KR102625844B1 - Heater with stove heat radiation portion structure - Google Patents

Abstract

The purpose of the present invention is to provide a heater with a heat dissipation structure. The configuration of the present invention includes a heat dissipation body having a heat dissipation opening at the front and coupled to the post 112 provided on the base 110 of the heater. 120); A heating element 130 embedded in the heat dissipation body 120; A reflector 140 disposed between the heating element 130 and the heat dissipation body 120; An angle adjustment coupling part that couples the heat dissipation body 120 to the post 112 so that the rotation angle of the heat dissipation body 120 with respect to the post 112 can be adjusted.
The effect of the present invention is that the concave reflector portion of the main reflector is configured in the shape of a cylindrical plate, and a heating element is embedded in the concave reflector portion, so that when the heat radiated from the heating element is reflected forward from the surface of the concave reflector portion, the heat reflection angle is larger. Because it is expanded, the heat radiated from the heating element radiates heat as widely as possible in the heating area, thereby maximizing heating efficiency, and through a simple structure in which the angle setting ball provided in the radiator is inserted into the plurality of angle adjustment holes formed in the bracket. By adjusting and maintaining the angle of the heat dissipation part, the radiation angle of the heat radiating from the heat dissipation part can be adjusted as desired at the place where the heater is used, making it convenient to use the heater.

Description

Heater with a heat radiation portion structure {Heater with stove heat radiation portion structure}

The present invention relates to a heater with a heat dissipation structure, and more specifically, to a new heat dissipation device that radiates heat as widely as possible in the heating area by heat radiating from the heating element and maintains it by adjusting the angle of the heat dissipation part through a simple structure. It relates to a heater having a secondary structure.

In general, a stove is a device that generates heat to warm the surroundings. It is divided into gas stoves, oil stoves, electric stoves, etc., and is mainly used in buildings or outdoors where indoor heating is not provided. Electric heaters have many advantages over gas or oil heaters, such as less pollution, so they are widely used for indoor heating. At this time, there is a wall-mounted type in which the electric heater is hung on the wall and an upright type in which the electric heater is used by simply standing it in a heating area. Compared to the wall-mounted type, the upright type is widely used because it can be easily placed and used.

At this time, the angle of the heat dissipation part where heat comes from the electric heater is often adjusted so that the heat dissipation location where direct heat can be received is not limited to one location and the range where heating can be performed can be expanded.

Therefore, taking this into consideration, by adopting a simple bracket structure that allows the angle to be adjusted in the vertical direction based on the vertical direction of the heat radiating part of the stove, the angle of the radiating part can be easily adjusted to expand the heat dissipating range, and the angle adjustment of the radiating part can be firmly maintained. It is necessary to be able to maintain it.

Korea Public Utility Model No. 20-1990-0006946 (published on April 3, 1990) Korea Public Utility Model No. 20-1989-0023272 (published on December 2, 1989)

The present invention was developed to solve the above problems, and the purpose of the present invention is to radiate heat as widely as possible in the heating area by the heat radiated from the heating element, and to maintain it by adjusting the angle of the heat radiating part through a simple structure. The goal is to provide a heater with a new heat dissipation structure.

According to the present invention for solving the above problems, a heat dissipation body 120 having a heat dissipation opening at the front and coupled to a post 112 provided on the base 110 of the stove; A heating element 130 embedded in the heat dissipation body 120; A heater is provided with a heat dissipation structure, characterized in that it includes a reflector 140 disposed between the heating element 130 and the heat dissipation body 120.

The reflector 140 is characterized by being provided with a plurality of heat conduction blocking holes 147 at least at the top and bottom.

The reflector 140 is characterized in that it is provided with at least two concave reflector parts 142, and the heating element 130 is accommodated and disposed in the concave reflector parts 142.

Side guard plates 128 are coupled to both left and right front surfaces of the heat dissipation body 120, so that a pair of side guide plates are disposed on the heat dissipation body 120, and the pair of side guard plates 128 are It is characterized by being composed of a cylindrical plate with a convex center portion.

The reflector 140 is provided with side reflector portions 148 on both left and right sides, so that the reflector 140 is configured to include a pair of side reflector portions 148, and the inner surface of the side reflector portion 148 is A clip 134 is provided, and the heating element 130 is composed of a straight tube-shaped heater with insulators 132 at both ends, and the insulators 132 of the heating element 130 are the side reflector portion ( It is characterized in that the part that is coupled to the clip 134 provided in 148 and radiates heat from the heating element 130 is spaced a certain distance away from the side reflector portion 148.

The heat dissipation body 120 is characterized by being provided with a plurality of holes 126 communicating with the inner and outer surfaces.

It is characterized in that it further includes an angle adjustment coupling part that couples the heat dissipation body 120 to the post 112 so that the rotation angle of the heat dissipation body 120 can be adjusted based on the post 112. .

The angle adjustment coupling unit includes a bracket 210 having a pair of vertical bracket pieces 213 connected to the left and right ends of the horizontal bracket piece 212, respectively; A hinge 220 supporting the pair of vertical bracket pieces 213 of the bracket 210 to be coupled to the heat dissipation body 120 of the heat dissipation portion (HTP); A plurality of angle adjustment holes 230 provided on the pair of vertical bracket pieces 213 and disposed at regular intervals along the circumferential direction with respect to the hinge 220; It is provided on the connection body part 125 of the heat dissipation body 120 constituting the heat dissipation part (HTP) and is inserted into the angle adjustment hole 230 so that the heat dissipation part (HTP) extends around the circumference of the post 112. It is configured to include an angle setting ball 240 that maintains the rotated angle along the mold rotation trajectory, and the heat dissipation part (HTP) is tilted in the vertical direction with respect to the post 112 by the angle adjustment coupling part. It is characterized in that the angle at which heat generated when the heating element 130 generates heat in the rotated state is radiated through the heat dissipation opening of the heat dissipation body 120 is adjusted.

