CN112665622A - Sensor, pipeline, sensor base and using method thereof - Google Patents

Abstract

The invention discloses a sensor base, and belongs to the technical field of sensors. A sensor base comprises a connecting pipe and a sensor body, wherein the connecting pipe is used for being fixed on a pipeline body, threads of the sensor body are arranged on the connecting pipe, an adjusting rod is connected in the connecting pipe in a sliding mode, an impeller blade and a first power blade are fixedly connected to a first rotating shaft, a second power blade and a first gear are fixedly connected to a second rotating shaft, a second gear is fixedly connected to one end of a third rotating shaft, a scraper blade is fixedly connected to the other end of the third rotating shaft, the second gear is meshed with the first gear, a filter screen is fixedly connected in the pipeline body, and the scraper blade is attached to the filter screen; the invention can fix the sensor more firmly, can cool the sensor working in high temperature environment, protects the internal elements of the sensor, can clean and dredge the filter screen in the pipeline, reduces the internal pressure and avoids the danger of pipe explosion.

Description

Sensor, pipeline, sensor base and using method thereof

Technical Field

The invention relates to the technical field of sensors, in particular to a sensor.

Background

A sensor is a device, module or subsystem whose purpose is to detect events or changes in the environment and to send information to other electronic devices.

The sensor is widely applied in pipelines, such as a pressure sensor, a flow velocity sensor, a temperature sensor and the like for measuring the pressure in the pipeline, the sensor is generally installed on a base through threads, the base is of a similar tubular structure, but the structure is simple, liquid with higher temperature can be conveyed in the pipeline for chemical engineering, the sensor needs to be radiated in time on occasions with higher temperature, the use of the sensor is prevented from being interfered by the temperature, the measurement accuracy of the sensor is influenced, in addition, the sensor is connected on the pipeline for a long time, the higher temperature can influence the threaded connection part of the sensor and the pipeline, in a high-temperature environment, the pretightening force of threaded connection can be reduced, the loosening condition is caused, and the method is very important for ensuring that the sensor is stably connected on the pipeline under the action of particularly combining flowing liquid impact, vibration and variable load, some sensors are usually arranged at the filter screen, and can conveniently detect the pressure around the filter screen, so that whether the filter screen is blocked or not can be judged, but only whether the filter screen is blocked or not can be monitored but the blockage cannot be cleaned.

Disclosure of Invention

The invention aims to solve the problems that a sensor is interfered in a high-temperature situation and the sensor arranged at a filter screen has no function of cleaning the filter screen.

In order to achieve the purpose, the invention adopts the following technical scheme:

a sensor base comprises a connecting pipe and a sensor body, wherein the connecting pipe is used for being fixed on a pipeline body, the sensor body is screwed on the connecting pipe, a cooling pipe is wound on the connecting pipe, a cooling box is fixedly connected on a fixed table, the cooling pipe is fixedly connected with the cooling box through a first pipeline, a first power box and a second power box are fixedly connected on the fixed table, the first power box is fixedly connected with the cooling pipe through a second pipeline, the second power box is fixedly connected with the cooling pipe through a third pipeline, the second power box is fixedly connected with the cooling box through a fourth pipeline, a first rotating shaft, a second rotating shaft and a third rotating shaft are rotatably connected in the pipeline body, an impeller blade and a first power blade are fixedly connected on the first rotating shaft, the impeller blade is rotatably connected in the first power box, the first power blade is rotatably connected in the pipeline body, fixedly connected with second power piece and first gear in the second pivot, the second power piece rotates to be connected in the second headstock, one end fixedly connected with second gear in the third pivot, third pivot other end fixedly connected with scraper blade, second gear and first gear engagement, this internal fixedly connected with filter screen of pipeline, scraper blade and filter screen laminating.

Preferably, sliding connection has the regulation pole in the connecting pipe, fixedly connected with fixed station on the connecting pipe, it is connected with the dead lever to rotate on the fixed station, dead lever top fixedly connected with fixed block, the fixed block is laminated with the sensor body, adjust pole sliding connection in the dead lever.

