KR20090008621U - Inhalation induction structure of electric heat exchange machine - Google Patents

Abstract

The present invention relates to a suction induction structure of the total heat exchanger to improve the heat exchange efficiency by inducing the air flowing from the indoor or outdoor to be evenly transmitted to both suction surfaces of the total heat exchange element.

The present invention is provided with a main body 10 and a main body 10 having suction and discharge passages 11 and 12 and indoor and outdoor suction ports 13 and 14 and indoor and external discharge ports 15 and 16. The internal slope of the filter 30 and the main body 10 that are disposed in a lozenge and installed on both suction surfaces of the heat exchange element 20 and the heat exchange element 20 that exchange heat between the outdoor air and the indoor air to filter foreign matter. Support partitions 40, suction passages 11, and discharge passages 12, respectively, disposed in the center to support the electrothermal exchange element 20 and the filter 30, and divide the suction passage 11 and the discharge passage 12, respectively. In each of the inlet fan 50 and the exhaust fan 60 is installed at the outlet of the), the inlet of the suction passage 11 and the discharge passage 12, the length of both suction surface of the heat exchange element 20 to the end of both sides The air induction plate (70) (80) is installed to be diagonally inclined diagonally.

Total heat exchanger, suction induction structure, total heat exchange element, air induction plate

Description

Induction structure of electric heat exchange machine

The present invention relates to a total heat exchanger, and more particularly, to the suction induction structure of the total heat exchanger to improve the heat exchange efficiency by inducing the air flowing from the indoor or outdoor to be evenly transferred to both suction surfaces of the total heat exchange element. It is about.

In general, the electrothermal heat exchanger is used as a part of the building air conditioning system. The indoor air discharged from the indoor air discharged in the process of discharging the indoor air to ventilate the building and ventilating the outdoor air to heat the building exchanges heat with each other. This is to reduce the heat loss generated during the ventilation process.

As shown in FIGS. 1 to 4, the total heat exchanger includes a main body including suction and discharge passages 1a and 1b, indoor and external suction ports 1c and 1d, and indoor and external discharge ports 1e and 1f. (1), a filter disposed in a lozenge inside the main body 1 and installed on both suction surfaces of both the heat exchange element 2 and the heat exchange element 2 for exchanging heat between the outdoor air and the indoor air to filter foreign matters; (3) and a support partition (4) disposed at the center of the inner slope of the main body (1) to support the heat exchange element (2) and the filter (3), and to partition the suction flow passage (1a) and the discharge flow passage (1b) (4). ), An intake fan 5 and an exhaust fan 6 provided at the outlets of the suction passage 1a and the discharge passage 1b, respectively.

In such a heat exchanger, the flow path through which the outdoor air sucked into the room passes and the flow path through the indoor air discharged into the outside are stacked at right angles to each other so that the outdoor air sucked into the room and the indoor air discharged to the outside are not mixed with each other. The total heat exchange element 2 which crosses and heat-exchanges is provided.

In addition, in the total heat exchanger, when foreign matter such as dust contained in the air flows into and accumulates inside the total heat exchange element 2, the internal flow path of the total heat exchange element 2 may be blocked, so that The filter 3 is disposed on both suction surfaces so that foreign matters contained in the air can be filtered by the filter 3 before being introduced into the heat exchange element 2.

The total heat exchanger is provided with a supporting partition 4 for supporting the total heat exchange element 2 and the filter 3, respectively, and partitioning the suction flow path 1a and the discharge flow path 1b.

However, the conventional electrothermal heat exchanger configured as described above has a large intake length of both suction surfaces of the total heat exchange element 2, and the suction flow path 1a and the discharge flow path 1 through the indoor suction port 1c and the outdoor suction port 1d. Since the air sucked into each inlet of 1b) is not evenly transmitted to both suction surfaces of the total heat exchange element 2, structurally, the entire suction surface of both sides of the heat exchange element 2 cannot be used. There was a problem that the heat exchange efficiency of 2) is greatly reduced.

That is, conventionally, the air sucked into the inlet of the suction channel 1a and the discharge channel 1b is easily transferred to the inlet of the suction surface on both sides of the total heat exchange element 2, but as shown in FIG. Since no air is transferred to the suction side 'A' and the 'B' portions on both sides of the total heat exchange element 2 located far from the inlet of the flow passage 1a and the discharge passage 1b, the heat exchange element is structurally There was a problem that the heat exchange efficiency of the total heat exchange element (2) is lowered because the heat exchange is not evenly performed on both suction surfaces of (2).

