KR101889819B1 - Roof ventilator - Google Patents

Abstract

The present invention relates to a roof ventilator which is mounted on a roof or the like to discharge polluted indoor air to the outside. The roof ventilator comprises an external casing, an internal rotation casing, an air suction unit, an air turning unit, a shaft fixing unit, and a motor fixing bracket. The roof ventilator significantly increases a polluted indoor air suction amount in each unit time by using all of a suction force generated by a principle of Bernoulli and another suction force generated by a motor to increase a suction amount and a discharge amount of polluted indoor air. Moreover, in spite of a back flow phenomenon of a fluid into which air flows from the outside, polluted air can be smoothly discharged, and the flowing air turns therein to more improve a flowing force and an exhaust amount of the air.

Description

Loop ventilator {ROOF VENTILATOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a roof ventilator mounted on a roof or the like for discharging polluted indoor air to the outside.

Generally, a roof ventilator is installed on a roof of a building such as a factory, an apartment, or the like, and discharges polluted air in the room quickly outdoors.

The roof ventilator uses the Bernoulli principle to discharge indoor air using the wind at a high flow rate passing through the upper part of the roof, and forcibly discharges the indoor air to the outside by using a power fan.

The roof ventilator performs ventilation for discharging polluted air to the outside or cooling for discharging high temperature air to the outside. Therefore, the loop ventilator is required to have a capability of discharging polluted indoor air to the outside in a short time.

As an example, Korean Utility Model No. 20-2008-0001163, ventilation device structure (open date: May 19, 2008), is installed on a wall of a building to forcibly introduce or exhaust air inside or outside to ventilate And a ventilation device structure which is mounted on a main body case of an electronic product or a computer to lower the internal temperature raised by heat generated in the product.

The ventilator structure includes a first fan shroud having a cooling fan and a second fan shroud surrounding the first fan shroud while being spaced apart from the first fan shroud.

Especially, since the auxiliary ventilation holes are provided between the first fan shroud and the second fan shroud, the peripheral pressure is lowered by the flow velocity of the air sucked or discharged by the fan through the ventilation hole inside the first shroud.

In other words, the ventilator structure has a structure in which the air is further moved through the auxiliary vents by the inner and outer pressure difference, thereby doubling the amount of air sucked or discharged so that the size and energy of the same fan are used, And has an effect of improving the suction or discharge capacity.

However, the ventilation device structure of Korean Utility Model No. 20-2008-0001163 exhausts hot air to the outside by using the Bernoulli principle through the first and second fan shrouds and the cooling fan, but the first and second Air is sucked only by the Bernoulli principle in the auxiliary ventilation holes formed between the fan shrouds. Therefore, in order to suck a large amount of air through the auxiliary ventilation holes, the pressure difference inside and outside the auxiliary ventilation holes must be increased. .

In addition, when the backflow phenomenon of the fluid flowing from the outside of the ventilation device to the inside of the ventilation device occurs due to various reasons, the ventilation device structure has a problem that the external fluid easily flows into the auxiliary ventilation hole, .

Korean Utility Model No. 20-2008-0001163, Structure of Ventilation Device, Disclosure Date May 19, 2008

The present invention increases the suction amount and discharge amount of contaminated indoor air by greatly increasing the intake amount of indoor air polluted per unit time by using both the suction force by the Bernoulli principle and the suction force generated by the motor, The present invention provides a loop ventilator in which contaminated air can be smoothly exhausted even when a phenomenon occurs, and the inflow air is circulated and discharged to improve the oil input and exhaust amount of the air.

In one embodiment, the roof ventilator has an outer casing formed with a first opening larger than an area of a second opening formed in the upper portion, the first vent having a first inclined side surface; And a second inclined side surface disposed inside the outer casing through the first opening and defining a gap with respect to an inner surface of the first inclined side surface, An inner rotating casing having a smaller fourth opening formed therein; A motor disposed inside the inner rotary casing through the third opening, a connection shaft coupled to a rotation shaft of the motor, a connection shaft coupled to the connection shaft to allow fluid to flow from the third opening toward the fourth opening A first fan, a connecting member having one side connected to the connecting shaft and the other side connected to the inside rotating casing to rotate the inside rotating casing, and a connecting member disposed inside the outside casing and disposed outside the inside rotating casing, An air suction unit including a second fan coupled to the shaft and sucking fluid from the gap; A first revolving member formed on an inner surface of the outer casing to pivot the fluid sucked into the outer casing, a second revolving member formed on an outer surface of the inner rotating casing to pivot the fluid introduced into the gap, And a third pivoting member formed on an inner surface of the rotating casing to pivot the fluid introduced into the third opening; And a shaft fixing unit having one end fixed to the inner surface of the outer casing and the other end opposite to the one end fixed to rotate the upper end of the connection shaft, Wherein a lower end of the first inclined side surface and a lower end of the second inclined side surface are formed as a first gap and an upper end of the first inclined side surface and an upper end of the second inclined side surface are formed in a direction And a second gap smaller than the first gap.

