KR101326772B1 - Moisture material dehydrator for cylinder - Google Patents

Abstract

The present invention relates to a cylinder having dehydration holes balls used by being installed in a crimp type dehydrator dehydrating moisture material including leftover food by crimping method. More specifically, the present invention relates to a cylinder for a moisture material dehydrator which can strengthen the function of exhausting foreign substances by changing the size of hydration holes when the foreign substances like bone chips mixed in the moisture material during dehydration are exhausted, and can make crushing function and the function of changing the size of hydration holes in manufacturing easy. The cylinder for a moisture material dehydrator of the present invention has a number of hydration holes whose size can be changed and can be recovered to the original size by elasticity. Both ends of the cylinder include a number of cylinder bars forming a number of dehydration holes by being separately fixed to a connection flange, and meanwhile, the cylinder bar has an insertion protruded part and an insertion groove part on the upper part and the lower part respectively, and the insertion protruded part is inserted into the insertion groove part of an adjacent cylinder bar, and the insertion protruded part of an adjacent cylinder bar is inserted into the insertion groove part. A gap is formed between the insertion protruded part and the insertion groove part which the insertion protruded part is inserted into, in order to form hydration holes.

Description

Moisture material dehydrator for cylinder

The present invention relates to a cylinder having a dehydration hole that is installed in a pressurized dehydrator for dehydrating a moisture material containing a large amount of water such as food waste in a compressed (axial) manner.

More specifically, when debris such as bone fragments mixed with moisture substance escapes into the dehydration hole during dehydration, the size of the dehydration hole can be changed to enhance the discharge function of the debris, and the function of crushing and dehydration size during manufacturing It relates to a cylinder for a water dehydrator made of plastic deformation does not occur during the change function.

In general, there are various moisture substances containing a large amount of moisture, such as food waste, and these moisture substances are dehydrated in large quantities for the purpose of preventing, recycling, and recycling environmental pollution, so that they are treated separately from moisture.

The water dehydrator cylinder is provided with a plurality of dehydration holes, the dehydration hole is used in the form of a mesh (mesh) form or long oval shape.

Among them, the long elliptic dewatering hole is drilled in equal parts in the circumference of the cylinder member regardless of the number of dewatering holes parallel to or parallel to the axial direction of the cylinder.

The group boundary meat which distinguishes the long oval type dehydration hole can not describe elasticity in the circumferential direction as a wide width, but the elasticity between the group dehydration holes is narrow so that elasticity is exhibited. Here, the elasticity of the Kansal is one side of the dehydration hole. When a foreign material thicker than its width passes through, it is pushed toward the other side of the dehydration hole as much as the difference between the width of the dehydration hole and the thickness of the foreign material. It is the return of liquidity.

Conventional long oval dewatering hole is so large that the maximum flow width of the Kansal is comparable to the width of the other side dewatering hole. If the flow width of the casal is large, there is a high probability of plastic deformation due to repeated passage of foreign matter.

In this way, when the elasticity of the carcass deteriorates or causes plastic deformation, the width becomes wider, and the substance to be left in the cylinder is released, which adversely affects the dehydration of the moisture substance.

In order to solve this problem, the present applicant has provided a cylinder member for food dehydrator (KR) Utility Model No. 332787.

In the cylinder member for food dehydrator of the (KR) Utility Model No. 332787, the elasticity of the Kansal is reduced by placing the flow width limiting projection for limiting the flow width of the Kansal on the outer inner side of the long axis in order to reduce the size of the Kansal. To prevent plastic deformation.

Conventional dehydration hole is formed in the cylinder member has a problem that a predetermined deformation occurs by the elastic deformation is made in a short length of the casing. In order to solve this problem, one has to lengthen the length of the canals. In this case, the length of the long oval dehydration hole is too long.

In addition, in the conventional method of forming the steel plate by rolling the steel plate, the manufacturing cost increases due to factors such as an increase in the loss rate of the steel plate, and the size of the dewatering hole is not easily changed.

(KR) Utility Model Registration No. 332787

In order to solve the above problems, the present invention, the size of the dehydration hole is changed when foreign matters such as bone fragments to be mixed into the moisture material to be discharged to the outside during the process of dehydration without lengthening the length of the dehydration hole exits to the dehydration hole However, it is intended to provide a cylinder for a water dehydrator made of a plastic deformation so that a long bar (bar) is deformed when the dehydration hole is changed.

