CN212871703U - System for testing current limiting effect of cut-off device - Google Patents

Abstract

The utility model discloses a system for be used for testing cut-off equipment's current-limiting effect, include: a water outlet is arranged at the bottom of the flow-limiting pool, an overflow port is arranged at the top of the flow-limiting pool, and a cut-off device can be arranged at the position of the water outlet so as to change the flow area of the water outlet; the water collecting tank is lower than the water outlet of the flow limiting tank and is respectively connected with the water outlet and the overflow port; the lifting device is arranged in the water collecting tank and is used for lifting the water in the water collecting tank into the flow limiting tank; the measuring module is used for measuring the flow of the water outlet and the flow of the overflow port; the control module is respectively connected with the lifting device, the measuring module and the cut-off device, controls the operation of the lifting device and changes the flow area of the water outlet according to the flow control cut-off device of the water outlet measured by the measuring module so as to test the flow limiting effect of the cut-off device. The utility model discloses a to the quantization of cut-off equipment's current-limiting effect, and the energy consumption is low, the operation is maintained simply, equipment drops into fewly.

Description

System for testing current limiting effect of cut-off device

Technical Field

The utility model belongs to the technical field of municipal administration sewage treatment, more specifically relates to a system for testing cut-off equipment's current-limiting effect.

Background

The method has the advantages of treating the urban black and odorous water body, realizing the cleanness of the river channel, the limpidity of the river water and the beauty of the river bank, and having important significance for promoting the construction of urban ecological civilization, improving the urban quality and promoting the economic development. Many black and odorous water body renovation technologies at home and abroad adopt a cut-off mode, and in an engineering case, a cut-off device is usually arranged in a sewage intercepting well so as to fully play the flow limiting function of the sewage intercepting well. For example, in sunny days, the sewage intercepting well enables sewage directly discharged into a river to be diverted to enter a sewage treatment system; in the initial rain, the rain and sewage mixed liquid enters a sewage treatment system for treatment; along with the increase of rainfall intensity and rainfall duration, the water level in the well rises, the cut-off equipment arranged on the sewage intercepting pipeline is opened, and the cut-off equipment controls the water quantity of the mixed liquid entering the sewage plant and the water quantity of the overflow river by reducing the flow area. Therefore, the intercepting device directly influences the running state of the sewage plant and the river inflow amount of pollutants, and therefore the black and odorous water body treatment quality and the whole water environment quality of the drainage basin are directly related. The cut-off equipment also has very big regulatory action to the actual sewage treatment ability of municipal administration, and the actual sewage treatment ability of municipal administration includes sewage treatment plant throughput, the ecological holding capacity of river and supporting rainwater regulation facility regulatory ability, and to guarantee municipal drainage system steady operation, then must guarantee that the displacement is not more than sewage treatment plant throughput, and the overflow water yield is not more than the ecological holding capacity of river, and the ponding can not be more than supporting rainwater regulation facility regulatory ability.

In recent years, intercepting devices are introduced into a lot of projects, but the phenomena that the amount of overflowing sewage and the amount of water entering a sewage plant are unknown and the total amount of pollutants entering a river and the plant is unknown generally exist, so that the current limiting effect of the intercepting devices cannot be judged, the high-standard requirement on water environment treatment cannot be met, the large-trend requirement for overall consideration of industrial plants, networks and river basin cannot be met, and the requirement for regulation and control of the large data of the future intelligent water utilities cannot be met.

Therefore, it is expected to develop a system for testing a current limiting effect of a cut-off device, which tests the current limiting effect of the cut-off device and realizes quantification of the current limiting effect of the cut-off device.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a system for testing cut-off equipment's current-limiting effect tests cut-off equipment's current-limiting effect, realizes the quantization to cut-off equipment's current-limiting effect, and the energy consumption is low, the operation maintenance is simple, equipment drops into fewly.

In order to achieve the above object, the present invention provides a system for testing a current limiting effect of an intercepting device, including:

the flow-limiting pool is provided with a water outlet at the bottom and an overflow port at the top, and the cut-off device can be installed at the water outlet to change the flow area of the water outlet;

the water collecting tank is lower than the water outlet of the flow limiting tank and is respectively connected with the water outlet and the overflow port;

the lifting device is arranged in the water collecting pool and used for lifting the water in the water collecting pool into the flow limiting pool;

the measuring module is used for measuring the flow of the water outlet and the flow of the overflow port respectively;

the control module is respectively connected with the lifting device, the measuring module and the cut-off device, controls the operation of the lifting device and changes the flow area of the water outlet by the cut-off device according to the flow rate of the water outlet measured by the measuring module so as to test the flow limiting effect of the cut-off device.

