KR102183783B1 - Apparatus of recycling laver washing water having improved screw cleaner - Google Patents

Abstract

We propose a laver washing water recycling device that removes laver powder as much as possible before introducing contaminated laver washing water into the filtration means, reduces the size and amount of laver powder passing through the screen net, and effectively cleans the screen net. The device includes a laver powder removing unit disposed on the removing unit support, and the laver powder removing unit is divided into an inner inner region and an outer outer region as the center of the cylindrical screen net, and the inner region is a spiral form from the cylindrical support. A screw cleaning unit on which a first brush formed along the spiral protrusion protruding from is mounted is located.

Description

Apparatus of recycling laver washing water having improved screw cleaner}

The present invention relates to a laver washing water recycling apparatus, and more particularly, to a laver washing water recycling apparatus that can recycle the washing water used for washing laver in a laver washing process by purifying it with an improved screw washing unit.

Laver is a type of seaweed, and is widely consumed in Korea, Japan, and China because of its high content of protein, minerals, and vitamins and good taste. Laver is mainly molded in a square shape, dried and distributed, and is sold as dried laver or baked laver. Dry laver is manufactured by removing foreign substances through a washing process, slicing it into small pieces, and then spreading the raw grass mixed with water on the foot. This laver washing water is contaminated with fine laver powder. The laver washing water contaminated with laver powder is reused in the process of washing new laver with purified water purified by a predetermined filtering means.

Korean Patent Publication No. 2018-0055354 proposes a method of purifying contaminated laver washing water with a filtration means such as a sand layer, activated carbon, and a filter. However, when contaminated laver washing water is added to the filtering means, laver powder contained in the laver washing water completely clogs the filtering means such as sand layer, activated carbon, and filter. If the filtering means is clogged, the function of the filtering means is prematurely lost. Accordingly, before introducing the contaminated laver washing water into the filtering means, it is preferable to remove the laver powder as much as possible in advance so that the function of the filtering means is not lost early.

On the other hand, in the recycling device, a brush is attached to a screw washing unit located inside the screen net to raise the laver powder and clean the screen net. In order to maintain the lifting force of the laver powder, the brush must have the constant length. However, since the length of the conventional brush is relatively long, it is made of thick bristle. In this case, the cleaning effect of the screen net decreases, and the size of the aperture of the screen net corresponding to the thickness of the brush is inevitably increased. The larger the size of the screen net, the larger the size and the amount of seaweed powder passing through the screen net. Accordingly, there is a need for a method of reducing the size of the eyes of the screen net, reducing the size and amount of seaweed powder passing through the screen net, and effectively cleaning the screen net.

The problem to be solved by the present invention is to remove laver powder as much as possible before introducing contaminated laver washing water into the filtering means, to reduce the size and amount of laver powder that exits the screen net, and to effectively perform washing of the screen net. It is to provide a laver washing water recycling device.

The laver washing water recycling apparatus having an improved screw washing unit for solving the present invention includes a laver powder removing unit disposed on the removal unit support, and the laver powder removing unit is an inner area inside and outside the center of the cylindrical screen net. Is divided into an outer region of and in the inner region is a screw cleaning unit equipped with a first brush formed along a spiral protrusion protruding from the cylindrical support in a spiral shape.

In the apparatus of the present invention, the outer region includes a brush structure composed of brush bars to which second and third brushes are attached to both sides. The spiral protrusion includes a spiral groove that is recessed along a circumference, and the first brush may be formed in the spiral groove. The height of the spiral protrusion may be constant throughout. The height of the spiral protrusions may gradually decrease or increase gradually or they may be combined.

In a preferred device of the present invention, as the thickness of the first brush filament becomes thinner, the size of the aperture of the screen net corresponding to the thickness may decrease. The brush structure is rotated by a manual gear, and a roller or a slip resin body or a combination thereof may be provided around the manual gear. The slip resin body may be made of engineering plastic containing oil. A scrubber is mounted on the upper portion of the screw washing unit, and the scrubber pushes the laver powder rising from the inner region and discharges it from the discharge bin. The discharge bin may be made of a transparent material. The outer area is an area between the screen net and the case, and the case and the support may be made of the same material.

