CN114353559A

CN114353559A - High-strength heat collecting pipe

Info

Publication number: CN114353559A
Application number: CN202210260916.5A
Authority: CN
Inventors: 邢业飞; 邢作新; 付建平
Original assignee: Shandong Huaye Yangguang New Energy Co ltd
Current assignee: Shandong Huaye Yangguang New Energy Co ltd
Priority date: 2022-03-17
Filing date: 2022-03-17
Publication date: 2022-04-15
Anticipated expiration: 2042-03-17
Also published as: CN114353559B

Abstract

The invention discloses a high-strength heat collecting pipe, which belongs to the technical field of heat exchange equipment and comprises a connecting pipe seat, wherein one side of the connecting pipe seat is movably connected with a plurality of sealing mechanisms, the other side of each sealing mechanism is fixedly provided with a heat exchange outer pipe, the outer side wall of each heat exchange outer pipe is adjustably connected with a heat exchange mechanism, and the inner cavity of each heat exchange outer pipe is slidably connected with an inner pipe mechanism. According to the invention, the impact force of a medium can synchronously drive the inner pipe backing ring at the tail end to slide in the heat exchange outer pipe, the inner pipe backing ring moves forwards under the action of the impact force and pulls the extrusion ring and the elastic rod on one side, after the heat exchange medium flows and contacts, the tension of the elastic rod can reversely drive the inner heat exchange pipe to reversely reset, the turbulence heat absorption plate which reciprocates adapts to the energy absorption and blocking treatment of the introduced medium, the abutting and accumulation of impurities of the heat exchange medium is realized, the accumulation of dirt on the inner wall of the inner heat exchange pipe is reduced by changing the direction of media flowing and turbulence, the service life and the overall strength are effectively prolonged, and the integral use requirement is met.

Description

High-strength heat collecting pipe

Technical Field

The invention belongs to the technical field of heat exchange equipment, and particularly relates to a high-strength heat collecting pipe.

Background

The heat collecting pipe is a heat collecting pipeline for realizing heat collection through heat exchange with an external medium, the medium in the pipeline circulates and can exchange the heat collected by the heat collecting pipe through the heat exchange into the medium, and the heat exchanging pipe is one of elements of the heat exchanger, is arranged in the cylinder and is used for exchanging the heat between the two media. Has high thermal conductivity and good isothermal property. It is a device that can rapidly transfer heat energy from one point to another with little heat loss.

Chinese patent document CN106767115B discloses a heat exchange tube and a heat exchanger. The heat exchange tube comprises a heat exchange tube body, wherein a turbulence structure with adjustable size is arranged in the heat exchange tube body, the heat exchange tube further comprises an adjusting part for controlling the size of the turbulence structure, and the adjusting part is connected with the turbulence structure. The heat exchange tube can prevent scale deposition, but still has certain defects in actual use, such as lack of adjustable processing capacity on turbulent flow equipment, influence on separation and treatment of the scale deposition, and can not well meet the overall use requirement.

Disclosure of Invention

The invention aims to: the high-strength heat collecting pipe aims to solve the problems that the problem of affecting the separation and treatment of accumulated scale due to the lack of adjustable treatment capacity of turbulent flow equipment.

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

a high-strength heat collecting pipe comprises a connecting pipe seat, wherein one side of the connecting pipe seat is movably connected with a plurality of sealing mechanisms, the other side of each sealing mechanism is fixedly provided with a heat exchange outer pipe, the outer side wall of each heat exchange outer pipe is adjustably connected with a heat exchange mechanism, the inner cavity of each heat exchange outer pipe is slidably connected with an inner pipe mechanism, and one end, far away from the sealing mechanism, of each heat exchange outer pipe is fixedly provided with a sealing mechanism;

the heat exchange mechanism comprises a heat exchange ring, wherein sliders are fixedly connected to two sides of an inner cavity of the heat exchange ring, the sliders are connected to a sliding groove formed in one side of the outer heat exchange tube in a sliding mode, a plurality of heat exchange fins are adjustably connected to the outer wall of the heat exchange ring, a fixing block is movably embedded in one side of the inner cavity of the heat exchange ring, the inner tube mechanism comprises an inner heat exchange tube, a plurality of friction balls are arranged on the outer side wall of the inner heat exchange tube in a surrounding mode, the friction balls are attached to one side of the inner cavity of the outer heat exchange tube, the inner heat exchange tube is connected to the inner cavity of the outer heat exchange tube in a sliding mode, and the friction balls are located in a turbulence plate fixedly connected to the bottom of the inner side of the inner heat exchange tube.

