CN210741624U - Dynamic flow controller detection device - Google Patents

Abstract

A dynamic flow controller detection device comprises a main loop and a test loop; the main loop comprises a large-diameter pipeline, a water tank, a variable frequency pump, a pressure stabilizing tank and an electromagnetic flowmeter, wherein the water tank, the variable frequency pump, the pressure stabilizing tank and the electromagnetic flowmeter are sequentially connected and connected back to the water tank through the large-diameter pipeline to form a circulating loop; the test loop comprises a small-diameter pipeline, a standard flowmeter, a detected flowmeter, a measuring cup, an electronic scale, a first electromagnetic valve and a second electromagnetic valve, wherein a water inlet of the standard flowmeter is connected between the surge tank and the electromagnetic flowmeter through the small-diameter pipeline, the small-diameter pipeline connected with a water outlet of the detected flowmeter is divided into a first branch and a second branch, and the first electromagnetic valve and the second electromagnetic valve are sequentially installed on the second branch and are respectively a normally open electromagnetic valve and a normally closed electromagnetic valve. The device adopts a small-pipe-diameter pipeline of a test loop led out from a large-pipe-diameter pipeline of a main loop to ensure the stability of the flow in the test loop; the method has two functions of detecting the measuring precision of the detected flowmeter and quickly filling.

Description

Dynamic flow controller detection device

Technical Field

The utility model relates to an instrument and meter detection area, in particular to dynamic flow controller detection device.

Background

As is well known, the dynamic flow controller is widely applied in various fields such as industry, agriculture, medical industry and daily life, and the domestic market of the dynamic flow controller is monopolized abroad at present. In recent years, with the rapid development of the domestic pharmaceutical, food, beverage and other industries, the filling control precision of the dynamic flow controller is more and more required by products such as medical medicaments, beverages, health care products and the like. However, the control precision of the electromagnetic flow controllers produced in China at present cannot meet the requirements of the industries. Therefore, it is important to develop a dynamic flow controller detection device with proprietary intellectual property rights to improve and enhance the control accuracy of the dynamic flow controller.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model provides a dynamic flow controller detection device.

The purpose of the utility model can be realized by the following technical scheme: a dynamic flow controller detection device comprises a main loop and a test loop; the main loop comprises a large-diameter pipeline, a water tank, a variable frequency pump, a pressure stabilizing tank and an electromagnetic flowmeter, the water tank, the variable frequency pump, the pressure stabilizing tank and the electromagnetic flowmeter are sequentially connected and connected back to the water tank through the large-diameter pipeline to form a circulating loop, a PID closed-loop controller is arranged in a frequency converter of the variable frequency pump, and a feedback signal is sent from the electromagnetic flowmeter; the testing loop comprises a small-diameter pipeline, a standard flowmeter, a detected flowmeter, a measuring cup, an electronic scale, a first electromagnetic valve and a second electromagnetic valve, wherein the standard flowmeter and the detected flowmeter are connected through the small-diameter pipeline, the small-diameter pipeline connected with a water inlet of the standard flowmeter is connected to the large-diameter pipeline between a pressure stabilizing tank and the electromagnetic flowmeter of a main loop, the small-diameter pipeline connected with a water outlet of the detected flowmeter is divided into a first branch and a second branch, the first branch is connected to a water tank, a water outlet of the second branch is arranged above the measuring cup, the measuring cup is placed on the electronic scale, the first electromagnetic valve and the second electromagnetic valve are sequentially installed on the second branch, the first electromagnetic valve is a normally open electromagnetic valve, and the second electromagnetic valve is a normally closed electromagnetic valve.

Further, the major loop still includes first valve, second valve, check valve, third valve, fourth valve, first valve is installed on the big pipe diameter pipeline between water tank and the inverter pump, check valve and second valve are installed on the big pipe diameter pipeline between inverter pump and surge tank, the third valve is installed on the big pipe diameter pipeline between surge tank and electromagnetic flowmeter, the fourth valve is installed on the big pipe diameter pipeline between electromagnetic flowmeter and water tank.

Furthermore, the main loop further comprises a first corrugated pipe and a second corrugated pipe, wherein the first corrugated pipe and the second corrugated pipe are respectively arranged on a water inlet and a water outlet of the variable frequency pump.

