CN212252073U - GIS vacuum pumping equipment system for SF6 gas filling - Google Patents

Abstract

The utility model relates to a GIS evacuation filling equipment field, concretely relates to GIS evacuation equipment system of gaseous filling of SF6, including PV 1' vacuum pump, T1 is from sealing joint, T2 is from sealing joint, T3 steel bottle joint, T4 steel bottle joint PV1 vacuum pump and T1 are from sealing joint between through first evacuation pipe connection, T1 is from sealing joint and T3 steel bottle connect between through first gaseous filling pipe connection, T2 is from sealing joint and PV1 vacuum pump between through second evacuation pipe connection, T2 is from sealing joint and T4 steel bottle connect between through second gaseous pipe connection; first evacuation pipeline, first gaseous filling pipeline, second evacuation pipeline and the gaseous filling pipeline of second install the process of a plurality of solenoid valve control evacuation and gas filling respectively to the configuration manometer detects, the utility model discloses possess unmanned on duty, carry out the vacuum survey automatically, carry out leak test, leak test qualified back automatic cycle filling, filling pressure reach functions such as back automatic shutdown automatically.

Description

GIS vacuum pumping equipment system for SF6 gas filling

Technical Field

The utility model relates to a GIS evacuation filling equipment field, concretely relates to GIS evacuation equipment system of gaseous filling of SF 6.

Background

In electric power construction, GIS is widely used due to its advantages of small floor area, safe and reliable operation, short installation period, etc. SF6 gas is used as an important medium for arc extinction and insulation in a GIS, after the GIS is installed and overhauled, the GIS is vacuumized to the required vacuum degree and is subjected to vacuum leakage detection, and the SF6 gas can be injected after the GIS is qualified. The existing GIS vacuumizing filling equipment in the market adopts manual reading and calculation in the aspects of monitoring vacuum degree, vacuum leakage conversion and filling pressure determination, and also adopts a mode of filling to required pressure once during filling, and the mode has the following defects in actual production:

(1) the equipment needs to be attended by a specially-assigned person, so that more labor cost is consumed;

(2) manual reading and calculation errors are large;

(3) the pressure of one-time injection is in place, so that the deformation of the weak part and the parts of the air chamber is easily caused.

SUMMERY OF THE UTILITY MODEL

In view of the technical problem who exists among the prior art, the utility model provides an intelligent GIS evacuation filling equipment with unmanned on duty, automatic vacuum measurement, automatic leak testing, leak testing qualified back automatic cycle filling, filling pressure reach back automatic shutdown is carried out automatically.

In order to realize the technical purpose, the utility model discloses a technical scheme as follows:

a GIS vacuum pumping equipment system for SF6 gas filling comprises a PV 1' vacuum pump, a T1 self-sealing joint, a T2 self-sealing joint, a T3 steel cylinder joint and a T4 steel cylinder joint, wherein the PV1 vacuum pump is connected with the T1 self-sealing joint through a first vacuum pumping pipeline, the T1 self-sealing joint is connected with the T3 steel cylinder joint through a first gas filling pipeline, the T2 self-sealing joint is connected with the PV1 vacuum pump through a second vacuum pumping pipeline, and the T2 self-sealing joint is connected with the T4 steel cylinder joint through a second gas filling pipeline;

from one end of a PV1 vacuum pump to the direction of a T1 self-sealing joint, a VZ1 electromagnetic valve, a VZ2 electromagnetic valve, a VZ3 electromagnetic valve and a VZ4 electromagnetic valve are sequentially arranged on the first vacuum-pumping pipeline;

from the first vacuum-pumping pipeline to the T2 self-sealing joint direction, a VZ7 electromagnetic valve and a VZ8 electromagnetic valve are sequentially installed on the second vacuum-pumping pipeline;

from the T1 to the T3 steel cylinder connector from the sealing connector, a DZY1 pressure gauge, a VZ6 electromagnetic valve and a VZ10 electromagnetic valve are sequentially arranged on the first gas filling pipeline;

and a DZY2 pressure gauge, a VZ9 electromagnetic valve and a VZ11 electromagnetic valve are sequentially arranged on the second gas filling pipeline from the T2 to the joint of the T4 steel cylinder from the sealing joint.