The heat dissipation part (HTP) includes a heat dissipation body 120 having a heat dissipation opening at the front, and a heating element 130 built into the heat dissipation body 120, and the heat dissipation part (HTP) includes the angle adjustment coupling part. It is maintained in a state rotated forward or backward along a cylindrical rotation trajectory based on the post 112, so that the heat generated when the heating element 130 is generated passes through the heat dissipation opening of the heat dissipation body 120. It is characterized in that it is configured so that the radiating angle is adjusted.

Among the pair of vertical bracket pieces 213 of the bracket 210, at least one vertical bracket piece 213 is connected to adjacent angle adjustment holes 230 among the plurality of angle adjustment holes 230. A fine angle adjustment hole 232 is further provided, and the angle setting ball 240 is inserted into the fine angle adjustment hole 232, thereby expanding the angle adjustment range of the heat dissipation part (HTP). Do it as

Among the pair of vertical bracket pieces 213 of the bracket 210, at least one vertical bracket piece 213 is provided with a stopper 214 to be disposed lower than the plurality of angle adjustment holes 230. The rear of the connecting body 125 below the heat dissipating body 120 of the heat dissipating part (HTP) is caught by the stopper 214 so that the heat dissipating part (HTP) is connected to the post 112 of the base 110 of the stove. It is characterized by being configured to prevent excessive tilting toward the rear based on the coupled hinge 220.

The horizontal bracket piece 212 of the bracket 210 is coupled to the post 112 of the base 110 of the stove by a reinforcing support pin 216 to increase the strength of the bracket 210 coupled to the post 112. It is characterized by being configured to reinforce.

The centers of the plurality of angle adjustment holes 230 formed in each of the pair of vertical bracket pieces 213 of the bracket 210 are arranged to be offset from each other, and the connection body portion 125 of the heat dissipation body 120 A portion of a pair of angle setting balls 240 is provided to protrude on the left and right sides, and the angle setting balls 240 provided on the left side of the connection body 125 are positioned on one side of the vertical bracket piece 213. When inserted into any one of the plurality of angle adjustment holes 230, it is in contact with the outer surface of the other vertical bracket piece 213 provided on the right side of the connection body portion 125. It is maintained in a pressed state, and the angle setting ball 240 provided on the right side of the connection body 125 is connected to any one of the plurality of angle adjustment holes 230 of the vertical bracket piece 213 on the other side. In the state inserted into (230), the angle of the heat radiation portion (HTP) is adjusted by being maintained in a pressed state in contact with the outer surface of the one vertical bracket piece 213 provided on the left side of the connection body portion 125. It is characterized by expanding the scope.

The heater with the heat dissipation structure of the present invention has a concave reflector portion of the reflector, which is the main part, configured in the shape of a cylindrical plate, and a heating element is embedded in the concave reflector portion, so that when heat radiated from the heating element is reflected forward from the surface of the concave reflector portion, Since the reflection angle of heat becomes wider, the heat radiated from the heating element radiates heat as widely as possible in the heating area, thereby increasing heating efficiency as much as possible.

In addition, the present invention adjusts and maintains the angle of the heat radiator through a simple structure in which angle setting balls provided in the heat radiator are inserted into a plurality of angle adjustment holes formed in the bracket, thereby controlling the radiation of heat radiated from the radiator in a place where the stove is used. Since the angle can be adjusted as desired, the stove is convenient to use.

The effects according to the present invention are not limited to the details exemplified above, and further various effects are included within the present invention.

1 is a perspective view of a heater equipped with a heat dissipation structure of the present invention, showing the safety net removed;
Figure 2 is a front perspective view of the heat dissipation body, which is the main part of the heat dissipation unit shown in Figure 1;
Figure 3 is a front view of Figure 2,
Figure 4 is a rear perspective view of the heat dissipation body, which is the main part of the heat dissipation unit shown in Figure 1;
Figure 5 is a perspective view of a reflector, which is another main part of the heat dissipation unit shown in Figure 1;
Figure 6 is a front view of Figure 5;
Figure 7 is a side cross-sectional view of Figure 5;
Figure 8 is a perspective view of the side guard plate, which is another main part of the heat dissipation part shown in Figure 1;
Figure 9 is a bottom perspective view of Figure 8;
Figure 10 is a side view of Figure 8;
11 is a front perspective view of a heater employing the heat dissipation structure of the present invention;
Figure 12 is a rear perspective view of Figure 11;
Figure 13 is a perspective view of the bracket, which is the main part of the present invention;
Figure 14 is a front view of Figure 13;
Figure 15 is a rear view of Figure 13;
Figure 16 is a left side view of Figure 13;
Figure 17 is a right side view of Figure 13;
Figure 18 is a right rear perspective view of the heat dissipation unit shown in Figure 12;
Figure 19 is a right side view of Figure 12;
Figure 20 is an enlarged side view of portion B of Figure 19, showing the bracket, angle adjustment hole, and angle setting ball;
Figure 21 is a longitudinal cross-sectional view taken along line AA of Figure 12, showing a state in which the main part, the bracket, the angle adjustment hole, and the angle setting ball are combined;
Figure 22 is a right side view of the bracket, which is a main part of another embodiment of the present invention;
Figure 23 is a perspective view of Figure 22;
Figure 24 is a right side view of the heater employing the bracket shown in Figure 23;
Figure 25 is an enlarged side view showing the state in which the angle setting ball is coupled to the fine angle adjustment hole of the bracket shown in Figure 23;
Figure 26 is a perspective view showing a stopper and a reinforcing support pin combined with the bracket, which is the main part of the present invention;
Figure 27 is an enlarged rear view showing the state in which the rear of the connection body part of the heat dissipation part is caught by the stopper of Figure 26 and the state in which the reinforcing support pin is coupled to the upper connection post part of the post provided on the base;
Figure 28 is a perspective view showing a state in which the centers of a plurality of angle adjustment holes formed in each pair of vertical bracket pieces of the bracket, which is the main part of the present invention, are misaligned;
FIG. 29 is a side view showing a state in which the centers of a plurality of angle adjustment holes of a pair of vertical bracket pieces of the bracket shown in FIG. 28 are misaligned.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. The purpose, features, and advantages of the present invention can be more easily understood by referring to the accompanying drawings and the following detailed description. Additionally, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Additionally, when describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, sequence, or order of the component is not limited by the term. When a component is described as being "connected," "coupled," or "connected" to another component, that component may be directly connected or connected to that other component, but there is another component between each component. It will be understood that elements may be “connected,” “combined,” or “connected.”