Further, the main circuit further comprises a first pressure sensor, a second pressure sensor and a third pressure sensor; the first pressure sensor is arranged on a large-pipe-diameter pipeline between a variable-frequency pump and a pressure stabilizing tank of the main loop; big pipe diameter pipeline between surge tank and the electromagnetic flowmeter of major loop falls into first horizontal segment, vertical section, second horizontal segment in proper order, first horizontal segment is connected with the delivery port of surge tank, the second horizontal segment is connected with electromagnetic flowmeter's water inlet to connect the little pipe diameter pipeline that the standard flowmeter water inlet of test loop is connected on the second horizontal segment, second pressure sensor installs on first horizontal segment, third pressure sensor installs on the second horizontal segment.

Further, the pipe diameter of the large-pipe-diameter pipeline of the main loop is DN50, the electromagnetic flowmeter of the main loop is DN50, and the pipe diameter of the small-pipe-diameter pipeline of the testing loop is DN 25.

Further, the standard flow meter of the main loop is an RHM06 mass flow meter.

Further, the test circuit further comprises a fifth valve, a sixth valve and a seventh valve, the fifth valve is installed on a small-diameter pipeline connected with a water inlet of the standard flowmeter, and the sixth valve and the seventh valve are respectively installed on the first branch and the second branch.

Further, the test circuit further comprises a fourth pressure sensor and a fifth pressure sensor, wherein the fourth pressure sensor and the fifth pressure sensor are respectively arranged on the front side and the rear side of the first electromagnetic valve and the second electromagnetic valve on the second branch.

Further, the electromagnetic flowmeter of the main loop and the standard flowmeter of the test loop are mounted on a calibration table.

Still further, a console is included.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the device adopts a small-pipe-diameter pipeline of a test loop led out from a large-pipe-diameter pipeline of a main loop to ensure the stability of the flow in the test loop;

2. the test loops have two functions, namely detection of the measurement precision of the detected flowmeter and quick filling;

3. the quick filling pipeline in the test loop adopts a normally open solenoid valve and a normally closed solenoid valve which are connected in series as a control device of the switch pipeline, so that the effective time of switching on and off the pipeline is the short time required by the driving of the electrification electromagnetic force, the response time of the switch pipeline is shortened, and the effect of quick start and stop is achieved;

4. the standard flow meter in the main loop plays the role of:

(1) when the measurement precision of the detected flowmeter is detected, the reference signal source is used as a reference signal source for calibrating the detected flowmeter, and is compared with the flow output value of the detected flowmeter to judge the performance excellence of the detected flowmeter;

(2) monitoring the real-time pipeline flow value in the test loop;

(3) as a detected signal when a flow stability measurement is made on the device.

Drawings

Fig. 1 is a top view of the present invention.

Fig. 2 is a front view of the water inlet portion from the water tank to the surge tank of the middle main circuit of the present invention.

Fig. 3 is a front view of the water outlet to the water tank part and the test circuit of the surge tank of the middle main circuit of the present invention.

The parts in the figures are numbered as follows:

1 Water tank

2 frequency conversion pump

3 pressure stabilizing tank

4 electromagnetic flowmeter

5 first valve

6 first corrugated pipe

7 second corrugated pipe

8 second valve

9 check valve

10 third valve

11 fourth valve

12 standard flowmeter

13 flow meter to be tested

14 measuring cup

15 electronic scale

16 the fifth valve

17 sixth valve

18 the seventh valve

19 first solenoid valve

20 second solenoid valve

21 first horizontal segment

22 vertical section

23 second horizontal segment

24 first branch

25 second branch

26 control console

27 calibration table

P1 first pressure sensor

P2 second pressure sensor

P3 third pressure sensor

P4 fourth pressure sensor

P5 fifth pressure sensor.

Detailed Description

The following detailed description of the embodiments of the present invention will be given with reference to the accompanying drawings to make it clear to those skilled in the art how to practice the invention. While the invention has been described in connection with its preferred embodiments, these embodiments are intended to be illustrative, and not to limit the scope of the invention.

A dynamic flow controller detection device comprises a main loop and a test loop.

Referring to fig. 1 to 3, the main circuit includes a large-diameter pipeline, a water tank 1, a variable frequency pump 2, a surge tank 3, an electromagnetic flowmeter 4, a first valve 5, a first bellows 6, a second bellows 7, a second valve 8, a check valve 9, a third valve 10, a fourth valve 11, a first pressure sensor P1, a second pressure sensor P2, and a third pressure sensor P3.

