KR200343598Y1 - structure for assembling spiral tube of heating exchange - Google Patents

Abstract

According to the present invention, in a heat exchanger in which an end portion of a spiral tube is joined to a through hole and the tube tube is positioned inside the fuselage, and the protection cap is fixed to the tube plate by bolts and nuts, the direction of the left and right screws on the outer circumferential surface is different. Spiral tube is formed to form a spiral to be mixed, and the reinforcing ring penetrated to the end of the spiral tube is attached to the through hole of the tube plate, thereby maintaining the airtightness of the tube body and the spiral tube, as well as the tube plate and spiral tube It prevents potential corrosion by blocking direct contact of the tube and prevents the tube from thinning when expanding the spiral tube.It can be used safely.If the spiral tube or spiral tube has aged, the spiral tube can be removed. Not only can replacement work be done from the tube sheet, but it also reduces work time. It improves the economics and forms spirals on the outer circumferential surface of the spiral tube to mix the shape of the left and right screws to control the speed of water flowing into the spiral tube, and forms a turbulent layer, which increases thermal efficiency and reduces the consumption of raw materials. It relates to a spiral tube assembly structure of the heat exchanger to improve the economics.

Description

Structure for assembling spiral tube of heating exchange

The present invention relates to a heat exchanger, and more particularly, to an assembly structure of a spiral tube which is installed to supply hot water heated to a kitchen or a bathroom.

In general, the heat exchanger 10 is capable of heating water by heat of burning gas or oil, and supplying the heated water to a bathroom or a sink, as shown in FIG. The exhaust pipe is formed on the outer circumferential surface, and both sides of the fuselage 11 are provided. The pipe plate 12 having the through-hole 12a formed at regular intervals on both sides of the fuselage 11 is welded. After installing the spiral tube 13 in the through hole 12a of the tube plate 12, the end of the spiral tube 13 is expanded and fixed, and a protective cap having an inlet pipe and an exhaust pipe formed at the end of the tube plate 12. (14) is in close contact and secured with bolts and nuts.

In addition, the spiral tube 13 installed in the through-hole 12a of the tube plate 12 is supplied to the inside of the pressure roller (not shown), when the tube is rotated, the pressure roller is rotated to spiral around the tube, that is, the outer peripheral surface Is molded as shown in FIG.

However, the conventional heat exchanger configured as described above has a problem in that dislocation corrosion occurs because the end portion of the spiral tube of the copper plate having the outer diameter of the spiral is directly contacted with the metal tube plate through-hole, and the splice is coupled to the through-hole of the tube plate. When expanding the end of the tube, there is a problem that the end of the tube becomes weaker and thinner.

In addition, if the end of the spiral tube is extended and fixed to the through hole of the tubular body, the spiral diameter of the spiral tube is larger than the through hole of the tubular tube, so even if an abnormality is found in the spiral tube during the manufacturing process, the spiral tube cannot be replaced. Not only inconvenient to use, but even had to replace the fuselage had a problem.

In addition, the spiral of the spiral tube is formed only in one direction to increase the flow rate of water introduced into the spiral tube, and the cold water supplied by the increased flow rate is discharged before being converted into hot water, thereby lowering the reliability of the product. In order to convert the cold water into hot water, it has to be heated and converted to a higher temperature, thereby lowering the economics due to waste of raw materials.

The present invention was made in view of the above-mentioned conventional defects, and its object is to heat the reinforcing ring of the same material having a smaller inner diameter than the outer diameter of the spiral tube and to couple to the end of the spiral tube, thereby ensuring the airtightness of the tubular body and the spiral tube. In addition, it prevents potential corrosion by blocking direct contact between the tube plate and the spiral tube, and prevents the thickness of the tube from thinning when expanding the spiral tube, thereby providing a spiral tube assembly structure of the heat exchanger that can be used safely.

In addition, another object of the present invention, when the aging spiral tube or spiral tube breakage, spiral tube assembly of heat exchanger that can not only replace the spiral tube from the tube plate, but also improve the economics by reducing the working time In providing a structure.

In addition, another object of the present invention is to form a spiral on the outer circumferential surface of the spiral tube so that the shape of the left and right screws are mixed, controlling the speed of water introduced into the spiral tube, and forming a turbulent layer to increase the thermal efficiency It is to provide a spiral tube assembly structure that improves the economic efficiency by reducing the consumption of.

The present invention for achieving the above object is, the heat exchanger for coupling the end of the spiral tube to the through hole and the tube plate placed inside the fuselage and fixing the protective cap formed with the inlet pipe and the exhaust pipe to the tube plate with bolts and nuts. In the phase,

A spiral tube forming a spiral such that a direction of left and right screws is mixed on an outer circumferential surface thereof;

The reinforcing ring penetrates the inside of the spiral tube and is mounted to the through hole of the tube plate.

1 is a partial cross-sectional view showing a typical heat exchanger

Figure 2 is a front view showing a spiral tube mounted to a typical heat exchanger

3 is an exploded perspective view of the present invention

4 is a cross-sectional view of the installation state of the present invention

Figure 5 shows the state of use of the subject innovation,

a is a state in which the reinforcing ring is moved to the through hole of the tube plate,

b shows a state in which the spiral of the spiral tube is moved to the through-hole of the tube plate.

<Explanation of symbols for the main parts of the drawings>

10: heat exchanger 11: fuselage

12: tube sheet 12a: through hole

13: spiral tube 14: protective cap

100: reinforcing ring

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 3 is an exploded perspective view of the present invention, Figure 4 is a cross-sectional view of the installation state of the present invention.

