KR101148109B1 - Flow meter - Google Patents

Abstract

The present invention includes an inlet formed so that the bypassed fluid is introduced into the inside, an outlet formed so that the fluid introduced through the inlet flows out, and a main body having a groove formed in the left and right directions, and the inlet and the outlet are A flow meter configured to communicate with the groove, the bypass holder being inserted into the groove and having a tube inserted therein, a fitting installed at an inlet side of the groove, and a bellows assembled between the bypass holder and the fitting. It is about.

Description

Flow meter {Flow meter}

The present invention relates to a flow meter for precisely measuring the mass flow rate of the fluid flowing through the flow path.

[Prior Art Document] Korea Patent Publication 10-2008-0018003

As shown in FIG. 1 or FIG. 2, a conventional flow meter includes a main body 200, a groove h formed in the main body 200, and a fitting inserted into the groove 11 formed in the main body 200. 150 and a bypass thread 190 is formed on the outside and the tube 192 is inserted into the groove 12 to be inserted into the groove 12.

The main body 200 has an inlet 141 through which the bypassed fluid flows, an outlet 142 through which the inflowed fluid flows out, and the groove h includes the first groove 11 and the second groove 12. It further comprises of.

The inner side of the bypass holder 190 has a hexagonal groove portion is formed so that the tube is inserted, tapered to the hexagonal groove portion, the inner tube 192 was press-fitted.

The above structure has a problem in that the tapering process in the hexagonal groove portion in the process of fixing the tube 192 inside the bypass holder 190 is expensive.

The following relates to a description of the flow meter with the above structure improved.

The hexagonal groove portion formed inside the bypass holder (not shown) was made parallel, and the outer taper formed on the outer edge was held in the inward direction to hold the tube (not shown).

In the above structure, the bypass holder (not shown) is inserted into the groove (not shown) by fitting so that it is difficult to separate each component.

The present invention has been made to solve the above problems, and an object thereof is to provide a flow meter which can reduce the processing cost by using a simple bellows manufacturing process and can accurately measure the flow rate.

The flow meter of the present invention for achieving the above object includes an inlet formed so that the bypassed fluid is introduced into the inside, and an outlet formed so that the fluid introduced through the inlet flows to the outside, the groove is formed in the left and right directions The main body, the inlet and outlet are configured to communicate with the groove, the bypass holder is inserted into the groove and the tube is inserted therein, the fitting is installed on the inlet side of the groove, the bypass holder and the fitting It includes a bellows assembled between, characterized in that the hole formed in the interior of the bellows to communicate with the inlet.

In addition, in the flow meter of the present invention, the inner peripheral surface of the groove is formed in parallel, the outer peripheral surface of the bypass holder is formed in parallel so that the bypass holder is coupled to one side of the groove, between the fitting and the bypass holder The spacer having a through hole formed therein is inserted, and a filter is inserted between the bellows and the spacer.

According to the flowmeter as described above, the following effects are obtained.

The present invention can easily disassemble and assemble each component can shorten the assembly time.

It can also be secured by pushing the bypass holder using a bellows that acts as a spring.

In addition, a spacer may be inserted between the fitting and the bypass holder to minimize friction of the cross section of the bellows while the fitting rotates during fitting assembly.

In addition, by inserting a filter between the spacer and the bellows to maximize the foreign matter blocking effect is good for maintaining the sensor performance, it can be a great help in the laminar flow of the most important fluid in the flowmeter performance.

1 is a cross-sectional view of a combined flow meter according to the prior art.
Figure 2 is a cross-sectional view of a flow meter separation according to the prior art.
3 is a cross-sectional view of a flow meter in accordance with a preferred embodiment of the present invention.
4 is a cross-sectional view of a flow meter separation in accordance with a preferred embodiment of the present invention.
5 is an exploded perspective view of a flow meter according to a preferred embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, and the same parts as in the prior art will be referred to the related art, and detailed description thereof will be omitted.

As shown in FIG. 3, the main body 100 has a long groove h formed in the left and right longitudinal directions.

The groove h is composed of a first groove 1, a second groove 2, and a third groove 3.

The first groove 1 is formed at an inlet side of the groove h to be inclined.

The first groove 1 is a place where the fitting 50 to be described later is inserted, and a thread is formed inside the first groove 1.

The second groove 2 is a passage connected to one side of the bypass holder 90 and a bellows 80 to be described later, which is connected to the third groove 3 to be described later, and an inner surface of the second groove 2 is It is configured in parallel.

The second groove 2 is preferably configured to have a smaller diameter than the first groove 1, and has a larger diameter than the third groove 3 to be described later.

An end portion 5 connecting the second groove 2 and the third groove 3 is formed between the second groove 2 and the third groove 3.

The end 5 is preferably recessed toward the upper direction of the main body 100 to form a groove.

The third groove 3 is formed to have a smaller diameter than the second groove 2 is configured to facilitate the assembly and separation of components to be described later.

The third groove 3 is located at the outlet side of the groove h, and is composed of a portion having a constant inner diameter and a semicircular shape at the right end.

The third groove 3 covers the outer circumferential surface of the bypass holder 90 to be described later.

The diameter of the third groove 3 is preferably smaller than the second groove (2).

In addition, a space is formed in the third groove 3 because the right end of the bypass holder 90 and the third groove 3 are spaced apart from each other.

An upper portion of the main body 100 is formed with an inlet port 41 through which the bypassed fluid flows in and an outlet port 42 through which the fluid introduced through the inlet port 41 flows out.

In addition, a passage 43 is formed at the right side of the third groove 3.