Furthermore, the second vacuum-pumping pipeline is specifically connected in a manner that one end of the second vacuum-pumping pipeline is connected to the T2 self-sealing joint, and the other end of the second vacuum-pumping pipeline is connected to the first vacuum-pumping pipeline between the VZ2 electromagnetic valve and the VZ3 electromagnetic valve.

Furthermore, a parallel gas filling pipeline is connected between the first vacuumizing pipeline and the second gas filling pipeline.

Furthermore, a VZ5 electromagnetic valve is further installed on the parallel gas filling pipeline.

Furthermore, an LC1 vacuum pump, a G1 gas-liquid separation tank and a BZ1 vacuum pressure gauge are sequentially arranged between the VZ1 electromagnetic valve and the VZ2 electromagnetic valve on the first vacuumizing pipeline, and a P1 vacuum probe is further arranged between the VZ3 electromagnetic valve and the VZ4 electromagnetic valve.

Furthermore, a P2 vacuum probe installed between the VZ7 solenoid valve and the VZ8 solenoid valve is further arranged on the second vacuum-pumping pipeline.

Furthermore, a BY1 pressure gauge and a RW1 pressure regulating valve which are arranged between the VZ10 electromagnetic valve and a T3 steel cylinder joint are arranged on the first gas filling pipeline.

Furthermore, a BY2 pressure gauge and an RW2 pressure regulating valve which are arranged between the VZ11 electromagnetic valve and a T4 steel cylinder joint are further arranged on the second gas filling pipeline.

Furthermore, the joint of the T3 steel cylinder and the joint of the T4 steel cylinder are both connected with an air-entrapping steel cylinder, and the bottom of the air-entrapping steel cylinder is provided with a weighing sensor.

Further, based on the above device, the flow of the GIS evacuation and the SF6 gas filling is as follows:

the method comprises the following steps: vacuumizing the position of the T1 self-sealing joint

Starting a PV1 vacuum pump, an LC1 vacuum pump, a VZ1 electromagnetic valve and a VZ2 electromagnetic valve, and then sequentially opening a VZ3 electromagnetic valve and a VZ4 electromagnetic valve, wherein the equipment firstly evacuates a T1 interface in sequence;

step two: leak test

After the T1 self-sealing joint reaches a set vacuum degree, closing the VZ3 electromagnetic valve and opening the VZ4 electromagnetic valve for a leakage test;

step three: vacuumizing the position of the T2 self-sealing joint

When the T1 self-sealing joint is subjected to a leakage test, the VZ7 electromagnetic valve and the VZ8 electromagnetic valve are opened at the time, the T2 self-sealing joint is vacuumized, and after the set vacuum degree is reached, the VZ7 electromagnetic valve is closed, and the VZ8 electromagnetic valve is opened for the leakage test;

step four: regulating the pressure at which the gas is filled

Connecting a T3 steel cylinder joint and a T4 steel cylinder joint with an air-entrapping steel cylinder, using an RW1 pressure-regulating valve and an RW2 pressure-regulating valve to perform pressure regulation, observing readings of a BY1 pressure gauge and a BY2 pressure gauge to the pressure value of equipment needing air inflation, and simultaneously adjusting the upper limit value of a DZY1 pressure gauge and the upper limit value of a DZY2 pressure gauge to the pressure value of the equipment needing air inflation and adjusting the lower limit value of the equipment needing air inflation to 0.3 Mpa;

step five: insufflation of T1 from seal joint

On the premise that the leakage tests of the T1 self-sealing joint and the T2 self-sealing joint are qualified, firstly, the VZ4 electromagnetic valve is closed, and the VZ6 electromagnetic valve is opened to inject gas into the T1 self-sealing joint;

step six: insufflation of T2 from seal joint

After the gas pressure value reaches the lower limit of the set pressure value of the DZY1 pressure gauge, automatically closing the VZ6 electromagnetic valve, stopping gas injection on the T1 self-sealing joint, then closing the VZ8 electromagnetic valve, opening the VZ9 electromagnetic valve to inject gas into the T2 self-sealing joint, after the gas pressure value reaches the lower limit of the set pressure value of the DZY2 pressure gauge, automatically closing the VZ9 electromagnetic valve, and stopping gas injection on the T2 self-sealing joint;

step seven: cyclic insufflation of T1 self-sealing joint and T2 self-sealing joint

