actual flow rate measurement unit 25B is provided with the primary pressure P1 of the fluid (cold water) from the primary pressure sensor 23 and the secondary pressure sensor 24. The secondary pressure P2 of the fluid from the valve and the valve opening degree (epv) from the valve opening degree detector 16 are input, and the actual flow rate QR of the fluid flowing through the conduit 13 is determined from these parameters. It calculates as a measured value of actual flow volume, and provides this calculated actual flow volume QR to the design flow exceeding notification part 25C, the excess flow totalizing part 25D, and continuous excess flow totalizing part 25E.

The design flow rate exceeding notification unit 25C compares the actual flow rate QR from the actual flow rate measurement unit 25B with the design flow rate QD (design flow rate QDC for cold water) from the design flow rate reading unit 25G. When the actual flow rate QR exceeds the design flow rate QD, while the actual flow rate QR exceeds the design flow rate QD, the design flow rate is exceeded by the excess flow rate integration part 25D and the continuous excess flow rate integration part 25E. Send an excess notification signal.

When the excess flow rate integrating unit 25D receives a design flow rate exceeding notification signal from the design flow rate exceeding notification unit 25C, the excess flow rate accumulating unit 25D receives the actual flow rate QR from the actual flow rate measuring unit 25B and the design flow rate reading unit 25G. The difference from the design flow rate QD (excess portion of the actual flow rate QR from the design flow rate QD) is obtained as the excess flow rate ΔQ, and the excess flow rate ΔQ is accumulated. The excess flow rate integration part 25D performs integration of the excess flow rate ΔQ for the entire period during which the design flow rate excess notification signal is generated.

Accordingly, as shown in FIG. 3, the period in which the actual flow rate QR exceeds the design flow rate QD is defined as the excess period T of the actual flow rate, and the design flow rate QD for each excess period T is obtained. The excess part of the actual flow amount QR from this is integrated, and the integrated value of the excess part (ΔQ) of the actual flow rate QR from the design flow volume QD for every this excess period T is the integrated value (ΣΔQ) of the excess flow rate. Is saved. The integrated value ΣΔQ of the excess flow rate at each time determined by the excess flow rate integration section 25D is stored in the excess flow rate integration value storage section 21. In addition, the integrated value ΣΔQ of the excess flow rate stored in the excess flow rate integrated value storage unit 21 is displayed on the display unit 17 and output to the air conditioner control device 10 or the monitoring device through the communication interface 19. do.

When the continuous excess flow rate integrating unit 25E receives a design flow rate exceeding notification signal from the design flow rate exceeding unit 25C, the continuous excess flow rate accumulating unit 25E receives the actual flow rate QR from the actual flow rate measuring unit 25B and the design flow rate reading unit 25G. The difference from the design flow rate QD (the excess of the actual flow rate QR from the design flow rate QD) is obtained as the excess flow rate ΔQC, and the excess flow rate ΔQC is integrated. The continuous excess flow rate integrating unit 25E performs integration of the excess flow rate ΔQC for each period during which the design flow rate excess notification signal is generated.

As a result, as shown in FIG. 4, the period in which the actual flow rate QR exceeds the design flow rate QD is defined as the excess period T of the actual flow rate, and from each of the excess periods T, from the design flow rate QD. The integrated value of the excess portion ΔQC of the actual flow rate QR is calculated as the integrated value ΣΔQC of the continuous excess flow rate. In this case, each time the new excess period T is entered, the integrated value ΣΔQC of the continuous excess flow rate up to that time is returned to zero, and integration from zero of the continuous excess flow rate is started. The integrated value ΣΔQC of the continuous excess flow rate determined by the continuous excess flow rate integration section 25E is sent to the continuous excess flow rate integration value abnormality alarm section 25F.

The continuous excess flow integrated value abnormality alarm unit 25F monitors the integrated value (ΣΔQC) of the continuous excess flow rate from the continuous excess flow integrated unit 25E, and the integrated value of the continuous excess flow rate (ΣΔQC) is an abnormality threshold storage unit. If the abnormality threshold Cth stored in (22) is exceeded, an alarm is output. The alarm from this continuous excess flow integrated value abnormality alarm part 25F is provided to the display part 17 and the valve control part 25A, and is output to the air conditioning control apparatus 10 or the monitoring apparatus via the communication interface 19. As shown in FIG.

In this case, occurrence of an abnormal state of the excess flow rate is displayed on the display unit 17. In addition, the valve control unit 25A receives the alarm from the continuous excess flow rate integrated value abnormality alarm unit 25F, and design flow rate in the actual flow rate QR in the actual flow rate measurement unit 25B and the design flow rate reading unit 25G. (QD) is acquired and the opening degree of the valve body 14 is forcibly changed to the closing direction so that the actual flow rate QR becomes the design flow rate QD. When the integrated value ΣΔQC of the continuous excess flow rate falls below the abnormality threshold Cth, the output of the alarm from the continuous excess flow rate integrated value abnormality alarm unit 25F is released. In this case, the control by the valve control unit 25A returns to the opening degree control according to the control set command value esp from the air conditioning control device 10.

As can be seen from the above description, according to the present embodiment, the actual flow rate QR of the fluid flowing through the conduit 13 is measured, and the actual flow rate QR of the fluid flowing through the conduit 13 is a design flow rate ( The excess part (ΔQ) of the actual flow rate (QR) from the design flow rate (QD) for each excess period (T) over QD) is integrated, and the integrated value (ΣΔQ) of the excess flow rate is displayed on the display unit 17, or Since the air conditioning control device 10 and the monitoring device are sent to the air conditioner, the integrated value of the excess flow rate (ΣΔQ) is used to quantitatively determine how much the system is operating according to the design, how far from the design, and so on. You will know. In addition, by analyzing the integrated value ΣΔQ of the excess flow rate, it is possible to verify how much the system is wasting energy, whether or not an abnormality is occurring, and the like.

