KR101841953B1 - Air blower having bypass function and heat exchanger having the same - Google Patents

Abstract

The present invention relates to an air blower having a bypass function and a heat exchanger having the same. According to the present invention, the air blower having a bypass function comprises: a fan housing with an inlet and an outlet; an impeller placed inside the fan housing to generate an air flow where air is introduced through the inlet and is discharged through the outlet by a rotation; an impeller driving motor to rotate the impeller; a bypass hole placed on the fan housing to be adjacent to the outlet of the fan housing; and a flow path conversion damper placed on the fan housing to open/close the bypass hole, to form an air blower flow path, wherein air introduced through the inlet is discharged through the outlet, with the bypass hole closed, to close the air blower flow path with the bypass hole open, and to form a bypass passage to make the bypass hole communicate with the outlet. Accordingly, the present invention is able to reduce a volume, to minimize a bypass flow path resistance, and to prevent the generation of a counter-electromotive force of the motor when bypassing indoor air.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an air blower, an air blower,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a bypass combined blower and an overall heat exchanger having the blower.

Generally, if a person is in a room for a long period of time in a room where the interior of the building is not well ventilated from outside, it is necessary to ventilate the room because the room air can not be kept comfortable due to pollution and CO2 increase. Opening a window and ventilation will cause not only pollution but also internal heat loss. An apparatus for solving such a problem is a ventilation system equipped with an overall heat exchanger.

The ventilation system includes a total heat exchanger installed in the building, an air inflow pipe line installed inside the building so as to be connected to the indoor unit of the building and connected to the total heat exchanger, And an air discharge pipe line. The total enthalpy heat exchanger is equipped with a heating element (also referred to as a heat exchanger element) in the inside of the total heat exchanger, and exchanges heat between room air exhausted from the room to the outside through the heating element and outdoor air introduced into the room from the outside, .

On the other hand, the total enthalpy heat exchanger is provided with a bypass device for ventilating the indoor air without passing through the heating elements, in the spring or fall season, in which the temperature difference between the indoor and the outdoor is small. In addition, when the smoke is generated in the room, the bypass apparatus rapidly discharges the smoke from the room to the outside.

(Hereinafter, referred to as prior art 1), there are provided a case 110 and 120 which are provided with a heating element 200 therein, A duct 300 is installed so that indoor air is exhausted to the outside through a bypass duct without passing through the heat transfer element 200. [ However, in the prior art 1, since the bypass duct is installed on the upper side of the case, not only bulky but also a large installation space is occupied. In addition, indoor air is exhausted through a bypass duct provided outside the case, which results in a large flow path resistance and a large power consumption.

In Korean Patent No. 10-1703672 (hereinafter referred to as Prior Art 2) (hereinafter referred to as Prior Art 2), an electric heat exchanging element 40 is installed inside the main body 10 and outdoor air is blown into the room When the indoor air is bypassed without passing through the total heat-exchanging element 40 when the room air is blown out to the outside, the bypass valve 50 is provided between the intake fan 20 for blowing indoor air and the exhaust fan 30 for blowing indoor air outdoors. The intake fan 20 is stopped and only the exhaust fan 30 is operated with the pass valve 50 opened so that room air is exhausted to the outside through the intake fan 20, the bypass valve 50, and the exhaust fan 30 Is disclosed. In the prior art 2, the bypass passage is provided inside the main body so that the configuration is simple and the volume is small. However, when the room air is bypassed to the outside, the suction fan 20 is moved through the suction fan 20, A counter electromotive force is generated in the fan motor of the suction fan 20, so that there is a danger of burning out the fan motor, and there is a disadvantage in that a power loss is generated because the air flow resistance is large.

SUMMARY OF THE INVENTION An object of the present invention is to provide a bypass-type blower which minimizes the volume and minimizes the bypass flow resistance, and an overall heat exchanger having the blower.

Another object of the present invention is to provide a bypass-type blower which prevents damages to a fan motor when bypassing room air, and an overall heat exchanger having the blower.

