JP7452050B2 - piping system - Google Patents

Description

The present invention relates to piping systems in which dead legs are formed.

Factories that produce pharmaceuticals, precision mechanical parts, electronic parts, etc. are equipped with piping systems that supply water to use points installed at various locations. The piping system includes a main pipe through which water supplied by a supply source flows and branch pipes branching from the main pipe. An example of a branch pipe is a pipe that is provided with an on-off valve as a closing mechanism at its tip and carries water to a point of use. Another example of a branch pipe is a pipe that is equipped with a meter at its tip as a closure mechanism. In such branch pipes, when water is in a stagnant state, dead legs are formed where there is a concern that water quality may deteriorate due to the stagnation of the water. In order to suppress the deterioration of water quality due to such dead legs, Non-Patent Document 1 states that the dead leg length, which indicates the distance from the center of the main pipe to the closing mechanism at the tip of the branch pipe, is set at 60% of the inner diameter of the branch pipe, as a guideline by the Japanese Ministry of Health, Labor and Welfare. It is stated that the amount should be increased within twice as much, and if possible, within 3 times.

Comparison of GMP structural and equipment requirements Manufacturing water equipment 001: Dead leg definition and setting, [online], General Incorporated Association Pharmaceutical Machinery Technology Society homepage, [searched on January 31, 2020] Internet, <URL: https://www ．． seikiken. or. jp/gmp/gmp_hikaku/hikaku_test. html#yousui001>

In the piping system described above, the larger the amount of water used at the use point located on the upstream side, the more likely the water will accumulate at the dead leg located on the downstream side of the main pipe.

An object of the present invention is to provide a piping system in which retention of water can be suppressed.

A piping system that solves the above problems is a piping system that includes a main pipe through which water supplied from a supply source flows, and the main pipe has an upstream pipe in which a first use point is provided and an upstream pipe in which a second use point is provided. said downstream piping has a flow path cross-sectional area smaller than said upstream piping, and is connected downstream of said first use point in said main pipe to said second use point. The apparatus further includes an adjusting section that has a bypass pipe that bypasses the point, and adjusts the flow rate of the downstream piping based on the flow rate of the bypass pipe.

In the piping system configured as described above, it is preferable that the adjustment section includes a flow rate adjustment valve in at least one of the downstream piping and the bypass pipe.
In the piping system configured as described above, it is preferable that the adjustment unit has a measuring device regarding the flow velocity in the downstream piping, and controls the flow rate adjustment valve based on the measurement result of the measuring device.

In the piping system configured as described above, it is preferable that the measuring device is disposed downstream of the second point of use in the downstream piping.
The piping system configured as described above further includes a reflux pipe that is connected to the downstream piping and returns the water that has passed through the downstream piping to the supply source, and the adjustment unit is configured such that the bypass pipe is connected to the downstream piping. It is preferable to adjust the flow rate of the downstream piping while maintaining the state in which the water flows through the bypass pipe.

According to the present invention, retention of water in the piping system is suppressed.

FIG. 1 is a diagram schematically showing an embodiment of a piping system. FIG. 2 is a functional block diagram showing an example of a schematic configuration of an adjustment section. 5 is a flowchart illustrating an example of flow rate adjustment processing. The figure which shows typically an example of schematic structure of an adjustment part in a modification.

An embodiment of a piping system will be described with reference to FIGS. 1 to 3.
As shown in FIG. 1, the piping system 10 includes a source 11 for supplying clean water. The supply source 11 includes a tank 12 that stores clean water, and a pump 13 that supplies the water in the tank 12 to the main pipe 15. The pump 13 supplies water at a preset flow rate to the main pipe 15. Note that each pipe constituting the piping system 10 is constructed of a stainless steel pipe, for example, a stainless steel pipe for piping specified in JIS.

