CN219999842U - Water cooling device for PE pipe detector - Google Patents

Abstract

The utility model discloses a water cooling device for a PE pipe detector, which comprises a water cooling part arranged on a detector shell, wherein the water cooling part comprises heat conducting components arranged on two lateral sides of the detector shell and a cooling component which is connected with the heat conducting components 2 and used for cooling the heat conducting components; the heat conduction assembly comprises a first heat conduction plate attached to the inner wall of the detector shell and a second heat conduction plate attached to the outer wall of the detector shell, one side, close to the second heat conduction plate, of the first heat conduction plate penetrates through the shell wall of the detector shell through a heat conduction rod to be connected with the second heat conduction plate, a flow channel for heat conduction liquid to pass through is formed in the second heat conduction plate, the cooling assembly comprises a liquid circulation piece for enabling the heat conduction liquid to circulate through the flow channel, and the cooling assembly further comprises a cooling piece for cooling the heat conduction liquid. The problem of PE pipe detector temperature continuously rising, lead to the electronic components who is located in PE pipe detector casing damage is avoided.

Description

Water cooling device for PE pipe detector

Technical Field

The utility model relates to the technical field of water cooling, in particular to a water cooling device for a PE pipe detector.

Background

The PE pipeline detector can rapidly and accurately detect the position, trend, depth and position and size of a damaged point of an anticorrosive coating of an underground tap water pipeline, a metal pipeline, a cable and the like under the condition of not damaging the ground covering soil, and is one of necessary instruments for tap water companies, gas companies, railway communication, municipal construction, engineering and mining, reconstruction of a foundation construction unit, maintenance and general investigation of the underground pipeline.

Because the electronic components of current PE pipe detector is integrated design, and factor components during operation can produce heat again, if the untimely temperature that will make PE pipe detector constantly rises, finally lead to electronic components to damage, consequently, need make a device that can cool down to PE pipe detector to solve this problem.

Disclosure of Invention

The utility model mainly aims to provide a water cooling device for a PE pipe detector, and aims to solve the technical problem that in the prior art, the temperature of the PE pipe detector is continuously increased, so that electronic components in a shell of the PE pipe detector are damaged.

In order to achieve the purpose, the water cooling device for the PE pipe detector comprises a water cooling part arranged on the detector shell, wherein the water cooling part comprises heat conduction components arranged on two lateral sides of the detector shell and a cooling component connected with the heat conduction components and used for cooling the heat conduction components;

the heat conduction assembly comprises a first heat conduction plate attached to the inner wall of the detector shell and a second heat conduction plate attached to the outer wall of the detector shell, one side, close to the second heat conduction plate, of the first heat conduction plate penetrates through the shell wall of the detector shell through a heat conduction rod to be connected with the second heat conduction plate, a flow channel for heat conduction liquid to pass through is formed in the second heat conduction plate, the cooling assembly comprises a liquid circulation piece for enabling the heat conduction liquid to circulate through the flow channel, and the cooling assembly further comprises a cooling piece for cooling the heat conduction liquid.

Preferably, the liquid circulation member includes a first conduit, a second conduit, a third conduit, and a water pump;

one end of the first conduit penetrates through the upper side of the second heat-conducting plate and stretches into the flow channel, one end of the second conduit penetrates through the lower side of the second heat-conducting plate and stretches into the flow channel, the water pump is used for enabling one end of the first conduit, which deviates from the first heat-conducting plate, to be communicated with the third conduit, and one end of the third conduit, which deviates from the water pump, and one end of the second conduit, which deviates from the second heat-conducting plate, are communicated through the cooling piece.

Preferably, the cooling part comprises a containing cylinder arranged at the bottom of the shell of the detector, a pipeline is arranged on an inner disc of the containing cylinder, two ends of the pipeline penetrate through the wall of the containing cylinder and extend out of the containing cylinder, one end pipe orifice of the pipeline extending out of the containing cylinder is communicated with one end of the second conduit, which is far away from the second heat-conducting plate, the other end of the pipeline is communicated with one end of the third conduit, which is far away from the water pump, a plurality of heat-conducting columns are distributed on the outer pipe wall of the pipeline, which is located in the containing cylinder, and an air flow part for enabling air to pass through the containing cylinder is arranged at a cylinder opening of the containing cylinder.

Preferably, the air flow piece comprises a fan which is detachably arranged at a cylinder opening at one end of the accommodating cylinder and used for conveying air into the accommodating cylinder, the air flow piece further comprises a screen which is detachably arranged at the cylinder opening at the other end of the accommodating cylinder and used for preventing sundries from entering the accommodating cylinder, and a filter screen is detachably arranged at an air inlet of the fan.

