CN113865410A - Auxiliary installation equipment for heat exchanger and pipeline - Google Patents

Abstract

The invention discloses auxiliary installation equipment for a heat exchanger and a pipeline, which comprises an auxiliary component, wherein the auxiliary component comprises a supporting block and an installation shell, and one end of the installation shell is fixedly connected with one end of the supporting block; the connecting part comprises a heat exchanger and a heat through pipe, the heat through pipe is arranged on the supporting block, the heat exchanger is arranged in the mounting shell, and the heat exchanger is in butt joint with the heat through pipe; according to the invention, the consistent butt joint device is connected between the heat exchanger and the heat through pipe, so that the heat circulation in the heat through pipe can be controlled, the flowing speed of heat from the heat exchanger can also be controlled, the operation is simple, the environment is protected, the energy is saved, and hot air which does not reach the standard can be refluxed, so that the energy is saved.

Description

Auxiliary installation equipment for heat exchanger and pipeline

Technical Field

The invention relates to the technical field of auxiliary installation of heat exchangers, in particular to auxiliary installation equipment for a heat exchanger and a pipeline.

Background

The peak regulation system comprises an electric heating device, a heat supply pipe network and a first control device; the electric heating device is electrically connected with the bus through the step-down transformer, and obtains heating electric energy from the power grid to heat a heating medium in the electric heating device; the electric heating device is connected with the heat supply pipe network through the heat exchanger and is connected with the heat exchanger, and the heat of the heating medium is transmitted to the medium heated by the heat supply pipe network and is connected with the main heat supply pipe network through the heat exchanger; the frequency modulation system comprises a battery and a second control device; the battery is connected with the output end of the step-down transformer, and the power-on energy is obtained from a power grid and stored in the battery; and the main controller is connected with the first control device and the second control device. By setting the peak shaving system and the frequency modulation system to be matched with each other, the peak shaving capacity and the power production quality can be improved simultaneously.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. In this section, as well as in the abstract and the title of the invention of this application, simplifications or omissions may be made to avoid obscuring the purpose of the section, the abstract and the title, and such simplifications or omissions are not intended to limit the scope of the invention.

Therefore, the technical problems to be solved by the invention are that the traditional heat exchanger and the heat through pipe are directly connected, so that heat leakage is easily caused, the energy contained in hot air is uncontrollable, the output heat does not reach the standard, heat waste is easily caused, and the flow rate is uncontrollable.

In order to solve the technical problems, the invention provides the following technical scheme: the auxiliary installation equipment for the heat exchanger and the pipeline comprises an auxiliary component, wherein the auxiliary component comprises a supporting block and an installation shell, and one end of the installation shell is fixedly connected with one end of the supporting block; and the connecting part comprises a heat exchanger and a heat through pipe, the heat through pipe is arranged on the supporting block, the heat exchanger is arranged in the mounting shell, and the heat exchanger is in butt joint with the heat through pipe.

As a preferable aspect of the auxiliary installation apparatus for a heat exchanger and a pipe of the present invention, wherein: the mounting shell is provided with a placement groove, and the heat exchanger is mounted in the placement groove; and a plurality of threaded holes are formed in two side walls of the placement groove, and the heat exchanger is connected with the two side walls of the placement groove in the placement groove through bolts.

As a preferable aspect of the auxiliary installation apparatus for a heat exchanger and a pipe of the present invention, wherein: the hot siphunculus erects in the pipe chase on the supporting shoe, the cover is equipped with the back flow on the hot siphunculus, back flow and the inside intercommunication of hot siphunculus, the back flow is located the pipe chase, the diameter of pipe chase mid portion matches with the back flow diameter, and the diameter of pipe chase tip matches with the diameter of hot siphunculus.

As a preferable aspect of the auxiliary installation apparatus for a heat exchanger and a pipe of the present invention, wherein: the auxiliary component further comprises a pair of sealing rings, a first screw rod and a second screw rod, the sealing rings are sleeved on the heat through pipe, the return pipe is located between the two sealing rings, the first screw rod penetrates into the pipe groove from one end of the supporting block, the second screw rod penetrates into the pipe groove from the other end of the supporting block, and the first screw rod and the second screw rod are matched with the sealing rings.

As a preferable aspect of the auxiliary installation apparatus for a heat exchanger and a pipe of the present invention, wherein: the auxiliary component further comprises a threaded sleeve, the threaded sleeve is sleeved on the hot through pipe, a thread groove is formed in the outer wall of the hot through pipe, and the thread groove is in threaded fit with the inner wall of the hot through pipe.

