KR102617617B1 - High efficiency and light weight box type heat exchange moudle installed in heat energy recovery ventilation system - Google Patents

Abstract

The highly efficient ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention relates to a heat exchange module that is relatively light, exhibits high heat exchange efficiency, and is easy to maintain, considering that the heat exchange ventilation system is installed on the ceiling. It is made of thermosetting synthetic resin. It is made up of a triangular pillar shape with a horizontal cross-section having the shape of a right triangle, but the inclined surface is open and both sides forming a right angle alternate in the vertical direction to form a plurality of distribution holes through which air circulates, and the plurality of distribution holes A first module assembly and a first module assembly forming a plurality of distribution layers penetrating through each distribution hole and the open slope by forming a plurality of separation walls in the horizontal direction to spatially separate each distribution hole so that the air passing through does not mix. It is installed between the corresponding second module assembly and the inclined surfaces facing the first module assembly and the second module assembly, and is made of synthetic resin material and is perpendicular to a plurality of sealed and fixed layers that connect the separation walls to form spatially separated flow paths. It is characterized in that it includes a copper wire heat exchange unit made of a plurality of copper wires arranged in the direction and fixed by the sealing fixing layer, and is relatively light compared to the conventional heat exchange module, while exhibiting high heat exchange efficiency, and providing protection against air flow. It has the effect of exhibiting relatively high heat exchange efficiency while relatively reducing resistance, and is easy to clean and maintain.

Description

High-efficiency ultra-light box-type heat exchange module installed in a heat exchange ventilation system {HIGH EFFICIENCY AND LIGHT WEIGHT BOX TYPE HEAT EXCHANGE MOUDLE INSTALLED IN HEAT ENERGY RECOVERY VENTILATION SYSTEM}

The present invention relates to a heat exchange module (device) added to a heat exchange ventilation system that is installed in various buildings with indoor spaces, provides ventilation between indoor spaces and outdoor spaces, and recovers heat energy from the indoor space. In particular, the heat exchange ventilation system This relates to a heat exchange module that is relatively light considering that it is installed on the ceiling, yet exhibits high heat exchange efficiency and is easy to maintain.

Recently, as rapid urbanization and industrialization have progressed, industrial facilities and traffic have increased due to the expansion of the city's population and scope of economic activities, resulting in worsening air pollution.

Meanwhile, as urban centers develop and living standards rise, most people spend 80-90% of their time in indoor spaces such as offices, homes, and schools, and indoor air quality is an important factor in determining quality of life. It has become established as a standard, and in particular, as appropriate ventilation is required to maintain clean indoor air quality, ventilation systems installed in buildings are being legislated and made essential.

Furthermore, as contagious respiratory diseases caused by viruses such as COVID-19 have recently become widespread around the world, ventilation of the air in indoor spaces has become more and more important.

Meanwhile, the ventilation system installed in a building like this has the function of recovering heat energy when air circulates between indoor and outdoor spaces in order to save heating or cooling energy.

For example, if the outside temperature (temperature of the outdoor space) in summer is 35℃ and the indoor temperature (temperature of the indoor space) when the air conditioner is in operation is 20℃, a temperature difference of 15℃ occurs between the indoor space and the outdoor space. , In the case of ventilation performed without heat exchange due to this temperature difference, cold air from the indoor space is discharged to the outdoor space, and hot air from the outdoor space flows into the indoor space, resulting in a significant loss of heat energy due to cooling.

Due to the above problem of heat energy loss due to ventilation, a typical ventilation system uses a heat exchange medium made of a material with high thermal conductivity between the air from the indoor space being discharged and the air from the incoming outdoor space, and the air flowing in from the indoor space is It includes a heat exchange module that provides an environment in which heat exchange can occur without mixing the outflowing air.

Accordingly, the importance of heat exchange modules is increasing as a way to increase energy efficiency in ventilation systems where heat exchange is performed, and the weight and heat exchange efficiency of these heat exchange modules play an important role.

As a prior art for a ventilation system in which heat exchange is performed in this way, the invention titled 'Heat Exchange Ventilation System' under application number 10-2018-0070964 has been disclosed.

As shown in the representative diagram of the invention titled 'Heat Exchange Ventilation System' in Figure 1, Application No. 10-2018-0070964, the prior art includes a partition panel that divides a portion of the internal space of the case to form a recirculation passage, and the partition wall. It includes a recirculation damper provided on the panel to selectively communicate with the recirculation passage and the outdoor air supply space, and an internal filtering module consisting of a filter means for filtering indoor air flowing into the recirculation passage.