As a further description of the above technical solution:

the turbulent flow heat absorption plate is a heat conduction metal part, and a plurality of arc heat absorption grooves are formed in one side of the turbulent flow heat absorption plate.

As a further description of the above technical solution:

the tail end of the inner heat exchange tube is fixedly connected with an inner tube backing ring, and the inner tube backing ring is connected to the inner cavity of the heat exchange outer tube in a sliding mode.

As a further description of the above technical solution:

the outer side wall of the inner heat exchange tube is sleeved with a laminating pad, one side of the laminating pad is fixedly connected with an inner tube sleeve, one side of the inner tube sleeve is fixedly connected with one side of an inner tube backing ring, and the inner tube sleeve is laminated with the inner cavity of the heat exchange outer tube.

As a further description of the above technical solution:

the sealing mechanism comprises a sealing pipe cap, one side of the sealing pipe cap is fixedly connected with an elastic ring through a sealing backing ring, one side of the elastic ring is attached to one side of the inner heat exchange pipe, one side of the sealing pipe cap is communicated with a communicating pipe, the communicating pipe is communicated with an external pump body, and one side of the sealing pipe cap is detachably connected with one side of the heat exchange outer pipe.

As a further description of the above technical solution:

the heat exchange fin is characterized in that an adjusting shaft is fixedly connected to one side of the heat exchange fin, the adjusting shaft is connected to a limiting groove formed in the outer side wall of the heat exchange ring in a sliding mode, and a plurality of limiting balls are filled in the limiting groove.

As a further description of the above technical solution:

the fixed block joint is at the spacing inslot cavity, and the fixed block inner chamber inlays and is equipped with the second sliding sleeve, sliding connection has the second slide bar in the second sliding sleeve, second slide bar top fixedly connected with fixture block, fixture block sliding connection is at fixed block inner chamber top, and the fixture block top laminates with corresponding position control axle mutually, second slide bar bottom fixedly connected with supporting shoe, supporting shoe bottom fixedly connected with gyro wheel, the laminating of gyro wheel one side has the set-square, the first slide bar of set-square one side fixedly connected with, first slide bar one end fixedly connected with handle, first slide bar lateral wall cover is equipped with first sliding sleeve, first sliding sleeve inlays and locates fixed block inner chamber one side, first slide bar lateral wall cover is equipped with first spring, first spring both ends correspond position fixed connection with first sliding sleeve and handle one side respectively.

As a further description of the above technical solution:

the sealing mechanism comprises a support ring, two sides of the support ring are fixedly connected with limiting blocks, one side of each limiting block is fixedly connected with a second spring, a sealing washer is fixedly connected between the second springs on the two sides, the sealing washer is sleeved outside the heat exchange outer pipe, a plurality of sealing rings are embedded on one side of the connecting pipe seat, the sealing rings are sleeved with the outside of the support ring, and one side of the support ring is fixedly connected with one side of the heat exchange outer pipe.

As a further description of the above technical solution:

the support ring inner chamber inlays and is equipped with the elasticity ring, the equal fixedly connected with elasticity pole in elasticity ring one side both ends, and fixedly connected with extrusion ring between the elasticity pole of both sides, and extrusion ring and inner tube mechanism one side fixed connection.

As a further description of the above technical solution:

the inner cavity of the heat exchange outer pipe is of a friction particle structure, and the friction particles in the inner cavity of the heat exchange outer pipe are attached to the outer wall of the friction ball.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. in the invention, after a heat exchange medium enters the heat exchange outer pipe through the front end connecting pipe seat, the flowing impact force of the heat exchange medium can realize that the top friction ball rotates in the heat exchange pipe through the contact with a plurality of turbulence heat absorbing plates, the friction ball can deflect in the inner cavity of the heat exchange outer pipe through the friction force when rotating, and the impact force of the medium can synchronously drive the tail end inner pipe backing ring to slide in the heat exchange outer pipe, the inner pipe backing ring moves forwards under the action of the impact force and pulls the extrusion ring and the elastic rod on one side, after the heat exchange medium flows and contacts, the tension of the elastic rod can reversely drive the inner heat exchange pipe to reset reversely, the energy absorption and blocking treatment of the introduced medium is adapted by the turbulence plates moving in a reciprocating way, the abutting accumulation of impurities of the heat exchange medium is realized, and the generation frequency of dirt on the inner wall of the inner heat exchange pipe is reduced through the turbulence of the medium circulation, effectively prolong the service life and the overall strength, and meet the overall use requirement.

