KR101155253B1 - Ventilation device - Google Patents

Abstract

The present invention relates to a heat-exchanging ventilator, and in particular, the upper separator and the lower separator to which a plurality of mats can be fitted respectively inside the wheel member are formed toward the center shaft boss to have a predetermined phase difference, and each upper separator The upper mat and the lower mat are mounted in the space between the lower and the lower separator, wherein the upper and lower mats constitute a heat exchange module formed by depositing silver nanoparticles on the upper end of the upper and lower mats. The outside air inlet and the outside air outlet are respectively formed at the upper and lower ends of the other side, and the vertical bulkhead is installed at the upper and lower sides, and the main body is provided with the horizontal bulkhead at the left and right sides, and the heat exchange module is vertically installed inside the cover member to form a multilayer structure. Heat exchanger / blowing means to block heat and exhaust between the inside and outside air while blocking the mixing of inside and outside air. By providing the heat exchange type ventilation device installed in the structure, the heat exchange module can be reduced in size by installing the heat exchange module in a multi-layer structure, and the heat transfer area increases as the heat exchange module forms a double structure of the upper mat and the lower mat. The heat exchange efficiency of the ventilation is increased, and thus it is related with the heat exchange type ventilation apparatus which prevents the rapid temperature change in the room during the ventilation operation.

 Heat exchanger, ventilator, heat exchanger module, mat, silver nanoparticles,

Description

Heat exchange ventilator {Ventilation device}

The present invention relates to a heat exchange type ventilator, and in particular, to provide a heat exchange module in which upper and lower mats on which silver nanoparticles are deposited on the inside of the wheel member are provided in multiple layers in order to increase heat exchange efficiency by increasing the contact area with air. In addition, by providing a ventilation device in which the heat exchange module is installed in a multi-layer structure inside the main body to significantly reduce the size compared to the existing ventilation device, as well as improving the heat exchange efficiency of the room heat loss during ventilation operation The present invention relates to a heat exchange ventilator that is hardly generated so that a sudden temperature change does not occur.

In general, the means for ventilating the interior of a building or a house is mainly to vent or direct air, such as a fan.

Ventilation means as described above are inefficient in terms of thermal efficiency by discharging the cold or hot air indoors in the summer or winter.

Recently, many heat exchange ventilators have been provided to compensate for these shortcomings. However, most of them are large in size, which leads to high space occupancy and difficult maintenance and repair. To do this, the building was inevitably renovated and there were many problems in place.

In addition, most of the heat transfer mat means used in the existing heat exchange ventilator is made of materials such as polyester, fiber, fabric, etc., although these materials satisfies the thermal characteristics to some extent, they are accompanied by the air flow in the form of particles during ventilation. Due to the mixture floating, there is a disadvantage that can adversely affect health in terms of purification of air, and to supplement this disadvantage, a metal screen, sealing means, etc. are additionally installed, but due to this the heat mat means and the surroundings Due to the complicated structure of the entire assembly including the members of the assembly, there are many problems in terms of management related to maintenance and repair.

Therefore, the present invention for solving the above problems can reduce the size of the overall ventilation device by installing the heat exchange module in a multi-layer structure, the heat transfer area is increased as the heat exchange module forms a double structure of the upper mat and the lower mat It is an object of the present invention to provide a heat exchange type ventilator that increases heat exchange efficiency during ventilation and thereby prevents a sudden temperature change in the room during the ventilation operation.

According to an aspect of the present invention,

Inner and outlet air is formed in the upper and lower ends of one side, and the outside air inlet and the outdoor air outlet are formed in the other upper and lower ends, respectively, and the vertical bulkheads are installed in the upper and lower sides, and the main body is provided with horizontal partition walls in the left and right sides.

The heat exchange module for exchanging the heat energy of the inside and the outside air is installed in the vertical direction inside the cover member to form a multi-layer structure, and inside the cover member so that the separating wall is interposed between the heat exchange modules so as to be interposed by the separating wall. The inner space of the cover member is divided into the inside air flow space and the outside air flow space to install a heat exchange / blower means in the center of the main body to allow the heat exchange between the inside and outside air while blocking the mixing of the inside and outside air,

The heat exchange module is formed radially toward the central axis boss with a predetermined phase difference between the upper separator and the lower separator, each of which can be fitted with a plurality of mats inside the wheel member, between each upper separator and the lower separator. The upper and lower mats are mounted in the space, and the upper and lower mats are formed by depositing silver nanoparticles on top thereof.
The bet flows into the bet outlet through a flow hole formed in one side of the cover member after the inlet flows into the bet flow space through the one side of the heat exchange module from the inlet inlet, is formed on the other side of the cover member from the outside air inlet After flowing into the outside air flow space through a flow hole, outside air flows through the other side of the heat exchange module to the outside air outlet, and heat energy in the air passing through one of the inside air flow space and the outside air flow space is exchanged. The module is characterized in that it is delivered to the air passing through the other one flow space.

