KR20170141360A - Ventilation apparatus - Google Patents

Abstract

The present invention relates to a range hood separation-type anti-condensation double suction constant air volume ventilation apparatus. The ventilation apparatus according to the present invention comprises: a casing which includes an inlet and an outlet; a blower which is installed in the casing, and generates a constant air volume; an inlet side connection duct which is connected to the inlet of the casing, and is connected to an exhaust duct of a range hood; and an outlet side connection duct which is provided with a heat insulation portion for anti-condensation therein. The blower includes: a fan housing which is provided with two side inlets and one outlet; an impeller which is provided in the fan housing and generates flow; an impeller driving motor which rotates the impeller; a vane which is hinge-coupled to the center direction side of the impeller which is the downside of the outlet of the fan housing, and opens and closes the outlet while rotating about the lower portion as an axis; a vane driving motor which is mounted on the outer surface of the fan housing and rotates the vane; and a fixing unit which fixes the fan housing to the casing. According to the present invention, flow resistance of discharging pollutants generated in the kitchen through a discharge passage of an apartment house is minimized, noise transferred to the kitchen is minimized, and condensation is prevented on the exhaust duct due to the temperature difference at the time of discharging the pollutants generated in the kitchen through the discharge passage of the apartment house.

Description

{VENTILATION APPARATUS} [0001]

[0001] The present invention relates to a ventilating apparatus for a respiratory hood separation type condensation preventing ambush airflow.

A kitchen stove (or a microwave oven) is installed in a kitchen such as a home or a restaurant, and the cooking is performed using the cooking stove. When food is cooked using a gas stove, pollutants such as smoke, odor, and dust are generated from the food, and a ventilator is installed to forcibly discharge the pollutants outdoors. The general ventilation device includes a range hood located on the upper side of the gas range, an exhaust duct connected to the range hood, a filter installed on the range hood side, and a blower connected to the exhaust duct to generate a suction force .

Generally, a ventilation system is installed in a multi-family house to vent the pollutants such as smoke, odor, and dust generated in the kitchen of each household to the outside. In the ventilation system, a ventilation device is installed in the kitchen of each furniture, and an exhaust duct of the ventilation device of each furniture communicates with an exhaust passage of the apartment house. In such a ventilation system, the pollutants generated from each furniture are discharged through the exhaust duct by the operation of the ventilation devices of the respective houses of the apartment house, and the pollutants discharged through the exhaust ducts of the respective houses are exhausted through the exhaust passage Ventilate the kitchen of each household while discharging it to the outside.

However, as the number of floors in apartment buildings increases, low - rise furniture is not well ventilated and noise is generated. High - rise furniture is well ventilated, but pollutants from low - rise furniture are introduced. Particularly, the blower of the ventilation device is installed adjacent to the cooking hood side, so that the noise in the kitchen is increased and the ventilation duct is not well discharged to the exhaust passage of the apartment house through the exhaust duct.

In order to solve such a problem, there has been proposed a system for controlling the amount of air blown from a ventilator of each house of a multi-family house to prevent the contaminants discharged through the air passage of the multi- Has been demanded.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a ventilating hood isolation type condensation preventing positive pressure air amount ventilation device which minimizes flow resistance for discharging contaminants generated in a kitchen to an exhaust passage of a house and minimizes noise transmitted to the kitchen.

Another object of the present invention is to provide a ventilating hood-free condensation preventing ventilation system for preventing the generation of condensation in the ventilation duct due to the temperature difference when the pollutants generated in the kitchen are discharged to the ventilation passage of the apartment house.

In order to accomplish the object of the present invention, there is provided an air conditioner comprising: a casing having an inlet and an outlet; A blower mounted inside the casing to generate a constant air flow rate; An inlet duct connected to the inlet of the casing and connected to the exhaust duct of the cooking hood; And a discharge duct connected to an outlet side of the casing and having a heat insulating portion for preventing condensation, wherein the blower includes a fan housing having two side inlets and a discharge opening; An impeller provided inside the fan housing to generate a flow; An impeller driving motor for rotating the impeller; A vane hinged to the center of the impeller downwardly of the fan housing discharge port to open and close the discharge port while being rotated around an axis of the lower portion; A vane drive motor mounted on an outer surface of the fan housing to rotate the vane; And a fixing unit for fixing the fan housing to the casing, wherein the range hood detachable condensation preventing respiratory air flow rate ventilation device is provided.