In addition, to provide a dehydration cylinder that can be broken, such as bone fragments and has a crushing function that can crush foreign matter to be discharged to the outside through the dehydration hole to facilitate the discharge of foreign substances such as bone fragments. do..

In addition, it is to provide a cylinder for a water dehydrator that can be provided with a function to change the size of the dehydration hole at the same time to reduce the manufacturing cost.

The present invention to achieve the above object is a water material dehydrator cylinder of the present invention, the number of dehydration holes vary in width, in the water material dehydrator cylinder returned to its original state by elasticity, both ends are spaced apart from the connection flange The cylinder bar includes a cylinder body for forming a plurality of dehydration holes by the cylinder bar is fixed, while the insertion bar and the insertion groove is formed in the upper and lower portions, respectively, the insertion projection is adjacent Is inserted into the insertion groove portion of the other cylinder bar, the insertion groove portion of the other cylinder bar is inserted into the insertion groove portion, a dehydration hole is formed between the insertion projection portion and the insertion groove portion is inserted into the insertion projection portion. It is characterized by having a gap as much as possible.

The cylinder bar is formed to alternately repeat the insertion protrusion and the insertion groove portion in the upper and lower portions.

A plurality of installation grooves are formed on the inner circumferential surface of the connecting flange so that a plurality of cylinder bars can be fixed at regular intervals. Preferably, the installation grooves are provided such that the upper end of the cylinder bar to be installed is opposed to the rotational direction of the moisture material. It is made to protrude inward.

The water dehydrator cylinder of the present invention made as described above includes a cylinder body having both ends of the cylinder bar fixed to the connecting flange so that the length of the cylinder bar is changed when the foreign substance is discharged, thereby changing the size of the dehydration hole. The length (size) of the ball is determined by the width of the insertion protrusion and the insertion groove, which has the advantage of preventing the occurrence of plastic deformation without lengthening the length of the dehydration hole.

In addition, the large size of the foreign material that rotates by the upper end (end portion) of the cylinder bar is rotated by the upper end (end portion) has the advantage that it can be more easily discharged to the outside.

In addition, by cutting the plate, using a plurality of cylinder bars that are manufactured so that the debris operation does not occur, it has the advantage of reducing the material loss by reducing the loss of material and at the same time dewatered by the spaced apart when fixing the cylinder bar By controlling the size of the ball has the advantage of easy size control of the dehydration hole.

1 is a partial perspective view of a cylinder for a water dehydrator showing a preferred embodiment of the present invention.
Figure 2 is a front view of the cylinder for water material dehydrator showing a preferred embodiment of the present invention.
Figure 3 is a schematic diagram of a cylinder bar of the cylinder for water dehydrator which is an embodiment of the present invention.
Figure 4 is a perspective view of a cylinder bar of the cylinder for water dehydrator which is an embodiment of the present invention.
Figure 5 is a schematic view of the flange for connecting the cylinder for water dehydrator which is an embodiment of the present invention.
Figure 6 is a schematic view of the auxiliary flange of the water dehydrator cylinder of the embodiment of the present invention.
Figure 7 is a schematic view of the end plate for connecting the cylinder for the water dehydrator which is an embodiment of the present invention.
Figure 8 is a schematic view of the auxiliary intermediate plate of the cylinder for water dehydrator which is an embodiment of the present invention.
Figure 9 is a schematic side separation of the cylinder for water dehydrator which is an embodiment of the present invention.
10 is a schematic view of a cylinder body of the water dehydrator cylinder which is an embodiment of the present invention.
Figure 11 is a side schematic view of a cylinder for water dehydrator showing another embodiment of the present invention.
12 is a schematic view of the intermediate plate of the auxiliary material for dehydrator cylinder for explaining another embodiment of the present invention.

It is to be understood that the terms and words used in the present specification and claims should not be construed as limited to a conventional or dictionary sense and that the configurations shown in the embodiments and drawings described herein are only the most preferred embodiments of the present invention It is to be understood that the invention is not limited to the specific embodiments disclosed herein, and that various equivalents and modifications may be made thereto without departing from the scope of the present invention.

The present invention is formed as shown in Figure 1 is a cylinder for water material dehydrator having a dehydration hole is used installed in the compression type dehydrator for dehydrating a moisture material containing a large amount of moisture, such as food waste (compression) type (S) to be.

