CN210485255U - Automatic efficient reliable argon filling system for titanium sponge cooling process - Google Patents

Automatic efficient reliable argon filling system for titanium sponge cooling process Download PDF

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Publication number
CN210485255U
CN210485255U CN201921586142.5U CN201921586142U CN210485255U CN 210485255 U CN210485255 U CN 210485255U CN 201921586142 U CN201921586142 U CN 201921586142U CN 210485255 U CN210485255 U CN 210485255U
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argon
valve
pressure side
argon filling
low
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陈德明
肖自江
肖志海
高文柱
周云英
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Xinjiang Xiangrun New Material Technology Co ltd
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Xinjiang Xiangsheng New Material Technology Co ltd
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Abstract

The utility model relates to an automatic high-efficiency reliable argon filling system in the titanium sponge cooling process, which solves the problem of poor reliability in the prior art, and is characterized in that a plurality of parallel reactors are respectively communicated with argon filling branch pipelines which are connected with a check valve and a control branch valve in series, each argon filling branch pipeline is further connected with a low-pressure side argon filling pipeline which is connected with a low-pressure side check valve and a low-pressure side control valve in series, and the low-pressure side argon filling pipeline is communicated with the outlet of an argon buffer tank; the inlet of the argon buffer tank is communicated with a high-pressure side argon filling pipeline which is connected with a near side control valve, an electric control main valve, a far side control valve and a high-pressure side check valve in series; and the pressure sensor communicated with the top of the argon buffer tank is electrically connected with the electric control main valve through an automatic argon filling controller. The method has the advantages of remarkably saving labor cost, along with high efficiency and reliability.

