KR20160054329A - Interworking method of plural centrifuge - Google Patents

Abstract

The present invention relates to a plurality of centrifugal separator interlocking methods, and more particularly, to a centrifugal separator having a plurality of centrifugal separators (100), which are sequentially driven so that, before the operation of the centrifugal separator (100) And the wastewater supplied to the centrifugal separator (100) which is pre-driven at the time of starting the preliminary driving of the centrifugal separator (100) is supplied to the centrifugal separator (100) .
As described above, the plurality of centrifugal separator interlocking methods of the present invention can sequentially operate a plurality of centrifugal separators, thereby enabling continuous operation during a large amount of waste water treatment, shortening the working time, and providing a relatively low-cost vertical centrifugal separator There is a remarkable effect that it is economically advantageous to use.

Description

[0002] Interworking method of plural centrifuge [

The present invention relates to a method of interlocking a plurality of centrifuges, and more particularly, to a method of interlocking a plurality of centrifuges, which includes a plurality of centrifugal separators and sequentially drives the centrifugal separators, ≪ / RTI >

In order to separate the water and the sludge contained in the wastewater, centrifugal force acts on the centrifugal separator when the container in which the wastewater is dewatered is rotated, and the material is separated by the density difference. Such a centrifugal separator is called a centrifugal separator.

Prior art for centrifugal separator is disclosed in Korean Patent Publication No. 2011-0096881, which is installed in a direction perpendicular to the bottom surface; A rotating body rotatably installed in the case, the rotating body including a cylindrical portion and a conical portion; A screw conveyor rotatably installed in the rotating body; A main motor for rotating the rotating body; And a speed reducer which decelerates the rotational speed of the screw conveyor more than the rotational speed of the rotary body.

Another prior art is a centrifugal separator in which industrial waste slurry is supplied through a slurry feed pipe, separated into a supernatant and a solid by centrifugal force, and separated and discharged into a supernatant outlet and a solids outlet, respectively, in Japanese Patent Registration No. 1446588, A case having a supply pipe, a supernatant discharge port and a solids discharge port; At least one solid matter discharge hole formed at the lower end of the side wall so as to discharge the solids to the solids discharge port of the case, and at least one solids discharge hole formed at the lower end of the side wall so as to discharge the solids through the bearing assembly, And at least one or more supernatant liquid discharging holes formed on the upper wall so that the supernatant liquid is discharged into the supernatant liquid discharging port of the case; A rotor driving motor for supplying rotational power to the rotating body; And a rotation driving unit that is coupled to the rotating body so as to be rotatable about a rotational axis in a vertical direction within the rotating body and receives rotational power from the rotating body driving motor through a speed reducer to rotate at a lower speed than the rotating body, And a screw conveyor comprising a hollow cylindrical body for receiving the industrial waste slurry received therein and discharging the waste slurry to the inside of the rotating body through at least one slurry discharge opening formed in the side wall, and a screw formed in a spiral direction on the outer peripheral surface of the cylindrical body Wherein the bearing assembly comprises a rolling bearing comprising a rolling body rolling contact between an inner ring integrally fixed to a rotary shaft of the rotary body and an outer ring integrally fixed to the case side, and the outer ring is filled with air An airblock of elastic material is used to fasten A vertical centrifugal separator equipped with a bearing air block is disclosed.

As described above, the conventional centrifugal separator is mostly driven independently. In order to remove the sludge accumulated in the centrifugal separator, it is necessary to stop the centrifugal separator. During this time, a large amount of waste water is treated It takes a lot of time to do so.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a method of interlocking centrifugal separators, which is capable of handling a large amount of waste water by sequentially interlocking with a plurality of centrifugal separators.

The plurality of centrifugal separator interlocking methods of the present invention include a plurality of centrifugal separators and are sequentially driven so that preliminary driving of the next centrifugal separator is started before the operation of the centrifugal separator being driven is started, The waste water supplied to the centrifugal separator 100 is supplied to the centrifugal separator 100 which is driven afterward.