The main pipe 15 is configured to be able to circulate water using the supply source 11 as a reference. The piping system 10 includes a supply amount adjustment pipe 16 that connects a downstream portion of the pump 13 in the main pipe 15 and the tank 12 . A first supply amount adjustment valve 17 is disposed in the supply amount adjustment pipe 16 . Further, the piping system 10 includes a second supply amount adjustment valve 18 and a supply amount measuring device 19 on the downstream side of the connecting portion of the supply amount adjustment pipe 16 in the main pipe 15 . By adjusting the first supply amount adjustment valve 17 and the second supply amount adjustment valve 18, the flow rate of water flowing into the main pipe 15 is adjusted. The piping system 10 adjusts the amount of water supplied to the main pipe 15 by adjusting the opening degrees of the first supply amount adjustment valve 17 and the second supply amount adjustment valve 18 based on the measured value of the supply amount measuring device 19. Q is configured to be adjustable with high accuracy. Note that the supply amount Q of water to the main pipe 15 does not include the water returned to the tank 12 through the supply amount adjustment pipe 16.

The main pipe 15 has an upstream pipe 21, a downstream pipe 22, a reflux pipe 23, and a drain pipe 24.
The upstream pipe 21 is connected to the pump 13. The upstream piping 21 is provided with one or more first use points 25 downstream of the second supply amount regulating valve 18 and the supply amount measuring device 19. A part of the first use point 25 is composed of a first branch pipe 26 branching from the main pipe 15 and a first on-off valve 27 which is a closing mechanism provided at the tip of the first branch pipe 26. Further, a first instrument branch pipe 28 for measuring the properties of the water flowing through the main pipe 15 in the upstream pipe 21 is connected to the upstream pipe 21 . A first meter 29 is provided as a closing mechanism.

The amount of water supplied to the main pipe 15 Q and the upstream cross-sectional area S1, which is the flow path cross-sectional area of the upstream pipe 21, are calculated based on the amount of water used at each time based on the purpose of water at each use point, for example. The settings are set as follows based on usage prediction information predicted for each point. In the following, the upstream cross-sectional area S1 is a value based on the size of a stainless steel pipe for piping specified in JIS, that is, a value based on the nominal diameter and nominal thickness.

The supply amount Q and the upstream cross-sectional area S1 are set on the assumption that the main pipe 15 is composed of only the upstream pipe 21. The supply amount Q and the upstream cross-sectional area S1 are set so that the maximum flow velocity v11 (=Q/S1), which is the value obtained by dividing the supply amount Q by the upstream cross-sectional area S1, is smaller than the upper limit of the appropriate flow velocity range. Ru. In addition, the supply amount Q and the upstream cross-sectional area S1 are the values obtained by dividing the minimum flow rate Qmin, which is obtained by subtracting the supply amount Q by the maximum usage amount of the entire piping system 10 based on usage prediction information, by the upstream cross-sectional area S1. The minimum flow velocity v12 (=Qmin/S1) is set to be larger than the lower limit of the appropriate flow velocity range. In addition, in stainless steel pipes for piping, the lower limit of the appropriate flow velocity range is 0.3 m/s, preferably 0.5 m/s, and the upper limit of the appropriate flow velocity range is 2.0 m/s, preferably 1.0 m/s. It is 5m/s.

The downstream pipe 22 is connected to the downstream end of the upstream pipe 21 at the branch point 30 via a joint (not shown). The downstream piping 22 has a smaller flow path cross-sectional area than the upstream piping 21. The downstream piping 22 is provided with one or more second use points 31. A part of the second point of use 31 is composed of a second branch pipe 32 branching from the main pipe 15 and a second on-off valve 33 which is a closing mechanism provided at the tip of the second branch pipe 32. Further, a second instrument branch pipe 34 for measuring the properties of the water flowing through the main pipe 15 in the downstream pipe 22 is connected to the downstream pipe 22, and the tip of the second instrument branch pipe 34 is connected to the downstream pipe 22. A second gauge 35 is provided as a closing mechanism.

