KR102185943B1 - Heat exchanger using ionic wind - Google Patents

Abstract

The present invention relates to a heat exchanger using ionic wind, which can improve heat transfer performance. The heat exchanger using ionic wind comprises: a heat sink having a fluid flow path allowing a fluid for recovering heat thereinto to pass therethrough; a housing accommodating the heat sink therein and forming a gas channel to introduce gas thereinto to discharge the gas; a plurality of heat exchange pins installed to be supported on a side of the heat sink to be extended along the gas channel, and including pin areas and a crosscut formed between the pin areas to cross a gas flow direction; and an electrode member corresponding to the position of the crosscut to be installed between the heat exchange pins, and creating an ionic wind by applying a high voltage.

Description

Heat exchanger using ion wind{HEAT EXCHANGER USING IONIC WIND}

The present invention relates to a heat exchanger using ion wind, and more particularly, an ion wind capable of effectively recovering the heat of gas introduced into the gas channel by using ion wind generated by an electrode member installed on a gas channel. It relates to a used heat exchanger.

In general, a heat exchanger is mainly used to recover heat possessed by a high-temperature fluid by allowing heat transfer between a high-temperature fluid and a low-temperature fluid. For example, power plants or the like use a heat exchanger for generating hot water by recovering heat contained in exhaust gas after power generation is performed using a gas turbine.

In addition, a heat exchanger that uses gas heat to produce hot water generally induces heat transfer between a gas channel through which gas flows and a fluid channel through which water flows to produce hot water, and heat transfer fins are installed to improve heat transfer performance. Are doing.

In general heat exchangers, a method of improving heat transfer performance is used by designing an extended surface that increases the contact area between the gas and the heat exchanger fin. When the extended surface is increased, a pressure drop occurs between the gas and the surface of the heat exchanger fin, resulting in a flow rate The fact that it is reduced and the heat exchange performance is poor is acting as a limitation of the design.

Korean Registered Patent Publication No. 1211895 (2012.12.06)

Accordingly, the present invention was conceived to solve the above problems, and an object of the present invention is to install an electrode member for generating ion wind along a gas channel, and by providing a crosscut heat exchange fin, a heat sink It is to provide a heat exchanger using an ionic wind to improve heat transfer performance between a fluid passing through the interior and an exhaust gas passing through a gas channel.

In order to achieve the above object, the present invention includes a heat sink provided with a fluid flow path through which a fluid for recovering heat is passed therein; A housing accommodating the heat sink and forming a gas channel through which gas is introduced and discharged; A plurality of heat exchange fins supported on a side surface of the heat sink, installed to extend along the gas channel, and including a cross cut formed between the fin region and the fin region to cross the gas flow direction; And an electrode member installed between the heat exchange fins facing each other to correspond to the position of the cross cut and generating ionic wind by applying a high voltage to a heat exchanger using ion wind.

According to an embodiment of the present invention, the electrode member is a wire electrode.

According to an embodiment of the present invention, the wire electrode may be installed in the form of a wire electrode module in which a plurality of wire electrodes are provided between one insulating plate and the other insulating plate.

According to an embodiment of the present invention, the fin regions of the heat exchange fins and the cross cut are disposed to face each other in the height direction.

According to an embodiment of the present invention, a guide groove into which a side surface of one insulating plate of one side of the wire electrode module is inserted in a height direction is formed on a side surface of the heat sink, and a side cover of the housing corresponding to the side surface of the heat sink A guide groove is formed in which the side surface of the other side insulating plate of the wire electrode module is inserted in the height direction.

According to an embodiment of the present invention, in the wire electrode module, a grounding part for grounding of the wire electrode is installed on side surfaces of one insulating plate and the other insulating plate, and the upper insulating plate of the wire electrode module is installed to protrude from the upper cover of the housing. And an insulating flange in contact with the surface of the upper cover.

According to an embodiment of the present invention, an insertion hole is formed in the upper cover of the housing corresponding to the upper surface of the heat sink to allow the wire electrode module to pass through the upper cover and to be inserted along the guide groove, and the In the lower cover of the housing corresponding to the upper cover of the housing, a mounting groove into which the lower insulating plate of the wire electrode module is fit is formed.

