KR100459196B1 - heating and cooling device of reactor for hydrogen storage alloys - Google Patents

Abstract

The present invention relates to a cooling and heating device using a hydrogen storage alloy, and in particular, to provide a reactor of a heating and cooling device using a hydrogen storage alloy to optimize the arrangement of each reaction vessel performing a heat exchange action to achieve a more efficient heat exchange. will be.

To this end, the present invention is filled with a hydrogen storage alloy therein, a plurality of reaction vessels formed so as to be gradually condensed from the inlet side of the air toward the outlet side of the air, provided between each of the reaction vessel to transfer heat from each reaction vessel Heat exchange fins for receiving heat exchange with outside air; In addition, the present invention proposes a reactor of a heating and cooling device using a hydrogen storage alloy, comprising: a hydrogen inlet pipe connected to one end of each of the reaction vessels, through which hydrogen inlet and outlet are made.

Description

Reheating and cooling device of reactor for hydrogen storage alloys

The present invention relates to a heat exchanger of a heating and cooling device using a hydrogen storage alloy, and more particularly, to a structure of each reactor performing endothermic or exothermic reactions by occluding and desorbing hydrogen while forming the heat exchanger.

In general, hydrogen storage alloys have an exothermic reaction when hydrogen is adsorbed, an endothermic reaction when hydrogen is released, and a heat pump (Hydrogen Storage Alloy) has a large capacity for storing hydrogen. It is known to be used in applications such as heat pumps and hydrogen storage devices.

However, in the prior art, since the specific technology for implementing the air-conditioning device using the hydrogen storage alloy has not been made, substantial commercialization has not been achieved.

In particular, when the hydrogen storage alloy is applied to an air conditioner, the reactor that performs the role of a heat exchanger, although it must be at least similar to the heat exchange efficiency of the heat exchanger using a common refrigerant, it is not the situation.

That is, conventionally, only a heat exchanger using a hydrogen storage alloy is thought to be formed in the same manner as a heat exchanger using a refrigerant, but no proposal has been made according to a specific arrangement structure or shape.

The present invention has been made to solve the various problems described above, and provides a reactor of a heating and cooling device using a hydrogen storage alloy to optimize the shape and arrangement of each reaction vessel performing a heat exchange action to achieve more efficient heat exchange. Its purpose is to.

1 is a schematic perspective view of a reactor constituting a heat exchanger of a heating and cooling device using a hydrogen storage alloy;

FIG. 2 is a cross-sectional view taken along line II of FIG. 1.

3 is a cross-sectional view schematically showing the shape of a reaction vessel according to another aspect of the present invention.

Explanation of symbols for the main parts of the drawings

110. Reaction vessel 120. Heat exchange fin

130. Hydrogen outflow pipe 140. Branch pipe

200. Hydrogen Storage Alloy

According to the aspect of the present invention for achieving the above object is filled with a hydrogen storage alloy, a plurality of reaction vessels formed to be gradually condensed from the inlet side of the air toward the outlet side of the air, and provided between each of the reaction vessels Heat exchange fins that receive heat from each reaction vessel and exchange heat with outside air; In addition, there is provided a reactor of a heating and cooling device using a hydrogen storage alloy, comprising: a hydrogen inlet pipe connected to one end of each of the reaction vessels, through which hydrogen inlet and outlet are made.

Hereinafter, with reference to the accompanying Figures 1 to 3 will be described in detail a preferred embodiment according to the present invention in more detail.

First, as shown in FIGS. 1 and 2, the reactor of the air-conditioning apparatus using the hydrogen storage alloy of the present invention has a large number of reaction vessels 110, a plurality of heat exchange fins 120, a hydrogen inlet pipe 130, and It is configured to include a branch pipe (140).

Each of the reaction vessels 110 is formed of a flat tube, and the hydrogen storage alloy 200 is filled therein, and is formed to be gradually condensed toward the side from which the air flows out from the side where the air flows in.

In particular, each reaction vessel 110 may be formed to form a wing (때) shape when viewed in a plane perpendicular to the flow direction of air. This is to form a conduit with each reaction vessel 110 is rounded along the flow direction of the air so that the flow of air can be smoothly guided. An embodiment thereof is shown in FIG. 3.

The configuration of each reaction vessel 110 as described above is one end of each reaction vessel 110 located on the air inlet side heat exchange is made larger than the other end is located on the outlet side of the air, the heat exchange ability toward the air outlet side Because it falls.

As a result, a temperature difference occurs due to a difference in reaction between one end of each reaction vessel 110 positioned on the air inlet side and the other end located on the air outlet side, and the sensible heat loss increases as the overall reaction switching cycle becomes longer. This may occur.

Therefore, the configuration of the present invention is to minimize the sensible heat loss by allowing more heat exchange to be performed at the site where the heat exchange is active.

