US20140131021A1

US20140131021A1 - Heat exchanger pipe and manufacturing method therefor

Info

Publication number: US20140131021A1
Application number: US13/677,757
Authority: US
Inventors: Sung-hwan Choi
Original assignee: Individual
Current assignee: Individual
Priority date: 2012-11-15
Filing date: 2012-11-15
Publication date: 2014-05-15

Abstract

The present invention relates to a heat exchanger pipe, which enables heat exchange between fluid flowing along the interior of the pipe and fluid existing exterior of the pipe, and the manufacturing method therefor, in particular, a heat exchanger pipe and manufacturing method therefor such that enhances flow of fluid within the pipe's interior, increases heat exchange rate by making more contact, enhancing adherence property and sealing property between the outer pipe and the insertion in the interior of said outer pipe in the manufacturing process, and at the same time is easy to manufacture.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention
The present invention relates to a heat exchanger pipe, which enables heat exchange between fluid flowing along the interior of the pipe and fluid existing exterior of the pipe, and the manufacturing method therefor, in particular, a heat exchanger pipe and manufacturing method therefor such that enhances flow of fluid within the pipe's interior, increases heat exchange rate by making more contact, enhancing adherence property and sealing property between the outer pipe and the insertion in the interior of said outer pipe in the manufacturing process, and at the same time is easy to manufacture.
2. Description of the Related Art
Heat exchanger pipes, used in air conditioning and heating systems such as boilers, heat pumps, and air conditioners, are used to provide not only hot water or heated water, but also heat and cold by enabling heat exchange between fluid that flowing along the interior of the pipe and fluid existing exterior of the pipe.
Fluid flowing along the interior of the pipe is typically a gas such as hot combustion gas, and the fluid existing exterior of the pipe being a liquid such as direct water, the hot combustion gas typically provides hot water or heated water by exchanging heat with the direct water while flowing within the heat exchanger pipe, but there is no special limitation on each of the fluids, either liquid or gas, in the interior and exterior of the pipe.
Meanwhile, as shown in FIG. 1 Korean Registered Patent No. 10-217265 discloses a heat exchanger tube for heating boilers, including a cylindrical exterior tube 1 and a pair of half part shells 3 and 4 installed within said exterior tube 1, thus in contact with the exterior tube 1.
Also, the surface area is expanded by arranging multiple ribs 5 within the half part shells 3 and 4 like a comb, and the longitudinal contact edges of the half part shells 3 and 4 each form interlocking groove type recess 7 and rib type tongue 8 in attempt to improve sealing.
However, a heat exchanger tube as described above (i.e., heat exchanger pipe) is problematic in that their lengths are each adjusted so that the terminal of each of the ribs 5 are aligned(in line) and the flow of the interior fluid is minor, thus the heat contact amount between the fluid, the source of heat, and ribs 5 is insufficient.
Also, the exterior tube 1 and half part shells 3 and 4 are assembled through a adhering method of applying pressure evenly to the entire outer surface of said exterior tube 1, and the actual applied force Fr herein is applied orthogonal to each outer surface in the exterior tube 1, while the force Fn needed to forcefully adhere the groove type recess 7 and rib type tongue 8 is not identical in direction to said actual applied force, thus it is problematic that a gap is formed between the groove type recess 7 and rib type tongue 8.