The downstream cross-sectional area S2, which is the flow path cross-sectional area of the downstream pipe 22, is set so that the sum of the bypass cross-sectional area S3, which is the cross-sectional area of the bypass pipe 41, which will be described later, is close to the upstream cross-sectional area S1. be done. Like the upstream cross-sectional area S1, the downstream cross-sectional area S2 is a value based on the size of the stainless steel pipe for piping defined in JIS, that is, the value based on the nominal diameter and nominal thickness.

In this embodiment, the main pipe 15 is divided into an upstream pipe 21 and a downstream pipe 22 based on the flow rate downstream of each use point.
Specifically, based on the supply amount Q and usage prediction information, the downstream flow rate of each use point in the main pipe 15 is calculated for each time, and the average flow rate of each use point is calculated. Then, the piping to which the use point located upstream of the use point whose average flow rate is less than 1/2 of the supply amount Q is connected is set as the upstream piping 21, and the piping to which the other use points are connected is set as the upstream piping 21. It is set as the downstream piping 22. That is, a portion of the main pipe 15 where the flow rate tends to be slow is set in the downstream pipe 22.

The reflux pipe 23 is a pipe connected to the downstream end of the downstream pipe 22 and the tank 12 . A circulation valve 36 that can open and close the reflux pipe 23 is disposed in the reflux pipe 23 . The piping system 10 is configured to allow water that has passed through the downstream piping 22 and a bypass pipe 41 (described later) to be returned to the tank 12 when the circulation valve 36 is in an open state.

The drain pipe 24 is a pipe that branches from the reflux pipe 23 and has an open downstream end. The drain pipe 24 is provided with a drain valve 37 that can open and close the drain pipe 24 . The piping system 10 is configured to be able to drain water flowing through the main pipe 15 to the outside when the drain valve 37 is in the open state.

The piping system 10 includes an adjustment unit 40 that adjusts the flow rate of water in the downstream pipe 22, that is, the flow rate of water in the downstream pipe 22. The adjustment section 40 includes a bypass pipe 41 , a downstream flow rate adjustment valve 42 , a bypass flow rate adjustment valve 43 , a downstream flow rate meter 44 , a bypass flow rate meter 45 , and a control device 50 .

The bypass pipe 41 is a pipe that branches from the downstream side of the first point of use 25 in the main pipe 15 and bypasses the second point of use 31 . The bypass pipe 41 has a flow passage cross-sectional area smaller than that of the upstream pipe 21. The bypass pipe 41 is connected to the downstream end of the upstream pipe 21 at the branch point 30 via a joint (not shown), and is connected to the downstream end of the downstream pipe 22 at the confluence point 38 via a joint (not shown). ing. The bypass cross-sectional area S3, which is the flow path cross-sectional area of the bypass pipe 41, is set so that the total value with the downstream cross-sectional area S2 becomes a value close to the upstream cross-sectional area S1, as described above. The bypass cross-sectional area S3, like the upstream cross-sectional area S1, is a value based on the size of a stainless steel pipe for piping defined in JIS, that is, a value based on the nominal diameter and nominal thickness.

The downstream flow rate adjustment valve 42 is an automatic valve disposed upstream of each second use point 31 in the downstream piping 22. The downstream flow regulating valve 42 reduces the amount of water flowing into the downstream pipe 22 and increases the amount of water flowing into the bypass pipe 41 by displacing the valve body in the closing direction. Further, the downstream flow rate regulating valve 42 increases the amount of water flowing into the downstream pipe 22 and reduces the amount of water flowing into the bypass pipe 41 by displacing the valve body in the opening direction.

The bypass flow rate adjustment valve 43 is an automatic valve disposed in the bypass pipe 41. The bypass flow rate adjustment valve 43 increases the amount of water flowing into the downstream pipe 22 and reduces the amount of water flowing into the bypass pipe 41 by displacing the valve body in the closing direction. Moreover, the bypass flow rate adjustment valve 43 reduces the amount of water flowing into the downstream pipe 22 and increases the amount of water flowing into the bypass pipe 41 by displacing the valve body in the opening direction.

