KR20030026105A - structure of damper for air conditioner using hydrogen storage alloy - Google Patents

Abstract

PURPOSE: A structure of a damper of an air conditioner using hydrogen storage alloy is provided to prevent deterioration of performance due to leakage of air. CONSTITUTION: Round parts(21a,22a,23a,24a) are formed on ends of guide members(21,22,23,24) in longitudinal direction, respectively. Corresponding surface contacting parts(210,230) with curvature approximately same with the round parts of the guide members are formed on both ends of a damper(200) in longitudinal direction so as to contact with the round parts of the guide members on surfaces correspondingly. Attachment between the damper and the guide members are improved thereby. Torsion is minimized as stiffness of both of the ends of the damper is reinforced.

Description

Structure of damper for air conditioner using hydrogen storage alloy

The present invention relates to an air conditioner using a hydrogen storage alloy, and more particularly, is installed inside the heat exchange chamber of an air conditioner using a hydrogen storage alloy so that air can be selectively supplied to the indoor side or the outdoor side. A damper structure of an air conditioner using a hydrogen storage alloy to switch directions.

In general, hydrogen can be stored in a liquid state inside a high pressure vessel under high pressure and cryogenic conditions, but recently, a method of more efficiently storing hydrogen using a hydrogen storage alloy has been proposed.

When hydrogen is occluded in the hydrogen storage alloy, an exothermic reaction occurs, whereas an endothermic reaction occurs when hydrogen is released or desorbed from the hydrogen storage alloy.

The above-described hydrogen storage alloy may be applied to various apparatuses that require heating or cooling by using an exothermic reaction or an endothermic reaction occurring when hydrogen is occluded or desorbed. Do it.

1 is a schematic view showing a heat exchange part structure of an air conditioner using a hydrogen storage alloy according to the prior art, Figure 2 is an enlarged view showing the main portion of the damper structure of the heat exchange chamber shown in FIG. The structure of the heat exchanger and the damper of the air conditioner using the conventional hydrogen storage alloy will be described as follows.

The heat exchange part 100 is provided with a hollow heat exchange chamber 20 inside the case 100a, and a pair of first reactor 110 and second reactor 120 are respectively formed in the heat exchange chamber 20. It is installed to face each other, the hydrogen storage alloy is filled in each of the first and second reactors 110 and 120, one side of the reactor is exothermic by the hydrogen is occluded or desorbed in each of the filled hydrogen storage alloy is endothermic The reactions alternate.

In addition, the hydrogen movement pipe 145 is connected between the first and second reactors 110 and 120, and the pumping means 141 and the valve means 142 are installed on the hydrogen movement pipe 145. Due to the pumping force of), it is possible to transfer hydrogen between the hydrogen storage alloy charged inside the reactor and the hydrogen storage alloy charged inside the other reactor.

Meanwhile, a pair of air inlets 131 and 132 may be provided at adjacent sides of the first and second reactors 110 and 120 to allow air from the indoor side and the outside side to flow into the heat exchange unit 100. When the side air flows into the heat exchange chamber 20, heat exchange is performed while passing through the first and second reactors 110 and 120.

In addition, the heat exchange part 100 is provided with a cold air discharge port 61 and a hot air discharge port 41 for discharging cold or warm air to the interior and exterior sides, and each of the discharge ports 61 and 41 is provided with blowing means 102 and 106. By the operation of the blower means it is possible to supply the cold and warm air from the heat exchange chamber 20 to the outside outside the room and to return the outside air to the heat exchange chamber 20 side.

In addition, guide members 21 to 24 that guide the flow of air introduced into the heat exchange chamber 20 while passing through the first and second reactors 110 and 120 are formed inside the heat exchange chamber 20 of the heat exchange unit 100. 1, the second reactor (110, 120) is installed adjacent to the flow direction of the air flowing into the heat exchange chamber 20 through the first reactor 110 and the second reactor 120 is directed toward the indoor side or the outdoor side. The damper 150 is switched according to the control of the controller so as to rotate around the rotation shaft 151.

Thus, as shown in FIG. 2, as the damper 150 is rotated by a predetermined angle under the control of the controller, both ends thereof are provided at the respective ends of the guide members 21 and 24 or the guide members 22 and 23. By separating and partitioning the inner region of the heat exchange chamber 20 in corresponding contact in the diagonal direction, it is possible to selectively switch the flow direction of air toward the outside of the room.

However, according to the conventional damper structure described above, in order to increase the amount of air flow, the area of the damper 150 must be increased, and the damper is required to reduce the weight of the damper in order to quickly switch the damper and reduce the weight of the system. It has to be formed with a relatively thin thickness compared to the area, in which case the problem that the strength and deformation of the damper occurs.

