CN220812190U - Be used for ultra-thin float electronic glass kiln to press and draw automatic drainage device of pressure pipe - Google Patents
Be used for ultra-thin float electronic glass kiln to press and draw automatic drainage device of pressure pipe Download PDFInfo
- Publication number
- CN220812190U CN220812190U CN202322605368.8U CN202322605368U CN220812190U CN 220812190 U CN220812190 U CN 220812190U CN 202322605368 U CN202322605368 U CN 202322605368U CN 220812190 U CN220812190 U CN 220812190U
- Authority
- CN
- China
- Prior art keywords
- pipe
- pressure guiding
- electromagnetic valve
- drainage device
- automatic drainage
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
- 239000011521 glass Substances 0.000 title claims abstract description 22
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 104
- 239000007788 liquid Substances 0.000 claims abstract description 34
- 238000002844 melting Methods 0.000 claims abstract description 23
- 230000008018 melting Effects 0.000 claims abstract description 23
- 239000000463 material Substances 0.000 claims description 6
- 229910000831 Steel Inorganic materials 0.000 claims description 4
- 239000010959 steel Substances 0.000 claims description 4
- 238000001514 detection method Methods 0.000 abstract description 7
- 238000003825 pressing Methods 0.000 description 14
- 229910001220 stainless steel Inorganic materials 0.000 description 6
- 239000010935 stainless steel Substances 0.000 description 6
- 230000001960 triggered effect Effects 0.000 description 5
- 230000001360 synchronised effect Effects 0.000 description 4
- 238000004519 manufacturing process Methods 0.000 description 3
- 230000009286 beneficial effect Effects 0.000 description 2
- 210000000481 breast Anatomy 0.000 description 2
- 238000000034 method Methods 0.000 description 2
- 238000012544 monitoring process Methods 0.000 description 2
- 239000002994 raw material Substances 0.000 description 2
- ZOXJGFHDIHLPTG-UHFFFAOYSA-N Boron Chemical compound [B] ZOXJGFHDIHLPTG-UHFFFAOYSA-N 0.000 description 1
- 238000006124 Pilkington process Methods 0.000 description 1
- QVGXLLKOCUKJST-UHFFFAOYSA-N atomic oxygen Chemical compound [O] QVGXLLKOCUKJST-UHFFFAOYSA-N 0.000 description 1
- 229910052796 boron Inorganic materials 0.000 description 1
- 238000005260 corrosion Methods 0.000 description 1
- 230000007797 corrosion Effects 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- JEIPFZHSYJVQDO-UHFFFAOYSA-N iron(III) oxide Inorganic materials O=[Fe]O[Fe]=O JEIPFZHSYJVQDO-UHFFFAOYSA-N 0.000 description 1
- 238000005259 measurement Methods 0.000 description 1
- 239000006060 molten glass Substances 0.000 description 1
- 229910052760 oxygen Inorganic materials 0.000 description 1
- 239000001301 oxygen Substances 0.000 description 1
- 239000000779 smoke Substances 0.000 description 1
- 239000002699 waste material Substances 0.000 description 1
Landscapes
- Waste-Gas Treatment And Other Accessory Devices For Furnaces (AREA)
Abstract
The automatic drainage device for the pressure guiding pipes of the ultra-thin float electronic glass kiln comprises a melting kiln, a kiln pressure detection system and pressure guiding pipes, wherein a first pressure guiding pipe and a second pressure guiding pipe are arranged on the walls on two sides of the melting kiln, a third pressure guiding pipe is horizontally communicated between the first pressure guiding pipe and the second pressure guiding pipe, a first ball valve, a first electromagnetic valve and a first water collecting tank are arranged below the third pressure guiding pipe on the first pressure guiding pipe and the second pressure guiding pipe in sequence downwards, a first liquid level sensor is arranged inside the first water collecting tank, a first drain pipe is arranged at the lower end of the first water collecting tank, a second electromagnetic valve is arranged on the first drain pipe, a fourth pressure guiding pipe is communicated below the third pressure guiding pipe, the kiln pressure detection system, the second ball valve, the third electromagnetic valve and the second water collecting tank are arranged on the fourth pressure guiding pipe downwards in sequence, a second liquid level sensor is arranged inside the second water collecting tank, a second drain pipe is arranged at the lower end of the second water collecting tank, and a fourth electromagnetic valve is arranged on the second drain pipe; the device realizes the collection and automatic discharge of condensed water.