The downstream flow meter 44 is disposed downstream of all the second use points 31 in the downstream pipe 22, and measures the amount of water flowing out from the downstream pipe 22 as the downstream flow rate Q2. The downstream flow meter 44 outputs a signal indicating the measured downstream flow rate Q2 to the control device 50. Note that the downstream flow velocity v2 (=Q2/S2) based on the downstream flow rate Q2 and the downstream cross-sectional area S2 is the lowest flow velocity in the downstream piping 22.

The bypass flow rate measuring device 45 is disposed on the downstream side of the bypass flow rate adjustment valve 43 in the bypass pipe 41, and measures the bypass flow rate Q3, which is the amount of water flowing into the bypass pipe 41. The bypass flow rate measuring device 45 outputs a signal indicating the measured bypass flow rate Q3 to the control device 50.

The control device 50 acquires various types of information, and executes various processes based on the acquired various types of information, as well as programs and various types of data stored in the memory. The control device 50 may be configured as a circuit including one or more dedicated hardware circuits such as an ASIC, one or more processors operating according to a computer program (software), or a combination thereof. A processor includes a CPU and memory, such as RAM and ROM, where the memory stores program codes or instructions configured to cause the CPU to perform processing. Memory or computer-readable media includes any available media that can be accessed by a general purpose or special purpose computer.

The control device 50 acquires the downstream flow rate Q2 outputted by the downstream flow rate meter 44 and the bypass flow rate Q3 outputted by the bypass flow rate meter 45. Then, the control device 50 controls the opening degree of the downstream flow rate adjustment valve 42 and the bypass flow rate adjustment valve 43 based on the acquired downstream flow rate Q2 and bypass flow rate Q3, and performs an adjustment process to adjust the flow velocity. I do.

As shown in FIG. 2, the control device 50 includes a flow rate acquisition section 51, a flow velocity calculation section 52, a valve control section 53, and a storage section 54.
The flow rate acquisition unit 51 acquires the downstream flow rate Q2 and the bypass flow rate Q3.

The flow velocity calculating section 52 calculates the downstream flow velocity v2 based on the downstream flow rate Q2, and calculates the bypass flow velocity v3 based on the bypass flow rate Q3.
The valve control unit 53 controls the opening degree of the downstream flow rate adjustment valve 42 and the bypass flow rate adjustment valve 43 based on the downstream flow rate v2 and the bypass flow rate v3.

The storage unit 54 stores the supply amount Q of water to the main pipe 15, the downstream cross-sectional area S2 and the bypass cross-sectional area S3 used for calculation by the flow rate calculation unit 52, and threshold values necessary for controlling the opening of each flow rate regulating valve 42, 43. etc. are memorized.

As shown in FIG. 3, in the adjustment process, the control device 50 performs a flow rate acquisition process (step S101). Here, the flow rate acquisition unit 51 acquires the downstream flow rate Q2 based on the signal from the downstream flow rate meter 44, and acquires the bypass flow rate Q3 based on the signal from the bypass flow rate meter 45.

Next, the control device 50 performs flow velocity calculation processing (step S102). Here, the flow velocity calculation unit 52 calculates the downstream flow velocity v2 (=Q2/S2) based on the downstream flow rate Q2 acquired by the flow rate acquisition unit 51 and the downstream cross-sectional area S2 stored in the storage unit 54. calculate. Further, the flow velocity calculation unit 52 calculates the bypass flow velocity v3 (=Q3/S3 ) is calculated.