In order to accomplish the object of the present invention, there is provided a fan apparatus comprising: a fan housing having a suction port and a discharge port; An impeller installed inside the fan housing and generating air flow that is sucked into the suction port by rotation and discharged to the discharge port; An impeller driving motor for rotating the impeller; A bypass hole provided in the fan housing adjacent to the discharge port of the fan housing; And an air blowing passage provided in the fan housing for opening and closing the bypass hole and discharging the air sucked into the suction port in a state in which the bypass hole is closed to the discharge port, And a bypass passage for communicating the bypass hole and the discharge port while closing the bypass hole and the bypass passage.

Preferably, the flow path switching damper includes a damper plate for forming an air flow passage while opening or closing the bypass hole or forming a bypass passage, and a damper motor for rotating the damper plate.

Preferably, the damper plate includes a curved plate portion forming a curved surface and a straight plate portion extending from the curved plate portion by a straight line.

Preferably, the damper plate includes a rigid plate portion of a rigid material which is not bent, and a flexible plate portion of a flexible material which is formed to extend from the rim of the rigid plate portion and has flexibility.

The fan housing includes a body portion having a suction port on a side surface thereof and having an impeller rotatably disposed therein, and a discharge portion formed on one side of the body portion to communicate with the body portion and discharging air sucked into the suction port by rotation of the impeller, And a duct portion, wherein an end of the discharge duct portion forms a discharge port, and the discharge hole portion is provided with the bypass hole.

In addition, an indoor side air supply device and an indoor side air outlet are provided on one side, an outdoor side air supply device and an outdoor side air outlet are provided on the other side, and a discharge flow path for discharging indoor air to the outside and an inflow A housing having a flow path; A heat exchange element mounted inside the housing for exchanging heat between indoor air and outdoor air; An exhaust blower provided in the exhaust passage so as to be adjacent to the outdoor side exhaust port to generate a discharge flow; An air supply blower provided in the inflow passage so as to be adjacent to the indoor side air supply mechanism to generate an inflow flow; And a bypass damper provided between the exhaust blower and the air supply blower for opening and closing the discharge passage and the inflow passage, wherein the air supply blower is the bypass combined blower of claim 1 .

The bypass damper preferably includes an opening / closing plate for opening / closing a passage for communicating the discharge passage and the inlet passage, and a damper motor for rotating the opening / closing plate to open / close the passage.

The present invention is characterized in that, when a fire occurs or smoke is generated in a room, smoke in the room is supplied to the indoor side air supply mechanism of the housing, the bypass passage of the air supply blower, the passage for communicating the inflow passage and the discharge passage, And exhausted through the outdoor side exhaust port, the flow resistance of the indoor smoke is low, and the indoor smoke is quickly discharged to the outdoor. Particularly, since the indoor smoke flows through the bypass passage of the air supply fan without flowing through the discharge port of the air supply blower, the impeller, and the suction port, the flow resistance is greatly reduced. This minimizes exposure of residents in the room to smoke in the room.

Further, according to the present invention, a bypass structure for discharging indoor air directly to the outside without passing through a heat exchange element is provided inside the housing, so that the structure of the total enthalpy heat exchanger is simple and the volume is reduced.

According to another aspect of the present invention, there is provided a bypass-type blower, wherein a fan hole and a flow path switching damper are provided in a fan housing to form an airflow passage through which the air sucked into the suction port is discharged to the discharge port in a state in which the bypass- When the air is bypassed, air is prevented from flowing through the discharge port, the impeller, and the suction port, and the bypass passage is formed in the bypass passage, So that the flow resistance of the air is reduced and the impeller driving motor for driving the impeller is prevented from reversing, thereby preventing the motor from being burned due to the generation of the back electromotive force.

