KR20060008381A - Radial direction air flow type regenerator - Google Patents

Abstract

The present invention relates to a radial heat exchanger, comprising: a rectangular box-shaped housing having a guide mounted on an inner wall of a width direction; The housing is fixed in half in its longitudinal direction, and the hollow part inside is partitioned by partition walls, and a plurality of slits are formed on the outer circumferential surface thereof, and both sides thereof are formed to have upper and lower ends with each other based on the long axis, and thus only through the hollow part. A heat exchange element consisting of semi-elliptic first and second ducts having a plurality of slit to communicate with each other; A partition wall having one end inserted into the guide and the other end fitted into a guide groove formed in the partition wall to bisect the housing in the width direction thereof; Removably fitted to the rotating shaft of the drive motor provided on the bottom surface of the heat exchange element is configured to include a heat exchange wheel and the heat exchange medium and the auxiliary wheel alternately stacked to form a drum.

According to the present invention, the configuration is simple and easy to install, the internal structure is simple, easy to maintain, such as separation, mounting, washing, high heat exchange efficiency, it is possible to easily adjust the size of the equipment.

Description

Rotary Radiating Heat Exchanger {RADIAL DIRECTION AIR FLOW TYPE REGENERATOR}

1 (a), (b) is an exemplary view of a radial flow heat exchanger according to the prior art,

2 is an exploded perspective view of a part of a radial flow heat exchanger according to the present invention;

3 is an exploded perspective view of main parts of a radial type heat exchanger according to the present invention;

4 and 5 are exemplary views of a heat exchange medium constituting the present invention radial flow heat exchanger.

♧ description of the symbols for the main parts of the drawing ♧

100 .... Housing 110,120 .... Fan

132 .... Bee suction channel 134 .... Boot discharge channel

142..Ambient air suction channel 144 .... Ambient air exhaust channel

150a, b..guide 200a, b..partition wall

300 .... Heat exchange element 310 .... Heat exchange wheel

320 .... Heavy part 330 .... 1 duct

340 .... the second duct 350 .... the bulkhead

360 .... rotation shaft

The present invention relates to a heat exchanger for exchanging sensible and latent heat at the same time while rotating the heat exchange wheel including a heat exchange medium to flow air in and out of the room and the outside in a counter flow, and more particularly, easy to assemble and install and high heat exchange efficiency. A new type of rotary radial heat exchanger.

In general, regenerative (heat transfer or heat storage) heat exchangers contact a heat accumulator (a heat storage medium, commonly referred to as a 'heat exchange medium') as a medium for storing heat, absorb heat from a high temperature fluid, and then contact a low temperature fluid. It is a heat exchanger that transfers heat to low temperature fluid and is used to efficiently ventilate indoor air in buildings and houses.

Among these regenerative heat exchangers, especially rotary heat exchangers are attracting attention as excellent energy energy facilities due to their low cost and high heat recovery compared to other types of heat exchangers. An axial flow type for performing intake and exhaust of the counterflow; It is roughly classified into a radial flow type that performs intake and exhaust of the counter flow in the radial direction of the heat exchange wheel.

However, most of the radial heat exchanger disclosed in the prior art adopts a belt driving type and has a complicated structure with many accessories for supporting and driving a drum type heat exchange wheel, which is very cumbersome and difficult to assemble and install.

For example, in Fig. 1, Registered Room No. 327441 (September 9, 2003) "Drum Heat Exchanger" is illustrated, as shown in Fig. 1 (a) and (b), the main body 17 and its longitudinal direction. The barrier plate 14 partitioning the inner space of the main body 17 and the barrier plate 14 are disposed inside the main body 17 so that the blocking plate 14 is inserted and embedded therein, and the heat transfer medium 19d is wound around the drum body 19c. Heat transfer drum 19 is provided in the form of a predetermined shape, and as an auxiliary device provided to rotate it is very complex, such as roller 18, belt 20, drive motor 21, idler 23 and bracket 24, etc. Due to the structure, maintenance is difficult, and since the heat transfer drum 19 itself is provided in a fixed form, it is almost impossible to replace (circle) itself, and even if it is replaceable, it is very cumbersome and difficult, and in particular, the heat exchange efficiency is poor. There was a downside to this.

The present invention has been made in view of the above-mentioned problems of the prior art, and has been created to solve this problem, and the mounting structure of the heat exchange wheel and the heat exchange element is simple and easy to assemble and install and free to be easily exchanged and cleaned Its purpose is to provide a new type of radial heat exchanger with maximum heat exchange efficiency.