Optionally, the measurement module comprises a first flow meter, the first flow meter is arranged on the sewage interception main pipe, and the first flow meter is connected to the control module;

when the flow measured by the first flowmeter is larger than a preset value, the control module controls the cut-off device to reduce the flow area of the water outlet.

Optionally, the system further comprises a steady flow tank, wherein the steady flow tank is arranged between the flow limiting tank and the water collecting tank, the steady flow tank is lower than the water outlet of the flow limiting tank and higher than the water collecting tank, the water outlet of the flow limiting tank is connected to the steady flow tank through a connecting pipe, and the steady flow tank is connected to the water collecting tank through a sewage intercepting main pipe;

the measuring module further comprises a second flowmeter, an overflow port of the flow limiting pool is connected with the water collecting pool through an overflow pipe, the second flowmeter is arranged on the overflow pipe, and the second flowmeter is connected with the control module.

Optionally, the pollutant intercepting main pipe further comprises a valve, the valve is arranged at the downstream of the first flowmeter, and the valve is electrically connected with the control module.

Optionally, the volume of the catch basin is not less than the sum of the volumes of the flow restricting basin and the flow stabilizing basin.

Optionally, the lifting device includes a pump and a confluence main pipe, the pump is disposed at the bottom of the water collecting tank, the confluence main pipe is connected between the water collecting tank and the flow-limiting tank, and water in the water collecting tank can flow back to the flow-limiting tank through the confluence main pipe under the action of the pump.

Optionally, the pipe diameter of the confluence main pipe is equal to that of the overflow pipe, the pipe diameter of the connecting pipe is equal to that of the pollutant interception main pipe, and the pipe diameter of the confluence main pipe is larger than that of the connecting pipe.

Optionally, the control module calculates a ratio of the flow measured by the first flow meter to the lift flow of the lift device and a ratio of the flow measured by the second flow meter to the lift flow of the lift device, respectively.

The beneficial effects of the utility model reside in that:

1. according to the scheme, the flow-limiting pool is used for simulating a sewage intercepting well, the lifting device is used for simulating rainfall, the water outlet is used for simulating sewage interception and river entry, the overflow port is used for simulating overflow and river entry, meanwhile, the measurement module is used for collecting water volume data and feeding the data back to the control module, the control module is used for controlling the cut-off device to adjust the water volume of the sewage interception and river entry and the water volume of the overflow and river entry, the actual operation condition of the municipal combined system sewage intercepting pipeline can be simulated, the functions of the pipeline can be fully exerted, the water volume of the sewage interception and the water volume of the overflow and river entry under the action of the cut; the flow-limiting pool and the water collecting pool are arranged along the water flow direction, so that the water flow of the water outlet and the overflow port is automatically converged to the water collecting pool, and the water flow pushing energy is saved; the test water can be recycled.

Other features and advantages of the present invention will be described in detail in the detailed description which follows.

Drawings

The above and other objects, features and advantages of the present invention will become more apparent by describing in more detail exemplary embodiments thereof with reference to the attached drawings, in which like reference numerals generally represent like parts throughout the exemplary embodiments of the present invention.

Fig. 1 shows a schematic structural view of a system for testing a current limiting effect of a flow interception device according to an embodiment of the present invention.

Fig. 2 shows a flow diagram of a system for testing the effect of flow restriction of an intercepting device according to one embodiment of the present invention.

Fig. 3 shows a schematic view of an open state of the shut off device according to an embodiment of the present invention.

Fig. 4 shows a schematic view of a semi-closed state of a cut-off device according to an embodiment of the invention.

Description of the reference numerals

1. A flow-limiting pool; 2. a flow stabilizing pool; 3. a water collecting tank; 4. a confluence main pipe; 5. a connecting pipe; 6. a sewage intercepting main pipe; 7. an overflow pipe; 8. a flow cut-off device; 9. a pump 10, a first flow meter; 11. a second flow meter; 12. a control module; 13. and (4) a valve.