2. According to the invention, the heat exchange fins can move in the limiting grooves through the rear side adjusting shaft to adjust the relative offset angles of the heat exchange fins outside, after a plurality of heat exchange fins are adjusted, the first sliding rod on one side is pulled to move in the first sliding sleeve to drive the set square to move and separate from the roller, at the moment, the fixture block moves into the inner cavity of the fixing block through the second sliding rod, and the fixing block is pulled to be clamped into the limiting groove of the heat exchange ring on one side, so that the adjustable assembly of the peripheral sides of the heat exchange fins can be realized, the adjustment treatment of the assembly position of the heat exchange tube is met through the insertion assembly of the fixing block, and the overall assembly adaptability is effectively improved.

3. According to the invention, the sealing mechanism can ensure the medium sealing treatment capacity, the reset tension is provided for the displacement of the inner heat exchange tube under the matching of the elastic rings and the elastic rods on the two sides, the treatment capacity of the adjustable inner heat exchange tube on scale is ensured, and the fixing stability of the heat exchange outer tube is ensured through the supporting effect of the connecting tube seat on the heat exchange outer tube through the sealing ring and the supporting ring, so that the integral use requirement is met.

Drawings

FIG. 1 is a schematic perspective view of a high-strength heat collecting tube according to the present invention;

FIG. 2 is a schematic view of a three-dimensional split structure of a high-strength heat collecting tube according to the present invention;

FIG. 3 is a schematic perspective view of a heat exchange mechanism of a high-strength heat collecting tube according to the present invention;

FIG. 4 is a schematic perspective view of a fixing block of a high-strength heat collecting tube according to the present invention;

FIG. 5 is a schematic view of a three-dimensional disassembled structure of a fixture block of a high-strength heat collecting tube according to the present invention;

FIG. 6 is a schematic view of an assembly structure of an inner heat exchange tube of a high-strength heat collection tube according to the present invention;

FIG. 7 is a schematic view of a three-dimensional structure of a turbulent heat absorbing plate of a high-strength heat collecting tube according to the present invention;

fig. 8 is a schematic perspective view of an inner heat exchange tube of a high-strength heat collection tube according to the present invention.

Illustration of the drawings:

1. connecting a pipe seat; 2. an outer heat exchange tube; 3. a sealing mechanism; 301. closing the pipe cap; 302. closing the backing ring; 303. an elastic ring; 304. a communicating pipe; 4. a heat exchange mechanism; 401. a heat exchange ring; 402. heat exchange fins; 403. limiting balls; 404. an adjustment shaft; 405. a fixed block; 406. a first slide bar; 407. a clamping block; 408. a slider; 409. a set square; 410. a roller; 411. a support block; 412. a second slide bar; 413. a sliding sleeve; 414. a first spring; 5. an inner tube mechanism; 501. an inner heat exchange tube; 502. a friction ball; 503. a turbulent heat absorbing plate; 504. attaching a pad; 505. an inner pipe sleeve; 506. an inner tube backing ring; 6. a chute; 7. a sealing mechanism; 701. a support ring; 702. a limiting block; 703. a second spring; 704. a sealing gasket; 705. an elastic ring; 706. an elastic rod; 707. and (4) a sealing ring.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution: a high-strength heat collecting pipe comprises a connecting pipe seat 1, wherein one side of the connecting pipe seat 1 is movably connected with a plurality of sealing mechanisms 7, the other side of each sealing mechanism 7 is fixedly provided with a heat exchange outer pipe 2, the outer side wall of each heat exchange outer pipe 2 is adjustably connected with a heat exchange mechanism 4, the inner cavity of each heat exchange outer pipe 2 is slidably connected with an inner pipe mechanism 5, and one end, far away from the sealing mechanism 7, of each heat exchange outer pipe 2 is fixedly provided with a sealing mechanism 3;

