KR102093616B1 - Apparatus for manufacturing support for fin tube - Google Patents

Abstract

The present invention relates to equipment for manufacturing a support for a fin tube. The support manufacturing equipment for a fin tube includes: a base plate installed in the horizontal direction with the ground; a lower heat transfer plate coupled to an upper part of the base plate; a mold seated on the upper surface of the lower heat transfer plate, comprising upper and lower molds, having an insertion hole, into which a pin tube is inserted, therein, and having a cavity, into which a molding raw material is inserted, in the edge of the insertion hole to mold a support; an upper heat transfer plate installed to be spaced apart at a predetermined interval on the upper part of the lower heat transfer plate; and an air cylinder moving the upper heat transfer plate up and down. The support is molded inside the mold and is fused to the outer surface of the fin tube at the same time. Therefore, the present invention has effects of: enabling easy manufacture by fusing a support on the outer periphery of a pin tube while molding the support; and stably and firmly supporting the fin tube so that the support does not deviate from the fin tube.

Description

Apparatus for manufacturing support for fin tube

The present invention relates to an apparatus for manufacturing a support for a pin tube, and in more detail, a support for a pin tube that is mounted to surround a part of a pin tube and molds a support supporting the pin tube and is mounted on the pin tube at the same time. It is about the device.

In general, the fin tube is mainly used in heat exchangers such as boilers, and includes a tube and a plurality of fins provided on an outer circumferential surface of the tube.

The boiler body is provided with a number of tubes to which the boiler water is supplied for generating steam, and these tubes are made of a fin tube to increase the heat conduction efficiency from combustion gas.

Looking at the structure of the fin tube, a hollow tube and a plurality of fins having a predetermined area on the outside of the tube are combined to be applied. Here, the bonding of the fins to the tube is intended to increase the heat exchange efficiency by expanding the thermal contact surface.

As a typical fin tube, a spiral finned tube is a heat exchanger in which a band-shaped fin is formed on the outer circumferential surface of a tube and wound in a spiral to form a fin. It has the advantage of being.

When the fin tube is applied to a heat exchanger, a plurality of fin tubes are arranged and used at regular intervals, and at this time, a plurality of fin tubes are arranged in a state in which supports are mounted to maintain the installation interval between each other.

However, as shown in FIG. 1, conventionally, in order to mount the support on the fin tube, after removing the pin coupled to the outer periphery of the existing fin tube 10, the support 20 in the section where the pin is removed By attaching), it took some time for the work process, and accordingly, there was a problem that productivity was reduced.

In addition, in the process of manually removing the pins, since a section in which the pins are removed has an error range, the positions where the supports are coupled are different from each other, so that the process of stacking or transferring a plurality of fin tubes by utilizing the supports There were many difficulties.

Republic of Korea, Registered Patent Publication, Registration No. 10-0650253

The present invention has been devised to solve this, and by removing the pin of the fin tube, and fusion of the support to the outer periphery of the fin tube, it is possible not only to mount the support in a certain section, but also to support the pin tube more firmly The purpose is to provide.

The present invention relates to an apparatus for manufacturing a support for a fin tube, wherein the apparatus for manufacturing a support for a fin tube is mounted on a base plate installed in a horizontal direction with the ground, a lower heating plate coupled to an upper portion of the base plate, and mounted on an upper surface of the lower heating plate. , It is composed of upper and lower molds, an insertion hole into which a pin tube is inserted is formed inside, and a cavity into which a molding material is inserted is formed at the edge of the insertion hole, a mold on which a support is molded, and a constant upper portion of the lower heating plate. An upper heat exchanger plate spaced apart, a top plate coupled to an upper surface of the upper heat exchanger plate, and coupled to an upper surface of the top plate, vertically coupled to the air cylinder and the base plate to elevate and move the upper heat exchanger plate, the upper portion It characterized in that it comprises a support rod for supporting the elevating movement of the heat transfer plate.

In addition, the support is characterized in that it is molded inside the mold and is fused to the outer surface of the fin tube at the same time.

