KR101935428B1 - A Dewatering Device - Google Patents

Abstract

The present invention relates to an inert matter dewatering device for transferring and dewatering the inert matter. More particularly, the present invention relates to a cylinder-pressurizing type inert matter dewatering device, which comprises: a hopper unit to which the inert matter is supplied; a hollow body unit into which the inert matter of the hopper unit flows; a transferring unit provided inside the body unit for transferring and pressing the inert matter; a screen unit communicating with the body unit for dewatering the moisture of the inert matter; and an inert matter discharge unit communicating with the screen unit to discharge dewatered inert matter to the outside while transferring. The inert matter supplied from the hopper unit is transferred by the transferring unit without being hindered in the body unit, so that water is discharged to the screen unit and the inert matter is easily discharged to the inert matter discharge unit, thereby dramatically enhancing the efficiency of the dewatering operation.

Description

[0001] The present invention relates to a dewatering device for a cylinder-

More particularly, the present invention relates to a dewatering device for dewatering a dewater, and more particularly, to a dewatering device for dewatering a dewater, and more particularly to a dewatering device for dewatering a dewater, A screen portion communicating with the transfer portion and the body portion for dewatering the moisture of the impurities and a contaminant discharge portion communicating with the screen portion for discharging the dehydrated contaminant to be discharged to the outside, To a cylinder-pressurized contaminant dewatering device in which moisture is discharged to a screen portion by being pushed while being conveyed by a conveying portion without being clogged, and contaminants are easily discharged to a contaminant discharging portion, and the efficiency of the dewatering operation is remarkably improved.

Generally, a screen is installed in a repair channel such as a drainage pumping station, a water supply depot, a related water supply pipe, a sewage disposal plant, and a dam, which are lower than the water surface, and the flooded impurities are screened by a screen. .

Normally, the contaminants collected and discharged through the screen take up a large volume due to a high water content. Therefore, the contaminants are transferred through a conventional contaminant transfer dehydrator to dehydrate the contaminants, thereby reducing the moisture content of the contaminants and discharging the contaminants to a minimum volume.

The structure of such a conventional contaminant transport dehydrator is roughly as follows.

A hollow body for receiving the impurities supplied from the hopper portion; a conveying means provided in the body for conveying the impurities and having a screw provided on the drive shaft; A tapered portion having a dewatering net and a water outlet for communicating with the dewatering net to pressurize the dirt and dehydrate the dirt, and a dirt discharge portion having a discharge port for discharging the dirt dehydrated in the tapered portion to the outside.

In the conventional contaminant conveying and dehydrator configured as described above, the contaminants are dehydrated while the contaminants are pressed on the inner surface of the tapered portion whose diameter is narrowed when the contaminants pass through the tapered portion provided with the dehydrating net, and the dehydrated water is discharged through the dehydrating net, The contaminants which have been discharged and moisture are continuously transferred are discharged to the outside through the discharge port at the discharge port of the contaminant which is connected to the taper portion.

However, in general, the sizes of the dusts collected by the places where the dusts are collected, the environment and the like are very various. In the conventional dusts removal and debris removal apparatus, there is no separate means for compensating the size of the dusts, The large-size contaminants are pressed too strongly to the dehydrating net through the feed screw, and the dehydrating net is frequently damaged or damaged.

Further, the small-sized contaminants are slightly depressed to the dehydrating net through the conveying screw, so that the dehydration is not effectively performed, so that the contaminants can not be dewatered in a state of high water content, There was a problem of being discharged.

In order to solve the above-mentioned problems, conventionally known is a 'contaminant transfer dehydrator with a variable ring' disclosed in Japanese Patent Laid-Open No. 10-2016-0127311.

Hereinafter, the construction and operation of the conventional 'debris conveying dehydrator with a variable ring' will be described.

A hollow body for receiving the impurities supplied from the hopper portion; a conveying means provided in the body for conveying the impurities and having a screw provided on the drive shaft; A tapered portion having a dewatering net and a water outlet for communicating with the dewatering portion and communicating with the dewatering portion and communicating with the dewatering portion and communicating with the dewatering portion, and a dewatering portion for discharging the dewatered dewatered material from the tapered portion, And a variable ring capable of being detachably attached to the pressure conduit is provided.