FIG. 1 is a perspective view showing an embodiment of a bypass-combined blower according to the present invention,
FIG. 2 is a side cross-sectional view showing an embodiment of a bypass-combined blower according to the present invention,
FIG. 3 is a front view showing an embodiment of a bypass-combined blower according to the present invention, FIG.
Fig. 4 is a front view showing a flow path switching damper constituting an embodiment of a bypass-combined blower according to the present invention; Fig.
5 and 6 are side cross-sectional views, respectively, of an operating state of an embodiment of a bypass-combined blower according to the present invention,
FIG. 7 is a plan sectional view showing an embodiment of an total enthalpy heat exchanger having a bypass-combined blower according to the present invention,
8 is a side cross-sectional view showing an exhaust blower constituting an embodiment of the total enthalpy heat exchanger according to the present invention,
9 is a side cross-sectional view illustrating a blower for an air supply unit constituting an embodiment of the total enthalpy heat exchanger according to the present invention,
10 is a plan sectional view showing a general operating state of an embodiment of the total enthalpy heat exchanger provided with a bypass combined blower according to the present invention,
11 is a plan sectional view showing a by-pass operation state of an embodiment of an total enthalpy heat exchanger having a bypass combined blower according to the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of a bypass combined blower and an total enthalpy heat exchanger having the blower according to the present invention will be described with reference to the accompanying drawings.

1 is a perspective view showing an embodiment of a bypass combined blower according to the present invention. 2 is a side cross-sectional view showing an embodiment of a bypass-combined blower according to the present invention. 3 is a front view showing an embodiment of a bypass-combined blower according to the present invention.

1, 2 and 3, an embodiment of a bypass combined blower according to the present invention includes a fan housing 100, an impeller 200, an impeller driving motor 300, a bypass hole BH, , And a flow path switching damper (400).

The fan housing 100 includes a body 110 having a suction port 112 formed at a side surface thereof and an impeller 200 disposed therein and a body 110 extending from one side of the body 110, And a discharge duct part 120 through which air sucked into the suction port 112 is discharged. The body 110 has two side plates 111 spaced apart from each other, a circular inlet 112 provided in each of the two side plates 111 and an outer peripheral surface of the two side plates 111, And includes a surrounding side cylinder (114). The discharge duct portion 120 is formed in the shape of a rectangular tube which is extended and protruded from the side cylindrical body 114 of the body portion 110 so as to communicate with the body portion 110. The end portion of the discharge duct portion 120 serves as a discharge port 121, Has a rectangular hole shape. The upper surface UF and the lower surface LF of the discharge duct portion 120 are referred to as the lower surface LF and the upper surface UF is referred to as the upper surface UF, Both sides to be connected are called sides. In other words, with reference to FIG. 2, the side closer to the center horizontal plane C passing through the center of the body 110 is the lower face LF and the far side is the upper face UF.

The impeller 200 is provided inside the fan housing 100 so that air is sucked into the suction port 112 by rotation and generates an air flow discharged to the discharge port 121. The impeller 200 includes a ring-shaped annular center plate 210 having a uniform thickness and a plurality of blades 220 formed at regular intervals on both sides of the annular center plate 210 to form a circle. The blades 220 of the impeller 200 are positioned in the center direction of the impeller 200, which is in the radial direction. The impeller 200 is rotatably disposed inside the body 110 of the fan housing 100.

The impeller driving motor 300 rotates the impeller 200. The impeller driving motor 300 is preferably an outer rotor type motor. The outer rotor of the impeller driving motor 300 is connected to the annular center plate 210 of the impeller 200 and the motor body of the impeller driving motor 300 is connected to the body of the fan housing 100 by a connection frame (110). The impeller 200 is rotated according to the rotation of the outer rotor.

The bypass hole BH is provided in the fan housing 100 adjacent to the discharge port 121 of the fan housing 100. Specifically, the bypass hole BH is provided over the upper surface UF of the discharge duct portion 120 of the fan housing 100 and a portion of the side cylindrical body 114 of the body portion 110. The bypass hole BH may be formed only on the upper surface UF of the discharge duct portion 120 of the fan housing 100. [ It is preferable that the bypass hole BH is formed in a rectangular shape.