Detailed Description

Preferred embodiments of the present invention will be described in more detail below. While the following describes preferred embodiments of the present invention, it should be understood that the present invention may be embodied in various forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", and the like, indicate the orientation or positional relationship indicated based on the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

The utility model discloses a system for be used for testing cut-off equipment's current-limiting effect, include:

the flow-limiting pool is provided with a water outlet at the bottom and an overflow port at the top, and a cut-off device can be arranged at the water outlet to change the overflowing area of the water outlet;

the water collecting tank is lower than the water outlet of the flow limiting tank and is respectively connected with the water outlet and the overflow port;

the lifting device is arranged in the water collecting tank and used for lifting the water in the water collecting tank into the flow limiting tank;

the measuring module is used for measuring the flow of the water outlet and the flow of the overflow port;

and the control module is respectively connected with the lifting device, the measuring module and the cut-off device, controls the operation of the lifting device and changes the flow area of the water outlet according to the flow control cut-off device of the water outlet measured by the measuring module so as to test the flow limiting effect of the cut-off device.

In the scheme, the flow-limiting pool is used for simulating a sewage intercepting well, the lifting device is used for simulating rainfall, the water outlet is used for simulating sewage interception and river entering, the overflow port is used for simulating overflow and river entering, meanwhile, the measurement module is used for collecting water volume data and feeding the data back to the control module, the control module is used for controlling the interception device to adjust the water volume of the sewage interception and river entering and the water volume of the overflow and river entering, the actual operation condition of the municipal combined system sewage intercepting pipeline can be simulated, the functions of the sewage interception and river entering water volume can be fully exerted, the sewage interception and factory entering water volume and the overflow and river entering water volume can be clearly defined under the action; the flow-limiting pool and the water collecting pool are arranged along the water flow direction, so that the water flow of the water outlet and the overflow port is automatically converged to the water collecting pool, and the water flow pushing energy is saved; the test water can be recycled.

As an alternative, the measuring module comprises a first flow meter, the first flow meter is arranged on the sewage intercepting main pipe, and the first flow meter is connected to the control module;

when the flow measured by the first flowmeter is larger than a preset value, the control module controls the cut-off device to reduce the flow area of the water outlet.

Specifically, the first flowmeter is arranged on the sewage interception main pipe, and the first flowmeter is arranged at a position which is at least 5 times of pipe diameter away from the upstream end of the sewage interception main pipe and at least 3 times of pipe diameter away from the downstream end.

As an alternative scheme, the device also comprises a steady flow pool, wherein the steady flow pool is arranged between the flow limiting pool and the water collecting pool, the steady flow pool is lower than a water outlet of the flow limiting pool and higher than the water collecting pool, the water outlet of the flow limiting pool is connected to the steady flow pool through a connecting pipe, and the steady flow pool is connected to the water collecting pool through a sewage intercepting main pipe;

the measuring module further comprises a second flowmeter, an overflow port of the flow limiting pool is connected with the water collecting pool through an overflow pipe, the second flowmeter is arranged on the overflow pipe, and the second flowmeter is connected with the control module.

Specifically, set up the stationary flow pond at the main pipe front end of cutting dirty, can stabilize the rivers, alleviate pipeline flow state change, provide stable rivers for the measurement of cutting dirty main pipe flow, the second flowmeter sets up on the overflow pipe, and its position should be apart from the distance of overflow pipe upstream end at least 5 times pipe diameter, apart from the distance of downstream end at least 3 times pipe diameter.

The utility model discloses an optimize device spatial arrangement, reduce area, with the function of traditional dispersion: flow-limiting, stationary flow and damming, optimize and combine to same system in, promote the water in the catch basin to the current-limiting pond through hoisting device, then through the design of pipeline slope, overall each vertical height in district, utilize the action of gravity as the rivers driving force, the connecting pipe, cut the rivers in dirty main pipe, the overflow pipe and converge to the catch basin once more, rivers are closed.

Optionally, the pollutant intercepting main pipe further comprises a valve, the valve is arranged at the downstream of the first flowmeter, and the valve is electrically connected with the control module.

Specifically, the control module can prevent water in the sewage interception main pipe from flowing into the water collecting tank by closing the valve when the system fails.

Alternatively, the volume of the catch basin is not less than the sum of the volumes of the flow-restricting basin and the flow-stabilizing basin.

Specifically, the volume of the water collecting tank is large enough to provide a sufficient water source for the system, meanwhile, water overflow in the system can be avoided, and when the system is not operated, water in the flow limiting tank and the flow stabilizing tank can be stored in the water collecting tank.

As an alternative scheme, the lifting device comprises a pump and a confluence main pipe, the pump is arranged at the bottom of the water collecting pool, the confluence main pipe is connected between the water collecting pool and the flow-limiting pool, and water in the water collecting pool can flow back to the flow-limiting pool through the confluence main pipe under the action of the pump.