As described above, the plurality of centrifugal separator interlocking methods of the present invention can sequentially operate a plurality of centrifugal separators, thereby enabling continuous operation during a large amount of waste water treatment, shortening the working time, and providing a relatively low-cost vertical centrifugal separator There is a remarkable effect that it is economically advantageous to use.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic diagram showing a plurality of centrifuges according to the present invention. Fig.
2 is a schematic cross-sectional view of the centrifuge of the present invention.
Figures 3 and 4 are schematic diagrams of the operating states of the clutch means mounted on the centrifuge of the invention.
5 is an enlarged schematic view of a part of the centrifuge of the present invention.
6 is a partial enlarged photograph of the centrifuge of the present invention.

In the present invention, a plurality of centrifuges (100) are provided and sequentially driven so that preliminary driving of the next tea centrifuge (100) starts before the operation of the centrifugal separator (100) The wastewater supplied to the centrifugal separator 100, which is pre-driven at the time, is supplied to the centrifugal separator 100 which is driven later.

Each of the plurality of centrifuges 100 is provided with respective individual controllers C1 and C2 and can be individually driven and controlled when the centrifugal separators 100 are interlocked with each other will be.

The centrifuge 100 includes a frame 110; A drain pipe (122) which is supported in a vertical direction on the bottom surface by the frame (110) and in which an internal space is formed, and a drain pipe (121) An outer cylinder 120 formed with a cylinder block; A center shaft 130 formed at an upper center portion of the outer cylinder 120; A first driving means (140) for rotationally driving the central axis; An impeller 150 rotating along the rotation of the outer cylinder 120 in the outer cylinder 120; And second driving means for driving the impeller 150.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, a method for interlocking a plurality of centrifuges according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view showing a plurality of centrifuges according to the present invention.

As shown in FIG. 1, the foot of the present invention includes a plurality of centrifugal separators 100, which are sequentially driven. In order to prevent the centrifugal separator 100 from being driven, The wastewater supplied to the centrifugal separator 100, which is pre-driven at the time of starting the operation, is supplied to the centrifugal separator 100 that is driven afterward.

That is, in a plurality of centrifuges (100), wastewater is supplied to one centrifuge (100) and is driven to separate sludge and water in the wastewater.

At this time, the process of supplying the wastewater and separating the water and the sludge follows the operation of the conventional centrifugal separator 100.

However, since the sludge accumulates in the centrifugal separator 100, it takes a long time to clean the sludge.

Accordingly, the operation of the centrifugal separator 100 is essentially stopped. When the operation of the centrifugal separator 100 is stopped, the centrifugal separator 100 of the next car is operated.

Particularly, the centrifugal separator 100 requires a predetermined driving time to reach a rotational speed of a certain trajectory since separation operation can be performed when the centrifugal separator 100 reaches a certain rotational speed.

For example, if the pre-driving centrifugal separator 100 is set to drive for 2 hours, if the time for the post-driven centrifugal separator 100 to reach the rotational speed of the trajectory is 5 minutes, the centrifugal separator 100 Starts to drive 5 minutes before the centrifugal separator 100 starts to operate, and when it is exactly 2 hours, the waste water supplied to the centrifugal separator 100 is supplied to the centrifugal separator 100 after the driving.

Since the means for supplying the wastewater is a well-known means of tolerance, detailed description is omitted.

Each of the plurality of centrifuges 100 is provided with respective individual controllers C 1 and C 2 so that they can be individually driven. When the plurality of centrifuges 100 are interlocked with each other, Respectively.

FIG. 2 is a schematic sectional view of the centrifugal separator of the present invention, FIGS. 3 and 4 are schematic views of the operating state of the clutch means mounted on the centrifugal separator of the present invention, FIG. 5 is an enlarged schematic view of a part of the centrifugal separator of the present invention, An enlarged view of a portion of the centrifuge.