SUMMARY OF THE INVENTION

In the present invention proposed in order to resolve the problems stated above are, in accomplishing heat exchange between fluid flowing along the interior of the pipe and fluid existing exterior of the pipe, a heat exchanger pipe and manufacturing method therefor such that enhances flow of fluid within the pipe's interior, increases heat exchange rate by making more contact, enhancing adherence property and sealing property between the outer pipe and the insertion in the interior of said outer pipe in the manufacturing process, and at the same time is easy to manufacture.
In order to achieve this, the heat exchanger pipe according to the present invention consists of a cylindrical outer pipe, a primary half part shell and secondary half part shell such that the outer surface is in contact with the inner surface of said outer pipe, if each comprises of a half-cylindrical form, and they are combined facing each other within the interior of said outer pipe, and the primary rib and secondary rib arranged orthogonal to the hypothetical boundary surface partitioning said primary half part shell and secondary half part shell, extending from each inner surface of said primary half part shell and secondary half part shell towards the interior space, but with a multiple of said primary rib, the length of said primary ribs are adjusted such that an ‘S’ shape is formulated when the terminals of said primary ribs are connected by an imaginary line, a multiple of said secondary rib, the length of said secondary ribs are adjusted such that an ‘S’ shape is formulated when the terminals of said secondary ribs are connected by an imaginary line, and the terminals of said primary rib and secondary rib are separated.
In this case, preferably a primary half part insertion consisting of said primary half part shell and primary rib and a secondary half part insertion consisting of said secondary half part shell and secondary rib are identically shaped through pressing out, but the cross section of said primary half part insertion and secondary half part insertion are bilaterally symmetrical.
Also, preferably terminals of both sides of said primary half part shell and terminals of both sides of secondary half part shell are each shaped in flat form, but a certain length from the terminal of said flat primary half part shell includes a primary bend bent towards said outer pipe, a certain length from the terminal of said flat secondary half part shell includes a secondary bend bent towards said outer pipe, the primary half part shell and secondary half part shell are inserted facing each other in the interior of said outer pipe and accordingly if pressure is applied on said outer pipe, said primary bend and secondary bend are straightened, and the flat terminal of said primary half part shell and the flat terminal of said secondary half part shell are adhered and joined.
Also, preferably multiple primary bumps are formed on the cross section of said primary half part shell, multiple secondary bumps are formed on the cross section of said secondary half part shell, thus pressure is applied on said outer pipe and when assembled said primary bumps and secondary bumps adhere as they interlock.
Also, preferably heat exchange grooves are formed on the surface of said outer pipe to expand surface area.
Also, preferably in the portions of both of the lengthwise terminals of said primary half part shell and secondary half part shell of said outer pipe, trap tongues, each projected towards each interior, are formed to prevent said primary half part shell and secondary half part shell from breaking away from said outer pipe.
Meanwhile, the heat exchanger pipe manufacturing method according to the present invention consists steps of preparing an insertion such that said primary half part shell and secondary half part shell are placed erect on top of a upper portion table identical to the diameter of said primary half part shell and secondary half part shell combined facing each other, preparing an outer pipe that enables placing said outer pipe erect on top of a lower portion table, such that supports the lower part of said upper portion table but has a larger diameter than said upper portion table, such that said primary half part shell and secondary half part shell are placed within the interior of said outer pipe, preparing to apply pressure to place the dies mold, such that is equipped with a taper component in the interior of the lower side and a pressure applying component in the interior of the upper side of said taper component, the diameter of the lower part of said taper component identical to the external diameter of said outer pipe, the diameter of said pressure applying component identical to the external diameter of said primary half part shell and secondary half part shell combined, on the upper side of said outer pipe, in a condition such that said dies mold is descended until the outer pipe is inserted in the interior of said dies mold, pushing down said dies mold to apply pressure on the outer pipe with said pressure applying component so that the inner surface of said outer pipe is adhered to the outer surface of said primary half part shell and secondary half part shell.
According to the heat exchanger pipe of the present invention described above, since the length of each rib is adjusted such that the terminals of the ribs equipped in each the primary half part shell and secondary half part shell to form an ‘S’ shape, the flow of fluid flowing within the interior of the pipe is further enhanced and more contact is made to increase heat exchange rate.
Also, according to the heat exchanger pipe manufacturing method in the present invention, by having a bend that bends identical in direction with the actual applied force when pressure is applied to the outer pipe, adherence property and sealing property between the outer pipe and the insertion in the interior of said outer pipe in the manufacturing process are enhanced, and at the same time manufacturing is made easy since adhesion of the outer pipe and insertion is achieved simply by inserting and pushing the dies mold.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional diagram displaying a heat exchanger pipe(heat exchange tube) according to prior art;