Closing the VZ4 electromagnetic valve again, opening the VZ6 electromagnetic valve, and injecting gas into the T1 self-sealing joint; and after the gas pressure value reaches the upper limit of the set pressure value of the DZY1 pressure gauge, automatically closing the VZ6 electromagnetic valve to complete gas injection on the T1 self-sealing joint, then closing the VZ8 electromagnetic valve, and opening the VZ9 electromagnetic valve to inject gas on the T2 interface.

Compared with the prior art, the utility model has the advantages that: above-mentioned each solenoid valve, manometer and air-vent valve detect each other, mutually support, have the function of automated inspection pressure for the solenoid valve can carry out on-off regulation according to the pressure that detects, reaches the purpose of automatic evacuation, automated inspection, automatic filling pressure, so circulate, makes the utility model discloses possess unmanned on duty, carry out vacuum measurement automatically, carry out leak test automatically, leak test qualified back automatic cycle filling, filling pressure reach functions such as back automatic shutdown.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Detailed Description

In order that those skilled in the art may better understand the technical solution of the present invention, the following embodiments are further described.

As shown in fig. 1, a GIS vacuum pumping equipment system for filling SF6 gas includes a PV 1' vacuum pump, a T1 self-sealing joint, a T2 self-sealing joint, a T3 steel cylinder joint, and a T4 steel cylinder joint, where the PV1 vacuum pump is connected to the T1 self-sealing joint through a first vacuum pumping pipe 1, the T1 self-sealing joint is connected to the T3 steel cylinder joint through a first gas filling pipe 2, the T2 self-sealing joint is connected to the PV1 vacuum pump through a second vacuum pumping pipe 3, the T2 self-sealing joint is connected to the T4 steel cylinder joint through a second gas filling pipe 4, and specifically, one end of the second vacuum pumping pipe 3 is connected to the T2 self-sealing joint, and the other end is connected to the first vacuum pumping pipe 1 between the VZ2 solenoid valve and the VZ3 solenoid valve. Preferably, in order to vacuumize the second gas filling pipe 4 before gas filling, a parallel type gas filling pipe 5 is further connected between the first vacuuming pipe 1 and the second gas filling pipe 4, and a VZ5 solenoid valve is further mounted on the parallel type gas filling pipe 5.

From one end of a PV1 vacuum pump to the direction of a T1 self-sealing joint, a VZ1 high vacuum solenoid valve, an LC1 vacuum pump, a G1 gas-liquid separation tank, a BZ1 vacuum pressure gauge, a VZ2 solenoid valve, a VZ3 solenoid valve, a P1 vacuum probe and a VZ4 solenoid valve are sequentially installed on the first vacuum-pumping pipeline 1, wherein the LC1 vacuum pump adopts a Roots vacuum pump;

from the first vacuum-pumping pipeline 1 to the T2 self-sealing joint direction, a VZ7 electromagnetic valve, a P2 vacuum probe and a VZ8 electromagnetic valve are sequentially arranged on the second vacuum-pumping pipeline 3;

from the T1 to the T3 steel cylinder joint direction from the sealed joint, the first gas filling pipeline 2 is sequentially provided with a DZY1 pressure gauge, a VZ6 electromagnetic valve, a VZ10 electromagnetic valve, a BY1 pressure gauge and a RW1 pressure regulating valve;

from the T2 to the T4 steel cylinder joint direction from the sealed joint, a DZY2 pressure gauge, a VZ9 electromagnetic valve, a VZ11 electromagnetic valve, a BY2 pressure gauge and a RW2 pressure regulating valve are sequentially installed on the second gas filling pipeline 4.