As a preferable aspect of the auxiliary installation apparatus for a heat exchanger and a pipe of the present invention, wherein: the threaded sleeve is provided with a rotating handle.

As a preferable aspect of the auxiliary installation apparatus for a heat exchanger and a pipe of the present invention, wherein: still include regulating part, regulating part includes control and switching piece, adapting unit still includes the butt joint, is provided with the heat delivery head on the heat exchanger, the heat delivery head is connected to butt joint one end, and the hot siphunculus is connected to the other end, and the control is installed at the heat delivery head tip, the one end that the hot siphunculus is connected with the butt joint is installed to the switching piece.

As a preferable aspect of the auxiliary installation apparatus for a heat exchanger and a pipe of the present invention, wherein: a cavity is arranged in the heat through pipe, a ring partition plate is arranged on the inner circumference of the heat through pipe, the cavity is divided into a plurality of alternately arranged return cavities and pipe cavities by the ring partition plate, one end of each return cavity, far away from the butt joint, is arranged in a closed mode, the return cavities are communicated with the return pipe, and the switching pieces are respectively matched with the return cavities and the pipe cavities; the switching piece comprises a shaft column and rotating plates, the circumferences of the rotating plates are arranged on the outer wall of the shaft column, the number of the rotating plates is respectively consistent with that of the return cavity and the pipe cavity, and the positions of the rotating plates can respectively correspond to those of the return cavity and the pipe cavity.

As a preferable aspect of the auxiliary installation apparatus for a heat exchanger and a pipe of the present invention, wherein: the control piece comprises a steering ring plate and a fan plate, a connecting shaft is arranged on the fan plate, a plurality of inclined straight grooves are formed in the circumference of the steering ring plate, the circumference of the fan plate is arranged on the steering ring plate, and the connecting shaft is embedded into the straight grooves; the inner wall of the heat output head close to the outlet is provided with a ring groove, the outer wall of the steering ring plate is provided with an end plate, and the end plate is embedded in the ring groove.

As a preferable aspect of the auxiliary installation apparatus for a heat exchanger and a pipe of the present invention, wherein: the butt joint comprises a sleeve, a rib plate and a barrel cover, the sleeve is coaxially positioned in the barrel cover, one end of the rib plate is connected with the outer wall of the sleeve, the other end of the rib plate is connected with the inner wall of the barrel cover, the sleeve is sleeved on the shaft column, one end of the barrel cover is connected with the heat through pipe, and the other end of the barrel cover is covered on the heat output head.

The invention has the beneficial effects that: according to the invention, the consistent auxiliary butt joint device is connected between the heat exchanger and the heat through pipe, so that the heat circulation in the heat through pipe can be controlled, the flowing speed of heat from the heat exchanger can also be controlled, the operation is simple, the environment is protected, the energy is saved, and hot air which does not reach the standard can be refluxed, so that the energy is saved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise. Wherein:

fig. 1 is a structural view of an auxiliary member and a connecting member in the first embodiment.

Fig. 2 is a view showing an installation structure of the adjusting member, the auxiliary member and the connecting member in the first and second embodiments.

Fig. 3 is a mounting structure diagram of the switching member and the heat pipe in the second embodiment.

Fig. 4 is a connection structure diagram of two ends of the butt joint, the heat exchanger and the heat through pipe in the second and third embodiments.

Fig. 5 is an overall structure diagram of the adjusting member in the second and third embodiments.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described and will be readily apparent to those of ordinary skill in the art without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Furthermore, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 and 2, a first embodiment of the present invention provides an auxiliary installation apparatus for a heat exchanger and a pipe, which includes an auxiliary member 300 and a connection member 100, and the auxiliary member 300 is installed on the auxiliary member 300 and can assist in connecting the connection member 100.

The auxiliary component 300 comprises a supporting block 301 and an installation shell 302, one end of the installation shell 302 is fixedly connected with one end of the supporting block 301, the connecting component 100 comprises a heat exchanger 101 and a heat through pipe 102, the heat through pipe 102 is installed on the supporting block 301, the heat exchanger 101 is installed in the installation shell 302, and the heat exchanger 101 is in butt joint with the heat through pipe 102. Specifically, the heat exchanger 101 is provided with a heat output head 101a, the heat output head 101a is of a circular pipeline structure, the heat through pipe 102 is also of a circular pipeline structure, and the ends of the heat through pipe and the heat through pipe can be connected by aligning the same axis.

