KR100651879B1 - Ventilating system - Google Patents

Abstract

A ventilation system is provided to modify paths in a heat exchange element to be in the shape of symmetrical diagonal lines for reducing loss of pressure and increase a volume of the heat exchange element without increasing a height thereof, thereby improving heat exchange efficiency. A ventilation system includes a heat exchanger(200) having at least two or more unit heat exchange elements(241) disposed in parallel and formed with air supply paths(220) and air exhaust paths(230) defined by path guide casings(242,243). The air supply paths and the air exhaust paths are formed in the diagonal line directions, which are symmetrical in the vertical direction in the heat exchanger.

Description

Ventilating system

1 is a perspective view schematically showing a heat exchanger configuration of a conventional ventilation system.

Figure 2 is a perspective view schematically showing the configuration of a heat exchanger of the ventilation system according to an embodiment of the present invention.

Figure 3 is a perspective view showing a flow path inside the heat exchange element of the ventilation system according to an embodiment of the present invention.

Figure 4 is a perspective view schematically showing the configuration of a heat exchanger of the ventilation system according to another embodiment of the present invention.

* Explanation of symbols for main parts of drawings *

100: heat exchanger 110: heat exchanger case

120: air supply passage 121: air supply inlet

122: air supply outlet 125: air supply fan scroll

130: exhaust passage 131: exhaust inlet

132 exhaust exhaust port 135 exhaust fan scroll

140: heat exchange element 141: unit heat exchange element
145: Bypass Euro 146: Guidelines
210: heat exchanger case 220: air supply passage
221: air supply inlet 222: air supply outlet
225: supply fan scroll 230: exhaust flow path
231: exhaust inlet 232: exhaust outlet
235: exhaust fan scroll 240: heat exchange element
241: unit heat exchange element 245: bypass flow path
246: guidelines

The present invention relates to a ventilation system including a heat exchanger, and more particularly, to a ventilation system having improved heat exchange efficiency in a heat exchanger.

The present invention relates to a ventilation system, and more particularly to an improved structure of the ventilation system.

The air in an enclosed space increases the carbon dioxide content over time due to the breathing of living things, which interferes with the breathing of living things. Therefore, if many people stay in a narrow space such as an office or a vehicle, it is necessary to frequently replace the indoor air with fresh air. At this time, a commonly used ventilation system.

Most conventional ventilation systems employ a method of forcibly discharging only indoor air to the outside using a single blower. However, when forcibly discharging only the indoor air by using one blower, the indoor air is discharged to the outside without filtration and the outdoor air is introduced without the heat exchange through the door or window gap, and the room is heated. And the cost of cooling has become unnecessarily high.

In addition, the sudden cold air and heat flows from the outside to the inside of the indoor air due to the rapid change in the temperature of the people who are feeling uncomfortable, especially when the indoor window or door frame is closed to discharge only the indoor air to the outside In this case, the inflow of fresh air is blocked and oxygen deficiency can occur, as well as the humidity control of the indoor air is not achieved at all, and it is not possible to maintain a comfortable indoor environment despite the ventilation system. There was this.

In order to solve this problem, a heat exchange type ventilation system in which outdoor air is first heat-exchanged with indoor air discharged to the outside and then supplied to a room has been proposed. Such a conventional ventilation system will be described with reference to FIG. 1.

In general, the heat exchange ventilation system includes a box-type heat exchanger 1 and an air supply unit and an exhaust unit communicating outdoor and indoor.

The heat exchanger 1 is generally formed in a box shape, and is provided with an air supply fan 15, an exhaust fan 25, and a heat transfer element 5 therein.

The heat exchanger 1 forms a part of the air supply part and the exhaust part flow path. First, the air supply flow path is formed as an air supply outlet 13 through the inside of the heat exchanger at the air supply inlet 11, and the exhaust flow path The exhaust inlet 21 is formed as an exhaust outlet 23 through the inside of the heat exchanger.

That is, an indoor exhaust duct, one end of which communicates with the room and the other end of which is connected to the exhaust inlet 21 of the heat exchanger, the inside of the heat exchanger, and one end of the heat exchanger Connected to the exhaust outlet 23 of the group and the other end is made in the order of the outdoor exhaust duct communicating with the outdoor.

In addition, the flow path of the air supply unit for supplying the outdoor fresh air to the indoor one end is in communication with the outdoor and the other end of the outdoor air supply duct connected to the air supply inlet 11 of the heat exchanger, inside the heat exchanger, one end the heat exchange Connected to the air supply outlet 13 of the air and the other end is made in the order of the indoor air supply duct in communication with the room.

On the other hand, the outdoor air is supplied to the indoor air through the air supply unit because the air supply fan 15 is operated to generate a suction force to suck the outdoor air, the exhaust air to the indoor air is exhausted through the exhaust unit This is because the fan 25 operates to generate a suction force for sucking air in the room.

Here, a heat exchange method between indoor air and outdoor air introduced into the heat exchanger will be described.

First, the contaminated air in the room flows into the lower portion of one side of the heat transfer element 5 from the inside of the heat exchanger 1, and flows out of the upper portion of the heat exchanger 1 to exit the heat exchanger. At the same time, the outdoor air flows into the lower part of the heat exchange element 5 from the inside of the heat exchanger 1 and flows out of the upper part of the heat exchanger 5 to exit the heat exchanger.

That is, inside the heating element, the passages of the indoor air and the outdoor air are formed to cross each other, and heat exchange occurs between the indoor air and the outdoor air through sidewalls of the respective passages.

Here, the heat exchange element in which only the heat exchange between the indoor air and the outdoor air is caused by heat exchange due to the temperature difference is called a sensible heat exchange element, and heat exchange is performed by the difference in humidity between the heat transfer, that is, the temperature difference between the indoor air and the outdoor air. The heat exchange element formed is called a total heat exchange element.

Recently, in order to further increase the heat exchange efficiency between the indoor air and the outdoor air, a total heat exchange element is used.

However, in the above-described conventional ventilation system, in order to increase the heat exchange efficiency through the heat exchanger, the size of the heat exchange element must be increased, thereby causing a problem that the height of the heat exchanger is increased.

On the other hand, in the ventilation system operated at a relatively high wind volume, the flow rate of the air flowing into the heat exchange element is very fast, the heat exchange efficiency through the heat exchange element is inevitably lower as the flow rate is faster.

Therefore, in order to increase the heat exchange efficiency, the volume of the heat exchange element is inevitably increased. However, in general, the heat exchanger is installed on the ceiling of the room, and in order to increase the volume of the heat exchanger element, the height of the heat exchanger is increased, and in order to compensate for this, a problem arises in that the height between each floor is further increased. .

Therefore, since the height of the heat exchanger preferably does not exceed a certain height, there is a demand for a heat exchanger having improved heat exchange efficiency without increasing the height of the heat exchanger.

In addition, in the conventional heat exchanger, the heat exchange element used in the heat exchanger is changed according to the size of the heat exchanger, thereby increasing the cost of constructing the ventilation system.

The present invention is to solve the above problems, an object of the present invention is to provide a ventilation system having a high heat exchange efficiency while maintaining a constant height of the heat exchanger.

In order to achieve the above object, the present invention is a heat exchanger having a heat exchange element capable of heat exchange between the outdoor air to be supplied and the indoor air to be exhausted, one end is installed in the outdoor side is in communication with the inside of the heat exchanger The other end is installed at the indoor side and communicates with the inside of the heat exchanger so that outdoor air is supplied to the interior, and one end is installed at the indoor side and communicates with the inside of the heat exchanger, and the other end is installed at the outdoor side. A ventilation system comprising an exhaust passage communicating with an interior of the heat exchanger to exhaust indoor air to the outside, wherein the air supply passage and the exhaust passage are formed in a diagonal direction of the heat exchanger. Provided is a ventilation system, characterized in that at least two unit heat exchange elements are arranged in parallel.

Here, an air supply fan scroll for supplying outdoor air to the indoor air on the air supply passage, an air supply fan scroll having a motor for driving the air supply fan, an exhaust fan for supplying indoor air to the outdoor air on the exhaust flow path, and a motor for driving the exhaust fan. Exhaust fan scroll is installed is preferably provided in the heat exchanger, it is preferable that both the supply fan scroll and the exhaust fan scroll is provided on one side of the heat exchanger.

 The air supply passage and the exhaust passage are symmetrical up, down, left, and right in the heat exchanger, and the air supply passage and the exhaust passage are partitioned through guidelines in the heat exchanger.

On the other hand, the heat exchanger further comprises a bypass damper which can selectively block the bypass flow path and the bypass flow path that is supplied to the indoor air without passing through the heat exchange element for general ventilation without heat exchange. desirable.

In addition, each of the air supply fan and the exhaust fan may be composed of a positive suction fan, the heat exchange element may be a total heat exchange element to further increase the heat exchange efficiency and may be provided as a hexagonal parallel flow heat exchange element.

The unit heat exchange element is to reduce the flow resistance of the air, the air passing through the inside of the unit heat exchange element is introduced in a diagonal direction with respect to the center of the unit heat exchange element, so as to flow out in an oblique direction to the center of the unit heat exchange element It is preferable.

Here, a guide casing may be provided at one side of each of the air inflow surface and the air outflow surface of the unit heat exchange element for oblique inflow and oblique outflow of air to the unit heat exchange element. Also in this case, it is preferable that the air supply passage and the exhaust passage be partitioned through the guideline in the heat exchanger and are symmetrical in the inside of the heat exchanger.

Hereinafter, with reference to the accompanying drawings, it will be described in detail a preferred embodiment according to the present invention, and the detailed description will be omitted for the content overlapping with the prior art.

Figure 2 is a perspective view schematically showing the configuration of a heat exchanger of the ventilation system according to an embodiment of the present invention.

As shown in FIG. 2, the ventilation system according to the exemplary embodiment includes a heat exchanger 100, an air supply passage 120, and an exhaust passage 130.

Here, the heat exchanger 100 is provided with a heat exchange element 140 that can be heat exchanged between the outdoor air to be supplied and the indoor air to be exhausted, the heat exchange element is at least two or more unit heat exchange elements 141 In parallel, in FIG. 2, five unit heat exchange elements 141 are connected in parallel.

The unit heat exchange element 141 may be a sensible heat exchange element that performs heat exchange only by the temperature difference between the outdoor air and the indoor air, but in order to further increase the heat exchange efficiency, the unit heat exchange element 141 is a total heat exchange element that performs heat exchange due to a humidity difference as well as a temperature difference. It would be desirable.

One end of the air supply passage 120 is installed at the outdoor side to communicate with the inside of the heat exchanger, and the other end is installed at the indoor side to communicate with the inside of the heat exchanger 100 so that the outdoor air is supplied to the indoor air. Will form a flow path.

That is, the air supply passage 120 is made of a duct pipe (not shown) to form a flow path of air between the outdoor and indoor, the heat exchanger may be provided between the duct pipe.

Similarly, one end of the exhaust flow path 130 is installed on the indoor side and communicates with the inside of the heat exchanger, and the other end is installed on the outdoor side and communicates with the inside of the heat exchanger so that the indoor air is exhausted to the outside. The flow path is formed.

In the heat exchanger, a part of the air supply passage 120 or the exhaust passage 130 is formed, each of which is formed in a diagonal direction.

First, as shown in the exhaust flow path (indicated by the dotted arrow) inside the heat exchanger, indoor air is introduced into the heat exchanger through an exhaust inlet 131, and the heat exchange element at one side of the heat exchanger lower side. After entering and passing through the 140, it is formed to flow out through the exhaust outlet 132 on the other side of the upper side of the heat exchanger.

On the contrary, in the air supply passage (indicated by the solid arrow) inside the heat exchanger, outdoor air is introduced into the heat exchanger through the air supply inlet 121, and the heat exchange element 140 is disposed at an upper side of the heat exchanger. After passing through and passed through, the other side of the heat exchanger is formed to be introduced into the room through the air supply outlet 122.

Thus, the air supply passage and the exhaust passage inside the heat exchanger are formed in a diagonal direction of the heat exchanger 100, thereby reducing the flow resistance of air than the heat exchanger shown in FIG.

On the other hand, inside the heat exchanger 100, two chambers are formed on both sides of the heat exchanger 140, respectively, above and below the case 110 of the heat exchanger, and the upper and lower chambers are guide lines 146, respectively. It is preferable to be divided into a), and in this way the air supply passage 120 and the exhaust passage 130 formed in the heat exchanger 100 consisting of one case 110 in a symmetrical form up and down each other Will be constructed.

Also, an air supply fan scroll 125 having an air supply fan for supplying outdoor air to the indoor air on the air supply flow passage, a motor for driving the air supply fan, an exhaust fan for supplying indoor air to the outdoor air on the exhaust flow path, and an exhaust fan are provided. Exhaust fan scroll 135 in which a driving motor is installed is preferably provided in the heat exchanger 100, which enables the configuration of a compact heat exchanger 100, which facilitates the installation of the entire ventilation system. There is this.

The air supply fan scroll and the exhaust fan scroll are both provided at one side of the heat exchanger. This is to ensure that the above-described exhaust flow path and the air supply flow path are formed in a diagonal direction, and at the same time, the flow rate is evenly distributed to each of the unit heat exchange elements 141 connected in parallel by sucking the air without pushing the air in order to generate the air flow. To make it possible.

In addition, the air supply fan and the exhaust fan is preferably a suction fan. This is because, as shown in FIG. 2, air is introduced into and discharged from both sides of each of the fans to form a smoother flow path, thereby reducing pressure loss.

Reference numeral 145 is a bypass flow path, a description thereof will be described in another embodiment according to the present invention to be described later.

Hereinafter, the heat exchange element 140 will be described in detail.

As illustrated in FIG. 2, at least two unit heat exchange elements 141 of the heat exchanger 140 of the heat exchanger are connected in parallel.

Meanwhile, although a unit heat exchange element 141 having a hexagonal shape is shown in FIG. 2, it may be possible to configure a heat exchange element having a cross-flow shape in which a flow path therein crosses a conventional quadrangular shape as a unit heat exchange element.

However, in order to further increase the heat exchange efficiency, it may be preferable that the internal air flow path is formed of a hexagonal unit heat exchange element 141 having a parallel flow form.

Here, the parallel flow type is the same as the counter flow type of the conventional hexagonal heat exchange element, but the conventional counter flow type flow paths are parallel to each other, but the air flow direction is different, but the parallel flow type is the air flow direction is Say the same thing to each other.

3 is a view schematically illustrating a flow path inside the unit heat exchange element 141 and illustrates a form in which the unit heat exchange element 141 shown in FIG. 2 is laid down for convenience of description.

As illustrated in FIG. 3, the unit heat exchange element 141 is stacked with the flow path layer 148 through which indoor air is introduced and exhausted to the outside and the flow path layer 149 through which outdoor air is introduced and exhausted into the interior. Here, a heat exchange film (not shown) is provided between the flow path layers to thereby exchange heat between the two layers.

Here, the rear right surface of the unit heat exchange element illustrated in FIG. 3 is an inflow surface through which indoor air is introduced, and the front left surface is an outflow surface through which the heat exchanged indoor air is exhausted. Similarly, the front right side is the inflow surface to which the outdoor air is introduced, and the rear left side is the outflow surface to which the outdoor air is supplied.

In the heat exchange system in the unit heat exchange element 141, heat exchange is performed in a cross flow form immediately after the air is introduced into the unit heat exchange element and immediately before the air is discharged, similarly to a general rectangular heat exchange element. In the part, the flow paths are formed side by side to perform heat exchange in the form of parallel flow.

Here, it is known that the heat exchange rate is higher in counterflow (parallel flow in the present invention) than in the crossflow mode.

On the other hand, through the parallel connection of the unit heat exchange elements 141 to increase the number of unit heat exchange elements required to increase the volume of the heat exchange element required in the high-air ventilation system, the heat exchange efficiency can be increased, the unit heat exchange element 141 It will be preferable to be provided to be removable in the longitudinal direction of the heat exchanger.

That is, when the unit heat exchange element is used, even when the capacity of the ventilation system is changed, the number of heat exchange elements that are simply connected may be adjusted to appropriately respond without changing the heat exchanger or the entire heat exchange element.

Hereinafter, another embodiment according to the present invention will be described in detail with reference to FIG. 4, and a description overlapping with the above embodiment will be omitted.

Figure 4 is a perspective view schematically showing the configuration of a heat exchanger of the ventilation system according to another embodiment of the present invention.

In another embodiment of the present invention, the same unit heat exchange element as the above-described embodiment is provided, but a predetermined guide casing is further provided on the air inlet and outlet surfaces of the unit heat exchange element. All other configurations are the same.

That is, since the air supply passage and the exhaust passage formed in the heat exchanger 200 are the same as in the above-described embodiment, only the unit heat exchange element 241 will be described herein.

As shown in FIG. 4, the outdoor air introduced into the heat exchanger 200 through the air supply inlet 221 is further provided with flow path guide casings 242 and 243 at the upper portion of each unit heat exchange element 241. .

That is, the outdoor air introduced as shown is not introduced into the vertical form toward the inner center of each unit heat exchange element, but is inclined in the air inlet surface of the unit heat exchange element by the flow path guide casing. . In other words, the left portion 243 of the flow path guide casing forms a channel through which air enters the air inflow surface of the unit heat exchange element.

Here, the flow path of air introduced into the unit heat exchange element is narrowly formed by the left portion 243 of the flow path guide casing, and thus the pressure loss is further reduced because the flow path is smoothly formed.

On the other hand, the outdoor air introduced in the diagonal form is heat exchanged in the heat exchange element and then flows out through the flow path guide casings 242 and 243 formed under each of the unit heat exchange elements 241.

Similarly, in this case, the outdoor air flows out in an oblique form from the air outlet surface of the unit heat exchange element by the right portion 243 of the flow path guide casing.

In summary, flow path guide casings 242 and 243 are formed on the air inflow surface and the air outflow surface of the unit heat exchange element so that an air flow path is formed in an oblique direction rather than perpendicular to the inflow surface and the outflow surface. This is to be provided.

On the other hand, the indoor air introduced through the exhaust inlet 221 flows in a diagonal form in a lower left direction of the heat exchange element and flows out in a diagonal form in an upper right direction of the heat exchange element.

As described above, when the flow path of the unit heat exchange element is formed in a diagonal shape up, down, left, and right, the shape of the flow path flowing in and out of each unit heat exchange element is smoothly formed. The flow path has an S shape.

Therefore, there is an effect that can further reduce the pressure loss through the configuration of such a heat exchange element.

On the other hand, the heat exchanger 200 of the ventilation system according to the present invention is a bypass damper (not shown) capable of selectively blocking the bypass flow path 145 and the bypass flow path supplied to the room without passing through the heat exchange element. It is preferable that further comprises.

That is, when the temperature of the outdoor air and the temperature of the indoor air are about the same as in spring or autumn, it is not necessary to exhaust power through the heat exchange element. In this case, the bypass passage 145 directly connected to the exhaust fan scroll 135 is opened without passing the indoor air exhausted to the outside through the heat exchange element 140. The selective opening of the bypass flow path may be made through a bypass damper (not shown).

On the contrary, the bypass flow passage and the bypass damper may be provided on the flow passage to be supplied indoors, or both may be provided.

On the other hand, the heat exchanger of the ventilation system according to the present invention is further provided with a filter (not shown) that can filter foreign matter in the air immediately before the air is introduced into the heat exchange element, to perform the air cleaning function in addition to the ventilation system capable of heat exchange. It may be possible to perform the function of the ventilation system.

The present invention is not limited to the above-described embodiments, and those skilled in the art can make modifications without departing from the spirit of the present invention, and such modifications are within the scope of the present invention.

The ventilation system according to the present invention described above has the following effects.

First, there is an effect of providing a ventilation system with less pressure loss by improving the flow path inside the heat exchanger, in particular, the flow path inside the heat exchange element in up, down, left and right diagonal forms.

Second, there is an effect of providing a ventilation system having a high heat exchange efficiency by increasing the volume of the heat exchange element without increasing the height of the heat exchanger.

Third, since the heat exchange element is configured by the connection of the unit heat exchange element, there is an effect that it can appropriately respond to the change in the capacity of the ventilation system.

Fourth, the flow path of the air flowing into and out of the unit heat exchange element is improved more smoothly through the flow path guide casing, thereby providing a ventilation system with less pressure loss.

Claims (12)

A heat exchanger having a heat exchange element capable of performing heat exchange between the supplied outdoor air and the exhausted indoor air; An air supply passage having one end installed at an outdoor side to communicate with the inside of the heat exchanger, and the other end installed at an indoor side to communicate with the inside of the heat exchanger; In the ventilation system comprising one end is installed on the indoor side and communicating with the interior of the heat exchanger, the other end is installed on the outdoor side and communicating with the interior of the heat exchanger to exhaust the indoor air to the outside, The air supply passage and the exhaust passage is formed in a diagonal direction of the heat exchanger, the heat exchange element is a ventilation system, characterized in that at least two or more unit heat exchange elements are arranged in parallel. The method of claim 1, An air supply fan scroll having an air supply fan for supplying outdoor air to the indoor air on the air supply flow path and a motor for driving the air supply fan, an exhaust fan for supplying indoor air to the outdoor air on the exhaust flow path, and a motor for driving the exhaust fan An exhaust fan scroll is provided in the heat exchanger. The method of claim 2, Both the air supply fan scroll and the exhaust fan scroll are provided on one side of the heat exchanger. The method of claim 3, wherein And the air supply passage and the exhaust passage are symmetric up, down, left and right in the heat exchanger. The method of claim 4, wherein And the air supply passage and the exhaust passage are partitioned through a guideline in the heat exchanger. The method of claim 5, The heat exchanger includes a bypass flow path through which outdoor air is supplied to the room without passing through the heat exchange element.  Ventilation system, characterized in that further comprises a bypass damper for selectively blocking the bypass flow path. The method of claim 2, The air supply fan and the exhaust fan is a ventilation system, characterized in that each of the suction fan. The method of claim 1, The unit heat exchange element is a ventilation system, characterized in that the total heat exchange element. The method of claim 8, The unit heat exchange element is a ventilation system, characterized in that the hexagonal parallel flow type heat exchange element. The method of claim 8, The air passing through the unit heat exchange element is introduced in an oblique direction with respect to the center of the unit heat exchange element, the ventilation system characterized in that flows out in an oblique direction with respect to the center of the heat exchange element. The method of claim 10, And a flow path guide casing is provided on each of the air inflow surface and the air outflow surface of the unit heat exchange element for oblique inflow and oblique outflow of air to the unit heat exchange element. The method of claim 10, And the air supply passage and the exhaust passage are partitioned through a guideline in the heat exchanger and symmetrically up, down, left, and right in the heat exchanger.

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