KR101090974B1 - By-pass motorized damper - Google Patents

Abstract

PURPOSE: An electric damper for a by-pass is provided to reduce the manufacturing cost of an electric damper and maintenance cost by simultaneously switching a bypass door through the operation of a shutoff door. CONSTITUTION: An electric damper for a by-pass comprises an outdoor air introducing bracket(110), a shutoff door(120), an electric motor(130), a by-pass inlet(140), a rack gear(150), a by-pass door(160) and a pinion gear(170). The outdoor air introducing bracket having a tubular shape is installed in an outdoor air entrance(31). The shutoff door is attached to the inner end of the outdoor air introducing bracket and is switched to a rotary type. The electric motor rotates the rotary shaft(121) of the shutoff door. The by-pass inlet is connected to the bypass channel. The by-pass door is installed in the by-pass inlet and is switched to a sliding-type by connecting the rotation of the shutoff door. It installs to the end part of the rotary shaft of the shutoff door and the pinion gear goes in gear with the rack gear. The pinion gear is installed to the end of the rotary shaft of the shutoff door and is engaged with the rack gear.

Description

By-pass motorized damper

According to the present invention, a heat exchange element 20 is installed in one body portion 10, and an air supply passage 30 and a discharge passage 40 intersected by the heat exchange element 20 are provided, and the heat exchange element 20 is provided. Outside air inlet port of the outdoor side end of the air supply passage 30 of the heat exchange ventilation unit provided with a bypass flow path 50 connected to the outside air supply port 32 which is the indoor side end of the air supply passage 30 directly without passing through It relates to an electric damper for bypass mounted to (31).

In the heat exchange ventilation unit, when the indoor temperature rises due to people, cooking utensils, and pre-products during the mid-term, especially in the spring, summer, or summer, fall, the outdoor environment, which is lower than the room temperature, is taken into the room without undergoing heat exchange. There are those equipped with a bypass function that can maintain.

The damper as shown in FIG. 1 is mainly used in the heat exchange ventilation unit provided with the bypass function, and a separate bypass flow path 50 is formed along one side of the body portion 10 of the heat exchange ventilation unit. In addition, the damper is installed in the open air inlet 31 of the inlet side end portion of the bypass flow path 50 to open and close the air flow path.

That is, as shown in FIG. 1 (b), when the door 11 of the damper is rotated to block the entrance to the bypass flow path 50, the air supply flow path 30 passing through the heat exchange element 20 is automatically opened. As shown in FIG. 1 (a), when the door 11 rotates in a direction to block the entrance to the air supply passage 30, the bypass flow path 50 is blocked, and this method is bypassed. The flow path 50 is provided along one side of the inside of the body portion 10 and is mainly applicable to the case in which a counterflow heat exchange element is used, resulting in an increase in the area of the body portion 10 of the heat exchange ventilation unit. In the case of the existing heat exchange ventilation unit that is not provided with the pass flow path 50, it is difficult to retrofit to add the bypass flow path 50 by applying the damper.

In addition, in the case of using the orthogonal heat exchange element, if a conventional damper is applied, a path of the bypass flow path becomes complicated.

In order to solve the above-mentioned problems, the object of the present invention is as follows.

First, it is an object of the present invention to provide a bypass electric damper that can be applied even when the bypass flow path 50 is formed along the lower surface as well as one side of the inside of the body portion 10 of the heat exchange ventilation unit.

Second, another object of the present invention is to provide a bypass electric damper that can be easily added to the bypass flow path 50 by installing in an existing heat exchange ventilation unit that is not provided with the bypass flow path 50. .

Third, another object of the present invention is to provide an electric damper for bypass, which is simple in structure and economical.

Technical composition of the present invention created to achieve the above object is as follows.