The inlet 41 and the outlet 42 communicate with the groove h, and the passage 43 is configured to communicate with the upper right of the groove h.

A fitting 50 is installed at the inlet side of the groove h, that is, the first groove 1.

The fitting 50 is connected to the first connecting portion 51 inserted into the inlet side of the third groove 3, the fixing portion 52 connected to the first connecting portion 51, and the fixing portion 52. It is composed of a second connecting portion (53).

Since the detailed structure of the fitting 50 is a conventional technology, a detailed description thereof will be omitted and reference will be made to patent documents of the prior art.

The inside of the fitting 50 has a hole (h) is formed to help the fluid flow into the bypass.

The first connection portion 1 is preferably in the shape of a hexagon to be fastened to the screw thread 6 of the first groove (1).

The screw is fastened to the hexagonal groove formed in the fixing portion (52).

The bypass holder 90 is inserted into the outlet side of the groove h, that is, the third groove 3.

The bypass holder 90 includes a first protrusion 90a having a large diameter and a second protrusion 90b having a smaller diameter than the first protrusion 90a. A groove 90c is formed between the first protrusion 90a and the second protrusion 90b.

The outer surface of the bypass holder 90 is formed in parallel, the bypass holder 90 is provided with a predetermined space inside the groove (h).

The first protrusion 90a has a cylindrical shape.

The outer surface of the second protrusion 90b and the inner surface of the third groove 3 are spaced apart from each other to form a space A.

The fluid flowing out to the outlet 42 through the space A is allowed to move to the outside.

In the present invention, the space of the bypass holder 90 is configured in a circular shape, but may be configured as a hexagonal groove portion.

A plurality of tubes 92 are inserted into the bypass holder 90.

The tube 92 is long in the form of a cylinder, and the inside is configured to form a hole.

The tube 92 is first inserted into the first protrusion 90a and configured to penetrate the second protrusion 90b.

 The tube 92 may be tightly inserted with a tolerance so as not to fall into the bypass holder 90.

In the present invention, since there is no screw structure for assembling the bypass holder 90, the effect of suppressing particle generation is great.

A bellows 80 is assembled between the bypass holder 90 and the fitting 50.

The bellows 80 is an assembly member that is easy to obtain, the manufacturing process is simple, and the price is very low.

The bellows 80 is installed in the groove h, that is, the second groove 2, close to the inlet 41.

The bellows 80 supports and fixes the pushing holder 90 while pushing the bypass holder 90 to a member having a plurality of wrinkles formed on an outer surface thereof.

Wrinkles formed on the outer surface of the bellows 80 serves as a spring.

That is, the bellows 90 is configured to have a large displacement while applying elastic force to the bypass holder 90 while elastically deforming.

By constructing the bellows 80 it is possible to fix the bypass holder 90 without being greatly affected by the dimensional difference between the products.

A hole 81 is formed inside the bellows 80.

The fluid introduced into the fitting 50 through the hole 81 may be configured to flow toward the inlet 41.

In the present invention, but the fluid to be moved to form a hole in the bellows 80 is configured to communicate with the inlet (41), any structure can be applied if the fluid can communicate with the inlet (41).

A spacer 60 having a through hole h formed therein is inserted between the fitting 50 and the bypass holder 90.

The space 60 is configured in the form of a disc.

When the spacer 60 is inserted between the fitting 50 and the bypass holder 90, and the fitting 50 is assembled, the fitting 50 may rotate and come into contact with the end surface of the bellows 80. Friction can be minimized.

A through hole h is formed at the center of the spacer 60.

The fluid introduced from the fitting 50 flows into the through hole h formed in the spacer 60.

A filter 70 is inserted between the bellows 80 and the spacer 60.

By configuring the filter 70 it can maximize the foreign matter blocking effect.

Inserting the filter 70 between the spacer 60 and the bellows can be of great help to the laminar flow of the fluid that is most important in the flowmeter's performance.

Referring to the operation according to the configuration of the present invention.

First, the fluid passes through the bypass in accordance with a hole h formed in the left and right directions inside the main body 100.

A portion of the fluid which in turn passes through the fitting 50 and the spacer 60 and the filter 70 is introduced into the inlet 41 through the hole 81 of the bellows 80.

The fluid flowing into the inlet 41 flows out through the space A and into the passage 43 while passing through the outlet 42.

While controlling the flow rate of the fluid from the inlet port 42, that is, the inlet port 41 and the outlet port 42, through which the fluid introduced into the inlet port 41 may be measured more accurately, the total flow rate may be measured. .

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or variations of the present invention without departing from the spirit and scope of the invention described in the claims below Can be carried out.

41: inlet 42: outlet 43: passage
50 fitting 60 spacer 61 through hole
70: filter 80: bellows 81: hole
90: bypass holder 92: tube 100: the body

Claims (2)

A main body including an inlet formed so that the bypassed fluid flows into the inside, and an outlet formed so that the fluid introduced through the inlet flows out;
The inlet and outlet are configured to communicate with the groove,
A bypass holder inserted into the groove and into which a tube is inserted;
A fitting installed at an inlet side of the groove;
And a bellows assembled between the bypass holder and the fitting.
A hole is formed in one side of the bellows, so that a portion of the fluid introduced into the fitting through the hole flows into the inlet. The method according to claim 1,
The inner circumferential surface of the groove is formed in parallel, the outer circumferential surface of the bypass holder is formed in parallel so that the bypass holder is coupled to one side of the groove,
A flowmeter, characterized in that a spacer having a through hole therein is inserted between the fitting and the bypass holder, and a filter is inserted between the bellows and the spacer.

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