The present invention is provided with a fluid flow path through which a fluid for recovering heat passes therethrough, and the erected flat plate type heat sink; A housing including an upper cover, a lower cover, and a side cover surrounding the heat sink, wherein a gas channel is formed between the side surface of the heat sink and the side cover; It is supported on the side of the heat sink and installed to extend along the gas channel, and includes a cross cut formed between the fin region and the gas flow direction, and spaced apart from each other in the height direction of the side of the heat sink Heat exchange fins to form a plurality of rows and arranged in parallel with each other; And a wire electrode installed between the fin regions facing each other in correspondence with the position of the cross cut and provided in a corresponding number along the heat exchange fins facing each other, and is insulated from the housing and the heat sink. Including;, the cross cut provides a heat exchanger using ion wind formed to separate the fin regions of the heat exchange fins from each other.

According to an embodiment of the present invention, the wire electrode is provided as a wire electrode module in which a plurality of wire electrodes extend in parallel between one insulating plate and the other insulating plate, and the heat sink surface is positioned at the cross cuts of the heat exchange fin. Correspondingly, a guide groove extending in a lateral height direction of the heat sink is formed, a guide groove extending in a lateral height direction of the side cover is formed in the side cover of the housing, and the wire electrode module is in the upper cover of the housing. An insertion hole that can be inserted into the guide groove is formed, and a mounting groove in which the lower insulating plate of the wire electrode module is inserted and fixed is formed in the lower cover of the housing, and the wire electrode module can be replaced with the entire module. Is installed.

According to the heat exchanger using the ion wind according to the present invention having the configuration as described above, the heat exchange efficiency is improved by using the ion wind by corona discharge generated from the electrode member while passing the fluid into the heat sink and passing the gas to the outside. There is an effect that can be improved.

It has the advantage of decomposing and removing organic and inorganic substances such as carbon dioxide, sulfur oxides, nitrogen oxides, bacteria, and bacteria by high voltage discharge and emission of electric field due to corona discharge.

1 is a perspective view showing a heat exchanger using ion wind according to an embodiment of the present invention.
2 is a perspective view showing a wire electrode module of a heat exchanger using ion wind.
3 is a perspective view showing a state in which a wire electrode module is installed in a heat exchanger using ion wind according to an embodiment of the present invention.
4 is a front view showing a state in which a wire electrode module is inserted between a heat sink and a side cover according to the present invention.
5 is a perspective view showing a heat exchanger using ion wind according to another embodiment of the present invention.
6 is a view for explaining the ion wind during corona discharge at the wire electrode in the heat exchanger using the ion wind according to the present invention.
7 is a graph showing the recovery rate of waste heat energy according to the prior art and the present invention.

The present invention will be described in detail in the text, since various modifications can be made and various forms can be obtained. However, this is not intended to limit the present invention to a specific disclosed form, and it should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention. In describing each drawing, similar reference numerals have been used for similar elements.

These terms are used only for the purpose of distinguishing one component from another component. The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Referring to the accompanying drawings, the heat exchanger using ionic wind according to the present invention includes a heat sink 200 having a fluid flow path inside the housing 100, a heat exchange fin 300 for heat exchange, and an electrode generating ion wind. It includes a wire electrode module 500 having a member.

The housing 100 includes upper and lower covers 110 and 120 for accommodating the heat sink 200, the heat exchange fin 300, and the wire electrode module 500 and forming a gas channel 400 through which gas is introduced and discharged, It has a partition wall structure including the side cover 130.

The upper and lower covers 110 and 120 are formed to face each other in a rectangular shape having a length corresponding to each other.

The side covers 130 are formed to correspond to each other on both sides of the upper and lower covers 110 and 120, and form the left and right gas channels 400 separated by the heat sink 200 along the longitudinal direction.

The side cover 130 is made of a multiple cover in which a plurality of partition walls are in contact with each other, but in an embodiment of the present invention, it is made of a double cover. The inner cover 131 of the side cover 130 is made of SUS material, and the outer cover 132 of the side cover 130 is made of PEEK (Poly Ether Ether Ketone) material like SUS. . In particular, since a high voltage is applied to the gas channel 400 through the electrode member, the side cover 130 should be made of a material having excellent insulation performance, such as a PEEK material.

As shown in FIG. 4, a guide groove 220 into which a side surface of an insulating plate 520a on one side of the wire electrode module 500 is inserted in the height direction is formed on the side of the heat sink 200. The guide groove 220 extends along both surfaces of the heat sink 200.