Figure 1 is a perspective view of a heater equipped with the heat dissipation structure of the present invention, showing the safety net removed, Figure 2 is a front perspective view of the heat dissipation body, which is the main part of the heat dissipation part shown in Figure 1, and Figure 3 is the front view of Figure 2. 4 is a rear perspective view of the heat dissipation body, which is the main part of the heat dissipation part shown in FIG. 1, FIG. 5 is a perspective view of the reflector, which is another main part of the heat dissipation part shown in FIG. 1, FIG. 6 is a front view of FIG. 5, and FIG. 7 is a FIG. 5 is a side cross-sectional view, Figure 8 is a perspective view of the side guard plate, which is another main part of the heat dissipation unit shown in Figure 1, Figure 9 is a bottom perspective view of Figure 8, Figure 10 is a side view of Figure 8, and Figure 11 is a heat dissipation of the present invention. A front perspective view of the heater employing the secondary structure, Figure 12 is a rear perspective view of Figure 11, Figure 13 is a perspective view of the bracket, which is a main part of the present invention, Figure 14 is a front view of Figure 13, Figure 15 is a rear view of Figure 13, Figure 16 is a left side view of FIG. 13, FIG. 17 is a right side view of FIG. 13, FIG. 18 is a right rear perspective view of the heat dissipation unit shown in FIG. 12, FIG. 19 is a right side view of FIG. 12, and FIG. 20 is an enlargement of portion B of FIG. 19. Figure 21 is a side view showing the bracket, angle adjustment hole, and angle setting ball. Figure 21 is a vertical cross-sectional view along line A-A of Figure 12, showing the main part of the bracket, angle adjustment hole, and angle setting ball combined. Figure 22 is a view showing the main part combined with the bracket, angle adjustment hole, and angle setting ball. The right side view of the bracket, which is a main part of another embodiment of the invention, Figure 23 is a perspective view of Figure 22, Figure 24 is a right side view of a heater employing the bracket shown in Figure 23, and Figure 25 is a fine angle adjustment of the bracket shown in Figure 23. An enlarged side view showing the state in which the angle setting ball is coupled to the hole, Figure 26 is a perspective view showing the state in which the stopper and the reinforcing support pin are coupled to the bracket, which is the main part of the present invention, and Figure 27 is a body connecting the heat sink to the stopper in Figure 26. Figure 28 is an enlarged rear view showing the state in which the rear part of the unit is hung and the reinforcing support pin is coupled to the upper connection post part of the post provided on the base. Figure 28 shows each of the pair of vertical bracket pieces of the bracket, which is the main part of the present invention. A perspective view showing a state in which the centers of the plurality of angle adjustment holes formed are misaligned. FIG. 29 is a side view showing a state in which the centers of the plurality of angle adjustment holes of a pair of vertical bracket pieces of the bracket shown in FIG. 28 are misaligned.

As shown in Figure 1, the present invention includes a heat dissipation body 120 having a heat dissipation opening at the front and coupled to the post 112 provided on the base 110 of the heater, and a heating element embedded in the heat dissipation body 120 ( 130), a reflector 140 disposed between the heating element 130 and the heat dissipation body 120, and a post 112 so that the rotation angle of the heat dissipation body 120 with respect to the post 112 can be adjusted. It is a heater equipped with a heat dissipation structure including an angle adjustment coupling part that couples the heat dissipation body 120. In the present invention, when heat is generated by the operation of the heating element 130, the heat is reflected by the reflector 140 and the heat is radiated to the heat dissipation opening in front of the heat dissipation body 120, thereby providing heating in a place where the heater is used. make it possible A safety net 127 is coupled in front of the front heat dissipation opening of the heat dissipation body 120. Figure 1 shows the safety net 127 in a disassembled state, and Figure 11 shows the safety net 127 in a combined state.

5 and 6, the reflector 140 is provided with a plurality of heat conduction blocking holes 147 at least at the top and bottom. A plurality of heat conduction blocking holes 147 are provided at regular intervals along the left and right side ends of the reflector 140. The reflector 140 is provided with at least two concave reflector portions 142. In the present invention, two concave reflector portions 142 are provided parallel to each other at the top and bottom. When the reflector 140 is viewed in the side cross-sectional view shown in FIG. 7, the concave reflector portion 142 is configured in the shape of a cylindrical plate protruding backward from the back of the reflector.

The plurality of heat conduction blocking holes 147 are formed at the upper and lower sides of the reflector 140, including the upper reflector 143 above the upper concave reflector 142, the lower reflector 144 below the lower concave reflector 142, and the upper and lower reflectors 144. Each is provided in the middle reflector portion 145 between the two concave reflector portions 142.