In addition, the support is characterized in that it is made of a rubber or silicone material.

Therefore, the present invention is not only easy to manufacture by forming the support and fusion of the support to the outer periphery of the fin tube, but also has a remarkable effect that the support does not deviate from the fin tube and firmly supports the fin tube more stably. have.

In addition, since the fins of the fin tube are not removed and can be applied to an existing fin tube, manufacturing is easy, and accordingly, there is a remarkable effect of improving productivity.

In addition, the support manufactured by the present invention is mounted on a certain section of the fin tube, but is formed in a hexagonal shape, so that the stacking between the fin tubes is easy to improve the installation efficiency, and also has a remarkable effect of high transport efficiency. .

1 is a photograph showing a conventional fin tube and support.
Figure 2 is a front view of the pin tube support manufacturing apparatus of the present invention.
3 is an enlarged view of a mold of a pin tube support manufacturing apparatus of the present invention.
Figure 4 is a side view of the fin tube in a state in which the support manufactured by the present invention is mounted.
5 is a front view of the fin tube in a state in which the support manufactured by the present invention is mounted.
Figure 6 is a front view showing a state in which the support manufactured by the present invention is stacked.

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings.

The accompanying drawings are only examples shown in order to describe the technical spirit of the present invention in more detail, so the technical spirit of the present invention is not limited to the form of the accompanying drawings.

2 is a front view of the pin tube support manufacturing apparatus 1000 of the present invention.

The apparatus for manufacturing a support for a fin tube of the present invention includes a base plate 100, a lower heat transfer plate 200, a mold 300, an upper heat transfer plate 400, an air cylinder 500, and a support rod 600.

The base plate 100 is installed in the horizontal direction on the ground.

Since the base plate is installed to allow the operator to easily work, it may be provided to have a predetermined height as needed.

In addition, a wheel may be provided on the bottom surface of the base plate for easy movement, and the wheel may be provided with a locking means for controlling movement.

In addition, the upper surface of the base plate 100 is to be coupled to the lower heating plate 200 in the horizontal direction, the lower heating plate 200 is the first heating in the space between the first upper and lower plates 220, 240 disposed vertically The means 260 is provided in a stacked structure, and serves to transfer heat to the mold.

The first heating means may be composed of a heating band, a heating coil, etc., as an embodiment in the present invention, to use a heating band.

The internal structure of the heating band is a mica plate with good insulation, which protects the heating element, surrounds a heat-resistant metal on its surface, and can be temperature-controlled in the control panel. Since the heating band is a commonly used general means, detailed description Is omitted.

That is, the heating band serves to transfer heat to the mold seated on the upper surface of the upper plate by heating the upper and lower plates.

Subsequently, a mold 300 is disposed on the upper surface of the lower heat transfer plate 200.

The mold 300 includes an upper mold 320 and a lower mold 340, wherein the upper and lower molds 320 and 340 are configured to be symmetrical to each other up and down.

The upper mold and the lower mold are respectively formed with an insertion hole 360 into which the pin tube 10 is inserted, and a cavity 380 which is formed on the edge of the insertion hole 360 and is a space into which molding material is inserted.

Subsequently, an upper heat exchanger plate 400 is installed at an upper side of the mold 300 so as to have a predetermined interval height from the mold, and the upper heat exchanger plate 400 is installed at a position corresponding to the lower heat exchanger plate 200 vertically. .

The upper heating plate 400, like the lower heating plate described above, is provided in a structure in which the second heating means 460 is stacked in the space between the second upper and lower plates 420 and 440, which are arranged vertically. .

In addition, an air cylinder 500 for raising and lowering the upper heat exchanger plate is coupled to the upper portion of the upper heat exchanger plate 400, and the upper heat exchanger plate is lowered by the operation of the air cylinder, and presses the mold downward to press the mold. It will transfer heat.

The air cylinder 500 is a device that converts the energy of compressed air into a mechanical reciprocating linear motion.