Preferably, fixedly connected with connecting rod on the regulation pole, fixedly connected with slide on the connecting rod, slide sliding connection is on the connecting pipe, slide bottom fixedly connected with telescopic link, the one end fixedly connected with flange of slide is kept away from to the telescopic link, flange fixed connection is on the connecting pipe, the spring has been cup jointed on the telescopic link, the both ends of spring offset with slide and flange respectively, the hollow section of thick bamboo of fixedly connected with on the sensor body, hollow section of thick bamboo offsets with the slide.

Preferably, the adjusting rod is fixedly connected with a cylindrical sliding block, and the fixing rod is provided with a sliding groove matched with the cylindrical sliding block.

Preferably, the fixed table is fixedly connected with a hinged seat, and the fixed rod is rotatably connected in the hinged seat.

Preferably, the pipeline body is fixedly connected with a connecting block, a sealing ring is fixedly connected in the connecting block, the first rotating shaft is rotatably connected in the connecting block, and the first rotating shaft is attached to the sealing ring.

Preferably, a bracket is fixedly connected in the pipeline body, and the third rotating shaft is rotatably connected to the bracket; fixedly connected with extends the platform on the fixed station, cooler bin fixed connection is on extending the platform, be equipped with the case lid on the cooler bin.

The sensor is characterized in that the sensor base is adopted.

The pipeline with the sensor comprises a pipeline body and a sensor base, wherein the connecting pipe is fixedly connected to the pipeline body.

A method of using a sensor mount, comprising the steps of:

s1: the sensor body is screwed into the connecting pipe, the bottom of the hollow cylinder on the sensor body is contacted with the sliding plate and presses down the sliding plate, the adjusting rod also slides downwards when the sliding plate slides downwards, the fixing rod rotates towards the direction of the sensor body at the moment, the fixing block at the top of the fixing rod clamps the sensor body, and the sensor body is fixed at the moment;

s2: when the sensor body is in work, fluid passes through the pipeline body, the fluid impacts the first power blade, the first rotating shaft rotates at the moment, the impeller blade connected to the top of the first rotating shaft rotates, negative pressure is generated when the impeller blade rotates, cooling liquid in the cooling box flows out under the influence of the negative pressure, the cooling liquid firstly flows into the cooling pipe through the first pipeline at the moment, then flows along the track of the cooling pipe and then flows into the first power box through the second pipeline, the cooling pipe is wound around the connecting pipe, and the cooling liquid flows in the cooling pipe to cool the connecting pipe, so that the sensor body is cooled;

s3: when the cooling liquid flows out of the cooling pipe and enters the second power box through the third pipeline, the cooling liquid impacts a second power sheet in the second power box, so that the second rotating shaft rotates, the first gear and the second gear on the second rotating shaft are meshed to drive the third rotating shaft to rotate, the scraper rotates together when the third rotating shaft rotates, particles on the filter screen are scraped off, the circulation performance in the pipeline body is better, and the danger of high-pressure pipe explosion is reduced;

s4: the cooling liquid flows back into the cooling box through a fourth pipeline after flowing through the second power box, the cooling liquid does not absorb heat after flowing out of the cooling pipe, the temperature is reduced through the outside air temperature, and the cooling liquid in the cooling box can be replaced by opening the box cover when the cooling liquid needs to be replaced;

s5: and repeating the steps of S2 and S3 to cool the sensor body, and cleaning and dredging the filter screen.

Compared with the prior art, the invention provides a sensor base, which has the following beneficial effects:

1. the sensor base is characterized in that a sensor body is screwed into a connecting pipe, the bottom of a hollow cylinder on the sensor body is contacted with a sliding plate and presses down the sliding plate, an adjusting rod also slides downwards when the sliding plate slides downwards, at the moment, a fixing rod rotates towards the direction of the sensor body, the fixing block at the top of the fixing rod clamps the sensor body, at the moment, the sensor body is fixed, when in work, fluid passes through a pipeline body, impacts a first power blade, at the moment, a first rotating shaft rotates, an impeller blade connected to the top of the first rotating shaft rotates, negative pressure is generated when the impeller blade rotates, cooling liquid in a cooling box flows out under the influence of the negative pressure, at the moment, the cooling liquid firstly enters a cooling pipe through the first pipeline, then flows along the track of the cooling pipe, then enters the first power box through a second pipeline, the cooling pipe is wound around the connecting pipe, and the cooling liquid flows in, thereby cooling the sensor body, when the cooling liquid flows out of the cooling liquid-operated cooling pipe and enters the second power box through the third pipeline, the cooling liquid impacts the second power sheet in the second power box, thereby the second rotating shaft rotates, the first gear on the second rotating shaft is meshed with the second gear to drive the third rotating shaft to rotate, the scraper blade rotates together when the third rotating shaft rotates to scrape off particles on the filter screen, the circulation performance in the pipeline body is better, the danger of high-pressure pipe explosion is reduced, and effectively avoids the long-term high-temperature working condition at the joint of the sensor and the pipeline, ensures that the sensor is stably connected on the pipeline, the cooling liquid flows back into the cooling box through the fourth pipeline after flowing through the second power box, and the cooling liquid does not absorb heat after flowing out of the cooling pipe, the cooling is carried out through the outside air temperature, and the cooling liquid in the cooling box can be replaced by opening the box cover when the cooling liquid needs to be replaced.

Drawings

Fig. 1 is a first schematic structural diagram of a sensor base according to the present invention;

fig. 2 is a schematic structural diagram of a sensor base according to the present invention;

FIG. 3 is a schematic structural diagram of a portion A of FIG. 2 of a sensor base according to the present invention;

FIG. 4 is a schematic structural diagram of a portion B of FIG. 2 of a sensor base according to the present invention;

FIG. 5 is a schematic structural diagram of a portion C in FIG. 2 of a sensor base according to the present invention;

FIG. 6 is a schematic structural diagram of a portion D in FIG. 2 of a sensor base according to the present invention;

fig. 7 is a schematic structural diagram of a portion E in fig. 2 of a sensor base according to the present invention.

In the figure: 1. a pipe body; 1001. a convex plate; 101. a connecting pipe; 102. a fixed table; 1021. a cooling tank; 1022. a box cover; 1023. an extension stage; 103. a first rotating shaft; 1031. a first power sheet; 1032. a first power box; 1033. impeller blades; 1035. connecting blocks; 1036. a seal ring; 2. a sensor body; 2001. a hollow cylinder; 2002. a connecting rod; 201. adjusting a rod; 2011. a slide plate; 2012. a cylindrical slider; 2013. a telescopic rod; 2014. a spring; 202. fixing the rod; 2021. a hinged seat; 2022. a fixed block; 3. a cooling tube; 301. a fourth conduit; 302. a first conduit; 303. a second conduit; 304. a third pipeline; 4. a second power box; 401. a second rotating shaft; 4011. a first gear; 402. a second power sheet; 5. filtering with a screen; 501. a squeegee; 5011. a third rotating shaft; 5012. a second gear; 5013. and (4) a bracket.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example 1:

referring to fig. 1, 2, 4, 5, and 6, a sensor base includes a connection pipe 101 and a sensor body 2, the connection pipe 101 is used to be fixed on a pipe body 1 and can be integrally formed by welding or machining the pipe, the sensor body 2 is threaded on the connection pipe 101, an adjustment rod 201 is slidably connected in the connection pipe 101, a fixing table 102 is fixedly connected on the connection pipe 101, a fixing rod 202 is rotatably connected on the fixing table 102, a fixing block 2022 is fixedly connected on the top of the fixing rod 202, the fixing block 2022 is attached to the sensor body 2, the adjustment rod 201 is slidably connected in the fixing rod 202, a cooling pipe 3 is wound on the connection pipe 101, a cooling tank 1021 is fixedly connected on the fixing table 102, the cooling pipe 3 is fixedly connected with the cooling tank 1021 through a first pipe 302, a first power box 1032 and a second power box 4 are fixedly connected on the fixing table 102, the first power box 1032 is fixedly connected with the cooling pipe 3 through a second, the second power box 4 is fixedly connected with the cooling pipe 3 through a third pipeline 304, the second power box 4 is fixedly connected with the cooling box 1021 through a fourth pipeline 301, a first rotating shaft 103 is connected in the pipeline body 1 in a rotating mode, a second rotating shaft 401 and a third rotating shaft 5011 are connected in the pipeline body 1, an impeller 1033 and a first power plate 1031 are fixedly connected to the first rotating shaft 103, the impeller 1033 is connected in the first power box 1032 in a rotating mode, the first power plate 1031 is connected in the pipeline body 1 in a rotating mode, a second power plate 402 and a first gear 4011 are fixedly connected to the second rotating shaft 401, the second power plate 402 is connected in the second power box 4 in a rotating mode, a second gear 5012 is fixedly connected to one end of the third rotating shaft 5011, a scraper 501 is fixedly connected to the other end of the third rotating shaft 5011, the second gear 5012 is meshed with the first gear 4011, a filter screen 5 is fixedly connected to the inside the pipeline body 1, and the scraper 501 is.