The mounting shell 302 is provided with a placing groove 302a, and the heat exchanger 101 is mounted in the placing groove 302 a; a plurality of threaded holes 302b are formed in two side walls of the placing groove 302a, hole grooves are formed in two sides of the heat exchanger 101, and the heat exchanger 101 is fixedly connected with the two side walls of the placing groove 302a through bolts 302c in the placing groove 302 a.

Be provided with chase 301a on supporting shoe 301, hot siphunculus 102 erects in chase 301a, chase 301 a's profile and hot siphunculus 102 outer wall match, and simultaneously, the cover is equipped with back flow C on the hot siphunculus 102, back flow C and the inside intercommunication of hot siphunculus 102, the steam that the temperature is not enough can circulate to the heat input head of hot siphunculus 102 through back flow C in the hot siphunculus 102, chase 301a mid portion's diameter matches with back flow C diameter, specifically, chase 301a tip's diameter is less than chase 301a mid portion's diameter, back flow C places chase 301a mid portion, hot siphunculus 102 erects at chase 301 a's two tip. The heat-pipe 102 can move on the support block 301 to facilitate moving away from or closer to the heat output stud 101 a.

The auxiliary component 300 further includes a pair of sealing rings 303, a first screw rod 304 and a second screw rod 305, the sealing rings 303 are provided and sleeved on the heat conduction pipe 102, the return pipe C is located between the two sealing rings 303, the first screw rod 304 penetrates into the pipe groove 301a from one end of the supporting block 301, the second screw rod 305 penetrates into the pipe groove 301a from the other end of the supporting block 301, the first screw rod 304 and the second screw rod 305 are matched with the sealing rings 303, where the matching means: the first screw rod 304 and the second screw rod 305 can be screwed to extrude towards the inside by rotating, two sealing rings 303 can be extruded to cling to two surfaces of the return pipe C, hot air is prevented from flowing out, and meanwhile, the first screw rod 304 and the second screw rod 305 extrude inwards to play a role in fixing the whole hot through pipe 102.

The auxiliary component 300 further comprises a threaded sleeve 306, the threaded sleeve 306 is sleeved on the heat through pipe 102, a threaded groove D is formed in the outer wall of the heat through pipe 102, the threaded groove D is in threaded fit with the inner wall of the heat through pipe 102, in the butt joint process, the threaded sleeve 306 is rotated, and due to the threaded fit with the outer wall of the heat through pipe 102, the heat through pipe 102 can move inwards or outwards to achieve the effect of being close to or far away from the heat output head 101 a.

Further, a rotating handle 306a is arranged on the threaded sleeve 306, an annular embedding hole 301a-1 is formed in the end portion of the pipe groove 301a, an annular embedding plate 306b is arranged on the outer wall of the threaded sleeve 306, and the annular embedding plate 306b is embedded into the annular embedding hole 301a-1 to limit the threaded sleeve 306.

Example 2

Referring to fig. 2 to 5, a second embodiment of the present invention is based on the previous embodiment, and further includes an adjusting member 200.

The connection member 100 includes a heat exchanger 101, a heat pipe 102, and a butt joint 103, the heat exchanger 101 is provided with a heat output head 101a, one end of the butt joint 103 is connected to the heat output head 101a, and the other end is connected to the heat pipe 102.

The adjusting component 200 comprises a control member 201 and a switching member 202, the control member 201 is installed at the end of the heat output head 101a, the switching member 202 is installed at one end of the heat through pipe 102 connected with the butt joint 103, two ends of the butt joint 103 can be respectively connected with the control member 201 and the switching member 202, and the on-off or reversing of the control member 201 and the switching member 202 can be respectively controlled.

Further, a chamber 102b is arranged in the heat-through pipe 102, a ring partition plate 102a is arranged on the inner circumference of the heat-through pipe 102, the ring partition plate 102a divides the chamber 102b into a plurality of spaces, each space is alternately arranged, and the adjacent spaces are a group: the heat exchanger is divided into a return cavity 102b-1 and a tube cavity 102b-2, a plurality of groups are formed by surrounding the partition plate 102a, one end of the return cavity 102b-1, which is far away from the butt joint 103, is arranged in a closed mode, the switching piece 202 is respectively matched with the return cavity 102b-1 and the tube cavity 102b-2, specifically, the switching piece 202 can rotate for a certain angle in the heat through pipe 102, the tube cavity 102b-2 can be opened when the return cavity 102b-1 is closed, and the return cavity 102b-1 can be opened when the tube cavity 102b-2 is closed.

