KR20220149868A - Apparatus for controllng fluid flow and damper comprising the same - Google Patents

Abstract

An objective of the present invention is to provide a flow control device and a damper including the flow control device capable of efficiently controlling the flow rate even at the initial stage of opening the damper. According to the present invention, a flow control device of a damper comprises: a regulator disposed between two adjacent blades and controlling the amount of fluid passing between the two blades. The regulator is configured such that each end of the two blades is disposed toward the rotating side from between the ends of the two blades so as to block a part of a space between the two blades when the two blades rotate.

Description

Flow control device and damper including same

The present invention relates to a flow control device and a damper including the same, and to a flow control device for controlling a flow rate of a fluid and a damper including the same.

A damper is a generic term for a moving wing structure that has a function of controlling or blocking the amount of fluid (air, exhaust gas, etc.) flowing in a duct or air conditioner.

Dampers are used in various ways in various forms, and depending on the purpose of use, fire dampers that completely block the flow of air and volume dampers that supply the desired amount of air by controlling the flow of air are representative. According to the structure of the duct, it can be divided into round and square shapes.

In the case of a volume damper that controls the flow of air in a double square duct, the initial point of time when the damper's control blade starts to open forms a higher pressure ratio than when it is fully opened. phenomenon occurs.

For this reason, in controlling a low air volume, even if the damper opening rate is low, a large change in the air volume occurs and thus an efficient control cannot be achieved.

Republic of Korea Patent Publication No. 10-2020-0142733

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a flow rate control device that efficiently controls the flow rate even at the initial stage of opening of the damper, and a damper including the same.

In order to achieve the above object, the damper flow control device according to the present invention includes a regulator disposed between two adjacent blades and configured to control the amount of fluid passing between the two blades. The adjuster is disposed from between the ends of the two blades to the side where each of the ends of the two blades rotate, so that when the two blades rotate, the fluid passes through a portion of the space between the two blades. is composed

Here, the regulator has a side portion having a curved structure formed along the rotation route of each of the adjacent ends of the two blades, and the side portion includes a passage portion through which the fluid passes and a blocking portion for blocking the passage of the fluid. .

In this case, the blocking portion may be tapered toward the rotational direction of the blade.

As an example, the blocking portion may be formed in a triangular structure in which the width becomes narrower in the rotational direction of the blade.

A plurality of the blocking parts may be disposed along the axial direction of the blade, and the passing part may be disposed between the plurality of blocking parts.

Here, in the plurality of blocking units, a relatively wide extended end of the blocking unit may be connected by a first connection frame, and a relatively narrow tip end may be connected by a second connection frame.

In this case, the first connection frame may be disposed between the ends of the two blades facing each other.

Meanwhile, the blade may be a blade of an opposing blade damper.

In this case, the adjuster includes one side plate having the side part disposed on one side and the other side plate having the side part disposed on the other side, wherein the one side plate and the other side plate are at the ends of the two blades, respectively. It may be made of a structure in which the separation distance increases toward the rotating side.

On the other hand, according to another aspect of the present invention, a plurality of blades arranged to be spaced apart from each other and configured to adjust the flow rate of the fluid while rotating; a driving unit for rotating the blade; And a plurality of the flow control device of any one of claims 1 to 9 disposed between the blades; a damper comprising a can be provided.

The present invention is a regulator configured to block the passage of fluid to a part of the space between the two blades when the two blades rotate by being arranged from between the ends of the two blades to the side where each of the ends of the two blades rotate By including, it has the effect of precisely controlling the flow rate when the damper is initially opened.

Specifically, in the present invention, since the regulator includes a blocking part having a tapered structure toward the ends of the two blades in the rotational direction, the change in air volume is made constant even when the opening rate of the damper is low, so that when the damper is initially opened, As the flow rate can be controlled more precisely, it is possible to efficiently control the flow rate. It has the advantage of being able to

Figure 1 (a) shows a parallel wing type damper, Figure 1 (b) is a cross-sectional view showing an opposing wing type damper.
Fig. 2(a) shows the flow rate curve according to the opening rate of the parallel-wing damper of Fig. 1(a), and Fig. 2(b) is a graph showing the flow rate curve according to the opening rate of the opposing-wing type damper of Fig. 1(b). to be.
3 is a view showing a flow control device for a damper according to the present invention.
FIG. 4 is a view showing that the damper is completely closed while the flow control device of the damper of FIG. 3 is disposed between the plurality of blades.
FIG. 5 is a view showing that the damper of FIG. 4 is initially opened.
FIG. 6 is a view showing that the damper of FIG. 5 is fully opened.
7 is a view showing a process until the damper is initially opened as in FIG. 5 .

