KR20220125819A - Mesh holder for liquid nozzle - Google Patents

Abstract

The present invention relates to a mesh holder for a liquid nozzle which inserts the bend edge (71a) of a mesh (71) into a ring-shaped groove (72e) formed on the downward edge (72b) of a holder (72), and then allows the lower end of the edge of the mesh (71) to be integrated into the holder (72) while it being in close contact with the holder (72) through inward compression of the outer downward edge (72d), so that it not only improves productivity and simplifies the assembly process by minimizing parts, but also allows liquid control to be realized more thoroughly and cleanly in a neat fixed state.

Description

Mesh holder for liquid nozzles {MESH HOLDER FOR LIQUID NOZZLE}

The present invention relates to a mesh holder for a liquid nozzle, and more particularly, by inserting the bending edge of the mesh into the ring-shaped groove formed on the downward edge of the holder, and then inwardly pressing the outer downward edge to close the lower end of the mesh and integrate it into the holder It relates to a mesh holder for liquid nozzles that enables thorough and clean control of liquids in a neat fixed state, as well as improving productivity and simplifying the assembly process by minimizing parts.

In general, a liquid supply device is a device that allows a liquid such as beverage, water, edible oil, or oil to be filled in a storage container such as a bottle or a barrel, and the liquid supply device is equipped with a liquid nozzle.

Figure 1a is a partial perspective view showing a quantitative supply device for beverages according to the prior art document (Republic of Korea Patent Publication No. 1698308), Figure 1b is a front view showing the injection device, which is the main component of the quantitative supply device for beverages according to the prior art document 1c is a perspective view of the injection device of the injection device, which is a main component of the quantitative supply device for beverages according to the prior art document, and FIG. It is a cross-sectional view showing a unit, and FIG. 1E is a cross-sectional view of a fixed-quantity supply device for beverages in a suction stroke.

The quantitative supply device 1 for beverage according to the prior art document is a storage tank 10 in which the injected solution is stored in large quantities as shown in FIGS. of the injection device 20 and a transport device 30 provided below the injection device 20 to continuously supply the container 2 into which a fixed amount of the solution is injected.

A driving motor (not shown) is provided on one side of the storage tank 10 , and the storage tank 10 and the injection device 20 mounted on the outer surface of the storage tank 10 by the driving motor can be rotated together. do.

The injection device 20 communicates with the inside of the storage tank 10 so that a predetermined amount of the solution inside the storage tank 10 can be injected into the container 2 at a predetermined interval along the outer circumference of the storage tank 10 . A plurality of them may be arranged consecutively.

The injection device 20 is disposed long in the vertical direction, and includes a stroke control unit 100 that can set the amount of the solution injected as a whole, and a lifting unit that moves the piston unit 300 in the vertical direction for injection of the solution ( 200), and a valve unit 400 that opens and closes for injection of a solution, and a piston unit 300 that reciprocates up and down for suction and filling of the solution.

At this time, the valve unit 400 is provided below the lifting unit 200 , and the valve unit 400 includes a valve block 410 fixed to one side of the storage tank 10 , and inside the valve block 410 . It includes a spool member 420 for opening and closing the flow path of the liquid, a spool lever 430 for rotating the spool member 420 , and a nozzle 440 for spraying the solution sucked into the container 2 . .

The nozzle 440 is provided on the lower surface of the valve block 410 and is mounted at a position where it can selectively communicate with the peeling flow path 423 , and a check valve 441 is provided inside the nozzle 440 , and a piston (320) to maintain the closed state until the pressure by the descending is generated.

The applicant of the present application intends to improve and invent a mesh holder for a liquid nozzle that can be applied to a quantitative supply device for beverages according to the prior art document and propose it as the present invention.

Republic of Korea Patent Publication No. 1698308

It is an object of the present invention to insert the bending edge of the mesh into the ring-shaped groove formed on the downward edge of the holder, and then integrate the lower edge of the mesh into the holder by inwardly pressing the outer downward edge to improve productivity by minimizing parts. And it is to provide a mesh holder for liquid nozzles that enables thorough and clean control of liquids in a neat fixed state as well as simplification of the assembly process.