The interior of the return cavity 102b-1 is communicated with the outside of the heat through pipe 102, the interior of the return pipe C is communicated with each return cavity 102b-1, meanwhile, the return pipe C is connected to the heat input head of the heat exchanger 101, when the insufficient heat of the passing hot air is detected, the switching piece 202 is switched, the return cavity 102b-1 is opened, the air enters the return cavity 102b-1, and then the air returns to the heat input head of the heat exchanger 101 through the return pipe C to exchange heat again.

If the heat of the hot air is detected to be sufficient, the switching element 202 is switched, the tube cavity 102b-2 is opened, and the hot air flows through the hot-air tube 102.

Further, the switch 202 includes a shaft column 202a and a rotating plate 202b, the rotating plate 202b is circumferentially disposed on the outer wall of the shaft column 202a, the number of the rotating plates 202b is respectively consistent with the number of the return cavities 102b-1 and the number of the tube cavities 102b-2, the position of the rotating plate 202b can respectively correspond to the positions of the return cavities 102b-1 and the tube cavities 102b-2, specifically, the rotating plate 202b can correspond to each return cavity 102b-1 and cover the entrance of the return cavity 102b-1, at this time, the entrance of the tube cavity 102b-2 is opened, the rotating shaft column 202a and the rotating plate 202b are also rotated by a certain angle, then the rotating plate 202b can cover the entrance of the tube cavity 102b-2, at this time, the entrance of the return cavity 102b-1 is opened.

The control member 201 comprises a steering ring plate 201a and a fan plate 201b, wherein a connecting shaft 201b-1 is arranged on the fan plate 201b, a plurality of inclined straight grooves 201a-1 are circumferentially arranged on the steering ring plate 201a, the fan plate 201b is circumferentially arranged on the steering ring plate 201a, and the connecting shaft 201b-1 is embedded in the straight grooves 201 a-1.

The fan plates 201b are arranged around the center of the steering ring plate 201a, and the space in the center of the steering ring plate 201a can be sealed by attaching each fan plate 201b to the adjacent fan plate 201 b.

Further, the control member 201 is arranged at the outlet end of the heat output head 101a and can rotate, the steering ring plate 201a is embedded in the inner wall of the outlet of the heat output head 101a, the steering ring plate 201a can move along the straight groove 201a-1, the steering ring plate 201a is rotated, the connecting shaft 201b-1 can move along the straight groove 201a-1, and the fan plate 201b rotates obliquely, at this time, the space in the center of the steering ring plate 201a can be gradually opened, and the larger the opening degree is along with the rotation of the steering ring plate 201a, the larger the opening degree is, the larger the reverse direction can close the outlet.

An annular groove 101a-1 is formed in the inner wall, close to the outlet, of the heat output head 101a, an end plate 201a-2 is arranged on the outer wall of the steering ring plate 201a, and the end plate 201a-2 is embedded in the annular groove 101 a-1.

The docking head 103 is sleeved on the shaft column 202a and can move on the shaft column 202a, the docking head 103 can be matched with the switch 202 and control the switch 202 to rotate when moving towards the rotating plate 202b, and the docking head 103 can be matched with the control member 201 and control the control member 201 to rotate when moving towards the fan plate 201 b.

Example 3

Referring to fig. 4 and 5, a third embodiment of the present invention is based on the previous embodiment, the docking head 103 includes a sleeve 103a, a rib 103b and a barrel cover 103c, the sleeve 103a is coaxially located in the barrel cover 103c, one end of the rib 103b is connected to the outer wall of the sleeve 103a, the other end is connected to the inner wall of the barrel cover 103c, the sleeve 103a is sleeved on the shaft column 202a, one end of the barrel cover 103c is connected to the heat pipe 102, and the other end is covered on the heat output head 101 a.

Furthermore, an annular caulking groove 102c is arranged at the end part of the heat through pipe 102, one end of the cylinder cover 103c extends into the caulking groove 102c, and one end of the cylinder cover 103c is always embedded into the caulking groove 102c when the butt joint 103 moves.

