KR20130009079A - Ventilation system - Google Patents

Abstract

PURPOSE: A ventilation system is provided to reduce loads on a heat exchanger, and to increase the service life of the heat exchanger with rapidly discharging internal air. CONSTITUTION: A ventilation system comprises an outer case(111), a heat exchanger(142), an intake fan, an exhaust fan(150), a first electric damper(130a), a bypass member(122), a first bottom plate, a second bottom plate, a second electric damper(130b), and a control box(170). The first bottom plate covers the bottom of the outer case. The second bottom plate is separated from the first bottom plate at a constant interval, and installed at the outer case. The second bottom plate forms a second bypass path connected to a first bypass path. The second electric damper is installed on the second bottom plate. The control box installed at the outer case controls the first and second electric dampers to direct air to the heat exchanger or the first and second bypass paths. [Reference numerals] (AA) Indoor; (BB) Outdoor

Description

Ventilation system {VENTILATION SYSTEM}

TECHNICAL FIELD The present invention relates to a ventilation system, and more particularly, to an improved ventilation system in order to make the structure of the ventilation system very simple, and to enable economical and efficient operation.

Recently, the adoption of a ventilation system equipped with a heat exchanger that saves energy by recovering heat from indoor air discharged to the outside when exhausting indoor air and supplying outdoor air to the room has been expanded.

In addition, the heat exchanger allows the supply and exhaust of the temperature difference to pass through different flow paths with the heat exchanger interposed therebetween, thereby allowing heat exchange to occur through the heat exchanger.

Such a heat exchanger is a known technique, and a ventilation system equipped with a heat exchanger in which air mixing on the air supply and exhaust is eliminated as heat exchange between the air supply and the exhaust is performed is also a common technology.

1A shows a plan view of a conventional ventilation system as described above, FIG. 1B shows a side view of FIG. 1A, and FIG. 1C shows a front view of FIG. 1A.

Referring to each of these figures, a conventional heat exchanger (10) is equipped with a heat exchanger (15) in the center of the outer case (11) to form an exterior, and on the left and right sides of the heat exchanger (15) outdoors. An air supply fan 19 for forcibly sucking outdoor air (OA), which is air introduced into the heat exchanger (15), and ventilation (RA), which is air introduced into the heat exchanger (15) indoors; Exhaust fans 16 for forcibly discharging the Return Air are provided respectively.

By the operation of the air supply fan 19, the outside air OA is sucked into the outside case 11 through the outside air inlet 18 formed at one side of the outside case 11, and the outside air OA thus sucked is After the heat exchange is made through the heat exchanger 15, supply air (SA) is introduced through the air supply air inlet 21 formed on one side of the outer case 11 opposite to the outside air inlet 18 in a diagonal direction. Will be.

And a cylindrical type electric damper (Motor Damper) for discharging the indoor air to the outside on the same side of the outer case 11 to one side of the outside air supply port 21, to control (or adjust) the amount of air sucked ( 12) is installed.

The electric damper 12 has a cylindrical body portion 12a, a damper 12b for adjusting the opening / closing degree of the body portion 12a, and an actuator (not shown) for rotating the damper 12b. It consists of. At this time, it is a matter of course that the ventilation inlet 12c is formed in the outer case 11 at the end of the inner passage of the body portion 12a so that the ventilation RA is introduced into the heat exchanger 15.

In addition, the exhaust fan 16 is operated to discharge the indoor air to the outside, and the electric damper 12 is operated together with the ventilation RA through the heat exchanger 15 through the ventilation inlet 12c. Heat exchange is performed, and exhaust air (EA) is discharged to the outside through the ventilation outlet 17 formed at one side of the outside air inlet 18.

In addition, the foreign air OA and the ventilation RA, which may be contaminated among the four sides of the heat exchanger 15, are mixed in the foreign air OA and the ventilation RA before passing through the heat exchanger 15, respectively. For example, an air filter 13, such as a HEPA (High Efficiency Particulate Air) filter, is installed, and the filter 13 is installed to be replaced separately from the heat exchanger 15. do.

In addition, the blocking plate 23 is installed so that the flow paths A, B, C, and D are partitioned so that the respective air OA, SA, EA, EA are not mixed with each other based on the heat exchanger 15.

As described above, the outer case 11 is provided with a control box 24 for controlling the ventilation system 10 to be operated. The control box 24 controls the operation of the ventilation system 10. Various components are mounted.