According to the present invention, a tube plate 12 having an end portion of a spiral tube 13 coupled to a through hole 12a and expanded is placed inside the body 11, and the tube plate 12 has an inlet pipe and an exhaust pipe formed therein. In the heat exchanger which fixes the cap 14 with a bolt and a nut,

Spiral tube 100 is formed to form a spiral so that the direction of the left and right screw is mixed on the outer circumferential surface, and coupled to the end of the spiral tube 100 through the reinforcing ring 200 through the tube plate 12 To be mounted in the through hole 12a, which will be described in more detail as follows.

The inner diameter of the reinforcing ring 200 is molded smaller than the outer diameter of the spiral tube 100.

The outer diameter of the reinforcing ring 200 is formed larger than the spiral outer diameter of the spiral tube 100.

The following describes the combining process and use process of the present invention configured as described above.

First, to form a spiral tube 100 to form a spiral so that the direction of the left screw and the right screw mixed on the outer peripheral surface, the reinforcement ring to be smaller than the outer diameter of the spiral tube 100 and the spiral tube 100 and the material (reinforcement ring ( 200 is molded, and heat is applied to the reinforcing ring 200 to be coupled to the end of the spiral tube 100 in the expanded state.

In this case, the reinforcing ring 200 coupled to the end of the spiral tube 100 is cooled and contracted with time, thereby being firmly coupled to the spiral tube 100.

Spiral tube 100 coupled to the reinforcing ring 200 is coupled to the through hole 12a of the tube plate 12 mounted on the body 11 as described above, and then expands the end of the spiral tube 100 to reinforce the ring. The outer circumferential surface of the 100 is firmly fixed to the through hole 12a of the tube plate 12.

After fixing the spiral tube 100 to which the reinforcing ring 200 is coupled to the through hole 12a of the tube plate 12 in the same manner as above, the fuselage body 100 is positioned inside the fuselage 11. The tube plate 12 is welded and fixed to one end of the 11, and the other side of the spiral tube 100 is fixed to the tube plate in the same manner as described above, and welded to the other end of the body 11.

The protection cap 14 having the inlet pipe and the exhaust pipe formed on both side ends of the fuselage 11 in which the fixed tube plate 12 is fixed is tightly fixed and fixed with bolts and nuts, thereby completing the heat exchanger 10.

To heat and heat the completed heat exchanger 10 as described above, when water flows into the inside of the spiral tube 100 in which spirals are formed so that the left and right screw directions are mixed, the right side of the left screw spirals is moved. As the direction of the screw turns, the turbulent layer is formed, and the water moves without increasing the flow rate due to the direction from the left screw's spiral to the right screw's spiral and the right screw's spiral to the left screw's spiral. It is converted into hot water, and the user can use the water converted into hot water.

On the other hand, if an abnormality occurs in the spiral tube 100 during use or the aging of the heat exchanger 10, the protective cap 14 is removed from the body 11, then the spiral tube 100 and the reinforcing ring ( The expanded portion of the 200 is pressed to be smaller than the diameter of the through hole 12a.

When the end diameters of the spiral tube 100 and the reinforcing ring 200 pressurized are smaller than the diameter of the through hole 12a, the spiral tube 100 is pushed out of the tube plate 12 as shown in FIG. 5A. Move to.

At this time, since the diameter of the reinforcing ring 200 coupled to the spiral tube 100 is larger than the spiral diameter of the spiral tube 100, the reinforcing ring 200 is separated from the through hole 12a and at the same time, The helix is deviated, as shown in FIG. 5B.

As described above, when the spiral tube 100 is separated from the through hole 12a of the tube plate 12, the spiral tube 100 can be easily replaced with a new spiral tube combined with a reinforcing ring.

In addition, the reinforcing ring 200, in one embodiment of the present invention, but described as an example of a spiral tube 100 mixed with the spiral of the left screw and the right screw, but may be used by applying to the conventional spiral tube 13 will be.

As described above, the present invention heats the reinforcing ring of the same material having a smaller inner diameter than the outer diameter of the spiral tube, so that it is coupled to the end of the spiral tube, thereby maintaining the airtightness of the tubular body and the spiral tube and blocking direct contact between the tube plate and the spiral tube. This prevents potential corrosion and prevents the tube from becoming thin when the spiral tube is expanded, so it can be used safely.

In addition, the present invention, when the aging spiral tube or spiral tube breakage occurs, it is possible to replace the spiral tube from the tube plate as well as the advantage of improving the economics by reducing the working time.

In addition, the present invention forms a spiral on the outer circumferential surface of the spiral tube to mix the shape of the left and right screws, thereby controlling the speed of water introduced into the spiral tube and forming a turbulent layer, thereby increasing the thermal efficiency to reduce the consumption of raw materials. There is an advantage in improving economics.

Claims (3)

The end of the spiral tube 13 is coupled to the through-hole 12a and the tube plate 12 is positioned inside the fuselage 11 and the protection cap 14 having an inlet pipe and an exhaust pipe formed on the tube plate 12. In the heat exchanger for fixing the Spiral tube 100 to form a spiral so that the direction of the left and right screws mixed on the outer peripheral surface; Spiral tube assembly structure of the heat exchanger, characterized in that coupled to the end of the spiral tube 100 through the reinforcing ring (200) penetrated inside and mounted in the through hole (12a) of the tube plate (12). The method of claim 1, Spiral tube assembly structure of the heat exchanger, characterized in that the inner diameter of the reinforcing ring 200 is formed smaller than the outer diameter of the spiral tube (100). The method of claim 1, Spiral tube assembly structure of the heat exchanger, characterized in that the outer diameter of the reinforcing ring 200 is formed larger than the spiral outer diameter of the spiral tube (100).