Next, the control device 50 performs opening degree control processing (step S103). Here, the valve control unit 53 adjusts the opening degree of the downstream flow rate adjustment valve 42 so that the downstream flow velocity v2 calculated by the flow velocity calculation unit 52 is larger than the lower limit flow velocity vmin and smaller than the upper limit flow velocity vmax. The opening degree of the bypass flow rate adjustment valve 43 is controlled. The lower limit flow rate vmin and the upper limit flow rate vmax are threshold values necessary for controlling each flow rate regulating valve 42, 43. In this embodiment, the downstream flow velocity v2 is the flow velocity of water flowing out from the downstream piping 22, that is, the lowest flow velocity of the water in the downstream piping 22. Therefore, the lower limit flow velocity vmin is set to a value larger than the lower limit value of the appropriate flow velocity range. The upper limit flow rate vmax is smaller than the upper limit of the appropriate flow rate range, taking into account the use of water at the second use point 31 and the fact that the flow rate of the water flowing into the downstream piping 22 does not exceed the appropriate flow rate range. set to the value. Further, the valve control unit 53 controls the opening degree of the downstream flow rate regulating valve 42 and the bypass flow rate so that the bypass flow velocity v3 calculated by the flow velocity calculation unit 52 is larger than the lower limit flow velocity vmin and smaller than the upper limit flow velocity vmax. The opening degree of the regulating valve 43 is controlled. Note that the valve control unit 53 preferably controls the opening degree of the downstream flow rate adjustment valve 42 and the opening degree of the bypass flow rate adjustment valve 43 so that the downstream flow rate v2 approaches the upper limit flow rate vmax.

In the piping system 10, dead legs are formed in the branch pipes 26, 32 constituting the use points 25, 31 where the on-off valves 27, 33 are provided, where there is a concern that water quality may deteriorate due to accumulation of water. As a result of conducting various experiments regarding dead legs, the present inventors have found that the higher the flow velocity at the connecting portion of the branch pipe in the main pipe 15, the less likely it is for water to accumulate in that branch pipe, that is, the lower the water quality caused by the dead leg. I found out that it can be suppressed.

In the piping system 10 described above, the downstream side of the main pipe 15, which is a portion where the flow velocity tends to be low, is configured with the downstream pipe 22 having a smaller cross-sectional area than the upstream pipe 21. Further, the piping system 10 is configured such that the downstream flow velocity v2 of the downstream piping 22 is maintained at a state higher than the lower limit flow velocity vmin and lower than the upper limit flow velocity vmax by the adjustment unit 40. This prevents the flow rate of water in the downstream pipe 22 from becoming small.

The effects of this embodiment will be explained.
(1) According to the configuration of the piping system 10, even if the amount of water flowing into the downstream pipe 22 decreases due to the use of water at the first use point 25, it is possible to suppress the accumulation of water on the downstream side of the main pipe 15. can.

(2) Through various experiments, the present inventors have found that the higher the flow velocity at the connecting portion of the branch pipe in the main pipe 15, the larger the allowable value of the dead leg length can be set. Furthermore, in the piping system 10, the flow velocity in the downstream piping 22 can be set to a higher flow velocity. For these reasons, in the piping system 10, the allowable value of the dead leg length at the second point of use 31 can be increased. As a result, it becomes possible to configure the second branch pipe 32 with a pipe having a smaller inner diameter, and an increase in the cost of the piping system 10 can be suppressed.

(3) The adjustment section 40 has a bypass flow rate adjustment valve 43 disposed in the bypass pipe 41. Thereby, the downstream flow rate Q2, that is, the downstream flow velocity v2, can be adjusted by adjusting the bypass flow rate Q3.

(4) The adjustment unit 40 has a downstream flow rate adjustment valve 42 disposed in the downstream piping 22. Thereby, the downstream flow rate Q2 of the downstream piping 22 can be directly adjusted.
(5) The adjustment unit 40 adjusts the flow rate by controlling the opening degrees of both the downstream flow rate adjustment valve 42 and the bypass flow rate adjustment valve 43. Therefore, the downstream flow rate Q2 and the bypass flow rate Q3 can be controlled with high responsiveness.

(6) The adjustment unit 40 adjusts the downstream flow rate Q2 and the bypass flow rate Q3 based on the measurement results of the downstream flow rate meter 44 and the bypass flow rate meter 45. Thereby, the downstream flow rate Q2 and the bypass flow rate Q3 can be adjusted with high accuracy.

(7) The downstream flow rate measuring device 44 measures the flow rate in the downstream side of the second use point 31 in the downstream piping 22, that is, in the portion of the downstream piping 22 where the flow rate is the lowest. Thereby, in the downstream piping 22, the water flows at a higher flow velocity than the downstream flow velocity v2 based on the downstream flow rate Q2. As a result, retention of water in the downstream piping 22 can be effectively suppressed.