The flow path switching damper 400 is provided in the fan housing 100 to open and close the bypass hole BH so that the air sucked into the inlet port 112 is discharged to the discharge port 121 while the bypass hole BH is closed And a bypass passage for communicating the bypass hole BH and the discharge port 121 while forming the bypass hole BH and covering the air flow passage is formed. 4, the flow path switching damper 400 includes a damper plate 410 which forms an air flow passage while opening and closing the bypass hole BH, or a bypass damper 410 which forms a bypass passage, And a damper motor 420 for rotating the damper plate 410. When the bypass hole BH is provided over the upper surface of the discharge duct portion 120 of the fan housing 100 and a portion of the side cylinder of the body 110, the damper plate 410 is formed as a curved surface plate portion 411, and a straight plate portion 412 extending in a straight line on the curved plate portion 411. [ When the damper plate includes the curved plate portion, the flow path resistance of the air flowing through the bypass passage is reduced. On the other hand, when the bypass hole BH is formed only on the upper surface of the discharge duct portion 120 of the fan housing 100, the damper plate 410 is formed as a straight plate. The damper plate 410 includes a rigid plate portion of a rigid material which is not bent and a flexible plate portion of a flexible material which is formed so as to extend on the rim of the rigid plate portion. It is preferable that the flexible plate portion is formed to extend to the other three sides except for the connecting portion of the rigid plate portion. It is preferable that the rigid material is plastic and the flexible material includes rubber, silicone, resin, or the like. A hinge shaft 413 is provided on one side of the damper plate 410 and the hinge shaft 413 is rotatably coupled to one side of the bypass hole BH, And is located at a distance from the discharge port 121. The rigid plate portion of the damper plate 410 is formed to have the same size as or equivalent to the size of the bypass hole BH and the flexible plate portion is formed larger than the size of the bypass hole BH. The flexible plate portion contacts the rim of the bypass hole BH to seal the bypass hole BH while the damper plate 410 blocks the hole in the bypass hole BH. The damper motor 420 is mounted on one side of the fan housing 100 and connected to the hinge shaft 413.

Hereinafter, the operation and effect of the bypass combined blower according to the present invention will be described.

5, when the damper plate 410 of the flow path switching damper 400 closes the bypass hole BH, the impeller driving motor 300 is operated The impeller 200 is rotated. A pressure difference between the inside and the outside of the fan housing 100 is generated due to the rotation of the impeller 200 so that air is sucked through the inlet 112 of the fan housing 100 to be discharged to the impeller 200 of the body 110 And is discharged through the discharge port 121 through the duct portion 120. [ 6, when the operation of the impeller driving motor 300 is stopped, the damper motor 420 of the flow path switching damper 400 is operated to rotate the damper plate 410. As a result, The one end side of the damper plate 410 (the opposite side of the rotation axis of the damper plate) is contacted with the lower surface of the discharge duct portion 120 of the fan housing 100 while being inclined to the discharge duct portion 120 . As a result, a bypass passage F is formed in which the discharge duct portion 120 is blocked and the bypass hole BH and the discharge port 121 are communicated with each other. That is, the bypass passage F is formed by a part of the discharge duct portion 120 and the damper plate 410, the bypass hole BH is located at one end, and the discharge port 121 is located at the opposite end. Air can flow through the bypass passage (F). When the damper plate 410 is rotated by operating the damper motor 420, the damper plate 410 rotates and contacts the inner surface of the discharge duct portion 120 as shown in FIG. 5, BH), the discharge duct portion 120 is opened, and an air flow passage through which the air sucked into the suction port 112 can be discharged to the discharge port 121 is formed.

FIG. 7 is a plan sectional view showing an embodiment of the total enthalpy heat exchanger provided with a bypass combined blower according to the present invention.

7, an embodiment of the total enthalpy heat exchanger having a bypass combined blower according to the present invention includes a housing 500, a heat exchanging element 600, an exhaust blower Q1, an air blower Q2 And a bypass damper 700. The air supply blower Q2 is a bypass air blower.