Description
Technical Field
The utility model relates to the field of ultrathin float electronic glass production, in particular to an automatic drainage device for an ultrathin float electronic glass kiln pressure guiding and pressing pipe.
Background
In the production line of ultrathin float electronic glass, glass raw materials are heated to molten glass in a melting furnace, the real-time monitoring of the pressure in the furnace is extremely important, and the change of the furnace pressure not only affects the adjustment of process parameters, but also directly reflects the use safety of the melting furnace.
In the design of the pressure guiding pipe of the melting furnace in the past, glass raw materials and smoke floating in the melting furnace can enter the pressure guiding pipe, condensed water is generated when high-temperature steam in the melting furnace meets the pipe wall of the low-temperature pressure guiding pipe outside the melting furnace, the mixed condensed water exists in the pipe for a long time, corrosion of the pipe can be caused, so that the pipe is blocked, and when the pressure guiding pipe is blocked to a certain extent, the measurement of the melting furnace pressure can be influenced, so that the part of the corroded pipe needs to be replaced periodically. And the kiln pressure pipes are staggered with other pipelines nearby, so that the operation space is limited, the kiln pressure pipes are close to the melting kiln, the temperature is high, the replacement difficulty is high, and the time and the labor are wasted.
To cope with this phenomenon, it is necessary to redesign the pipeline, separate the condensed water mixed with the waste from the main pipeline of the pressure guiding pipe, and collect and process separately, and at the same time, avoid the influence on the detection of kiln pressure.
For example, CN111056730a discloses a kiln pressure detection control system for a high boron glass total oxygen kiln, which comprises a melting kiln, the melting kiln is provided with a melting kiln breast wall, a pressure guiding position is arranged on the melting kiln breast wall, and the system further comprises: the system is mainly used for detecting kiln pressure, also has the mentioned discharge of condensed water, is mainly or artificially discharged after being monitored and found by the industrial computer, does not have an automatic discharge system, or has monitoring capability to cause untimely discharge of the condensed water and blockage of the pressure guiding pipe, thereby causing unstable kiln pressure.
Disclosure of Invention
The utility model aims to solve the technical problem of providing the automatic drainage device for the pressure guiding pipe of the ultra-thin float electronic glass kiln, which realizes the collection and automatic drainage of condensed water on the premise of not influencing the kiln pressure, solves the problem of blockage of the pressure guiding pipe and ensures the stability of the kiln pressure.
In order to solve the technical problems, the utility model adopts the following technical scheme: the utility model provides an automatic drainage device of pressure pipe is drawn to pressure to electronic glass kiln for ultra-thin float process, including the melting furnace, kiln pressure detecting system and draw the pressure pipe, the melting furnace both sides wall mount has first pressure pipe, the second draws the pressure pipe, the level intercommunication has the third to draw between first pressure pipe and the second pressure pipe draws the pressure pipe, first ball valve is all installed down in proper order to first pressure pipe and second pressure pipe under the third pressure pipe, first solenoid valve, first water catch tank inside is provided with first level sensor, first water catch tank lower extreme is provided with first drain pipe, be provided with the second solenoid valve on the first drain pipe, third draws pressure pipe below intercommunication has the fourth to draw the pressure pipe, kiln pressure detecting system is installed down in proper order on the fourth pressure pipe, the second ball valve, the third solenoid valve, the second water catch tank, second water catch tank is provided with second level sensor in the second water catch tank inside, second water catch tank lower extreme is provided with the second drain pipe, be provided with the fourth solenoid valve on the second drain pipe.
In the preferred scheme, the first pressure guiding pipe and the second pressure guiding pipe adopt steel pipes with the same materials and the same specifications.
In the preferred scheme, the first pressure guiding pipe, the second pressure guiding pipe, the third pressure guiding pipe, the fourth pressure guiding pipe, the first water collecting tank, the first drain pipe, the second water collecting tank and the second drain pipe are made of stainless steel pipes, and the first ball valve, the first electromagnetic valve, the second ball valve, the third electromagnetic valve and the fourth electromagnetic valve are made of stainless steel materials.
In the preferred scheme, the first ball valve and the second ball valve are manual ball valves and are normally open for emergency closing.
In the preferred scheme, the first liquid level sensor and the second liquid level sensor are respectively provided with an upper floating ball and a lower floating ball.