The object of the present invention is to solve the above-mentioned drawbacks as described above, induces the air flowing from the indoor or outdoor to be evenly transferred to both suction surfaces of the total heat exchange element, so that both sides of the total heat exchange element It is to provide a suction induction structure of the total heat exchanger to enable the use of all, through which the heat exchange is smoothly performed throughout the entire heat exchange element to further improve the heat exchange efficiency.

In order to achieve the above object, the present invention is inclined diagonally to the inlet of the suction flow path where the indoor air is sucked and the air induction plate extending to the ends of the suction surface of both sides of the heat exchange element at the inlet of the discharge flow path where the outdoor air is sucked. By installing, the air introduced from the indoor or outdoor by the air induction plate is to be evenly guided on both suction surfaces of the total heat exchange element.

In the present invention, since the air flowing from the indoor or outdoor is uniformly transmitted to both suction surfaces of the total heat exchange element, the entire suction sides of the total heat exchange element can be used. Thus, the heat exchange is smoothly performed throughout the total heat exchange element. As a result, the heat exchange efficiency can be further improved.

Hereinafter, the technical configuration of the present invention in detail according to the accompanying drawings.

As shown in FIGS. 5 and 6, the suction induction structure of the inventive heat exchanger includes the suction and discharge passages 11 and 12 and the indoor and external suction ports 13 and 14 and the indoor and external discharge ports 15 ( 16 is provided on the suction surface of both sides of the main body 10, the heat transfer element 20, the heat exchange element 20 is arranged in a lozenge inside the main body 10 to exchange heat between the outdoor air and the indoor air, respectively And the filter 30 for filtering foreign matters is disposed at the centers of the inner slopes of the main body 10, respectively, to support the heat exchange element 20 and the filter 30, and divide the suction flow path 11 and the discharge flow path 12. The intake fan 50 and the exhaust fan 60, which are respectively installed at the outlet of the support partition 40, the suction passage 11 and the discharge passage 12, respectively, wherein the suction passage 11 and the discharge passage 12 At the inlet of the air induction plates 70, 80 extending to the ends of both sides of the suction surface of the heat exchange element 20, respectively, inclined diagonally Generated and characterized in that on the technical configuration.

Here, the electrothermal heat exchanger according to the present invention is installed to be embedded in the ceiling of the building, so that the outdoor air sucked into the room and the indoor air discharged to the outside heat exchange with each other when the room is ventilated, thereby allowing the indoor air and indoor temperature to be sucked into the room. It is possible to reduce heat loss by reducing the difference with.

The inside of the main body 10 is provided with a suction passage 11 for guiding the outdoor air to the inside and a discharge passage 12 for guiding the indoor air to the outside, and the indoor air is sucked to one side of the main body 10. The indoor suction port 13 and the indoor discharge port 15 through which the outdoor air is discharged are provided. The other side of the main body 10 includes the outdoor suction port 14 through which the outdoor air is sucked and the outdoor air discharged to the outdoor. The outlet 16 is provided, and the outdoor inlet 14 and the indoor outlet 15 are connected by the suction passage 11 to suck the outdoor air into the room, and the indoor inlet 13 and the outdoor outlet 16 ) Is connected by the discharge passage 12 so that the indoor air can be discharged to the outside.

The suction passage 11 and the discharge passage 12 cross each other at an intermediate portion thereof so that the outdoor air sucked into the indoor space and the indoor air discharged to the outside can exchange with each other, and the suction passage 11 and the discharge passage 11 At the intersection where (12) intersects, an electrothermal exchange element (20) is arranged so that the air passing through the suction passage (11) and the air passing through the discharge passage (12) can exchange heat with each other without being mixed with each other. .

The total heat exchange element 20 is alternately stacked so that the flow path through which the air sucked into and the discharged air pass through are perpendicular to each other, such that the air passing through the suction flow path 11 and the discharge flow passage 12 are alternately stacked. The air passing through them can cross and exchange heat without mixing with each other.