A heat exchange element 20 is installed inside one body portion 10, and an air supply passage 30 and a discharge passage 40 intersected by the heat exchange element 20 are provided, and pass through the heat exchange element 20. Air inlet 31 which is an outdoor side end of the air supply passage 30 of the heat exchange ventilation unit having a bypass flow path 50 connected to the outdoor air supply port 32 which is the indoor side end of the air supply passage 30 It relates to a bypass electric damper to be mounted on the outside, the outer end and the inner end has a tubular shape of the open end and the outside air inlet bracket 110 is installed in the outside air inlet (31); A blocking door 120 attached to an inner end of the external air inlet bracket 110 to be opened and closed by rotation; An electric motor 130 mounted to one side of the external air inlet bracket 110 to rotate the rotating shaft 121 of the blocking door 120; A bypass inlet 140 which is opened by cutting a predetermined area between the outer end and the inner end of the external air inlet bracket 110 and connected to the bypass flow path 50; A bypass door 160 installed at the bypass inlet 140 and having a rack gear 150 formed on one side thereof in a longitudinal direction and opening and closing in a sliding manner in association with a rotation of the blocking door 120; And a pinion gear 170 mounted to an end of the rotation shaft 121 of the blocking door 120 and engaged with the rack gear 150, and is rotated in the direction in which the blocking door 120 opens. When the bypass door 160 is interlocked with each other and rotates in the direction in which the blocking door 120 is closed, the bypass door 160 is interlocked with the bypass door 160.

Technical effects of the configuration of the present invention are as follows.

First, the bypass flow path 50 is applicable to the case formed along the lower surface as well as one side of the inside of the body portion 10 of the heat exchange ventilation unit.

In other words, when the bypass flow path 50 is formed under the body of the heat exchange ventilating unit, the external air inlet bracket 110 is mounted such that the bypass door 160 is located at the bottom as shown in FIG. 3 or 4. Although not shown separately in the accompanying drawings, when the bypass passage 50 is formed along one side of the body portion of the heat exchange ventilation unit, the outside air inlet bracket 110 is positioned such that the bypass door 160 is positioned at the side. It can also be rotated and mounted.

That is, there is an advantage that it can be used by mounting to various types of heat exchange ventilation unit.

Second, the bypass flow path 50 may be easily installed by installing in an existing heat exchange ventilation unit that is not provided with the bypass flow path 50.

In other words, in the case of the conventional heat exchange ventilation unit in which the bypass flow path 50 is not integrally provided as shown in FIG. 5, a separate bypass flow path 50 may be adapted to pass through the outside of the heat exchange ventilation unit. have.

Third, it is possible to provide an electric damper for bypass, which is simple in structure and economical.

In other words, by adopting a simple structure in which the bypass door 160 is opened and closed at the same time by interlocking with the operation of the blocking door 120, the manufacturing cost can be lowered and the maintenance cost can be reduced.

1 schematically shows a planar structure of a heat exchange ventilation unit in which a conventional bypass flow path 50 is formed, (a) is a case where direct introduction of outside air through the bypass flow path 50 is performed, and (b) is a bypass. The case where the general ventilation which the path flow path 50 was interrupted | blocked is made is shown.
Figure 2 is a specific embodiment of the bypass electric damper of the present invention.
Figure 3 schematically shows a planar structure of a heat exchange ventilating unit to which the present invention is applied.
Figure 4 is a side structure showing the bypass flow path 50 of the heat exchange ventilating unit to which the present invention is applied, the bypass flow path 50 into the space between the lower portion of the heat exchange element 20 and the lower inner surface of the body portion 10. ) Is formed.
5 is a case where the bypass flow path 50 is installed to pass through the outside of the heat exchange ventilation unit.
FIG. 6 illustrates a structure and process of operating the bypass door 160 using the rotary lever 190 and the boss 161 as another embodiment of the present invention. The rest of the configuration is the same as that shown in FIG. Do.

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

Figure 2 is a specific embodiment of the electric damper for the bypass of the present invention, Figure 3 schematically shows a planar structure of the heat exchange ventilation unit to which the present invention is applied, Figure 4 is a bypass flow path of the heat exchange ventilation unit to which the present invention is applied ( 50 is a side structure illustrating a case in which a bypass flow path 50 is formed as a space between a lower portion of the heat exchange element 20 and a lower inner surface of the body portion 10.

The bypass flow path 50 is not necessarily limited to being installed inside the heat exchange ventilating unit, and by modifying an existing heat exchange venting unit not provided with a bypass flow path separately, as shown in FIG. Bypass passage 50 passing through may be installed.

2 to 4, the heat exchange element 20 is installed in one body 10, and the air supply passage 30 and the discharge passage 40 intersected by the heat exchange element 20 are shown in FIG. Apart from the heat exchange element 20 of the air supply passage 30 of the heat exchange ventilation unit is provided with a bypass flow path 50 which is connected to the outside air supply port 32 which is the indoor side end of the air supply passage 30 directly. It relates to a bypass electric damper mounted to the outdoor air inlet 31 that is the outdoor side end.