In the preferred scheme, the first water collection tank at the bottommost end of the first pressure guiding pipe and the second pressure guiding pipe is provided with the same height, and the first water drainage pipe is also provided with the same height.
In the preferred scheme, the upper floating ball and the lower floating ball of the first liquid level sensor in the first water collecting tank at the bottommost end of the first pressure guiding pipe and the second pressure guiding pipe are respectively provided with equal heights, and the two upper floating balls are equal in height and the two lower floating balls are equal in height.
In a preferred scheme, the second water collection tank is arranged at a lower height than the first water collection tank.
In a preferred embodiment, the second drain pipe is arranged at a lower level than the first drain pipe.
In a preferred scheme, the first electromagnetic valve and the second electromagnetic valve are synchronously arranged, namely the second electromagnetic valve is synchronously closed when the first electromagnetic valve is opened, the second electromagnetic valve is synchronously opened when the first electromagnetic valve is closed, and the third electromagnetic valve and the fourth electromagnetic valve are synchronously arranged.
In the preferred scheme, the first electromagnetic valve and the third electromagnetic valve are normally closed, and the second electromagnetic valve and the fourth electromagnetic valve are normally open.
The utility model provides an automatic drainage device for an ultrathin float electronic glass kiln pressure guiding pipe, which has the following beneficial effects:
1. The utility model has the advantages of exquisite and practical design and simple and reliable structure, and realizes the collection and automatic discharge of condensed water on the premise of not influencing kiln pressure;
2. The utility model solves the problems of rust and blockage of the pressure guiding pipe caused by inaccurate control of manual discharge opportunity, and ensures the stability and safety of kiln pressure;
3. The utility model has simple operation, automatically triggers the switch valve to collect and discharge, saves manual operation, saves labor cost and ensures personal safety;
4. the utility model has low manufacturing cost, strong operability and high practical and popularization value.
Drawings
The utility model is further described below with reference to the accompanying drawings and examples of implementation:
FIG. 1 is a schematic diagram of the structure of the present utility model;
In the figure: the kiln comprises a melting furnace 1, a first pressure guiding pipe 2, a second pressure guiding pipe 3, a third pressure guiding pipe 4, a fourth pressure guiding pipe 5, a first ball valve 6, a first electromagnetic valve 7, a first water collecting tank 8, a first liquid level sensor 9, a first drain pipe 10, a second electromagnetic valve 11, a second ball valve 12, a third electromagnetic valve 13, a second water collecting tank 14, a second liquid level sensor 15, a second drain pipe 16, a fourth electromagnetic valve 17 and a kiln pressure detection system 18.
Detailed Description
As shown in fig. 1, the automatic drainage device for the kiln pressure guiding and pressing pipes of the ultra-thin float electronic glass comprises a melting kiln 1, a kiln pressure detection system 18 and guiding and pressing pipes, wherein a first guiding and pressing pipe 2 and a second guiding and pressing pipe 3 are installed on the walls of two sides of the melting kiln 1, a third guiding and pressing pipe 4 is horizontally communicated between the first guiding and pressing pipe 2 and the second guiding and pressing pipe 3, a first ball valve 6, a first electromagnetic valve 7 and a first water collecting tank 8 are sequentially installed below the third guiding and pressing pipe 4 on the first guiding and pressing pipe 2 and the second guiding and pressing pipe 3 downwards, a first liquid level sensor 9 is arranged in the first water collecting tank 8, a first drainage pipe 10 is arranged at the lower end of the first water collecting tank 8, a second electromagnetic valve 11 is arranged on the first drainage pipe 10, a fourth guiding and pressing pipe 5 is communicated below the third guiding and pressing pipe 4, a kiln pressure detection system 18, a second ball valve 12, a third electromagnetic valve 13 and a second water collecting tank 14 are sequentially installed downwards on the fourth guiding and pressing pipe 5, a second liquid level sensor 15 is arranged inside the second water collecting tank 14, and a fourth electromagnetic valve 16 is arranged at the lower end of the second water collecting tank 16.