As an alternative scheme, the pipe diameter of the confluence main pipe is equal to that of the overflow pipe, the pipe diameter of the connecting pipe is equal to that of the pollutant interception main pipe, and the pipe diameter of the confluence main pipe is larger than that of the connecting pipe.

Specifically, in the system, a flow limiting pool A, a flow stabilizing pool B and a water collecting pool C are provided, wherein the flow limiting pool A mainly has the function of simulating a sewage intercepting well to split mixed sewage collected at the upstream, so that one part of the mixed sewage enters a sewage plant, namely a sewage intercepting main pipe, and the other part of the mixed sewage overflows into an external water body, namely an overflow pipe; the flow stabilizing pool B mainly has the function of providing stable water flow; the water collecting tank C has the main functions of collecting the overflow water quantity of the flow limiting tank A and the water outlet quantity of the flow stabilizing tank B, and simultaneously providing a water source for the flow limiting tank A through a lifting device;

the connecting pipe is L_A-BDiameter of pipe D_A-B(ii) a The sewage interception main pipe is L_B-CPipe diameter D_B-C(ii) a The confluence main pipe is L_C-ADiameter of pipe D_C-A(ii) a An overflow pipe is L_A-CDiameter of pipe D_A-C(ii) a Wherein the pipe diameters are related to each other_C-A＝D_A-C＞D_A-B＝D_B-CFlow rate relationship Q_C-A>Q_A-B＝Q_B-C＝(n+1)Q_dr(n is the cut-off multiple of the sewage-cutting main pipe, Q)_drSewage amount in dry season), Q_C-A≈Q_A-C+Q_A-B(ii) a Length L_B-C＞＝5*D_B-C+L_J1+3*D_B-C，L_A-C＞＝5*D_A-C+L_J2+3*D_A-C(L_J1Length of pipe occupied for first flowmeter, L_J2The length of the conduit occupied by the second flow meter); relative relation H of elevation H of tube bottom_A-C＞H_C-A＞H_A-B＝H_B-CThe gradient i of each pipeline corresponds to the common gradient of the pipe diameter; volume V_C＞＝V_A+V_B，V_B>V_A。

Alternatively, the control module calculates a ratio of the flow measured by the first flow meter to the lift flow of the lift device and a ratio of the flow measured by the second flow meter to the lift flow of the lift device, respectively.

Specifically, the control module is preferably a PLC (programmable logic controller), the PLC is used for acquiring the flow in the sewage interception main pipe to control the opening degree of the intercepting device so as to adjust the water amount entering the sewage interception main pipe, the water amount discharge is controlled fundamentally, and the control module plays an important role in quantifying the flow limiting effect;

the flow measured by the first flowmeter is the water quantity entering the sewage intercepting main pipe from the water outlet, the flow measured by the second flowmeter is the water quantity entering the overflow pipe from the overflow port, the ratio of the water discharge to the lifting flow of the lifting device and the ratio of the overflow to the lifting flow of the lifting device are calculated by the control module, the intercepting effect of the intercepting device can be embodied, and the intercepting effect can be quantized according to the proportion of the water quantities of all parts.

The utility model also discloses a method of test cut-off equipment's current-limiting effect utilizes foretell system for testing cut-off equipment's current-limiting effect, and the method includes following step:

1) injecting enough starting water source into the water collecting tank, and installing the cut-off device on the water outlet;

2) starting a lifting device to lift a water source in the water collecting tank to the flow limiting tank, so that the system enters a sunny running state;

3) gradually increasing the flow of the lifting device to enable the system to enter an initial rainfall running state, transmitting the measured flow of the water outlet to the control module by the measuring module in real time, and gradually reducing the overflowing area of the water outlet by the control module according to the flow control cut-off device of the water outlet.

As an alternative scheme, the system further comprises a steady flow pool, wherein the steady flow pool is arranged between the flow limiting pool and the water collecting pool, the steady flow pool is lower than a water outlet of the flow limiting pool and higher than the water collecting pool, the water outlet of the flow limiting pool is connected to the steady flow pool through a connecting pipe, and the steady flow pool is connected to the water collecting pool through a sewage intercepting main pipe;

the measuring module further comprises a second flowmeter, an overflow port of the flow limiting pool is connected with the water collecting pool through an overflow pipe, the second flowmeter is arranged on the overflow pipe, and the second flowmeter is connected with the control module;

the method further comprises the following steps:

4) when the overflow area of the water outlet reaches the minimum value, controlling the flow of the lifting device to keep stable, enabling the system to enter a rainfall stabilization period, and when the water level in the flow limiting pool rises to an overflow water level, causing an overflow phenomenon to occur, and transmitting the measured flow to the control module by the second flowmeter in real time;

5) the control module respectively calculates the ratio of the flow measured by the first flow meter to the lifting flow of the lifting device and the ratio of the flow measured by the second flow meter to the lifting flow of the lifting device.