Description

Automatic efficient reliable argon filling system for titanium sponge cooling process
Technical Field
The utility model relates to an argon filling system for a titanium sponge cooling process, in particular to an automatic high-efficiency reliable argon filling system for a titanium sponge cooling process.
Background
The argon filling in the titanium sponge cooling process is performed by manpower for full-time inspection and argon filling operation, and the problems of high labor cost and poor reliability are obviously caused.
Disclosure of Invention
The utility model aims to overcome the above-mentioned defect of prior art, provide a titanium sponge cooling process's automatic high-efficient reliable argon filling system.
In order to realize the aim, the automatic high-efficiency reliable argon filling system for the titanium sponge cooling process is characterized in that a plurality of parallel reactors are respectively communicated with argon filling branch pipelines of a series check branch valve and a control branch valve, each argon filling branch pipeline is further communicated with a low-pressure side argon filling pipeline of a series low-pressure side check valve and a low-pressure side control valve, and the low-pressure side argon filling pipeline is communicated with the outlet of an argon buffer tank; the inlet of the argon buffer tank is communicated with a high-pressure side argon filling pipeline which is connected with a near side control valve, an electric control main valve, a far side control valve and a high-pressure side check valve in series; and the pressure sensor communicated with the top of the argon buffer tank is electrically connected with the electric control main valve through an automatic argon filling controller. The method has the advantages of remarkably saving labor cost, along with high efficiency and reliability.
As optimization, when the pressure sensor detects that the pressure in the argon buffer tank is lower than the set pressure, the automatic argon filling controller opens the electric control main valve, and high-pressure argon is supplemented to the argon buffer tank through the high-pressure side argon filling pipeline; when the pressure sensor detects that the pressure in the argon buffer tank is higher than the set pressure, the automatic argon filling controller closes the electric control main valve and stops the high-pressure argon from being supplied to the argon buffer tank through the high-pressure side argon filling pipeline.
And as optimization, the high-pressure side argon filling pipeline is communicated with an argon high-pressure gas source.
And as optimization, the top of the argon buffer tank is communicated with an argon barometer parallel to the pressure sensor.
As optimization, the center of the top of the argon buffer tank is communicated with a pressure sensor through a vertical pipe, and one side of the top of the argon buffer tank is communicated with an argon barometer through the vertical pipe.
As optimization, the automatic argon filling controller is a DCS or PLC controller.
As optimization, the inlet and the outlet of the argon buffer tank are respectively positioned on two sides of the upper part of the argon buffer tank body.
As optimization, a check branch valve and a control branch valve are sequentially connected in series in the argon filling branch pipeline from downstream to upstream, and a low-pressure side check valve and a low-pressure side control valve are sequentially connected in series in the low-pressure side argon filling pipeline from downstream to upstream; the high-pressure side argon filling pipeline is sequentially connected with a near side control valve, an electric control main valve, a far side control valve and a high-pressure side check valve in series from downstream to upstream.
As optimization, a check branch valve, a manual control branch valve and an electric control branch valve are connected in series in the argon filling branch pipeline, and a low-pressure side check valve, a low-pressure side manual control valve and a low-pressure side electric control valve are connected in series in the low-pressure side argon filling pipeline; a near-side manual control valve, an electric control main valve, a far-side manual control valve and a high-pressure side check valve are connected in series in the high-pressure side argon filling pipeline; the automatic argon filling controller is electrically connected with the electric control branch valve, the low-voltage side electric control valve, the electric control main valve and the pressure sensor. The automatic argon filling controller switches on and off and adjusts the low-pressure side electric control valve and the electric control branch valve according to the argon filling requirement.
As optimization, a check branch valve, a manual control branch valve and an electric control branch valve are sequentially connected in series in the argon filling branch pipeline from downstream to upstream, and a low-pressure side check valve, a low-pressure side manual control valve and a low-pressure side electric control valve are sequentially connected in series in the low-pressure side argon filling pipeline from downstream to upstream; the high-pressure side argon filling pipeline is sequentially connected with a near-side manual control valve, an electric control main valve, a far-side manual control valve and a high-pressure side check valve in series from downstream to upstream. The automatic argon filling controller switches on and off and adjusts the low-pressure side electric control valve and the electric control branch valve according to the argon filling requirement.
After the technical scheme is adopted, the utility model discloses automatic high-efficient reliable argon filling system of titanium sponge cooling process has and is showing saving the cost of labor, high-efficient reliable advantage.
Drawings
Fig. 1 and 2 are schematic structural diagrams of first and second embodiments of an automatic, efficient and reliable argon filling system for a titanium sponge cooling process according to the present invention.