As shown in Figures 1 and 11, the heating element 130 is accommodated and disposed in the concave reflector portion 142 of the reflector 140. The heating element 130 is composed of a straight tube-shaped heater with insulators 132 at both ends. At this time, the reflector 140 is provided with side reflector portions 148 on both left and right sides, so that the reflector 140 is configured to include a pair of side reflector portions 148. Side reflector parts 148 are provided on the left and right side ends of the reflector 140, respectively, and clips 134 are provided on the inner surfaces of the side reflector parts 148, respectively, so that the insulator 132 of the heating element 130 ) is coupled to the clip 134 provided on the two parallel side reflector portions 148 of the reflector 140, so that the heating element 130 is embedded in the concave reflector portion 142 of the reflector 140.

The heat generated when the heating element 130 embedded in the concave reflector portion 142 of the reflector 140 generates heat is reflected by the concave reflector 140 and radiated through the heat dissipation opening in the front of the heat dissipation body 120, thereby heating Heating can be done in place.

At this time, the concave reflector portion 142 of the reflector 140 is configured in the shape of a cylindrical plate, and the heating element 130 is embedded in the concave reflector portion 142, so that the heat radiated from the heating element 130 is radiated from the concave reflector portion ( Since the reflection angle of heat when reflected forward from the surface of 142) becomes wider, the heat radiated from the heating element 130 radiates heat as widely as possible in the heating area, thereby increasing heating efficiency as much as possible.

Meanwhile, the reflector 140 is provided with a plurality of heat conduction blocking holes 147 to prevent heat conduction from the reflector 140 toward the peripheral portion, that is, toward the heat dissipation body 120, as much as possible, thereby preventing heat conduction from being conducted to the heat generating body 120. The heat dissipation body 120 is overheated by the heat generated when (130) generates heat, preventing the heater user from being burned by contact with the heat dissipation body 120 and the safety net. The heat dissipation body 120 made of plastic is It also has the effect of preventing melting and damage due to overheating.

At this time, as shown in FIGS. 1 and 11, the heating element 130 is accommodated and disposed in the concave reflector portion 142 of the reflector 140, and at the same time, the insulator 132 of the heating element 130 is connected to the reflector 140. ) by being coupled to the clip 134 provided on the two side reflector portions 148, the portion from which heat is radiated from the heating element 130 is configured to be spaced a certain distance from the side reflector portion 148 of the reflector 140. Therefore, the heat generated when the heating element 130 generates heat is prevented from being conducted directly to the side reflector portion 148 of the reflector 140, and as a result, the side reflector portion 148 of the reflector 140 is overheated and exposed to the surrounding area. Since the heat of the heating element 130 is prevented from being conducted to the heat dissipating body 120, the heat generated when the heating element 130 overheats the heat dissipating body 120, causing the heater user to use the heat dissipating body 120 and the heat dissipating body 120. It is effective in more reliably preventing burns caused by contact with the safety net, etc., and also more reliably preventing cases in which the heat dissipation body 120 made of plastic is melted and burned out due to overheating.

Side guard plates 128 (shown in FIGS. 8 to 10) are coupled to both left and right front surfaces of the heat dissipation body 120, and a pair of left and right side guard plates 128 are coupled to the heat dissipation body 120. Take the composition. 1 and 11 show a pair of side guard plates 128 coupled to the front of the heat dissipation body 120. At this time, the pair of side guard plates 128 is composed of a cylindrical plate with a convex center portion.

Therefore, even if the heat generated when the heating element 130 generates heat during use of the heater is conducted to the side guard plate 128 through the heat dissipation body 120, the heater user may accidentally conduct the side guard plate ( Even if the body is in contact with 128), the user's body only touches the central convex part, preventing the user from feeling too hot due to contact with the side guard plate 128 while using the heater, and this prevents the user's body from touching the side guard plate (128). 128), it is effective in preventing burns even if accidentally touched.

2 to 4, a heat dissipation body 120 is shown, and the heat dissipation body 120 is provided with a plurality of holes 126 communicating with its inner and outer surfaces.

Therefore, external air enters the inside of the heat dissipation unit (HTP) (i.e., the inside between the reflector 140 and the heat dissipation body 120) through the hole 126 of the heat dissipation body 120, and then enters the heat dissipation part HTP. ) Because air circulation is performed to the outside of the hole (126), even if the heat generated when the heating element (130) generates heat is conducted to the heat dissipation body (120) through the reflector (140), ) prevents the heat dissipation body 120 from overheating due to air circulation, thereby preventing burns when the user's body comes into contact with the heat dissipation body 120 or the heat dissipation body 120 melting due to overheating and being damaged, etc. It has the effect of preventing cases even more reliably.

At this time, the heat dissipation body 120 is provided with a pair of left and right side body walls 122, an upper body wall 123, and a lower body wall 124, and a pair of side body walls 122 and an upper body wall. The connecting body portion 125 is provided between (123) and the inner end of the lower body wall 124, and a pair of side body walls 122, upper body wall 123, and lower body wall 124 are It is configured to be inclined toward the center of the heat dissipation body 120. See Figures 2 to 4.

Therefore, the volume of the heat dissipation body 120 gradually decreases as it moves backward, thereby minimizing the volume that the heat dissipation body 120 occupies, thereby minimizing the volume of the heat dissipation part (HTP). Therefore, the volume of the heat dissipation part (HTP) can be minimized while the heater is in use. ) has the effect of preventing a person's body from getting caught in the heat dissipation body 120, and furthermore, it has the effect of making it more convenient to use the heater.

In addition, the hole 126 of the heat dissipation body 120 is formed to communicate with both sides of the left and right pair of side body walls 122, the upper body wall 123, and the lower body wall 124, and includes a plurality of holes ( 126) are arranged in the longitudinal and transverse directions, and the plurality of holes 126 formed in the pair of side body walls 122 have an area that gradually decreases from the outer end to the inner end of the side body wall 122. and the plurality of holes 126 formed in the upper body wall 123 and the lower body wall 124 gradually gradually move from the outer end to the inner end of the upper body wall 123 and the lower body wall 124. It is designed to reduce the area. See Figure 3.