In this embodiment, the first pressure guiding pipe 2 and the second pressure guiding pipe 3 are made of steel pipes of the same material and the same specification; the first pressure guiding pipe 2, the second pressure guiding pipe 3, the third pressure guiding pipe 4, the fourth pressure guiding pipe 5, the first water collecting tank 8, the first water draining pipe 10, the second water collecting tank 14 and the second water draining pipe 16 are made of stainless steel, and the first ball valve 6, the first electromagnetic valve 7, the second electromagnetic valve 11, the second ball valve 12, the third electromagnetic valve 13 and the fourth electromagnetic valve 17 are made of stainless steel; the first ball valve 6 and the second ball valve 12 are manual ball valves and are normally open for emergency closing; the first liquid level sensor 9 and the second liquid level sensor 15 are respectively provided with an upper floating ball and a lower floating ball; the first water collection tank 8 at the lowest ends of the first pressure guiding pipe 2 and the second pressure guiding pipe 3 is provided with the same height, and the first water drainage pipe 10 is also provided with the same height; the upper floating balls and the lower floating balls of the first liquid level sensor 9 in the first water collection tank 8 at the bottommost ends of the first pressure guiding pipe 2 and the second pressure guiding pipe 3 are respectively arranged at equal heights, and the two upper floating balls are at equal heights, and the two lower floating balls are at equal heights; the second water collection tank 14 is arranged at a lower height than the first water collection tank 8; the second drain pipe 16 is disposed at a lower level than the first drain pipe 10; in a preferred scheme, the first electromagnetic valve 7 and the second electromagnetic valve 11 are synchronous, namely, the second electromagnetic valve 11 is synchronous to be closed when the first electromagnetic valve 7 is opened, the second electromagnetic valve 11 is synchronous to be opened when the first electromagnetic valve 7 is closed, and the third electromagnetic valve 13 and the fourth electromagnetic valve 17 are synchronous in the same way; the first electromagnetic valve 7 and the third electromagnetic valve 13 are normally closed, and the second electromagnetic valve 11 and the fourth electromagnetic valve 17 are normally open.
The specific use is as follows:
Example 1: the first ball valve 6 and the second ball valve 12 below the extending pipelines of the first pressure guiding pipe 2, the second pressure guiding pipe 3 and the fourth pressure guiding pipe 5 are normally open, the first electromagnetic valve 7 and the third electromagnetic valve 13 at the inlet of the first water collecting tank 8 and the second water collecting tank 14 are opened, the second electromagnetic valve 11 and the fourth electromagnetic valve 17 at the outlet of the first water collecting tank 8 and the second water collecting tank 14 are closed, condensed water formed in the first pressure guiding pipe 2 and the second pressure guiding pipe 3 outside the melting furnace 1 flows to the first water collecting tank 8 and the second water collecting tank 14 along the pipe wall, when the water collecting level reaches the floating ball positions of the first liquid level sensor 9 and the second liquid level sensor 15, the first liquid level sensor 9 and the second liquid level sensor 15 are triggered to respectively send signals to the first electromagnetic valve 7, the second electromagnetic valve 11, the third electromagnetic valve 13 and the fourth electromagnetic valve 17, the first electromagnetic valve 7 and the third electromagnetic valve 13 are closed, the second electromagnetic valve 11 and the fourth electromagnetic valve 17 are opened, the first water collecting tank 8 and the second water collecting tank 14 begin to drain, the water level of the first water collecting tank 8 and the second water collecting tank 14 reach the floating ball position below the first liquid level sensor 9 and the second liquid level sensor 15, the first liquid level sensor 9 and the second liquid level sensor 15 are triggered to respectively send signals to the first electromagnetic valve 7, the second electromagnetic valve 11, the third electromagnetic valve 13 and the fourth electromagnetic valve 17, the first electromagnetic valve 7 and the third electromagnetic valve 13 are opened, the second electromagnetic valve 11 and the fourth electromagnetic valve 17 are closed, and the first water collecting tank 8 and the second water collecting tank 14 continue to collect water.