An object of the present invention is to make the downward length of the outer downward border relatively longer than the downward length of the inner downward border to support and closely adhere to the lower end of the mesh edge during inward compression of the outer downward border so that it is integrated into the holder so that it is more rigidly fixed To provide a mesh holder for the liquid nozzle that maintains the

An object of the present invention is to prevent a phenomenon such as resistance or obstruction to the ejection path of a liquid by bending the end of the lower outer border to a region relatively smaller than the diameter of the inner periphery of the inner lower border when the outer lower edge is pressed inward. It is to provide a mesh holder for liquid nozzles that can be prevented in advance.

An object of the present invention is to bend the lower outer edge inwardly and press it on a flat horizontal line so that the lower edge of the mesh can be gently wrapped around the lower edge of the mesh so that it can be in close contact with the inner lower border, so that the mesh can be integrated into the holder. An object of the present invention is to provide a mesh holder for liquid nozzles that can significantly reduce defects.

The present invention for achieving the above object,

In the mesh holder for a liquid nozzle comprising a holder having a downward exit in the downward rim, and a mesh mounted on the downward rim,

The bent edge bent upward from the outer edge of the mesh is inserted into a ring-shaped groove that is drilled upward from the lower end of the lower edge and divided into an inner lower edge and an outer lower edge, and then the outer lower edge is compressed inwardly to form the edge of the mesh. The basic feature in terms of its technical configuration is that the lower end is closely attached to the holder and integrated into the holder.

The present invention inserts the bending edge of the mesh into the ring-shaped groove formed on the downward edge of the holder, and then integrates it into the holder while closely contacting the lower end of the edge of the mesh by inward pressing of the outer downward edge. It not only simplifies the process, but also has the effect of enabling thorough and clean control of the liquid as a neat fixed state.

The present invention makes the downward length of the outer downward border relatively longer than the downward length of the inner downward border, so that when the outer downward border is compressed inwardly, it closely adheres to the bottom of the mesh while supporting it to be integrated into the holder, thereby maintaining a more robust fixed state. It has a caking effect.

The present invention prevents a phenomenon such as resistance or obstruction to the ejection path of the liquid by bending the end of the outer downward border to a region relatively smaller than the diameter of the inner periphery of the inner downward border when the outer downward border is pressed inward. It has the effect of preventing it.

The present invention bends the lower outer edge inwardly and compresses it on a flat horizontal line so that the lower edge of the mesh can be gently wrapped around the lower edge of the mesh so that it can be in close contact with the inner lower border, thereby eliminating the defect in the process of integrating the mesh into the holder. It has a significant reduction effect.

Figure 1a is a partial perspective view showing a quantitative supply for beverages according to the prior art document.
Figure 1b is a front view showing the injection device, which is a main component of the quantitative supply device for beverages according to the prior art document.
Figure 1c is a perspective view of the injection device of the injection device, which is the main component of the quantitative supply device for beverages according to the prior art document.
Figure 1d is a cross-sectional view showing a valve unit as a main component of the injection device applied to the quantitative supply for beverages according to the prior art document.
Figure 1e is a cross-sectional view of the quantitative supply for beverages in the case of a suction stroke.
Figure 2 is a photograph showing an automatic quantitative supply of edible oil for explaining the liquid nozzle according to an embodiment of the present invention.
Figure 3 (a) is a photograph of a state in which edible oil, that is, liquid is supplied from the liquid nozzle according to an embodiment of the present invention.
Figure 3 (b) is a photograph of a state in which edible oil, that is, liquid is supplied and then blocked from the liquid nozzle according to an embodiment of the present invention.
Figure 4 is a photograph showing a single edible oil quantitative supplying device applied to the edible oil automated quantitative supplying device of Figure 2;
5 is a photograph showing a liquid nozzle according to the present invention.
6 (A) to (D) are longitudinal cross-sectional views showing the operation process of the liquid nozzle according to the present invention.
7 is an enlarged cross-sectional view showing the liquid nozzle (K) according to the present invention.
Figure 8a is an exploded cross-sectional view showing a manufacturing process of the mesh holder for a liquid nozzle according to the present invention.
Figure 8b is a longitudinal cross-sectional view showing a mesh holder for a liquid nozzle according to the present invention.
Figure 8c is a photograph showing a mesh holder for a liquid nozzle according to the present invention.