Hereinafter, preferred embodiments will be described in detail so that those of ordinary skill in the art can easily practice the present invention with reference to the accompanying drawings. However, in describing a preferred embodiment of the present invention in detail, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the same reference numerals are used throughout the drawings for parts having similar functions and functions. In addition, in this specification, terms such as 'upper', 'upper', 'upper surface', 'lower', 'lower', 'lower surface', 'side', etc. are based on the drawings, and in fact, the components are arranged It may vary depending on the direction you are going.

In addition, throughout the specification, when a part is 'connected' with another part, it is not only 'directly connected' but also 'indirectly connected' with other components interposed therebetween. also includes In addition, 'including' a certain component means that other components may be further included, rather than excluding other components, unless otherwise stated.

Figure 1 (a) shows a parallel wing type damper, Figure 1 (b) is a cross-sectional view showing an opposing wing type damper.

Referring to the drawings, the volume damper can be divided into two types according to the rotation direction of the blade (damper blade) B.

First, the air volume control damper shown in FIG. 1(a) is a parallel blade damper rotating in one direction, and since the neighboring blades B are configured to rotate in the same direction, the damper is closed In the process from (Full Close) to open (initial opening), the pressure difference of the fluid is large and the amount of change in the area through which the fluid passes is large, so the flow rate changes rapidly, which is more severe as the size of the damper increases.

In addition, the air volume control damper shown in FIG. 1 (b) is an opposed blade damper rotating in different directions, and since the blades (B) adjacent to each other rotate in opposite directions, it is configured to rotate in one direction. , It is easier to control the flow rate compared to the parallel wing type damper, but there is a limitation in that it is difficult to control the low orbit (initial opening) fine flow rate in the industrial damper with a large size of the damper.

Fig. 2(a) shows the flow rate curve according to the opening rate of the parallel-wing damper of Fig. 1(a), and Fig. 2(b) is a graph showing the flow rate curve according to the opening rate of the opposing-wing type damper of Fig. 1(b). to be. (For reference, α in the drawing is a value indicating the size of the damper in an arbitrary ratio, and the larger this value, the larger the size of the damper)

Referring to the drawings, in the air flow control damper, it is possible when the opening rate (Stroke) and the air flow (Air Flow) are linearized in order to obtain accurate flow control.

In other words, in the wind volume control damper, as the curve representing the opening rate and the air volume is not a non-linear curve with an irregular rate of change, but a linear curve with a relatively regular rate of change, that is, the closer to a straight line, the more accurate the flow rate control can be performed.

Therefore, in order to approximate the linear curve, the size of the parallel-wing damper must be adjusted to supply a larger pressure drop, which inevitably increases the operating cost of the supply fan. should be applied to increase the air volume control effect.

However, in dampers such as industrial boilers and large air conditioners where the size of the damper is inevitably increased, it is very difficult to obtain a linear curve even for an opposing-wing type damper.

The inability to control the linear curve means that low load operation cannot be guaranteed in a device to which a high turndown ratio is applied, and it can be said that stable operation of the device is impossible. .

Therefore, in order to linearize the flow control of the volume damper, measures to reduce the excessive flow rate in the low orbit (initial opening) are required.

To implement this measure, the present invention provides a regulator 100 for further regulating the flow rate between the two blades B.

3 is a view showing a flow control device for a damper according to the present invention.

In addition, FIG. 4 is a view showing that the damper is completely closed with the flow control device of the damper of FIG. 3 disposed between the plurality of blades, and FIG. 5 is a view showing that the damper of FIG. 4 is initially opened, FIG. 6 is a view showing that the damper of FIG. 5 is fully opened.

Referring to the drawings, the damper flow control device according to the present invention includes a regulator 100 .

The controller 100 is disposed between the two adjacent blades (B), and controls the amount of fluid passing between the two blades (B).

Specifically, the adjusting body 100 is disposed from between the ends Ba of the two blades B facing each other toward the side in which the blade B rotates.

That is, the control body 100 has a structure in which one end is disposed between the ends Ba of the two blades B, and the two blades B are extended toward the rotating side.

This regulator 100 is configured to block the passage of fluid for a portion of the space between the two blades B when the two blades B rotate, and accordingly, during the course of the rotation of the two blades B, especially It enables fine flow control at the beginning of opening.

For reference, although not shown in the drawings, the adjuster 100 may be installed and fixed to the inner wall of the passage in which the damper is installed.

More specifically, the control body 100 has a side portion 110 of a curved structure formed along the rotation route of each of the adjacent ends Ba of the two blades (B).

That is, one side part 110 of the controller 100 has a curved structure along the rotation route of one end of the two blades B, and the other side part 110 of the controller 100 has two It is formed in a curved structure along the rotation route of the other end of the blade (B).

