KR200473576Y1 - Distribution guider for fluid distributor - Google Patents

Abstract

The present invention relates to a dispensing guide for a fluid dispenser to further enhance the dispensing efficiency of the fluid dispenser and significantly reduce noise.
The present invention relates to a body 1 embedded in a main body 10 of a fluid distributor in which a plurality of distribution holes 12 and 12 'for distributing a fluid to a fluid inlet 11 are formed, A plurality of guide holes (2, 2 ') formed in the guide holes (2, 2') for guiding the fluid to be evenly distributed and communicating with the distribution holes (12, 12 ' (3, 3 ') which protrude and intersect each other at the center of the body (1) to partition the guide holes (2, 2').

Description

{DISTRIBUTION GUIDER FOR FLUID DISTRIBUTOR}

The present invention relates to a dispensing guide for a fluid dispenser, and more particularly to a dispensing guide for a fluid dispenser that can further improve dispensing efficiency and significantly reduce noise in a fluid dispenser.

Generally, a refrigerating structure of an air conditioner that sucks hot air and exchanges heat with low-temperature refrigerant includes a compressor that compresses refrigerant into a gas state at a high temperature and a high pressure, a condenser that condenses into a liquid state by heat radiation, And a fluid distributor for distributing the refrigerant to the evaporator through the distribution pipe.

A fluid distributor for distributing the liquid / gaseous refrigerant (hereinafter, referred to as a fluid) distributes the fluid drawn from the inlet flow path through a plurality of distribution pipes, and various developments have been made to improve the distribution performance efficiently. The prior art of the distributor will be described in the following reference.

Reference 1 discloses a distributor having a distributing portion formed with a conical distributing projection at the center of a distributing portion for receiving and distributing the fluid from the inserting portion to uniformly distribute the fluid introduced from the inserting portion.

The fluid distributor 100 disclosed in Reference 1 divides the fluid introduced from the inlet flow path 111 evenly by the central conical distribution projection 125 of the distribution channel 121 of the head 120, The flow sectional area is reduced toward the distributor 123 by the gradually increasing conical distribution projection 125 to induce the fluid flowing in the mixing portion 122 to be evenly distributed in the distributor 123 .

However, the fluid distributor 100 circumferentially distributes the fluid drawn toward the distributing portion 123 disposed radially around the central distributing projection 125 to induce an even distribution, but the mixing of the fluid distributor 100 There is no means for guiding smooth fluid flow on the outer side of the portion 122 (inner surface of the main body 110), and it is difficult to expect an improved dispensing performance.

That is, the fluid distributor 100 is configured such that the even distribution of the fluid is guided centrally by the distributing projection 125 in the center of the distributing channel 121, but the fluid (fluid) (Since the flow cross-sectional area toward the distributor 123 is reduced by being concentrated in the center with the dispensing protrusions 125), there is no means for inducing an even distribution in the center It is difficult to achieve an improved dispensing efficiency since the dispersed but dispersed fluid can not guide the uniformly and steady flow toward each distribution portion 123.

The fluid that has passed through the mixing passage 113 has a problem that noise is generated due to the vortex generated by colliding with the inner wall of the mixing portion 122 in the process of being distributed to the distribution portion 123 via the mixing portion 122, The mixing flow path 113 communicating the inlet flow path 111 of the main body 110 with the distribution flow path 113 is reduced in flow area compared to the inlet flow path 111 and is distributed and discharged, There is a problem of noise generation due to the increase of the flow rate of the fluid flowing inside.

In addition, it does not provide uniform distribution efficiency along the direction of the distributing portion 123 (the horizontal direction or the inclined direction toward the outside as shown in the drawing) where the stopping jaws 127 are formed.

That is, as shown in the drawing, the distributor 123 formed in an oblique direction is formed in a slope parallel to the inclined surface of the distributing projection 125, so that even distribution efficiency can be expected with a stable flow of the fluid. However, The direction of the distributor 123 can not be properly guided to the dispensing protrusions 125 and the direction of the dispenser 123 can not be properly adjusted. Therefore, there is a high possibility that the fluid hits the inner wall of the distributor 123 while flowing, The distribution efficiency can not be expected.

In Ref. 2, a distribution pipe having a plurality of dividing balls is built in a distributor, so that the introduced fluid is dispersed through the dividing hole and then introduced into the distribution pipe, thereby reducing the pressure loss and noise caused by the fluid distribution in the distributor Which can be controlled by a controller.