Therefore, the length of the pressurizing pipe can be varied by adjusting the quantity of the attaching and detaching ring depending on the size and size of the inflowing impurities, thereby changing the diameter of the front end of the pressurizing pipe, .

KR 10-2016-0127311 (publication number) 2016.11.03. KR 10-0797556 (registration number) 2008.01.17. KR 10-1998-0008293 (publication number) 1998.04.30.

However, in the conventional 'contaminant conveying dehydrator with a variable ring', a variable pressing means is formed at the end of the dehydrating section so as to communicate with the dehydrating net, and the attachment variable ring attached to the main variable ring of the variable pressing means It is possible to adjust the size of the front end of the pressurized pipe to adjust the degree of pressing the pressurized pipe to the pressurized pipe in the process of passing the obstacle through the pressurized pipe so as to pressurize and dehydrate the contaminants of various sizes However, this is inconvenient to use because it is necessary to attach or detach the variable ring every time according to the size of the obstacle to be transferred, and to change the diameter.

In addition, since the conventional dehydrator is configured to install or remove the variable ring, the manufacturing cost and the labor cost are high, which lowers the economical efficiency and detachably attaches the variable ring.

Further, in the conventional dehydrator, when the impurities such as the sanitary napkin, the vinyl material and the strap are not easily cut into the thin and long shape, there is a problem that the load of the motor is caught by the screw shaft or even the rotation of the screw is stopped or broken There arises a problem that the rotation of the screw is disturbed at the portion where the screw is moved from the hopper to the screw.

Furthermore, the fine particles of the impurities generated during the compression were fixed to the perforated network, blocking the perforated network or decreasing the size of the perforations, thereby preventing dehydration.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art,

 A cylinder-pressurized contaminant dewatering device in which water is discharged to the screen portion and the contaminants are easily discharged to the discharge portion of the screen by being pressed by the conveying portion without being hindered in the body portion by the hopper portion so that the efficiency of the dewatering operation is remarkably improved. The purpose is to provide.

Another object of the present invention is to provide a simple structure and convenient use by allowing the dehydration pressure, which is installed in the discharge port of the scum, to be controlled through the load of the weight.

Another object of the present invention is to eliminate the screw type to be combined with the impurities in the conveyance of the impurities and to provide the impure guide ribs at the end of the neck of the hopper which is the position where the impurities are most caught, So that the efficiency of the system can be improved.

It is another object of the present invention to provide a cleaning brush on the outer surface of a screen portion provided on a body portion to remove dirt sludge adhering to a dewatering hole of a screen portion, thereby enhancing dewatering efficiency of the screen.

In order to accomplish the above object, the present invention provides an apparatus for dewatering an object, comprising: a hopper unit 110 including an extension part 111, a tapered part 112, and a neck part 113 for supplying impurities; A hollow body 120 communicating with the neck portion 113 of the hopper portion 110 and allowing the contaminants to flow through the neck portion 113; A hydraulic cylinder 131 that is provided at one end of the body 120 and is connected to the operating rod 132 that is reciprocally slid in a reciprocating manner in the hydraulic cylinder 131, And a compression cigarette 133 that slides along the inside of the body 120 and performs opening and closing of the body that presses the contaminant flowing through the neck 113 and descends or stops the contaminants to the body. Transmission 130; A screen unit 140 formed on the other side of the body 120 and dewatered by the impurities conveyed and pressed by the impregnated transfer unit 130; And a compression tapered portion which is connected to one end of the screen unit 140 and has a smaller diameter as it goes from an inlet side to an outlet side so that a back pressure is formed and a contaminant can be compressed while a contaminant passing through the screen unit 140 flows. And a contaminant discharge unit 150 including the contaminant compression unit 151 to be discharged and discharged to the outside while the dehydrated contaminant is transferred.

The neck portion 113 formed in the hopper portion 110 of the present invention is further provided with a guide rib 113a through which the impurities supplied to the body portion 120 are guided.