Example 2: the first ball valve 6 and the second ball valve 12 below the extending pipelines of the first pressure guiding pipe 2, the second pressure guiding pipe 3 and the fourth pressure guiding pipe 5 are normally open, the first electromagnetic valve 7 and the third electromagnetic valve 13 at the inlet of the first water collecting tank 8 and the second water collecting tank 14 are opened, the second electromagnetic valve 11 and the fourth electromagnetic valve 17 at the outlet of the first water collecting tank 8 and the second water collecting tank 14 are closed, condensed water formed in the first pressure guiding pipe 2 and the second pressure guiding pipe 3 outside the melting furnace 1 flows to the first water collecting tank 8 and the second water collecting tank 14 along the pipe wall, the first water collecting tank 8 is higher than the second water collecting tank 14, the first pressure guiding pipe 2 and the second pressure guiding pipe 3 are main pressure guiding pipes, the water of the third pressure guiding pipe 4 can reach the fourth pressure guiding pipe 5 only through the third pressure guiding pipe 4 horizontally arranged, the water collecting level firstly reaches the floating ball position on the first liquid level sensor 9, triggering a first liquid level sensor 9 to send a signal to a first electromagnetic valve 7 and a second electromagnetic valve 11, wherein the first electromagnetic valve 7 is closed, meanwhile, the second electromagnetic valve 11 is opened, the first water collecting tank 8 starts to drain water, a second liquid level sensor 15 is not triggered, a third electromagnetic valve 13 is still opened, a fourth electromagnetic valve 17 is still closed, at the moment, water in the first pressure guiding pipe 2 and the second pressure guiding pipe 3 is shunted to the third pressure guiding pipe 4 and the fourth pressure guiding pipe 5, condensed water is accumulated in a second water collecting tank 14, the water level of the second water collecting tank 14 slowly rises, the first water collecting tank 8 drains to a floating ball position below the first liquid level sensor 9, triggering the first liquid level sensor 9 to send a signal to the first electromagnetic valve 7 and the second electromagnetic valve 11, the first electromagnetic valve 7 is opened, meanwhile, the second electromagnetic valve 11 is closed, and the first water collecting tank 8 continues to collect water; when the water level of the second water collecting tank 14 rises to the floating ball position on the second liquid level sensor 15, the second liquid level sensor 15 is triggered to send signals to the third electromagnetic valve 13 and the fourth electromagnetic valve 17, the third electromagnetic valve 13 is closed, the fourth electromagnetic valve 17 is opened, the second water collecting tank 14 starts to drain water, the water level of the second water collecting tank 14 reaches the floating ball position under the second liquid level sensor 15, the second liquid level sensor 15 is triggered to send signals to the third electromagnetic valve 13 and the fourth electromagnetic valve 17, the third electromagnetic valve 13 is opened, the fourth electromagnetic valve 17 is closed, and the second water collecting tank 14 continues to collect water.
In the preferred scheme, a third pressure guiding pipe 4 is horizontally communicated between the first pressure guiding pipe 2 and the second pressure guiding pipe 3, and the first pressure guiding pipe 2, the second pressure guiding pipe 3 and the third pressure guiding pipe 4 are formed into a communicating vessel by the arrangement, so that the consistency of pressures at two sides of the first pressure guiding pipe 2 and the second pressure guiding pipe 3 is ensured, and the stability of kiln pressures at two sides of the kiln 1 is ensured.
In a preferred scheme, the first ball valve 6 and the second ball valve 12 are manual ball valves and are normally open; the first electromagnetic valve 7 and the third electromagnetic valve 13 are set to be normally closed, and the second electromagnetic valve 11 and the fourth electromagnetic valve 17 are set to be normally open; the arrangement accords with the condensate water collection rule, ensures the continuity of condensate water collection, simultaneously avoids frequent opening and closing of the valve, and integrally prolongs the service life of the device.
In the preferred scheme, the first ball valve 6 and the first electromagnetic valve 7 are respectively and sequentially installed below the third pressure guiding pipe 4 on the first pressure guiding pipe 2 and the second pressure guiding pipe 3, the second ball valve 12 and the third electromagnetic valve 13 are respectively and sequentially installed on the fourth pressure guiding pipe 5 and the first pressure guiding pipe 2 and the second pressure guiding pipe 3 downwards, the first ball valve 6 and the second ball valve 12 are manual ball valves and are normally opened for emergency closing, the above double-switch valve is electrically operated, one manual and double-insurance, the reliability of the device is fully ensured, and the safety of the device is improved.