According to the present invention, by installing the heat exchange module in a multi-layer structure it can reduce the size of the overall ventilation device, heat exchange module heat transfer by depositing silver nanoparticles on the upper and lower mats while forming a dual structure of the upper mat and the lower mat By increasing the area and increasing the heat exchange efficiency per unit area, the heat exchange efficiency is increased during ventilation, and thus, it is expected to provide an effect of providing a heat exchange type ventilator that prevents a sudden temperature change in the room during the ventilation operation.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, FIGS. 1 to 9.

First, Figures 1 to 4 show a heat exchange module applied to the present invention.

According to the drawing, the heat exchange module 20 is installed in a two-layer structure while radially installing the upper mat 30 and the lower mat 31 inside the wheel member 21.

A plurality of upper separators 22 are radially formed at an inner upper end of the wheel member 21, and a plurality of lower separators 23 are formed radially at an inner lower end of the wheel member 21. The separator 22 and the lower separator 23 are to have a predetermined phase difference.

Mats 30 and 31 are assembled between the upper and lower separators 22 and 23, respectively, and the mats 30 and 31 are porous materials through which air can pass, for example, sponges. , Made of a foam material that allows air to pass through, such as a mat, and deposited on the top of the mat (30) (31), as shown in FIG. To absorb heat efficiently.

In constructing the heat exchange module 20, the upper mat 30 and the lower mat 31 are installed in the wheel member 21 in a two-layered structure so that air may pass through the upper and lower mats 30 and 31. When the silver nanoparticles deposited on each of the mat (30) (31) absorbs heat in the air secondly, the heat exchange efficiency is increased, and between the upper mat 30 and the lower mat 31 The gap (G) of 1mm ~ 3mm was formed so that the heat conduction can be made independently in each of the upper and lower mats (30) (31).

In addition, since the thermal conductivity can be differentiated according to the deposition degree (density) of the silver nanoparticles deposited on the upper and lower mats 30 and 31, the deposition degree of the silver nanoparticles is differentiated according to the indoor space where the ventilation device is installed. Thus, it is possible to provide the mat 30, 31 having the appropriate thermal conductivity characteristics in accordance with the ventilation amount.

Meanwhile, a shaft boss 24 is formed at the center of the wheel member 21, a time gear 25 is formed at an upper end of the outer circumferential surface of the wheel member 21, and an engaging protrusion 26 is formed to protrude outward from the lower end. .

The ventilation device using the heat exchange module 20 configured as described above will be described with reference to FIGS. 5 to 9.

Ventilation device of the present invention is largely composed of a main body (1) and heat exchange / blowing means (100).

The main body 1 has a cover 2 that can be opened and closed, and an internal air outlet 4 and an internal air inlet 3 are formed at upper and lower ends of one side of the main body 1 when viewed in a plan view as shown in FIG. The outside air inlet 5 and the outside air outlet 6 are respectively formed at the upper and lower ends of the other side, and the vertical bulkhead 7 is installed at the upper and lower sides of the main body 1, and the horizontal bulkhead 8 is installed at the left and right sides.

The blower outlet 4 and the blower outlet 6 are provided with a blower 10 for forced circulation of the blower and the outside air, and the filter member 9 for filtering fine dust and foreign substances at the blower inlet side and the outside air inlet side. Is installed.

Assuming that the main body 1 is partitioned into a left space and a right space around the vertical bulkhead 7, the right space is used as a bet flow passage communicating with the inside inlet 3 and the inside outlet 4, The left space is used as an outside air flow passage communicating with the outside air inlet 5 and the outside air outlet 6.

On the other hand, the heat exchange module 20 described above is installed vertically in the cover member 40 to form a multi-layer structure, the configuration of the heat exchange / blower means for the heat exchange between the inside and the outside air while blocking the mixing of the inside and outside air To explain,

As shown in FIG. 8, the cover member 40 is separated into a first body 41 and a second body 42 which are coupled to each other to form a cover member 40 of one body, and the cover member ( The upper guide groove 43 and the lower guide groove 44 for guiding the heat exchange module 20 to rotate in a state where the heat exchange module 20 is inserted are formed at the upper and lower ends of the 40, and the upper guide groove 43 or the lower guide groove 44 ) Is formed in the withdrawal hole 45 in communication with the outside so that the time belt 48 fastened to the time gear 25 of the wheel member 21 of the heat exchange module 20 is drawn out through the withdrawal hole 45. It can be fastened to the drive gear 47 of the motor 46 which is installed on the outside of the cover member 40.