Therefore, the area of the hole 126 located at a relatively greater distance from the heating element 130 is compared to the area of the hole 126 located at a position relatively closer to the heating element 130 in the heat dissipation body 120. Because it is configured to be smaller, the amount of air circulated inside and outside the heat dissipation body 120 through the holes 126 located at a relatively closer distance from the heating element 130 is relatively greater, and the heating element ( Since the amount of air circulating inside and outside of the heat dissipation body 120 is relatively small through the holes 126 located at a relatively greater distance from 130, the entire holes 126 of the heat dissipation body 120 This has the effect of allowing the cooling of the heat dissipation body 120 by circulation of air through them to be more efficient. That is, the amount of air circulation between the inside and outside of the heat dissipation body 120 is relatively increased through the holes 126 located in the heat dissipation body 120 relatively closer to the heating element 130, thereby creating a heat dissipation body ( In 120), the portion that is relatively closer to the heating element 130 is cooled more by the circulation of a relatively larger amount of air, and the hole in the heat dissipation body 120 is located relatively further from the heating element 130. Since the amount of air circulation between the inside and outside of the heat dissipation body 120 can be relatively reduced through (126), the hole 126 is located at a position relatively further from the heating element 130 in the heat dissipation body 120. The cooling action of the heat dissipation body 120 is made more efficient by the circulation of air through the entire holes 126 of the heat dissipation body 120 by allowing less cooling by circulating a relatively small amount of air through the holes. It can be done.

In addition, the area of the hole 126 in the heat dissipation body 120 is located at a relatively greater distance from the heating element 130 than the area of the hole 126 at a position relatively closer to the heating element 130. Since it is configured to be smaller, the strength of the heat dissipation body 120 itself is maintained properly.

As shown in FIGS. 11 and 12, the heater has a post 112 extending vertically from the base 110, and a connection body 125 is provided at the bottom center of the heat dissipation portion (HTP). . The connection body part 125 of the heat dissipation part (HTP) is configured to be coupled to the post 112 of the base 110 by a bracket 210 and an angle adjustment coupling part. The post 112 includes a lower connection post portion 112A and an upper connection post portion 112B coupled to the lower connection post portion 112A, and the connection body portion 125 of the heat dissipation portion (HTP) By being coupled to the upper connection post portion 112B by the temporary bracket 210 and the angle adjustment coupling portion, the connection body portion 125 of the heat dissipation portion (HTP) is connected to the base via the bracket 210 and the angle adjustment coupling portion. It is configured to be connected to the post 112 of (110), and as a result, the heat dissipation part (HTP) is coupled to the post 112 provided on the base 110 of the heater by the bracket 210 and the angle adjustment coupling. It becomes. The angle adjustment coupling part will be described later.

As shown in FIGS. 13 to 15, the bracket 210 is configured to include a pair of vertical bracket pieces 213 respectively connected to the left and right ends of the horizontal bracket piece 212. A coupling pin 215 protrudes downward from the horizontal bracket piece 212, and the coupling pin 215 is coupled to the upper connection post portion 112B of the post 112. As shown in FIGS. 14 and 15 , when the bracket 210 is viewed from the front or rear, the bracket 210 is formed in a U-shaped shape by a horizontal bracket piece 212 and a pair of left and right vertical bracket pieces 213. A pair of vertical bracket pieces 213 is provided with a hinge pin coupling hole 221. The hinge pin coupling hole 221 communicates with both sides of the vertical bracket piece 213.

In addition, as shown in FIGS. 16 and 17, the pair of vertical bracket pieces 213 are provided with a plurality of angle adjustment holes 230 disposed below the hinge pin coupling hole 221. A plurality of angle adjustment holes 230 communicate with both sides of the vertical bracket piece 213. A plurality of angle adjustment holes 230 are arranged at regular intervals along the circumferential direction. In the area between the front and rear ends of the vertical bracket piece 213, a plurality of angle adjustment holes 230 are formed along a downwardly convex cylindrical trajectory for a certain period of time. By being arranged, a plurality of angle adjustment holes 230 are arranged at regular intervals along the circumferential direction on the vertical bracket piece 213. The plurality of angle adjustment holes 230 have a structure arranged at regular intervals along the circumferential direction based on the hinge 220, which will be described later.

As shown in FIG. 20, the angle adjustment coupling portion includes a hinge 220, a plurality of angle adjustment holes 230, and an angle setting ball 240.

The hinge 220 supports a pair of vertical bracket pieces 213 of the bracket 210 so that they are coupled to the heat dissipation body 120 of the heat dissipation portion (HTP). At this time, the hinge 220 includes a hinge pin coupling hole 221 (see FIGS. 13, 16, and 17) formed in a pair of vertical bracket pieces 213 of the bracket 210, and the heat dissipation body 120. A pin coupling hole 223 on the connection body 125 side (see FIG. 18) penetrating both sides of the connection body 125, and a hinge pin coupling hole 221 of the pair of vertical bracket pieces 213. and a hinge pin 225 (see FIGS. 12 and 21) inserted into the pin coupling hole 223 on the connection body 125 side. Accordingly, the hinge 220 has a structure that supports the pair of vertical bracket pieces 213 of the bracket 210 to be coupled to the heat dissipation body 120 of the heat dissipation portion (HTP). Since the pair of vertical bracket pieces 213 of the bracket 210 are coupled to the connection body portion 125 provided at the center of the lower part of the heat dissipation body 120 via the hinge 220, the bracket 210 ) has a structure that supports the heat dissipation part (HTP) to be coupled to the heat dissipation body 120. The heat dissipation part (HTP) can rotate along a cylindrical rotation trajectory with respect to the bracket 210 based on the hinge 220 . When based on an imaginary vertical line (see FIG. 20) extending vertically from the vertical bracket piece 213 of the bracket 210, the heat dissipation part (HTP) moves forward along a cylindrical rotational trajectory with respect to the hinge 220. It can be rotated or rotated backwards.