Detailed Description
In the first embodiment, as shown in fig. 1, the automatic high-efficiency reliable argon filling system for the titanium sponge cooling process of the present invention is that a plurality of parallel reactors 1 are respectively connected to argon filling branch pipelines 41 of a series check branch valve 21 and a control branch valve 31, each argon filling branch pipeline 41 is further connected to a low pressure side argon filling pipeline 42 of a series low pressure side check valve 22 and a low pressure side control valve 32, and the low pressure side argon filling pipeline 42 is connected to the outlet of an argon buffer tank 5; the inlet of the argon buffer tank 5 is communicated with a high-pressure side argon filling pipeline 43 which is connected with the near side control valve 33, the electric control main valve 3, the far side control valve 34 and the high-pressure side check valve 23 in series; and an automatic argon filling controller 6 is electrically connected between a pressure sensor PS communicated with the top of the argon buffer tank 5 and the electric control main valve 3.
When the pressure sensor PS detects that the pressure in the argon buffer tank 5 is lower than the set pressure, the automatic argon filling controller 6 opens the electric control main valve 3, and high-pressure argon is supplied to the argon buffer tank 5 through the high-pressure side argon filling pipeline 43; when the pressure sensor PS detects that the pressure in the argon buffer tank 5 is higher than the set pressure, the automatic argon filling controller 6 closes the electric control main valve 3, and stops the high-pressure argon filling pipeline 43 from supplying high-pressure argon to the argon buffer tank 5. The high-pressure side argon filling pipeline 43 is communicated with an argon high-pressure gas source.
The top of the argon buffer tank 5 is communicated with an argon barometer P which is parallel to the pressure sensor PS. The center of the top of the argon buffer tank 5 is communicated with a pressure sensor PS through a vertical pipe, and one side of the top of the argon buffer tank 5 is communicated with an argon barometer P through the vertical pipe.
The automatic argon filling controller 6 is a DCS or PLC controller. The inlet and the outlet of the argon buffer tank 5 are respectively positioned at two sides of the upper part of the tank body of the argon buffer tank 5. The non-return branch valve 21 and the control branch valve 31 are connected in series in the argon-filling branch line 41 from downstream to upstream, and the low-pressure side non-return valve 22 and the low-pressure side control valve 32 are connected in series in the low-pressure side argon-filling line 42 from downstream to upstream; the high-pressure side argon filling pipeline 43 is connected with the near side control valve 33, the electric control main valve 3, the far side control valve 34 and the high-pressure side check valve 23 in series from the downstream to the upstream. The method has the advantages of remarkably saving labor cost, along with high efficiency and reliability.
In the second embodiment, as shown in fig. 2, the automatic, efficient and reliable argon filling system for the titanium sponge cooling process of the present invention is different from the first embodiment in that: a non-return branch valve 21, a manual control branch valve 71 and an electric control branch valve 72 are connected in series in the argon filling branch pipeline 41, and a low-pressure side non-return valve 22, a low-pressure side manual control valve 73 and a low-pressure side electric control valve 74 are connected in series in the low-pressure side argon filling pipeline 42; a near-side manual control valve 75, an electric control main valve 3, a far-side manual control valve 76 and a high-pressure side check valve 23 are connected in series in the high-pressure side argon filling pipeline 43; the automatic argon filling controller 6 is electrically connected with the electric control branch valve 72, the low-pressure side electric control valve 74, the electric control main valve 3 and the pressure sensor PS. The argon filling branch pipeline 41 is sequentially connected with the check branch valve 21, the manual control branch valve 71 and the electric control branch valve 72 in series from the downstream to the upstream, and the low-pressure side argon filling pipeline 42 is sequentially connected with the low-pressure side check valve 22, the low-pressure side manual control valve 73 and the low-pressure side electric control valve 74 in series from the downstream to the upstream; the high-pressure side argon filling pipeline 43 is connected with the near side manual control valve 75, the electric control main valve 3, the far side manual control valve 76 and the high-pressure side check valve 23 in series from the downstream to the upstream.
When the pressure sensor PS detects that the pressure in the argon buffer tank 5 is lower than the set pressure, the automatic argon filling controller 6 opens the electric control main valve 3, and high-pressure argon is supplied to the argon buffer tank 5 through the high-pressure side argon filling pipeline 43; when the pressure sensor PS detects that the pressure in the argon buffer tank 5 is higher than the set pressure, the automatic argon filling controller 6 closes the electric control main valve 3, and stops the high-pressure argon filling pipeline 43 from supplying high-pressure argon to the argon buffer tank 5. The automatic argon filling controller 6 switches on and off and adjusts the low-pressure side electric control valve 74 and the electric control branch valve 72 according to the argon filling requirement.
After the technical scheme is adopted, the utility model discloses automatic high-efficient reliable argon filling system of titanium sponge cooling process has and is showing saving the cost of labor, high-efficient reliable advantage.