The centrifugal separator 100 of the present invention is provided with an outer tube 120 supported in a vertical direction to the frame 110. A water inlet tube 121 for receiving wastewater is formed in a lower portion of the outer tube 120, And a discharge pipe 122 through which waste water is discharged is formed on the upper outer side surface.

A center shaft 130 is formed at an upper center portion of the outer cylinder 120 and a first driving means 140 for rotationally driving the center shaft 130 is provided.

The first driving means 140 includes a pulley 141 installed on the upper portion of the central shaft 130 and rotating integrally with the central shaft 130 and a first driving motor 143 for rotating the pulley 141 The pulley 141 receives the rotational power of the first drive motor 143 by the belt 142. [

Accordingly, the centrifugal separator 100 is constructed such that the sludge contained in the wastewater by the centrifugal force generated when the wastewater received through the water inlet pipe 121 of the outer cylinder 120 is rotated during rotation of the outer cylinder 120 is discharged to the inner surface of the outer cylinder 120 And the water is discharged to the outside through the discharge pipe 122 to separate the water and the sludge.

The impeller 150 is configured to rotate along the centrifugal force formed by the rotation of the outer cylinder 120. The impeller 150 rotates along the centrifugal force of the outer cylinder 120, The relationship will be described in detail below.

In order to remove the sludge collected in the outer cylinder 120, the impeller 150 is rotated in the state where the outer cylinder 120 is stopped or the impeller 150 is stopped or the outer cylinder 120 in the direction opposite to the direction of rotation.

Accordingly, the second driving means 160 for rotationally driving the impeller 150 is installed.

The second driving unit 160 includes a rotating shaft 161, a first gear 162 mounted on an upper end of the rotating shaft 161, a second gear 163 meshing with the first gear 162, A drive shaft 165 for driving the second gear 163 to rotate; and a second drive motor 166 for driving the drive shaft 165.

Particularly, the center shaft 130 for rotating the outer cylinder 120 is formed in the shape of a hollow tube, and the rotation shaft 161 is inserted into the center shaft 130 through the upper portion of the outer cylinder 120 .

The first gear 162 and the second gear 163 are installed as bevel gears so that the drive shaft 165 for driving the second gear 163 is installed to be perpendicular to the rotation shaft 161.

Therefore, the drive shaft 165 is rotationally driven by the second drive motor 166 and the second gear 163 is also rotated by the rotational drive of the drive shaft 165, so that the power transmission direction The first gear 162, which is gear-engaged so as to be rotated, rotates the rotating shaft 161, thereby forcing the impeller 150 to rotate.

If the first gear 162 and the second gear 163 are always kept in the gear engagement state, the rotation of the outer cylinder 120 may interfere with the rotation of the impeller 150, A clutch means 170 for selectively controlling the gear engagement of the first gear 162 and the second gear 163 is provided.

The configuration of the clutch means 170 is as follows.

The drive shaft 165 is fixed to the second drive motor 166 and a guide bushing 172 for linearly moving the drive shaft 165 on the drive shaft 165 is mounted.

A second gear 163 engaged with the first gear 162 is fastened to the front surface of the guide bushing 172.

The second gear 163 and the guide bushing 172 are engaged with each other so that the second gear 163 is rotated by the rotation of the drive shaft 165 but the guide bushing 172 is not rotated.

The tightening relationship between the guide bushing 172 and the second gear 173 is made possible by a joint or a bearing, so that detailed explanation is omitted.

Particularly, the outer peripheral surface of the drive shaft 165 is formed in a sawtooth shape and the inner peripheral surface of the corresponding second gear 172 is formed in a sawtooth shape. By forming the inner peripheral surface of the guide bushing 172 smoothly, Is transmitted to the second gear 173 only.

Further, the lower end of the support bar 174 standing upright in parallel with the rotary shaft 161 is fixed on the frame 110.