The diameter of the first fan of the loop ventilator is formed to be half of the diameter of the first opening to increase the flow rate of the fluid.

The second fan of the roof ventilator is provided with a connecting member connected to the connecting shaft and a fan member formed at an end of the connecting member and formed in a size smaller than a corresponding gap between the first inclined side surface and the second inclined side surface, .

The loop ventilator further includes a motor fixing bracket for fixing the motor to a lower end of the outer casing.

The loop ventilator according to the present invention increases intake amount and discharge amount of polluted indoor air by increasing the intake amount of indoor polluted air per unit time by using both the suction force by the Bernoulli principle and the suction force generated by the motor, So that it is possible to smoothly exhaust the polluted air, and the introduced air can be circulated in the interior to improve the oil input and exhaust amount of the air.

1 is an assembled cross-sectional view of a roof ventilator according to an embodiment of the present invention.
Fig. 2 is a disassembled cross-sectional view of the outer casing from the loop ventilator of Fig. 1; Fig.
3 is an exploded cross-sectional view of the inner rotating casing and the air suction unit of Fig. 1; Fig.

BRIEF DESCRIPTION OF THE DRAWINGS The invention, which is set forth below, may be embodied with various changes and may have various embodiments, and specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail.

It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Also, the terms first, second, etc. may be used to distinguish between various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

1 is an assembled cross-sectional view of a roof ventilator according to an embodiment of the present invention. Fig. 2 is an exploded cross-sectional view of the outer casing from the loop ventilator of Fig. 1; 3 is an exploded cross-sectional view of the inner rotating casing and the air suction unit of Fig. 1; Fig.

1 to 3, the roof ventilator 800 includes an outer casing 100, an inner rotating casing 200, an air suction unit 300, an air swing unit 400, and a shaft fixing unit 500 . In addition, the loop ventilator 800 may further include a motor fixing bracket 600.

The outer casing (100) is formed into a hollow cylindrical shape. A first opening 110 is formed in a lower portion of the outer casing 100 and a second opening 120 is formed in an upper portion of the outer casing 100 opposite to a lower portion of the outer casing 100.

In one embodiment of the present invention, the outer casing 100 may be made of a metal material, but may be made of a synthetic resin or the like.

The first opening 110 of the outer casing 100 having a cylindrical shape is formed with a first diameter D1 and the second opening 120 is formed with a first diameter D1, (D2) smaller than the first diameter D2.

The outer casing 100 has a first inclined side surface 130 which is inclined due to the difference in the diameters of the first opening 110 and the second opening 120.

The contaminated air or heated air flows into the first opening 110 of the outer casing 100 and the contaminated or heated air is discharged through the second opening 120 of the outer casing 100.

In an embodiment of the present invention, since the diameter of the second opening 120 is smaller than the first opening 110 of the outer casing 100, more air can be introduced into the first opening 110, Air can be vented to the opening 120 more quickly.

The inner rotating casing (200) is formed in a shape that is flush with the outer casing (100).

The inner rotating casing 200 is formed with a third opening 210 having a smaller area than the first opening 110 and having an area smaller than that of the second opening 120 on the inner rotating casing 200 A fourth opening 220 is formed.

Due to the difference in diameter of the third opening 210 and the fourth opening 220, the inner rotary casing 200 has the inclined second inclined side surface 230.

The inner rotating casing 200 is disposed inside the outer casing 100 through the first opening 110 of the outer casing 100 and the central axis of the outer casing 100 and the center of the inner rotating casing 200 The axes are aligned identically.

In one embodiment of the present invention, the outer casing 100 is fixed to the structure while the inner rotating casing 200 is radially rotated about the central axis within the outer casing 100.

A gap 150 is formed between the first inclined side face 110 of the outer casing 100 and the second inclined side face 210 of the inner rotating casing 200. In this case,

Specifically, the gap 150 at the lower end of the first oblique side face 110 and the second oblique side face 210 is formed as a first gap G1, and the upper end of the first oblique side face 110 and the second oblique side face 210 are formed with a second gap G2 that is smaller than the first gap G1.

By forming the first gap G1 and the second gap G2 different from each other as described above, more air can be introduced through the first gap G1, and air can be supplied to the second gap G1 It can be discharged quickly.

The air suction unit 300 sucks air through the first opening 110 of the outer casing 100 and the third opening 210 of the inner rotating casing 200 and then the second opening of the outer casing 100 120 and the fourth opening 220 of the inner rotating casing 200.