The angle adjustment hole 230 is provided on a pair of vertical bracket pieces 213 of the bracket 210. 13, 16, and 17, a plurality of angle adjustment holes 230 are arranged at regular intervals along the circumferential direction with the hinge 220 as a reference. As shown in Figures 16 and 17, when the vertical bracket piece 213 of the bracket 210 is viewed from the side, a plurality of angle adjustment holes ( 230) are placed at regular intervals.

As shown in FIG. 18, the angle setting ball 240 is provided on the connection body portion 125 of the heat dissipation body 120 constituting the heat dissipation portion (HTP). As shown in FIG. 21, a ball housing 242 is provided inside the connection body portion 125, a ball projection hole 126 is provided at the tip of the ball housing 242, and the inside of the ball housing 242 A spring 244 is built in, and a part of the angle setting ball 240 is formed in the ball projection hole 126 and the connection body portion 125 of the ball housing 242 by the elastic force of the spring 244. It protrudes into the ball emergence hole 126 on the (120) side, and a part of the angle setting ball 240 is inserted into the angle adjustment hole 230 formed in the vertical bracket piece 213 of the bracket 210. The ball housing 242, spring 244, and angle setting ball 240 are connected to the heat dissipation body 120 so that they are disposed at positions facing a pair of vertical bracket pieces 213 on both left and right sides of the bracket 210. Provided in the body portion 125, a portion of the pair of angle setting balls 240 are disposed on both left and right sides of the connection body portion 125 of the heat dissipation body 120. It is inserted into the angle adjustment hole 230 formed in the left and right pair of vertical bracket pieces 213 of the bracket 210.

Therefore, as shown in FIGS. 20 and 21, a portion of the left and right pair of angle setting balls 240 provided on the connection body portion 125 of the heat dissipation body 120 constituting the heat dissipation portion (HTP) is By being inserted into the angle adjustment hole 230 formed in the vertical bracket pieces 213 on both left and right sides of the bracket 210 fixed to the post 112 of the base 110, the heat radiation portion (HTP) is based on the post 112. This ensures that the rotated angle is maintained along the cylindrical rotation trajectory. When the heat dissipation part (HTP) and the post 112 of the base 110 are viewed from the side, the angle at which the heat dissipation part (HTP) is rotated forward or backward along a cylindrical rotation trajectory is based on an imaginary vertical line. to maintain.

As shown in FIG. 11, the heat dissipation part (HTP) includes a heat dissipation body 120 having a heat dissipation opening at the front, and a heating element 130 built into the heat dissipation body 120. ) is maintained in a state rotated forward or backward along a cylindrical rotation trajectory with respect to the post 112 provided on the base 110 by the angle adjustment coupling unit, so that the heat generated when the heating element 130 is generated is maintained. The angle of radiation through the heat dissipation opening of the heat dissipation body 120 is adjusted.

Therefore, the present invention adjusts the angle of the heat dissipation part (HTP) by inserting the angle setting ball 240 provided in the heat dissipation part (HTP) into the plurality of angle adjustment holes 230 formed in the bracket 210 by a simple structure. By maintaining this, the radiation angle of the heat radiating from the heat sink (HTP) can be adjusted as desired at the place where the heater is used, making it convenient to use the heater.

Meanwhile, Figure 22 is a right side view of the bracket 210, which is a main part of another embodiment of the present invention, and Figure 23 is a perspective view of Figure 22. As shown in FIGS. 22 and 23, among the plurality of angle adjustment holes 230, fine angle adjustment holes 232 are further provided between adjacent angle adjustment holes 230. As shown in Figure 22, the fine angle adjustment hole 232 is further provided on one vertical bracket piece 213 among the left and right vertical bracket pieces 213 of the bracket 210. Both sides of the fine angle adjustment hole 232 are connected to adjacent angle adjustment holes 230.

Therefore, as shown in FIG. 25, the angle setting ball 240 is inserted into the fine angle adjustment hole 232, thereby expanding the angle adjustment range of the heat dissipation portion (HTP). This is to increase the angle adjustment resolution of the heat dissipation part (HTP). Increasing the resolution of the angle adjustment of the heat dissipation part (HTP) means that the angle of the heat dissipation part (HTP) can be adjusted more precisely. This allows more detailed adjustment of the angle of heat radiating from the heat dissipation part (HTP). You can use the heater more conveniently in the place where the heater is used.

Meanwhile, as shown in FIG. 26, at least one vertical bracket piece 213 among the pair of vertical bracket pieces 213 of the bracket 210 is provided with a stopper 214. The stopper 214 is inserted into the stopper 214 coupling hole 126 provided in the vertical bracket piece 213. The stopper 214 may be composed of a screw nail that is screwed into the stopper 214 coupling hole 126 of the vertical bracket piece 213. The stopper 214 protrudes into the area between the left and right pair of vertical bracket pieces 213. The stopper 214 is provided on the vertical bracket piece 213 to be disposed lower than the plurality of angle adjustment holes 230.