Such a water material dehydrator cylinder (S) of the present invention is largely formed of a plurality of cylinder bars (11, 12) to form a cylinder body (10) having a plurality of dehydration holes, and the cylinder body (10) A connection made of a semi-circle (ring) in which a plurality of connecting holes 21 are formed so as to be fixed to both ends of the cylinder bars 11 and 12 and connected to another adjacent dehydrator cylinder S or another moisture dehydrator member. The auxiliary flange 30 in the form of a semi-circle (ring) is installed between the flange 20 and the connecting flange 20, and the cylinder body 10 is installed on both ends of the connecting flange 20 ) For supporting the connection flange 20 and the connection end plate 40 having a plurality of connection holes 42 formed thereon, and the connection flange 20 and the support flange 30 are installed. It consists of a combination of the components (members) of the intermediate plate 50.

The cylinder body 10 is formed in a zigzag form as shown in Figs. 3 and 4 to insert a plurality of '┏┓' type insertion protrusions (15, 15 ') and' ┗┛ 'type in the upper and lower portions, respectively. End cylinder bar 12 having a combination of a plurality of cylinder bars 11 having grooves 16 and 16 'formed therein, preferably having an insertion protrusion and an insertion groove only at either one of the upper and lower portions. It is preferable to include.

Cylinder bar (11, 12) made as described above can be produced by cutting the iron plate having a certain width as a processing method such as press processing, laser processing, as shown in Figure 3 to minimize the pieces (pieces) discarded during manufacturing It can prevent the loss of material.

9 and 10,

The plurality of cylinder bars 11 formed as described above are fixedly installed by a method such as welding at regular intervals on the inner circumference of the connecting flange 20 located at both ends, and installed on the inner circumference of the connecting flange 20. The height h of the dehydration hole 1 is determined according to the intervals.

That is, the size of the plurality of dehydration hole (1) is determined by the height (h) and length (L), the height (h) is determined in accordance with the interval installed on the inner circumference of the connecting flange 20, the length L is determined by the width of the insertion protrusions 15 and 15 'and the insertion grooves 16 and 16'.

By forming the cylinder body 10 having a plurality of dehydration holes 1 by using the cylinder bar 11 having the insertion protrusions 15 and 15 'and the insertion grooves 16 and 16' as described above. The dehydration hole (1) is formed so that a plurality of spaced apart in the center axis direction of the cylinder, while the plurality of dehydration holes (1) in the center axis direction of the cylinder are connected to each other. For this reason, the length of the dehydration hole 1 can be processed into the shape of a long hole or the shape of a short hole.

Referring to Figure 5,

The connection flange 20 is formed in a semi-circle (ring) shape, a plurality of connection holes 21 are formed so that the connection member such as bolts or rivets are installed, the coupling formed on the end plate 40 for connection at both ends Coupling projection 22 is inserted into the ball 41 is formed, the installation hole 23 is formed in the middle portion so that the auxiliary intermediate plate 50 is installed.

Thus, the inner circumference of the connecting flange 20 formed in a semi-circular (ring) form is installed in the welding method, the cylinder body 10 made of a plurality of cylinder bars, by the connecting end plate 40 and Figure 1 2 and 9 are combined (combined) as shown.

Referring to FIG. 6,

The auxiliary flange 30 is formed in the shape of a semi-circle (ring), such as a connecting flange 20 made of a semi-circle (ring) form, the both ends are inserted into the coupling hole 41 formed in the connecting end plate 40 Coupling projection 32 is formed, the installation hole 33 is formed in the middle portion so that the auxiliary intermediate plate 50 is installed.

The auxiliary flange 30 is installed between the connecting flange 20 as shown in Figure 2 and 10 to support the cylinder body 10 made of a plurality of cylinder bars in the middle to sag the cylinder bar, etc. It supports to prevent the same deformation.

Referring to Figure 7,

A plurality of coupling holes 41 are formed in the connecting end plate 40 so that the connecting flange 20 and the auxiliary flange 30 are installed, and the coupling holes 41 are connected to each other such as bolts or rivets. A plurality of connection holes 42 are formed so that the member is installed, while the connection flange 20 is formed wider than the width of the connection flange 20 so as to protrude inward when installed in the connection flange 20, and has a supporting portion 43, The supporting portion 43 supports the cylinder bars 11 and 12 of the cylinder body 10 as shown in FIG.

Referring to FIG. 8,

The auxiliary intermediate plate 50 is fitted in correspondence with the installation holes 23 and 33 to be installed in the installation holes 23 and 33 formed in the connection flange 20 and the auxiliary flange 30, respectively. 51 is formed to serve to support the connection flange 20 and the auxiliary flange (30).

