KR101817999B1 - The device for dehydration of sludge - Google Patents

Abstract

A sludge dehydration device is disclosed. As the disclosed sludge dehydration device comprises a supply member, a sludge moving member, a sludge compression member, a water tank member, a water flow transmitting member, a primary moving member, and a secondary moving member, the sludge containing the water and the impurities is repeatedly compressed to increase a dehydration rate of the impurities and the water separated from the sludge can be recycled, and compared to a large sludge disposal system with drying equipment, the sludge dehydration device can be manufactured with a simple structure, thereby manufacturing costs can be reduced.

Description

The device for dehydration of sludge < RTI ID = 0.0 >

The present invention relates to a sludge dewatering apparatus.

Sludge refers to solid matter that has settled in the floors when the sewage is settled in a water tank or a water tank, and various sludge is produced during the sewage treatment process.

Conventionally, the sludge has been disposed of by a method of dumping or landing in the sea, but in recent years, it has become a major cause of environmental pollution. Therefore, water is dehydrated from impurities and dehydrated impurities thereof are widely utilized as energy.

The apparatus for removing water from the sludge containing water and impurities and for separating the impurities separately is a sludge disposal apparatus. An example of such a sludge disposal apparatus is the following patent document.

Conventional sludge disposal apparatuses have adopted a method of obtaining dehydrated sludge by drying water using hot air equipment or high temperature equipment. However, in the method of drying water as described above, And there was a problem that it was applicable only to a large-scale sludge treatment such as a sewage treatment plant because a high cost and a lot of manpower were required in the drying work process.

In addition, water separated from sludge containing soil or food can be used as agriculture water, but it is disadvantageous that it can waste water that can be recycled because it is dried.

No. 10-1308170, filed on Mar. 19, 2013, entitled " Sludge Treatment Apparatus with Dehydrator " Published Japanese Patent Application No. 10-2015-0053993, Publication Date: May 19, 201, entitled "Dewatering Treatment Method of Sludge and Dewatering Treatment Device"

It is an object of the present invention to provide a sludge dewatering apparatus which is simple in structure, has excellent dewatering rate of impurities, and can recycle water separated from sludge.

According to an aspect of the present invention, there is provided a sludge dewatering device comprising: a supply member to which sludge mixed with impurities is supplied; A sludge moving member for moving the sludge supplied from the supply member in one direction to another direction; A sludge compression member for compressing the sludge moved in the sludge moving member to separate water from the sludge; A water tank member in which the water separated from the sludge can be stored; A water transfer member for moving the water separated from the sludge to the water tank member; A primary moving member for moving the residual sludge mixed with the residual impurities precipitated in the lower part of the water stored in the water tank member and the water from one side of the water tank member to the other side of the water tank member; And a secondary moving member for moving the residual sludge moved in the primary moving member from the primary moving member toward the sludge moving member, wherein the sludge moving member includes a sludge moving case, A sludge moving blade formed in the form of a clockwise or counterclockwise thread at an outer surface of the sludge moving shaft so that the sludge can be moved along the thread, And a sludge moving means for rotating the sludge moving shaft, wherein the sludge moving case comprises a plurality of drain holes formed in the sludge moving case so that the water separated from the sludge can be drained to the outside of the sludge moving case, Wherein the impurities are removed from the sludge moving case A drainage hole for discharging the water discharged from the drainage hole to the water tank member; and a drainage hole for allowing the drainage hole to be operated, Wherein the water transferring case includes a water receiving portion to which the water drained from the drain hole is collected, a protective case for protecting the water moving portion, And a water drainage portion for draining to the tank member.

According to the sludge dewatering apparatus according to one aspect of the present invention, the sludge containing the water and the impurities is repeatedly compressed to increase the dewatering rate of the impurities, and the water separated from the sludge can be recycled , And the manufacturing cost can be reduced because the sludge treatment apparatus is manufactured in a simple structure as compared with the large sludge treatment apparatus having the drying equipment.