In addition, the heat exchange fins 120 are provided between the reaction vessels 110 to receive heat from the reaction vessels 110 and heat exchange with outside air to thereby maximize the heat exchange area.

In particular, both ends of each of the heat exchange fins 120 are installed to be in close contact with each of the reaction vessels 110 so as to facilitate heat conduction, and are arranged to have an approximately zigzag shape when viewed based on the flow direction of air, thereby improving heat exchange efficiency. To improve.

Of course, the heat exchange fins 120 do not have to be arranged to form a zigzag shape. However, in order to enlarge the heat exchange area, the arrangement in the above-described shape is more preferable.

In addition, the hydrogen inflow pipe 130 is a pipe through which outflow of hydrogen is made.

The hydrogen outflow pipe 130 guides the hydrogen flow supplied to the branch pipe 140 or guides the hydrogen flow discharged from the branch pipe 140.

In addition, the branch pipe 140 guides the hydrogen flowing through the hydrogen outlet pipe 130 to each reaction vessel 110 or directs the hydrogen discharged from each reaction vessel 110 to the hydrogen outlet pipe ( 130).

At this time, the branch pipe 140 is one end is connected in communication with the hydrogen outflow pipe 130, the other end is made of a plurality of branches from the one end is connected to each reaction vessel 110.

Hereinafter, a series of processes for performing exothermic and endothermic reactions of the reactor made as described above will be described in more detail.

First, when the reactor 100 according to the present invention is used for the exothermic reaction, hydrogen is provided to the branch pipe 140 through the hydrogen outlet pipe 130.

That is, the hydrogen provided through the hydrogen outlet pipe 130 is introduced into each reaction vessel 110 along the respective pipes of the branch pipe 140 in the process of passing through the branch pipe 140.

In this process, the hydrogen is occluded in the hydrogen storage alloy 200 in each reaction vessel (110).

Therefore, each of the reaction vessels 110 performs an exothermic reaction.

At this time, the outside air passes through each reaction vessel 110 and heat emitted from the surface of each reaction vessel 110 and the surface of each heat exchange fin 120 provided between each reaction vessel 110 and Heat exchange.

In particular, since each of the reaction vessels 110 has a wider area of the front side (the air inflow side) than the rear side (the side from which the air flows out), the reaction vessel 110 has a large amount at the front side of each of the reaction vessels 110. Heat exchange takes place.

That is, considering that more hydrogen storage alloys 200 are filled in the front side of each reaction vessel 110, the front side of each reaction vessel 110 is more than the rear side of each reaction vessel 110. Since active exothermic reaction is made, more heat exchange is performed at the front side of each reaction vessel 110.

Accordingly, since the sensible heat loss that may be generated at the rear side of each reaction vessel 110 is compensated at the front side of each of the reaction vessels 110, the total sensible heat loss can be minimized.

In addition, it is possible to shorten the reaction conversion cycle of the hydrogen storage alloy 200 due to the above advantages.

On the other hand, the series of processes in which the reactor 100 according to the present invention performs the endothermic reaction is the same except that the opposite hydrogen flow is performed as in the exothermic reaction described above.

That is, as the hydrogen is released from each reaction vessel 110, the endothermic reaction by the hydrogen hernia from the hydrogen storage alloy 200 is performed to absorb the surrounding heat, thereby cooling the surroundings.

At this time, the heat exchange process between each reaction vessel 110, each heat exchange fin 120 and the outside air passing through each of the above is the same as the above-described embodiment, and thus a detailed description thereof will be omitted.

As described above, the reactor of the heating and cooling device using the hydrogen storage alloy according to the present invention has the effect of obtaining the maximum heat exchange efficiency by improving the shape of each reaction vessel.

Claims (5)

A plurality of reaction vessels filled with a hydrogen storage alloy and formed to be gradually condensed from the inflow side of the air to the outflow side of the air, Heat exchange fins provided between the reaction vessels to receive heat from the reaction vessels, and to exchange heat with external air; And, Reactor of a heating and cooling device using a hydrogen storage alloy, characterized in that comprises each of the reaction vessel hydrogen outlet pipe. The method of claim 1, Each reaction vessel Reactor of a heating and cooling device using a hydrogen storage alloy, characterized in that formed in a flat tube (flat tube). The method of claim 1, Each reactor vessel is a reactor of a heating and cooling device using a hydrogen storage alloy, characterized in that formed in the shape of a blade (翼) is rounded concentrically round the flow direction of the air so that the air flow can be guided smoothly. The method of claim 1, Each heat exchange fin Reactor of a heating and cooling device using a hydrogen storage alloy, characterized in that arranged in a zigzag shape when viewed based on the flow direction of the air. The method of claim 1, One end is connected in communication with the hydrogen outlet pipe, the other end is branched from the one end of the reactor of the heating and cooling device using a hydrogen storage alloy, characterized in that it further comprises a branch pipe connected to each reaction vessel.