The housing 500 is provided with an indoor side air supply mechanism 531 and an indoor side air outlet 532 on one side and an outdoor side air supply mechanism 541 and an outdoor side air outlet 542 on the other side, And a discharge passage P2 for guiding the indoor air to be discharged out of the room. The housing 500 includes front, rear, left and right plates 510, 520, 530, and 540 connected to form a square, and front, rear, left, And an upper and a lower side plate (number not shown) for forming an inner space by covering the upper and lower ends of the upper and lower plates. The positions of the front, rear, left, and right positions of the housing 500 are set based on FIG. 7 for convenience of explanation. The left side plate 530 is provided with an indoor side air supply mechanism 531 and an indoor side air outlet 532 and the right side plate 540 is provided with an outdoor side air supply mechanism 541 and an outdoor side air outlet 542. The indoor side air supply mechanism 531 and the outdoor side air outlet 542 are positioned facing each other and the indoor side air outlet 532 and the outdoor side air supply mechanism 541 face each other. The inflow channel P1 is formed so as to communicate with the indoor side air supply mechanism 531 of the left side plate 530 and the outdoor side air supply mechanism 541 of the right side plate 540. The discharge flow path P2 is connected to the left side plate 530, Side exhaust port 532 of the right side plate 540 and the exhaust side outlet 542 of the right side plate 540. [

The heat exchange element 600 is mounted inside the housing 500 to exchange heat between indoor air and outdoor air. The heat exchange element 600 is installed inside the housing 500 to connect the inflow passage P1 and the discharge passage P2 to each other and is connected to the indoor air discharged into the inflow passage P1 and the discharge passage P2 Heat exchange the air. The heat exchange element 600 is in the shape of a hexahedron and the four corners of the heat exchange element 600 are respectively disposed at the middle portions of the front, back, left and right plates 510, 520, 530 and 540 of the housing 500 Is located inside the housing (500). The partition walls W are provided at the middle portions of the front, rear, left and right plates 510, 520, 530 and 540 so that the respective corners of the heat exchange element 600 are supported on the partition W. As the heat exchange element 600 is located inside the housing 500, four compartment spaces are provided inside the housing 500. The compartment space communicating with the indoor side air supply mechanism 531 of the left side plate 530 of the housing 500 is divided into a compartment space communicating with the first compartment space S1 and the indoor side air outlet 532 of the left side plate 530 The partition space communicating with the second compartment space S2 and the outdoor side exhaust port 542 of the right side plate 540 is communicated with the third compartment space S3 and the outdoor side air supply mechanism 541 of the right side plate 540 The first and fourth compartment spaces S1 and S4 located in the diagonal direction form the inflow passage P1 and the second and third compartment spaces S4 and S4 located in the diagonal direction. The spaces S2 and S3 form a discharge passage P2.

The exhaust blower Q1 is provided in the exhaust passage P2 so as to be adjacent to the outdoor side exhaust port 542 to generate an exhaust flow. Specifically, the exhaust blower Q1 is installed in the housing 500 so as to be located in the third compartment space S3 communicating with the outdoor side exhaust port 542. [ 8, the exhaust blower Q1 includes a fan housing 100 'having an intake port 112 and a discharge port 121, and a fan housing 100' provided inside the fan housing 100 ' And an impeller driving motor 300 that rotates the impeller 200. The impeller 200 includes an impeller 200 for rotating the impeller 200, The fan housing 100 is installed inside the housing 500 by the fixing means so that the discharge port 121 of the blower Q1 is communicated with the outlet 542 of the outdoor side.

The air supply blower Q2 is provided in the inflow passage P1 so as to be adjacent to the indoor side air supply mechanism 531 to generate an air supply flow. Specifically, the air supply blower Q2 is installed inside the housing 500 so as to be located in the first compartment space S1 communicating with the indoor side air supply mechanism 531. [ The air supply blower (Q2) is a bypass air blower. 9, the air supply blower Q2 is provided with a fan housing 100, an impeller 200, an impeller driving motor 300, a bypass hole BH, and a flow path switching damper 400 . The configuration of the fan housing 100 of the air supply fan Q2, the impeller 200, the impeller driving motor 300, the bypass hole BH and the flow path switching damper 400 is the same as that of the above- Are the same as those of the housing 100, the impeller 200, the impeller driving motor 300, the bypass hole BH, and the flow path switching damper 400, respectively. Therefore, detailed description is omitted. The fan housing 100 is installed in the housing 500 by fixing means (not shown) so that the fan housing outlet 121 of the air supply blower Q2 is communicated with the indoor side air supply mechanism 531. [