Specifically, the method is used for testing the flow limiting effect of the cut-off equipment, the flow limiting effect of the cut-off equipment in different stages can be fed back in real time through the appropriate amount of water discharge and overflow, the quantification of the flow limiting effect of the cut-off equipment is realized, and the method is low in energy consumption, simple in operation and maintenance and low in equipment investment.

When the system operates, the control module adjusts the cut-off device according to the data measured by the measuring module, controls the water discharge amount to ensure that the water discharge amount is not higher than a preset value (equivalent to the treatment capacity of a sewage treatment plant), synchronously monitors the overflow water amount, wherein the water discharge amount is equivalent to the sewage interception plant inlet amount, the overflow water amount is equivalent to the overflow river inlet amount, and the flow limiting effect of the cut-off device is quantized and the flow limiting capacity of the cut-off device is embodied by utilizing the ratio of the water discharge amount to the flow of the lifting device and the ratio of the overflow amount to the flow of the lifting device.

Examples

Fig. 1 shows a schematic structural view of a system for testing a flow restriction effect of a flow cut-off device according to an embodiment; fig. 2 shows a flow diagram of a system for testing the flow restricting effect of a flow stop of the present embodiment.

As shown in fig. 1 and 2, a system for testing a flow restriction effect of a flow cut-off device includes: the flow-limiting device comprises a flow-limiting pool 1, a flow-stabilizing pool 2 and a water collecting pool 3, wherein the volume of the water collecting pool 3 is larger than the sum of the volumes of the flow-limiting pool 1 and the flow-stabilizing pool 2;

the flow-limiting pool 1 is a rectangular pool body, a water outlet is arranged at the lower part of one side wall, an overflow port is arranged at the upper part of the other side wall, the cut-off device 8 is arranged at the water outlet in the flow-limiting pool 1 so as to change the overflowing area of the water outlet, the installation schematic diagram is shown in fig. 3 and 4, the cut-off device is opened as shown in fig. 3, and the cut-off device is semi-closed as shown in fig. 4;

the water outlet of the flow-limiting pool 1 is connected with the flow-stabilizing pool 2 through a connecting pipe 5, the flow-stabilizing pool 2 is connected with the water collecting pool 3 through a sewage intercepting main pipe 6, the water collecting pool 3 is connected with the flow-limiting pool 1 through a lifting device, and the overflow port of the flow-limiting pool 1 is connected with the water collecting pool 3 through an overflow pipe 7; when the system operates, water in the water collecting tank 3 is lifted to the flow limiting tank 1 through the lifting device, then through the gradient design of the pipeline, the gravity is used as a water flow driving force, so that water flows in the connecting pipe 5, the sewage intercepting main pipe 6 and the overflow pipe 7 are converged to the water collecting tank 3 again, and the water flow is closed;

the lifting device comprises a pump 9 and a confluence main pipe 4, wherein the pump 9 is arranged at the bottom of the water collecting tank 3, the confluence main pipe 4 is connected between the water collecting tank 3 and the flow-limiting tank 1, and water in the water collecting tank 3 can flow back to the flow-limiting tank 1 through the confluence main pipe 4 under the action of the pump 9;

the measuring module comprises a first flowmeter 10 and a second flowmeter 11, the first flowmeter 10 is arranged on the sewage intercepting main pipe 6 and used for measuring the water discharge amount in the sewage intercepting main pipe 6, the second flowmeter 11 is arranged on the overflow pipe 7 and used for measuring the overflow water amount in the overflow pipe 7, and the valve 13 is arranged on the sewage intercepting main pipe 6 and located at the downstream of the first flowmeter 10

The control module 12 is a PLC controller, and is connected to the pump 9, the cut-off device 8, the first flowmeter 10, the second flowmeter 11 and the valve 13, respectively, and when the flow measured by the first flowmeter 10 is greater than a preset value, the PLC controller controls the cut-off device 8 to reduce the flow area of the drain outlet, and calculates the ratio of the flow measured by the first flowmeter to the lift flow of the lift device and the ratio of the flow measured by the second flowmeter to the lift flow of the lift device, respectively.