The water tank 1, the variable frequency pump 2, the pressure stabilizing tank 3 and the electromagnetic flowmeter 4 are sequentially connected and connected back to the water tank 1 through a large-pipe-diameter pipeline to form a circulation loop, a PID closed-loop controller is arranged in a frequency converter of the variable frequency pump 2, and a feedback signal is sent from the electromagnetic flowmeter 4.

First valve 5 is installed on the big pipe diameter pipeline between water tank 1 and variable frequency pump 2, first bellows 6 and second bellows 7 are installed respectively on the water inlet and the delivery port of variable frequency pump 2, check valve 9 and second valve 8 are installed on the big pipe diameter pipeline between variable frequency pump 2 and surge tank 3, third valve 10 is installed on the big pipe diameter pipeline between surge tank 3 and electromagnetic flowmeter 4, fourth valve 11 is installed on the big pipe diameter pipeline between electromagnetic flowmeter 4 and water tank 1.

The first pressure sensor P1 is installed on the large-diameter pipeline between the variable frequency pump 2 and the surge tank 3 of the main circuit.

The large-pipe-diameter pipeline between the surge tank 3 and the electromagnetic flowmeter 4 is sequentially divided into a first horizontal section 21, a vertical section 22 and a second horizontal section 23, the first horizontal section 21 is connected with a water outlet of the surge tank 3, and the second horizontal section 23 is connected with a water inlet of the electromagnetic flowmeter 4. The second pressure sensor P2 is mounted on the first horizontal section 21, and the third pressure sensor P3 is mounted on the second horizontal section 23.

In the main loop of this embodiment, the pipe diameter of the large pipe diameter pipeline is DN 50; the volume of the water tank 1 is 600L, and the volume of the pressure stabilizing tank 3 is 200L; the frequency converter of the variable frequency pump 2 is an ABBACS355 frequency converter, and the frequency converter of the variable frequency pump 2 adjusts the output frequency through a PID closed-loop control method according to the feedback signal of the electromagnetic flowmeter 4 to control the rotating speed of the motor of the variable frequency pump 2, so that the function of controlling the water flow in the large-diameter pipeline is realized; the electromagnetic flow meter 4 is a DN50 electromagnetic flow meter; the first valve 5, the second valve 8, the third valve 10 and the fourth valve 11 are all manual valves.

Referring to fig. 1 and 3, the test circuit comprises a small-caliber pipeline, a standard flowmeter 12, a flowmeter to be tested 13, a measuring cup 14, an electronic scale 15, a fifth valve 16, a sixth valve 17, a seventh valve 18, a first electromagnetic valve 19, a second electromagnetic valve 20, a fourth pressure sensor P4 and a fifth pressure sensor P5.

The standard flowmeter 12 and the detected flowmeter 13 are connected through a small-diameter pipeline, the small-diameter pipeline connected with a water inlet of the standard flowmeter 12 is connected to a second horizontal section 23 of the large-diameter pipeline between the surge tank 3 and the electromagnetic flowmeter 4 of the main loop, the small-diameter pipeline connected with a water outlet of the detected flowmeter 13 is divided into a first branch 24 and a second branch 25, the first branch 24 is connected to the water tank 1, a water outlet of the second branch 25 is arranged above the measuring cup 14, and the measuring cup 14 is placed on the electronic scale 15.

The fifth valve 16 is installed on a small-diameter pipeline connected with the water inlet of the standard flowmeter 12, and the sixth valve and the seventh valve are respectively installed on the first branch and the second branch.

The first solenoid valve 19 and the second solenoid valve 20 are sequentially installed on the second branch 25. The first electromagnetic valve 19 is a normally open electromagnetic valve and is closed after being electrified; the second electromagnetic valve 20 is a normally closed electromagnetic valve and is opened after being electrified. The electromagnetic valve has the working characteristics that the action after the electromagnetic valve is electrified is driven by the electromagnetic force, the action speed is high, but the action speed is low due to the fact that the electromagnetic valve is flicked by mechanical action after the electromagnetic valve is electrified, a normally open electromagnetic valve and a normally closed electromagnetic valve are connected in series to be used as a switch, the effective time of conducting and closing the second branch is the short time required by the driving of the electromagnetic force, and the effect of quickly starting and stopping is achieved.