FIG. 2 is a perspective view displaying a heat exchanger pipe according to the first embodiment of the present invention;

FIG. 3 is a cross-sectional diagram displaying a heat exchanger pipe according to the first embodiment of the present invention;

FIG. 4 is a cross-sectional diagram displaying a heat exchanger pipe according to the second embodiment of the present invention;

FIG. 5 is a partial cross-sectional diagram displaying a heat exchanger pipe according to the third embodiment of the present invention;

FIG. 6 is a partial cross-sectional diagram displaying a heat exchanger pipe according to the fourth embodiment of the present invention;

FIG. 7 is a perspective view displaying a heat exchanger pipe according to the fifth embodiment of the present invention;

FIG. 8 is a perspective view displaying a heat exchanger pipe according to the sixth embodiment of the present invention;

FIG. 9 is a diagram showing the heat exchanger pipe manufacturing method according to the embodiments of the present invention;

DETAILED DESCRIPTION OF THE INVENTION

Hereinafter, with reference to the attached drawings, preferable embodiments of the trap apparatus for heat exchanger pipe and manufacturing method therefor will be described in detail.
First, the heat exchanger pipe 20 according to the first embodiment of the present invention, as in the perspective view of FIG. 2 and the cross-sectional diagram of FIG. 3, includes a cylinder shaped outer pipe 21, and a primary half part insertion 22, 23 and secondary half part insertion 24, 25 inserted in the interior or said outer pipe 21. For example the outer pipe 21 is made of metal such as steel, and the primary half part insertion 22, 23 and secondary half part insertion 24, 25 are made of aluminum.
In this case, the primary half part insertion 22, 23 consists of a primary half part shell 22 in semicylinder form, the cylinder cut along its length, and multiple primary ribs 23 on said primary half part shell 22. Similarly, the secondary half part insertion 24, 25 consists of a secondary half part shell 24 and multiple secondary ribs 25.
Also, the terminal F of the primary half part shell 22 and the terminal F′ of the secondary half part shell 24 each consist of flat sides, so that when the terminals of the primary half part shell 22 and secondary half part shell 24 which are arranged to face each other are tightly assembled through adhesion, leakage of the fluid flowing along the interior of the primary half part shell 22 and secondary half part shell 24 part shell 22 through the gap between the secondary half part shell 24 is prevented.
Also, the primary ribs 23, installed at regular intervals, extend from the inner surface of the primary half part shell 22 towards the interior space, and the secondary ribs 25, installed at regular intervals, extend from the inner surface of the secondary half part shell 24 towards the interior space, both the primary ribs 23 and secondary ribs 25 arranged orthogonal to the hypothetical boundary surface partitioning said primary half part shell 22 and secondary half part shell 24.
In particular, in the present invention the length of said primary ribs 23 and secondary ribs 25 are each adjusted such that an ‘S’ shape is formulated when the terminals of each are connected by an imaginary line, and the terminals of the primary ribs 23 and secondary ribs 25 that face each other above and below are separated from contact.
For example, according to the figure, the primary ribs 23 are sequentially places the 1^st primary rib 23 a to the 6^th primary rib 23 f starting from the left, wherein the 2^ndsecondary rib 25 b is longer than the 1^st primary rib 23 a, and the 3^rd primary rib 23 c is shorter than the 2^nd primary rib 23 b.
Also, the lengths are adjusted such that the 4^th primary rib 23 d is longer than the 3^rd primary rib 23 c, the 5^th primary rib 23 e is shorter than the 4^th primary rib 23 d, the 6^th primary rib 23 f is shorter than the 5^th primary rib 23 e.
Therefore, when the terminals of the 1^st primary rib 23 a to 6^th primary rib 23 f are connected by an imaginary line, an overlap of two ‘S’ shapes(as shown by a dotted line in FIG. 3) is formed.