A plurality of clamping blocks 202a-1 are arranged on the circumference of the shaft column 202a, an inserting block 103a-1 is arranged at one end, facing the rotating plate 202b, of the sleeve 103a, and the inserting block 103a-1 is matched with gaps between adjacent clamping blocks 202a-1, wherein the matching means: a gap is reserved between adjacent fixture blocks 202a-1, the size of the gap is matched with that of the insertion block 103a-1, when the butt joint 103 is moved, the insertion block 103a-1 can be aligned with the gap and inserted into the gap, then the butt joint 103 is rotated, and the shaft column 202a rotates together to realize the rotation switching channel of the rotating plate 202 b.

The two annular partition plates 102a, which are relatively far away from each other, of the adjacent return cavity 102B-1 and the tube cavity 102B-2 are provided with straight plates a, specifically, in one set of the return cavity 102B-1 and the tube cavity 102B-2, the relatively far annular partition plate 102a extends and is provided with a straight plate a outwards, the straight plate a extends and is arranged to one end, close to the butt joint 103, of the heat pipe 102, the two straight plates a are provided with long grooves B, the two long grooves B are oppositely arranged, blocks 202B-1 are arranged on two sides of the rotating plate 202B, the blocks 202B-1 are matched with the long grooves B, one block 202B-1 is matched with one long groove B, and the other block 202B-1 is matched with the other long groove B, where the matching means: the block 202B-1 can be inserted along one of the slots B such that the rotating plate 202B corresponds to the return cavity 102B-1 or the lumen 102B-2, for example, the return cavity 102B-1, and then when the rotation is switched, another block 202B-1 is rotated into the corresponding slot B, and the straight plate a can block the rotating plate 202B from over-rotating, and at this time, the rotating plate 202B corresponds to the lumen 102B-2.

Further, the outer wall of the steering ring plate 201a is further provided with a limiting strip 201a-3, the limiting strip 201a-3 extends outwards and vertically, the inner wall of one end, close to the heat output head 101a, of the cylinder cover 103c is provided with a ring-shaped containing groove 103c-1, the limiting strip 201a-3 extends into the containing groove 103c-1, the inner wall of the cylinder cover 103c is circumferentially provided with a plurality of limiting grooves 103c-2, the limiting grooves 103c-2 are communicated with the containing groove 103c-1, and the limiting strip 201a-3 is matched with the limiting grooves 103c-2, wherein the matching refers to: when the butt joint 103 moves towards one end of the heat output head 101a, the limiting bar 201a-3 enters the limiting groove 103c-2 from the accommodating groove 103c-1 to be clamped, and then the butt joint 103 can be rotated to drive the steering ring plate 201a to rotate together.

When the butt joint 103 is in the middle area, the insertion block 103a-1 is not matched with the fixture block 202a-1, the limiting strip 201a-3 is located in the accommodating groove 103c-1, the butt joint 103 can be adjusted at the moment, the two ends cannot be affected, the butt joint 103 also plays a role in sealing the space between the heat output head 101a and the heat through pipe 102, and heat leakage is prevented.

It is important to note that the construction and arrangement of the present application as shown in the various exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperatures, pressures, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of this invention. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present inventions. Therefore, the present invention is not limited to a particular embodiment, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Moreover, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those unrelated to the presently contemplated best mode of carrying out the invention, or those unrelated to enabling the invention).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure, without undue experimentation.

It should be noted that the above-mentioned embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims (10)

1. The utility model provides an auxiliary erection equipment of heat exchanger and pipeline which characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the auxiliary component (300) comprises a supporting block (301) and a mounting shell (302), and one end of the mounting shell (302) is fixedly connected with one end of the supporting block (301); and the number of the first and second groups,

the connecting part (100) comprises a heat exchanger (101) and a heat through pipe (102), the heat through pipe (102) is installed on the supporting block (301), the heat exchanger (101) is installed in the installation shell (302), and the heat exchanger (101) is in butt joint with the heat through pipe (102).

2. An auxiliary heat exchanger and pipe mounting apparatus as claimed in claim 1, wherein: the mounting shell (302) is provided with a placement groove (302a), and the heat exchanger (101) is mounted in the placement groove (302 a);

a plurality of threaded holes (302b) are formed in two side walls of the placement groove (302a), and the heat exchanger (101) is connected with the two side walls of the placement groove (302a) through bolts (302c) in the placement groove (302 a).