Example 2:

referring to fig. 1, 2 and 3, basically the same as embodiment 1, further, a connecting rod 2002 is fixedly connected to the adjusting rod 201, a sliding plate 2011 is fixedly connected to the connecting rod 2002, the sliding plate 2011 is slidably connected to the connecting pipe 101, an expansion rod 2013 is fixedly connected to the bottom of the sliding plate 2011, one end of the expansion rod 2013, which is far away from the sliding plate 2011, is fixedly connected to a convex plate 1001, the convex plate 1001 is fixedly connected to the connecting pipe 101, a spring 2014 is sleeved on the expansion rod 2013, two ends of the spring 2014 respectively abut against the sliding plate 2011 and the convex plate 1001, a hollow cylinder 2001 is fixedly connected to the sensor body 2, the hollow cylinder 2001 abuts against the sliding plate 2011, a cylindrical slider 2012 is fixedly connected to the adjusting rod 201, a sliding groove matched with the cylindrical slider 2012 is formed in the fixing rod 202, a hinge base 2021 is fixedly connected to the fixing base 102, the fixing rod 202 is rotatably, the bottom of the hollow cylinder 2001 on the sensor body 2 contacts with the sliding plate 2011 and presses down the sliding plate 2011, the adjusting rod 201 also slides downwards when the sliding plate 2011 slides downwards, at the moment, the fixing rod 202 rotates towards the sensor body 2, the fixing block 2022 at the top of the fixing rod 202 clamps the sensor body 2, and at the moment, the sensor body 2 is fixed.

Example 3:

referring to fig. 4 and 5, basically the same as embodiment 1, further, a connecting block 1035 is fixedly connected to the pipe body 1, a sealing ring 1036 is fixedly connected to the inside of the connecting block 1035, the first rotating shaft 103 is rotatably connected to the inside of the connecting block 1035, the first rotating shaft 103 is attached to the sealing ring 1036, a bracket 5013 is fixedly connected to the inside of the pipe body 1, the third rotating shaft 5011 is rotatably connected to the bracket 5013, the second rotating shaft 401 is rotated by impacting the second power plate 402 through circulation of cooling water, and the second rotating shaft 401 drives the scraper 501 to rotate through engagement of the first gear 4011 and the second gear 5012 to clean and dredge the filter screen.

Example 4:

referring to fig. 1 and 2, substantially the same as embodiment 1, further, an extension table 1023 is fixedly connected to the fixing table 102, a cooling box 1021 is fixedly connected to the extension table 1023, a box cover 1022 is arranged on the cooling box 1021, the number of the fixing rods 202 is two, and the two groups of the fixing rods 202 are symmetrically and rotatably connected to the fixing table 102, and the two groups of the fixing rods 202 fix the sensor body 2 more firmly.

