CN215669871U - Full-automatic vacuumizing water supply and drainage system - Google Patents

Abstract

The utility model discloses a full-automatic vacuumizing water supply and drainage system, which comprises a gas-water separation tank, a control cabinet, a first water pump, a second water pump and a water tank, wherein the water tank is provided with a first floating ball switch, a second floating ball switch and a third floating ball switch; a floating ball switch and two valves are adopted to determine the starting condition of the vacuum pump, the valves and the water pump realize an interlocking function, and the other two water pool floating ball switches, the pressure sensor and the other two valves determine the starting and stopping of the water pump, so that the full-automatic control of vacuum and water supply and drainage linkage is realized.

Description

Full-automatic vacuumizing water supply and drainage system

Technical Field

The utility model relates to the field of water supply and drainage, in particular to a full-automatic vacuumizing water supply and drainage system.

Background

The existing water supply and drainage equipment vacuum pumping equipment needs to be provided with a vacuum tank and a gas-water separator, and needs manual control, particularly manual control of a drainage pump, so that the operation is complicated.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a fully-automatic vacuumizing water supply and drainage system.

In order to achieve the purpose, the technical scheme of the utility model is as follows:

a full-automatic vacuumizing water supply and drainage system is characterized by comprising a gas-water separation tank, a control cabinet, a first water pump, a second water pump and a water pool, wherein a first floating ball switch, a second floating ball switch and a third floating ball switch are sequentially arranged on one side of the water pool from bottom to top, the lower part of the water pool is respectively connected with one ends of a first water inlet pipeline and a second water inlet pipeline through a water inlet main pipe, the other end of the first water inlet pipeline is connected with an inlet of the first water pump, the other end of the second water inlet pipeline is connected with an inlet of the second water pump, an outlet of the first water pump is communicated with one end of a main water adding pipe through a first water adding pipeline, an outlet of the second water pump is communicated with one end of the main water adding pipe through a first water adding pipeline, the other end of the main water adding pipe is communicated with the middle part of the gas-water separation tank, the first water adding pipeline is provided with a first valve, the second water adding pipeline is provided with a second valve, the other outlet of the first water pump is connected with one end of a first water outlet pipeline, the other outlet of the second water pump is connected with one end of a second water outlet pipeline, the other ends of the first water outlet pipeline and the second water outlet pipeline are communicated with a water outlet main pipe, the first water outlet pipeline is provided with a third valve, the second water outlet pipeline is provided with a fourth valve, the upper part and the lower part of the gas-water separation tank are communicated through a vacuum pipeline, and the vacuum pipeline is provided with a first vacuum pump and a second vacuum pump which are connected in parallel;

the first water pump, the second water pump, the first valve, the second valve, the third valve, the fourth valve, the first vacuum pump and the second vacuum pump are all controlled by the control cabinet.

Further, the vacuum pipeline comprises an upper vacuum main pipe, a first vacuum pipeline, a second vacuum pipeline and a lower vacuum main pipe, one end of the upper vacuum main pipe is communicated with the upper portion of the gas-water separation tank, the other end of the upper vacuum main pipe is connected with the upper ends of the first vacuum pipeline and the second vacuum pipeline respectively, the lower ends of the first vacuum pipeline and the second vacuum pipeline are connected with one end of the lower vacuum main pipe, the other end of the lower vacuum main pipe is communicated with the lower portion of the gas-water separation tank, the first vacuum pipeline is provided with a first vacuum pump, and the second vacuum pipeline is provided with a second vacuum pump.

Furthermore, the first vacuum pipeline and the second vacuum pipeline are respectively provided with a butterfly valve and an air check valve.

Further, a liquid level sensor is arranged at the upper part of the gas-water separation tank, and a float switch is arranged in the gas-water separation tank.

Furthermore, the first water inlet pipeline and the second water inlet pipeline are both provided with a gate valve.

The utility model adopts a float switch and two valves to determine the starting condition of the vacuum pump, the valves and the water pump realize the interlocking function, and the other two water pool float switches, the pressure sensor and the other two valves determine the starting and stopping of the water pump, thereby realizing the full-automatic control vacuum and water supply and drainage linkage.