Meanwhile, in FIGS. 1A to 1C, reference numeral 22 denotes a bracket on which the ventilation system 10 may be mounted, and reference numeral 25 denotes a cover (not shown) covering the upper portion of the outer case 11. It is a hinge device fixed to.

However, the conventional ventilation system 10 configured as described above has the following problems.

First, the size of the diameter of the body portion 12a of the electric damper 12 and the degree of opening / closing of the damper 12b are varied according to the air circulation treatment capacity, in particular, the capacity of discharging indoor ventilation RA to the outside. Ventilation (RA) must be inhaled.

In this way, the diameter of the body portion 12a should be changed according to the ventilation capacity. That is, the specification of the electric damper 12 must be changed.

When the electric damper 12 is excessively largely changed, it may be difficult to install the ventilation system 10 due to insufficient installation space of the ventilation system 10, and the size of the diameter of the electric damper 12 is changed. The problem arises that the specification of the ventilation system 10 as well as the structure of the outer case 11 should be changed.

In particular, the existing ventilation system 10 is inefficient and inefficient because the ventilation RA must always pass through the heat exchanger 15. That is, even when only a simple ventilation function for simply discharging the ventilation 10b to the outside is required, the life of the heat exchanger 15 is not only shortened because the ventilation RA must pass through the heat exchanger 15 at all times. The rate of air circulation in the heat exchanger 15 is reduced, which may eventually overload the ventilation system 10.

The present invention was created in order to solve the above problems, it is possible to change the installation structure, as well as the electric damper structure, and to change the discharge path of the ventilation to economical and efficient operation, and to improve the ventilation system compatibility The aim is to provide a ventilation system.

Ventilation system of the present invention for achieving the above object, the outer case; A heat exchanger installed at a center inside the outer case to allow heat exchange with outdoor air and indoor ventilation; An air supply fan installed in the outer case to one side of the heat exchanger to force the outside air into the room; An exhaust fan installed in the outer case to the other side of the heat exchanger and forcibly discharging the ventilation to the outside; A first electric damper installed inside the ventilation suction port formed on one side of the outer case to discharge the ventilation to the outside and controlling the ventilation discharged; Bypass installed in the outer case between the first electric damper and the ventilation inlet port, when the damper of the first electric damper is completely closed, the bypass to form a first bypass passage so that the ventilation flows to the bottom of the outer case Absence; A first bottom plate covering a bottom surface of the outer case; A second bottom plate spaced apart from the first bottom plate at a predetermined interval and installed in the outer case to form a second bypass passage communicating with the first bypass path between the first bottom plate; A second electric damper installed at the second bottom plate at the bottom of the exhaust fan; And a control box installed at the outer case to control the first and second electric dampers to allow the ventilation to be introduced into the heat exchanger or to flow the first and second bypass passages.

The second bottom plate is characterized in that the first and second bypass through-holes are formed to communicate with the first and second bypass passages.

According to an embodiment of the present invention, a bypass passage may be formed in the outer case, and an electric damper may be installed in the outdoor air discharge passage to discharge the indoor air to the heat exchanger, and may be discharged through the bypass passage.

That is, when the indoor air does not need to be introduced into the heat exchanger, the indoor air can be quickly discharged to the outside through the bypass passage without introducing the indoor air into the heat exchanger.

Therefore, since indoor air is not introduced into the heat exchanger, not only can the indoor air be discharged quickly, but the life of the heat exchanger can be extended, and the ventilation system can be operated economically and efficiently, and the load of the heat exchanger is reduced. Can be.

In addition, by changing the structure of the electric damper to be installed in the outer case, as well as by forming a bypass passage as described above can respond regardless of the indoor air emissions.

Therefore, the compatibility of the ventilation system can be improved.

1A is a plan view of a conventional ventilation system.
1B is a side view of FIG. 1A;
1C is a front view of FIG. 1A;
Figure 2a is a plan view showing the configuration of a ventilation system according to the present invention.
2B is a side view of FIG. 2A;
2C is a front view of FIG. 2A;
Figure 3 is a perspective view of the electric damper of Figure 2a.

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

2A is a plan view showing the configuration of the ventilation system according to the present invention, FIG. 2B is a side view of FIG. 2A, and FIG. 2C is a front view of FIG. 2A.