Preferably, one end of the heat conduction column, which is close to the pipeline, stretches into the pipeline, a concave hole for heat conduction liquid to flow in is concavely formed at one end of the heat conduction column, which is close to the pipeline, and a drainage plate for introducing the heat conduction liquid into the concave hole is arranged at the orifice of the concave hole.

Preferably, the bottom of the detector shell is provided with a bottom plate, four corners between the bottom plate and the detector shell are vertically provided with supporting legs respectively, and the cooling assembly is positioned between the bottom plate and the detector shell.

Preferably, a plurality of grooves are concavely formed on one side of the first heat conducting plate away from the shell wall of the detector shell.

Preferably, the outer walls of the first conduit, the second conduit and the third conduit are sleeved with a pipeline protecting sleeve.

According to the technical scheme, heat in the detector is transferred to the first heat-conducting plate, the first heat-conducting plate transfers the heat to the second heat-conducting plate through the heat-conducting rod, the liquid circulation piece enables heat-conducting liquid to circulate and pass through the flow channel, when the heat-conducting liquid passes through the flow channel, the heat-conducting liquid and the second heat-conducting plate are transferred, the temperature of the second heat-conducting plate is reduced, the heat-conducting liquid subsequently flows through the cooling piece after passing through the flow channel, the cooling piece cools the heat-conducting liquid, and the heat-conducting plate is reciprocated in such a way that the temperature of the second heat-conducting plate is reduced, and the detector is cooled; through mutually supporting between the above-mentioned structure to realize reducing the effect of detector temperature, and then avoided PE pipe detector temperature to rise continuously, lead to the problem that is located the damage of the electronic components of PE pipe detector casing.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of a heat transfer assembly and fluid circulation member of the present utility model;

FIG. 3 is a schematic diagram of a cooling member according to the present utility model;

fig. 4 is a schematic structural diagram of a heat conducting column according to the present utility model.

Reference numerals illustrate:

1. a detector; 1-1, a detector housing; 2. a heat conducting component; 21. a first heat-conducting plate; 21a, grooves; 22. a second heat-conducting plate; 23. a heat conduction rod; 24. a flow passage; 3. a cooling component; 31. a liquid circulation member; 311. a first conduit; 312. a second conduit; 313. a third conduit; 314. a water pump; 32. a cooling member; 321. a housing tube; 322. a pipe; 323. a heat conducting column; 323-1, concave holes; 324. a blower; 325. a filter screen; 326. a screen plate; 327. a drainage plate; 4. a bottom plate; 5. and (5) supporting legs.

The achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

Furthermore, descriptions such as those referred to as "first," "second," and the like, are provided for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implying an order of magnitude of the indicated technical features in the present disclosure. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present utility model, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the present utility model, unless specifically stated and limited otherwise, the terms "connected," "affixed," and the like are to be construed broadly, and for example, "affixed" may be a fixed connection, a removable connection, or an integral body; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

In addition, the technical solutions of the embodiments of the present utility model may be combined with each other, but it is necessary to be based on the fact that those skilled in the art can implement the technical solutions, and when the technical solutions are contradictory or cannot be implemented, the combination of the technical solutions should be considered as not existing, and not falling within the scope of protection claimed by the present utility model.

The utility model provides a water cooling device for a PE pipe detector. The sonde 1 includes a sonde housing 1-1.

Referring to fig. 1 to 4, the water cooling device for a PE pipe detector 1 includes a water cooling component disposed on a detector housing 1-1, where the water cooling component includes a heat conduction component 2 disposed on two lateral sides of the detector housing 1-1 and a cooling component 3 connected to the heat conduction component 2 and used for cooling the heat conduction component 2;

the heat conduction assembly 2 comprises a first heat conduction plate 21 attached to the inner wall of the detector housing 1-1 and a second heat conduction plate 22 attached to the outer wall of the detector housing 1-1, one side, close to the second heat conduction plate 22, of the first heat conduction plate 21 penetrates through the housing wall of the detector housing 1-1 through a heat conduction rod 23 to be connected with the second heat conduction plate 22, a flow channel 24 for heat conduction liquid to pass through is formed in the second heat conduction plate 22, the cooling assembly 3 comprises a liquid circulation piece 31 for enabling the heat conduction liquid to circulate through the flow channel 24, and the cooling assembly 3 further comprises a cooling piece 32 for cooling the heat conduction liquid.

In the technical scheme of the utility model, heat in the detector 1 is transferred to the first heat-conducting plate 21, the first heat-conducting plate 21 transfers heat to the second heat-conducting plate 22 through the heat-conducting rod 23, the liquid circulation piece 31 enables heat-conducting liquid to circulate and reciprocate through the flow channel 24, when the heat-conducting liquid passes through the flow channel 24, the heat-conducting liquid and the second heat-conducting plate 22 are transferred, so that the temperature of the second heat-conducting plate 22 is reduced, after the heat-conducting liquid passes through the flow channel 24, the heat-conducting liquid then flows through the cooling piece 32, the cooling piece 32 cools the heat-conducting liquid, and the heat-conducting liquid is reciprocated in such a way that the temperature of the second heat-conducting plate 22 is reduced, so that the detector 1 is cooled; through mutually supporting between the above-mentioned structure to realize reducing the effect of detector 1 temperature, and then avoided PE pipe detector 1 temperature to rise continually, lead to the problem that is located the damage of the electronic components of PE pipe detector 1 casing.

Referring to fig. 1-2, the liquid circulation member 31 includes a first conduit 311, a second conduit 312, a third conduit 313 and a water pump 314;

one end of the first conduit 311 extends into the runner 24 through the upper side of the second heat-conducting plate 22, one end of the second conduit 312 extends into the runner 24 through the lower side of the second heat-conducting plate 22, the water pump 314 is used for enabling one end of the first conduit 311, which is away from the first heat-conducting plate 21, to be communicated with the third conduit 313, and one end of the third conduit 313, which is away from the water pump 314, and one end of the second conduit 312, which is away from the second heat-conducting plate 22, are communicated through the cooling member 32. The water pump 314 is operative to drive the heat-conducting liquid to enter the first conduit 311 from the third conduit 313, so that the heat-conducting liquid enters the flow channel 24, and the second conduit 312 is operative to discharge the heat-conducting liquid in the flow channel 24, and the heat-conducting liquid is circulated in the flow channel 24 by the water pump 314 through the communication of the cooling member 32.

Referring to fig. 3, the cooling element 32 includes a receiving cylinder 321 disposed at the bottom of the detector housing 1-1, a pipe 322 is disposed on an inner disc of the receiving cylinder 321, two ends of the pipe 322 penetrate through a wall of the receiving cylinder 321 and extend out of the receiving cylinder 321, a nozzle at one end of the pipe 322 extending out of the receiving cylinder 321 is connected to one end of the second conduit 312, which is away from the second heat-conducting plate 22, and another end of the pipe is connected to one end of the third conduit 313, which is away from the water pump 314, a plurality of heat-conducting columns 323 are disposed on an outer wall of the pipe 322, which is located in the receiving cylinder 321, at intervals, and an air flow element for making air pass through the receiving cylinder 321 is disposed at a nozzle of the receiving cylinder 321. The pipe 322 is configured to communicate the second conduit 312 and the third conduit 313, when the heat-conducting liquid passes through the pipe 322, the heat-conducting liquid transfers heat to the pipe 322, the pipe 322 transfers heat to the heat-conducting column 323, and the air flow member drives the air to pass through the accommodating cylinder 321, so that the temperature of the heat-conducting column 323 is reduced, and the temperature of the heat-conducting liquid is further reduced.

Referring to fig. 3, the airflow member includes a fan 324 detachably disposed at a nozzle of the accommodating cylinder 321, the fan 324 is configured to convey air into the accommodating cylinder 321, the airflow member further includes a screen 326 detachably disposed at a nozzle of the other end of the accommodating cylinder 321 and configured to prevent impurities from entering the accommodating cylinder 321, and a filter screen 325 is detachably disposed at an air inlet of the fan 324. The air outside the accommodating cylinder 321 can be conveyed to the inside of the accommodating cylinder 321 through the fan 324, so that the external air flows through the accommodating cylinder 321, and the heat conducting column 323 is cooled.

Referring to fig. 4, an end of the heat conducting column 323 near the pipe 322 extends into the pipe 322, a concave hole 323-1 into which the heat conducting liquid flows is concavely formed at an end of the heat conducting column 323 near the pipe 322, and a drainage plate 327 for guiding the heat conducting liquid into the concave hole 323-1 is disposed at an orifice of the concave hole 323-1. The drainage plate 327 is obliquely arranged at the orifice of the concave hole 323-1, the inclined surface faces the flowing direction of the heat conducting liquid, when the heat conducting liquid passes through the concave hole 323-1, the heat conducting liquid can enter the corresponding concave hole 323-1 under the guidance of the drainage plate 327, meanwhile, the heat conducting liquid originally reserved in the concave hole 323-1 can be discharged and extruded by the newly-entered heat conducting liquid, the replacement of the liquid is realized, and the heat conducting liquid enters the concave hole 323-1, so that the heat radiating speed of the heat conducting liquid can be accelerated.

Referring to fig. 3, a bottom plate 4 is disposed at the bottom of the detector housing 1-1, supporting legs 5 are vertically disposed at four corners between the bottom plate 4 and the detector housing 1-1, and the cooling component 3 is disposed between the bottom plate 4 and the detector housing 1-1. Through the cooperation between bottom plate 4 and supporting leg 5, can realize preventing that cooling module 3 from producing wearing and tearing with ground contact.