The filter 30 is disposed on both suction surfaces of the total heat exchange element 20, and the filter 30 filters before the foreign matter such as dust contained in the air is introduced into the heat exchange element 20. To prevent foreign matters from accumulating on the inner flow path of the total heat exchange element 20.

The support partitions 40 are disposed at the centers of the internal slopes of the main body 10, respectively, and the support partitions 40 support the heat exchange element 20 and the filter 30, and at the same time the suction flow passage 11 and It serves to partition the discharge passage (12).

The intake fan 50 and the exhaust fan 60 are respectively installed at the outlets of the suction and discharge passages 11 and 12 so that air can flow smoothly along the suction passage 11 and the discharge passage 12. By generating wind power, according to the operation of the intake fan 50 and the exhaust fan 60, the outdoor air and the indoor air flow along the suction passage 11 and the discharge passage 12, respectively, and the ventilation is performed.

The air induction plates 70 and 80 are installed at the inlets of the suction passage 11 and the discharge passage 12, respectively, as shown in FIGS. 5 and 6, and the air sucked into the suction surfaces on both sides of the total heat exchange element 20. The air guide plate 70 and 80 are guided so as to be evenly distributed throughout, and the air induction plate 70 and 80 extend from the inlet of the suction channel 11 and the discharge channel 12 to the ends of both suction surfaces of the total heat exchange element 20 far from the inlet. Each is installed diagonally inclined so as to extend.

The present invention configured as described above is installed in the ceiling of a building to discharge indoor air to ventilate the building and ventilate the indoor air discharged by the outdoor air being sucked in the process of inhaling the outdoor air into the room to exchange heat with each other. It is the same as the conventional one to reduce the heat loss generated in the.

However, in the present invention, even when the length of both suction surfaces of the total heat exchange element 20 is long, the inlet passage 11 and the discharge passage 12 are provided through the indoor suction opening 13 and the outdoor suction opening 14. Since each sucked air is uniformly transmitted to both suction surfaces of the total heat exchange element 20 by the air induction plates 70 and 80, as shown in FIG. 6, structurally, both suction surfaces of the heat exchange element 20 Since the whole can be used, there is an advantage that can greatly improve the heat exchange efficiency of the total heat exchange element (20).

That is, in the present invention, the air sucked into the inlet of the suction passage 11 and the discharge passage 12, respectively, as shown in FIG. 6 is sucked in the flow passage 11 and the discharge passage 12 by the air guide plate 70, 80 The suction side 'C' and 'D' portions of both sides of the total heat exchange element 20 located far away from the inlet are also transferred to the wells, whereby they are evenly distributed on both sides of the heat exchange element 20. Since the heat exchange is made there is an advantage that can greatly improve the heat exchange efficiency of the total heat exchange element (20).

1 is a perspective view showing the appearance of a conventional total heat exchanger.

Figure 2 is a perspective view showing the inside of a conventional heat exchanger.

Figure 3 is a front sectional view of a conventional total heat exchanger.

Figure 4 is a plan sectional view of a conventional total heat exchanger.

5 is a perspective view showing the structure of the present invention.

Figure 6 is a plan sectional view showing the operation of the present invention.

<Code Description of Main Parts of Drawing>

10: main body 11: suction flow path

12: discharge passage 13: indoor suction

14: outdoor inlet 15: indoor outlet

16: outdoor outlet 20: total heat exchange element

30 filter 40 support partition

50: intake fan 60: exhaust fan

70,80: Air induction plate

Claims (1)

A main body 10 having suction and discharge passages 11 and 12, indoor and external suction ports 13 and 14, and indoor and external discharge ports 15 and 16, and a lozenge disposed inside the main body 10. On the suction surfaces of both sides of the heat exchange element 20 and the heat exchange element 20 that exchange heat between the outdoor air and the indoor air, respectively, in the center of the internal slope of the filter 30 and the main body 10 for filtering foreign substances. A support partition 40 arranged to support the electrothermal exchange element 20 and the filter 30 and partition the suction passage 11 and the discharge passage 12, and the outlet of the suction passage 11 and the discharge passage 12. In each of the intake fan 50 and the exhaust fan 60 is installed in the inlet, the air extending to the inlet of the suction passage 11 and the discharge passage 12 to the end of the suction surface of both sides of the heat exchange element 20 long Suction induction structure of the total heat exchanger, characterized in that the induction plate 70, 80 is installed diagonally inclined.

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