The fluid distributor of Reference 2 has a distribution pipe having a plurality of branch holes formed between the inlet portion and the distribution portion of the fluid to guide the fluid through the branch holes of the distribution pipe, The pressure loss and the noise reduction by mixing and distribution are expected. However, it is expected that noise is generated due to the resistance of the fluid that hits the distribution pipe formed with a plurality of branching holes, and the fluid having passed through the branching hole having a small flowing cross- The flow of the fluid passing through the distribution pipe becomes gentle and irregular, and an even distribution can not be expected.

In addition, Reference 3 discloses a refrigerant distributor including a discharge tube fixing portion, a refrigerant inlet tube, and a plurality of discharge tubes for distributing the refrigerant to a hollow body portion which forms an appearance of a refrigerant distributor, and Reference 4 discloses a refrigerant distributor It is a ^{fluid distributor} consists of a fluid inlet pipe and a plurality of distribution pipes is a fluid passing through the inlet pipe so that the distribution made uniform velocity distribution is disclosed.

Reference 5 discloses a distributor in which a liquid phase and a gaseous refrigerant delivered from a capillary are uniformly mixed and can be distributed to an evaporator. Reference 6 discloses a distributor used for a heat exchanger or the like to provide an outlet plate having a plurality of outflow holes A fluidized bed ^{fluid distributor} in which the ^distributor of two-phase fluid (gas / liquid) is made compact and lightweight and the uniform distribution performance is improved is disclosed in Reference 7, and a perforated plate and a collecting plate are installed in a distributor, Phase fluid (gas / liquid) can be distributed at an arbitrary ratio by stacking and arranging the two-phase fluid (gas / liquid).

(Reference 1) Korean Patent Laid-Open No. 10-2010-52346, 201.05.19. (Reference 2) Japanese Unexamined Patent Publication No. 2003-75028, Mar. 13, 2003. (Reference 3) Korean Patent Publication No. 10-2005-072250, 2005.07.11. (Reference 4) Korean Patent Publication No. 10-2000-0009340, 2000.02.15. (Reference 5) Korean Published Patent Application No. 10-2009-0089068, Aug. 21, 2009. (Reference 6) JP-A-1-159043, Jun. 22, 1989. (Reference 7) Japanese Patent Application Laid-Open No. 6-229651, 1984.08.19.

The present invention constitutes a distribution guide in which a guide hole for distributing and guiding a fluid is provided for each distribution hole in order to evenly distribute the fluid drawn in the inlet flow path to each distribution hole, So that the flow of the fluid is uniformly guided to the distribution guide installed inside the fluid distributor, thereby enhancing the distribution efficiency and eliminating vortex generation, thereby greatly reducing the noise.

Hereinafter, the problem of the present invention will be described in detail as follows.

The present invention relates to a fluid distributor for distributing a fluid drawn through a draw-in flow path through at least two or more dispensing holes, wherein the fluid introduced from the center of the main body of the distributor is embedded in the fluid distributor body, The fluid is communicated to each of the distribution holes and distributed along the guide holes formed so that the flow cross-sectional area becomes gradually smaller toward the distribution hole, so that the distribution is uniformly distributed to each distribution hole.

In addition, the present invention prevents the generation of vortex by preventing the inflow fluid from being hitting against the inner wall of the distributor as in the conventional process of distributing the fluid through the distribution hole, thereby preventing the noise from being generated, thereby greatly reducing the noise.

In addition, the present invention makes it possible to construct a fluid distributor with a distribution guide built in a fluid distributor for improving the distribution efficiency, and to provide uniform distribution efficiency regardless of the direction of the distribution port.

According to an aspect of the present invention, A body embedded in a main body of a fluid distributor having a plurality of distribution holes for distributing a fluid to a fluid inlet and a fluid inlet; A plurality of guide holes formed in the body to guide the fluid to be evenly distributed and to communicate with the dispensing holes (12, 12 ') of the fluid distributor; And a distribution guide protruding from the adjacent guide holes and intersecting each other at the center of the body to divide the guide holes and protrude in a mountain shape.

The present invention provides a more efficient dispensing efficiency because the fluid introduced from the inlet flow path can be guided and distributed evenly by a distribution guide that distributes and guides the fluid evenly for each of a plurality of distribution holes.

In addition, the present invention is configured such that the flow area of the guiding hole of the distribution guide for uniform distribution without any vortex generation during the dispensing process of the introduced fluid can be gradually decreased, thereby improving the dispensing efficiency and at the same time, It is possible to greatly reduce the occurrence of noise.