The method for testing the current limiting effect of the cut-off equipment by utilizing the system comprises the following steps:

1) injecting enough starting water source into the water collecting tank 3, and installing the cut-off device 8 at the water outlet;

2) starting a lifting device to lift a water source in the water collecting tank 3 to the flow limiting tank 1, so that the system enters a sunny running state;

3) gradually increasing the flow of the lifting device to enable the system to enter an initial rainfall running state, transmitting the measured flow of the water outlet to a PLC (programmable logic controller) in real time by a measuring module, and gradually reducing the flow area of the water outlet by the PLC according to a flow control cut-off device 8 of the water outlet;

4) when the overflow area of the water outlet reaches the minimum value, controlling the flow of the lifting device to keep stable, enabling the system to enter a rainfall stabilization period, and when the water level in the flow limiting pool rises to an overflow water level, causing an overflow phenomenon to occur, and transmitting the measured flow to the PLC in real time by the second flowmeter;

5) the PLC respectively calculates the ratio of the flow measured by the first flowmeter to the lifting flow of the lifting device and the ratio of the flow measured by the second flowmeter to the lifting flow of the lifting device, and quantifies the flow limiting effect of the cut-off device 8 by utilizing the proportion of the discharged water amount to the flow of the lifting device and the proportion of the overflow water amount to the flow of the lifting device.

While various embodiments of the present invention have been described above, the above description is intended to be illustrative, not exhaustive, and not limited to the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments.

Claims (8)

1. A system for testing the flow restriction effect of a flow stop device, comprising:

the flow-limiting pool is provided with a water outlet at the bottom and an overflow port at the top, and the cut-off device can be installed at the water outlet to change the flow area of the water outlet;

the water collecting tank is lower than the water outlet of the flow limiting tank and is respectively connected with the water outlet and the overflow port;

the lifting device is arranged in the water collecting pool and used for lifting the water in the water collecting pool into the flow limiting pool;

the measuring module is used for measuring the flow of the water outlet and the flow of the overflow port;

the control module is respectively connected with the lifting device, the measuring module and the cut-off device, controls the operation of the lifting device and changes the flow area of the water outlet by the cut-off device according to the flow rate of the water outlet measured by the measuring module so as to test the flow limiting effect of the cut-off device.

2. The system for testing the current limiting effect of a flow closure device according to claim 1, further comprising a flow stabilization basin disposed between the flow restriction basin and the water collection basin, the flow stabilization basin being lower than the water outlet of the flow restriction basin and higher than the water collection basin, the water outlet of the flow restriction basin being connected to the flow stabilization basin by a connection pipe, the flow stabilization basin being connected to the water collection basin by a sewage intercepting dry pipe;

the measuring module comprises a second flowmeter, an overflow port of the flow-limiting pool is connected with the water collecting pool through an overflow pipe, the second flowmeter is arranged on the overflow pipe, and the second flowmeter is connected with the control module.

3. The system for testing the flow restriction effect of a flow stop device according to claim 2, wherein the measurement module comprises a first flow meter disposed on the intercepting main pipe, the first flow meter being connected to the control module;

when the flow measured by the first flowmeter is larger than a preset value, the control module controls the cut-off device to reduce the flow area of the water outlet.

4. The system for testing the flow restriction of a flow stop device according to claim 3, further comprising a valve on the blowdown trunk line, the valve being disposed downstream of the first flow meter, the valve being electrically connected to the control module.

5. The system for testing the flow restriction effect of a flow closure device according to claim 2, wherein the volume of the catch basin is not less than the sum of the volumes of the flow restriction basin and the flow stabilization basin.

6. The system for testing the flow-limiting effect of a flow-stopping device according to claim 2, wherein the lifting device comprises a pump and a confluence main, the pump is disposed at the bottom of the water collecting tank, the confluence main is connected between the water collecting tank and the flow-limiting tank, and water in the water collecting tank can flow back to the flow-limiting tank through the confluence main under the action of the pump.

7. The system for testing a flow limiting effect of a shut-off device according to claim 6, wherein a pipe diameter of the confluence main pipe is equal to a pipe diameter of the overflow pipe, a pipe diameter of the connection pipe is equal to a pipe diameter of the interception dry pipe, and the pipe diameter of the confluence main pipe is greater than the pipe diameter of the connection pipe.

8. The system of claim 3, wherein the control module calculates a ratio of the flow measured by the first flow meter to the lift flow of the lift device and a ratio of the flow measured by the second flow meter to the lift flow of the lift device, respectively.

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