In the preferred scheme, the first pressure guiding pipe 2 and the second pressure guiding pipe 3 are made of steel pipes with the same material and the same specification; the heights of the first water collection tanks 8 at the lowest ends of the first pressure guiding pipes 2 and the second pressure guiding pipes 3 are equal, and the heights of the first water drainage pipes 10 are equal; in the preferred scheme, the upper floating balls and the lower floating balls in the first water collection tank 8 at the bottommost ends of the first pressure guiding pipe 2 and the second pressure guiding pipe 3 are respectively arranged at equal heights, and the two upper floating balls are at equal heights, and the two lower floating balls are at equal heights; the first electromagnetic valve 7 and the second electromagnetic valve 11 are synchronously arranged, namely the second electromagnetic valve 11 is synchronously closed when the first electromagnetic valve 7 is opened, the second electromagnetic valve 11 is synchronously opened when the first electromagnetic valve 7 is closed, and the third electromagnetic valve 13 and the fourth electromagnetic valve 17 are synchronously arranged; the arrangement further ensures the synchronism of the first pressure guiding pipe 2 and the second pressure guiding pipe 3 at the two sides of the kiln 1, thereby further ensuring the stability and safety of kiln pressures at the two sides of the kiln 1.
In a preferred scheme, the first pressure guiding pipe 2, the second pressure guiding pipe 3, the third pressure guiding pipe 4, the fourth pressure guiding pipe 5, the first water collecting tank 8, the first water draining pipe 10, the second water collecting tank 14 and the second water draining pipe 16 are made of stainless steel pipes, and the first ball valve 6, the first electromagnetic valve 7, the second electromagnetic valve 11, the second ball valve 12, the third electromagnetic valve 13 and the fourth electromagnetic valve 17 are made of stainless steel materials; the arrangement further ensures that the inside of the device is not rusted, thereby further solving the problem of blockage of the pressure guiding pipe pipeline system, being beneficial to the operation in high-temperature environment and further prolonging the service life of the device.
In conclusion, the utility model has the advantages of exquisite and practical design, simple and reliable structure, thoroughly solves the problem that the safety of kiln burning is affected by the blockage of the pressure guiding pipe, realizes the collection and automatic discharge of condensed water on the premise of not affecting kiln pressure, omits manual operation, saves labor cost, ensures the safety of personnel and kiln burning, and prolongs the overall service life of kiln burning and devices.
Claims (9)
1. The utility model provides an automatic drainage device of pressure pipe is drawn to ultra-thin float electronic glass kiln pressure, includes melting furnace (1), kiln pressure detecting system (18) and draws pressure pipe, its characterized in that: install on the wall of melting furnace (1) both sides and draw and press pipe (2), second draws and press pipe (3), first drawing and press pipe (2) and second draw and press pipe (3) between the level intercommunication have third draw and press pipe (4), first drawing press pipe (2) and second draw and press pipe (3) on the third draw and press pipe (4) under, all install first ball valve (6) downwards in proper order, first solenoid valve (7), first header tank (8) inside is provided with first liquid level sensor (9), first header tank (8) lower extreme is provided with first drain pipe (10), be provided with second solenoid valve (11) on first drain pipe (10), third draws and press pipe (4) below intercommunication have fourth to draw and press pipe (5), kiln pressure detecting system (18) are installed down in proper order on fourth drawing press pipe (5), second ball valve (12), third solenoid valve (13), second header tank (14) inside is provided with second liquid level sensor (15), second header tank (16) are provided with second drain pipe (16) down.
2. The automatic drainage device for the ultra-thin float electronic glass kiln pressure guiding tube according to claim 1, wherein the automatic drainage device is characterized in that: the first pressure guiding pipe (2) and the second pressure guiding pipe (3) are made of steel pipes of the same material and the same specification.
3. The automatic drainage device for the ultra-thin float electronic glass kiln pressure guiding tube according to claim 1, wherein the automatic drainage device is characterized in that: the first ball valve (6) and the second ball valve (12) are manual ball valves and are normally open.
4. The automatic drainage device for the ultra-thin float electronic glass kiln pressure guiding tube according to claim 1, wherein the automatic drainage device is characterized in that: the first liquid level sensor (9) and the second liquid level sensor (15) are respectively provided with an upper floating ball and a lower floating ball.
5. The automatic drainage device for the ultra-thin float electronic glass kiln pressure guiding tube according to claim 1, wherein the automatic drainage device is characterized in that: the heights of the first water collection tanks (8) at the bottommost ends of the first pressure guiding pipe (2) and the second pressure guiding pipe (3) are equal, and the heights of the first water drainage pipes (10) are equal.