That is, when the damper torsion occurs due to a sudden temperature change, a gap is generated between the contact surfaces of the damper 150 and the guide members 21 to 24 when the air flows to the indoor side and the outdoor side, thereby reducing the flow loss of the flowed air. This caused a problem of degrading the performance of the system.

The present invention has been made to solve the conventional problems as described above, the present invention improves the adhesion performance of the portion where the damper and the guide member to the interview, in particular to reinforce the strength of the both ends of the damper in contact with the contact surface of the guide member torsion It is an object of the present invention to provide a damper structure of an air conditioner using a hydrogen storage alloy, which minimizes the occurrence and prevents performance degradation of the system due to leakage of flowing air.

1 is a schematic diagram showing a heat exchange part structure of an air conditioner using a hydrogen storage alloy according to the prior art,

FIG. 2 is an enlarged view illustrating main parts of the damper structure of the heat exchange chamber illustrated in FIG.

3 is a perspective view illustrating main parts of a damper structure according to an embodiment of the present invention;

4A and 4B are sectional views showing an operating state of the damper shown in FIG.

* Description of the symbols for the main parts of the drawings *

20 .... heat exchange chamber, 21,22,23,24 .... guide member,

21a, 22a, 23a, 24a .... round part, 110, 120 ... 1st, 2nd reactor,

200 .... damper, 210,230 ... corresponding interview,

220,240 .... Strengthening Department.

In order to achieve the above object, according to the present invention, the first and second reactors are installed inside the hollow heat exchange chamber and filled with hydrogen storage alloys to alternately endothermic and exothermic. A guide member for guiding the outside air introduced through the second reactor into the heat exchange chamber and the first and second reactors are rotated by a predetermined angle so that both ends thereof correspond to each end of the guide member. In the air conditioner using a hydrogen storage alloy comprising a damper for selectively switching the flow direction of the air by separating and partitioning the inner region of the heat exchange chamber, the end of the guide member to form a rounded portion along the length direction respectively Meanwhile, both ends of the damper have approximately the same curvature as the round part so as to be interviewed in correspondence with the round part. The damper structure of the air conditioner is provided with corresponding parts of the interview along the longitudinal direction with using a hydrogen storage alloy, characterized in that respectively.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the drawings.

In the following description, the same members among the main components of the heat exchanger according to the present invention will be given the same reference numbers with reference to the above-described prior art according to Figs. 1 to 2, and the detailed description thereof will be omitted.

Figure 3 is a perspective view of the main portion showing a damper structure according to an embodiment of the present invention, Figure 4a, Figure 4b is a cross-sectional view showing the operating state of the damper shown in Figure 3, as shown in the figure, the present invention The concave or convex round portions 21a to 24a are formed at each end of the guide members 21 to 24 which are in contact with both ends of the damper 200, and the rounds are formed at both ends of the damper 200. Corresponding interview portions 210 and 230 having approximately the same curvature as the round portions 21a to 24a are formed so as to be interviewed corresponding to the portions 21a to 24a, so that the contact between the guide members 21 to 24 and the damper 200 is formed. It is to improve the performance and to reinforce the strength of the damper 200.

In addition, on the damper 200 adjacent to the corresponding interview portions 210 and 230, strength reinforcement portions 220 and 240 bent in a direction parallel to the corresponding interview portions 210 and 230 may be formed to further impart strength to the damper 200. It would be.

Hereinafter, the damper 200 will be described in detail.

As shown in FIGS. 3 to 4A and 4B, guide members 21 to 24 are installed at adjacent sides of the first and second reactors 110 and 120 provided in the heat exchange chamber 20, respectively. Each end of ˜24 has round portions 21a to 24a having a predetermined curvature.

That is, the round portions 21a and 22a of the guide members 21 and 22 adjacent to the first reactor 110 may be convex, and the round portions of the guide members 23 and 24 adjacent to the second reactor 120 may be 23a, 24a has a concave shape.

In addition, a damper 200 rotatable about the rotation shaft 201 is installed between the guide members 21 to 24, and both ends of the damper 200 correspond to the respective round parts 21a to 24a. Corresponding interview portions 210 and 230 that are bent along the longitudinal direction are formed to be interviewed.

Both ends of the damper 200 are separated by contacting the guide members 21 to 24 positioned in the diagonal direction to separate the area of the heat exchange chamber 20.

In this case, the corresponding interview portions 210 and 230 may be formed of curved surfaces having substantially the same curvature as the round portions 21a to 24a.