(8) The piping system 10 includes a return pipe 23 that returns the water that has passed through the downstream pipe 22 to the supply source 11. Further, the adjustment unit 40 has a bypass pipe 41 connected to the downstream pipe 22, and adjusts the downstream flow rate Q2 and the bypass flow rate Q3 so that both the downstream flow velocity v2 and the bypass flow velocity v3 fall within the appropriate flow velocity range. are doing. Thereby, in the downstream piping 22 and the bypass pipe 41, water whose quality is suppressed from deteriorating due to stagnation can be returned to the supply source 11.

(9) The lower limit flow velocity vmin of the downstream flow velocity v2 and the bypass flow velocity v3 is set to a value larger than the lower limit value of the appropriate flow velocity range, and the upper limit flow velocity vmax is set to a value smaller than the upper limit value of the proper flow velocity range. Thereby, retention of water in the downstream pipe 22 and the bypass pipe 41 can be suppressed.

(10) By controlling the downstream flow rate Q2 so that the downstream flow velocity v2 approaches the upper limit flow velocity vmax, retention of water on the downstream side of the main pipe 15 can be suppressed more effectively.

(11) Since the downstream cross-sectional area S2 is smaller than the bypass cross-sectional area S3, the state in which the downstream flow velocity v2 is high is easily maintained. Thereby, retention of water in the downstream piping 22 can be effectively suppressed.

This embodiment can be modified and implemented as follows. This embodiment and the following modified examples can be implemented in combination with each other within a technically consistent range.
- The bypass pipe 41 is not limited to a configuration in which it is connected to the downstream piping 22, but may be configured to drain all the water that has passed through the bypass pipe 41. In this configuration, the bypass flow rate adjustment valve 43 can be controlled by the opening degree control similar to that of the embodiment described above, and the downstream flow rate Q2 can be adjusted. Further, as another opening degree control, the bypass flow rate adjustment valve 43 can be controlled by an opening degree control including a closed state, and the downstream flow rate Q2 can also be adjusted.

- The downstream piping 22 is not limited to a configuration in which it is connected to the reflux pipe 23, but may be configured to drain all the water that has passed through the downstream piping 22.
- The adjustment unit 40 is not limited to a configuration that controls the opening degrees of the downstream flow rate adjustment valve 42 and the bypass flow rate adjustment valve 43 based on the measurement results of the downstream flow rate Q2 and the bypass flow rate Q3. The adjustment unit 40 may perform the opening degree control based only on the measurement result of the downstream flow rate Q2. Further, the adjustment unit 40 may calculate the amount of water passing through the upstream pipe 21 and then perform the opening control based only on the measurement result of the bypass flow rate Q3.

- The downstream flow meter 44 may have any configuration as long as it measures the flow rate of water in the downstream piping 22. Therefore, the downstream flow meter 44 may be configured to measure the amount of water flowing into the downstream pipe 22. In such a configuration, the upper limit flow velocity vmax is set to the upper limit value of the appropriate flow velocity range.

- The adjustment unit 40 has a downstream flow rate meter instead of the downstream flow rate meter 44, and adjusts the opening degree and the degree of opening of the downstream flow rate adjustment valve 42 based on the downstream flow rate v2 measured by the downstream flow rate meter. The opening degree of the bypass flow rate adjustment valve 43 may be controlled.

- The adjustment unit 40 has a bypass flow rate meter instead of the bypass flow rate meter 45, and adjusts the opening degree of the downstream flow rate adjustment valve 42 and the bypass flow rate adjustment valve based on the bypass flow rate v3 measured by the bypass rate meter. The opening degree of 43 may be controlled.