Example 5:

referring to fig. 2 and fig. 7, in order to further ensure that the sensor body 2 is more firmly connected to the conduit body 1, on the basis of embodiment 4, a fixing mechanism is added, which specifically comprises a fixing cylinder 6 fixedly connected to the fixing table 102, a sealing disc 601 slidably connected to the fixing cylinder 6, a fixing rod 602 fixedly connected to the sealing disc 601, the fixing rod 602 slidably and sealingly penetrates through the housing of the fixing cylinder 6 and is fixedly connected to the adjusting rod 201, the upper end of the fixing cylinder 6 is communicated with the second conduit 303 through a liquid inlet pipe 603, a one-way liquid inlet valve 604 is disposed on the liquid inlet pipe 603, the upper end of the fixing cylinder 6 is also communicated with the second conduit 303 through a liquid return cylinder 605, a one-way liquid outlet valve 607 and an electromagnetic valve 606 are disposed on the liquid return cylinder 605, when in operation, the electromagnetic valve 606 is closed, the liquid in the second conduit 303 enters the fixing cylinder 6 through the liquid inlet pipe 603, and a first, along with the increase of the cooling liquid in the stabilizing cylinder 6, the sealing disc 601 is pressed upwards, so that the stabilizing rod 602 drives the adjusting rod 201 to apply a pulling force downwards, the fixing rod 202 is enabled to clamp the sensor body 2 more stably, and the connection stability is improved.

A sensor, which adopts the sensor base in the embodiment 1, can be used in pipelines for conveying various high-temperature liquids through the sensor base.

The utility model provides a pipeline with sensor, includes pipeline body 1 and sensor base, and connecting pipe fixed connection is on the pipeline body, and this pipeline can be used to connect in chemical industry liquid conveying pipeline for the state monitoring of liquid in the chemical industry high temperature liquid conveying pipeline.

A use method of a sensor base comprises the following steps:

s1: the sensor body 2 is screwed into the connecting pipe 101, the bottom of the hollow barrel 2001 on the sensor body 2 is contacted with the sliding plate 2011 and presses down the sliding plate 2011, the adjusting rod 201 also slides downwards when the sliding plate 2011 slides downwards, the fixing rod 202 rotates towards the direction of the sensor body 2 at the moment, the fixing block 2022 at the top of the fixing rod 202 clamps the sensor body 2, and the sensor body 2 is fixed at the moment;

s2: when the sensor body 2 works, fluid passes through the pipeline body 1, the fluid impacts the first power plate 1031, the first rotating shaft 103 rotates at the moment, the impeller 1033 connected to the top of the first rotating shaft 103 rotates, negative pressure is generated when the impeller 1033 rotates, cooling liquid in the cooling box 1021 flows out under the influence of the negative pressure, the cooling liquid firstly enters the cooling pipe 3 through the first pipeline 302 at the moment, then flows along the track of the cooling pipe 3 and then enters the first power box 1032 through the second pipeline 303, the cooling pipe 3 is wound on the connecting pipe 101, and the cooling liquid flows in the cooling pipe 3 to cool the connecting pipe 101, so that the sensor body 2 is cooled;

s3: when the cooling liquid flows out of the cooling pipe 3 and enters the second power box 4 through the third pipeline 304, the cooling liquid impacts a second power sheet 402 in the second power box 4, so that the second rotating shaft 401 rotates, the first gear 4011 and the second gear 5012 on the second rotating shaft 401 are meshed to drive the third rotating shaft 5011 to rotate, the scraper 501 rotates together when the third rotating shaft 5011 rotates to scrape particles on the filter screen 5, the circulation performance in the pipeline body 1 is better, and the danger of high-pressure pipe explosion is reduced;

s4: after flowing through the second power box 4, the cooling liquid flows back into the cooling box 1021 through the fourth pipeline 301, the cooling liquid does not absorb heat after flowing out of the cooling pipe 3, the temperature is reduced through the outside air temperature, and when the cooling liquid needs to be replaced, the cooling liquid in the cooling box 1021 can be replaced by opening the box cover 1022;

s5: and repeating the steps of S2 and S3 to cool the sensor body 2 and clean and dredge the filter screen 5.