According to the laver washing water recycling apparatus of the present invention, by having a screw washing unit having a spiral structure, the laver powder is removed as much as possible before introducing the contaminated laver washing water into the filtering means, and the size and amount of laver powder exiting the screen net And effectively perform screen net cleaning.

1 is a perspective view showing the appearance of a laver washing water recycling apparatus according to the present invention,
2 is a view showing the core part of the present invention separately.
3 is a perspective view showing the brush structure and manual gear of FIG. 2.
4 is an exploded perspective view of FIG. 3.
5 is a perspective view for explaining a process of rotating the manual gear in the recycling device according to the present invention.
6 is a diagram illustrating a modified example of FIG. 2.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below may be modified in various forms, and the scope of the present invention is not limited to the embodiments described below. Embodiments of the present invention are provided to more completely describe the present invention to those of ordinary skill in the art. Meanwhile, terms indicating a location such as upper, lower, and front are only related to those shown in the drawings. In practice, the recycling device can be used in any optional orientation, and in actual use, the spatial orientation changes according to the orientation and rotation of the recycling device.

According to an embodiment of the present invention, by providing a screw washing unit having a spiral structure, the laver powder is removed as much as possible before the contaminated laver washing water is introduced into the filtering means, and the size and amount of laver powder exiting the screen net are reduced, and the screen We propose a laver washing water recycling device that effectively cleans the net. To this end, a recycling device equipped with a screw washing unit having a spiral structure will be specifically examined, and an effect obtained by mounting a screw washing unit having a spiral structure will be described in detail. Here, the contaminated laver washing water is the washing water used to wash laver in the laver washing process and contains laver powder.

The recycling device of the present invention removes the laver powder contained in the contaminated laver washing water as much as possible before the contaminated laver washing water is introduced into the filtering means such as a sand layer, activated carbon, and filters, so that the function of the filtering means is not lost early Avoid. That is, the recycling device 100 is disposed before the step of filtering with the filtering means. If the laver powder is sufficiently removed before being introduced into the filtration means, the filtration means such as a sand layer, activated carbon, and a filter can be used for a longer time, so that the cost of replacing the filtration means can be significantly reduced.

1 is a perspective view showing the appearance of a laver washing water recycling apparatus according to an embodiment of the present invention, FIG. 2 is a view showing a separate core part of the present invention, and FIG. 3 is a perspective view showing the brush structure and manual gear of FIG. 2 . 4 is an exploded perspective view of FIG. 3. However, the drawings are not represented in a strict sense, and there may be components not shown in the drawings for convenience of description.

1 and 2, the recycling device 100 includes a laver powder removal unit 150 fixed to the fixing plate 20 and disposed on the removal unit support 10. Removal unit support 10 ) Is in the form of a box, and has a first motor 11, a coupling 12 connected to the spindle 15, an inlet 13 and an outlet 14. First motor 11 And the coupling 12 transmits the rotational force to the screw washing unit 60, the inlet 13 is a place where contaminated laver washing water is introduced, and the outlet 14 is a place where the purified water purified by the present invention is discharged. A first O-ring 21 for blocking leakage is installed at the part where the coupling 15 and the fixing plate 20 meet. At this time, the laver washing water is water containing laver powder, and the purified water is It is water from which laver powder is removed to the maximum by the recycling device 100 of the present invention.

The laver powder removal unit 150 is divided into an inner area (a) inside the screen net 50 and an outer area (b) outside the screen net 50 around the cylindrical screen net 50. In the inner region (a), a screw washing unit 60 that raises the laver powder together with the washing water introduced from the inlet 13 and cleans the screen net 50 from the inside is positioned. A scrubber 64 is mounted on the screw washing unit 60 to push the laver powder raised while rotating together with the screw washing unit 60 to the discharge path 72. A bearing portion 71 is provided at the center of the upper portion of the discharge bin 70, and a rotation pin 65 attached to the upper surface of the scrubber 64 is inserted into the bearing portion 71 to rotate. That is, the screw cleaning unit 60 and the scrubber 64 are connected to the coupling 12 and the bearing unit 71 and rotate together.

The screw cleaning unit 60 includes a cylindrical screw support 61 and a spiral protrusion 62, and a first brush 63 is planted in the spiral protrusion 62 protruding in a spiral shape. That is, the screw cleaning unit 60 is composed of a screw support 61, a spiral protrusion 62, and a first brush 63. The first brush 63 is a bunch of brush filaments, which are a plurality of elastic synthetic resin fibers, and as the screw cleaning unit 60 rotates, the first brush 63 becomes the screen eye of the screen net 50 ( Clean the screen aperture, 50a). The screen net 50 has a structure similar to a mesh in a cylindrical shape, and includes a plurality of screen eyes 50a. As the screw cleaning unit 60 rotates, each brush filament of the first brush 63 enters and exits the screen eye 50a to block clogging of the screen eye 50a with seaweed powder. do.

When the screw washing unit 60 rotates in a clockwise direction, the laver washing water introduced from the inlet 13 is a lifting force that rises due to the rotation of the spiral protrusion 62 and the first brush 63 attached to the spiral protrusion 62 Have. The lifting force is related to the first gap D1 which is the sum of the first protrusion height H1 and the first gap S1. Here, the first protrusion height H1 is the protruding height of the spiral protrusion 62, and the first interval S1 is the distance between the spiral protrusion 62 and the screen net 50. When the first gap D1 increases, the lifting force decreases, but the amount of influent water to be treated increases. As the first gap D1 decreases, the lifting force increases, but the amount of influent to be treated decreases. Accordingly, the first gap D1 of the present invention is appropriately adjusted in consideration of the amount of influent water to be treated, the lifting force, and the like.

The first protrusion height H1 may be constant over the entire spiral protrusion 62 or may be adjusted in various ways. For example, the first protrusion height H1 may gradually decrease in a certain area and may increase gradually in another area. That is, the first height H1 is an average value. In other words, the first protrusion height H1 of the spiral protrusion may gradually decrease or increase gradually, or they may be combined. The first protrusion height H1 may be adjusted in consideration of the lifting force and smooth flow of laver washing water by the screw washing unit 60 according to an embodiment of the present invention. In the drawings, it is only taken as an example of a constant first protrusion height H1.

The spiral protrusion 62 according to the embodiment of the present invention contributes to imparting the lifting force. If there is no spiral protrusion 62, the lifting force must be secured only by the first brush 63. When the spiral protrusion 62 is present, the length of the filament of the first brush 63 is shortened compared to the prior art without the spiral protrusion 62. In addition, compared to the filament of the first brush 63 of the present invention, since the length of the conventional brush bristle is longer, the screen eye 50a needs to be relatively large compared to the present invention to clean the screen eye 50a. Conventionally, in order to maintain the rigidity, the brush hair should be thicker than the first brush 63 of the present invention. In other words, the first brush 63 of the present invention can be applied with a filament having a shorter length and a thin thickness compared to the conventional one.

The first gap D1 of the present invention is the sum of the first height H1 and the first gap S1. In other words, as the first height H1 increases, the first interval S1 decreases. Under the condition that the first gap D1 is properly maintained in consideration of the amount of influent water, the lifting force, etc., the first gap S1 may be designed to be reduced to the maximum. When the first gap S1 is reduced, the length of the hairs of the first brush 63 attached to the screw protrusion 62 is shortened. When the length of the hairs of the first brush 63 is shortened, the thickness of the hairs of the first brush 63 can be made thin so as to correspond thereto, and sufficient elasticity can be maintained to clean the screen eyes 50a.

In the screw cleaning unit 60, the length and thickness of the filaments of the first brush 63 have an important meaning. If the length of the filament of the first brush 63 is short and the thickness is thin, the size of the aperture 50a of the screen net 50 corresponding thereto may be reduced. This is because, while each brush filament of the first brush 63 enters and exits the screen eye 50a, the screen eye 50a blocks the clogging phenomenon of clogging with laver powder. When the size of the screen eye 50a is reduced, the size and amount of seaweed powder that escapes to the screen eye 50a are greatly reduced.

For example, if the size of the screen eye 50a is 0.6 mm, which is generally used, laver powder having an average diameter of less than 0.6 mm escapes to the screen eye 50a. However, if the size of the screen eye 50a is 0.4mm, furthermore 0.2mm, only the laver powder having an average diameter of 0.4mm, furthermore than 0.2mm will escape. In other words, if the size of the screen eye 50a is 0.4 mm, the laver powder having an average diameter greater than 0.4 mm is prevented from escaping into the screen net 50. In addition, when the thickness of the filament of the first brush 63 becomes thinner, the elasticity and flexibility of the filament increase. In this case, it is possible to wash the screen eye 50a while the first brush 63 filament easily enters and exits the screen eye 50a.

Meanwhile, as the diameter of the screw support 61 increases and the second gap S2 between the protrusions 62 decreases in the screw cleaning unit 60 having the same height, the total length of the first brush 63 increases. . When the length of the first brush 63 increases, the amount of hairs of the first brush 63 planted in the first brush 63 increases, so that the bristle of the first brush 63 further fills the first gap D1. . When the total length of the first brush 63 increases, the lifting force increases, and clogging of the screen net 50 is more effectively prevented. In the embodiment of the present invention, it is preferable to enlarge the diameter of the screw washing unit 60 to the maximum in light of the recycling device 100 of the present invention, and to reduce the second interval S2 to the minimum. The first brush 63 of the present invention may further increase the cleaning effect of the screen net 50 by arranging the spiral protrusions 62 in two rows.

The water of the laver washing water escapes to the screen eye 50a and becomes purified water. The laver powder of the laver washing water rises and rises toward the scrubber 64 and is pushed by the rotation of the scrubber 64 to exit the discharge bin 70. The laver powder that is forcibly discharged to the discharge container 70 by the scrubber 64 is discharged to the outside through the discharge path 72 attached to the discharge container 70. The discharge path 72 is connected to the ramp 73 so that the collected laver powder can fall to a certain place. At this time, it is preferable that the discharge bin 70 and the discharge path 72 are made of a transparent material. When the discharge bin 70 and the discharge path 72 are transparent, it is possible to directly check the state in which the laver powder is removed, so that the rotational speed of the screw washing unit 60 can be appropriately controlled.

The screen net 50 is a cylindrical filtration means in which a plurality of screen eyes 50a are formed as described above, and the upper part is fixed by the upper ring 51, and the lower part is fixed by the lower ring 52. On the upper ring 51, there is a second O-ring 53 that prevents laver powder from overflowing, and the lower ring 52 is fixed to the fixing plate 20. That is, the screen net 50 is fixed and does not move. The diameter of the screen eye 50a may be variously set, for example, 0.2mm to 0.6mm, and the smaller the diameter of the screen eye 50a, the smaller the size of the laver powder that can pass through the screen net 50. have. That is, the screen eye 50a can reduce the laver powder passing through to the maximum, so that the laver powder flowing into the filtering means can be reduced to the maximum.

The outer region (b) exists between the case 30 and the screen net (50). In the outer region b, a brush structure 41 comprising a brush bar 41b equipped with a second brush 41a and a third brush 41c is inserted at both sides. Typically, the second brushes 41a are arranged in two rows and relatively thin brush hairs are employed, and the third brush 41c is arranged in one row and relatively thick brush hairs are employed. When the brush structure 41 rotates, the second brush 41a cleans the screen net 50, and the third brush 41c cleans the case 30. The second brush 41a uses a relatively thin brush bristle to increase the efficiency of cleaning the screen net 50 and blocks the passage of laver powder.

The brush bar 41b is attached to the manual gear 42 on the other side, and when the manual gear 42 rotates, the brush structure 41 rotates together. The passive gear 42 is engaged with the active gear 43, and the passive gear 42 and the active gear 43 are disposed on the cover 44. The active gear 43 rotates by receiving a rotational force from the second motor 45. When the active gear 43 rotates by the second motor 45, the passive gear 42 engaged therewith rotates, and the brush structure 41 rotates by the rotation of the passive gear 42. Accordingly, it is important to stably rotate the manual gear 42 and the brush structure 41 without shaking. This will be described in detail with reference to FIG. 5.

The case 30 is preferably a transparent material, and is made of the same material as the fixing plate 20, for example PVC-based, acrylic, or the like. If the case 30 and the fixing plate 20 are of the same material, the case 30 and the fixing plate 20 can be fused by heat, so that the purified water in the outer region (b) can be reliably blocked from leaking to the outside of the case 30. I can. If, if the case 30 and the fixing plate 20 are bonded with an adhesive, the adhesive strength of the adhesive decreases over time and water leakage may occur. 3 and 4, the brush structure 41 is mounted in the mounting groove 40a at a constant interval in the brush mounting table 40 on one side. Since there is an empty space between the brush structures 41, the purified water passing through the screen net 50 may flow.

5 is a perspective view for explaining a process of rotating the manual gear 42 in the recycling device according to an embodiment of the present invention. At this time, since the recycling device 100 is the same as described above, this will be referred to.

5, the cover 44 is provided with a gear receiving portion (42a) that provides a space for rotating the manual gear (42). The gear accommodating portion 42a has a stepped 49, and a roller 46 and a slip resin body 48 for stably rotating the manual gear 42 are disposed on a part of the stepped 49. The roller 46 is installed in the recessed roller receiving portion 47 on the inner side of the gear receiving portion 42a, and the slip-resistant resin body 48 is fixed to the stepped portion 49 between the roller receiving portions 47. At this time, the roller 46 and the slip resin body 48 coincide with the circumference of the same radius so that the manual gear 42 moves smoothly. It is preferable that the slippery resin body 48 is made of an engineering plastic containing oil.

The part contained in the manual gear 42 is inserted so as to contact the roller 46 and the slippery resin body 48. The roller 46 and the slip resin body 48 allow the manual gear 42 to rotate stably. If there is no roller 46 and slippery resin body 48, since the manual gear 42 rotates eccentrically, irregular rotation is caused in the brush structure 41. If the rotation is irregular, the wear of the manual gear 42 and the gear receiving portion 42a becomes severe, and the brush structure 41 is easily damaged. If the roller 46 does not operate properly, the slip resin body 48 implements stable rotation of the manual gear 42 before the roller 46 is replaced. The embodiment of the present invention can be selectively applied by applying the structure or size of the recycling device to any one of the roller 46 or the slip resin body 48 or a combination thereof.

6 is a diagram illustrating a modified example of FIG. 2. In this case, the screw washing unit 60a is the same as the screw washing unit 60 of FIG. 2 except that the spiral groove 81 is present. Accordingly, detailed description of the same reference numerals will be omitted.

According to FIG. 6, the screw cleaning part 60a includes a screw support 61 and a spiral protrusion 80 in a cylindrical shape, and a first brush 63 is provided in the spiral groove 81 formed along the spiral protrusion 80. Is planted. That is, the screw cleaning unit 60 is composed of a screw support 61, a spiral protrusion 80 having a spiral groove 81, and a first brush 63. When the screw washing unit 60 rotates in the clockwise direction, the laver washing water introduced from the inlet 13 is rotated by the spiral protrusion 80 having the spiral groove 81 and the first brush 63 attached thereto. It has a rising power. The lifting force is related to the second gap D2 which is the sum of the second protrusion height H2 and the third gap S3. Here, the second protrusion height H2 is the protruding height of the spiral protrusion 62, and the third spacing S3 is the distance between the spiral protrusion 80 and the screen net 50. The second protrusion height H2 has the same function and role as the first protrusion height H1.