3. An auxiliary installation apparatus for a heat exchanger and a pipe as claimed in claim 1 or 2, wherein: the hot runner pipe comprises a supporting block (301), and is characterized in that a pipe groove (301a) is formed in the supporting block (301), a hot runner pipe (102) is erected in the pipe groove (301a), a return pipe (C) is sleeved on the hot runner pipe (102) and communicated with the inside of the hot runner pipe (102), the return pipe (C) is located in the pipe groove (301a), the diameter of the middle part of the pipe groove (301a) is matched with that of the return pipe (C), and the diameter of the end part of the pipe groove (301a) is matched with that of the hot runner pipe (102).

4. An auxiliary heat exchanger and pipe mounting apparatus as claimed in claim 3, wherein: the auxiliary component (300) further comprises a sealing ring (303), a first screw rod (304) and a second screw rod (305), the sealing ring (303) is provided with a pair and sleeved on the heat through pipe (102), the return pipe (C) is located between the two sealing rings (303), the first screw rod (304) penetrates into the pipe groove (301a) from one end of the supporting block (301), the second screw rod (305) penetrates into the pipe groove (301a) from the other end of the supporting block (301), and the first screw rod (304) and the second screw rod (305) are matched with the sealing ring (303).

5. An auxiliary heat exchanger and pipe mounting apparatus as claimed in claim 4, wherein: the auxiliary component (300) further comprises a threaded sleeve (306), the threaded sleeve (306) is sleeved on the hot through pipe (102), a threaded groove (D) is formed in the outer wall of the hot through pipe (102), and the threaded groove (D) is in threaded fit with the inner wall of the hot through pipe (102).

6. An auxiliary heat exchanger and pipe mounting apparatus as claimed in claim 5, wherein: the threaded sleeve (306) is provided with a rotating handle (306 a).

7. An auxiliary installation apparatus for a heat exchanger and a pipe as claimed in claim 1 or 2, wherein: still include regulating part (200), regulating part (200) include control (201) and switch (202), connecting part (100) still include butt joint (103), are provided with heat output head (101a) on heat exchanger (101), heat output head (101a) are connected to butt joint (103) one end, and hot siphunculus (102) is connected to the other end, and control (201) are installed at heat output head (101a) tip, the one end that is connected at hot siphunculus (102) and butt joint (103) is installed in switch (202).

8. An auxiliary heat exchanger and pipe mounting apparatus as claimed in claim 7, wherein: a cavity (102b) is arranged in the heat through pipe (102), a ring partition plate (102a) is arranged on the inner circumference of the heat through pipe (102), the cavity (102b) is divided into a plurality of return cavities (102b-1) and pipe cavities (102b-2) which are alternately arranged by the ring partition plate (102a), one end, far away from the butt joint (103), of each return cavity (102b-1) is arranged in a closed mode, the return cavities (102b-1) are communicated with a return pipe (C), and the switching piece (202) is respectively matched with the return cavities (102b-1) and the pipe cavities (102 b-2);

the switching piece (202) comprises a shaft column (202a) and rotating plates (202b), the rotating plates (202b) are circumferentially arranged on the outer wall of the shaft column (202a), the number of the rotating plates (202b) is respectively consistent with that of the return cavity (102b-1) and the tube cavity (102b-2), and the positions of the rotating plates (202b) respectively correspond to those of the return cavity (102b-1) and the tube cavity (102 b-2).

9. An auxiliary heat exchanger and pipe mounting apparatus as claimed in claim 7, wherein: the control piece (201) comprises a steering ring plate (201a) and a fan plate (201b), a connecting shaft (201b-1) is arranged on the fan plate (201b), a plurality of inclined straight grooves (201a-1) are formed in the circumference of the steering ring plate (201a), the fan plate (201b) is circumferentially arranged on the steering ring plate (201a), and the connecting shaft (201b-1) is embedded into the straight grooves (201 a-1);

an annular groove (101a-1) is formed in the inner wall, close to the outlet, of the heat output head (101a), an end plate (201a-2) is arranged on the outer wall of the steering ring plate (201a), and the end plate (201a-2) is embedded in the annular groove (101 a-1).

10. An auxiliary heat exchanger and pipe mounting apparatus as claimed in claim 9, wherein: the butt joint (103) comprises a sleeve (103a), a rib plate (103b) and a barrel cover (103c), the sleeve (103a) is coaxially located in the barrel cover (103c), one end of the rib plate (103b) is connected with the outer wall of the sleeve (103a), the other end of the rib plate is connected with the inner wall of the barrel cover (103c), the sleeve (103a) is sleeved on the shaft column (202a), one end of the barrel cover (103c) is connected with the heat through pipe (102), and the other end of the barrel cover is covered on the heat output head (101 a).

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