In addition, in the side cover 130 of the housing 100 corresponding to the side of the heat sink 200, the side surface of the other side insulating plate 520b of the wire electrode module 500 is inserted into the guide groove 140 in the height direction. ) Is formed. The guide groove 140 extends along the surface of the inner cover 131 of the side cover 130. The inner cover 131 enters between the upper and lower covers 110 and 120 so that the guide groove 140 through which the other insulating plate 520b of the wire electrode module 500 is guided can be formed in the inner cover 131 of the side cover 130 Formed by

In addition, an insertion hole 111 is formed that penetrates the upper cover 110 of the housing 100 and allows insertion along the guide grooves 140 and 220 formed between the cross cuts 310, and the upper portion of the housing 100 In the lower cover 120 of the housing 100 corresponding to the cover 110, a mounting groove 121 into which the lower insulating plates 520a and 520b of the wire electrode module 500 are fit is formed.

The heat sink 200 is formed in a flat plate shape and is arranged in a form erected at the center of the upper and lower covers 110 and 120 to support the heat exchange fins 300 and separate the space into two. In this case, the space separated into two may form the left and right gas channels 400, respectively.

The heat sink 200 is provided with a fluid flow path formed to allow fluid to pass through the heat sink 200. The fluid flow path extends inside the heat sink 200 in a zigzag shape.

Inside the heat sink 200, a plurality of flow paths are formed that are parallel to each other in the height direction, each extending, and a connection pipe 210 integrally connecting a plurality of flow paths to the upper and lower surfaces of the heat sink 200 into one flow path. ) Is installed. The connection pipe 210 is curved in a curved shape and is integrally connected with the flow path inside the heat sink 200 to lead from one inlet to the other outlet, and form a fluid flow path through which the fluid passes inside the heat sink 200 in a zigzag form. have.

Referring to the drawings, a plurality of heat exchange fins 300 for heat exchange are installed on both surfaces of the heat sink 200.

A plurality of heat exchange fins 300 are installed at intervals to form a plurality of rows in the height direction of the heat sink 200.

Each fin row extends longitudinally along both surfaces of the heat sink 200.

Gas channels 400 are formed in the upper and lower spaces between each fin row. The gas channel 400 extends longitudinally along both surfaces of the heat sink 200 between each fin row, and thus perpendicularly intersects the fluid flow path inside the heat sink 200.

According to the present invention, each fin row has a cross cut 310 penetrating in the vertical direction crossing the extension direction of the fin row. The cross cut 310 may be a form in which a plate-shaped long heat exchange fin 300 is cut at predetermined intervals in a vertical direction, and a plurality of short heat exchange fins 300 may be arranged at intervals in the length direction. . In this case, the fin regions of the heat exchange fins 300 and the cross cut 310 are disposed to face each other in the height direction.

The cross cut 310 controls the pressure drop accompanying the expansion of the heat exchange surface in the heat exchange fin 300 so that the thermal boundary layer is not fully developed and re-delivered continuously so that a high temperature difference between the exhaust gas and the heat exchange fin 300 can be maintained. do. Accordingly, the convective heat transfer rate in the heat exchange fins 300 increases.

According to the present invention, the electrode member is disposed along each gas channel 400 in a direction crossing the extending direction of the gas channel 400. When a high voltage is applied to the electrode member, a corona wind is formed in the direction of the pin.

As such an electrode member, a mesh member, a needle, a needle member, a wire, etc. may be used, and a wire electrode 510 is used in the embodiment of the present invention. Tungsten wire is used as the wire electrode 510.

When a high voltage, such as 7kv, is applied to both ends of the wire electrode 510 while the heat sink 200 is grounded, a corona discharge occurs near the wire electrode 510 and ion wind is formed, and the surface of the heat exchange fin 300 As the flow accelerates, heat transfer increases.

In the heat sink 200 according to the present invention, the induction electrode is electrically grounded. This eliminates the need to install a separate induction electrode, so there is no space limitation for installing the induction electrode, and thus the device can be downsized.

The wire electrode 510 is installed in the form of a wire electrode module 500 in which a plurality of wire electrodes 510 are provided at intervals in the height direction between one insulating plate 520a and the other insulating plate 520b.