The fan housing includes a body having a suction port on each side of the fan housing and having the impeller therein, and a discharge port extending from one side of the body to discharge the air sucked into the suction port as the impeller rotates. And a hinge coupling portion provided at a lower portion of the discharge duct portion and hinged to the vane.

And an edge groove on which the vane is closely contacted and supported is provided on an end surface of the discharge duct portion.

The vane is positioned in a horizontal state in the same direction as the flow direction of the air discharged through the discharge port in a state where the vane opens the discharge port and is located outside the discharge duct portion.

Wherein the outflow-side connecting duct includes an inner wall layer, an outer wall layer, and an intermediate wall layer positioned between the inner wall layer and the outer wall layer, wherein the inner wall layer and the outer wall layer are the same first material, It is preferable to include a second material which is different from the material.

It is preferable that the first material has a lower melting point than the second material and the second material has a lower thermal conductivity than the first material.

Preferably, the first material includes polypropylene, and the second material includes a silicon component.

The present invention is characterized in that a suction force is generated by the operation of the blower and the pollutant is sucked through the range hood and the pollutants sucked into the range hood are discharged to the exhaust passage through the exhaust duct and the casing, And the air is discharged while being discharged through the discharge port. Therefore, when the air containing the pollutants passes through the blower, the flow resistance of the air is low, so that the flow loss is minimized and the noise generation is minimized. In addition, since the vane of the blower opens and closes the discharge port of the fan housing, the discharge port of the fan housing is blocked by the vane in a state where the blower is not operated, thereby preventing contaminants from entering the kitchen, Is hinged to the lower portion of the discharge port and is located parallel to the flow direction of the air to the outside of the discharge port and is positioned at a portion where the discharge of air is small so that the flow resistance of the air is not generated.

In addition, since the flow loss is minimized during the operation of the blower, the present invention discharges the air including the pollutant in a regular air flow in a state of using a blower of a constant air volume, So that exhaust of pollutants is smoothly performed.

In addition, since the outflow-side connecting duct includes the heat insulating portion, when the air containing pollutants generated in the kitchen is discharged to the exhaust passage, condensation is generated in the exhaust duct due to the temperature difference between the inside of the exhaust passage and the main air . This prevents the generation of mold due to the occurrence of condensation on the outflow-side connecting duct and also prevents the condensation water from flowing into the indoor side.

In addition, the present invention is not installed in a cooking hood located in a kitchen, but is installed on the side of an exhaust passage to minimize minute noise generated from the ventilator side toward the kitchen, .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view of a ventilation system provided with an embodiment of a variable respiratory air flow rate avoiding apparatus of the present invention; FIG.
FIG. 2 is a plan view showing an embodiment of a range hood ventilation apparatus for preventing condensation of a hood according to the present invention,
Fig. 3 is a front view showing an embodiment of a range hood ventilation device for preventing condensation of hoods according to the present invention,
FIG. 4 is a front view showing a fan housing of an air blower constituting an embodiment of a range-limiting respiratory air ventilation fan according to the present invention,
FIG. 5 is a perspective view showing a fan housing of a blower which constitutes an embodiment of a ventilating fixed ventilation fan of the present invention,
FIG. 6 is a front view showing a vane of a blower constituting an embodiment of a range-limiting respiratory air ventilation fan according to the present invention,
FIG. 7 is a side view of a vane of a blower constituting an embodiment of a range-limiting respiratory air ventilation fan of the present invention; FIG.
FIG. 8 is a cross-sectional view illustrating an outflow-side connecting duct constituting an embodiment of a range-respiratory air-conditioned air volume ventilation apparatus according to the present invention,
FIG. 9 is a front sectional view showing an operating state of a range hood ventilation device for preventing condensation of a hood according to the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a ventilation system for preventing respiratory hood separation type condensation according to the present invention will be described with reference to the accompanying drawings.