The compression cistern 133 constituting the contaminant discharge unit 150 according to the present invention is formed in a hollow shape such that the compression cistern 133 can slide reciprocally by the expansion and contraction of the operation rod 132 along the inside of the body 120, And a compression plate 133b which is provided at a front end of the compression body 133a and presses the contaminants. The compression plate 133b is formed gradually thicker from the upper end to the lower end of the compression body 133a.

A plurality of dewatering holes 141 are formed in the screen unit 140 of the present invention so as to discharge water that is dewatered while the contaminants are pressurized by the dewatering unit 130, The inner diameter of the inner surface 141a of the screen 140 is gradually increased toward the outer diameter 141b of the outer surface of the screen 140.

In the present invention, a plurality of slot grooves (151a) are formed in the bottom surface of the inner wall of the compression tapered portion of the clogged discharge portion (150) from the inlet portion to the outlet portion, 151a are formed to have the same width as the inner diameter 141a of the dewatering hole 141.

The screen cleaning brush 160 may further include a screen cleaning brush 160 for cleaning the dewatering hole 141 to prevent the dewatering hole 141 from being clogged with debris of the dirt, A brush unit 161 installed on the outer surface of the brush unit 161 and slidably reciprocated along the screen unit 140 and a brush unit 161 installed on the upper side of the brush unit 161 and installed on the outer body unit 142 And a helical shaft rod 163 reciprocating the brush part 161 along the outer surface of the screen part 140 while rotating forward or backward by a motor 162 that is rotated by the motor 162.

In addition, a plurality of water jetting openings 164 are further formed at a central portion of the brush part 161 of the present invention at regular intervals along the circumferential direction so that water is sprayed to the screen part 140.

In addition, the end portion of the guide rib 113a of the present invention is spaced apart from the lower end surface of the neck portion 113 by a predetermined distance d.

The cylinder-pressurized contaminant dewatering device of the present invention is characterized in that the contaminants supplied from the hopper portion are pressed while being conveyed by the conveying portion without interfering with the inside of the body portion, whereby water is discharged to the screen portion and the contaminants are easily discharged to the contaminant discharging portion, .

In addition, the present invention is advantageous in that the structure is simple and convenient to use because the dehydration pressure, which is installed in the discharge port of the scum, is controlled by the load of the weight.

Further, according to the present invention, a screw system to be combined with a contaminant is eliminated in the conveyance of the contaminants, and the contaminant guide rib is provided at the end of the neck of the hopper, which is the position where the contaminants are most caught, so that even thin and long contaminants can flow well into the trunk. Is improved.

In addition, the present invention has an advantage that the dewatering efficiency of the screen is improved by providing a cleaning brush on the outer surface of the screen portion provided on the body portion to remove the sludge dregs fixed to the dewatering hole of the screen portion.

1 is a schematic state sectional view of a cylinder-pressurized contaminant dewatering apparatus according to the present invention,
FIG. 2 is another embodiment in which the impurities are pressurized and dehydrated in the body by the transfer part provided in the cylinder-pressurized contaminant dewatering device according to the present invention,
3 is a side view and a plan view of a cylinder-pressurized contaminant dewatering device according to the present invention, in which a guide rib is provided in a hopper part of a cylinder,
FIG. 4 is a state in which the cleaning brush provided in the cylinder-pressurized contaminant dewatering device according to the present invention is cleaned while reciprocating the outer surface of the screen portion,
FIG. 5 is an enlarged view of a slot groove of a dewatering hole and a contaminant compression unit of a screen unit provided in a cylinder-pressurized contaminant dewatering apparatus according to the present invention,
FIG. 6 is a state in which the contaminants are dewatered and discharged through the dirt discharge portion of the cylinder-pressurized dirt dewatering device according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

As shown in FIGS. 1 to 6, the cylinder-pressurized contaminant dewatering apparatus 100 according to the present invention comprises:

A hopper portion 110 composed of an extension portion 111, a tapered portion 112, and a neck portion 113 so as to supply the impurities;

A hollow body 120 communicating with the neck portion 113 of the hopper portion 110 and allowing the contaminants to flow through the neck portion 113;