The present invention is a rectangular box-shaped housing having a guide placed on the inner wall in the width direction in order to achieve the above technical problem; The housing is fixed in half in its longitudinal direction, and the hollow part inside is partitioned by partition walls, and a plurality of slits are formed on the outer circumferential surface thereof, and both sides thereof are formed to have upper and lower ends with each other based on the long axis, and thus only through the hollow part. A heat exchange element consisting of semi-elliptic first and second ducts having a plurality of slit to communicate with each other; A dividing wall having one end inserted into the guide and the other end fitted into a guide groove formed in the partition wall to bisect the housing in the width direction thereof; Removably fitted to the rotating shaft of the drive motor provided on the bottom surface of the heat exchange element, the heat exchange medium and the auxiliary wheel is alternately stacked to provide a rotary radial heat exchanger comprising a heat exchange wheel formed in a drum form There is this.

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

Figure 2 is an exploded perspective view of a part of the heat exchanger according to the present invention, Figure 3 is an exploded perspective view of the main portion of the heat exchanger according to the present invention.

As shown in Figures 2 to 3, the present invention the axial heat exchanger is a rectangular box-shaped housing 100, the partition walls (200a, b) arranged in the longitudinal direction so as to bisect them in the width direction, and the partition wall ( It is arranged in the middle of the length of 200a, b) and consists of a heat exchange element 300 that bisects the housing 100 in its longitudinal direction.

Short side of the housing 100, that is, both side in the width direction surface through the duct-shaped air suction channel 132, the air discharge channel 134, the air suction channel 142, the outdoor air discharge channel through 144 are provided respectively.

In addition, the 'c' shaped guides 150a and b are fixed in the center of the separation distance between the air suction channel 132 and the air discharge channel 144 and the air discharge channel 134 and the air suction channel 142. do.

In addition, the fan (110, 120) is installed and fixed to the air discharge channel 134 and the external air discharge channel 144, the fan (110, 120) is a kind of cross-flow fan that sucks air in the axial direction and discharges in the radial direction.

The partition walls 200a and b are rectangular plate-shaped members for separating the flow path through which the inside air is sucked in and discharged and the flow path through which the outside air is sucked out and discharged to prevent mixing between the air flowing in and out, and each outer end of the partition wall 200a and b has a guide. It is fitted into and fixed to (150a, b) and each inner end is fixed to the guide groove 352 formed in the partition wall 350 constituting the heat exchange element 300.

The heat exchange element 300, as shown in Figure 3, the semi-elliptic first and second ducts (330, 340) to each other to form an oval cylindrical body, the inside is formed to have a hollow portion 320, hollow portion ( Part of the edge of the 320, that is, the first and second duct 330, 340 is in contact with the partition wall 350 to prevent the leakage of air is made of a structure.

Particularly, each of the first and second ducts 330 and 340 has an arc-shaped cut slit (air penetration hole) formed in a radial direction thereof. The slits on the discharge side are formed to communicate with each other through the hollow portion 320 of the heat exchange element 300.

In addition, a driving motor (not shown) is fixed to the bottom surface of the hollow portion, for example, the bottom surface of the housing 100, and a rotation shaft 360 is installed in the driving motor, and the heat exchange wheel 310 shown on the rotation shaft 360 is provided. It may be provided in a form that is locked so as not to be easily separated from the rotary shaft 360 by the locking member 312 after being fitted in the vertical direction and the key (key).

Here, the heat exchange wheel 310 may be a radial type heat exchange wheel of the drum type laminated with the auxiliary wheels on both sides of the wheel frame after mounting the mohair heat exchange medium to the wheel frame, or further modified by mohair The heat exchange medium may be a drum-shaped radial flow hybrid wheel, which is directly attached to the auxiliary wheel and laminated. The heat exchange medium is not limited to a mohair heat exchange medium, and a general heat exchange medium may be used.

As shown in Figs. 4 and 5, the mohair heat exchange medium (80, 80 ') is made of a thin, soft plastic or woven fiber (cloth) as the base 82, the heat-retaining member 84 on the base 82 ) Or the one end of the heat-retaining member 84 is penetrated downwardly from the upper surface of the base 82, and then vertically bent to move horizontally, and then penetrated upward again. Arranged in a "staple shape" and can be in the form of firmly attaching and fixing the auxiliary base 86 to the back of the base 82 in this arrangement state.

In addition, some of these heat-retaining members 84 may be formed by bundling a plurality of bundles and twisting two or more bundles thereof, and may be provided in the form of being bundled on a fiber when the fiber is a base 82.