Like the primary ribs 23, the secondary ribs 25 also consist of six ribs, formulates an overlap of two ‘S’ shapes when the terminals of the 1^stto 6^th secondary ribs 25 are connected by an imaginary line, and these primary ribs 23 and secondary ribs 25 are separated from contact.
Accordingly, conventionally the terminals of each rib(refer to 5 in FIG. 1) of the heat exchanger tube were aligned(in line) to formulate a comb shape and the flow of interior fluid was minor, but the present invention further includes an ‘S’ shaped flow component, thereby the fluid flowing along the interior side of the primary half part shell 22 and secondary half part shell 24 further fluctuates to increase the amount of heat contact among said fluid and the primary and secondary ribs 23 and 25.
Also, the amount of heat contact increases as there is more contact between a heat source fluid such as hot combustion gas and the primary and secondary ribs 23 and 25, and heat delivery to the outer pipe 21 in contact with the primary half part shell 22 and secondary half part shell 24 increases, thus heat exchange with for example, direct water exterior of the outer pipe 21 is made more efficient.
Yet, the primary half part insertion 22, 23 is formed by pressing out the primary half part shell 22 and primary rib 23 together, the secondary half part insertion 24, 25 is formed by pressing out the secondary half part shell 24 and secondary rib 25 together, and if the primary half part insertion 22, 23 and secondary half part insertion 24, 25 use the same formation cast, the cost of manufacturing can be minimized.
Of course, in this case the primary half part insertion 22, 23 and secondary half part insertion 24, 25 must be assembled such that their sides are bilaterally symmetrical.
Hereinafter, the heat exchanger pipe according to the second embodiment of the present invention is described with reference to the attached figures.
As shown in FIG. 4, the heat exchanger pipe 30 following the second embodiment of the present invention consists of a cylinder shaped outer pipe 31 and the primary half part insertion 32, 33 and secondary half part insertion 34, 35 inserted within the interior of said outer pipe 31.
In this case, the primary half part insertion 32, 33 consists of the primary half part shell 32 and multible primary ribs 33, the secondary half part insertion 34, 35 consists of the secondary half part shell 34 and multiple secondary ribs 35. This point is equivalent to the first embodiment of the present invention explained above.
However, the heat exchanger pipe according to the second embodiment of the present invention consists of the primary ribs 33, sequentially placing the 1^st primary rib 23 to the 5^th primary rib 23 starting from the left of the figure, and the secondary ribs 35, also consisting of five ribs, such that an ‘S’ shape is formed when the terminals of the five primary ribs 33 are sequentially connected, and the same for the secondary ribs 25.
In other words, the first embodiment as explained through FIG. 3, consists of six ribs(refer to 23, 25 of FIG. 3), while the second embodiment of the present invention consists of five ribs 33, 35, thereby the change in number of ribs can somewhat change the ‘S’ shape, but the invention allows increasing the heat exchange rate by increasing fluid flow even in this case.
Hereinafter, referring to the attached figures the heat exchanger according to the third embodiment of the present invention is explained.
Yet, the third embodiment of the present invention is based on the first embodiment, thus the differences are mainly shown and explained.
As shown in (a) and (b) of FIG. 5, the heat exchanger pipe according to the third embodiment of the present invention includes the primary half part insertion 22, 23 and secondary half part insertion 24, 25 inserted in the interior of the cylinder shaped outer pipe(refer to 21 of FIG. 2), the primary half part insertion 22, 23 consisting of the primary half part shell 22 and multiple primary ribs 23, the secondary half part insertion 24, 25 consisting of the secondary half part shell 24 and multiple secondary ribs 25. This point is identical to the primary embodiment of the present invention explained above.