The partition panel is mounted in such a way that both ends are respectively inserted into opposing side walls of the case, and a ventilation hole is formed in the partition panel to allow the internal air discharge space within the case to communicate with the recirculation passage.

The filter means consists of a pre-filter and a main filter arranged in close contact with the pre-filter, and the main filter is a HEPA filter with a fine particle collection function or a combination filter with a fine particle collection function and a deodorization function. is used.

In more detail, an outside air intake port and an outside air discharge port are provided on the outdoor side, an inside air intake port and an outside air supply port are provided on the inside side, an outside air intake space communicating with the outside air intake port, and an outside air intake space communicating with the inside exhaust port. A case comprising an internal exhaust space, an internal suction space in communication with the internal suction port, and an external air supply space in communication with the external air supply port, a heat exchanger provided in the case, and suction of outdoor air into the case, A suction blower that supplies indoor air, an exhaust blower that sucks indoor air into the case and discharges it to the outdoor side, and is installed below the heat exchanger in the case so that the internal suction space and internal exhaust space communicate without passing through the heat exchanger. A bypass cover constituting a bypass passage, a bypass damper that selectively communicates the internal suction port and the bypass passage, and a bypass damper that is mounted in the case and divides a portion of the internal space of the case to form a recirculation passage. It includes a partition panel, a recirculation damper provided on the partition panel to selectively communicate with the recirculation passage and the outdoor air supply space, and an internal filtering module consisting of a filter means for filtering indoor air flowing into the recirculation passage. , Through this configuration, the prior art allows selective use of the general ventilation mode, bypass ventilation mode, and recirculation mode, and also improves convenience of use because the inconvenience of replacing the heat exchanger and filter unit when operating the recirculation mode can be avoided. There is an advantage to improving.

Meanwhile, the heat exchanger (heat exchange module) as also mentioned in the prior art is used to ensure that mutual heat exchange occurs while the air in the indoor space and the air in the outdoor space are distributed in separate spaces so that they do not mix, and is usually shown in Figure 2. As shown in the drawing showing the general form of the heat exchanger, it is shaped like a rectangular parallelepiped and flows only in the direction facing each other so that it flows in a perpendicular direction. It is made of a metal material with high thermal conductivity, so that the indoor air with a temperature difference Ensure heat exchange occurs without mixing with outdoor air.

Due to these structural characteristics, conventional heat exchangers (heat exchange modules) have a considerable volume, and in particular, as a large amount of metal materials with high thermal conductivity are used for heat exchange, there is a problem in that the weight of the heat exchanger itself becomes relatively heavy. .

For this reason, the weight and volume of the heat exchanger are very important factors in that the heat exchanger is installed in a heat exchange ventilation system that is installed in a manner that hangs from the interior space of the ceiling. In particular, the weight of the heat exchanger is an important factor in the heat exchange ventilation system. Therefore, a heat exchanger that is relatively lightweight and has high heat exchange efficiency is required for the installation and maintenance of heat exchange ventilation systems.

The box-type heat exchange module applied to the heat exchange ventilation system of the present invention was created to solve the problems of the prior art as described above, and its purpose is to provide a heat exchange module that is relatively light and provides high heat exchange efficiency.

In addition, the object of the box-type heat exchange module according to the present invention is to provide a heat exchange module that can efficiently recover heat energy while relatively reducing resistance to air flow.

In addition, the object of the box-type heat exchange module according to the present invention is to provide a heat exchange module that is easy to clean and maintain.

Other objects of the present invention can be understood through the features of the present invention, can be more clearly seen through embodiments of the present invention, and can be realized by the means and combinations indicated in the claims.

In order to achieve the problems that the present invention aims to solve as described above, the present invention has the following technical features.

The high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention is a high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system, is made of thermosetting synthetic resin, and has a triangular pillar shape with a horizontal cross-section in the shape of a right triangle, but the inclined surface is Both open and right-angled sides alternate in the vertical direction to form a plurality of distribution holes through which air flows, and a plurality of horizontal separation walls are horizontal to separate each distribution hole spatially so that the air passing through the plurality of distribution holes is not mixed. A first module assembly formed in one direction to form a plurality of distribution layers penetrating through each distribution hole and an open inclined surface; a second module assembly made of the same material and shape as the first module assembly, but having a distribution layer that provides a passage passing in the horizontal direction in connection with the distribution layer formed in the first module assembly; and a flow path that is installed between the opposing inclined surfaces of the triangular pillar-shaped first module assembly and the second module assembly, is made of a synthetic resin material, and is spatially separated by connecting the separation wall of the first module assembly and the second module assembly. It is characterized in that it includes; a copper wire heat exchanger made of a plurality of copper wires arranged in a vertical direction with a plurality of sealed fixed layers forming a and fixed by the sealed fixed layer.