Further, according to the present embodiment, whenever the actual flow rate QR exceeds the design flow rate QD, the actual flow rate from the design flow rate QD while the actual flow rate QR exceeds the design flow rate QD ( The excess amount ΔQC of QR) is integrated as a continuous excess flow rate, and an alarm is output when the integrated value ΣΔQC of the continuous excess flow rate exceeds the abnormality threshold Cth, and the indication is displayed on the display unit 17, or Since the air conditioner 10 and the monitoring device are sent to the air conditioner, the occurrence of an abnormal state of the excess flow rate can be immediately confirmed, and the countermeasure can be promptly taken.

In addition, according to the present embodiment, an alarm is output when the integrated value ΣΔQC of the continuous excess flow rate exceeds the abnormality threshold Cth, and the opening degree of the valve body 14 is forcibly changed to the closing direction, thereby providing a pipeline. Since the flow rate of the fluid flowing through (13) is reduced to the design flow rate QD, an abnormal state can be escaped and energy saving can be attained.

In addition, in the above description, on the premise that the mode signal which informs cooling of the flow control valve 8 from the air conditioning control device 10 is provided, the flow control valve 8 is provided from the air conditioning control device 10. The same processing operation is performed even when a mode signal for informing heating is provided. In this case, the design flow rate reading unit 25G reads the design flow rate QDH for hot water stored in the design flow rate storage unit 20, and exceeds the design flow rate exceeding notification unit 25C as the design flow rate QD. The flow rate integration unit 25D and the continuous excess flow rate integration unit 25E are provided.

In addition, in the above-mentioned embodiment, although the mode signal which informs cooling / heating is provided to the flow control valve 8 from the air conditioning control apparatus 10, the temperature of the fluid in the conduit 13 is detected, The flow rate control valve 8 may determine cooling / heating.

In addition, in embodiment mentioned above, when the integrated value ((DELTA) (DELTA) QC) of continuous excess flow volume exceeds the abnormality threshold (Cth), the opening degree of the valve body 14 is forcibly changed to the closing direction, and the pipeline 13 flows. Although the flow rate of the fluid is reduced to the design flow rate QD, the flow rate of the fluid may not necessarily be reduced to the design flow rate QD. For example, the opening degree of the valve body 14 may be closed only by a predetermined opening degree.

In addition, in the above-mentioned embodiment, although the valve control part 25A was made to control the opening degree of the valve body 14, flow control is based on the actual flow amount QR measured by the actual flow amount measuring part 25B. It may be performed. In this case, the control set command value θsp is not sent to the valve opening degree command value but is sent from the air conditioner control device 10 at the flow rate command value (0 to 100%) so as to match the control set command value θsp. Although flow control is performed, even in this case, the excess of the actual flow amount QR from the design flow rate QD is integrated, and the same effect can be obtained.

1 is an instrumentation diagram showing an example of an air conditioning control system to which a flow control system according to the present invention is applied.

The figure which shows the principal part of the flow control valve used in this air conditioning control system.

FIG. 3 is a view for explaining a form in which an excess flow rate is accumulated in an excess flow rate integration part of the flow control valve. FIG.

4 is a view for explaining a form in which the continuous excess flow rate is accumulated in the continuous excess flow rate integration part of the flow control valve.

<Explanation of symbols for the main parts of the drawings>

1: heat source 2: pump

3: water supply header 4: water supply line

5: air conditioner 6: return pipe

7: return header 8: flow control valve

9: air supply temperature sensor 10: air conditioning controller

11: coil 12: blower

13: pipeline 14: valve body

15: Motor 16: Valve Opening Detector

17: display unit 18, 19: communication interface

20: designed flow rate storage 21: excess flow accumulated value storage

22: abnormal threshold memory 23: primary pressure sensor

24: secondary pressure sensor 25: processing unit

25A: valve control section 25B: actual flow measurement section

25C: Design Flow Excess Notification Unit 25D: Excess Flow Integrator

25E: Continuous excess flow integrator

25F: Continuous excess flow accumulated value abnormality alarm part

25G: Design Flow Reading

Claims (5)

A valve body for adjusting the opening and closing amount of the flow path through which the fluid flows, Design flow rate storage means for storing an operational design flow rate determined as a value smaller than the flow rate of the fluid flowing through the flow path when the valve body has an opening degree maximum; Real flow rate measuring means for measuring a real flow rate of the fluid flowing through the flow path; The actual flow rate measured by the actual flow rate measurement means is compared with the design flow rate stored in the design flow rate storage means, and the period in which the actual flow rate exceeds the design flow rate is defined as the excess period of the actual flow rate, Excess flow rate integrating means for accumulating an excess of the actual flow rate from the design flow rate; Whenever the actual flow rate measured by the actual flow rate measuring means exceeds the design flow rate stored in the design flow rate storage means, the excess of the actual flow rate from the design flow rate while the actual flow rate exceeds the design flow rate is continuously exceeded. Continuous excess flow rate integration means for integrating as Alarm output means for outputting an alarm when the integrated value of the continuous excess flow rate exceeds a predetermined threshold value; A means for reducing the flow rate of the fluid flowing through the flow path by forcibly changing the opening degree of the valve body in the closing direction in response to the alarm output from the alarm output means; Flow control system comprising a. delete delete The method of claim 1, The valve body is installed in a conduit between the air conditioner and the heat source. 5. The method of claim 4, The design flow rate storage means, A flow rate control system for storing the design flow rate for cold water selected as the design flow rate at the time of cooling using the air conditioner and the design flow rate for hot water selected as the design flow rate at the time of heating using the air conditioner. .

Images