A hydraulic cylinder 131 that is provided at one end of the body 120 and is connected to the operating rod 132 that is reciprocally slid in a reciprocating manner in the hydraulic cylinder 131, And a compression collar 133 which slides along the inside of the body 120 and presses the contaminants flowing through the neck 113 and closes or closes the contaminants to or from the body, A transfer unit 130;

A screen unit 140 formed on the other side of the body 120 and dewatered by the impurities conveyed and pressed by the impregnated transfer unit 130; And

And a contaminant discharging unit 150 connected to one end of the screen unit 140 and discharged to the outside while the dehydrated contaminant is transported,

The contaminant discharge unit 150 is provided with a compression tapered portion having a smaller diameter as it goes from the inlet side to the outlet side so that the back pressure can be formed by the contaminants passing through the screen unit 140, And a clogged discharge adjusting unit 152 provided at an outlet of the clogged compression unit 151 and controlling the discharge of the clogged product. The clogged discharge adjusting unit 152 includes a cover 152a A hinge 152b for rotating the cover 152a and a weight 152c provided on the cover 152a for controlling the discharge of the contaminants.

Generally, a screen is installed in a repair channel such as a drainage pumping station, a water supply water intake pipe, a related water supply pipe, a sewage treatment plant, and a dam, and the flooded impurities are screened with a screen, and then the collected contaminants are discharged to the outside, Dehydration of the water is carried out and only the dried impurities are removed.

Fig. 1 shows a schematic state sectional view of a cylinder-pressurized contaminant dewatering device of the present invention.

1, when water containing contaminants flows into the extension part 111 formed on the upper side of the hopper part 110, the water is supplied to the neck part (not shown) through the tapered part 112, 113 to the body 120. [0031]

Such contaminants can be mixed with vinyl, sanitary napkins, diapers, hair, cloth, etc., and the thin and long contaminants are not easily cut. When they are mixed with other contaminants, the contaminants are bundled together into the trunk 120 When a conventional screw is rotated to transport a contaminant, jamming may occur due to the obstacle being caught by the screw, and even the screw may be damaged.

Therefore, in the present invention, instead of the screw device installed inside the body 120, the impregnated transfer unit 130 in which the compression shaft 133 without the screw rotary screw device is installed is provided.

The impregnated transferring unit 130 includes the hydraulic cylinder 131, the operation rod 132 and the compression cylinder 133. The impurities are introduced into the body 120 through the neck 113, The operation rod 132 is extended by the hydraulic cylinder 131 by the operation of the control unit (not shown) so that the compression cistern 133 is moved toward the screen unit 140 and the contaminant discharge unit 150 Pushing the inflowing contaminants while pushing.

The contaminants pressurized by the compression syringe 133 are discharged by the back pressure formed by the compression tapered portion of the clogged discharge portion 151 formed on the clogged discharge portion 150 and the inner wall of the cover 152a The water is released (dehydrated) while being compressed, and the moisture that exits is discharged through the screen unit 140.

The hydraulic cylinder 131 is not limited to being operated by hydraulic pressure but is a name for integrating cylinders driven by pneumatic or electric power and may be operated at different intervals according to the state of impurities entering the hopper unit 110 .

The compression cylinder 133 constituting the contaminant discharge unit 150 includes a hollow compression body 130 formed to be reciprocally slidable by the expansion and contraction of the operation rod 132 along the inside of the body 120, And a compression plate 133b which is provided at the tip of the compression body 133a and presses the contaminants. The compression plate 133b is gradually thicker from the upper end to the lower end. That is, the compression plate 133b is formed such that its cross-sectional shape is gradually wider from one end to the other end, like a wedge shape.

When the compression plate 133b is retracted, the compression plate 133b moves forward in the direction of the screen unit 140 along the inside of the body 120 and pushes the contaminants backward. When the compression plate 133b is retracted, 120 are collapsed, so that some of the contaminants flow down (scatter) from the upper side to the bottom side (lower side) of the body 120. At this time, when the compression plate 133b is pressed while being advanced, the contaminant flowing down to the bottom of the body 120 by the inclined surface of the compression plate 133b is pushed up to the upper side again 3 (a)).

The lower portion of the compression plate 133b protrudes toward the screen 140 from the upper portion and slopes toward the upper portion to push the contaminant positioned in the opposite direction in the body 120 and move forward, Move it up to the top.