Drawings

FIG. 1 is a schematic diagram of the system of the present invention.

Reference numerals:

1 a gas-water separation tank, 2 a control cabinet, 3 a water tank, 4 a first water pump, 5 a second water pump,

6 a first float switch, 7 a second float switch, 8 a third float switch, 9 a water inlet main pipe,

10 a first water inlet pipeline, 11 a second water inlet pipeline, 12 a first water adding pipeline, 13 a second water adding pipeline,

14 a first valve, 15 a second valve, 16 a main water adding pipe, 17 a first water outlet pipeline,

18 second water outlet pipeline, 19 water outlet main pipe, 20 third valve, 21 fourth valve,

22 a first vacuum pump, 23 a second vacuum pump, 24 an upper vacuum manifold, 25 a first vacuum pipeline,

26 second vacuum pipeline, 27 lower vacuum main pipe, 28 liquid level sensor, 29 float switch,

30 gate valves, 31 butterfly valves, 32 air check valves.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The utility model discloses a full-automatic vacuumizing water supply and drainage system which is characterized by comprising a gas-water separation tank 1, a control cabinet 2, a first water pump 4, a second water pump 5 and a water pool 3, wherein a first floating ball switch 6, a second floating ball switch 7 and a third floating ball switch 8 are sequentially arranged on one side of the water pool 3 from bottom to top, the lower part of the water pool 3 is respectively connected with one ends of a first water inlet pipeline 10 and a second water inlet pipeline 11 through a water inlet main pipe 9, the other end of the first water inlet pipeline 10 is connected with an inlet of the first water pump 4, the other end of the second water inlet pipeline 11 is connected with an inlet of the second water pump 5, and the first water inlet pipeline 10 and the second water inlet pipeline 11 are both provided with a gate valve 30.

An outlet of the first water pump 4 is communicated with one end of a main water adding pipe 16 through a first water adding pipe 12, an outlet of the second water pump 5 is communicated with one end of the main water adding pipe 16 through the first water adding pipe 12, the other end of the main water adding pipe 16 is communicated with the middle part of the gas-water separation tank 1, the first water adding pipe 12 is provided with a first valve 14, the second water adding pipe 13 is provided with a second valve 15, the other outlet of the first water pump 4 is connected with one end of a first water outlet pipe 17, the other outlet of the second water pump 5 is connected with one end of a second water outlet pipe 18, the other ends of the first water outlet pipe 17 and the second water outlet pipe 18 are communicated with a water outlet main pipe 19, the first water outlet pipe 17 is provided with a second valve 20, the second water outlet pipe 18 is provided with a fourth valve 21, the upper part and the lower part of the gas-water separation tank 1 are communicated through a vacuum pipe, the vacuum line is provided with a first vacuum pump 22 and a second vacuum pump 23 connected in parallel.

The upper part of the gas-water separation tank 1 is provided with a liquid level sensor 28, a float switch 29 is arranged in the gas-water separation tank 1, and along with the rising of the water level, the rising of the float switch 29 is identified by the liquid level sensor 28.

The liquid level sensor 28, the first water pump 4, the second water pump 5, the first valve 14, the second valve 15, the third valve 20, the fourth valve 21, the first vacuum pump 22 and the second vacuum pump 23 are all controlled by the control cabinet 2.

The vacuum line includes vacuum main 24, first vacuum line 25, second vacuum line 26 and vacuum main 27 down, go up vacuum main 24's one end and the upper portion intercommunication of gas-water separation jar 1, it is connected with first vacuum line 25 and second vacuum line 26's upper end respectively to go up vacuum main 24's the other end, first vacuum line 25 and second vacuum line 26's lower extreme is connected with vacuum main 27's one end down, vacuum main 27's the other end and the lower part intercommunication of gas-water separation jar 1 down, first vacuum line 25 is equipped with first vacuum pump 22, second vacuum line 26 is equipped with second vacuum pump 23. The first vacuum line 25 and the second vacuum line 26 are each provided with a butterfly valve 31 and an air check valve 32.