Preferably, the joint of the T3 steel cylinder and the joint of the T4 steel cylinder are both connected with a gas filling steel cylinder 6, and the bottom of the gas filling steel cylinder 6 is provided with a weighing sensor 7.

Based on the above-mentioned equipment, the flow of its GIS evacuation and SF6 gas filling is as follows:

the method comprises the following steps: vacuumizing the position of the T1 self-sealing joint

Starting a PV1 vacuum pump, an LC1 vacuum pump, a VZ1 electromagnetic valve and a VZ2 electromagnetic valve, and then sequentially opening a VZ3 electromagnetic valve and a VZ4 electromagnetic valve, wherein the equipment firstly evacuates a T1 interface in sequence;

step two: leak test

After the T1 self-sealing joint reaches a set vacuum degree, closing the VZ3 electromagnetic valve and opening the VZ4 electromagnetic valve for a leakage test;

step three: vacuumizing the position of the T2 self-sealing joint

When the T1 self-sealing joint is subjected to a leakage test, the VZ7 electromagnetic valve and the VZ8 electromagnetic valve are opened at the time, the T2 self-sealing joint is vacuumized, and after the set vacuum degree is reached, the VZ7 electromagnetic valve is closed, and the VZ8 electromagnetic valve is opened for the leakage test;

step four: regulating the pressure at which the gas is filled

Connecting a T3 steel cylinder joint and a T4 steel cylinder joint with an air-entrapping steel cylinder 6, using an RW1 pressure-regulating valve and an RW2 pressure-regulating valve to perform pressure regulation, observing readings of a BY1 pressure gauge and a BY2 pressure gauge to the pressure value of equipment needing air inflation, and simultaneously adjusting the upper limit value and the lower limit value of a DZY1 pressure gauge and a DZY2 pressure gauge to the pressure value and the lower limit value of the equipment needing air inflation to 0.3 Mpa;

step five: insufflation of T1 from seal joint

On the premise that the leakage tests of the T1 self-sealing joint and the T2 self-sealing joint are qualified, firstly, the VZ4 electromagnetic valve is closed, and the VZ6 electromagnetic valve is opened to inject gas into the T1 self-sealing joint;

step six: insufflation of T2 from seal joint

After the gas pressure value reaches the lower limit of the set pressure value of the DZY1 pressure gauge, automatically closing the VZ6 electromagnetic valve, stopping gas injection on the T1 self-sealing joint, then closing the VZ8 electromagnetic valve, opening the VZ9 electromagnetic valve to inject gas into the T2 self-sealing joint, after the gas pressure value reaches the lower limit of the set pressure value of the DZY2 pressure gauge, automatically closing the VZ9 electromagnetic valve, and stopping gas injection on the T2 self-sealing joint; if the gas in the gas-filled steel cylinder at the joint of the T3 steel cylinder joint is detected to be insufficient in weight through the weighing sensor 7, the VZ10 electromagnetic valve is automatically closed to stop gas injection, then the VZ11 electromagnetic valve is automatically opened, the gas-filled steel cylinder 6 at the joint of the T4 steel cylinder joint is used for gas filling, and a warning requirement is given to replace the gas-filled steel cylinder 6.

Step seven: cyclic insufflation of T1 self-sealing joint and T2 self-sealing joint

Closing the VZ4 electromagnetic valve again, opening the VZ6 electromagnetic valve, and injecting gas into the T1 self-sealing joint; and after the gas pressure value reaches the upper limit of the set pressure value of the DZY1 pressure gauge, automatically closing the VZ6 electromagnetic valve to complete gas injection on the T1 self-sealing joint, then closing the VZ8 electromagnetic valve, and opening the VZ9 electromagnetic valve to inject gas on the T2 interface. And after the gas pressure value reaches the upper limit of the set pressure value of the DZY2 pressure gauge, automatically closing the VZ9 electromagnetic valve, and completing gas injection on the T2 self-sealing joint.