Claims (10)

1. An automatic high-efficiency reliable argon filling system for a titanium sponge cooling process is characterized in that a plurality of parallel reactors are respectively communicated with argon filling branch pipelines of a series check branch valve and a control branch valve, each argon filling branch pipeline is further connected with a low-pressure side argon filling pipeline of a series low-pressure side check valve and a low-pressure side control valve in a common way, and the low-pressure side argon filling pipeline is communicated with an outlet of an argon buffer tank; the inlet of the argon buffer tank is communicated with a high-pressure side argon filling pipeline which is connected with a near side control valve, an electric control main valve, a far side control valve and a high-pressure side check valve in series; and the pressure sensor communicated with the top of the argon buffer tank is electrically connected with the electric control main valve through an automatic argon filling controller.
2. The automatic efficient reliable argon filling system for the titanium sponge cooling process according to claim 1, wherein when the pressure sensor detects that the pressure in the argon buffer tank is lower than the set pressure, the automatic argon filling controller opens the electric control main valve, and the high-pressure side argon filling pipeline supplies high-pressure argon to the argon buffer tank; when the pressure sensor detects that the pressure in the argon buffer tank is higher than the set pressure, the automatic argon filling controller closes the electric control main valve and stops the high-pressure argon from being supplied to the argon buffer tank through the high-pressure side argon filling pipeline.
3. The automatic efficient reliable argon filling system for the titanium sponge cooling process according to claim 2, wherein the high-pressure side argon filling pipeline is communicated with an argon high-pressure gas source.
4. The automatic efficient reliable argon filling system for the titanium sponge cooling process according to claim 1, wherein the top of the argon buffer tank is communicated with an argon barometer which is parallel to the pressure sensor.
5. The automatic efficient reliable argon filling system for the titanium sponge cooling process according to claim 4, wherein the center of the top of the argon buffer tank is communicated with a pressure sensor through a vertical pipe, and one side of the top of the argon buffer tank is communicated with an argon barometer through the vertical pipe.
6. The automatic high-efficiency reliable argon filling system for the titanium sponge cooling process in claim 1, wherein the automatic argon filling controller is a DCS or PLC controller.
7. The automatic efficient reliable argon filling system for the titanium sponge cooling process according to claim 1, wherein the inlet and the outlet of the argon buffer tank are respectively positioned at two sides of the upper part of the body of the argon buffer tank.
8. The automatic efficient reliable argon filling system for the titanium sponge cooling process according to claim 1, wherein a check branch valve and a control branch valve are sequentially connected in series in the argon filling branch pipeline from downstream to upstream, a low-pressure side check valve and a low-pressure side control valve are sequentially connected in series in the low-pressure side argon filling pipeline from downstream to upstream, and a near side control valve, an electric control main valve, a far side control valve and a high-pressure side check valve are sequentially connected in series in the high-pressure side argon filling pipeline from downstream to upstream.
9. The automatic efficient reliable argon filling system for the titanium sponge cooling process according to any one of claims 1 to 8, wherein a check branch valve, a manual control branch valve and an electric control branch valve are connected in series in the argon filling branch pipeline, a low-pressure side check valve, a low-pressure side manual control valve and a low-pressure side electric control valve are connected in series in the low-pressure side argon filling pipeline, and a near-side manual control valve, an electric control main valve, a far-side manual control valve and a high-pressure side check valve are connected in series in the high-pressure side argon filling pipeline; the automatic argon filling controller is electrically connected with the electric control branch valve, the low-voltage side electric control valve, the electric control main valve and the pressure sensor.
10. The automatic efficient reliable argon filling system for the titanium sponge cooling process according to claim 9, wherein the argon filling branch pipeline is sequentially connected with the check branch valve, the manual control branch valve and the electric control branch valve in series from downstream to upstream, and the low pressure side argon filling pipeline is sequentially connected with the low pressure side check valve, the low pressure side manual control valve and the low pressure side electric control valve in series from downstream to upstream; the high-pressure side argon filling pipeline is sequentially connected with a near-side manual control valve, an electric control main valve, a far-side manual control valve and a high-pressure side check valve in series from downstream to upstream.
CN201921586142.5U 2019-09-24 2019-09-24 Automatic efficient reliable argon filling system for titanium sponge cooling process Active CN210485255U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201921586142.5U CN210485255U (en) 2019-09-24 2019-09-24 Automatic efficient reliable argon filling system for titanium sponge cooling process

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201921586142.5U CN210485255U (en) 2019-09-24 2019-09-24 Automatic efficient reliable argon filling system for titanium sponge cooling process

Publications (1)

Publication Number Publication Date
CN210485255U true CN210485255U (en) 2020-05-08

Family

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Family Applications (1)

Application Number Title Priority Date Filing Date
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Country Status (1)

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CN (1) CN210485255U (en)

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Effective date of registration: 20220622

Address after: 839000 south of Yizhou District, Hami City, Xinjiang Uygur Autonomous Region, circular economy industrial park in the south, Southeast of Haruo Railway

Patentee after: XINJIANG XIANGRUN NEW MATERIAL TECHNOLOGY CO.,LTD.

Address before: 839000 heavy industry processing zone, industrial park, Yizhou District, Hami City, Xinjiang Uygur Autonomous Region

Patentee before: XINJIANG XIANGSHENG NEW MATERIAL TECHNOLOGY Co.,Ltd.