FIG. 1 is a perspective view of a sludge dewatering apparatus according to an embodiment of the present invention, which is connected to a garbage impurity separation and sedimentation apparatus, viewed from above at an angle. FIG.
FIG. 2 is a perspective view of the sludge dewatering apparatus according to an embodiment of the present invention, viewed from above at an angle; FIG.
FIG. 3 is a perspective view showing a sludge dewatering apparatus shown in FIG. 2 in which an outer frame is separated. FIG.
4 is a partial cross-sectional view of a supply member, a sludge moving member, and a sludge compression member constituting a sludge dewatering device according to an embodiment of the present invention, viewed from the front.
5 is an enlarged view of portion A shown in Fig.
6 is an enlarged view showing a state in which the pressing member and the compression force transmitting member shown in Fig. 5 are advanced forward; Fig.
FIG. 7 is a partial cross-sectional view of the water conveying member constituting the sludge dewatering device shown in FIG. 2, viewed from above at an angle.
8 is a partial cross-sectional view of the water tank member, the primary shifting member, and the secondary shifting member constituting the sludge dewatering apparatus shown in FIG. 2 viewed diagonally from above.
9 is a partial cross-sectional view of the water tank member, the primary shifting member, and the secondary shifting member shown in Fig.
Fig. 10 is an enlarged view of part B shown in Fig. 4; Fig.

Hereinafter, a sludge dewatering apparatus according to an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a perspective view of a sludge dewatering apparatus according to an embodiment of the present invention, which is connected to a garbage impurity separation and sedimentation apparatus, viewed obliquely from above, FIG. 2 is a perspective view of a sludge dewatering apparatus according to an embodiment of the present invention, FIG. 3 is a perspective view showing an outer frame separated from the sludge dewatering apparatus shown in FIG. 2, FIG. 4 is a perspective view illustrating a sludge dewatering apparatus according to an embodiment of the present invention, FIG. 5 is an enlarged view of the portion A shown in FIG. 4, and FIG. 6 is a front view of the compression member and the compression force carrier shown in FIG. FIG. 7 is a partial cross-sectional view of the water conveying member constituting the sludge dewatering device shown in FIG. 2, FIG. 9 is a partial sectional view of the water tank member, the primary moving member, and the secondary moving member constituting the sludge dewatering device shown in FIG. 2, Sectional view of the secondary moving member viewed from the rear, and Fig. 10 is an enlarged view of the portion B shown in Fig.

Referring to FIGS. 1 to 10 together, the sludge dewatering apparatus 100 according to the present embodiment includes a supply member 101, a sludge shifting member 110, and a sludge compression member 106.

In the present embodiment, the sludge dewatering apparatus 100 is connected to a waste impurity separation and precipitation apparatus 10 in which impurities are separated from the impurities by dipping the impurities so as to form sludge in which the impurities and water are mixed It is needless to say that it can be used separately without being connected with the waste impurity separation and precipitation apparatus 10 described above.

Further, in the present embodiment, the sludge dewatering device 100 further includes an outer frame 20 at the outer periphery thereof in consideration of the safety of the operator and the inner components.

The supply member 101 includes a sludge supply unit 102 and a sludge supply pipe 103 to which the sludge is supplied from the waste impurity separation and precipitation apparatus 10.

The sludge supply unit 102 is open at its upper part so that the sludge can be supplied.

Sectional area of the upper portion of the sludge supply portion 102 is formed to be relatively larger than a lower portion of the sludge supply portion 102 so that the sludge supply portion 102 can easily supply the sludge to the lower portion of the sludge supply portion 102, So that it is formed into a hopper shape such as a funnel.

The sludge supply pipe 103 connects the sludge supply unit 102 to the sludge moving member 110 to move the sludge to the sludge moving member 110.

The sludge supply pipe 103 may be formed in an elbow shape as in the present embodiment, or may be formed in an upright shape and connected thereto.

In addition, the sludge may be directly introduced into the sludge moving member 110 without the supplying member 101 if necessary.

The sludge moving member 110 moves the sludge supplied from the supplying member 101 in one direction to another direction and includes a sludge moving case 111, a sludge moving shaft 112, (113), and sludge moving means (114).

The sludge moving case 111 is formed in a cylindrical shape having a relatively long length in a predetermined direction and is connected to the sludge supply pipe 103 by screwing or welding, The sludge is moved into the sludge moving case 111.

In addition, the sludge moving case 111 includes a drain hole 115 formed in the sludge moving case 111 so that the water separated from the sludge can be drained to the outside of the sludge moving case 111, and the impurities separated from the sludge And a discharge hole 116 which can be discharged to the outside of the sludge moving case 111.

The sludge moving shaft 112 is rotated inside the sludge moving case 111.

The sludge moving blade 113 is formed in a clockwise or counterclockwise direction on the outer surface of the sludge moving shaft 112 so that the sludge can be moved along the thread, And is rotated together with the sludge moving shaft 112. The sludge moving shaft 112 is rotated with the sludge moving shaft 112 as shown in Fig.

The sludge moving means 114 rotates the sludge moving shaft 112 to which the sludge moving blade 113 is coupled.

In detail, as the sludge moving shaft 112 is rotated by the sludge moving means 114, the sludge moving vane 113 coupled with the sludge moving shaft 112 is rotated together with the sludge moving vane 113 The sludge is moved forward from the rear side where the sludge supply pipe 103 is formed and loaded on the distal end of the sludge moving shaft 112.

The sludge moving means 114 may be an electric motor or the like and may be connected directly to the sludge moving shaft 112 in front of or behind the sludge moving shaft 112. The sludge moving shaft 112 and the sludge moving means 114 may be separated from each other The sludge moving shaft 112 may be rotated by a chain or the like.

The sludge compression member 106 separates water from the sludge by compressing the sludge moved in the sludge shifting member 110. In the present embodiment, the sludge compression member 106 compresses the pressure member 119, And a compressive force transmitting body 117, as shown in Fig.

The pressing member 119 can be actuated forward and backward, and can be a pneumo-hydraulic cylinder or the like.

The present embodiment is characterized in that the pressing member 119 includes a hydraulic cylinder and the cylinder body constituting the hydraulic cylinder included in the pressing member 119 is coupled to the rear of the sludge moving member 110, The piston constituting the hydraulic cylinder included in the member 119 is inserted axially in the center of the sludge moving shaft 112 to be operated in forward and backward directions and the piston is mounted on the distal end of the sludge moving shaft 112 The sludge can be separated from the sludge by compressing the sludge.

The compression force transmitting member 117 is coupled to the distal end of the piston constituting the hydraulic cylinder included in the pressing member 119 so as to push the sludge directly so that a uniform compression force is transmitted to a wide range of the sludge And one surface which is in contact with the sludge is formed in a planar shape.

The maximum force of the compressive force transmitting body 117 is relatively smaller than the inner wall of the sludge moving member 110 so that most of the sludge loaded on the distal end of the sludge moving shaft 112 passes through the compression force transmitting body 117, The sludge is moved to the front side of the compressive force transmitting body 117 through the spacing space formed in the sludge moving member 110 and the sludge moved to the front side of the compressive force transmitting body 117, ) Will push you directly.

The drain holes 115 are formed in the lower part of the sludge moving case 111 to be relatively small in size so as to prevent the impurities from being discharged from the sludge moving case 111 and are separated from the sludge by the sludge compression member 106 And the water is drained to the outside through the drain hole (115).

Further, the front end of the sludge moving case 111 having the discharge hole 116 is formed with a relatively large diameter, so that the impurity moved forward can be separated from the sludge by the piston and the compressive force transmitting body 117 The sludge is supplied to the sludge supply member 101 through the discharge hole 116 without being moved backward together with the compression force transfer member 117.

Of course, the sludge may be separated into the water and the impurities by rotating the sludge moving shaft 112 of the sludge dewatering device 100. However, as in the present embodiment, the sludge compression member 106 ) To further increase the dewatering rate of the impurities by further compressing the sludge.

Further, in this embodiment, the sludge compression member 106 further includes a guide member 118.

A plurality of slots 117a spaced apart from each other are formed on the outer circumference of the compressive force transmitting body 117 and each of the slots 117a is formed in a predetermined position so that the outer circumferential portion of the compressive force transmitting body 117 is constant in the moving direction of the compressive force transmitting body 117 And is formed into a depressed shape.

The guide member 118 is fixed to the inner wall of the sludge moving case 111 and is formed in a plate shape and has a predetermined length in the length direction of the sludge moving case 111.

The guide member 118 formed as described above is inserted into one of the plurality of slots 117a and when the compression force transmitting member 117 is moved back and forth along the inside of the sludge moving case 111, 119 and the compression force transmitting body 117 coupled to the distal end portion of the piston is not rotated together with the sludge moving shaft 112 but is rotated along the guide member 118 Only forward and backward movement can be repeated.

Therefore, damage or breakage of the pressing member 119, which may occur when the piston and the compression force transmitting member 117 are rotated, can be prevented in advance.

A plurality of the guide members 118 may be used in the plurality of slots 117a.

Although the guide member 118 is included in the sludge compression member 106 in the present embodiment, the guide member is disposed outside the moving case 111, for example, at the outer periphery of the moving case 111, And may be connected to the piston so that the guide member 118 can support the piston to operate in the forward and backward directions.

Reference numeral 109 denotes a support connected between the sludge compression member 106 and the sludge shifting member 110 in a plurality of ways to prevent shaking generated during operation of the sludge compression member 106, So that the member 106 can be moved forward and backward only.

The sludge dewatering apparatus 100 further includes a water tank member 130, a water conveyance member 120, a first moving member 140, and a second moving member 150. [

The water tank member 130 includes a water inlet 131 through which the water is received, a check hole 132, and a partition wall 133.

The water receiving portion 131 is connected to the water conveyance member 120 to be described later and the water separated from the sludge is received.

The check hole 132 is for checking the state of the water stored in the water tank member 130 such as the amount of water and the degree of turbidity of the water or for cleaning suspended matters floating on the surface of the water, And is formed at an intermediate position between the upper surface of the water tank member 130 and the upper surface of the water tank member 130,

The partition wall member 133 is formed inside the water tank member and separates the space inside the water tank member. The first partition wall member 134, the second partition wall member 135, and the third partition wall member 136 ).

Specifically, the first partition wall member 134 protrudes vertically from the upper surface of the water tank member 130 in the bottom surface direction, and is spaced from the upper surface of the water tank member 130 by a predetermined distance, To a height spaced a certain distance from the bottom surface of the base 130.

The second partition wall member 135 protrudes vertically from the upper surface of the water tank member 130 in the bottom surface direction and is spaced apart from the first partition wall member 134, The first partition wall member 134 is spaced apart from the first partition wall member 134 by a distance equal to the distance from the bottom surface of the water tank member 130, The height of the water tank member 130 is smaller than that of the first partition wall member 134. [

The third partition wall member 136 protrudes vertically from the upper surface of the water tank member 130 and is spaced apart from the second partition wall member 135. The third partition wall member 136 is spaced apart from the upper surface of the water tank member 130, The distance between the first partition wall member 134 and the second partition wall member 135 is larger than the distance between the first partition wall member 134 and the second partition wall member 135 and extends to the bottom surface of the water tank member 130.

The water tank member 130 may be formed such that the gap between the bottom surface of the water tank member 130 and the first partition member 134 is greater than the gap between the bottom surface of the water tank member 130 and the second partition member 135, The impurities can be precipitated easily.

A space formed between the case of the water tank member 130 and the third partition wall member 136 is separated from the upper surface of the water tank member 130 and the upper portion of the third partition wall member 136 Only the water in which the residual impurities are minimized is stored.

 The water is discharged from the upper surface of the water tank member 130 in the space defined by the case 130 of the water tank member 130 and the first and second diaphragm members 134 and 135, The water is moved backward to the water receiving portion 131 of the water tank member 130 by being moved along the space separated between the upper portion of the member 134 and the upper portion of the second partition wall member 135 Can be prevented.

9, the distance from the bottom surface of the water tank member 130 is larger than that of the first partition member 134, the second partition member 135 is the next largest, When the water is received into the water tank member 130, the residual impurities contained in the water may flow into the water tank member 130, The water does not flow back to the outside through the water receiving portion 131 and the water is supplied to the first partition wall member 134 and the second partition wall member 130. However, 135, and the third partition wall member 136, respectively.

The lower portion of the third partition wall member 136 is formed in a connected state with the bottom surface of the water tank member 130 without a space so that the residual impurities are introduced into the third partition wall member 136 and the case of the water tank member 130 The third partition wall member 136 can not be moved to the space formed by the third partition wall member 136 and only the water is moved to the spaced space formed in the upper portion of the third partition wall member 136, The water in the space becomes able to store only the water in which the residual impurities are minimized.

As described above, the water in which residual impurities are minimized can be reused by removing water from the water tank member 130 by a pump or the like.

The water transfer member 120 moves the water separated from the sludge to the water tank member 130.

Specifically, the water transfer member 120 includes a water transfer case 121, a water transfer unit 123, and a water transfer means 124.

The water transfer case 121 includes a water receiving part 121a to which the water drained in the drain hole 115 is collected, a protective case 121b for protecting the water moving part 123, And a water drainage unit 121c for draining the water moved from the water tank unit 130 to the water tank member 130.

The water-soluble part 121a is positioned below the drain hole 115, and the upper part of the water hole 121a is opened to form the water.

The water receiving portion 121a may be coupled to the sludge moving case 111 by bolts or the like and may be formed at a relatively lower position than the drain hole 115 while being spaced apart from the lower portion of the sludge moving case 111. [ And the water falling down from the drain hole 115 may be supported.

The water moving part 123 moves the water drained in the drain hole 115 to the water tank member 130.

In the present embodiment, the water moving part 123 includes a water receiving part 126 for receiving the water received by the water receiving part 121a, and a water receiving part 126 for separating the separated water from the water receiving part 121c And a lower chain belt shaft 127 positioned at upper and lower portions of the chain belt 125. The upper chain belt 128 and the lower chain belt shaft 127 are connected to each other by a chain belt 125. [

The water receiving portion 126 is coupled to the chain belt 125 by screwing or welding or the like so that the upper chain belt shaft 128 and the lower chain belt shaft 127 together with the chain belt 125 Lt; / RTI >

The water flow moving unit 124 may be an electric motor or the like to operate the water flow moving unit 123.

In detail, when the water receiving portion 126 formed at a predetermined interval passes through the water receiving portion 121a through the lower chain belt shaft 127, the open portion of the water receiving portion 126 moves upward So that the water is collected into the water receiving portion 126.

When the water moving means 124 is connected to one of the upper chain belt shaft 128 and the lower chain belt shaft 127 to operate the chain belt 125, The portion 126 is moved together from the bottom to the top.

The water receiving portion 126 is moved upward together with the chain belt 125 and passes through the upper chain belt shaft 128 so that the water receiving portion 126 is rotated to rotate the water receiving portion 126 The opened portion is directed downward, so that the water collected in the water receiving portion 126 is moved to the water drainage portion 121c.

A water drainage hole 122 is formed in a lower part of the water drainage part 121c to drain the water to the water tank 130.

The primary shifting member 140 is disposed at a position where the residual sludge in which the water and the residual impurities mixed in the lower part of the water stored in the water tank member 130 are mixed is discharged from the one side of the water tank member 130 To the side.

Specifically, the primary moving member 140 includes a primary moving case 141, a primary moving shaft 142, a primary moving blade 143, and a primary moving means 144.

The primary moving case 141 has a cylindrical shape that is relatively long in one direction and can be coupled to a lower portion of the water tank member 130 in which the residual sludge can be moved.

The primary moving shaft 142 is rotated inside the primary moving case 141.

The primary moving wing 143 is coupled with the primary moving shaft 142 by welding or the like and is formed in a clockwise or counterclockwise threaded form on the outer surface of the primary moving shaft 142, The residual sludge can be moved along the thread of the moving blade 143.

The primary moving means 144 may be an electric motor or the like for rotating the primary moving shaft 142 to which the primary moving blade 143 is coupled, Or may be connected to a chain or the like to rotate the primary moving shaft 142 in a state where the primary moving shaft 142 and the primary moving means 144 are separated from each other. The primary moving means 144 rotates the primary moving wing 143 coupled to the primary moving axis 142 and the primary moving axis 142 to rotate the primary moving wing 143 The residual sludge located between neighboring wings is moved forward from the rear side where the primary moving means 144 is located along the thread of the primary moving wing 143 to move the primary moving shaft 142 Lt; / RTI >

The secondary moving member 150 moves the residual sludge moved in the primary moving member 140 from the primary moving member 140 to the sludge moving member 110, 151, a secondary moving shaft 152, a secondary moving blade 153, a secondary moving means 154, and a connecting member 155.

The residual sludge is moved in the secondary moving case 151 and is formed into a columnar shape relatively long in a certain direction. One end of the secondary sludge is connected to the primary moving case 141, So that the sludge is moved from the secondary moving member (150) to the sludge shifting member (110).

The secondary moving shaft 152 is rotated inside the secondary moving case 151.

The secondary movement wing 153 is formed in the form of a clockwise or counterclockwise thread on the outer surface of the secondary movement shaft 152 so that the residual sludge can be moved along the thread, Is coupled to the moving shaft 152 by welding or the like and is rotated together with the secondary moving shaft 152.

The secondary moving means 154 may be an electric motor or the like for rotating the secondary moving shaft 152 to which the secondary moving blade 153 is coupled, The secondary moving shaft 152 may be connected to the secondary moving shaft 152 by a chain or the like in a state where the secondary moving shaft 152 and the secondary moving unit 154 are separated from each other.

The connecting body 155 extends from the secondary case 151 and moves the residual sludge to the sludge moving member 110.

The secondary moving means 154 rotates the secondary moving wing 153 connected to the secondary moving axis 152 and the secondary moving axis 152 to rotate the secondary moving wing 153 The residual sludge located between neighboring wings is moved along the thread of the secondary moving wing 153 and the residual sludge moved as described above is returned to the sludge moving member 110 .

The water level of the water existing in the secondary moving member 150 is formed to be equal to the upper height of the tertiary partition wall member 136 constituting the water tank member 130, So that the water can be moved to an upper portion of the secondary moving member 150.

In this embodiment, the sludge moving case 111 moves the residual sludge discharged through the connecting body 155 into the sludge moving member 110, and moves the sludge moving case 111 from the outer periphery to the outer periphery And a residual sludge supply unit 155a formed of a funnel-shaped hopper which is inclined at an angle so as to be upwardly directed toward the bottom of the hopper.

The maximum outer size of the hopper in the residual sludge supply unit 155a facing the connecting body 155 is relatively larger than the maximum outer size of the connecting body 155, Even if a large amount of the residual sludge is moved, the residual sludge can be moved without a bottleneck section.

The sludge dewatering apparatus 100 may further include an opening and closing member 160 capable of opening and closing the drain hole 116 constituting the sludge shifting member 110. The opening and closing member 160 Includes an elastic member 162 and a discharge hole stopper 161.

The elastic member 162 provides elasticity and the discharge hole stopper 161 is connected to the elastic member 162 and formed at the upper end of the discharge hole 116 to open and close the discharge hole 116 .

The discharge hole stopper 161 closes the discharge hole 116 when the compression force for pushing the impurities separated from the sludge compression member 106 is smaller than the predetermined elastic force of the elastic member 162 The elastic member 162 is retracted so that the discharge hole stopper 161 can be retracted when the compression force for pushing the impurities separated from the sludge compression member 106 is greater than a predetermined elastic force of the elastic member 162 The elastic member 162 is moved in the direction in which the elastic member 162 contracts, and the impurities are discharged to the discharge hole 116.

The discharge hole stopper 161 is inclined at a predetermined angle so that the surface facing the sludge compression member 106 is directed downward toward the elastic member 162 from the center of the discharge hole stopper 161 to the outside thereof So that the impurities can be induced to be discharged.

10, when the impurities compressed by the operation of moving the sludge compression member 106 forward and rearward advance and reach the discharge hole stopper 161, the impurities are discharged to the discharge The impurities are moved along the inclined surface formed on the outer periphery of the hole stopper 161 and through the gap between the sludge moving case 111 and the discharge hole stopper 161, And the like.

As described above, the sludge compression member 106 repeats the forward and backward operations with the discharge hole stopper 161 closing the discharge hole 116, so that the impurities are repeatedly compressed in the stacked state The dehydration rate of the impurities is increased.

Hereinafter, the operation of the sludge dewatering apparatus 100 will be briefly described.

First, the sludge is supplied from the waste impurity separation / sedimentation apparatus 10 through the supply member 101.

Then, in the sludge moving member 110, the sludge is moved forward from the rear side where the sludge supplying member 101 is located, and is then loaded on the end of the sludge moving shaft 112.

Then, due to repeated forward and backward operations of the sludge compression member 106, the sludge is compressed and separated into the water and the impurities so that the water is transferred to the water transfer member 120, And is placed at the distal end of the sludge moving case 111 where the discharge hole 116 is formed.

The separated water is stored in the water tank member 130 via the water transfer member 120.

The residual sludge settling on the lower part of the water stored in the water tank member 130 is moved back into the sludge shifting member 110 via the first shifting member 140 and the second shifting member 150, do.

The sludge compression member 106 forms the separated impurities and separates the water from the residual sludge to form the residual impurities. The impurities and the residual impurities are separated from the discharge holes 116, The sludge moving case 111,

If the sludge compression member 106 compresses the impurities and the residual impurities less than the preset elastic force of the elastic member 162, the discharge hole stopper 161 does not move and the discharge hole 116 So that the impurities and the residual impurities are continuously deposited on the distal end of the sludge moving case 111.

The discharge hole 116 opened by the movement of the discharge hole stopper 161 is stopped when the squeezing force of the sludge compression member 106 pushing the impurity and the residual impurity is greater than the preset elastic force of the elastic member 162. [ The impurities and the residual impurities are discharged to the outside.

Further, the residue, from which the residual impurities have been separated, is again stored in the water tank member 130 via the water transfer member 120, so that the impurity content of the water stored in the water tank member 130 is reduced .

As described above, the sludge dewatering apparatus 100 is configured such that the water separated from the sludge flows through the sludge shifting member 110, the sludge compression member 106, the water flow transmitting member 120, The first moving member 140 and the second moving member 150 are successively passed through the member 130 and then returned to the sludge shifting member 110 are circulated.

The sludge dewatering device 100 configured as described above can repeatedly compress the sludge containing the water and the impurities to increase the dewatering rate of the impurities and recycle the separated water from the sludge, Compared to large sludge disposal equipment with drying equipment, it can be manufactured in a simple structure, thus reducing manufacturing cost.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the following claims And can be changed. However, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

According to the sludge dewatering apparatus according to one aspect of the present invention, it is possible to manufacture an apparatus capable of reducing the manufacturing cost by a simple structure, to increase the dewatering rate of impurities, to obtain water with minimal impurities, Which can be recycled.

100: Sludge dewatering device
101: Supply member
106: sludge compression member
110: sludge moving member
120: a flow-
130: Water tank member
140: primary shifting member
150: secondary moving member

Claims (10)

A supply member supplied with sludge in which impurities and water are mixed;
A sludge moving member for moving the sludge supplied from the supply member in one direction to another direction;
A sludge compression member for compressing the sludge moved in the sludge moving member to separate water from the sludge;
A water tank member in which the water separated from the sludge can be stored;
A water transfer member for moving the water separated from the sludge to the water tank member;
A primary moving member for moving the residual sludge mixed with the residual impurities precipitated in the lower part of the water stored in the water tank member and the water from one side of the water tank member to the other side of the water tank member; And
And a secondary moving member for moving the residual sludge moved from the primary moving member to the sludge moving member from the primary moving member,
The sludge moving member
A sludge moving case,
A sludge moving shaft rotated within the sludge moving case,
A sludge moving blade formed in the form of a clockwise or counterclockwise thread at an outer surface of the sludge moving shaft and capable of moving the sludge along the thread,
And sludge moving means for rotating the sludge moving shaft coupled with the sludge moving blade,
Wherein the sludge moving case includes a plurality of drain holes formed to allow the water separated from the sludge to be drained to the outside of the sludge moving case,
And a discharge hole through which the impurities separated from the sludge can be discharged to the outside of the sludge transfer case,
The water-
A water delivery case,
A water moving part for allowing the water drained in the drain hole to be moved to the water tank member,
And an oil transfer means for causing the water transfer means to operate,
The water-
A water receiving portion to which the water drained in the drain hole is collected,
A protective case for protecting the flow-
And a water drainage part for draining the water moved in the water flow moving part to the water tank member. delete delete delete The method according to claim 1,
The water tank member
A water receiving portion for receiving the water,
A confirmation hole for checking the state of the water and cleaning the floating matters floating on the surface of the water,
And a partition wall formed inside the water tank member to separate a space inside the water tank member,
Wherein the partition wall protrudes vertically from the upper surface of the water tank member at a predetermined distance from the upper surface of the water tank member and extends from the upper surface of the water tank member toward the lower surface of the water tank member, A partition wall member,
The water tank member is formed to be spaced apart from the first partition member and spaced apart from the upper surface of the water tank member by a distance equal to a distance between the first partition member and the second partition member, And a second partition wall member extending from the bottom of the water tank member by a predetermined distance, the height of the second partition wall member being relatively longer than the first partition wall member, A partition wall member,
Wherein the distance between the first partition wall member and the second partition wall member is larger than the distance between the first partition wall member and the second partition wall member, And a third partition wall member formed to extend relatively to the bottom surface of the water tank member,
The gap between the bottom surface of the water tank member and the first partition wall member is formed to be relatively larger than the gap between the bottom surface of the water tank member and the second partition wall member,
Only the water is moved through a gap formed by the upper surface of the water tank member and the upper portion of the third partition wall member in the space formed by the case of the water tank member and the third partition wall member so that only the water in which the residual impurities are minimized is stored Wherein the sludge dewatering device is a sludge dewatering device. The method according to claim 1,
The primary shifting member
A primary moving case,
A primary moving shaft rotated in the primary moving case,
A primary moving blade formed in the form of a clockwise or counterclockwise thread on an outer surface of the primary moving shaft and capable of moving the residual sludge along the thread,
And a primary transfer means for rotating the primary transfer shaft coupled with the primary transfer wing. 6. The method of claim 5,
The secondary moving member
A secondary moving case,
A secondary moving shaft rotated in the secondary moving case,
A secondary moving blade formed in the form of a clockwise or counterclockwise thread on an outer surface of the secondary moving shaft and capable of moving the residual sludge along the thread,
A secondary moving means for rotating the secondary moving shaft coupled with the secondary moving wing,
And a connecting body extending from the secondary moving case to move the residual sludge to the sludge moving member,
The water level of the water existing in the secondary moving member is formed to be equal to the upper height of the third partition member constituting the water tank member so that the water moves from the primary moving member to the upper portion of the secondary moving member The sludge dewatering device comprising: The method according to claim 1,
Wherein the sludge dewatering device further comprises an opening and closing member capable of opening and closing the discharge hole constituting the sludge moving member,
The opening and closing member includes an elastic member for providing elasticity,
And a discharge hole cap connected to the elastic member and formed in the upper end of the discharge hole to open and close the discharge hole,
Wherein the discharge hole stopper blocks the discharge hole when the compression force for pushing the impurities separated from the sludge compression member is smaller than a preset elastic force of the elastic member,
Wherein when the compression force for pushing the impurities separated from the sludge compression member is larger than the predetermined elastic force of the elastic member, the elastic member is contracted and the discharge hole stopper is moved in a direction in which the elastic member contracts, And the impurities are discharged through the discharge hole. 9. The method of claim 8,
The discharge hole stop
Wherein the surface facing the sludge compression member is inclined at a predetermined angle so as to be directed downward toward the elastic member from the center of the discharge hole stopper to thereby guide the impurities to be discharged. The method according to claim 1,
The sludge dewatering device
Wherein the water separated from the sludge sequentially passes through the sludge shifting member, the sludge compression member, the water flow transmitting member, the water tank member, the first shifting member, and the second shifting member, And returning to the sludge moving member again.

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