In addition, in the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention, the first module assembly and the second module assembly are formed on the outside of the inclined surface and a support frame formed on the outside in the vertical direction of the vertical center axis of the inclined surface. It is characterized by further including ;.

In addition, in the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention, the support frame forms an insertion space into which the copper wire heat exchanger is inserted at a portion formed on the outside of the inclined surface, and the first module assembly and the first module assembly The two module assemblies are directly connected to each other to form an exterior with the copper wire heat exchanger embedded therein.

In addition, in the highly efficient ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention, the sealed fixing layer of the copper wire heat exchange part is formed to be relatively thicker than the dividing wall and has an insertion groove into which the exposed side of the dividing wall is inserted. It is characterized by;

The highly efficient ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention has the effect of providing high heat exchange efficiency while being relatively lighter than conventional heat exchange modules through the technical features described above.

In addition, the box-type heat exchange module according to the present invention has the effect of exhibiting relatively high heat exchange efficiency while relatively reducing resistance to air flow.

In addition, the box-type heat exchange module according to the present invention is easy to clean and maintain.

Furthermore, through the above effects, there is an effect of reducing heating and cooling costs by effectively recovering heat energy in ventilating indoor air in indoor spaces through a heat exchange ventilation system using the box-type heat exchange module according to the present invention, and cleaning costs. This easy-to-use box-type heat exchange module according to the present invention has the effect of easily maintaining the performance of the heat exchange ventilation system.

Other effects of the present invention can be understood through the characteristics of the present invention, can be more clearly seen through embodiments of the present invention, and can be achieved by means and combinations indicated in the claims.

Figure 1 is a representative drawing of the invention titled 'Heat Exchange Ventilation System' under Application No. 10-2018-0070964;
Figure 2 is a diagram showing the general form of a heat exchanger;
Figure 3 is a diagram illustrating the configuration according to an embodiment of a high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention;
Figure 4 is a view for explaining the first module assembly and the second module assembly of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention;
Figure 5 is a view for explaining the flow path by the first module assembly and the second module assembly of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention;
Figure 6 is a view for explaining the support frame added to the first module assembly and the second module assembly of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention;
Figure 7 is a view for explaining an embodiment of a support frame added to the first module assembly and the second module assembly of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention;
Figure 8 is a view for explaining the copper wire heat exchange part of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention;
Figure 9 is a view for explaining the sealed fixed layer of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention;
Figure 10 is a diagram for explaining the characteristics of the copper wire heat exchange part of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention.

The detailed description of the present invention described below refers to the accompanying drawings, which show by way of example specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different from one another but are not necessarily mutually exclusive. For example, specific shapes, structures and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention with respect to one embodiment. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the technical spirit and scope of the present invention. Accordingly, the detailed description set forth below is not intended to be taken in a limiting sense, and the scope of the present invention is limited only by the appended claims, together with all equivalents to those claimed. Similar reference numbers in the drawings refer to identical or similar functions across various aspects.

3 As shown in the drawing for explaining the configuration according to an embodiment of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention, the box-type heat exchange module 10 according to the present invention includes the first module assembly 110. and a second module assembly 120 and a copper wire heat exchange unit 130.

As shown in (a) of FIG. 3, the box-type heat exchange module 10 according to the present invention is made in a box shape, and the internal air and external air can be distributed in a separated state through four sides. It has a structure.

As shown in (b) of FIG. 3, the box-type heat exchange module 10 according to the present invention includes a first module assembly 110, a second module assembly 120, and a copper wire heat exchange unit 130. They are combined to form the appearance of the box-type heat exchange module 10 according to the present invention, as shown in FIG. 3.

The first module assembly 110 has the shape and structure as shown in FIG. 4, a drawing for explaining the first module assembly and the second module assembly of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention. , phenol resin, urea resin, melamine resin, silicon resin, polyester, polyurethane, etc., can be molded from thermosetting synthetic resin materials, and it is preferable that it is made of polyester material, which has excellent water resistance, heat resistance, and cold resistance and good dimensional stability. .

Specifically, as shown in FIG. 4, the first module assembly 110 is formed in the shape of a triangular pillar with a horizontal cross-section in the shape of a right triangle, but as shown in (a) of FIG. 4, the inclined surface is open. As shown in (b) of FIG. 4, both sides forming a right angle alternate in the vertical direction to form a plurality of distribution holes 111 through which air flows.