Therefore, the present invention can uniformly provide a compressive force to be pressed against the contaminants flowing into the inside of the body 120 by the compressed flat plate 133b formed in the compression cylinder 133, .

A plurality of dewatering holes 141 are formed in the screen unit 140 so as to discharge moisture that is dewatered while the contaminants are pressurized by the dewatering unit 130.

An outer body portion 142 is formed on the outer side of the screen portion 140. The outer body portion 142 has an outlet 142a through which the water dewatered through the dewatering hole 141 is discharged to the outside.

Accordingly, the impurities are dewatered through the dewatering hole 141 into the interior of the outer body portion 142 while being discharged by the discharge port 142a .

The outer body portion 142 may be extended to the contaminant compression portion 151 of the contaminant discharge portion 150.

In addition, the dewatering holes 141 formed in the screen unit 140 are formed in a shape gradually increasing in diameter from the inside to the outside. This is to prevent the debris from clogging the dehydration hole 141.

That is, the diameter of the outer diameter 141b formed on the outer wall surface portion of the screen unit 140 is larger than the inner diameter 141a formed on the inner wall surface portion of the screen unit 140 The debris of the contaminants flowing through the inner diameter can be easily discharged through the outer diameter to prevent the dehydration hole 141 from being clogged.

In addition, a plurality of slot grooves 151a are formed in the bottom surface of the inner wall of the compression tapered portion of the contaminant compression portion 151 of the impurity discharge portion 150 of the present invention from the inlet portion to the outlet portion. This is for the purpose of allowing moisture to be further dewatered from the contaminants pressed in the compression tapered portion of the contaminant compression unit 151 to flow to the screen unit 140 and discharged through the dewatering hole 141. Therefore, most of the moisture passing through the contaminant compressing unit 151 is discharged.

1, a dewatering hole is formed as shown in FIG. 2, and the slot groove 151a is formed only in the dirt discharging portion 150 where no dewatering hole is formed . In the present invention, the inner diameters of the slot groove 151a and the dewatering hole 141 are different from each other according to the inflowing contaminants and are formed to have an optimum width so that the contaminants do not flow into the inflow port. Therefore, when the contaminants are changed to a fine shape by compression, they are formed at intervals such that fine contaminants can easily escape. Therefore, if the width of the slot groove 151a is made equal to the inner diameter 141a of the dewatering hole 141, a passage through which the water that has not slipped out due to the dewatering hole moves, and a large dirt that can not escape through the dewatering hole, It will not escape to the groove.

The neck portion 113 formed in the hopper 110 is further provided with a guide rib 113a through which the impurities supplied to the body 120 are guided.

The guide ribs 113a are tapered from the upper portion of the inner wall of the neck portion 113 toward the lower portion. The guide ribs 113a are provided on the neck portion 113 and are provided only in the front and rear of the guide ribs 113a in the direction in which the compression cistern 133 moves. In the present invention, the neck portion 113 is rectangular in shape, unlike the cylindrical body portion 120, and the rectangular neck portion 113 has a square shape in a portion coupled to the body portion 120 as well. The shape of the neck portion that meets the body portion 120 is connected to the structure of the rectangular guide rib 113a to prevent the obstacle from being fixed at a position where the body portion 120 is engaged with the body portion 120. [

The contaminants flowing through the hopper part 110 are easily introduced into the body part 120 through the inclined part of the guide rib 113a provided in the neck part 113, So as not to directly contact the compression cylinder 133.

The end of the guide rib 113a is spaced apart from the lower end of the neck 113 by a predetermined distance d. This is to prevent the end of the guide rib 113a from coming into close contact with the outer surface of the compression cistern 133 when the compression cistern 133 passes the lower end surface of the neck 113.

This is because the compression rib 133 is slid along the inside of the body 120 and is positioned on the lower end surface of the neck 113 when the guide rib 113a is closed A contaminant is inserted into the space formed between the end of the guide rib 113a and the lower end of the inner wall surface of the neck 113. As a result, .