The external air inlet bracket 110 has a tubular shape in which the outer end and the inner end are opened as a whole, and a flange 111 is provided to facilitate installation at the external air inlet 31.

The overall shape of the external air intake bracket 110 is not necessarily limited to the quadrangular shape as shown in FIG. 2, and various polygonal shapes other than a circular, elliptical, or rectangular shape may be applied.

The blocking door 120 is attached to the inner end of the external air inlet bracket 110 and is opened and closed by rotation. The external shape of the blocking door 120 has a shape corresponding to the shape of the external air inlet bracket 110.

Electric motor 130 is mounted on one side of the external air inlet bracket 110 serves to rotate the rotating shaft 121 of the blocking door 120, although not shown in detail in the accompanying drawings, but may be added to the reduction gear if necessary. have.

The bypass inlet 140 is opened by cutting a predetermined area between the outer end and the inner end of the outer air inlet bracket 110 and is connected to the bypass flow path 50.

The bypass inlet 140 does not have to be provided at the lower surface of the outside air inlet bracket 110 and may be provided at the left and right sides of the outside air inlet bracket 110, in which case the rotation shaft 121 of the blocking door 120 is provided. ) Will be installed horizontally rather than vertically.

Bypass door 160 is installed in the bypass inlet 140, the rack gear 150 is formed on one side in the longitudinal direction and is opened and closed in a sliding manner in conjunction with the rotation of the blocking door 120.

Guide rails 141 are provided at both sides of the bypass inlet 140 in the lengthwise direction of the bypass inlet 140 to accommodate the bypass door 160 to guide the sliding motion.

Pinion gears 170 engaged with the rack gears 150 are mounted at ends of the rotation shaft 121 of the blocking door 120.

In this way, the rack gear 150 and the pinion gear 170 are engaged with each other. When the blocking door 120 rotates in the open direction, the bypass door 160 is closed in conjunction with this, and the blocking door 120 is closed. By rotating in conjunction with this, the bypass door 160 is opened.

Therefore, when bypass is not required, the blocking door 120 is opened and the bypass door 160 is closed to allow ventilation through the air supply passage 30 and the discharge passage 40 to be exchanged. By passing through the device 20 to the heat exchange between the discharged indoor air and the supplied outdoor air, if the direct introduction of the outdoor air through the bypass is required to close the blocking door 120 and bypass door 160 is Open air is supplied directly to the room through the bypass passage 50 instead of the air supply passage 30, and the outdoor muddy air is discharged to the outside through the discharge passage 40.

It is preferable to provide a gasket 180 for maintaining airtightness along the edge of the blocking door 120 to more completely block the air supply passage 30 when the blocking door 120 is closed.

6 illustrates a structure and process of operating the bypass door 160 using the rotary lever 190 and the boss 161 as another embodiment of the present invention.

In another exemplary embodiment illustrated in FIG. 6, only the way in which the blocking door 120 and the bypass door 160 are interlocked is different, and the remaining components are the same.

The bypass door 160 is installed in the bypass inlet 140 and is opened and closed in a sliding manner in conjunction with the rotation of the blocking door 120, and a boss 161 protruding from one surface thereof is provided.

Here, the boss 161 refers to a member having a shape such as a pillar protruding to one surface of the bypass door 160 as shown in FIG. 6.

The rotary lever 190 is mounted at the end of the rotation shaft 121 of the blocking door 120 to form a right angle with the rotation shaft 121, the rotation lever 190 is rotated together with the rotation shaft 121.

A slot 191 cut in the longitudinal direction is provided along the center of the rotary lever 190, and the boss 161 of the bypass door 160 is accommodated in the slot 191.

Therefore, when the blocking door 120 is rotated, the rotary lever 190 is also rotated together, and the boss 161 is pulled or pushed, thereby interlocking and opening the bypass door 160.

That is, when the blocking door 120 rotates in the open direction, the rotation lever 190 rotates in conjunction with this, pushing the boss 161 of the bypass door 160 to close the bypass door 160, and the blocking door 120 is closed. ) Rotates in the direction of closing, the rotary lever 190 is to open the bypass door 160 by pulling the boss 161 of the bypass door 160.