A preferred embodiment of the mesh holder for a liquid nozzle according to the present invention will be described with reference to the drawings, and a plurality of the embodiments may exist, and the object, features and advantages of the present invention can be better understood through these embodiments. be able to understand

Figure 2 is a photograph showing an automatic quantitative supply of edible oil for explaining the liquid nozzle (K) according to an embodiment of the present invention.

As shown in FIG. 2, the automated quantitative supplying device for cooking oil quickly fills the edible oil by a fixed amount while rotating the liquid nozzle (K) together when the barrel, that is, the storage container (J), is sequentially rotated along the conveyor (C). and the storage container (J) filled with edible oil in this way is designed to be transferred to the next process for covering the lid.

Figure 3 (A) is a photograph of a state that edible oil, that is, liquid is supplied from the liquid nozzle (K) according to an embodiment of the present invention, Figure 3 (B) is a liquid nozzle according to an embodiment of the present invention In (K), it is a photograph of the state that cooking oil, that is, liquid is supplied and then shut off.

When the liquid is supplied from the liquid nozzle (K), the liquid is quickly supplied in a sufficient amount as shown in FIG.

4 is a photograph showing a single edible oil quantitative supply device applied to the edible oil automated quantitative supply device of FIG. 2 .

As shown in FIG. 4, the single edible oil quantitative supply device applied to the edible oil automated quantitative supply device is a supply pipe (T1) connected to a supply tube (T) for supplying edible oil, that is, a liquid in a state in which the supply pipe (T1) is in communication with the cylinder (50) For example, a piston 60 to be described later, which is operated pneumatically, is lifted into the cylinder 50 to realize supply and cut-off of the liquid.

5 is a photograph showing the liquid nozzle K according to the present invention, FIGS. 6 (A) to (D) are longitudinal cross-sectional views showing the operation process of the liquid nozzle K according to the present invention, and FIG. 7 is this view It is an enlarged cross-sectional view showing the liquid nozzle (K) according to the invention.

The liquid nozzle K according to the present invention includes a cylinder 50 having an under outlet 50a for discharging the liquid downward as shown in FIGS. 5 to 7, and the under outlet ( It includes a piston 60 that opens and closes 50a), and when liquid needs to be supplied according to the structure of the piston 60 that opens and closes the under outlet 50a, as shown in FIG. On the other hand, when it is necessary to block the ejection of the liquid immediately after the liquid is filled in the storage container (J), as shown in FIG.

Referring to FIG. 6 more specifically, (a) is the piston 60 is lowered into the cylinder 50 by pneumatic pressure, and the supply pipe T1 connected to the supply tube T is closed by the piston 60 and at the same time The under outlet (50a) is also shown to be closed by the piston (60), and in (B), the piston (60) is maximally raised by pneumatic pressure and the supply pipe (T1) is maximally opened and the under outlet (50a) is The maximum opening shows that a large amount of liquid can be supplied, and in (C), the piston 60 is partially lowered by pneumatic pressure, and the liquid is partially opened with the partial opening of the supply pipe T1 and the under outlet 50a. In (D), the piston 60 is maximally descended into the cylinder 50 by pneumatic pressure to close the supply pipe T1 and close the under outlet 50a. It shows the state in which the supply of the edible oil is completely stopped, and the process from (A) to (D) of FIG. 6 is applied to the automated quantitative supply of edible oil of FIG. 2 as one cycle and stored along the conveyor (C). When the container (J) is sequentially rotated and moved, it is to be able to quickly fill the edible oil with a time difference as the liquid nozzle (K).

On the other hand, the liquid nozzle (K) according to the present invention is a cylinder 50 having an under outlet (50a) for discharging the liquid downward, as shown in FIG. 7, and the under outlet (50a) while ascending into the cylinder (50). It includes a piston 60 for opening and closing, in this case, the mesh 71 may be directly fixed to the lower end of the under outlet 50a, and the mesh holder 70 having a holder 72 on which the mesh 71 is mounted. can be detachably mounted to the under outlet (50a), and as such a mesh holder (70), when a foreign material is found, it is quickly disassembled to enable simple removal.