In addition, a top plate 700 is installed between the upper heat exchanger plate 400 and the air cylinder 500 to prevent the heat of the upper heat exchanger plate from conducting to the air cylinder, and a plurality of plates are further combined according to user needs. Can be used.

The top plate 700 is to minimize the surface in contact with the upper heating plate 400, the upper surface should be disposed horizontally with the upper heating plate so that the air cylinder can be coupled, in the present invention, as an embodiment, to have a single layer Use a top plate with multiple plates combined.

Subsequently, the upper heat transfer plate 400 is guided and lowered by the support rod 600 coupled to the base plate 100 in the vertical direction, and the support rod 600 is vertical to the upper surface of the base plate. Combined, it is provided to penetrate the lower heat transfer plate 200 and the upper heat transfer plate 400 vertically.

In addition, in the present invention, the support rods 600 are respectively coupled to the four corners of the base plate 100 to provide a total of four support rods.

Accordingly, a through hole is formed in the four corners of the upper heat transfer plate 400 and the lower heat transfer plate 200 so that the support rod 600 can pass therethrough, and the support rod is coupled through the through hole.

In addition, a lower bearing 620 is coupled between the outer circumferential surface of the support rod 600 and the lower lateral inner circumferential surface of the through hole formed in the lower heat transfer plate 200, and a buffer member 640 is mounted below the lower bearing 620. In the present invention, as an embodiment of the buffer member 640, a spring having an elastic restoring force was used.

The spring has an effect of preventing the heat of the lower heating plate from conducting to the base plate as well as buffering the force received by the lower heating plate as the upper heating plate descends.

In addition, an upper bearing 660 is coupled between the outer circumferential surface of the support rod 600 and the upper circumferential inner circumferential surface of the through hole formed in the upper heat exchanger plate 400, so that the upper heat transfer plate is easily moved up and down along the support rod.

That is, the support rod serves to stably support and guide the reciprocating motion in which the upper heat transfer plate moves up and down by an air cylinder.

3 is an enlarged view of a mold of a pin tube support manufacturing apparatus of the present invention, and will be described in more detail with reference to FIG. 3.

The mold 300 includes upper and lower molds 320 and 340 that are configured to be symmetrical to each other up and down.

The upper mold 320 and the lower mold 340 are configured to be coupled and detached from each other, and both sides of the upper mold 320 and the lower mold 340 are up and down at positions corresponding to each other up and down. A coupling hole penetrated into is formed, and the upper and lower molds are coupled by penetrating both the coupling holes and inserting the coupling member.

In addition, the upper mold and the lower mold are respectively formed with an insertion hole 360 into which the pin tube 10 is inserted, and a cavity 380 which is formed on the edge of the insertion hole 360 and is a space into which molding material is inserted.

In addition, the overall shape of the insertion hole 360 is circular, the pin tube is seated on the insertion hole, the overall shape of the cavity 380 is hexagonal, and rubber or silicon raw material is inserted into the cavity, to the cavity shape. It is molded into a hexagon.

In other words, the present invention is to form a support by fusion of rubber or silicone raw material on the outer periphery of the fin tube, while the fin tube is seated on the insertion hole 360 which is the center of the mold 300, and the support is It is molded inside the mold and is fused to the outer surface of the fin tube.

At this time, the rubber or silicone raw material inserted into the cavity 380 will have a soft hardness, but it will be preferable to be manufactured in a sheet shape having a predetermined length and thickness.

 In addition, the mold is preferably made of a metal material having a high thermal conductivity.

In the present invention, as an example, three cavities are provided in the upper and lower molds, respectively, so that three products (supports) are produced in one mold, but this is not limited to the present invention.

Hereinafter, a process in which the support is molded by the present device will be described.

First, the operator puts a rubber or silicone raw material into the cavity 380 of the lower mold 340, and seats the pin tube on the insertion hole 360.

Thereafter, the upper mold 320 in which the rubber or silicon raw material is inserted into the cavity 380 is coupled to the upper surface of the lower mold.