And, as shown in (a) of FIG. 4, a plurality of separation walls 112 are placed horizontally to separate each distribution hole 111 spatially so that the air passing through the plurality of distribution holes 111 does not mix. It is formed in this direction to form a plurality of distribution layers penetrating through each distribution hole 111 and the open slope.

That is, the first module assembly 110 in the shape of a triangular pillar forms each distribution layer by a plurality of distribution holes 111 formed on both sides and a separation wall 112 that divides the internal space into each distribution hole 111. And, the internal air and external air distributed through each distribution layer are distributed without mixing with each other.

Meanwhile, the second module assembly 120 as shown in FIG. 3 is made of the same material and shape as the first module assembly 110 as shown in FIG. 4, but the first module assembly 110 In connection with the distribution layer formed in , a distribution layer is formed through a distribution hole and a separation wall to provide a passage penetrating in the horizontal direction.

Therefore, the first module assembly 110 and the second module assembly 120 are shown in Figure 5 for explaining the flow path by the first module assembly and the second module assembly of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention. By being arranged and assembled as shown in (a) of the drawing, the distribution layer of the first module assembly 110 and the distribution layer of the second module assembly 120 are linked as shown in (b) of FIG. 4. A flow path is formed, and air is distributed through the flow path thus formed.

The first module assembly 110 and the second module assembly 120 as described above illustrate the support frame added to the first module assembly and the second module assembly of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention in Figure 6. As shown in the drawing, it further includes a support frame 140 formed on the outside of the inclined surface and in a direction perpendicular to the vertical center axis of the inclined surface.

This support frame 140 has the shape and structure as shown in FIG. 6, and includes a first module assembly 110 and a second module assembly (110) made of a relatively thin plate-shaped synthetic resin material to reduce the overall weight. It serves to increase the structural rigidity of the first module assembly 120 and to provide a part where the first module assembly 110 and the second module assembly 120 are coupled to each other when assembled.

Therefore, as shown in FIG. 6, the support frame 140 consists of a portion 141 formed on the outer side of the inclined surface and a portion 142 formed on the outer side in the vertical direction of the vertical center axis of the inclined surface. .

Meanwhile, such a support frame 140 is molded together during molding of the first module assembly 110 and the second module assembly 120, so that the support frame 140 is formed together with the first module assembly 110 and the second module. It is preferable to be formed integrally with the assembly 120.

In addition, in the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention, the support frame 140 is the first module assembly and the second module assembly of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention. As shown in (a) of the drawing for explaining an embodiment of the support frame added to the insertion space 143 where the copper wire heat exchanger 130 is inserted into the portion 141 formed on the outside of the inclined surface. is formed so that the copper wire heat exchange part 130 is inserted as shown in (b) of FIG. 7.

Therefore, the copper wire heat exchanger 130 is installed by inserting into the insertion space 143 formed in the support frame 140, and as shown in (c) of FIG. 7, the first module assembly 110 and When the second module assembly 120 is directly coupled to each other and assembled, the appearance of the box-type heat exchange module 10 according to the present invention is formed in a state in which the copper wire heat exchange part 130 is not exposed but is embedded.

The copper wire heat exchange unit 130 is made of copper with a thermal conductivity of 400 W/mk, as shown in Figure 8, a diagram for explaining the copper wire heat exchange unit of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention. A plurality of copper wires 131 made of metal in the form of thin wires are arranged and fixed in a vertical direction to the distribution layer of the first module assembly 110 and the second module assembly 120, and the thermal conductivity characteristics of copper Provides an environment in which heat exchange can occur between external air and internal air through the copper wire 131.

On the other hand, the larger the diameter of the copper wire 131, the smaller the amount of heat (ΔQ) conducted during a certain time (Δt), so the copper wire 131 is formed as thin as possible to increase the contact area with the circulating air and reduce the amount of heat stolen. It is desirable to increase it.

As shown in FIG. 3, the copper wire heat exchange unit 130 including a plurality of copper wires 131 is formed by facing the first module assembly 110 and the second module assembly 120 in the shape of a triangular pillar. The beam is installed between the inclined surfaces, and as shown in FIG. 8, it is made of synthetic resin material and connects the separation wall 112 of the first module assembly 110 and the second module assembly 120 to form a spatially separated flow path. It consists of a plurality of sealed fixing layers 132 and a plurality of copper wires 131 arranged in a vertical direction to the sealed fixing layer 132 and fixed by the sealing fixing layer 132.