8A is an exploded cross-sectional view showing a manufacturing process of the mesh holder 70 for liquid nozzles according to the present invention, FIG. 8B is a longitudinal cross-sectional view showing the mesh holder 70 for liquid nozzles according to the present invention, and FIG. 8C is the present invention It is a photograph showing the mesh holder 70 for the liquid nozzle according to.

The mesh holder 70 for a liquid nozzle according to the present invention has a holder 72 having a downward outlet 72a in the center of the downward rim 72b, as shown in FIGS. 8a to 8c, and the downward rim 72b. It includes a mesh 71 to be mounted, and is drilled upward from the lower end of the downward edge 72b of the holder 72 to divide the mesh into an inner downward border 72c and an outer downward border 72d. The mesh in the ring-shaped groove 72e After inserting the bent edge 71a bent upward from the outer edge of the 71, the outer downward edge 72d is pressed inward to close the lower end of the edge of the mesh 71 so that it can be integrated into the holder 72. .

In general, when a liquid nozzle (K) wants to provide a mesh such as the mesh 71 of the present invention, most of the meshes are fixed in an assembled type by mobilizing a nut or the like or fixed by welding. In this case, excessive parts and assembly complexity further It inevitably leads to a decrease in productivity and poor control of the liquid due to an unclean condition due to welding.

In the present invention, in consideration of this problem, the bending edge 71a of the mesh 71 is inserted into the ring-shaped groove 72e formed in the downward edge 72b of the holder 72, and then the mesh by inward compression of the outer downward edge 72d. By making it possible to integrate the lower end of the edge of 71 into the holder 72 while closely adhering to it, productivity improvement and assembly process simplification according to the minimization of parts, as well as a neat fixed state, can be realized more thoroughly and cleanly. it was made to

At this time, the downward length of the outer downward border (72d) is relatively longer than the downward length of the inner downward border (72c). It is integrated into the holder 72 to maintain a more robust fixed state.

Furthermore, when the outer downward border 72d is pressed inward, the end of the outer downward border 72d is bent to a region relatively smaller than the diameter of the inner periphery of the inner downward border 72c, thereby resisting the ejection path of the liquid. In order to prevent such phenomena as interference or interference in advance.

And, the outer downward border (72d) is bent obliquely through an inwardly tapered U.S. jig and then compressed horizontally through a flat U.S. jig to gently wrap the lower edge of the mesh 71 while gently wrapping the inner lower edge. By making it close toward the (72c), it is possible to significantly reduce defects in the process of integrating the mesh 71 with the holder 72.

The present invention can be used in industrial fields that can supply water, beverages, edible oil, sesame oil, and various oils.

T : supply pipe T1 : supply pipe
C : Conveyor J : Storage container
K: liquid nozzle 50: cylinder
50a: under outlet 60: piston
70: mesh holder 71: mesh
71a: bending border 72: holder
72a: downward exit 72b: downward border
72c: inner lower border 72d: outer lower border
72e: ring groove

Claims (4)

In the mesh holder for a liquid nozzle comprising a holder (72) having a downward outlet (72a) at the center of the downward edge (72b), and a mesh (71) mounted on the downward edge (72b),
A bent edge 71a bent upward from the outer edge of the mesh 71 in a ring-shaped groove 72e that is drilled upward from the lower end of the downward edge 72b and divided into an inner downward edge 72c and an outer downward edge 72d. ), and then press the outer downward edge (72d) inward to close the lower end of the edge of the mesh (71) and integrate it into the holder (72). The method of claim 1,
A mesh holder for a liquid nozzle, characterized in that the downward length of the outer downward rim (72d) is relatively longer than the downward length of the inner downward rim (72c). 3. The method of claim 1 or 2,
When the outer lower edge (72d) is compressed inwardly, the end of the outer lower edge (72d) is bent to a region relatively smaller than the diameter of the inner periphery of the inner lower edge (72c) for liquid nozzle mesh holder. 3. The method of claim 1 or 2,
The outer downward border (72d) is a mesh holder for a liquid nozzle, characterized in that after being bent obliquely inwardly compressed on a horizontal line.

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