6. The automatic drainage device for the ultra-thin float electronic glass kiln pressure guiding tube according to claim 1, wherein the automatic drainage device is characterized in that: the upper floating balls and the lower floating balls of the first liquid level sensor (9) in the first water collecting tank (8) at the bottommost ends of the first pressure guiding pipe (2) and the second pressure guiding pipe (3) are respectively arranged at equal heights, and the two upper floating balls are equal in height, and the two lower floating balls are equal in height.
7. The automatic drainage device for the ultra-thin float electronic glass kiln pressure guiding tube according to claim 1, wherein the automatic drainage device is characterized in that: the second water collection tank (14) is arranged at a lower height than the first water collection tank (8).
8. The automatic drainage device for the ultra-thin float electronic glass kiln pressure guiding tube according to claim 1, wherein the automatic drainage device is characterized in that: the second drain pipe (16) is arranged at a lower level than the first drain pipe (10).
9. The automatic drainage device for the ultra-thin float electronic glass kiln pressure guiding tube according to claim 1, wherein the automatic drainage device is characterized in that: the first electromagnetic valve (7) and the second electromagnetic valve (11) are synchronously arranged, namely the second electromagnetic valve (11) is synchronously closed when the first electromagnetic valve (7) is opened, the second electromagnetic valve (11) is synchronously opened when the first electromagnetic valve (7) is closed, and the third electromagnetic valve (13) and the fourth electromagnetic valve (17) are synchronously arranged.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202322605368.8U CN220812190U (en) | 2023-09-25 | 2023-09-25 | Be used for ultra-thin float electronic glass kiln to press and draw automatic drainage device of pressure pipe |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202322605368.8U CN220812190U (en) | 2023-09-25 | 2023-09-25 | Be used for ultra-thin float electronic glass kiln to press and draw automatic drainage device of pressure pipe |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN220812190U true CN220812190U (en) | 2024-04-19 |
Family
ID=90678546
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202322605368.8U Active CN220812190U (en) | 2023-09-25 | 2023-09-25 | Be used for ultra-thin float electronic glass kiln to press and draw automatic drainage device of pressure pipe |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN220812190U (en) |
-
2023
- 2023-09-25 CN CN202322605368.8U patent/CN220812190U/en active Active
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CN201162948Y (en) | Full-automatic safety type coal gas dewatering device | |
| CN220812190U (en) | Be used for ultra-thin float electronic glass kiln to press and draw automatic drainage device of pressure pipe | |
| CN109142646B (en) | Automatic sampling detection device of desulfurization absorption tower pH meter of thermal power factory | |
| CN107805678A (en) | A kind of drainage system for discharging State of Blast Furnace internal water accumulation | |
| CN208802845U (en) | Thermal power plant system for recycling sample water | |
| CN205013824U (en) | Take gas collection metering device's air bleeding valve | |
| CN205502170U (en) | Modularization negative pressure station | |
| CN207893428U (en) | A kind of coal gas drainer automatic gas leakage preventing device | |
| CN212273689U (en) | Compressed air gas holder drainage system | |
| CN213066156U (en) | Automatic drainage device for accumulated water in industrial horizontal flue | |
| CN215939522U (en) | Full-automatic energy-saving gas-liquid separation condensed water drainage tank | |
| CN215367638U (en) | Vacuum drainage control device | |
| CN220794504U (en) | Water-draining pressure-taking pipe for melting reaction system | |
| CN220467664U (en) | Water-saving device for heat insulating material hydrophobicity tester | |
| CN2898559Y (en) | Self-shutting drainer | |
| CN2484552Y (en) | Cooler on-line leakage alarm device | |
| CN218713496U (en) | Bury formula initial stage rainwater automatic collection device | |
| CN213749481U (en) | Back flush desulfurization slurry density measuring device | |
| CN215759428U (en) | Landfill gas condensate water drainage device at crossing | |
| CN216410328U (en) | Metallurgical gas conveying pipe network resistance state monitoring and remote early warning system | |
| CN217234856U (en) | Intelligent control detection type leakage-proof gas drainer | |
| CN218962606U (en) | Chemical industry reation kettle that possesses exhaust function | |
| CN217109104U (en) | Air-consumption-free condensate water discharge system | |
| CN218106622U (en) | Non-condensable gas water seal flame retardant device | |
| CN218937506U (en) | Pressure measuring device for detecting water level of water tank at bottom of industrial heating furnace |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| GR01 | Patent grant | ||
| GR01 | Patent grant |