However, the third embodiment of the present invention includes the primary bend 22 a and secondary bend 24 a, used when assembling both terminals of the primary half part shell 22 and both terminals of the secondary half part shell 24, the primary bend 22 a and secondary bend 24 a are distinguishable by observing each bending outward based on each the primary bent side 22 a′ and secondary bent side 24 a′.
In other words, both terminals of the primary half part shell 22 and both terminals of the secondary half part shell 24 each consist of flat forms, herein a certain length from the terminal of the flat primary half part shell 22 as in (a) of FIG. 5 includes a primary bend bent 22 a towards the outer pipe 31, and a certain length from the terminal of the flat secondary half part shell 24 includes a secondary bend 24 a bent towards said outer pipe 31.
Thus, as (b) of FIG. 5, when pressure is applied during assembling, in the process such that the outer pipe 21 is compressed and adhered to the outer surface of the primary half part shell 22 and secondary half part shell 24, the primary bend 22 a and secondary bend 24 a are pressed and spread to the inner side, and the flat terminal of the primary half part shell 22 and the flat terminal of the secondary half part shell 24 are slightly oppressed and transformed and eventually tightly assembled together through adhesion.
Therefore, conventionally the force actually applied during assembly(refer to ‘Fr’ of FIG. 1) is applied orthogonal to the outer surface of each exterior tube 1, while the force(refer to ‘Fn’ of FIG. 1) needed to tightly adhere the groove type recess 7 and rib type tongue 8 is not identical in direction to the actual applied force, thus the problem regarding the gap formed between the groove type recess 7 and rib type tongue 8 is resolved.
In addition, as the fourth embodiment of the present invention shown in FIG. 6, if multiple primary bumps 22 b are formed on the flat side of the primary half part shell 22 and multiple secondary bumps(not shown) are formed on the flat side of the secondary half part shell 24, pressure can be applied evenly on the outer pipe 21 as above and when assembled said primary bumps 22 b and secondary bumps adhere better as they interlock.
Of course, if slight incision grooves 22 c are made in each bent sides of the primary bend 22 a and secondary bend 24 a, when the outer pipe 21 is assembled by equally applying pressure on the entire pipe, the direction the primary bend 22 a and secondary bend 24 a are straightened is directed, thus can be assembled easily.
Hereinafter, referring to the attached figures, the heat exchanger according to the fifth embodiment is explained.
As shown in FIG. 7, the heat exchanger pipe according to the fifth embodiment of the present invention includes an outer pipe 41 and an insertion 42, as described above, which consists of a primary half part insertion and secondary half part insertion. This point is equivalent to explanations above.
However, in the fifth embodiment of the present invention a heat exchange groove 41 a is formed on the surface of the outer pipe 41 in order to expand surface area, thus heat of the fluid (i.e., hot combustion gas etc.) flowing within the interior of the outer pipe 41 can be more efficiently transferred to the fluid(i.e., direct water etc.) filling the exterior of the outer pipe 41.
Yet, FIG. 7 exemplifies the formation of multiple of the linear shaped heat exchange grooves formed along the length of the outer pipe 41 around the outer pipe 41 along the circumference, but forming multiple of them along the circumference of the outer pipe 41 or along the length of the circular heat exchange groove with regular intervals and forming heat exchange grooves on the outer surface of the outer pipe 41 along various patterns such as a spiral helix are also possible.
Hereinafter, the heat exchanger pipe according to the sixth embodiment of the present invention is explained in reference to the attached figures.
As shown in FIG. 8, the heat exchanger pipe 50 according to the sixth embodiment of the present invention includes an outer pipe 51 and an insertion 52, as described above, which consists of a primary half part insertion and secondary half part insertion.