In addition, the present invention can facilitate the manufacture of a fluid dispenser by providing an even distribution and a noise reduction-reducing distribution guide in the fluid dispenser, and it is possible to provide uniform dispensing efficiency regardless of the direction of the dispenser Lt; / RTI >

1 is a perspective view showing an embodiment of the present invention;
Figure 2 is a cross-
Figure 3 is a cross-sectional view of some other embodiments of the present invention
4 is a front view and a rear view of the present invention
5 and 6 are cross-sectional views of a fluid distributor to which one embodiment of the present invention is applied
7 is a cross-sectional view showing another embodiment of the present invention
Fig. 8 is an exploded perspective view of the main part of Fig.
9 is a schematic view of a conventional fluid distributor

The present invention provides a dispensing guide for evenly distributing the fluid introduced from the inlet flow path and distributing the flow of the fluid evenly through the guide holes communicating with the plurality of distribution holes and distributing the fluid, The present invention is characterized in that a distribution port of a fluid distributor having an advantage such as uniform distribution of fluid and no vortex generation and noise reduction can be provided.

The fluid distributor is formed with a plurality of distribution holes, each having a draw-in passage through which fluid is drawn into one side of the main body, and a distribution pipe for distributing and discharging the fluid drawn in from the draw-in passage to the opposite side.

The distribution guide is formed in a circular body having a size (diameter) conforming to the inner diameter of a body of a fluid distributor, which is usually formed in a circular tubular shape, for incorporation into the body of the fluid distributor, and guide holes communicating with the distribution holes are formed do.

Since the distribution holes of the fluid distributor are formed on the circumference with respect to the center of the main body, the guide holes of the distribution guide are also formed in positions and numbers corresponding to the respective distribution holes on the circumference with reference to the center point of the main body.

The guide hole communicating with the distribution hole is tapered to guide the flow of the fluid as the flow cross-sectional area decreases from the inlet through which the fluid flows from the inlet flow path to the outlet communicating with the distribution hole.

As described above, the guide hole whose flow cross-sectional area is reduced toward the outlet side of the distribution hole is formed such that a minute wire is protruded between neighboring guide holes, and these minute wires are intersected with each other around the center point of the body to constitute a distribution guide of the fluid distributor .

The implementation of this invention will be described in detail with the accompanying drawings.

FIG. 1 is a perspective view showing one embodiment of the present invention, FIG. 2 is a sectional view of the present invention, FIG. 3 is a sectional view showing some other embodiments of the present invention, and FIG. 4 is a front view and a rear view of the present invention.

The fluid distributor comprises a main body 10 having a draw-in passage 11 through which a fluid is drawn and a plurality of dividing tubes 13 and 13 'coupled to the opposite sides of the main body 10 in order to distribute the fluid introduced from the draw- And the distribution holes 12 and 12 'of the fluid distributor are formed and configured.

The present invention is built into the main body 10 of the fluid distributor so that the fluid introduced from the inlet flow path 11 can be evenly distributed to the distribution holes 12 and 12 ' So that noise can be greatly reduced.

The distribution guide is formed by forming the body 1 with a standard (diameter, size) conforming to the inner diameter of the main body 10 of the fluid distributor and the guide holes 2, 2 'communicating with the distribution holes 12, 12' Respectively.

Since the fluid dispenser has a plurality of distribution holes 12 and 12 'formed on the circumference with respect to the center of the body 10 having a circular tubular shape, the distribution guide also has a body 1 having a size conforming to the inner diameter of the body 10 (Size), and the guide holes 2, 2 'are also disposed at positions communicating with the distribution holes 12, 12' on the circumference with respect to the center of the body 1.

That is, as shown in the drawing, the fluid distributor body 10 having a circular cross section is formed by forming several distribution holes 12 and 12 'on the circumference with respect to the center of the fluid distributor, And the guide holes 2 and 2 'are formed in the body 1 in positions and in the number corresponding to the distribution holes 12 and 12' Are guided and distributed to the respective distribution holes 12 and 12 'through the guide holes 2 and 2'.

In the case where the fluid distributor is a non-circular shape, unlike the example shown in the drawing, the dispensing guide of the present invention may also be configured so that the outer shape of the body 1 matches the shape of the fluid distributor, And the like.

The dispensing guide is arranged in the main body 10 of the body 1 so that the guide holes 2 and 2 'of the body 1 can be accurately engaged with the respective dispensing holes 12 and 12' The key 4 for determining the engaging position is protruded and the main body 10 is formed with a key groove 41 to which the key 4 is coupled by the key 4 and the key groove 10, To be able to engage in the correct position in the body 10 of the dispenser.

The dispensing guide is configured such that the guide holes 2 and 2 'of the body 1 are closely contacted to the dispensing holes 12 and 12' so that the body 1 can be stably fixed in the body 10 Such as welding.

The guide holes 2 and 2 'of the distribution guide communicating with the distributor holes 12 and 12' of the fluid distributor body 10 are connected to the distributor holes 2 and 2 'from the inlet 21, 12 ' and 12 ' in the direction of the outlet 22.