The fourth pressure sensor P4 and the fifth pressure sensor P5 are respectively installed on the front side and the rear side of the first solenoid valve 19 and the second solenoid valve 20 on the second branch 25, and the fourth pressure sensor P4 and the fifth pressure sensor P5 are used for monitoring the opening and closing state of the second branch 25.

In the test circuit of this embodiment, the pipe diameter of the small pipe diameter pipeline is DN 25; the standard flowmeter 12 is supported by the calibration platform 27, the standard flowmeter 12 is an RHM06 mass flowmeter, the working voltage is 24V, the flow measurement range is 0-20 kg/min, the measurement precision is 0.1%, and the standard flowmeter has the function of simultaneously realizing 4-20 mA current output and voltage pulse output; the fifth valve 16, the sixth valve 17 and the seventh valve 18 are all manual valves.

The device also comprises a control console 26, wherein the control console 26 is in communication connection with one or more of the variable frequency pump 2, the electromagnetic flow meter 4, the first pressure sensor P1, the second pressure sensor P2 and the third pressure sensor P3 of the main loop, the standard flow meter 12 of the test loop, the tested flow meter 13, the electronic scale 15, the first electromagnetic valve 19 and the second electromagnetic valve 20.

The stability of the flow in the test loop is ensured by leading out the small-pipe-diameter pipeline of the test loop on the large-pipe-diameter pipeline of the main loop. The test loop has two functions, namely detection of the measurement precision of the detected flowmeter and quick filling.

When the device is used for detecting the measurement precision of the detected flowmeter, all valves of the main loop, the fifth valve 16 and the sixth valve 17 of the test loop are opened, and the operation console 26 controls the variable frequency pump 2 of the main loop to work. The variable frequency pump 2 pumps water out of the water tank 1, after the water flow is stabilized by the pressure stabilizing tank 3, one part of the water flow flows back to the water tank 1 after flowing through the electromagnetic flowmeter 4, and the other part of the water flow enters the test loop and flows back to the water tank 1 after flowing through the standard flowmeter 12, the flowmeter 13 to be tested and the first branch 24. The measurement accuracy of the flow meter 13 to be tested is evaluated by measuring and calculating the difference between the output results of the flow values of the standard flow meter 12 and the flow meter 13 to be tested.

When the device is used for quick filling, all valves of the main loop, the fifth valve 16 and the seventh valve 18 of the test loop are opened, the operation console 26 controls the variable frequency pump 2 of the main loop to work, and controls the first electromagnetic valve 19 and the second electromagnetic valve 20 of the test loop to be switched on and off. The variable frequency pump 2 pumps water out of the water tank 1, after the water flow is stabilized by the pressure stabilizing tank 3, one part of the water flow flows back to the water tank 1 after flowing through the electromagnetic flowmeter 4, and the other part of the water flow enters the test loop. By controlling the first electromagnetic valve 19 and the second electromagnetic valve 20 to be switched on and off, the other part of the water flow flows into the measuring cup 14 through the standard flowmeter 12, the to-be-detected flowmeter 13 and the second branch 25, and the quick filling is realized. When the quick filling performance of the device is detected, the first electromagnetic valve 19 and the second electromagnetic valve 20 are controlled to switch for a plurality of times in the same time, and the quality of the water in the measuring cup 14 in each switching time is recorded, so that the judgment can be made.

The standard flowmeter 12 in the main loop is used as an extremely important component in the device, and the important explanation is that the standard flowmeter plays the following roles:

1. when the measurement precision of the detected flowmeter is detected, the reference signal source is used as a reference signal source for calibrating the detected flowmeter and is compared with the flow output value of the detected flowmeter to judge the performance excellence of the detected flowmeter;

2. monitoring the pipeline flow in the test loop in real time;

3. and can be used as a detected signal when the flow stability of the device is detected.

It should be noted that many variations and modifications of the embodiments of the present invention are possible, which are fully described, and are not limited to the specific examples of the above embodiments. The above embodiments are merely illustrative of the present invention and are not intended to limit the present invention. In conclusion, the scope of the present invention should include those changes or substitutions and modifications which are obvious to those of ordinary skill in the art.