In particular, a trap tongue 51 a projecting towards the inner side on which said insertion 52 is inserted is formed at both terminals of the outer pipe 51, and the trap tongues 51 a are formed on both length-wise terminals of the insertion 52 in the outer pipe 51.
Therefore, since the insertion 52 is sturdily fixed without moving towards the terminal of one side or the other of the outer pipe 51, by applying pressure to the entire outer pipe the concerned insertion 52 is prevented from breaking away from the outer pip 51 after the inner surface of the outer pipe 51 and the outer surface of the insertion 52 are assembled to be in contact.
Hereinafter, the manufacturing method of the heat exchanger pipe as in the embodiments of the present invention above is explained. Yet, as an example, the manufacturing method of a heat exchanger pipe according to the first embodiment of the present invention explained with reference to FIG. 2 will be explained hereinafter.
First, as shown in (a) of FIG. 9, tables T, T′ are prepared for the manufacture of heat exchangers according to the present invention. Tables T, T′ consist of a lower portion table T and an upper portion table T′ fixed on top of said lower portion table T.
The upper portion table T′ is of size identical to the diameter of the primary half part shell 22 and secondary half part shell 24 assembled to each other, thus the primary half part shell 22 and secondary half part shell 24 can be stably put on top, and the lower portion table T has a bigger diameter than the upper portion table T′, so the outer pipe 21 can be put.
Next, as (b) of FIG. 9, the primary half part shell 22 and secondary half part shell 24 assembled facing each other is put erect on top of the upper portion table T′. In other words, the primary half part insertion 22, 23 and secondary half part insertion 24, 25 are prepared(insertion preparation step).
Next, as (c) of FIG. 9, the outer pipe 21′ of the prototype is put erect on top of the lower portion table so that the primary half part shell 22
secondary half part shell 24 are put within the inner side of the outer pipe 21′ (outer pipe preparation step). The unprocessed outer pipe 21′ of the prototype has a diameter bigger than the diameter of the assembled primary half part shell 22 and secondary half part shell 24 put together, thus can be inserted through the upper part of the primary half part shell 22 and secondary half part shell 24.
Next, as D of FIG. 9, the interior of the inner side is furnished with a taper component, which narrows down in width towards the upper side, the upper side of said taper component is equipped with a pressure applying component, the lower part diameter of the taper component is identical(or, may be slightly bigger) in diameter with the outer pipe 21, and the diameter of the pressure applying component arranges a dies mold D, with diameter equivalent to (or, may be slightly smaller) the diameter of the primary half part shell 22 and secondary half part shell 24 put together, at the upper side of the outer pipe 21(preparation step to apply pressure).
Next, as (e) of FIG. 9, in a condition such that said dies mold D is descended until the circular outer pipe 21′ is inserted in the interior of said dies mold D, pressure is applied so that said dies mold D is pushed down to to apply pressure on the circular outer pipe 21′ with the pressure applying component, and the inner surface of the outer pipe 21 such that the circular outer pipe 21′ is contracted is adhered to the outer surface of said primary half part shell 22 and secondary half part shell 24, thus manufacturing of the heat exchanger pipe is made convenient and simple.
In conclusion, the embodiments of the present invention have been described. However, those skilled in the art will appreciate that the spirit and scope of the present invention are not limited to the specific embodiments, but various modifications and transformations are possible, without departing from the essence of the invention.
Therefore, the described preferred embodiments are provided to illustrate the scope of the invention to those skilled in the art, are foreshadowing in all aspects and must be understood as not being limiting. The scope of the present invention will be defined in the accompanying claims.