the heat exchange mechanism 4 comprises a heat exchange ring 401, both sides of an inner cavity of the heat exchange ring 401 are fixedly connected with sliders 408, the sliders 408 are slidably connected in a chute 6 formed in one side of an outer heat exchange tube 2, the outer wall of the heat exchange ring 401 is adjustably connected with a plurality of heat exchange fins 402, one side of the inner cavity of the heat exchange ring 401 is movably embedded with a fixed block 405, the inner tube mechanism 5 comprises an inner heat exchange tube 501, the outer side wall of the inner heat exchange tube 501 is embedded with a plurality of friction balls 502 in a surrounding manner, the friction balls 502 are attached to one side of the inner cavity of the outer heat exchange tube 2, the inner heat exchange tube 501 is slidably connected to the inner cavity of the outer heat exchange tube 2, the friction balls 502 are positioned at the bottom of the inner side of the inner heat exchange tube 501 and fixedly connected with a turbulence heat absorption plate 503, the turbulence heat absorption plate 503 is a heat conduction metal piece, one side of the turbulence heat absorption plate 503 is provided with a plurality of arc heat absorption grooves, and the tail end of the inner heat exchange tube 501 is fixedly connected with an inner cushion ring 506, the inner pipe backing ring 506 is slidably connected to the inner cavity of the heat exchange outer pipe 2, the outer side wall of the inner heat exchange pipe 501 is sleeved with the attaching pad 504, one side of the attaching pad 504 is fixedly connected with an inner pipe sleeve 505, one side of the inner pipe sleeve 505 is fixedly connected with one side of the inner pipe backing ring 506, and the inner pipe sleeve 505 is attached to the inner cavity of the heat exchange outer pipe 2.

The implementation mode is specifically as follows: after a heat exchange medium enters the heat exchange outer tube 2 through the front end connecting tube seat 1, the impact force of the heat exchange medium can be transmitted into the inner heat exchange tube 501 on one side through the supporting ring 701, the flowing impact force of the heat exchange medium can realize that the top friction ball 502 rotates in the inner heat exchange tube 501 through the contact with the turbulence heat absorbing plates 503, the friction ball 502 can deflect in the inner cavity of the heat exchange outer tube 2 through the friction force when rotating, the impact force of the medium can synchronously drive the inner tube backing ring 506 at the tail end to slide in the heat exchange outer tube 2, the inner tube backing ring 506 moves forwards under the impact force and pulls the extrusion ring and the elastic rod 706 on one side, after the heat exchange medium flows and contacts, the tension of the elastic rod 706 can reversely drive the inner heat exchange tube 501 to reversely reset, and the reset inner heat exchange tube 501 can drive the heat absorbing plates 503 to reset through the adhesion of the friction ball 502 and the inner cavity of the heat exchange outer tube 2, thereby can adapt to the energy-absorbing fender that lets in the medium through reciprocating motion's vortex absorber plate 503 and connect the processing, the realization is piled up the butt of heat exchange medium impurity, and can deposit the stress destruction of dirt body with interior heat exchange tube 501 department when vortex absorber plate 503 removes, thereby can change the accumulation of reducing interior heat exchange tube 501 inner wall dirt through vortex to the medium circulation, satisfy whole user needs, closing mechanism 3 through the design, closing tube cap 301 can seal backing ring 302 and elastic ring 303 through the rear side and realize and laminate the position in heat exchange tube 501's abundant spacing, and elastic ring 303 can carry out elastic support after heat exchange tube 501 takes place the displacement, thereby heat exchange tube 501 reset effect in improving.

An adjusting shaft 404 is fixedly connected to one side of the heat exchange fin 402, the adjusting shaft 404 is slidably connected to a limiting groove formed in the outer side wall of the heat exchange ring 401, a plurality of limiting balls 403 are filled in the limiting groove, the fixing block 405 is clamped in an inner cavity of the limiting groove, a second sliding sleeve 413 is embedded in the inner cavity of the fixing block 405, a second sliding rod 412 is slidably connected to the second sliding sleeve 413, a clamping block 407 is fixedly connected to the top end of the second sliding rod 412, the clamping block 407 is slidably connected to the top of the inner cavity of the fixing block 405, the top of the clamping block 407 is attached to the adjusting shaft 404 at the corresponding position, a supporting block 411 is fixedly connected to the bottom end of the second sliding rod 412, a roller 410 is fixedly connected to the bottom of the supporting block 411, a triangular plate 409 is attached to one side of the roller 410, a first sliding rod 406 is fixedly connected to one side of the triangular plate 409, a handle is fixedly connected to one end of the first sliding rod 406, and a first sliding sleeve 413 is sleeved on the outer side wall of the first sliding sleeve 406, the first sliding sleeve 413 is embedded in one side of an inner cavity of the fixed block 405, a first spring 414 is sleeved on the outer side wall of the first sliding rod 406, and two ends of the first spring 414 are fixedly connected with the first sliding sleeve 413 and one side of the handle at corresponding positions respectively.

As shown in fig. 3 to 5, the embodiment specifically is: the heat exchange fins 402 can move in the limiting grooves through the rear adjusting shaft 404, so that the relative offset angle of the heat exchange fins 402 outside can be adjusted, the heat exchange fins 402 can ensure heat exchange treatment adjustment through the fit with the heat exchange ring 401, the limiting balls 403 in the heat exchange ring 401 can ensure the extrusion fixation of the adjusting shaft 404, after a plurality of heat exchange fins 402 are adjusted, one side first slide rod 406 is pulled to move in the first sliding sleeve 413, the first slide rod 406 moves to drive the triangular plate 409 to move and separate from the roller 410, at the moment, the fixture block 407 moves into the inner cavity of the fixing block 405 through the second slide rod 412, the fixing block 405 is pulled to be clamped into the limiting groove of the one side heat exchange ring 401, after the handle is loosened, the first spring 414 can ensure the support of the roller 410 by the first slide rod 406 and the triangular plate 409 through self-pulling force, and ensure the two side fixing blocks 405 are extruded and limited and fixed with the corresponding position adjusting shaft 404 after being reset, the fixing block 405 can be clamped into a limiting groove on one side of the heat exchange ring 401, so that adjustable assembly on the peripheral side of the heat exchange fins 402 can be achieved, insertion assembly of the fixing block 405 meets the adjustment treatment of the assembly position of the heat exchange tube, and overall assembly adaptability is effectively improved.

The sealing mechanism 3 comprises a sealing pipe cap 301, one side of the sealing pipe cap 301 is fixedly connected with an elastic ring 303 through a sealing backing ring 302, one side of the elastic ring 303 is attached to one side of an inner heat exchange pipe 501, one side of the sealing pipe cap 301 is communicated with a communicating pipe 304, the communicating pipe 304 is communicated with an external pump body, one side of the sealing pipe cap 301 is detachably connected with one side of an outer heat exchange pipe 2, the sealing mechanism 7 comprises a supporting ring 701, two sides of the supporting ring 701 are both fixedly connected with limiting blocks 702, one side of each limiting block 702 is fixedly connected with a second spring 703, a sealing gasket 704 is fixedly connected between the second springs 703 at two sides, the sealing gasket 704 is sleeved outside the outer heat exchange pipe 2, a plurality of sealing rings 707 are embedded at one side of the connecting pipe seat 1, the sealing rings 707 are sleeved with the outside of the supporting ring 701, one side of the supporting ring 701 is fixedly connected with one side of the outer heat exchange pipe 2, the inner cavity of the support ring 701 is embedded with an elastic ring 705, two ends of one side of the elastic ring 705 are fixedly connected with elastic rods 706, extrusion rings are fixedly connected between the elastic rods 706 on two sides, the extrusion rings are fixedly connected with one side of the inner tube mechanism 5, the inner cavity of the heat exchange outer tube 2 is of a friction particle structure, and friction particles in the inner cavity of the heat exchange outer tube 2 are attached to the outer wall of the friction ball 502.

As shown in fig. 2, the embodiment specifically includes: sealing mechanism 7 can guarantee the medium and seal the throughput, and through the both sides elasticity ring 705 and elasticity pole 706 cooperation down provide the power that resets to the displacement of inner heat exchange tube 501, guarantee the throughput of adjustable inner heat exchange tube 501 to the scale deposit, and through the supporting role of connecting tube socket 1 through sealing ring 707 and support ring 701 to heat exchange outer tube 2, guarantee heat exchange outer tube 2 fixed stability, effectively improve thermal-arrest heat exchange efficiency, satisfy whole user needs, seal ring 704 can establish outside the support ring 701 through the compression cover of rear side second spring 703 simultaneously, thereby can guarantee support ring 701 and heat exchange outer tube 2 cover and establish the compactness of connecting.

The working principle is as follows: when the heat exchanger is used for heat collection and heat exchange, after a heat exchange medium enters the heat exchange outer tube 2 through the front end connecting tube seat 1, the impact force of the heat exchange medium can be transmitted into the inner heat exchange tube 501 on one side through the support ring 701, the flowing impact force of the heat exchange medium can realize that the top friction ball 502 rotates in the inner heat exchange tube 501 through the contact with the flow-disturbing heat-absorbing plates 503, the friction ball 502 can deflect in the inner cavity of the heat exchange outer tube 2 through the friction force when rotating, and the impact force of the medium can synchronously drive the tail end inner tube backing ring 506 to slide in the heat exchange outer tube 2, the inner tube backing ring 506 moves forwards under the action of the impact force and pulls the extrusion ring and the elastic rod 706 on one side, after the heat exchange medium flows and contacts, the pulling force of the elastic rod 706 can reversely drive the inner heat exchange tube 501 to reversely reset, and the reset inner heat exchange tube 501 can drive the flow-disturbing heat-absorbing plates 503 to reset through the joint of the friction ball 502 and the inner cavity of the heat exchange outer tube 2, therefore, the energy absorption blocking treatment of the introduced medium can be adapted through the turbulence heat absorption plate 503 which moves in a reciprocating manner, and the blocking accumulation of impurities of the heat exchange medium is realized;

the heat exchange fins 402 can move in the restriction groove by the rear adjustment shaft 404, so that the relative offset angle of the heat exchange fins 402 at the outside can be adjusted, and the heat exchange fins 402 can ensure heat exchange treatment adjustment by fitting with the heat exchange ring 401, and the limit balls 403 in the heat exchanging ring 401 can ensure the extrusion fixation of the adjusting shaft 404, after the plurality of heat exchange fins 402 are adjusted, the first sliding rod 406 at one side is pulled to move in the first sliding sleeve 413, the first sliding rod 406 moves to drive the triangular plate 409 to move and separate from the roller 410, at this time, the fixture block 407 moves into the inner cavity of the fixing block 405 through the second sliding rod 412, the fixing block 405 is pulled to be clamped into the limiting groove of the heat exchange ring 401 at one side, after the handle is loosened, the first spring 414 can ensure that the first sliding rod 406 and the triangular plate 409 support the roller 410 by using self-pulling force, and ensure that the fixed blocks 405 on the two sides are reset and then extrude, limit and fix with the corresponding position adjusting shaft 404;

the sealing mechanism 7 can ensure the medium sealing processing capacity, provides a reset force for the displacement of the inner heat exchange tube 501 under the matching of the

elastic rings

705 and 706 at two sides, and supports the heat exchange outer tube 2 through the sealing ring 707 and the support ring 701 of the connection tube seat 1, and meanwhile, the sealing washer 704 can be sleeved outside the support ring 701 through the compression sleeve of the rear second spring 703, so that the tightness of the connection between the support ring 701 and the heat exchange outer tube 2 is ensured.

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

1. A high-strength heat collecting pipe comprises a connecting pipe seat (1), and is characterized in that one side of the connecting pipe seat (1) is movably connected with a plurality of sealing mechanisms (7), the other side of each sealing mechanism (7) is fixedly provided with a heat exchange outer pipe (2), the outer side wall of each heat exchange outer pipe (2) is adjustably connected with a heat exchange mechanism (4), the inner cavity of each heat exchange outer pipe (2) is slidably connected with an inner pipe mechanism (5), and one end, far away from the sealing mechanisms (7), of each heat exchange outer pipe (2) is fixedly provided with a sealing mechanism (3);

heat exchange mechanism (4) are including heat exchange ring (401), the equal fixedly connected with slider (408) in heat exchange ring (401) inner chamber both sides, slider (408) sliding connection is in spout (6) that heat exchange outer tube (2) one side was seted up, heat exchange ring (401) outer wall adjustable be connected with a plurality of heat transfer fins (402), heat exchange ring (401) inner chamber one side activity is inlayed and is equipped with fixed block (405), inner tube mechanism (5) are including interior heat exchange tube (501), interior heat exchange tube (501) lateral wall is encircleed and is inlayed and be equipped with a plurality of friction ball (502), and friction ball (502) and heat exchange outer tube (2) inner chamber one side laminate mutually, interior heat exchange tube (501) sliding connection is in heat exchange outer tube (2) inner chamber, friction ball (502) are located heat exchange tube (501) inboard bottom fixedly connected with spoiler (503).

2. The high-strength heat collecting tube as claimed in claim 1, wherein the turbulent heat absorbing plate (503) is a heat conducting metal member, and one side of the turbulent heat absorbing plate (503) is provided with a plurality of arc heat absorbing grooves.

3. The high-strength heat collecting pipe according to claim 1, characterized in that an inner pipe backing ring (506) is fixedly connected to the end of the inner heat exchanging pipe (501), and the inner pipe backing ring (506) is slidably connected to the inner cavity of the heat exchanging outer pipe (2).

4. The high-strength heat collecting pipe according to claim 3, characterized in that the outer side wall of the inner heat exchanging pipe (501) is sleeved with a joint pad (504), one side of the joint pad (504) is fixedly connected with an inner pipe sleeve (505), one side of the inner pipe sleeve (505) is fixedly connected with one side of an inner pipe backing ring (506), and the inner pipe sleeve (505) is jointed with the inner cavity of the heat exchanging outer pipe (2).

5. The high-strength heat collecting pipe according to claim 1, characterized in that the sealing mechanism (3) comprises a sealing pipe cap (301), one side of the sealing pipe cap (301) is fixedly connected with an elastic ring (303) through a sealing backing ring (302), one side of the elastic ring (303) is attached to one side of the inner heat exchanging pipe (501), one side of the sealing pipe cap (301) is communicated with a communicating pipe (304), the communicating pipe (304) is communicated with an external pump body, and one side of the sealing pipe cap (301) is detachably connected with one side of the outer heat exchanging pipe (2).

6. The high-strength heat collecting pipe according to claim 1, characterized in that an adjusting shaft (404) is fixedly connected to one side of the heat exchanging fins (402), the adjusting shaft (404) is slidably connected to a limiting groove formed in the outer side wall of the heat exchanging ring (401), and a plurality of limiting balls (403) are filled in the limiting groove.

7. The high-strength heat collecting pipe according to claim 5, characterized in that the fixing block (405) is connected in a clamping manner in an inner cavity of the limiting groove, a second sliding sleeve (413) is embedded in the inner cavity of the fixing block (405), a second sliding rod (412) is connected in the second sliding sleeve (413) in a sliding manner, a clamping block (407) is fixedly connected to the top end of the second sliding rod (412), the clamping block (407) is connected to the top of the inner cavity of the fixing block (405) in a sliding manner, the top of the clamping block (407) is attached to the corresponding position adjusting shaft (404), a supporting block (411) is fixedly connected to the bottom end of the second sliding rod (412), a roller (410) is fixedly connected to the bottom of the supporting block (411), a triangular plate (409) is attached to one side of the roller (410), a first sliding rod (406) is fixedly connected to one side of the triangular plate (409), and a handle is fixedly connected to one end of the first sliding rod (406), the outer side wall of the first sliding rod (406) is sleeved with a first sliding sleeve (413), the first sliding sleeve (413) is embedded in one side of an inner cavity of the fixed block (405), the outer side wall of the first sliding rod (406) is sleeved with a first spring (414), and two ends of the first spring (414) are fixedly connected with the first sliding sleeve (413) and one side of the handle in a corresponding position respectively.

8. The high-strength heat collecting pipe according to claim 1, characterized in that the sealing mechanism (7) comprises a supporting ring (701), both sides of the supporting ring (701) are fixedly connected with a limiting block (702), one side of the limiting block (702) is fixedly connected with a second spring (703), a sealing washer (704) is fixedly connected between the second springs (703) at both sides, the sealing washer (704) is sleeved outside the heat exchange outer pipe (2), one side of the connecting pipe seat (1) is embedded with a plurality of sealing rings (707), the sealing rings (707) are sleeved outside the supporting ring (701), and one side of the supporting ring (701) is fixedly connected with one side of the heat exchange outer pipe (2).

9. The high-strength heat collecting pipe according to claim 8, characterized in that an elastic ring (705) is embedded in the inner cavity of the support ring (701), both ends of one side of the elastic ring (705) are fixedly connected with elastic rods (706), an extrusion ring is fixedly connected between the elastic rods (706) of both sides, and the extrusion ring is fixedly connected with one side of the inner pipe mechanism (5).

10. The high-strength heat collecting pipe according to claim 1, characterized in that the inner cavity of the heat exchange outer pipe (2) is of a friction particle structure, and the friction particles in the inner cavity of the heat exchange outer pipe (2) are attached to the outer wall of the friction ball (502).