Claims (10)

1. The dynamic flow controller detection device is characterized by comprising a main loop and a test loop;

the main loop comprises a large-diameter pipeline, a water tank, a variable frequency pump, a pressure stabilizing tank and an electromagnetic flowmeter, the water tank, the variable frequency pump, the pressure stabilizing tank and the electromagnetic flowmeter are sequentially connected and connected back to the water tank through the large-diameter pipeline to form a circulating loop, a PID closed-loop controller is arranged in a frequency converter of the variable frequency pump, and a feedback signal is sent from the electromagnetic flowmeter;

the testing loop comprises a small-diameter pipeline, a standard flowmeter, a detected flowmeter, a measuring cup, an electronic scale, a first electromagnetic valve and a second electromagnetic valve, wherein the standard flowmeter and the detected flowmeter are connected through the small-diameter pipeline, the small-diameter pipeline connected with a water inlet of the standard flowmeter is connected to the large-diameter pipeline between a pressure stabilizing tank and the electromagnetic flowmeter of a main loop, the small-diameter pipeline connected with a water outlet of the detected flowmeter is divided into a first branch and a second branch, the first branch is connected to a water tank, a water outlet of the second branch is arranged above the measuring cup, the measuring cup is placed on the electronic scale, the first electromagnetic valve and the second electromagnetic valve are sequentially installed on the second branch, the first electromagnetic valve is a normally open electromagnetic valve, and the second electromagnetic valve is a normally closed electromagnetic valve.

2. The dynamic flow controller testing device of claim 1, wherein the main circuit further comprises a first valve, a second valve, a check valve, a third valve, and a fourth valve, the first valve being installed on the large-diameter pipe between the water tank and the inverter pump, the check valve and the second valve being installed on the large-diameter pipe between the inverter pump and the surge tank, the third valve being installed on the large-diameter pipe between the surge tank and the electromagnetic flow meter, and the fourth valve being installed on the large-diameter pipe between the electromagnetic flow meter and the water tank.

3. The dynamic flow controller detection device of claim 1, wherein the main circuit further comprises a first bellows and a second bellows, and the first bellows and the second bellows are respectively installed on a water inlet and a water outlet of the variable frequency pump.

4. The dynamic flow controller detection device of claim 1, wherein the primary circuit further comprises a first pressure sensor, a second pressure sensor, a third pressure sensor; the first pressure sensor is arranged on a large-pipe-diameter pipeline between a variable-frequency pump and a pressure stabilizing tank of the main loop; big pipe diameter pipeline between surge tank and the electromagnetic flowmeter of major loop falls into first horizontal segment, vertical section, second horizontal segment in proper order, first horizontal segment is connected with the delivery port of surge tank, the second horizontal segment is connected with electromagnetic flowmeter's water inlet to connect the little pipe diameter pipeline that the standard flowmeter water inlet of test loop is connected on the second horizontal segment, second pressure sensor installs on first horizontal segment, third pressure sensor installs on the second horizontal segment.

5. The dynamic flow controller detection device according to claim 1, wherein the pipe diameter of the large-diameter pipe of the main loop is DN50, the electromagnetic flow meter of the main loop is DN50 electromagnetic flow meter, and the pipe diameter of the small-diameter pipe of the test loop is DN 25.

6. The dynamic flow controller test device of claim 1, wherein the standard flow meter of the primary loop is an RHM06 mass flow meter.

7. The dynamic flow controller testing device of claim 1, wherein the test loop further comprises a fifth valve, a sixth valve, and a seventh valve, the fifth valve is installed on the small-diameter pipeline connected to the water inlet of the standard flowmeter, and the sixth valve and the seventh valve are installed on the first branch and the second branch, respectively.

8. The dynamic flow controller testing device of claim 1, wherein the testing circuit further comprises a fourth pressure sensor and a fifth pressure sensor, and the fourth pressure sensor and the fifth pressure sensor are respectively installed on the front side and the rear side of the first solenoid valve and the second solenoid valve on the second branch.

9. The dynamic flow controller test device of claim 1, wherein the electromagnetic flow meter of the main loop and the standard flow meter of the test loop are mounted on a calibration stand.

10. The dynamic flow controller detection device of any one of claims 1 to 9, further comprising a console.

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