The air suction unit 300 includes a motor 310, a connecting shaft 320, a first fan 330, a connecting member 340 and a second fan 350.

The motor 310 is a device for converting electric energy into rotational energy. Various motors capable of forward rotation and reverse rotation and capable of controlling the rotational speed per minute (RPM) can be used.

The motor 310 is disposed inside the inner rotary casing 200 through the third opening 210.

1, the loop ventilator 800 may further include a motor fixing bracket 600 to fix the motor 310 to a predetermined position in an embodiment of the present invention.

One end of the motor fixing bracket 600 is coupled to the inner side of the outer casing 100 and the other end opposite to the one end of the motor fixing bracket 600 is coupled to the motor 310, And is firmly coupled to the outer casing 100 through the bracket 600. The motor fixing bracket 600 may be formed in various shapes that do not hinder the suction of air, for example.

The connecting shaft 320 is connected to the rotating shaft of the motor 310 and rotates together with the rotating shaft of the motor 310 of the connecting shaft 320. The connecting shaft 320 passes through the center of the fourth opening 220 of the inner rotating casing 200 and the connecting shaft 320 is disposed in parallel with the axis of the motor 310.

The first fan 330 is disposed inside the inner rotating casing 200 and is coupled to the connecting shaft 320 and rotated together with the connecting shaft 320.

In an embodiment of the present invention, the first fan 330 sucks indoor air contaminated into the inside rotating casing 200.

The air introduced into the third opening 210 of the inner rotary casing 200 through the first fan 330 flows through the fourth opening 220 of the inner rotary casing 200 by the shape of the inner rotary casing 200 .

The diameter D3 of the first fan 330 is larger than the diameter D3 of the first opening 110 of the outer casing 100 to increase the amount of air polluted by the first fan 330, (D1).

The connecting member 340 serves to fix the inner rotating casing 200 to the connecting shaft 320.

One end of the connecting member 340 is fixed to the inner rotating casing 200 and the other end opposite to the one end of the connecting member 340 is fixed to the connecting shaft 320, The rotary casing 200 is rotated inside the outer casing 100.

In order to prevent or suppress the vibration of the inner rotary casing 200 due to the high-speed rotation of the inner rotary casing 200, at least two connecting members 340 are provided in the inner rotary casing 200 and the connection And may be coupled to the shaft 320.

The first fan 330 disposed inside the inner rotating casing 200 quickly provides air to the outer casing 100 and includes a gap 150 formed between the outer casing 100 and the inner rotating casing 200, The relatively low pressure is formed by the Bernoulli principle, and the contaminated air is additionally introduced into the gap 150.

The amount of air flowing into the gap 150 is proportional to the speed of the air discharged from the fourth opening 220 of the inner rotary casing 200, but when the gap 150 is too wide, the inflow efficiency of the amount of air flowing into the gap 150 When the air flows back to the outer casing 100, air that has flowed back through the gap 150 can be introduced into the room.

In an embodiment of the present invention, the connection shaft 320 is provided with a second fan (not shown) to increase the amount of air that flows into the gap 150 to be discharged and smoothly discharges air even if air flows back through the outer casing 100 350 are coupled.

The second fan 350 is disposed inside the outer casing 100 and disposed outside the inner rotating casing 200.

The second fan 350 is selectively formed only at a position corresponding to the outer gap 150 of the inner rotating casing 200 to attract air from the gap 150 to increase the amount of air flowing into the gap 150, Thereby preventing air from flowing backward into the gap 150 from the outside.

The second fan 350 includes a coupling member 352 and a fan member 354.

The coupling member 352 is formed in a columnar shape and one end of the coupling member 352 is coupled to the coupling shaft 320. In an embodiment of the present invention, a plurality of coupling members 352 may be coupled to the coupling shaft 320 in a radial manner.

The fan member 354 is formed at the other end opposite to the one end of the engaging member 353 and the fan member 354 may include a rotor blade that sucks air by rotation.

The width of the rotor blades constituting the fan member 354 is made, for example, such that the fan member 354 contacts the outer casing 100 and is not interfered with. A part of the fan member 354 is disposed inside the gap 150 and a part of the fan member 354 is disposed outside the gap 150 to improve the air suction efficiency of the fan member 354 have.

Since the end of the connecting shaft 320 on which the second fan 350 is mounted can be severely flowed by the rotation of the connecting shaft 320, the end of the connecting shaft 320 is fixed by the shaft fixing unit 500 And is rotatably fixed.

One end of the shaft fixing unit 500 is fixed to the inner surface of the outer casing 100 and the other end opposite to the one end of the shaft fixing unit 500 is fitted to the connection shaft 320, It is possible to prevent the connection shaft 320 from flowing or generating vibration from the connection shaft 320. In one embodiment of the present invention, the shaft fixing unit 500 may include a bearing coupled with the connecting shaft 320.