As the second gap D2 increases, the lifting force decreases, but the amount of influent water to be treated increases. As the second gap D2 becomes smaller, the lifting force increases, but the amount of influent to be treated decreases. Accordingly, the second interval D2 of the present invention is appropriately adjusted in consideration of the amount of influent water to be treated, the lifting force, and the like. Meanwhile, when the spiral groove 81 is present, the third interval S3 may be smaller than the first interval S1. In this case, while sufficiently securing the lifting force by the spiral protrusion 80, it is possible to effectively clean the screen net 50. The depth of the spiral groove 81 is set in consideration of the lifting force of the laver washing water, the shape of the spiral protrusion 80, and the cleaning effect of the screen net.

The fact that the length of the hairs of the third spacing S3 and the first brush 63 is shortened and the thickness of the first brush 63 is shortened is the same as described in relation to the first spacing S1. In addition, when the third interval S3 is smaller than the first interval S1, the length of the hairs of the first brush 63 may be shortened and the thickness of the first brush 63 may be made thinner. In this case, the size of the screen eye 50a can be further reduced, so that the size and amount of the laver powder exiting the screen eye 50a is greatly reduced.

Above, the present invention has been described in detail with reference to preferred embodiments, but the present invention is not limited to the above embodiments, and various modifications are made by those of ordinary skill in the art within the scope of the technical idea of the present invention. It is possible.

10; Removal part support
11, 45; 1st and 2nd motor
12; Coupling 13; Inlet
14; Outlet 20; Fixed plate
21, 53; 1st and 2nd O-ring
30; Case 40; Brush mount
41; Brush structure
63, 41a, 41c; 1st to 3rd brush
42; Manual gear 43; Active gear
46; Roller 47; Roller receiving part
48; Slip resin body 49; Step
50; Screen network
50a; Screen eyes 51; Upper ring
52; Lower ring
60, 60a; Screw cleaning part
61; Screw support
62, 80; Spiral protrusion
64; Scrubber 65; Rotating pin
70; Discharge bin 71; Bearing
72; Discharge furnace 73; runway
81; Spiral groove 150; Nori powder removal unit

Claims (11)

Including a seaweed powder removal unit disposed on the removal unit support,
The laver powder removal unit
The center of the cylindrical screen net is divided into an inner inner area and an outer outer area, and in the inner area is a screw washing unit equipped with a first brush formed along a spiral protrusion that protrudes from the cylindrical support in a spiral shape,
The height of the spiral protrusion is gradually decreased or gradually increased or they are combined in consideration of the lifting force and flow of the laver washing water containing laver powder,
The spiral protrusion has a height of a first height (H1) and a first gap (S1) between the spiral protrusion and the screen net, and the first gap (S1) is reduced to shorten the hair length of the first brush. A laver washing water recycling apparatus having an improved screw washing unit, characterized in that the thickness of the first brush is thinned. The laver washing water recycling apparatus according to claim 1, wherein the outer region comprises a brush structure consisting of brush bars to which second and third brushes are attached to both sides. The laver washing water recycling apparatus according to claim 1, wherein the spiral protrusion includes a spiral groove recessed along the periphery, and the first brush is formed in the spiral groove. The laver washing water recycling apparatus according to claim 1, wherein the height of the spiral protrusion is constant throughout. delete According to claim 1, When the thickness of the first brush (filament) is thinner, the size of the aperture of the screen net corresponding to the thickness is also reduced. Device. The laver washing water having an improved screw cleaning unit according to claim 2, wherein the brush structure is rotated by a manual gear, and any one of a roller or a slip resin body or a combination thereof is provided around the manual gear. Recycling device. [8] The apparatus of claim 7, wherein the slip resin body is made of an engineering plastic containing oil. The laver washing water recycling apparatus according to claim 1, wherein a scrubber is mounted on the upper portion of the screw washing unit, and the scrubber pushes out laver powder rising from the inner region and discharges it from the discharge bin. . 10. The laver washing water recycling apparatus according to claim 9, wherein the discharge bin is made of a transparent material. The laver washing water recycling apparatus according to claim 1, wherein the outer area is an area between the screen net and the case, and the case and the cylindrical support are made of the same material.

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