When the two heat exchange modules 20 are installed inside the cover member 40, the separation wall 60 is interposed between the heat exchange modules 20, and the heat exchange module is disposed at the center of the separation wall 60. The center shaft 61 for fitting into the axial boss 24 of (20) is provided so that it may protrude up and down.

Accordingly, the upper guide groove 43 of the cover member 40 in a state in which the two heat exchange modules 20 in which the central shaft 61 is fitted to the shaft boss 24 are spaced up and down by the separating wall 60. And it is installed to fit in the lower guide groove 44, although not shown to form a separate binding pin in the central shaft (61), and formed a pin groove for the binding pin is fitted into the shaft boss (24) Rotating only one of the heat exchange modules 20 allows the remaining heat exchange modules to rotate together.

The separation wall 60 is installed in the same direction as the vertical partition wall 7 so that the inner space of the cover member 40 is also used as the inside air flow passage and the left side as the outside air flow passage.

In addition, the cover 2 is formed by respectively forming a blocking cover 51 at upper and lower ends of the first body 41 (which may use a second body if necessary) of the two bodies forming the cover member 40. Is closed while the upper blocking cover 51 is in close contact with the cover 2, the lower blocking cover 51 is in close contact with the bottom of the main body 1 to be sealed, the first body 41 The first flow hole 49 and the second flow hole 50 are respectively formed at both sides of the middle portion of the center so that the outside air and the bet flow through the first and second flow holes 49 and 50.

As shown in FIGS. 5 to 7, the upper and lower brackets are respectively disposed on the upper and lower sides of the cover member 40 in a state where the first body 41 and the second body 42 are coupled to form a cover member 40. 62 and the lower bracket 63, the upper and lower ends of the central shaft 61 is inserted into the coupling hole formed in the center of the upper and lower brackets 62 and 63 to be squeezed, and the cover member ( 40, the side bracket 64 is screw-assembled in the up, down, left and right directions, respectively, and the cover member 40 is vertically partitioned 7 and the transverse bulkhead 8 using the side bracket 64. To combine.

In addition, as shown in FIG. 9, the sealing part 65 protrudes from the upper and lower guide grooves 43 and 44 of the cover member 40 so that the sealing part 65 is a wheel member. 21 is inserted between the time gear 25 and the engaging protrusion 26 to prevent the outflow of air, the sealing portion 65 is a material that can suppress the flow of air to the maximum while being flexible, such as yarn, fibers Use

Referring to the operation and effects of the present invention configured as described above are as follows.

When the ventilator 10 operates and the blower 10 and the motor 46 are driven, the bet introduced into the air inlet 3 by driving the blower 10 includes the cover member 40 constituting the heat exchange / blowing means 100. The outside air is discharged to the outside through the right air outlet (4) through the right space of the outside, and the outside air introduced into the outside air inlet (5) by the drive of the blower 10 passes through the left space of the cover member 40 to the outside air outlet It is fed into the room through (6).

At this time, as the time belt 48 hung on the drive gear 47 by the driving of the motor 46 rotates the wheel member 21 of the heat exchange module 20, the cover member of the heat exchange / blowing means 100. Two heat exchange modules 20 installed in the 40 will be rotated at a constant speed at the same time.

Here, the operation of the present invention will be described by taking an example of a state in which the air conditioner is operated indoors in the summer and the indoor air is cold and the outdoor air is hot.

First, when the indoor air (bet) is introduced into the main body 1 through the bet 3 and the filter member 9, the bet is covered by the cover member through the upper and lower spaces of the second body 42 of the cover member 40 40 flows into the inside, wherein the bet is penetrated to the upper and lower sides of the two heat exchange modules 20 and is discharged through the first flow hole 49 and discharged to the outside through the bet outlet 4, in this process The cold air (heat energy) is absorbed by the silver nanoparticles deposited on the upper and lower mats 30 and 31 constituting the heat exchange module 20, and the cold air absorbed by the silver nanoparticles is rotated to cover the heat exchange module 20. When it moves to the left space of the member 40, that is, the outdoor air flow space, it is delivered to the outside air in the process of heat-exchanging with the outside air supplied to the room, and is supplied back to the room.

Meanwhile, when outdoor air (outside air) passes through the outside air inlet 5 and the filter member 9 and flows into the left space of the main body 1, the outside air is middle part of the first body 41 of the cover member 40. After flowing into the left space of the cover member 40 through the second flow hole 50 provided in the upper and lower mat 30 of the heat exchange module 20 while flowing to the upper and lower sides of the cover member 40 Through the heat exchange with the silver nano-particles having cold air passes through the gap between the upper and lower parts of the second body 42 of the cover member 40 in a state where the temperature is lowered and is supplied to the room through the outside air outlet (6).