The working principle is as follows: in the invention, a sensor body 2 is screwed into a connecting pipe 101, the bottom of a hollow cylinder 2001 on the sensor body 2 contacts a sliding plate 2011 and presses the sliding plate 2011 down, when the sliding plate 2011 slides down, an adjusting rod 201 also slides downwards, at the moment, a fixing rod 202 rotates towards the sensor body 2, a fixing block 2022 at the top of the fixing rod 202 clamps the sensor body 2, at the moment, the sensor body 2 is fixed, when a fluid passes through a pipeline body 1 during working, the fluid impacts a first power plate 1031, at the moment, a first rotating shaft 103 rotates, an impeller 1033 connected with the top of the first rotating shaft 103 rotates, negative pressure is generated when the impeller 1033 rotates, a cooling liquid in a cooling box 1021 flows out under the influence of the negative pressure, at the moment, the cooling liquid firstly enters a cooling pipe 3 through a first pipeline 302, then flows along the track of the cooling pipe 3, and then enters the first power box 1032 through a second pipeline 303, the cooling pipe 3 is wound around the connecting pipe 101, the cooling liquid flows in the cooling pipe 3 to cool the connecting pipe 101, thereby cooling the sensor body 2, when the cooling liquid flows out of the cooling liquid-operated cooling pipe 3 and enters the second power box 4 through the third pipeline 304, the cooling liquid impacts the second power piece 402 in the second power box 4, therefore, the second rotating shaft 401 rotates, the first gear 4011 on the second rotating shaft 401 is meshed with the second gear 5012 to drive the third rotating shaft 5011 to rotate, the scraper 501 rotates together when the third rotating shaft 5011 rotates to scrape off particles on the filter screen 5, so that the flow property in the pipeline body 1 is better, the danger of high-pressure pipe explosion is reduced, the cooling liquid flows back to the cooling box 1021 through the fourth pipeline 301 after flowing through the second power box 4, and the cooling liquid does not absorb heat after flowing out of the cooling pipe 3, when the temperature of the outside air is lowered, the tank cover 1022 is opened to replace the coolant in the cooling tank 1021.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (10)

1. A sensor base comprises a connecting pipe (101) and a sensor body (2), wherein the connecting pipe (101) is used for being fixed on a pipeline body (1), the sensor body (2) is threaded on the connecting pipe (101), and is characterized in that the connecting pipe (101) is wound and connected with a cooling pipe (3), a fixing table (102) is fixedly connected with a cooling tank (1021), the cooling pipe (3) is fixedly connected with the cooling tank (1021) through a first pipeline (302), the fixing table (102) is fixedly connected with a first power box (1032) and a second power box (4), the first power box (1032) is fixedly connected with the cooling pipe (3) through a second pipeline (303), the second power box (4) is fixedly connected with the cooling pipe (3) through a third pipeline (304), and the second power box (4) is fixedly connected with the cooling tank (1021) through a fourth pipeline (301), the pipeline comprises a pipeline body (1), wherein a first rotating shaft (103), a second rotating shaft (401) and a third rotating shaft (5011) are rotationally connected in the pipeline body (1), an impeller blade (1033) and a first power blade (1031) are fixedly connected to the first rotating shaft (103), the impeller blade (1033) is rotationally connected to a first power box (1032), the first power blade (1031) is rotationally connected to the pipeline body (1), a second power blade (402) and a first gear (4011) are fixedly connected to the second rotating shaft (401), the second power blade (402) is rotationally connected to a second power box (4), a second gear (5012) is fixedly connected to one end of the third rotating shaft (5011), a scraper blade (501) is fixedly connected to the other end of the third rotating shaft (5011), the second gear (5012) is meshed with the first gear (4011), a filter screen (5) is fixedly connected to the interior of the pipeline body (1), the scraper (501) is attached to the filter screen (5).

2. The sensor base according to claim 1, wherein an adjusting rod (201) is slidably connected in the connecting pipe (101), a fixed table (102) is fixedly connected to the connecting pipe (101), a fixed rod (202) is rotatably connected to the fixed table (102), a fixed block (2022) is fixedly connected to the top of the fixed rod (202), the fixed block (2022) is attached to the sensor body (2), and the adjusting rod (201) is slidably connected in the fixed rod (202).