Due to this, one side of the two blades (B) is disposed along the route where one of the two blades (B) rotates and the side part 110 of the regulator 100 is opened, so that one blade (B) is opened while rotating. The open part is covered by one side part 110 of the adjusting body 100 .

In addition, by disposing the other side side part 110 of the regulator 100 along the route where the other one of the two blades B rotates and opens, the other one blade B rotates and opens. The open part is covered by the other side part 110 of the adjusting body 100 .

For reference, as the adjacent ends Ba of the two blades B rotate as close as possible to the extent that they almost touch the side surface 110 of the controller 100 while rotating, the ends Ba and the controller ( The fluid hardly flows through the gap between the side surfaces 110 of 100).

The side portion 110 of such a curved structure is configured to allow the fluid to pass through only a portion thereof.

Specifically, the side portion 110 of the regulator 100 includes a passage portion 111 through which the fluid passes and a blocking portion 112 for blocking the passage of the fluid.

The passing part 111 is an open part to allow the fluid to pass through, and the blocking part 112 is a closed part to prevent the fluid from passing therethrough.

As the flow rate is blocked in a certain part (passing part 111), the regulator 100 having such a side part 110 can reduce the excessive flow flow made in the low orbit (initial opening) during the rotation process of the blade B. have.

On the other hand, the blocking portion 112 may take a structure tapered toward the rotational direction of the blade (B).

As an example, the blocking portion 112 may be formed in a triangular structure in which the width of the side portion 110 becomes narrower in the rotational direction of the blade B.

At this time, the triangular structure means that it appears as a triangular shape when viewed from the lateral direction, that is, has a triangular shape on the side view, and substantially has a curved shape in which both sides of the triangle correspond to the curved structure of the side part 110 . can

By the blocking part 112 formed in such a tapered structure, the flow rate of the fluid can be precisely controlled when the damper is initially opened.

Furthermore, a plurality of blocking parts 112 of the adjusting body 100 are disposed along the axial direction of the blade B, and a structure in which a passing part 111 is disposed between the plurality of blocking parts 112 can be achieved. .

Here, in the plurality of blocking portions 112, the relatively wide extended end 112a of the blocking portion 112 is connected by the first connecting frame 121, and a relatively narrow tip portion 112b. may take a structure connected by the second connection frame 122 .

In this case, the first connection frame 121 may be disposed between the ends Ba of the two blades B facing each other.

On the other hand, the above-described blade (B) of the damper on which the regulator 100 of the present invention is disposed may be a blade (B) of the opposing-wing type damper, which is the flow rate of the regulator 100 of the present invention compared to the parallel-wing type damper. This is because the flow rate control efficiency can be maximized by being used for the easy-to-control opposing-wing damper.

As such, when the adjuster 100 is applied to the opposing wing type damper as shown in the drawing, the adjuster 100 includes a side plate P1 having a side part 110 disposed on one side, and a side part disposed on the other side ( It may include the other side plate (P2) having 110).

At this time, each of the one side plate P1 and the other side plate P2 has a link bar 123 disposed at an end thereof in the longitudinal direction, and the first connecting frame 121 and the second connecting frame 122 have a link bar ( 123) is linked.

And the one side plate (P1) and the other side plate (P2), the end (Ba) of each of the two blades (B) may take a structure in which the separation distance increases toward the rotating side.

Furthermore, although not shown in the drawings, the present invention is a structure in which one side plate (P1) and the other side plate (P2) of the regulator 100 are connected without being spaced apart from each other, and the space between them is filled to take an integrated structure, Specifically, the blocking part 112 of the side part 110 on one side plate P1 and the blocking part 112 of the side part 110 on the other side plate P2 are connected to form an integrated structure, and one side plate P1 The passing part 111 of the side part 110 in the side plate P2 and the passing part 111 of the side part 110 in the other side plate P2 may be connected to take a single hole structure.

Specifically, a process in which the flow rate is precisely controlled when the damper is initially opened by the regulator 100 of the present invention configured as described above will be described with reference to FIG. 7 as follows.

Specifically, in FIG. 7 , a process until the initial opening of the damper is completed is sequentially shown from top to bottom. For reference, in each of the three drawings included in FIG. 7 , the passage range of the fluid with respect to the regulator 100 disposed in each of the parts (A) and (B) is shown.

In the first diagram at the top, the damper is in a fully closed state and the blade B is in a state before rotation, at which time the first of the adjuster 100 is placed between the adjacent ends Ba of the two blades B. As the connection frame 121 is sandwiched, the fluid does not pass through the damper.