1 is a side view showing a ventilation system provided with an embodiment of a range hood ventilation apparatus for preventing condensation of a hood according to the present invention. 2 is a plan view showing an embodiment of a ventilating air volume control device for a separate type condensation preventing respiratory hood according to the present invention. 3 is a front view showing an embodiment of a ventilating air volume control device for a separate type condensation preventing range hood according to the present invention.

As shown in FIG. 1, the ventilation system provided with the embodiment of the diaphragm hood separation type condensation preventing respiratory positive airflow amount ventilating apparatus according to the present invention includes a lens hood H positioned on the upper side of the stove 10, H) and the exhaust passage (P), and a range hood separation type condensation preventing respiratory air flow amount ventilation device (E) according to the present invention connected to the exhaust duct (D). The ventilation device E is not located on the side of the cooking hood H but on the side of the exhaust passage P side.

As shown in Figs. 2 and 3, the ventilating hood ventilation system according to the present invention includes a casing C, a blower F, an inflow side connecting duct D1, And a connecting duct D2.

The casing (C) is provided with an inlet (1) and an outlet (2). 22, 23, 24, and 25 in the upper, lower, front, rear, left and right sides of the casing C in a hexahedron shape, (26). The inlet port 1 is provided in the left side plate 23 and the outlet port 2 is provided in the right side plate 24 (refer to FIGS.

The blower F is mounted inside the casing C to generate a constant air flow rate. 4, the blower includes a fan housing 100, an impeller 200, an impeller driving motor 300, a vane 400, a vane driving motor 500, a fixed unit 500, .

4 and 5, the fan housing 100 includes a body 110 having a suction port 112 on a side surface thereof and an impeller 200 disposed therein, and a body 110 having one side of the body 110 A discharge duct part 120 provided with a discharge port through which the air sucked into the suction port 112 is discharged according to the rotation of the impeller 200 and a vane 400 provided at a lower part of the discharge duct part 120, And a hinge engaging portion 130 which is hinged. 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 a side cylindrical body 114 which surrounds and has holes. The discharge duct portion 120 is formed in a rectangular tube shape extending and projected from the side cylindrical body 114 of the body portion 110 so as to communicate with the hole of the side cylindrical body 114 of the body portion 110, The discharge port 121 is formed and the discharge port 121 is shaped like a square hole. And a flange portion 122 is provided at an edge of the discharge port 121 in a direction perpendicular to the discharge duct portion 120. The lower surface of the discharge duct portion 120 is referred to as a lower surface and the upper surface (a surface facing the lower surface) and both surfaces are referred to as a side surface. The lower surface of the discharge duct part 120 is adjacent to the center line of the body 110 and the upper surface of the discharge duct part 120 is located farther away from the center line of the body 110 than the lower surface of the discharge duct part 120.

The impeller 200 is provided inside the fan housing 100 and generates a flow by rotation. The impeller 200 includes a ring-shaped annular center plate 210 having a uniform thickness, a plurality of blades 220 formed at regular intervals on both sides of the annular center plate 210, Blade < / RTI > 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 impeller driving motor 300 has an outer rotor 310 connected to the annular center plate 210 of the impeller 200. The blades 220 are rotated in accordance with the rotation of the outer rotor 310.

The vane 400 is hinged to one side of the fan housing 100 under the discharge port 121 to open and close the discharge port 121 while rotating the lower portion about the axis. It is preferable that the vane 400 is formed in a rectangular plate shape larger than the discharge port 121 so as to open and close the discharge port 121. The vane 400 includes a plate portion 410 formed in a rectangular shape, a coupling portion 420 provided at one end of the plate portion 410, and a flexible rim 420 surrounding the rim of the plate portion 410. [ (430).