Referring to fig. 2, a plurality of grooves 21a are concavely formed on a side of the first heat conductive plate 21 facing away from the wall of the detector housing 1-1. The grooves 21a on the first heat-conducting plate 21 are used for increasing the contact area between the first heat-conducting plate 21 and air, so as to accelerate the heat transfer speed between the first heat-conducting plate 21 and the detector 1.

Referring to fig. 1, the outer walls of the first conduit 311, the second conduit 312 and the third conduit 313 are respectively sleeved with a protecting sleeve of a pipeline 322. The pipeline 322 protecting sleeve is used for protecting the first conduit 311, the second conduit 312 and the third conduit 313, avoiding the first conduit 311, the second conduit 312 and the third conduit 313 from being damaged by external force, and prolonging the service lives of the first conduit 311, the second conduit 312 and the third conduit 313.

The foregoing description of the preferred embodiments of the present utility model should not be construed as limiting the scope of the utility model, but rather utilizing equivalent structural changes made in the present utility model description and drawings or directly/indirectly applied to other related technical fields are included in the scope of the present utility model.

Claims (8)

1. The water cooling device for the PE pipe detector is characterized by comprising a water cooling part arranged on the detector shell, wherein the water cooling part comprises heat conduction components arranged on two lateral sides of the detector shell and a cooling component connected with the heat conduction components and used for cooling the heat conduction components;

the heat conduction assembly comprises a first heat conduction plate attached to the inner wall of the detector shell and a second heat conduction plate attached to the outer wall of the detector shell, one side, close to the second heat conduction plate, of the first heat conduction plate penetrates through the shell wall of the detector shell through a heat conduction rod to be connected with the second heat conduction plate, a flow channel for heat conduction liquid to pass through is formed in the second heat conduction plate, the cooling assembly comprises a liquid circulation piece for enabling the heat conduction liquid to circulate through the flow channel, and the cooling assembly further comprises a cooling piece for cooling the heat conduction liquid.

2. The water cooling device for a PE pipe detector according to claim 1, wherein the liquid circulation member includes a first conduit, a second conduit, a third conduit, and a water pump;

one end of the first conduit penetrates through the upper side of the second heat-conducting plate and stretches into the flow channel, one end of the second conduit penetrates through the lower side of the second heat-conducting plate and stretches into the flow channel, the water pump is used for enabling one end of the first conduit, which deviates from the first heat-conducting plate, to be communicated with the third conduit, and one end of the third conduit, which deviates from the water pump, and one end of the second conduit, which deviates from the second heat-conducting plate, are communicated through the cooling piece.

3. The water cooling device for the PE pipe detector according to claim 2, wherein the cooling component comprises a containing cylinder arranged at the bottom of the detector shell, a pipeline is arranged on an inner disc of the containing cylinder, two ends of the pipeline penetrate through the wall of the containing cylinder and extend out of the containing cylinder, one end pipe orifice of the pipeline extending out of the containing cylinder is communicated with one end of the second conduit, which is far away from the second heat conducting plate, the other end of the pipeline is communicated with one end of the third conduit, which is far away from the water pump, a plurality of heat conducting columns are distributed on the outer pipe wall of the pipeline, which is positioned in the containing cylinder, at a cylinder opening of the containing cylinder, an air flow component for enabling air to pass through the containing cylinder is arranged.

4. The water cooling device for a PE pipe detector according to claim 3, wherein the air flow member comprises a fan detachably arranged at a nozzle at one end of the accommodating cylinder, the fan is used for conveying air into the accommodating cylinder, the air flow member further comprises a screen detachably arranged at the nozzle at the other end of the accommodating cylinder and used for preventing sundries from entering the accommodating cylinder, and a filter screen is detachably arranged at an air inlet of the fan.

5. The water cooling device for the PE pipe detector according to claim 3, wherein one end, close to the pipeline, of the heat conducting column extends into the pipeline, a concave hole for heat conducting liquid to flow in is concavely formed in one end, close to the pipeline, of the heat conducting column, and a drainage plate for introducing the heat conducting liquid into the concave hole is arranged at an orifice of the concave hole.

6. The water cooling device for the PE pipe detector according to claim 1, wherein a bottom plate is arranged at the bottom of the detector shell, supporting legs are vertically arranged at four corners between the bottom plate and the detector shell respectively, and the cooling assembly is arranged between the bottom plate and the detector shell.

7. The water cooling device for a PE pipe detector according to claim 1, wherein a plurality of grooves are formed in a concave manner on one side of the first heat conducting plate away from the shell wall of the detector shell.

8. The water cooling device for the PE pipe detector according to claim 2, wherein the outer walls of the first conduit, the second conduit and the third conduit are respectively sleeved with a pipeline protecting sleeve.