In the second drawing from the top, the damper is just opened and the blade B is rotated by about 15%, and at this time, the ends Ba of the two blades B are connected to the blocking part ( In the process of rotating to the extent between the extended end 112a and the tip 112b of the 112, the fluid can pass from the passage portion 111, which gradually increases in area, to an area of intermediate height.

In the third drawing from the bottom, in a state in which the initial opening of the damper is completed and the blade B is rotated by about 30%, at this time, the ends Ba of the two blades B are blocked by the adjuster 100 . Since the tip portion 112b of the portion 112 is rotated, the fluid can pass through the entire area of the passage portion 111 .

An effective aspect of the present invention configured as described above will be described as follows.

Looking at the pressure difference of the fluid with reference to the damper, at the initial stage of opening the damper by rotating the blade (B), a higher pressure difference is formed than when the damper is fully opened, so that the fluid excessively passes. In the present invention, by preventing this by the tapered structure of the blocking part 112 , it is possible to more precisely control the flow rate of the fluid when the damper is initially opened.

That is, in the damper according to the prior art, in controlling a low air flow rate, even if the opening rate of the damper is low, a large amount of change in the air volume occurs, so that efficient control cannot be achieved. Since the blocking part 112 of the tapered structure is configured in the rotational direction of the silver blade B, it is possible to more precisely control the flow rate of the fluid when the damper is initially opened.

On the other hand, the damper according to another aspect of the present invention, although not shown in the drawings, includes a blade, a driving unit, and the above-described flow control device.

At this time, the blades are arranged in the passage of the fluid and rotate to adjust the flow rate of the fluid, and a plurality of blades are arranged to be spaced apart from each other.

In addition, the driving unit rotates the blade, for example, a motor may be utilized.

In addition, the flow control device is disposed between the plurality of blades, the specific configuration will be omitted because it has been described above.

As a result, the present invention is arranged from between the ends Ba of the two blades B to the side where each of the ends Ba of the two blades B rotates, so that the two blades B are rotated when the two blades B are rotated. By including the regulator 100 configured to block the passage of fluid for a portion of the space between the blades B, it is possible to precisely control the flow rate when the damper is initially opened.

Specifically, according to the present invention, the control body 100 includes the blocking part 112 of the tapered structure toward the ends Ba of the two blades B in the rotational direction, so that the air flow rate is low even when the damper opening rate is low. As the flow rate of the fluid can be controlled more precisely when the damper is initially opened because the change of Load operation can be reliably ensured to ensure stable operation of the equipment.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains will realize that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. You will understand. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

B : Blade Ba : (of the blade) end
100: control body 110: side part
111: passing part 112: blocking part
112a: extended end 112b: tip
P1: one side plate P2: other side plate
121: first connection frame 122: second connection frame
123: link bar

Claims (10)

It is disposed between two adjacent blades, and includes a regulator for controlling the amount of fluid passing between the two blades,
The adjuster is disposed from between the ends of the two blades to the side where each of the ends of the two blades rotate, so that when the two blades rotate, the fluid passes through a part of the space between the two blades A flow control device of the damper configured to do so.
According to claim 1,
The regulator has a side portion of a curved structure formed along the rotation route of each of the adjacent ends of the two blades,
The side portion of the damper flow control device, characterized in that it comprises a passage portion through which the fluid passes and a blocking portion for blocking the passage of the fluid.
3. The method of claim 2,
The flow control device of the damper, characterized in that the blocking portion is tapered toward the rotational direction of the blade.
4. The method of claim 3,
The blocking portion is a flow control device for a damper, characterized in that the width is formed in a triangular structure that becomes narrower in the rotational direction of the blade.
4. The method of claim 3,
A plurality of blocking portions are disposed along the axial direction of the blade, and the passage portion is disposed between the plurality of blocking portions.
6. The method of claim 5,
A plurality of the blocking unit,
A flow control device for a damper, characterized in that a relatively wide extended end of the blocking portion is connected by a first connecting frame, and a relatively narrow tip is connected by a second connecting frame.
7. The method of claim 6,
The first connection frame is a flow control device for a damper, characterized in that disposed between the ends of the two blades facing each other.
3. The method of claim 2,
The blade is a flow control device for a damper, characterized in that the blade of the opposing blade damper.
9. The method of claim 8,
The adjuster includes one side plate having the side part disposed on one side, and the other side plate having the side part disposed on the other side,
The one side plate and the other side plate, the flow rate control device of the damper, characterized in that made of a structure in which the separation distance increases toward the rotating side of each of the ends of the two blades.
a plurality of blades disposed to be spaced apart from each other and configured to rotate and adjust the flow rate of the fluid;
a driving unit for rotating the blade; and
The flow control device of any one of claims 1 to 9 disposed between the plurality of blades;
damper including.

Images