Claims

What is claimed is:

1. A heat exchanger pipe wherein consists of

a cylindrical outer pipe,

a primary half part shell and secondary half part shell such that the outer surface is in contact with the inner surface of said outer pipe, if each comprises of a semicylinder form, and they are combined facing each other within the interior of said outer pipe,

and the primary rib and secondary rib arranged orthogonal to the hypothetical boundary surface partitioning said primary half part shell and secondary half part shell, extending from each inner surface of said primary half part shell and secondary half part shell towards the interior space, but with

a multiple of said primary rib, the length of said primary ribs are adjusted such that an ‘S’ shape is formulated when the terminals of said primary ribs are connected by an imaginary line,

a multiple of said secondary rib, the length of said secondary ribs are adjusted such that an ‘S’ shape is formulated when the terminals of said secondary ribs are connected by an imaginary line,

and the terminals of said primary rib and secondary rib are separated.

2. The heat exchanger pipe in claim 1, wherein

a primary half part insertion consisting of said primary half part shell and primary rib and a secondary half part insertion consisting of said secondary half part shell and secondary rib are identically shaped through pressing out, but the cross section of said primary half part insertion and secondary half part insertion are bilaterally symmetrical.

3. The heat exchanger pipe in claim 2, wherein

terminals of both sides of said primary half part shell and terminals of both sides of secondary half part shell are each shaped in flat form, but

a certain length from the terminal of said flat primary half part shell includes a primary bend bent towards said outer pipe, a certain length from the terminal of said flat secondary half part shell includes a secondary bend bent towards said outer pipe,

the primary half part shell and secondary half part shell are inserted facing each other in the interior of said outer pipe and accordingly if pressure is applied on said outer pipe, said primary bend and secondary bend are straightened, and the flat terminal of said primary half part shell and the flat terminal of said secondary half part shell are adhered and joined.

4. The heat exchanger pipe in claim 3, wherein

multiple primary bumps are formed on the cross section of said primary half part shell, multiple secondary bumps are formed on the cross section of said secondary half part shell, thus pressure is applied on said outer pipe and when assembled said primary bumps and secondary bumps adhere as they interlock.

5. The heat exchanger pipe in claim 1, wherein

heat exchange grooves are formed on the surface of said outer pipe to expand surface area.

6. The heat exchanger pipe in claim 1, wherein

In the portions of both of the length-wise terminals of said primary half part shell and secondary half part shell of said outer pipe, trap tongues, each projected towards each interior, are formed to prevent said primary half part shell and secondary half part shell from breaking away from said outer pipe.

7. The heat exchanger pipe manufacturing method that manufactures a heat exchanger pipe identical to that in claim 1, wherein consists steps of:

preparing an insertion such that said primary half part shell and secondary half part shell are placed erect on top of a upper portion table identical to the diameter of said primary half part shell and secondary half part shell combined facing each other,

preparing an outer pipe that enables placing said outer pipe erect on top of a lower portion table, such that supports the lower part of said upper portion table but has a larger diameter than said upper portion table, such that said primary half part shell and secondary half part shell are placed within the interior of said outer pipe,

preparing to apply pressure to place the dies mold, such that is equipped with a taper component in the interior of the lower side and a pressure applying component in the interior of the upper side of said taper component, the diameter of the lower part of said taper component identical to the external diameter of said outer pipe, the diameter of said pressure applying component identical to the external diameter of said primary half part shell and secondary half part shell combined, on the upper side of said outer pipe,

in a condition such that said dies mold is descended until the outer pipe is inserted in the interior of said dies mold, a pressure application step in which said dies mold is pushed down to apply pressure on the outer pipe with said pressure applying component so that the inner surface of said outer pipe is adhered to the outer surface of said primary half part shell and secondary half part shell.

8. The heat exchanger pipe manufacturing method that manufactures a heat exchanger pipe identical to that in claim 2, wherein consists steps of:

9. The heat exchanger pipe manufacturing method that manufactures a heat exchanger pipe identical to that in claim 3, wherein consists steps of:

10. The heat exchanger pipe manufacturing method that manufactures a heat exchanger pipe identical to that in claim 4, wherein consists steps of:

11. The heat exchanger pipe manufacturing method that manufactures a heat exchanger pipe identical to that in claim 5, wherein consists steps of:

12. The heat exchanger pipe manufacturing method that manufactures a heat exchanger pipe identical to that in claim 6, wherein consists steps of: