KR200452325Y1 - Rotary nozzle type forming device for manufacturing noodle - Google Patents

Abstract

The surface contained in the lead device is arranged to be flat without being biased to one side, and the surface strands do not escape to the outside, and the surface strands are not attached to the lead device or pinched on the floor for easy shaping and separation. A rotating nozzle type surface forming apparatus is disclosed. Rotating nozzle type surface forming apparatus of the present invention by using a rotating injection nozzle to give a rotational force while lifting the surface from the lower portion of the lead-type device to form a round shape in the nest form. In particular, two air jet nozzles are attached to each bowl in accordance with the number of individual bowls in the lead-type device, and the jet nozzles are configured to allow angle adjustment in the rotational direction. At the same time, the air output was affected, and the upper part of the lead device was equipped with a porous network to prevent air from escaping, while allowing the air to escape easily from the inside. Due to the shape of the nozzle which floats due to the rotating spray nozzle at the bottom and is inclined in the rotational direction, the surface is rotated in the lead-type apparatus while the surface is rounded and the separated strand is reflowed to improve the shape of the surface. And prevent the occurrence of feed.

Description

ROTARY NOZZLE TYPE FORMING DEVICE FOR MANUFACTURING NOODLE}

The present invention relates to a cotton forming apparatus, and more particularly to a device for improving the shape of the surface in the lead-type device used for the shaping of the surface during the manufacturing of noodles.

The noodle forming apparatus is provided at the inlet and drying inlet so that the noodles contained in the lead-type apparatus after the noodle cutting can be adjusted before the shape is fixed through the nudge and drying.

Normally, the injected or steamed cotton is supplied to the cutter by attaching a portion of the cotton strand before passing through the cutter, or the pressed cotton strand of the cutting portion is stuck while falling in the cutting portion, or it is biased to one side while being put into the lead device after cutting. .

In this state, when the cotton passes through the drying or milking process, the shape of the noodles is not uniform and non-uniform, which degrades the quality. Causes a decrease.

Conventionally, in order to prevent the sticking of these surface strands and to flatten the shape of the upper surface, the surface is arranged by hand or by attaching an air jet nozzle to the upper part of the lead device.

In the conventional method of forming the surface using the air nozzle, the injection nozzle is flowed from the upper side of the soldering apparatus to the left and right to arrange the surface line, the first upper left and right flow, and the second lower side to the left and right flow, There are a variety of methods, such as forming a surface by forming an air curtain by closely arranging the injection nozzles in a row, a method of forming the surface in the form of a rotation from the top.

However, this type of air injection in the upper part causes energy loss due to the increase of air consumption when there are many nozzles, and it is not easy to separate the face from the lead mold because the cotton wire is guided to the perforation part of the bottom of the lead device. A problem occurs. In addition, various problems have occurred, such as the line strand is separated to the outside to increase the defect.

The present invention is to solve the problems as described above, the object of the present invention is to arrange the flat surface without bias to one side of the lead-type device, so that the surface strands do not escape to the outside at the same time the surface strands The present invention provides a rotary nozzle type face forming apparatus which facilitates shaping and separating of faces by preventing them from being attached or pinched on the floor.

In order to achieve the above object, the rotating nozzle type surface forming apparatus according to the present invention is a surface forming apparatus for adjusting the shape of a surface contained in a soldering apparatus for forming a melted or dried surface, in the lower side of the soldering apparatus. At least one injection nozzle for injecting compressed air upwards, a drive device for rotating the injection nozzle, and a porous network for sealing the upper portion of the lead-type device.

In addition, the injection nozzle of the rotary nozzle type surface forming apparatus according to the present invention is provided to adjust the direction of the nozzle portion.

In addition, the nozzle portion of the rotary nozzle type surface forming apparatus according to the present invention is inclined in the rotation direction of the injection nozzle.

In addition, the injection nozzle of the rotating nozzle type surface forming apparatus according to the present invention is the body connected to the drive device, the bridge branched from the body, the elbow rotatably connected to the bridge, the nozzle portion provided at the end of the elbow Include.

According to another aspect of the present invention, in the surface forming apparatus for adjusting the shape of the surface contained in the lead-type device for forming the melt or dry surface, the compressed air using the at least one rotatable injection nozzle lower side of the lead-type device There is provided a rotating nozzle type surface forming apparatus for rotating the surface strand in the lead-type device by rotating spraying in.

In addition, the injection nozzle of the rotary nozzle-type surface forming apparatus according to the present invention is provided to adjust the nozzle direction of the end.

In addition, the injection nozzle of the rotary nozzle type surface forming apparatus according to the present invention is provided to be inclined in the nozzle nozzle rotation direction of the end.

The rotating nozzle type surface forming apparatus according to the present invention forms a surface in a nest form by giving a rotational force while causing the surface to float by injecting air of a rotating nozzle from the lower portion of the lead-type apparatus. In particular, two air jet nozzles are attached to each bowl according to the number of individual bowls in the lead-type device, and the jet nozzles are configured to be angle-adjusted in the rotational direction, thereby simultaneously rotating the air jet nozzles in the upper direction and the tangential direction. Because the earth output is affected, the surface contained in the lead-type device rises due to the rotating nozzle of the lower part and the shape of the nozzle is inclined in the rotational direction so that the surface rotates in the lead-type device while simultaneously forming the surface roundly. By reflowing the strands, the shape of the noodles is improved and feed is suppressed.