According to the utility model, the first float switch 6, the float switch 29, the liquid level sensor 28, the first valve 14 and the second valve 15 determine starting and stopping of the first vacuum pump 22 and the second vacuum pump 23, the first valve 14 and the second valve 15 realize an interlocking function with the first water pump 4 and the second water pump 5, and the second float switch 7, the third float switch 8, the pressure sensor, the third valve 20 and the fourth valve 21 determine starting and stopping of the first water pump 4 and the second water pump 5.

When the vacuum pumping is implemented, the gas-water separation tank 1 is filled with water, the first float switch 6 is closed, the first valve 14 and the second valve 15 are opened, the third valve 20 and the fourth valve 21 are closed, the first vacuum pump 22 and the second vacuum pump 23 are started, and when the liquid level of the gas-water separation tank 1 reaches a high liquid level, the first vacuum pump 22 and the second vacuum pump 23 are stopped, so that the vacuum pumping is completed.

And closing the second float switch 7, closing the first valve 14 or the second valve 15, starting the first water pump 4 or the second water pump 5, and gradually opening the corresponding third valve 20 or the fourth valve 21 when the water pump reaches the rated rotating speed to supply and discharge water.

And the third float switch 8 is closed, and the other water pump of the first water pump 4 or the second water pump 5 is started to supply and drain water.

The second float switch 7 is turned off, the first water pump 4 and the second water pump 5 are stopped, the first valve 14 and the second valve 15 are opened, and the third valve 20 and the fourth valve 21 are closed.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the utility model has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (5)

1. A full-automatic vacuumizing water supply and drainage system is characterized by comprising a gas-water separation tank, a control cabinet, a first water pump, a second water pump and a water pool, wherein a first floating ball switch, a second floating ball switch and a third floating ball switch are sequentially arranged on one side of the water pool from bottom to top, the lower part of the water pool is respectively connected with one ends of a first water inlet pipeline and a second water inlet pipeline through a water inlet main pipe, the other end of the first water inlet pipeline is connected with an inlet of the first water pump, the other end of the second water inlet pipeline is connected with an inlet of the second water pump, an outlet of the first water pump is communicated with one end of a main water adding pipe through a first water adding pipeline, an outlet of the second water pump is communicated with one end of the main water adding pipe through a first water adding pipeline, the other end of the main water adding pipe is communicated with the middle part of the gas-water separation tank, the first water adding pipeline is provided with a first valve, the second water adding pipeline is provided with a second valve, the other outlet of the first water pump is connected with one end of a first water outlet pipeline, the other outlet of the second water pump is connected with one end of a second water outlet pipeline, the other ends of the first water outlet pipeline and the second water outlet pipeline are communicated with a water outlet main pipe, the first water outlet pipeline is provided with a third valve, the second water outlet pipeline is provided with a fourth valve, the upper part and the lower part of the gas-water separation tank are communicated through a vacuum pipeline, and the vacuum pipeline is provided with a first vacuum pump and a second vacuum pump which are connected in parallel;

the first water pump, the second water pump, the first valve, the second valve, the third valve, the fourth valve, the first vacuum pump and the second vacuum pump are all controlled by the control cabinet.

2. The water supply and drainage system with full automatic vacuum pumping according to claim 1, wherein the vacuum pipeline comprises an upper vacuum main pipe, a first vacuum pipeline, a second vacuum pipeline and a lower vacuum main pipe, one end of the upper vacuum main pipe is communicated with the upper part of the gas-water separation tank, the other end of the upper vacuum main pipe is respectively connected with the upper ends of the first vacuum pipeline and the second vacuum pipeline, the lower ends of the first vacuum pipeline and the second vacuum pipeline are connected with one end of the lower vacuum main pipe, the other end of the lower vacuum main pipe is communicated with the lower part of the gas-water separation tank, the first vacuum pipeline is provided with a first vacuum pump, and the second vacuum pipeline is provided with a second vacuum pump.

3. A fully automatic vacuum pumping water supply and drainage system as claimed in claim 2, wherein said first vacuum line and said second vacuum line are each provided with a butterfly valve and an air check valve.

4. The fully automatic vacuum pumping water supply and drainage system as claimed in claim 1, wherein a liquid level sensor is arranged at the upper part of the gas-water separation tank, and a float switch is arranged in the gas-water separation tank.

5. The system of claim 1, wherein the first and second inlet lines are provided with a gate valve.

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