The contaminants entering the lower end of the guide rib can enter between the end of the neck 113 and the guide rib 113a but are moved between the guide ribs at the time of advancing and retracting the compression hole 133, . Since such a phenomenon is caused by the movement of the compression syringe, there is no need for the guide rib to be formed at the other position of the horizontal sash relative to the moving direction of the compression syringe.

Therefore, the compression cistern 133 at the time of forward advancing completely blocks the neck portion 113 so that the contaminants can not be further dropped to the body portion 120. The pushing-out claw 133 at the time of backward- So that the length of the extrusion opening 133 should be longer than the length of the neck 113. In this case,

The end of the guide rib 113a of the present invention is spaced apart from the lower end of the neck 113 by a predetermined distance d so that the end of the guide rib 113a and the inner wall of the neck 113 It is possible to prevent the contaminants from getting caught in the space formed between the lower end and the lower end.

The contaminant discharge unit 150 includes the contaminant compression unit 151 formed with a compression tapered portion and the contaminant discharge control unit 152 for controlling the discharge of the contaminants. The cover 152a, the hinge 152b, and the weight 152c.

The cover 152a is configured to open and close the outlet 151b of the contaminant compression unit 151 by the rotation of the hinge 152b, And the weight 152c is detachably attached to the outside to provide a back pressure to the contaminant discharged through the outlet 151b.

The weight 152c is provided at a weight of, for example, 10kg, 20kg, 30kg and so on, and the weight is appropriately selected and replaced according to the contaminant to be compressed.

Accordingly, when the contaminant discharging unit 150 flows into the contaminant compressing unit 151 while the contaminant is being pressurized, the cover 152a is opened by the rotation of the hinge 152b, The dehydrated contaminants are discharged.

Meanwhile, the screen unit 140 of the present invention is further provided with a screen cleaning brush 160 that cleans the dewatering hole 141 to prevent the dewatering hole 141 from being clogged with debris.

The screen cleaning brush 160 includes a brush part 161 attached to an outer surface of the screen part 140 and reciprocatingly sliding along the screen part 140, And a helical shaft rod 163 for reciprocating the brush part 161 along the outer surface of the screen part 140 while rotating forward or backward by a motor 162 installed on the outer body part 142, .

A plurality of water jetting openings 164 are further formed at a central portion of the brush portion 161 at predetermined intervals along the circumferential direction. The water jetting port 164 is connected to the water supply device 165 to spray water.

When the spiral shaft rod 163 is rotated forward by the forward rotation of the motor 162, the brush part 161 advances in one direction along the outer surface of the screen part 140, When the helical shaft rod 163 is reversely rotated by the reverse rotation of the motor 162 and the brush part 161 is moved backward in the reverse direction along the outer surface of the screen part 140 The dewatering hole 141 is cleaned. At this time, water is sprayed to the water jet opening 164 by the water supply device 165. The water rinsed in the dewatering hole 141 while being sprayed to the water jetting port 164 is discharged to the outside through the discharge port 142a.

An operation procedure of dewatering the contaminants through the cylinder-pressurized contaminant dewatering device 100 of the present invention constructed as above will be described below.

First, when moisture containing contaminants flows into the upper side of the hopper part 110, the water is supplied to the body part 120 through the neck part 113 at the lower end.

The contaminants supplied to the body 120 are conveyed and pressed toward the screen unit 140 by the compression cistern 133 of the conveying unit 130. [

Then, a back pressure is formed on the impregnated pressurizing part 150, so that the impurities are compressed and debris is dewatered through the dewatering hole 141 of the screen part 140, and the dewatered water is discharged to the outside through the discharge opening 142a .

When the continuous contaminant is squeezed by the above procedure, the cover 152a of the contaminant discharging control unit 152 is opened and the contaminant is discharged.

During this process, the screen cleaning brush 160 is operated to clean the dewatering hole 141, so that the dewatering operation of the dewater can be performed efficiently.

As described above, the cylinder-pressurized contaminant dewatering device according to the present invention comprises a hopper portion to which a contaminant is supplied, a hollow body portion into which the contaminant of the hopper portion flows, a conveying portion provided inside the body portion to press and press the contaminant, A screen part for dewatering the moisture of the impurities and a contaminant discharge part for communicating with the screen part to discharge the dewatered contaminants to the outside while being conveyed, so that the impurities supplied from the hopper part are conveyed by the conveying part The water is discharged to the screen portion and the contaminants are easily discharged to the discharge portion of the clogged object, and the efficiency of the dewatering operation is remarkably improved.