Referring to the drawings, in the ventilation system 100 according to the present invention, the outside air inlet 124 is formed so that one side of the outside air (OA), which is the outdoor air from the outside, and in the diagonal direction with the outside air inlet 124 The air inlet air outlet 125 formed on the opposite side to supply air to the inside of the air (OA), and a ventilation suction inlet formed so that the air (RA), which is indoor air, is discharged to the outside on one side of the air supply air outlet 125 ( 121 and an outer case 111 having a ventilation outlet 123 formed to discharge the ventilation RA to the outside on one side of the outside air inlet 124, respectively.

And in the ventilation system 100 according to the present invention, the heat exchanger is installed in the inner center of the outer case 111 configured as described above to allow heat exchange while passing through the outdoor air (OA) and the indoor ventilation (RA) ( 142, an air supply fan 160 installed in the outer case 111 to one side of the heat exchanger 142 to force the outside air OA into the room, and an outer case to the other side of the heat exchanger 142. An exhaust fan 150 installed in the outlet 111 for forcibly discharging the ventilation RA to the outside, and inside the ventilation suction port 121 formed on one side of the outer case 111 to discharge the ventilation RA to the outside. A first electric damper 130a for controlling the ventilation RA installed and discharged is provided.

In addition, the ventilation system 100 according to the present invention is installed in the outer case 111 between the first electric damper 130a and the ventilation suction port 121, and the damper of the first electric damper 130a as described later. When the 131 is completely closed, the bypass member 122 forming the first bypass passage S1 so that the ventilation RA sucked through the ventilation inlet 121 flows to the bottom of the outer case 111. The first bottom plate 112 covering the bottom bottom surface of the outer case 111 and the first bottom plate 112 are spaced apart from the first bottom plate 112 by a predetermined distance from the first bottom plate ( And a second bottom plate 116 forming a second bypass passage S2 communicating with the first bypass passage S1.

Therefore, as shown in FIG. 2B, the first bypass through hole 116a is formed in the second bottom plate 116 in the bypass member 122 so that the first and second bypass passages S1 and S2 communicate with each other. Is formed.

In the ventilation system 100 according to the present invention, the second electric damper 130b installed on the second bottom plate 116 at the bottom of the exhaust fan 150 and the outer case 111 are installed on the ventilation ( Overall operation of the first and second electric dampers 130a and 130b and the ventilation system 100 to allow RA to be introduced into the heat exchanger 142 or to flow the first and second bypass passages S1 and S2. The control box 170 for controlling the is provided.

In addition, four corners of the heat exchanger 142 are provided with a blocking plate 113 for partitioning (or blocking) the flow paths A, B, C, and D so that the outside air OA and the exhaust are not mixed with each other.

The first and second electric dampers 130a and 130b are provided with the same two electric dampers in the ventilation system 100 according to the present invention, as shown in FIG. A circular damper 131 rotatably installed to open and close the body 134 and the circular damper hole 131a formed to penetrate the rear surface of the closed body 134, and the damper 131 is driven to rotate. It is configured to include an actuator 136 to make.

In addition, a guide member 132 is provided at the inlet of the damper hole 131a to guide the rotation of the damper 131.

In addition, in FIG. 3, reference numeral 133 denotes a rotating shaft connected to the body 134 and the actuator 136 to support and rotate the dampers 131 of the first and second electric dampers 130a and 130b. In order to mount the first and second electric dampers 130a and 130b to the bypass member 122 and the second bottom plate 116, a plurality of fastening holes are formed to fasten a fastening member such as a screw.

In addition, the bypass member 122, as shown in Figures 2a and 2b, is provided integrally with the first electric damper (130a), the front surface is formed in the form of a rectangular box open. That is, the bypass member 122 has a form in which the front surface is open like the first and second electric dampers 130a and 130b, and thus the bypass member 122 is in communication with the ventilation suction port 121.

As shown in FIG. 2C, a second bypass through hole 116b communicating with the second bypass passage S2 is formed in the second bottom plate 116 at the bottom of the second electric damper 130b. . However, since the second electric damper 130b is mounted in close contact with the second bottom plate 116, as shown in FIG. 3, the second bypass through hole 116b is formed of the second electric damper 130b. When the damper 131 is opened, the damper 131 is opened, and when the damper 131 is closed, the second bypass through hole 116b is also closed.

In addition, the outside air (OA) and the ventilation (RA), which may be contaminated among the four sides of the heat exchanger (142), are mixed in the outside air (OA) and the ventilation (RA) before being introduced into the heat exchanger (142), respectively. An air filter 141 for filtering foreign matter is installed, and the air filter 141 is installed to be replaced separately from the heat exchanger 15.