The coupling portion 420 of the vane 400 is rotatably coupled to the hinge coupling portion 130 of the discharge duct portion 120 of the fan housing 100. 6, the hinge coupling portion 130 of the discharge duct portion 120 includes a locking protrusion 131 protruding from the inner surface of one side surface of the discharge duct portion 120, And an engagement hole 132 penetrating the other side surface. One end of the engaging portion 420 of the vane 400 is inserted into the engaging projection 131 and the other end of the engaging portion 420 is positioned in the engaging hole 132. [

The vane drive motor 500 is mounted on the fan housing 100 to rotate the vane 400. The vane drive motor 500 is mounted on the outer side of one side of the discharge duct portion 120 of the fan housing 100. At this time, the motor shaft of the vane drive motor 500 is fixedly coupled to the coupling portion 420 of the vane 400 through the coupling hole 132 of the discharge duct portion 120.

7, when the vane driving motor 500 is rotated forward, the vane 400 is rotated with the coupling portion 420 of the vane 400 as a hinge axis, Thereby closing the discharge port 121 of the ink cartridge. When the vane driving motor 500 is reversely rotated, the vane 400 rotates about the coupling portion 420 of the vane 400 as a hinge axis, and is horizontally positioned in the outward direction of the discharge duct portion 120, And the discharge port 121 of the housing 100 is opened.

It is preferable that the rim groove 123 is provided on the end surface of the discharge duct portion 120 of the fan housing 100 so that the vane 400 is supported and adhered tightly. The rim groove 123 preferably has a uniform depth in a rectangular shape. It is preferable that stoppers 124 are formed to protrude from the inner wall of both sides of the discharge duct portion 120. It is preferable that a flow guide protrusion which reduces the flow resistance of air is provided beside the hinge coupling part 130 of the discharge duct part 120 of the fan housing 100.

A fixed unit (not shown) fixes the fan housing 100 of the blower F to the casing C. The fixed unit includes bolts and nuts.

The inlet-side connecting duct D1 is connected to the inlet 1 of the casing C. A flange portion is provided on one side of the inlet side connecting duct D1 and the flange portion is coupled to the left side plate 23 so that the inlet side connecting duct D1 is connected to the inlet 1 of the casing C. In addition, the other of the inflow-side connecting ducts (D1) is connected to the exhaust duct (D) of the cooking hood (H).

The outflow-side connecting duct (D2) is connected to the outlet (2) side of the casing (C). A flange portion is provided on one side of the outlet side connecting duct D2 and the outlet side connecting duct D2 is connected to the outlet 2 of the casing C while the flange portion thereof is coupled to the right side plate 24. And the outflow-side connecting duct (D2) communicates with the exhaust passage (P) of the apartment house. The outlet-side connecting duct (D2) is provided with a heat insulating portion for preventing condensation.

8, the outflow-side connecting duct D2 includes an inner wall layer 31, an outer wall layer 32, and an intermediate wall layer 33 located between the inner wall layer 31 and the outer wall layer 32 The inner wall layer 31 and the outer wall layer 32 are made of the same first material and the intermediate wall layer 33 includes a second material different from the first material. The middle wall layer 33 constitutes a heat insulating portion. It is preferable that the first material has a lower melting point than the second material and the second material has a thermal conductivity lower than that of the first material. Preferably, the first material comprises polypropylene and the second material comprises a silicon component.

Hereinafter, the operation and effect of the ventilating fan unit for preventing respiratory hood separation type condensation according to the present invention will be described.

First, when food is cooked using a gas stove (or microwave oven) in a kitchen, contaminants such as smoke, odor, and dust are generated. A suction force is generated as the blower F is operated while the vane 400 of the ventilation device E is open and contaminants generated while being cooked by the suction force of the blower F are supplied to the cooking hood H And flows into the casing C through the inlet duct D1 of the ventilator E while flowing through the exhaust duct D. The contaminants introduced into the casing (C) are sucked through the suction ports (112) of the fan housing (100) and discharged through the discharge port (121) of the discharge duct section (120). The pollutant discharged from the fan housing 100 is discharged to the exhaust passage P via the outlet-side connecting duct D2. The pollutants introduced into the exhaust passage (P) are exhausted to the outside through the exhaust passage (P). If the food is not cooked, the vents 400 close the discharge port 121 and stop the operation of the blower F.