The sealing fixing layer 132 is formed to be relatively thicker than the separation wall 112 and has a structure that can be sealed while interviewing each other, and can be sealed by attaching and fixing each other by adding an attachment means such as a sponge-type double-sided tape. You can.

Meanwhile, this sealed fixed layer 132 is made of a silicon-based soft synthetic resin material, as shown in Figure 9, a diagram for explaining the sealed fixed layer of the high-efficiency ultra-light box-type heat exchange module installed in the heat exchange ventilation system of the present invention, and is separated from the above. It is preferable to have an insertion groove 133 that is relatively thicker than the wall 112 and is inserted into the exposed side of the separation wall 112.

When the copper wire heat exchanger 130 is installed between the first module assembly 110 and the second module assembly 120 by fitting the separating wall 112 into the insertion groove 133 of the sealed fixing layer 132. It can be installed more easily, and in particular, the flow path formed by combining the first module assembly 110 and the second module assembly 120 is more completely sealed, thereby preventing air from mixing between internal air and external air.

The copper wire heat exchange unit 130 as described above is a first module assembly ( As the distribution layer formed by the 110) and the second module assembly 120 is arranged at a 45 degree angle, the contact area and time between the internal air and external air crossing each other at right angles are made the same for both the internal air and the external air. As shown in (b) of FIG. 10, heat conduction is conducted between the portion exposed to the internal air and the portion exposed to the external air through a plurality of copper wires 131 centered on each sealed fixing layer 132. Heat exchange occurs more efficiently.

Meanwhile, the box-type heat exchange module 10 according to the present invention as described above includes a first module assembly 110, a second module assembly 120, and a copper wire heat exchange unit 130, and each of the above components It has a structure and shape that is easy to assemble and disassemble, and is made of materials that can be washed with water, so the box-type heat exchange module (10) according to the present invention can be easily disassembled and cleaned, and subsequent assembly is also simple. Maintenance to maintain heat exchange efficiency is easy.

In the above, the present invention has been described based on preferred embodiments, but the technical idea of the present invention is not limited thereto, and modifications or modifications may be made within the scope set forth in the claims by those skilled in the art. It is clear to everyone that such modifications or changes fall within the scope of the appended patent claims.

10: Box-type heat exchange module according to the present invention
110: first module assembly
111: distribution center
112: separation wall
120: second module assembly
130: Copper wire heat exchange unit
131: copper wire
132: Sealed fixed layer
133: Insertion groove
140: support frame
141: Area formed on the outside of the slope
142: Area formed on the outside in the direction perpendicular to the vertical center axis of the slope

Claims (4)

In the highly efficient ultra-light box-type heat exchange module installed in the heat exchange ventilation system,
It is made of thermosetting synthetic resin and has a triangular pillar shape with a horizontal cross-section having the shape of a right triangle, but the inclined surface is open and both sides forming a right angle alternate in the vertical direction to form a plurality of distribution holes through which air circulates. A first module assembly forming a plurality of separation walls in the horizontal direction to separate each distribution hole spatially so that the air passing through the distribution hole is not mixed, thereby forming a plurality of distribution layers penetrating through each distribution hole and the open slope;
a second module assembly made of the same material and shape as the first module assembly, but having a distribution layer that provides a passage passing in the horizontal direction in connection with the distribution layer formed in the first module assembly; and
It is installed between the opposing inclined surfaces of the triangular pillar-shaped first module assembly and the second module assembly, is made of synthetic resin material, and connects the separation wall of the first module assembly and the second module assembly to form a spatially separated flow path. It includes a copper wire heat exchange unit made of a plurality of copper wires arranged in a vertical direction with a plurality of sealed fixed layers and fixed by the sealed fixed layers,
The sealed fixed layer of the copper wire heat exchanger is
A high-efficiency ultra-light box-type heat exchange module installed in a heat exchange ventilation system, characterized in that it is formed relatively thicker than the separation wall and has an insertion groove into which the exposed side of the separation wall is inserted. The method of claim 1, wherein the first module assembly and the second module assembly
A high-efficiency ultra-light box-type heat exchange module installed in a heat exchange ventilation system, further comprising: a support frame formed on the outside of the inclined surface and in the vertical direction of the vertical center axis of the inclined surface. The method of claim 2, wherein the support frame is
Forming an insertion space into which the copper wire heat exchanger is inserted at a portion formed on the outside of the inclined surface, and the first module assembly and the second module assembly are directly fastened to each other to form an appearance with the copper wire heat exchanger embedded therein. A highly efficient, ultra-light box-type heat exchange module installed in a heat exchange ventilation system characterized by ; delete