On the other hand, the illustration of the cover covering the upper portion of the outer case 111 in Figures 2a to 2c was omitted, and the control box 170 in Figures 2b and 2c also omitted to show the configuration of the drawings more clearly.

Referring to the operation of the ventilation system according to the present invention having the configuration as described above are as follows.

Referring back to the drawings, the ventilation system 100 according to the present invention, first, when operating the air supply fan 160 to suck the outside air (OA), the outside air (OA) through the outside air inlet 124 After entering the outer case 111 and introduced into the heat exchanger 142 to exchange heat, it is introduced into the room through the outside air supply port 125. That is, the outside air OA flows through the flow paths C and D, and the air supply SA is sucked into the room.

In addition, there are two methods for discharging indoor air to the outside through the ventilation system 100 according to the present invention.

First, the first case will be explained.

The exhaust fan 150 is operated to exhaust the polluted ventilation RA, which is outdoor air, to the outdoors. At this time, the first electric damper 130a is operated (ON), and in the case of the second electric damper 130b.

Therefore, the air in the room is sucked through the ventilation inlet 121, flows in through the damper hole 131a of the first electric damper 130a, and then is introduced into the heat exchanger 142 to exchange heat and finally ventilate. It is discharged through the outlet 123.

That is, since the second electric damper 130b is off, the second bypass through hole 116b is closed so that the ventilation RA flows only through the flow paths A and B on the second bottom plate 116. Will be discharged.

In the second case, for example, when the indoor air is not polluted, but the indoor air is discharged to circulate the indoor air, the indoor air is not introduced into the heat exchanger 142, but simply discharged quickly to the outside. Can be applied to

Specifically, the first electric damper 130a is turned off, the second electric damper 130b is turned on, and the exhaust fan 150 is operated.

Then, since the damper hole 131a of the first electric damper 130a is closed, the indoor exhaust ventilation BEA passes through the first bypass passage S1 and the first bypass passage S1 and the first bypass. The second bypass through hole 116b communicating with the damper hole 131a of the opened second electric damper 130b after flowing through the second bypass passage S2 communicated through the pass through hole 116a. It exits through and is discharged to the outside through the ventilation outlet 123.

Therefore, in the case where it is necessary to discharge the air immediately to the outside without introducing air in the room to the heat exchanger 142, the second method may be performed as described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. . Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

111. Outer case
112. First bottom plate
113. Partition plate
116. Second bottom plate
116b. 2nd bypass through hole
121. Ventilation intake
122. Bypass member
123. Ventilation outlet
124. Outlet intake
125. Fresh air supply
130a. First electric damper
130b. Second electric damper
131. Damper
131a. Damper hole
134.Body
136. Actuator
142. Heat Exchanger
160. Supply fan
150. Exhaust Fan
170. Control Box
S1. 1st bypass passage
S2. 2nd bypass passage

Claims (3)

An outer case;
A heat exchanger installed at a center inside the outer case to allow heat exchange with outdoor air and indoor ventilation;
An air supply fan installed in the outer case to one side of the heat exchanger to force the outside air into the room;
An exhaust fan installed in the outer case to the other side of the heat exchanger and forcibly discharging the ventilation to the outside;
A first electric damper installed inside the ventilation suction port formed on one side of the outer case to discharge the ventilation to the outside and controlling the ventilation discharged;
Bypass installed in the outer case between the first electric damper and the ventilation inlet port, when the damper of the first electric damper is completely closed, the bypass to form a first bypass passage so that the ventilation flows to the bottom of the outer case Absence;
A first bottom plate covering a bottom surface of the outer case;
A second bottom plate spaced apart from the first bottom plate at a predetermined interval and installed in the outer case to form a second bypass passage communicating with the first bypass path between the first bottom plate;
A second electric damper installed at the second bottom plate at the bottom of the exhaust fan;
And a control box installed at the outer case to control the first and second electric dampers to allow the ventilation to be introduced into the heat exchanger or to flow the first and second bypass passages.
And the first and second bypass through holes are formed in the second bottom plate so that the first and second bypass passages communicate with each other. The method of claim 1,
The first and second electric dampers,
A body of a rectangular box shape having an open front surface;
A circular damper rotatably installed while opening and closing a circular through hole formed at a rear side of the closed body;
And an actuator for driving the damper to rotate. The method of claim 1,
The bypass member is provided integrally with the first electric damper, the ventilation system, characterized in that formed in the form of a rectangular box.

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