Above evacuation and gas filling flow adopt industrial automation control system to control, the utility model adopts the above technical scheme after, possess unmanned on duty, carry out vacuum measurement automatically, carry out leak test automatically, leak test is qualified after automatic cycle filling, filling pressure reach back automatic shutdown function.

The above is to the present invention provides a GIS vacuum pumping equipment system for SF6 gas filling, which is introduced in detail, and the description of the specific embodiment is only used to help understanding the method and the core idea of the present invention. It should be noted that, for those skilled in the art, without departing from the principle of the present invention, the present invention can be further modified and modified, and such modifications and modifications also fall within the protection scope of the appended claims.

Claims (9)

1. A GIS vacuum pumping equipment system for filling SF6 gas is characterized by comprising a PV 1' vacuum pump, a T1 self-sealing joint, a T2 self-sealing joint, a T3 steel cylinder joint and a T4 steel cylinder joint, wherein the PV1 vacuum pump is connected with the T1 self-sealing joint through a first vacuum pumping pipeline, the T1 self-sealing joint is connected with the T3 steel cylinder joint through a first gas filling pipeline, the T2 self-sealing joint is connected with the PV1 vacuum pump through a second vacuum pumping pipeline, and the T2 self-sealing joint is connected with the T4 steel cylinder joint through a second gas filling pipeline;

from one end of a PV1 vacuum pump to the direction of a T1 self-sealing joint, a VZ1 electromagnetic valve, a VZ2 electromagnetic valve, a VZ3 electromagnetic valve and a VZ4 electromagnetic valve are sequentially arranged on the first vacuum-pumping pipeline;

from the first vacuum-pumping pipeline to the T2 self-sealing joint direction, a VZ7 electromagnetic valve and a VZ8 electromagnetic valve are sequentially installed on the second vacuum-pumping pipeline;

from the T1 to the T3 steel cylinder connector from the sealing connector, a DZY1 pressure gauge, a VZ6 electromagnetic valve and a VZ10 electromagnetic valve are sequentially arranged on the first gas filling pipeline;

and a DZY2 pressure gauge, a VZ9 electromagnetic valve and a VZ11 electromagnetic valve are sequentially arranged on the second gas filling pipeline from the T2 to the joint of the T4 steel cylinder from the sealing joint.

2. The SF6 gas filled GIS vacuum extractor system of claim 1, wherein the second vacuum line is connected at one end to the T2 self sealing adapter and at the other end to the first vacuum line between the VZ2 solenoid valve and the VZ3 solenoid valve.

3. The SF6 gas filled GIS evacuation equipment system of claim 1, wherein a parallel gas filling line is further connected between the first evacuation line and the second gas filling line.

4. The GIS evacuation equipment system for SF6 gas filling according to claim 3, wherein said parallel gas filling piping is further installed with VZ5 solenoid valve.

5. The GIS vacuum-pumping equipment system filled with SF6 gas as claimed in claim 1, wherein LC1 vacuum pump, G1 gas-liquid separation tank, BZ1 vacuum pressure gauge are installed between VZ1 solenoid valve and VZ2 solenoid valve on said first vacuum-pumping pipeline, P1 vacuum probe is installed between VZ3 solenoid valve and VZ4 solenoid valve.

6. The SF6 gas filled GIS vacuum extractor system of claim 2, wherein the second vacuum line further includes a P2 vacuum probe mounted between the VZ7 solenoid valve and the VZ8 solenoid valve.

7. The GIS vacuum pumping equipment system for SF6 gas filling according to claim 1, wherein said first gas filling pipe is further provided with BY1 pressure gauge and RW1 pressure regulating valve between VZ10 solenoid valve and T3 cylinder connection.

8. The GIS vacuum pumping apparatus system for SF6 gas filling according to claim 1, wherein said second gas filling pipe is further provided with a BY2 pressure gauge and a RW2 pressure regulating valve between the VZ11 solenoid valve and the T4 cylinder connection.

9. The SF6 gas filled GIS vacuum pumping equipment system as claimed in claim 1, wherein a gas cylinder is connected to each of the T3 and T4 cylinder connectors, and a load cell is disposed at the bottom of the gas cylinder.

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