In the wire electrode module 500, a ground part 521 for grounding the wire electrode 510 is formed on side surfaces of one insulating plate 520a and the other insulating plate 520b.

The wire electrode module 500 passes through the upper cover 110 of the housing 100 and allows insertion through the guide grooves 140 and 220 formed along the cross cut 310 between each pin column 111 Is formed, and an insulating flange 530 is provided on the top of the wire electrode module 500 to protrude from the upper cover 110 of the housing 100 and in contact with the outer surface of the upper cover 110.

When the wire electrode module 500 is inserted through the insertion hole 111 of the upper cover 110, it is preferable that the wire electrode 510 can be positioned in the cross cut 310 between each pin column.

The insulating flange 530 is preferably formed to be spaced apart so as not to interfere with the connection pipe 210 exposed above the upper cover 110.

FIG. 5 is a perspective view showing a heat exchanger using ion wind according to another embodiment of the present invention. In describing another embodiment of the heat exchanger using ion wind according to the present invention, the same configuration as the embodiment of the present invention and For configurations having the same function, the same configuration code is used, and detailed descriptions of these configurations are omitted to avoid repetitive configurations.

As shown in FIG. 5, according to the heat exchanger using ion wind according to another embodiment of the present invention, the heat sink 200 disposed between the upper and lower covers 110 and 120 as the width of the upper and lower covers 110 and 120 is enlarged is side A plurality of heat exchange fins 300 may be disposed in succession in the direction, and are supported and disposed on the side of the heat sink 200 corresponding to the heat sink 200, and a cross cut 310 between the heat exchange fins 300 Wire electrode modules 500 inserted therebetween are installed in an expandable form.

The expansion type heat exchanger configured as described above not only increases heat exchange performance due to an increase in the flow rate of the fluid passing through the heat sink 200 and the exhaust gas passing through the gas channel 400, but also improves the heat insulation performance of the heat exchanger. You will be able to.

6 is a view for explaining ion wind during corona discharge at the wire electrode 510 in the heat exchanger using ion wind according to the present invention.

Referring to the drawings, a wire electrode 510 installed corresponding to the position of a cross cut 310 formed at an interval between a plurality of heat exchange fins 300 formed at intervals along the length direction of the gas channel 400 Since a high voltage is applied to the wire electrode 510, corona discharge is generated, and ion wind is formed to accelerate the flow on the surface of the heat exchange fin 300 to increase heat transfer. At this time, in the cross-cut 310, the electric field is cut, thereby suppressing the reverse flow of the ion wind and maintaining an optimal distance with the wire electrode 510, thereby maximizing the heat transfer effect of the corona wind.

Accordingly, since the flow rate of the exhaust gas between the heat exchange fins 300 increases, a smooth flow of the exhaust gas passing through the gas channel 400 can be ensured, and the flow rate of the high-temperature exhaust gas passing through the gas channel 400 is reduced. As it increases, heat exchange performance with the fluid passing through the heat sink 200 is improved.

In addition, organic and inorganic substances such as carbon dioxide, sulfur oxides, nitrogen oxides, bacteria, and bacteria contained in the exhaust gas due to high voltage discharge due to corona discharge generated from the wire electrode 510 of the gas channel 400 and the emission of electric fields. Since it can be removed by decomposition, it is possible to achieve a purification effect on exhaust gas.

7 is a graph showing the recovery rate of waste heat energy according to the prior art and the present invention. The present invention is generated by the wire electrode 510 installed on the gas channel 400 by applying a heat exchanger using ion wind to a gas generator. The energy production efficiency of the exhaust gas introduced into the gas channel 400 using ion wind is shown, and the prior art shows the energy production efficiency of the gas generator in a state in which the heat exchanger according to the present invention is not applied.

As a result of the experiment, by applying the heat exchanger according to the present invention, the energy production efficiency in the present invention was maintained at approximately 42% to 47%, and the energy production efficiency of the prior art was maintained at a maximum of 30%. It shows that the energy production efficiency of exhaust gas has increased.

Accordingly, the present invention can be seen that the heat exchange efficiency can be stably improved by using the ion wind caused by the corona discharge generated from the electrode member while passing the fluid into the heat sink and passing the gas to the outside. In addition, it can be seen that by generating ionic wind due to corona discharge, organic and inorganic substances such as carbon dioxide, sulfur oxides, nitrogen oxides, bacteria, and bacteria can be decomposed and removed through high voltage discharge and emission of an electric field.