A suction force is generated by the operation of the blower F so that contaminants are sucked through the range hood H and contaminants sucked into the range hood H are sucked through the exhaust duct D and the casing C The air is sucked through the air inlets 112 provided on both side surfaces of the fan housing 100 of the air blower F and discharged through the air outlets 121 as shown in FIG. So that the flow of air including the pollutant is minimized when the air passing through the blower F is flowed to minimize the flow loss and also minimizes noise generation. Since the vane 400 of the blower F opens and closes the discharge port 121 of the fan housing 100, the discharge port 121 of the fan housing 100 is opened by the vane 400 in a state in which the blower F is not operated The vane 400 is hinged to the lower side of the discharge port 121 to prevent the flow of air to the outside of the discharge port 121. In addition, And is located at a portion where the air is less discharged, so that the flow resistance of the air is not generated.

In addition, since the flow loss is minimized during the operation of the blower (F), the air containing the pollutant is discharged in a regular air flow in a state where the air blower (F) The exhaust of the pollutant becomes smooth by the exhaust passage of the city apartment house.

In the present invention, since the outflow-side connecting duct D2 includes the heat insulating portion, the air containing the pollutants generated in the kitchen is separated from the inside of the exhaust passage P and the temperature of the kitchen air, Thereby preventing condensation from occurring on the outlet side connecting duct (D2). This prevents the generation of mold due to the occurrence of dew condensation on the outflow-side connecting duct (D2) and also prevents the condensation water from flowing into the indoor side.

In addition, the present invention is not installed in the cooking hood H located in the kitchen, but is installed on the side of the exhaust passage P to minimize the noise transmitted from the ventilator E to the kitchen, The cooker can cook in a quiet state.

C; Casing F; air blower
D1; Inlet side connecting duct D2; Outlet duct
100; A fan housing 200; Impeller
300; An impeller drive motor 400; Vane
500; Vane drive motor

Claims (7)

A casing having an inlet and an outlet;
A blower mounted inside the casing to generate a constant air flow rate;
An inlet duct connected to the inlet of the casing and connected to the exhaust duct of the cooking hood;
And an outflow-side connecting duct connected to the outlet side of the casing and having a heat insulating portion for preventing condensation,
The blower
A fan housing having two side inlets and a single outlet;
An impeller provided inside the fan housing to generate a flow;
An impeller driving motor for rotating the impeller;
A vane hinged to the center of the impeller downwardly of the fan housing discharge port to open and close the discharge port while being rotated around an axis of the lower portion;
A vane drive motor mounted on an outer surface of the fan housing to rotate the vane;
And a fixing unit for fixing the fan housing to the casing. The air conditioner according to claim 1, wherein the fan housing includes a body portion having a suction port on both sides thereof, the impeller being positioned therein, and an air outlet portion extending from one side of the body portion, And a hinge coupling portion provided at a lower portion of the discharge duct portion and hinged to the vane. The ventilation fan ventilation device according to Claim 1, [3] The apparatus according to claim 2, wherein an edge groove is formed on an end surface of the discharge duct portion to support the vane. The cooking stove as claimed in claim 1, wherein the vane is positioned in a horizontal state in the same direction as the flow direction of the air discharged through the discharge opening in a state where the vane opens the discharge opening, Separate condensation - proof ventilation air volume ventilation system. [2] The apparatus of claim 1, wherein the outflow-side connecting duct comprises an inner wall layer, an outer wall layer, and an intermediate wall layer positioned between the inner wall layer and the outer wall layer, Wherein the middle wall layer comprises a second material different from the first material. ≪ RTI ID = 0.0 > [10] < / RTI > [6] The apparatus according to claim 5, wherein the first material has a lower melting point than the second material, and the second material has a thermal conductivity lower than that of the first material. . [6] The apparatus according to claim 5, wherein the first material comprises polypropylene, and the second material comprises a silicon component.

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