Therefore, according to the rotary nozzle type surface forming apparatus of the present invention, the shape of the surface after oiling or drying is greatly improved, and the adhesion and detachment of the cotton line strands are reduced, thereby reducing the contamination of the oil bath or the dryer. In addition, as the surface formability is improved, quality can be improved and errors in the packaging machine can be significantly reduced. Therefore, it is possible to meet the needs of the buyer as a whole and to reduce the production cost by reducing the amount of feed generated. This can reduce the occurrence of serious faults.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are a front view and a side view showing a rotating nozzle type surface forming apparatus according to an embodiment of the present invention, Figure 3 is a perspective view of the rotating nozzle type surface forming apparatus according to the present invention, Figure 4 is 5 is a view illustrating a spray nozzle of a rotating nozzle type surface forming apparatus according to the present invention, and FIG. 5 is a schematic view for explaining the operation of the rotating nozzle type surface forming apparatus according to the present invention.

Referring to the drawings, the surface forming apparatus according to the present invention is the injection nozzle 10 for injecting compressed air to the lead-type device 1, and the drive device 20 for providing a rotational driving force for the injection nozzle 10 to rotate And an upper porous network 30 which prevents the surface leaking out of the lead-type device 1 by air pressure and prevents air from escaping.

At least one injection nozzle 10 is provided below the lead device 1. In the present embodiment, the two nozzle portions 10a and 10b are provided in a pair and installed on the outer concentric circle of the lead-type device 1, but the present invention is not limited thereto.

Each nozzle part 10a, 10b is branched from the body 14 via bridges 11 and 12, and air is connected to the body 14 with an external regulator 15 and a solenoid valve (shown in FIG. 2). 16). In addition, the nozzle parts 10a and 10b are connected to the main body 14 by elbows 17 and 18 so as to adjust the angle.

The injection nozzle 10 is rotatably provided by the drive device 20. The drive device 20 includes a motor 22 and a gearbox 24. Conventional lead type device (1) is provided to be able to process a plurality of face bundles at the same time (see Figure 3), the gearbox 24 of the present embodiment is installed to drive two sets of injection nozzles 10 at the same time have.

A rotary joint 19 is installed in the body 14 to supply air to the rotating spray nozzle 10, and is connected to the air hose of the regulator 15.

The upper porous net 30 is a conventional net, which allows air to pass through and prevents leakage of the surface strands.

Next, the surface shaping | molding operation | movement of the rotary nozzle type surface forming apparatus which has the above structure is demonstrated.

First, in the lead device 1, the surface injected or steamed prior to surface molding is contained by a predetermined amount through the cutter. At this time, the surface strands are not uniformly shaped due to some reasons before the cutting through the cutter, the surface strands pressed when the cutting is stuck to each other, or due to the bias in the lead device.

In this state, when the injection nozzle 10 is rotated as shown in FIG. 3, since the surface strands have a floating force due to the air pressure of the injection nozzle 10, air gaps are formed between the surface strands and the surface strands, and are pressed together. The strands are separated from each other.

When the nozzles 10a and 10b of the rotating spray nozzle 10 are rotated by a predetermined angle in the rotation direction R of the spray nozzle 10 as shown in FIG. 3, the surface strands are subjected to a wave shock. It begins to flow and then rotates by flotation and tangential rotation.

4 and 5, the nozzles 10a and 10b are inclined at a predetermined angle along the rotational direction of the injection nozzle 10 to inject air (D direction), perpendicular to the plane. Flotation force F1 and tangential rotational power F2 are generated. As described above, the vertical flotation force (F1) forms a gap between the surface strands so that the agglomerated surfaces are separated, and the tangential rotational force (F2) acts together with the vertical flotation force (F1) to rotate the surface strands.

Rotating surface strands are more effectively separated from the surface strands bound by the wave impact, and the surface strands that are separated from the outside of the lead device 10 or inserted into a hole or a gap (not shown) of the lead device (1). It will return to position.

On the other hand, since the porous network 30 is provided in the upper part of the lead device 1, the surface strands are effectively prevented from leaving the lead device (1).

Conventionally, nine nozzles per plane were continuously sprayed from the top, but according to the present invention, two nozzles are sprayed from the lower side of the lead-type device 1, but since the intermittent supply is possible for the required time, the air consumption is significantly reduced. Occurs.

1 is a front view of a rotating nozzle type surface forming apparatus according to the present invention.

Figure 2 is a side view of a rotary nozzle type surface forming apparatus according to the present invention.

Figure 3 is a perspective view schematically showing a rotary nozzle type surface forming apparatus according to the present invention.

Figure 4 is an enlarged view of the nozzle of the rotary nozzle type surface forming apparatus according to the present invention.

5 is a schematic view for explaining a rotary nozzle type surface forming apparatus according to the present invention.

Explanation of symbols on the main parts of the drawings

1 .. Lead type device 10 .. Spray nozzle

10a, 10b. Nozzle 14. Body

15. Regulator 17, 18 Elbow

20.Driver 22.Motor

24. Gearbox 30. Perforated network

Claims (7)

In the surface shaping device for adjusting the shape of the surface contained in the lead device for shaping the milk or dry cotton, At least one injection nozzle having a nozzle unit for injecting compressed air upward from the lower side of the lead device, a drive device for rotating the injection nozzle, and a porous network for sealing the upper portion of the lead device, The nozzle unit is inclined in the rotational direction of the injection nozzle so that the compressed air is rotated from the lower side of the lead-type device so that the surface strands rotate while floating in the lead-type device, The jet nozzle comprises a body connected to the drive device, a bridge branched from the body, an elbow rotatably connected to the bridge, and a nozzle portion provided at the end of the elbow Device. The method of claim 1, The injection nozzle is a rotary nozzle type surface forming apparatus, characterized in that provided to adjust the direction of the nozzle portion. delete delete delete delete delete

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