Therefore, as shown in FIG. 27, since the rear of the connection body portion 125 below the heat dissipation body 120 of the heat dissipation portion (HTP) is caught by the stopper 214, the heat dissipation portion (HTP) is a heater. is excessively shifted toward the rear based on the hinge 220 coupled to the post 112 of the base 110 (specifically, based on the hinge 220 coupled to the upper connection block provided on the base 110). prevent it from happening. Since the connection body portion 125 of the heat dissipation body 120 is caught on the stopper 214 so that the front opening portion of the heat dissipation body 120 of the heat dissipation part (HTP) is not excessively rotated downward toward the ground, heat dissipation occurs. It is possible to prevent too much heat radiated from the heating element 130 built into the heat radiating part (HTP) from radiating to the ground. In this way, if the heat radiating from the heat radiating part (HTP) radiates too much from the heating area only to the ground, By preventing this, a decrease in heating efficiency is prevented in the heating area.

Meanwhile, as shown in FIGS. 26 and 27, a reinforcing support pin 216 is coupled to the horizontal bracket piece 212 of the bracket 210, and the bracket 210 is supported by the reinforcing support pin 216. It is coupled to the post 112 of the base 110 of the heater.

Therefore, by reinforcing the strength of the bracket 210 coupled to the post 112, the heat dissipation part (HTP) is more stably and firmly coupled to the post 112 of the base 110 through the bracket 210. There is.

Meanwhile, Figures 28 and 29 show another embodiment with a modified structure of the bracket 210, which is the main part of the present invention.

Referring to FIGS. 28 and 29, the centers of the plurality of angle adjustment holes 230 formed in each pair of vertical bracket pieces 213 of the bracket 210 are arranged to be offset from each other. If the pair of vertical bracket pieces 213 are respectively referred to as the left vertical bracket piece 213 and the right vertical bracket piece 213, the center of the plurality of angle adjustment holes 230 formed in the left vertical bracket piece 213 is located on the right side. It is configured to be offset from the center of the plurality of angle adjustment holes 230 formed in the vertical bracket piece 213 rather than being arranged on the same line.

At this time, the connection body portion 125 of the heat dissipation body 120 is provided with a portion of a pair of angle setting balls 240 protruding from the left and right sides.

Accordingly, the angle setting ball 240 provided on the left side of the connection body portion 125 is connected to any one of the plurality of angle adjustment holes 230 of the vertical bracket piece 213 on one side. In the inserted state, it is maintained in a pressed state by contacting the outer surface of the other vertical bracket piece 213 provided on the right side of the connecting body portion 125, and the angle provided on the right side of the connecting body portion 125 When the setting ball 240 is inserted into any one angle adjustment hole 230 among the plurality of angle adjustment holes 230 of the other vertical bracket piece 213, it is located on the left side of the connection body portion 125. Since it is maintained in a pressed state by contacting the outer surface of the vertical bracket piece 213 on one side, there is an effect of expanding the angle adjustment range of the heat dissipation portion (HTP). In other words, as the heat dissipation part (HTP) is rotated based on the hinge 220, the left angle setting ball 240, which partially protrudes from the left side of the connection body part 215, is connected to the bracket 210. It is inserted into one of the angle adjustment holes 230 provided in the left vertical bracket piece 213, maintains the rotation angle adjustment state of the heat dissipation part (HTP), and connects the heat dissipation part (HTP) to the hinge 220. When rotated based on , the right angle setting ball 240, a portion of which protrudes from the right side of the connection body 215, is provided at an angle on the right vertical bracket piece 213 of the bracket 210. Since it is inserted into the adjustment hole 230 and maintains the rotation angle adjustment state of the heat radiation part (HTP), the rotation angle of the heat radiation part (HTP) can be finely adjusted, so that the rotation angle of the heat radiation part (HTP) can be finely adjusted. This has the effect of expanding the angle adjustment range.

Above, specific embodiments of the present invention have been described in detail. However, the spirit and scope of the present invention are not limited to these specific embodiments, and it is known by common knowledge in the technical field to which the present invention pertains that various modifications and variations can be made without changing the gist of the present invention. Anyone who has it will understand.

Therefore, the embodiments described above are provided to fully inform those skilled in the art of the present invention of the scope of the invention, and should be understood as illustrative in all respects and not restrictive. The invention is defined only by the scope of the claims.

110. Base 112. Post
112A. Lower connection post part 112B. Upper connection post part
HTP. Heat dissipation unit 120. Heat dissipation body
122. Side body wall 123. Upper body wall
124. Lower body wall 125. Connected body portion (125)
126. Hall 127. Safety Net
128. Side guard plate 130. Heating element
132. Insulator 134. Clip
140. Reflector 142. Concave reflector part
143. Upper reflector part 144. Lower reflector part
145. Middle reflector 147. Heat conduction blocking hole
148. Side reflector 210. Bracket
212. Horizontal bracket section 213. Vertical bracket section
214. Stopper 215. Coupling pin
216. Reinforcement support pin 220. Hinge
221. Hinge pin coupling hole 223. Pin coupling hole on the connection body (125) side
225. Hinge pin 230. Angle adjustment hole
232. Fine angle adjustment hole 240. Angle setting ball
242. Ball housing 244. Spring

Claims (13)