100: Cylinder pressurized contaminant dehydrator
110: Hopper section 111: Expansion section 112: Tapered section 113: Neck section 113a: Guide rib
120:
130: The contamination is sent
131: Hydraulic cylinder 132: Operation rod 133: Compression
133a: Compression body 133b: Compressed plate
140:
141: Dewatering hole 141a: Inner diameter 141b: Outer diameter
142: outer body portion 142a:
150:
151: Hollow compression section 151a: Slot groove 151b: Outlet 152: Clogged discharge control section
152a: cover 152b: hinge 152c: weight
160: Screen cleaning brush
161: brush part 162: motor 163: spiral shaft rod 164: water jet opening
165: Water supply device

Claims (8)

In an impurity dehydration apparatus,
A hopper portion 110 composed of an extension portion 111, a tapered portion 112, and a neck portion 113 so as to supply a contaminant;
A hollow body 120 communicating with the neck portion 113 of the hopper portion 110 and allowing the contaminants to flow through the neck portion 113;
A hydraulic cylinder 131 that is provided at one end of the body 120 and is connected to the operating rod 132 that is reciprocally slid in a reciprocating manner in the hydraulic cylinder 131, And a compression cigarette 133 that slides along the inside of the body 120 and performs opening and closing of the body that presses the contaminant flowing through the neck 113 and descends or stops the contaminants to the body. Transmission 130;
A screen unit 140 formed on the other side of the body 120 and dewatered by the impurities conveyed and pressed by the impregnated transfer unit 130; And
A compression tapered portion is formed which communicates with one end of the screen unit 140 and has a diameter decreasing from the inlet side to the outlet side so that a back pressure is formed while the contaminants passing through the screen unit 140 are introduced, And a contaminant discharging part (150) including the contaminant compressing part (151) to discharge the dehydrated contaminant to the outside,
A plurality of dewatering holes 141 are formed in the screen unit 140 so that the dewatered water is discharged while the impurities are pressed by the dewatering unit 130,
The dewatering hole 141 is formed to have a diameter gradually increasing from the inner diameter 141a formed on the inner wall surface portion of the screen portion 140 to the outer diameter 141b formed on the outer wall surface portion of the screen portion 140,
A plurality of slot grooves 151a are formed in the bottom surface of the inner wall of the compression tapered portion of the contaminant compression unit 151 of the contaminant discharge unit 150 from the inlet to the outlet,
And the width of the slot groove (151a) is formed to be equal to the inner diameter (141a) of the dewatering hole (141).
The method according to claim 1,
Wherein the neck portion (113) formed in the hopper portion (110) is further provided with a guide rib (113a) guided by a contaminant supplied to the body portion (120).
3. The method of claim 2,
The compression cylinder 133 constituting the contaminant discharge unit 150 includes a hollow compression body 130 formed to be reciprocally slidable by the expansion and contraction of the operation rod 132 along the inside of the body 120, (133a) and a compression plate (133b) provided at the tip of the compression body (133a) to press the contaminants, and the compression plate (133b) is formed thicker gradually from the upper end to the lower end. .
delete delete The method according to claim 1,
The screen unit 140 is further provided with a screen cleaning brush 160 that cleans the dewatering hole 141 to prevent the dewatering hole 141 from being clogged by debris of the dirt,
The screen cleaning brush 160 includes a brush part 161 attached to an outer surface of the screen part 140 and reciprocatingly sliding along the screen part 140, And a spiral shaft rod (163) reciprocating the brush part (161) along the outer surface of the screen part (140) while rotating forward or backward by a motor (162).
The method according to claim 6,
And a plurality of water jetting openings (164) are further formed at a central portion of the brush part (161) at regular intervals along the circumferential direction so that water is sprayed to the screen part (140).
3. The method of claim 2,
Wherein the end of the guide rib (113a) is spaced apart from the lower end surface of the neck portion (113) by a predetermined distance (d).

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