3. The sensor base is characterized in that a connecting rod (2002) is fixedly connected to the adjusting rod (201), a sliding plate (2011) is fixedly connected to the connecting rod (2002), the sliding plate (2011) is slidably connected to the connecting pipe (101), a telescopic rod (2013) is fixedly connected to the bottom of the sliding plate (2011), a convex plate (1001) is fixedly connected to one end, far away from the sliding plate (2011), of the telescopic rod (2013), the convex plate (1001) is fixedly connected to the connecting pipe (101), a spring (2014) is sleeved on the telescopic rod (2013), two ends of the spring (2014) are respectively abutted to the sliding plate (2011) and the convex plate (1001), a hollow barrel (2001) is fixedly connected to the sensor body (2), and the hollow barrel (2001) is abutted to the sliding plate (2011).

4. The sensor base according to claim 3, wherein a cylindrical sliding block (2012) is fixedly connected to the adjusting rod (201), and a sliding groove matched with the cylindrical sliding block (2012) is formed on the fixing rod (202).

5. The sensor base of claim 4, characterized in that a hinge seat (2021) is fixedly connected to the fixed table (102), and the fixing rod (202) is rotatably connected in the hinge seat (2021).

6. The sensor base according to claim 1, wherein a connecting block (1035) is fixedly connected to the pipe body (1), a sealing ring (1036) is fixedly connected to the inside of the connecting block (1035), the first rotating shaft (103) is rotatably connected to the inside of the connecting block (1035), and the first rotating shaft (103) is attached to the sealing ring (1036).

7. The sensor base according to claim 1, characterized in that a bracket (5013) is fixedly connected in the pipe body (1), and the third rotating shaft (5011) is rotatably connected to the bracket (5013);

fixedly connected with extends platform (1023) on fixed station (102), cooler bin (1021) fixed connection is equipped with case lid (1022) on extending platform (1023).

8. A sensor, characterized in that a sensor base according to claim 1 is used.

9. A pipe with a sensor, characterized by comprising a pipe body (1) and the sensor base of claim 1, wherein the connecting pipe (101) is fixedly connected to the pipe body (1).

10. A method of using the sensor mount of claim 1, comprising the steps of:

s1: the sensor body (2) is screwed into the connecting pipe (101), the bottom of a hollow barrel (2001) on the sensor body (2) is contacted with a sliding plate (2011) and presses down the sliding plate (2011), the adjusting rod (201) also slides downwards when the sliding plate (2011) slides downwards, the fixing rod (202) rotates towards the sensor body (2), the fixing block (2022) at the top of the fixing rod (202) clamps the sensor body (2), and the sensor body (2) is fixed;

s2: when the sensor is in work, fluid passes through the pipeline body (1), the fluid impacts the first power sheet (1031), the first rotating shaft (103) rotates, the impeller blade (1033) connected to the top of the first rotating shaft (103) rotates, negative pressure is generated when the impeller blade (1033) rotates, cooling liquid in the cooling box (1021) flows out under the influence of the negative pressure, the cooling liquid firstly enters the cooling pipe (3) through the first pipeline (302), then flows along the track of the cooling pipe (3), and then enters the first power box (1032) through the second pipeline (303), the cooling pipe (3) is wound on the connecting pipe (101), and the cooling liquid flows in the cooling pipe (3) to cool the connecting pipe (101), so that the sensor body (2) is cooled;

s3: when the cooling liquid flows out of the cooling pipe (3) and then enters the second power box (4) through the third pipeline (304), the cooling liquid impacts a second power sheet (402) in the second power box (4), so that the second rotating shaft (401) rotates, a first gear (4011) on the second rotating shaft (401) is meshed with a second gear (5012) to drive the third rotating shaft (5011) to rotate, and a scraper (501) rotates together when the third rotating shaft (5011) rotates to scrape particles on the filter screen (5), so that the inner circulation of the pipeline body (1) is better, and the danger of high-pressure pipe explosion is reduced;

s4: after flowing through the second power box (4), the cooling liquid flows back into the cooling box (1021) through the fourth pipeline (301), the cooling liquid does not absorb heat after flowing out of the cooling pipe (3), the temperature is reduced through the outside air temperature, and the cooling liquid in the cooling box (1021) can be replaced by opening the box cover (1022) when the cooling liquid needs to be replaced;

s5: and repeating the steps of S2 and S3 to cool the sensor body (2) and clean and dredge the filter screen (5).

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