A heat dissipation body 120 having a heat dissipation opening at the front and coupled to a post 112 provided on the base 110 of the heater;
A heating element 130 embedded in the heat dissipation body 120;
It is configured to include a reflector 140 disposed between the heating element 130 and the heat dissipation body 120,
The reflector 140 is provided with a plurality of heat conduction blocking holes 147 at least at the top and bottom,
The reflector 140 is provided with at least two concave reflector portions 142, and the heating element 130 is accommodated and disposed in the concave reflector portion 142,
Side guard plates 128 are coupled to both left and right front surfaces of the heat dissipation body 120, and a pair of side guard plates 128 are disposed on the heat dissipation body 120. (128) is composed of a cylindrical plate with a convex center portion,
The heat dissipation body 120 is provided with a plurality of holes 126 communicating with the inner and outer surfaces,
The heat dissipation body 120 includes a pair of left and right side body walls 122, an upper body wall 123, and a lower body wall 124, and a pair of side body walls 122 and an upper body wall 123. ) and a connection body portion 125 is provided between the inner end of the lower body wall 124, and a pair of side body walls 122, upper body wall 123, and lower body wall 124 are heat dissipation bodies ( It is configured to be inclined toward the center of 120),
The holes 126 of the heat dissipation body 120 are formed to communicate with both sides of the left and right pair of side body walls 122, the upper body wall 123, and the lower body wall 124, and simultaneously form a plurality of holes 126. are arranged in the longitudinal and transverse directions, and the plurality of holes 126 formed in the pair of side body walls 122 are configured to gradually decrease in area from the outer end to the inner end of the side body wall 122. , the plurality of holes 126 formed in the upper body wall 123 and the lower body wall 124 also gradually increase in area from the outer end to the inner end of the upper body wall 123 and the lower body wall 124. A heater having a heat dissipation structure configured to shrink.
delete delete delete According to paragraph 1,
The reflector 140 is provided with side reflector portions 148 on both left and right sides so that the reflector 140 is configured to include a pair of side reflector portions 148, and the inner surface of the side reflector portion 148 is A clip 134 is provided, and the heating element 130 is composed of a straight tube-shaped heater with insulators 132 at both ends, and the insulators 132 of the heating element 130 are the side reflector portion ( A heater with a heat dissipation structure, characterized in that the part coupled to the clip 134 provided in the heating element 130 and radiating heat from the heating element 130 is spaced a certain distance away from the side reflector part 148.
delete According to paragraph 1,
Characterized in that it is configured to further include an angle adjustment coupling part that couples the heat dissipation body 120 to the post 112 so that the rotation angle of the heat dissipation body 120 can be adjusted based on the post 112. A heater with a heat dissipation structure.
In clause 7,
The angle adjustment coupling part,
A bracket (210) having a pair of vertical bracket pieces (213) connected to the left and right side ends of the horizontal bracket piece (212), respectively;
A hinge 220 supporting the pair of vertical bracket pieces 213 of the bracket 210 to be coupled to the heat dissipation body 120 of the heat dissipation portion (HTP);
A plurality of angle adjustment holes 230 provided on the pair of vertical bracket pieces 213 and disposed at regular intervals along the circumferential direction with respect to the hinge 220;
It is provided on the connection body part 125 of the heat dissipation body 120 constituting the heat dissipation part (HTP) and is inserted into the angle adjustment hole 230 so that the heat dissipation part (HTP) extends around the circumference of the post 112. It is configured to include an angle setting ball 240 that maintains the rotated angle along the mold rotation trajectory,
In a state where the heat radiating part (HTP) is rotated in the vertical direction with respect to the post 112 by the angle adjusting coupling part, heat generated when the heating element 130 generates heat is transmitted to the heat dissipating body 120. A heater with a heat dissipation structure, characterized in that it is configured to adjust the angle radiating through the opening.
According to clause 8,
The heat dissipation part (HTP) includes a heat dissipation body 120 having a heat dissipation opening at the front, and a heating element 130 built into the heat dissipation body 120, and the heat dissipation part (HTP) includes the angle adjustment coupling part. It is maintained in a state rotated forward or backward along a cylindrical rotation trajectory based on the post 112, so that the heat generated when the heating element 130 is generated passes through the heat dissipation opening of the heat dissipation body 120. A heater with a heat dissipation structure configured to adjust the radiation angle.
According to clause 8,
Among the pair of vertical bracket pieces 213 of the bracket 210, at least one vertical bracket piece 213 is connected to adjacent angle adjustment holes 230 among the plurality of angle adjustment holes 230. A fine angle adjustment hole 232 is further provided, and the angle setting ball 240 is inserted into the fine angle adjustment hole 232, thereby expanding the angle adjustment range of the heat dissipation part (HTP). A heater with a heat dissipation structure.
According to clause 8,
Among the pair of vertical bracket pieces 213 of the bracket 210, at least one vertical bracket piece 213 is provided with a stopper 214 to be disposed lower than the plurality of angle adjustment holes 230. The rear of the connecting body 125 below the heat dissipating body 120 of the heat dissipating part (HTP) is caught by the stopper 214 so that the heat dissipating part (HTP) is connected to the post 112 of the base 110 of the heater. A heater with a heat dissipation structure configured to prevent excessive tilting toward the rear based on the combined hinge 220.
According to clause 8,
The horizontal bracket piece 212 of the bracket 210 is coupled to the post 112 provided on the base 110 of the heater by a reinforcing support pin 216, so that the bracket 210 is coupled to the post 112. A heater with a heat dissipation structure that reinforces the strength of the heater.
According to clause 8,
The centers of the plurality of angle adjustment holes 230 formed in each of the pair of vertical bracket pieces 213 of the bracket 210 are arranged to be offset from each other, and the connection body portion 125 of the heat dissipation body 120 A portion of a pair of angle setting balls 240 is provided to protrude on the left and right sides, and the angle setting balls 240 provided on the left side of the connection body 125 are positioned on one side of the vertical bracket piece 213. When inserted into any one of the plurality of angle adjustment holes 230, it is in contact with the outer surface of the other vertical bracket piece 213 provided on the right side of the connection body portion 125. It is maintained in a pressed state, and the angle setting ball 240 provided on the right side of the connection body 125 is connected to any one of the plurality of angle adjustment holes 230 of the vertical bracket piece 213 on the other side. In the state inserted into (230), the angle of the heat dissipation portion (HTP) is adjusted by being maintained in a pressed state in contact with the outer surface of the one vertical bracket piece 213 provided on the left side of the connection body portion 125. A heater with a heat dissipation structure that extends the range.

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