The guide holes 2 and 2 'whose flow cross-sectional area decreases toward the outlet 22 toward the distributing holes 12 and 12' are formed in such a manner that the fluid introduced from the draw- The fluid flowing through the body 10 is prevented from being swirled by the fluid flowing in the main body 10 during the dispensing process, Since the fluid flows without any resistance and the distribution is induced, the generation of noise can be greatly reduced.

The guide holes (2, 2 ') for guiding the fluid to distribute the fluid as described above can also be formed by inclining the entirety as shown in FIG.

The minute wires 3, 3 'are protruded between the guide holes 2, 2' of the body 1 and the minute wires 3, 3 'protruded between the adjacent guide holes 2, 'Intersect each other at the center (center point) of the body 1 so that the guide holes 2 and 2' are partitioned.

The branch wirings 3, 3 'protruded between the neighboring guide holes 2, 2' define the guide holes 2, 2 'at the center of the body 1 of the distribution guide, 2 '' between the guide holes 2 and 2 'by the guide holes 2 and 2' whose flow cross-sectional area becomes narrower toward the outlet 22 as shown in the drawing, .

Therefore, the branch interconnections 3, 3 'protruding in the mountain shape divide the fluid drawn from the inlet flow path 11 into the guide holes 2, 2' The flow toward the guide holes 2, 2 ', which are communicated to the distribution holes 12, 12' and the flow cross-sectional area becomes narrower toward the outlet 22, are uniformly guided and evenly distributed.

In addition, since the distribution of the fluid is guided through the guide holes (2,2 ') of the distribution guides to the distribution holes (12, 12'), the direction of the distribution holes (12, 12 ' Direction or horizontal direction, see Figures 5 and 6).

6 and 7 show an example in which the fluid guide is integrally formed in the fluid distributor and the distributing holes 12A and 12A 'are integrally connected to the guide holes 2A and 2A' formed in the divided wires 3 and 3 ' And the body 1A can be screwed or welded to one side of the fluid distributor body 10A so that the body 1A can be integrated.

That is, the guide holes 2A and 2A 'and the distribution holes 12A and 12A' are integrally formed in the body 1A and the guide holes 2A and 2A 'and the distribution holes 12A and 12A' The formed body 1A is configured to be coupled to the opposite side of the draw-in passage 11A of the fluid distributor body 10A.

The body 1A in which the dispensing holes 12A and 12A 'are formed in the guide holes 2A and 2A' as described above is formed with the threaded portion 5 so that the fluid distributor body 10A is formed as the threaded portion 5, Or by welding or the like.

As described above, the distribution guide having the guide holes 2A and 2A 'and the distribution holes 12A and 12A' formed in the body 1A is coupled to the main body 10A so that the fluid distributor is integrally formed, Can be achieved more easily.

10, 10A: main body 11, 11A:
12, 12 ', 12A, 12A: distribution holes 13, 13': distribution pipe
1.1A: body 2, 2 ', 2A, 2A': guide ball
3,3 ': Minute wiring 4: Key
41: key groove 5:

Claims (4)

(1) formed with guide holes (2, 2 ') partitioned by minute wirings (3, 3') and embedded in a main body (10) of a fluid distributor;
(3, 3 ') formed by projecting in a mountain shape between adjacent guide holes (2, 2') which intersect with each other at the center of the body (1) and divide the guide holes ;
An outlet 22 on the distributor hole 12, 12 'side to which the fluid is distributed from the inlet 21 on the inlet channel 11 side of the fluid distributor partitioned by the distributor wire 3, 3' (2, 2 ') for guiding the fluid to be evenly distributed to the distribution holes (12, 12') of the fluid distributor body (10) Distribution guide. A body 1A integrally coupled to one side of a main body 10A of a fluid distributor having a fluid inlet passage 11A;
(3, 3 ') intersecting each other at the center of the body (1A) to form guide holes (2A, 2A') and protrude in a mountain shape;
The outlet 22 of the distributing holes 12A and 12A 'is divided by the distributing lines 3 and 3' and the fluid is distributed at the inlet 21 of the inlet channel 11A of the fluid distributor into which the fluid is introduced. The guide holes 2A and 2A 'are formed so that the flow cross-sectional area becomes smaller toward the outer circumferential surface and guide the even distribution of the fluid.
And a distribution hole (12A, 12A ') formed continuously with the guide holes (2A, 2A') of the body (1A). 3. The method of claim 2,
Characterized in that the body (1A) is screwed to one side of the fluid distributor body (10A) and integrated therewith. delete

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