The bypass damper 700 is provided between the exhaust blower Q1 and the air supply blower Q2 to open and close the inflow passage P1 and the discharge passage P2. The bypass damper 700 includes an opening and closing plate 710 for opening and closing a passage for communicating the inflow passage P1 and the discharge passage P2 and a valve plate 710 for opening and closing the passage And a damper motor (not shown) that rotates the opening / closing plate 710 so as to open and close. The passage communicating the inflow passage P1 with the discharge passage P2 is formed between the third partition space S3 in which the blower Q1 for the exhaust is located and the first partition space S1 in which the blower Q2 for the air supply is located (Not shown).

Hereinafter, the operation and effects of the total enthalpy heat exchanger having the bypass combined blower according to the present invention will be described.

The total enthalpy heat exchanger having a bypass combined blower according to the present invention is installed in a building to ventilate indoor air. At this time, the indoor side air supply mechanism 531 and the exhaust port 532 of the total enthalpy heat exchanger are communicated with the interior of the building, and the outdoor side air supply mechanism 541 and the exhaust port 542 are communicated with the exterior of the building.

10, the bypass hole BH of the air supply blower Q2 is blocked by the damper plate 410 of the flow path switching damper 400 and the bypass damper 400 of the bypass damper 400 is closed, The air supply fan Q2 and the air blower Q1 are actuated simultaneously in a state in which the opening and closing plate 710 of the air conditioner 700 closes the passage for communicating the inflow passage P1 and the discharge passage P2. When the exhaust blower Q1 and the air supply blower Q2 operate, outdoor air flows into the interior of the housing 500 through the outdoor side air supply mechanism 541 and flows through the inflow path P1, And flows into the room through the indoor side air supply mechanism 531 while passing through the air inlet 112 and the air outlet 121 of the air supply blower Q2 through the air supply duct 600. [ At the same time, the room air flows into the interior of the housing 500 through the indoor side exhaust port 532, flows through the exhaust flow path P2, passes through the heat exchange device 600, and is sucked into the suction port 112 of the exhaust blower Q1. And is discharged to the outside through the outdoor side exhaust port 542 while passing through the discharge port 121. At this time, the outdoor air flowing into the inflow channel P1 of the housing 500 and the indoor air discharged into the discharge channel P2 are exchanged with each other while passing through the heat exchange element 600, To reduce the indoor heat loss.

11, the bypass hole BH of the air supply blower Q2 is connected to a flow path switching damper (not shown) The damper plate 410 of the bypass damper 700 opens the bypass passage and closes the air passage so that the opening and closing plate 710 of the bypass damper 700 communicates the inflow passage P1 with the discharge passage P2 In the open state, the air supply fan (Q2) is stopped and only the air blower (Q1) is operated. When the air supply fan Q2 is stopped and only the air blowing fan Q1 operates, the room air flows into the housing 500 through the indoor side air supply mechanism 531 and the air blowing out from the air outlet 121 of the air supply blower Q2 The indoor air passing through the bypass passage BH and the bypass passage F and having passed through the bypass passage F passes through the inflow passage P1 and the discharge passage P2 without passing through the heat exchanging element 600, And is discharged to the outside of the room through the outdoor air outlet 542 while passing through the air inlet 112 of the air blower Q1 and the outlet 121. [ A part of the room air flows into the housing 500 through the indoor side exhaust port 532 and passes through the heat exchanging device 600 while passing through the exhaust blower Q1 to the outdoor side And is exhausted to the exhaust port 542.

As described above, according to the present invention, when a fire occurs or smoke is generated in the room, the smoke in the room is separated from the indoor side air supply mechanism 531 of the housing 500, the bypass passage F of the air supply fan Q2, The exhaust air is exhausted through the passage for communicating the inflow passage P1 with the exhaust passage P2 and the exhaust blower Q1 and the outdoor side exhaust port 542 so that the flow resistance of the indoor smoke is small, . Particularly, the indoor smoke flows through the discharge port 121 of the air supply fan Q2, the impeller 200, and the bypass passage F of the air supply fan Q2 without flowing through the air inlet 112 So that the flow resistance is greatly reduced. This minimizes exposure of residents in the room to smoke in the room.