The cylinder (S) for the dehydrator, which includes a cylinder body forming a plurality of dehydration holes by the cylinder bar made as described above, has to be discharged to the outside through the dehydration hole such as bone fragments when dehydration of moisture substance. The size of the dehydration hole (1) is changed as shown in Figure 10 so that it can be more easily discharged, the cylinder bars (11, 12) fixed at both ends of the connection flange 20 when the size of the dehydration hole (1) ) Is made by deformation.

In this way, the cylinder bars 11 and 12 having a long length are deformed to change the size of the dehydration hole 1, thereby changing the dehydration hole 1 due to the discharge of foreign matter. Will not cause plastic deformation. In addition, the length L of the dehydration hole 1 is determined by the width of the insertion protrusions 15 and 15 'and the insertion grooves 16 and 16', so that the cylinder bars 11 and 12 to prevent plastic deformation. Since the relationship with the length of the dehydration hole (1) in the state to minimize the length (L) is a structure that can prevent plastic deformation.

11 and 12 are related to the cylinder for water dehydrator made to have a crushing function that can crush the debris, such as bone fragments,

For installation at equal intervals so that the cylinder bars 11 and 12 may be installed at regular intervals on the inner circumference of the connecting flange 20 where the cylinder body 10 including the cylinder bars 11 and 12 is installed. The groove 25 is formed, and the installation groove 25 is formed such that the upper end portion 11a of the cylinder bar 11 protrudes inward as shown in FIG. 11. That is, the groove 25 for installation on the inner circumference of the connecting flange 20 so that the upper end portion 11a (upper end portion) of the cylinder bar 11 protrudes inward to face the direction in which the moisture substance rotates. ) Is formed.

In addition, as shown in FIG. 12, it is preferable that an installation groove 35, such as the connection flange 20, is formed on the inner circumference of the auxiliary flange 30.

As such, the cylinder for water substance dehydrator (S) having a crushing function capable of crushing a debris that can be crushed such as bone fragments is dehydrated by crushing a foreign substance such as a bone fragment having a larger size than the dehydration hole (1). The dehydration hole (1) is excessively deformed by allowing it to be discharged to the ball has the advantage of preventing the occurrence of plastic deformation.

S: Cylinder for dehydrator h: Spacing
L: Dehydration Length 1: Dehydration Hole
10: cylinder body 11, 12: cylinder bar
20: connection flange 30: auxiliary flange
40: connection end plate 50: auxiliary intermediate plate

Claims (5)

In the cylinder for water dehydrator made of a plurality of dehydration holes are changed in size but returned to its original state by elasticity,
A plurality of cylinder bars 11 in which a plurality of '┏┓' shaped insertion protrusions 15 and 15 'and' ┗┛ 'shaped insertion grooves 16 and 16' are formed in a zigzag form on the upper and lower portions, respectively. Combination to form the cylinder body 10,
When the plurality of cylinder bars 11 are combined, a plurality of gaps formed in the cylinder body 10 are formed between the insertion protrusions 15 and 15 'inserted into the insertion grooves 16 and 16'. The dehydration hole (1) is to be formed, but when the foreign matter passes through the dehydration hole (1) so that the dehydration hole (1) is connected only to both ends of the cylinder bar (11) so that deformation does not occur due to plastic deformation flange 20 Fixed to the
Dehydration work by adjusting the separation distance from the adjacent cylinder bar 11 when combining a plurality of cylinder bars 11 and adjusting the size of the insertion protrusions 15 and 15 'and the insertion grooves 16 and 16'. (1) It is possible to control the size, the cylinder for water dehydrator, characterized in that made to prevent plastic deformation of the dehydration hole (1) due to the passage of foreign matter. The method of claim 1,
The inner circumferential surface of the connecting flange is a cylinder for water dehydrator, characterized in that a plurality of installation grooves are formed so that a plurality of cylinder bars can be fixed at regular intervals. 3. The method of claim 2,
The installation groove is a cylinder for water dehydrator, characterized in that the upper end portion of the cylinder bar to be installed is provided with a shredding function to protrude inwards to face the rotation direction of the moisture material to crush the foreign matter. The method of claim 1,
The cylinder for the water dehydrator, characterized in that the upper end of the cylinder bar protrudes inward to face the rotational direction of the moisture material and has a crushing function to crush the foreign matter. delete

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