On the other hand, in order to vigorously circulate the air introduced into the inner rotating casing 200 and the outer casing 100 through the air suction unit 300 to discharge the air from the outer casing 100 more quickly, the loop ventilator 800 And an air swing unit (400).

The air swing unit 400 includes a first swing member 410, a second swing member 420, and a third swing member 430.

A plurality of first revolving members (410) are formed on the inner peripheral surface of the outer casing (100). The first pivoting member 410 is formed by arranging a band in a spiral shape on an inner circumferential surface of the outer casing 100 so that the first pivoting member 410 pivots the introduced air inside the outer casing 100.

A plurality of second revolving members 420 are formed on the outer circumferential surface of the inner rotating casing 200. The second revolving member 420 is formed by arranging a band in a form of a spiral in an inclined manner on the outer peripheral surface of the inner rotary casing 200.

As the inner rotating casing 200 is rotated at a high speed, the second rotating member 420 rotates the air introduced into the gap 150 between the inner rotating casing 200 and the outer casing 100.

A plurality of third swing members 430 are formed on the inner peripheral surface of the inner rotating casing 200. The third rotating member 430 is formed by arranging a band in a form of a spiral in an inclined manner on the inner circumferential surface of the inner rotating casing 200.

As the inner rotating casing 200 is rotated at a high speed, the third rotating member 430 rotates the air introduced into the inner rotating casing 200 and provides the air to the outer casing 100.

In one embodiment of the present invention, the first to third revolving members 410, 420, and 430 can improve the swirling force of the outside air by turning all the externally provided air in the same direction.

The air pivoted by the first to third revolving members 410, 420, and 430 is quickly discharged from the outer casing 100 while rotating inside the outer casing 100.

As described in detail above, by using the suction force generated by the Bernoulli principle and the suction force generated by the motor, the amount of indoor air polluted air per unit time is greatly increased to increase the suction amount and discharge amount of contaminated indoor air, So that it is possible to smoothly exhaust the contaminated air, and it is possible to improve the oil input and exhaust amount by circulating the introduced air inside.

It should be noted that the embodiments disclosed in the drawings are merely examples of specific examples for the purpose of understanding, and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

100 ... outer casing 200 ... inner rotating casing
300 ... air intake unit 400 ... air circulation unit
500 ... Axis fixing unit 600 ... Motor fixing bracket

Claims (4)

An outer casing having an area of a first opening formed at a lower portion thereof larger than an area of a second opening formed at an upper portion thereof and having a first inclined side face;
And a second inclined side surface disposed inside the outer casing through the first opening and defining a gap with respect to an inner surface of the first inclined side surface, An inner rotating casing having a smaller fourth opening formed therein;
A motor disposed inside the inner rotary casing through the third opening, a connection shaft coupled to a rotation shaft of the motor, a connection shaft coupled to the connection shaft to allow fluid to flow from the third opening toward the fourth opening A first fan, a connecting member having one side connected to the connecting shaft and the other side connected to the inside rotating casing to rotate the inside rotating casing, and a connecting member disposed inside the outside casing and disposed outside the inside rotating casing, An air suction unit including a second fan coupled to the shaft and sucking fluid from the gap;
A first revolving member formed on an inner surface of the outer casing to pivot the fluid sucked into the outer casing, a second revolving member formed on an outer surface of the inner rotating casing to pivot the fluid introduced into the gap, And a third pivoting member formed on an inner surface of the rotating casing to pivot the fluid introduced into the third opening; And
And a shaft fixing unit for fixing one end of the connection shaft to the inner side of the outer casing and the other end of the shaft opposite to the one end for rotation,
The first to third pivot members are formed in a direction to pivot the introduced fluid in the same direction,
Wherein a lower end of the first inclined side face and a lower end of the second inclined side face are formed as a first gap and an upper end of the first inclined side face and an upper end of the second inclined side face are formed as a second gap smaller than the first gap And,
The second fan is formed at the end of the connecting member and connected to the connecting shaft so as to exhaust air in the gap even if air flows back in the direction toward the gap through the outer casing, And a fan member formed in a size smaller than a gap corresponding to the gap between the second oblique side surfaces,
Wherein a portion of the fan member of the second fan is disposed within the gap to improve air intake efficiency of the air within the gap by the fan member and a portion of the fan member is located on the outside of the gap, The writer. The method according to claim 1,
Wherein the diameter of the first fan is about half the diameter of the first opening to increase the flow rate of the fluid. delete The method according to claim 1,
And a motor fixing bracket for fixing the motor to the lower end of the outer casing.

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