The reason is that when the corresponding interview portions 210 and 230 are formed in a curved surface, the contact surfaces of the end portions of the guide members 21 to 24 and the damper 150 are planar as in the case of the conventional damper 150 shown in FIG. This is because the contact area between the end portions of the guide members 21 to 24 and the damper 200 can be further increased as compared with the case of contact, thereby improving the adhesion performance.

In addition, it is because the strength of the damper 200 can be reinforced by forming the bent surface by the corresponding contact portions 210 and 230 in the damper 200 in the planar state.

The strength reinforcement parts 220 and 240 that are bent in a direction parallel to the corresponding contact parts 210 and 230 are formed on the dampers 200 adjacent to the corresponding interview parts 210 and 230. The corresponding interview parts 210 and 230 and the strength reinforcement parts are formed. The 220 and 240 are formed to be connected in an approximately 'S' shape, so that the contact portions of the round portions 21a to 24a and the damper 200 are gently connected along the flow direction of air to flow toward the heat exchange chamber 20. The flow loss can be reduced by minimizing air resistance, and by forming bent surfaces at both ends of the damper 200, higher strength can be given to the damper 200.

In this case, in order to form the corresponding interview parts 210 and 230 and the strength reinforcing parts 220 and 240, when the damper 200 is used as a metal material, the flat metal material may be bent and processed using a press device or the like. And, of course, the synthetic resin material may be formed by integrally injection molding.

Referring to the operation and effect of the damper structure of the present invention made of the above-described configuration is as follows.

First, when the damper 200 is located as shown in FIG. 4A, the first reactor 110 is in communication with the outdoor side, and the second reactor 120 is in communication with the indoor side.

At this time, both ends of the damper 200 are separated and partitioned the heat exchange chamber 20 while connecting between the guide members (21, 24) located on the diagonal.

That is, in the convex round part 21a, the concave part of the corresponding interview part 210 is interviewed, and in the concave round part 24a, the convex part of the corresponding interview part 230 is interviewed. By maintaining the close contact state, the air introduced into the heat exchange chamber 20 through the first and second reactors 110 and 120 is guided to the outdoor side and the indoor side, respectively.

On the other hand, when the above-described damper 200 is rotated by a predetermined angle and positioned as shown in FIG. 4B under the control of the controller, the first reactor 110 is in a state of communicating with the indoor side, and the second reactor ( 120 is in communication with the outdoor side.

At this time, the convex part of the corresponding interview part 210 is interviewed in the concave round part 23a, and the corresponding interview part 210 is interviewed in the convex round part 22a, and it is intimate. By maintaining the contact state, the air introduced into the heat exchange chamber 20 through the first and second reactors 110 and 120 is guided to the indoor side and the outdoor side, respectively.

On the other hand, the embodiment of the present invention as described above is configured to help the understanding of the present invention is not limited only to the above-described embodiment, various modifications are possible within the scope without departing from the spirit of the present invention.

As described in detail above, the damper structure according to the present invention has the following effects.

First, the round part and the corresponding contact part may be in close contact with each other by forming a round part and a corresponding contact part having a shape corresponding to the portion where the guide member and the damper come into contact with each other, and the contact area between the guide member and the damper may be increased. There is an effect that can improve the contact performance of the guide member.

Second, by increasing the thickness of the damper or by simply bending the corresponding contact portion and the strength reinforcement on the damper without using a high-strength material, the damper is provided with strength, thereby reducing the occurrence of torsion due to sudden temperature changes and the like. There is an effect that can improve the performance of the system by minimizing the flow loss generated between the contact surface of the guide member.

Claims (2)

It is installed inside the hollow heat exchange chamber and filled with hydrogen storage alloys, respectively, and the first and second reactors alternately carrying out endothermic and exothermic reactions, and external air introduced through the first and second reactors. Air flow is provided between the guide member for guiding the inside of the heat exchange chamber and the first and second reactors so that both ends thereof contact each end of the guide member while being rotated by a predetermined angle to separate and partition the internal region of the heat exchange chamber. In the air conditioner using a hydrogen storage alloy comprising a damper for selectively switching the direction, Round portions are formed at the ends of the guide member in the longitudinal direction thereof, while corresponding ends of the dampers have substantially the same curvature as the round portions so as to be interviewed corresponding to the round portions. Damper structure of the air conditioner using a hydrogen storage alloy, characterized in that each formed according to. The method of claim 1, The damper structure of the air conditioner using a hydrogen storage alloy, characterized in that at least one or more strength reinforcement bent in a direction parallel to the corresponding interview portion formed on the damper.