- The adjustment unit 40 may be configured to adjust the downstream flow rate Q2 based on the flow rate of the bypass flow rate Q3. Therefore, the adjustment section 40 may have a configuration including either the downstream flow rate adjustment valve 42 or the bypass flow rate adjustment valve 43. Even with such a configuration, the downstream flow rate Q2 can be adjusted by adjusting the bypass flow rate Q3 using the flow rate adjustment valve.

- As shown in FIG. 4, the adjustment unit 40 is a three-way valve to which the upstream piping 21, the downstream piping 22, and the bypass pipe 41 are connected, instead of the downstream flow regulating valve 42 and the bypass flow regulating valve 43. It may be 60. The three-way valve 60 is an automatic valve, and the opening degree with respect to the downstream pipe 22 and the opening degree with respect to the bypass pipe 41 are controlled by the control device 50.

- Each pipe constituting the piping system 10 is not limited to a stainless steel pipe for piping, but may be a metal pipe such as copper or aluminum, or a resin pipe such as a vinyl chloride pipe.

DESCRIPTION OF SYMBOLS 10... Piping system, 11... Supply source, 12... Tank, 13... Pump, 15... Main pipe, 16... Supply amount adjustment pipe, 17... First supply amount adjustment valve, 18... Second supply amount adjustment valve, 19... Supply Quantity measuring instrument, 21...Upstream piping, 22...Downstream piping, 23...Recirculation pipe, 24...Drainage pipe, 25...First use point, 26...First branch pipe, 27...First on-off valve, 28...No. 1 Instrument branch pipe, 29...First instrument, 30...Diversion point, 31...Second use point, 32...Second branch pipe, 33...Second on-off valve, 34...Second instrument branch pipe, 35...Second branch pipe 2 Instrument, 36... Circulation valve, 37... Drain valve, 38... Confluence point, 40... Adjustment section, 41... Bypass pipe, 42... Downstream flow rate adjustment valve, 43... Bypass flow rate adjustment valve, 44... Downstream flow rate measuring device , 45... Bypass flow rate measuring device, 50... Control device, 51... Flow rate acquisition section, 52... Flow rate calculation section, 53... Valve control section, 54... Storage section, 60... Three-way valve.

Claims (4)

A piping system comprising a main pipe through which water supplied from a supply source flows,
The main pipe is composed of an upstream pipe in which a first use point is provided and a downstream pipe in which a second use point is provided,
The downstream piping has a smaller flow path cross-sectional area than the upstream piping,
The main pipe further includes a bypass pipe that is connected to the downstream side of the first use point and bypasses the second use point, and that adjusts the flow rate of the downstream pipe according to the flow rate of the bypass pipe. ,
The adjustment unit includes a flow rate adjustment valve disposed in at least one of the downstream pipe and the bypass pipe, and a measuring device related to the flow velocity in the downstream pipe, and based on the measurement result of the measuring device. controlling the flow rate regulating valve;
plumbing system. The piping system according to claim 1 , wherein the measuring instrument is disposed downstream of the second point of use in the downstream piping. further comprising a reflux pipe connected to the downstream piping and returning the water that has passed through the downstream piping to the supply source,
The adjustment unit is configured such that the bypass pipe is connected to the downstream side of the second point of use in the downstream piping, and adjusts the flow rate of the downstream piping while maintaining a state in which the water flows through the bypass pipe. The piping system according to 1 or 2 . A piping system comprising a main pipe through which water supplied from a supply source flows,
The main pipe is composed of an upstream pipe in which a first use point is provided and a downstream pipe in which a second use point is provided,
The downstream piping has a smaller flow path cross-sectional area than the upstream piping,
an adjustment unit having a bypass pipe connected to the downstream side of the first use point in the main pipe and bypassing the second use point, and adjusting the flow rate of the downstream pipe according to the flow rate of the bypass pipe ;
further comprising a reflux pipe connected to the downstream piping and configured to return the water that has passed through the downstream piping to the supply source,
The adjustment unit is configured such that the bypass pipe is connected to the downstream side of the second point of use in the downstream piping, and adjusts the flow rate of the downstream piping while maintaining the state in which the water flows through the bypass pipe.
plumbing system.