In addition, also in the arrangement method, it may arrange | position regularly so that it may have the same shape, and may arrange | position irregularly in arbitrary (random) shape.

In particular, the heat-retaining member 120 has a diameter of 15 to 250 μm, preferably 80 to 200 μm; A filament form, alone or in combination, of nylon, polypropylene, metallic stainless steel, etc. having a porosity of 80 to 96%, preferably 88 to 94%, can be used.

Here, the porosity refers to the ratio of the volume of air to the total volume of the heat exchange medium. In order to increase the heat exchange efficiency of the heat exchange medium, the heat exchange area should be as wide as possible. It is related to the diameter of the heat-retaining fibers constituting the heat exchange medium.

Therefore, if the porosity of the heat exchange medium and the diameter of the heat-retaining fiber are reduced, the heat exchange area is increased compared to the same volume, so that the heat exchange efficiency can be increased, and the volume of the heat exchange medium can be reduced to facilitate the manufacture of a small heat exchanger while passing through the heat exchange medium. This has the disadvantage that the passage resistance of the air is increased.

On the contrary, if the porosity of the heat exchange medium and the diameter of the heat-retaining fiber are increased, the air resistance passing through the heat exchange medium can be reduced, but since the heat exchange area is reduced compared to the same volume, the heat exchange efficiency is reduced and the volume of the heat exchange medium is small. It is difficult to manufacture heat exchangers.

The present invention has been made for many years of experiments to meet the demanding conditions to make the optimum conditions 15-250㎛ diameter, 80-96% porosity is passed through the heat exchange medium within the range of temperature exchange efficiency of about 70-95% The pressure loss caused by the resistance of air is suitable for the condition below 250 Pa (N / ㎡). Especially preferably, the diameter of 80 ~ 200㎛, the porosity of 88 ~ 94% are within the range of about 70 ~ 95% of temperature exchange efficiency. The pressure loss caused by the resistance of the air passing through the heat exchange medium in the interior is so limited because it is very suitable for the conditions of 150 Pa (N / m 2) or less.

Meanwhile, the first and second ducts 330 and 340 are designed to exactly match the width of the long axis (the long diameter of the ellipse) and the housing 100 and are fixed to the inner surface thereof so that the air leakage does not occur at all. shall.

Radial heat exchanger of the present invention having such a configuration is utilized as a ventilation system of a building or the like.

For example, the indoor contaminated hot air is sucked into the housing 100 through the air intake channel 132 by driving the fan 110, and then the pressure difference in the space partitioned with the heat exchange element 300 interposed therebetween. The indoor air is sucked into the slit of the first duct 330 and then heat exchanged through the rotating heat exchange medium (80, 80 ').

Heat-exchanged indoor air is discharged through the other side slit in a temperature-decreased state and then discharged to the outside by the air exhaust channel 134 by the fan 110.

On the other hand, external fresh air sucked through the outside air suction channel 142 by the driving of the fan 120 flows into the heat exchange element 300 through the slit of the second duct 340, and then the heat exchange medium 80, 80 ') is heat exchanged and then supplied to the room via the outdoor air discharge channel (144).

Therefore, the indoor air can be ventilated without much loss of energy to prevent energy waste and to perform efficient heat exchange.

On the other hand, if the air volume decreases due to foreign matter attached to the heat exchange medium due to long time use, loosen the locking member 312 in the stopped state, take out the heat exchange wheel 310 and replace it with a new one, or exchange the heat exchange medium 80 80 ') can be conveniently used in the form of separating and washing and then remounting.

As described in detail above, the present invention provides the following effects.

First, the configuration is simple and easy to install.

Second, the internal structure is simple, so it is easy to remove, install, and maintain.

Third, heat exchange efficiency is high.

Fourth, the size of the equipment can be easily adjusted.

Claims (1)

A rectangular box-shaped housing having a guide mounted on the inner wall in the width direction; The housing is fixed in half in its longitudinal direction, and the hollow part inside is partitioned by partition walls, and a plurality of slits are formed on the outer circumferential surface thereof, and both sides thereof are formed to have upper and lower ends with each other based on the long axis, and thus only through the hollow part. A heat exchange element consisting of semi-elliptic first and second ducts having a plurality of slit to communicate with each other; A partition wall having one end inserted into the guide and the other end fitted into a guide groove formed in the partition wall to bisect the housing in the width direction thereof; A radial radial heat exchanger comprising: a heat exchange wheel detachably fitted to a rotation shaft of a driving motor provided on a bottom surface of the heat exchange element, the heat exchange medium and an auxiliary wheel being alternately stacked to form a drum.

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