The above description of the present invention is for illustrative purposes only, and those of ordinary skill in the art to which the present invention pertains can understand that it is possible to easily transform it into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not limiting. The scope of the present invention is indicated by the claims to be described later, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention.

100: housing 110: upper cover
120: lower cover 130: side cover
200: heat sink 210: connector
300: heat exchange pin 310: cross cut
400: gas channel 500: wire electrode module
510: wire electrode 520a, 520b: insulating plate
530; Insulation flange

Claims (9)

A heat sink provided with a fluid passage through which a fluid for recovering heat passes therethrough;
A housing accommodating the heat sink and forming a gas channel through which gas is introduced and discharged;
A plurality of heat exchange fins supported on a side surface of the heat sink, installed to extend along the gas channel, and including a cross cut formed between the fin region and the fin region to cross the gas flow direction; And
A heat exchanger using ion wind, comprising an electrode member installed between the heat exchange fins facing each other to correspond to the position of the cross cut, and generating ion wind by applying a high voltage.
The method of claim 1,
The electrode member is a heat exchanger using ion wind, characterized in that the wire electrode.
The method of claim 2,
The wire electrode is a heat exchanger using ion wind, characterized in that installed in the form of a wire electrode module provided with a plurality of wire electrodes between one insulating plate and the other insulating plate.
The method of claim 1,
Heat exchanger using ion wind, characterized in that the fin regions of the heat exchange fins and the cross cut are disposed to face each other in a height direction.
The method of claim 3,
A guide groove is formed on the side of the heat sink into which the side of the insulating plate on one side of the wire electrode module is inserted in the height direction,
Heat exchanger using ion wind, characterized in that a guide groove is formed in the side cover of the housing corresponding to the side surface of the heat sink in which the side surface of the other insulating plate of the wire electrode module is inserted in the height direction.
The method of claim 5,
In the wire electrode module, a grounding portion for grounding the wire electrode is installed on side surfaces of one insulating plate and the other insulating plate,
Heat exchanger using ion wind, characterized in that the upper insulating plate of the wire electrode module is installed to protrude from the upper cover of the housing and has an insulating flange in contact with the surface of the upper cover.
The method of claim 6,
An insertion hole is formed in the upper cover of the housing corresponding to the upper surface of the heat sink to allow the wire electrode module to pass through the upper cover and be inserted along the guide groove,
Heat exchanger using ion wind, characterized in that the lower cover of the housing corresponding to the upper cover of the housing is formed with a mounting groove in which the lower insulating plate of the wire electrode module is fitted in shape.
A fluid flow path through which a fluid for recovering heat passes therethrough, and an erected flat plate-shaped heat sink;
A housing including an upper cover, a lower cover, and a side cover surrounding the heat sink, wherein a gas channel is formed between the side surface of the heat sink and the side cover;
It is supported on the side of the heat sink and installed to extend along the gas channel, and includes a cross cut formed between the fin region and the gas flow direction, and spaced apart from each other in the height direction of the side of the heat sink Heat exchange fins to form a plurality of rows and arranged in parallel with each other; And
A wire electrode installed between the fin regions of the heat exchange fins facing each other in correspondence with the position of the cross cut and provided in a corresponding number along the heat exchange fins facing each other, and insulated from the housing and the heat sink; Including,
The cross cut is a heat exchanger using ion wind, characterized in that formed to separate the fin regions of the heat exchange fins from each other.
The method of claim 8,
The wire electrode is provided as a wire electrode module having a plurality of wire electrodes extending in parallel between one insulating plate and the other insulating plate,
A guide groove extending in a lateral height direction of the heat sink corresponding to the positions of the cross cuts of the heat exchange fin is formed on the surface of the heat sink,
A guide groove extending in the side height direction of the side cover is formed in the side cover of the housing,
An insertion hole into which the wire electrode module can be inserted into the guide groove is formed in the upper cover of the housing,
A mounting groove is formed in the lower cover of the housing to which the lower insulating plate of the wire electrode module is inserted and fixed,
The wire electrode module is a heat exchanger using ion wind, characterized in that the module is mounted interchangeably.

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