That is, the cold cold air (heat energy) of the indoor indoors with the outside air passing through the left space of the cover member 40 to be supplied from the outdoor to the indoor by the heat exchange module 20 of the heat exchange / blower means (100). The ventilation bet which is supplied back to the room again and lost the cold air is discharged to the outside through the internal air outlet (4), and the hot warmth (heat energy) of the outdoor air in the summer season is discharged from the indoor to the outdoor by the heat exchange module 20. Since it is discharged to the outside again with the bet passing through the right space of the cover member 40 to lose, even if the outdoor air is introduced into the room during the summer ventilation, the cold air of the indoor air discharged from the indoor to the outdoor from the indoor to the indoor It will be introduced into the room with the outdoor air introduced into the room will not cause a sudden change in the room temperature.

On the other hand, the heat exchange module 20 installed in the cover member 40 applied to the present invention can be used to install a multi-layer tower type, such as two layers, three layers, four layers, if necessary, the heat exchange module 20 Since it can be installed in the tower type it can significantly reduce the size of the ventilation system.

1 is an exploded perspective view showing a heat exchange module of the present invention.

2 is a plan view showing a heat exchange module of the present invention.

3 is a cross-sectional view showing a heat exchange module of the present invention.

4 is a view showing a mat applied to the heat exchange module of the present invention.

5 is an exploded perspective view of the heat exchanging ventilator of the present invention.

Figure 6 is a perspective view of a heat exchange ventilator of the present invention.

7 is a plan view showing a heat exchange ventilator of the present invention.

Figure 8 is an exploded view showing a cover member applied to the present invention.

9 is a sectional view showing a heat exchange ventilator of the present invention.

Explanation of symbols for main parts of the drawings

1: body, 2: cover,

3: bet entrance, 4: bet exit,

5: outside entrance, 6: outside exit,

7: longitudinal bulkheads, 8: transverse bulkheads,

9: filter element, 10: blower,

20: heat exchange module, 21: wheel member,

22: upper separator, 23: lower separator,

24: Jumbo Boss, 25: Time Gear,

26; Mating protrusions, 30, 31: mat,

40: cover member, 41, 42: body,

43,44: guide groove, 49,50: floating hole,

51: blocking cover, 60: dividing wall,

61: central axis, 62: upper bracket,

63: lower bracket, 64: side bracket,

65: sealing,

Claims (4)

The inside and outside ends of the inlet opening (4) and the inlet opening (3) is formed on one side, and the outside air inlet (5), the outside air outlet (6) is formed in the other upper and lower ends, respectively, and the vertical bulkhead (7) on the upper and lower sides are placed on the left and right sides The main body 1 in which the horizontal partition 8 is installed is provided, The heat exchange module 20 for exchanging heat energy of the inside and the outside air is installed in the vertical direction inside the cover member 40 so as to form a multi-layer structure, and is located between the heat exchange module 20 inside the cover member 40. The separation wall 60 is interposed so that the inner space of the cover member 40 is separated into the inside flow space and the outside air flow space by the separation wall 60 to block the mixing of the inside and the outside air while blocking the mixing of the inside and the outside air. The heat exchange / blowing means 100 to achieve this is installed in the center of the main body 1, The heat exchange module 20 has a central shaft boss 24 having a predetermined phase difference between the upper separator 22 and the lower separator 23 into which a plurality of mats can be fitted, respectively, inside the wheel member 21. The upper mat 30 and the lower mat 31 is mounted in a space between the upper separator 22 and the lower separator 23, and the upper and lower mats 30 and 31 are radially formed toward each other. It is composed by depositing silver nanoparticles on the top, It is introduced into the bet outlet 4 through the flow hole 49 formed in one side of the cover member 40 after flowing into the bet flow space through the one side of the heat exchange module 20 from the bet inlet (3) Is flowed into the outside air flow space through the flow hole 50 formed at the other side of the cover member 40 from the outside air inlet 5 and then the outside air outlet through the other side of the heat exchange module 20. Outside air flows to (6), and the heat energy of the air passing through any one of the inside air flow space and the outside air flow space is transferred to the air passing through the other flow space through the heat exchange module 20. Heat exchange ventilation system. delete delete The method of claim 1, Protrusions formed in the middle of the upper and lower guide grooves (43, 44) of the cover member 40 made of yarn or fiber, so that the seal 65 is the time of the wheel member 21 Heat exchange type ventilator characterized in that the leakage of air does not occur between the gear 25 and the engaging projection (26).

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