In addition, according to the present invention, a bypass structure for discharging the room air directly to the outside without passing through the heat exchange element 600 is provided inside the housing 500, so that the structure of the total heat exchanger is simple and the volume is small.

In the bypass combined blower of the present invention, the bypass hole (BH) and the flow path switching damper (400) are provided in the fan housing (100), and the flow path switching damper The vent hole BH is communicated with the vent hole BH while the vent hole is opened and the vent hole BH is communicated with the vent hole 121. [ When the air is bypassed, the air flows through the bypass passage F without flowing through the discharge port 121, the impeller 200, and the suction port 112, The flow resistance of the air is reduced and the impeller driving motor 300 for driving the impeller 200 is prevented from rotating in the reverse direction, thereby preventing damage to the motor due to the generation of the back electromotive force.

100; A fan housing 200; Impeller
300; Impeller drive motor BH; Bypass hole
400; Channel switching damper 500; housing
600; A heat exchange element 700; Bypass damper

Claims (7)

A fan housing having a suction port and a discharge port;
An impeller installed inside the fan housing and generating air flow that is sucked into the suction port by rotation and discharged to the discharge port;
An impeller driving motor for rotating the impeller;
A bypass hole provided in the fan housing adjacent to the discharge port of the fan housing;
Is provided in the fan housing being more Majesty the bypass hole, the blowing of the bypass holes the air sucked into the suction port and forming the air passage to be discharged to the discharge port, is closed the bypass hole open, And a bypass passage for communicating the bypass hole and the discharge port so that the air passes through the bypass hole and the discharge port without passing through the impeller while closing the flow passage. The blower according to claim 1, wherein the flow path switching damper comprises a damper plate for forming an air flow passage while opening or closing the bypass hole, or forming a bypass passage, and a damper motor for rotating the damper plate. The blower according to claim 2, wherein the damper plate comprises a curved plate portion curved to reduce a flow path resistance when air flows, and a straight plate portion extending linearly on the curved plate portion. The blower as claimed in claim 2, wherein the damper plate includes a rigid plate portion of a rigid material that is not bent, and a flexible plate portion formed of a flexible material and extending to the rim of the rigid plate portion. The fan according to claim 1, wherein the fan housing includes a body portion having a suction port on a side surface thereof and having an impeller rotatably disposed therein, and a fan portion extending from one side of the body portion to communicate with the body portion, Wherein the end of the discharge duct portion forms a discharge port, and the discharge duct portion includes the bypass hole. Side air supply mechanism and an indoor exhaust port on one side, an outdoor side air supply mechanism and an outdoor exhaust port on the other side, and an exhaust flow path through which indoor air is discharged to the outside and an inflow flow path through which the outdoor air flows into the room A housing;
A heat exchange element mounted inside the housing for exchanging heat between indoor air and outdoor air;
An exhaust blower provided in the exhaust passage so as to be adjacent to the outdoor side exhaust port to generate a discharge flow;
An air supply blower provided in the inflow passage so as to be adjacent to the indoor side air supply mechanism to generate an inflow flow;
And a bypass damper provided between the exhaust blower and the air supply fan for opening and closing the discharge flow passage and the inflow passage,
In the air supply fan,
A fan housing having a suction port and a discharge port;
An impeller installed inside the fan housing and generating air flow that is sucked into the suction port by rotation and discharged to the discharge port;
An impeller driving motor for rotating the impeller;
A bypass hole provided in the fan housing adjacent to the discharge port of the fan housing;
And an air blowing passage provided in the fan housing for opening and closing the bypass hole and discharging the air sucked into the suction port in a state where the bypass hole is closed to the discharge port, And a bypass passage for communicating the bypass hole and the discharge port so that the air passes through the bypass hole and the discharge port without passing through the impeller,
Wherein the blower opening of the blower for blowing air is opened by the passage switching damper to block the blowing passage and open the bypass passage when the smoke in the room is discharged to the outside, The air supply fan is stopped and only the air blower for exhaust is operated. delete

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