At this time, the rubber or silicone raw material has a soft hardness, and is prepared in a sheet shape having a predetermined length and thickness, so that it does not damage the fins of the fins even when it comes into contact with the fin tube, and is provided so as not to flow out of the cavity.

Next, by operating the control panel, by causing the upper heat exchanger plate 300 to be lowered by the air cylinder 500, the lower heat exchanger plate 200 and the upper heat exchanger plate 300 is pressed between the mold 300.

At this time, the upper heating plate and the lower heating plate are in a state heated by a heating means.

That is, since the upper mold is in direct contact with the upper heating plate, and the lower mold is in direct contact with the lower heating plate, heat is evenly transferred to the entire mold, so that a high-quality support is manufactured.

Since the support 20 is molded inside the mold 300 and is fused to the outer surface of the fin tube 10, the outer shape is formed in the same hexagon as the formation of the cavity while filling the space between the fins. Lose.

Referring to FIG. 4 in more detail, the fin tube used in the present invention includes a tube and a fin provided on an outer circumferential surface of the tube, wherein the tube is made of a hollow tube, and the outer circumferential surface of the tube The pin is wound in a spiral shape and is coupled along the length of the tube.

That is, by forming the support by fusion of the fin tube on the outer surface of the fin tube while the fin tube is seated in the center of the mold, the support is filled with a space between the fins of the fin tube, thereby forming an outer shape. Is formed as a whole hexagon.

Accordingly, the support, as shown in Figure 5, is formed in a honeycomb shape with a vertical cross-section of a hexagonal shape, as shown in Figure 6, has the advantage of easy space utilization even when a plurality of fin tubes are stacked. .

Therefore, the present invention is not only easy to manufacture by forming the support and fusion of the support to the outer periphery of the fin tube, but also has a remarkable effect that the support does not deviate from the fin tube and firmly supports the fin tube more stably. have.

In addition, since the fins of the fin tube are not removed and can be applied to an existing fin tube, manufacturing is easy, and accordingly, there is a remarkable effect of improving productivity.

In addition, the support manufactured by the present invention is mounted on a certain section of the fin tube, but is formed in a hexagonal shape, so that the stacking between the fin tubes is easy, and the installation efficiency is improved, and there is a remarkable effect of high transport efficiency. .

As described above, the present invention has been described with reference to the embodiment shown in the drawings, but this is only for explaining the invention, and those skilled in the art to which the present invention pertains various modifications or equivalents from the detailed description of the invention It will be understood that one embodiment is possible.

Therefore, the true scope of the present invention should be determined by the technical spirit of the claims.

10: Fin tube
20: Support
1000: Support device for pin tubes
100: base plate
200: lower heating plate
220: first upper plate
240: first lower plate
260: first heating means
300: mold
320: Upper mold
340: lower mold
360: Insert
380: cavity
400: upper heating plate
420: second upper plate
440: second lower plate
460: second heating means
500: Air cylinder
600: support rod
620: Lower bearing
640: buffer member
660: Upper bearing
700: Top plate

Claims (3)

A base plate installed in a horizontal direction with the ground;
A lower heat transfer plate coupled to an upper portion of the base plate;
It is seated on the upper surface of the lower heating plate, and is composed of upper and lower molds, and an insertion hole through which a pin tube is inserted is formed inside, and a cavity into which molding material is inserted is formed on the edge of the insertion hole, and a support mold is formed. ;
An upper heat exchanger plate spaced apart at a predetermined interval on the upper portion of the lower heat exchanger plate;
A top plate coupled to an upper surface of the upper heat transfer plate;
It is coupled to the upper surface of the top plate, the air cylinder to elevate the upper heat transfer plate; And
It is coupled to the base plate in the vertical direction, the support rod for supporting the vertical movement of the upper heating plate; pin tube support manufacturing apparatus comprising a.
According to claim 1,
The support is molded in the mold, and at the same time, it is fused to the outer surface of the fin tube support manufacturing apparatus for a fin tube.
According to claim 2,
The support is made of a support device for a fin tube, characterized in that made of a rubber or silicone material.

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