6 illustrates the movement of the bypass door 160 that interlocks with the rotation of the rotating shaft 121 of the blocking door 120.

As described above, specific embodiments of the present invention have been described with reference to the accompanying drawings, but the protection scope of the present invention is not necessarily limited to these embodiments, and various design changes and additions of well-known technology are within the scope of the technical idea of the present invention. In the case of deletion, simple numerical limitation, etc., the scope of protection of the present invention should be clarified.

11: Door
10: Body part
20: heat exchange element
30: Supply air flow path
31: Outside air inlet 32: Outside air supply port
40: discharge euro
50: Bypass Euro
110: outside air inlet bracket
111: flange
120: blocking door
121: rotating shaft
130: electric motor
140: bypass inlet
141: Guide rail
150: rack gear
160: bypass door
161: Boss
170: Pinion gear
180: gasket
190: rotary lever
191: slot

Claims (3)

A heat exchange element 20 is installed inside one body portion 10, and an air supply passage 30 and a discharge passage 40 intersected by the heat exchange element 20 are provided, and pass through the heat exchange element 20. Air inlet 31 which is an outdoor side end of the air supply passage 30 of the heat exchange ventilation unit having a bypass flow path 50 connected to the outdoor air supply port 32 which is the indoor side end of the air supply passage 30 The electric damper for bypass installed in the,
An external air inlet bracket (110) having an outer end and an inner end in an open tube shape and installed at the external air inlet (31);
A blocking door 120 attached to an inner end of the external air inlet bracket 110 to be opened and closed by rotation;
An electric motor 130 mounted to one side of the external air inlet bracket 110 to rotate the rotating shaft 121 of the blocking door 120;
A bypass inlet 140 which is opened by cutting a predetermined area between the outer end and the inner end of the external air inlet bracket 110 and connected to the bypass flow path 50;
A bypass door 160 installed at the bypass inlet 140 and having a rack gear 150 formed on one side thereof in a longitudinal direction and opening and closing in a sliding manner in association with a rotation of the blocking door 120; And,
A pinion gear 170 mounted to an end of the rotation shaft 121 of the blocking door 120 and engaged with the rack gear 150;
When the blocking door 120 rotates in the open direction, the bypass door 160 is closed in conjunction with this, and when the blocking door 120 rotates in the closing direction, the bypass door is interlocked with the bypass door ( Electric damper for bypass, characterized in that the opening 160. A heat exchange element 20 is installed inside one body portion 10, and an air supply passage 30 and a discharge passage 40 intersected by the heat exchange element 20 are provided, and pass through the heat exchange element 20. Air inlet 31 which is an outdoor side end of the air supply passage 30 of the heat exchange ventilation unit having a bypass flow path 50 connected to the outdoor air supply port 32 which is the indoor side end of the air supply passage 30 The electric damper for bypass installed in the,
An external air inlet bracket (110) having an outer end and an inner end in an open tube shape and installed at the external air inlet (31);
A blocking door 120 attached to an inner end of the external air inlet bracket 110 to be opened and closed by rotation;
An electric motor 130 mounted to one side of the external air inlet bracket 110 to rotate the rotating shaft 121 of the blocking door 120;
A bypass inlet 140 which is opened by cutting a predetermined area between the outer end and the inner end of the external air inlet bracket 110 and connected to the bypass flow path 50;
A bypass door 160 installed at the bypass inlet 140 and having a boss 161 protruding from one side surface in a sliding manner in conjunction with a rotation of the blocking door 120; And,
A rotation lever 190 mounted at an end of the rotation shaft 121 of the blocking door 120 to form a right angle with the rotation shaft 121 to rotate together;
It is configured to include,
A slot 191 cut in the longitudinal direction is provided along the center of the rotary lever 190 so that the boss 161 of the bypass door 160 is accommodated in the slot 191.
When the blocking door 120 rotates in the opening direction, the bypass lever 160 is closed by pushing the boss 161 of the bypass door 160 while the rotary lever 190 rotates in association with the blocking door 120. When the door 120 rotates in the direction of closing the bypass lever 160, the bypass lever 160 is opened by pulling the boss 161 of the bypass door 160 in conjunction with this rotation lever 190 Electric damper. The method of claim 1 or 2,
A gasket 180 for maintaining airtightness along an edge of the blocking door 120;
Bypass electric damper characterized in that it is further provided.

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