The hinge shaft 173 is fastened to the support bar 174 so that the seesaw bar 172 performs seesaw motion. The upper end of the seesaw bar 172 is hinged to the side of the guide bushing 172, And is hinged to a cylinder 175 that linearly moves horizontally.

Therefore, the seesaw bar 172 performs seesaw motion due to the horizontal linear motion of the cylinder 175, and the guide bushing 172 fastened to the upper end of the seesaw bar 172 linearly moves on the drive shaft 165, The second gear 163 fastened to the front surface of the guide bushing 172 also linearly moves to be engaged with the first gear 162 so as not to transmit or transmit the power.

Particularly, since the third gear 164, which is opposed to the first gear 162, is mounted on the upper surface of the pulley 141, the first gear 162 and the second gear 163 are simultaneously moved together with the first gear 162 And the rotational directions of the first gear 162 and the third gear 164 are opposite to each other.

Of course, it is preferable that the third gear 164 be a bevel gear.

When the drive shaft 165 is rotated so that the rotation direction of the third gear 164 is the same as the direction of the outer cylinder 120, the first gear 162 is naturally rotated in the direction opposite to the rotation direction of the third gear 164 The impeller 150 is rotated in a direction opposite to the rotating direction of the outer cylinder 120 and scrapes the accumulated sludge in the outer cylinder 120.

Meanwhile, an impeller 150 is installed inside the outer cylinder 120 to rotate together with the centrifugal force of the outer cylinder 120 to rotate.

The impeller 150 is installed to rotate along the centrifugal force generated by the rotation of the outer cylinder 120. A rotating shaft 161 which is a rotational center of the impeller 150 is formed on the impeller 150. [

Therefore, the impeller 150 rotating along the centrifugal force of the outer cylinder 120 is forced to be relatively slower than the rotational speed of the outer cylinder 120.

This is most effective when the rotational speed of the outer cylinder 120 and the rotational speed of the impeller 150 substantially coincide with each other due to the working efficiency of the centrifugal separator 100. Therefore, the rotational speed of the impeller 150 is close to the rotational speed of the outer cylinder 120 A bearing block 180 is installed between the rotary shaft 161 and the central shaft 130 to induce rolling contact with each other.

The bearing block 180 is formed in a hollow body and passes through the hollow shaft of the rotary shaft 161. The lower surface of the bearing block 180 is fastened to the upper surface of the third gear 164, (164).

At this time, a contact member is mounted on the inner surface of the bearing block 180 to improve the contact force with the rotating shaft 161.

The contact member is made of synthetic resin or synthetic rubber.

A plurality of through holes 181 formed radially toward the center of the bearing block 180 are formed on the side surface of the bearing block 180.

The through hole 181 is formed with a thread on the inner surface thereof and the ball bearing 183 is inserted into the through hole 181 and then inserted into the through hole 181 as the tightening bolt 182 to be tightened by the ball bearing 183 and the outer circumferential surface of the rotating shaft 161 are in contact with each other and the contact force between the ball bearing 183 and the rotating shaft 161 is changed by tightening the tightening bolt 182.

Therefore, when the first gear 162 and the third gear 164 are not engaged with the second gear 163 and the outer cylinder 120 is rotated, the contact force generated by the bearing block 180 causes the rotation of the rotating shaft The impeller 150 is rotated together with the outer cylinder 120. When the first gear 162 and the third gear 164 are gear-meshed with the second gear 163, The power received by the second gear 163 is greater than the contact force, and the direction of rotation of the impeller 150 and the outer cylinder 120 is reversed.

The bearing block 180 may be provided in a plurality of positions that can contact the outer circumferential surface of the rotating shaft 161.

As described above, the plurality of centrifugal separator interlocking methods of the present invention can sequentially operate a plurality of centrifugal separators, thereby enabling continuous operation during a large amount of waste water treatment, shortening the working time, and providing a relatively low-cost vertical centrifugal separator There is a remarkable effect that it is economically advantageous to use.

100. Centrifuge
110. Frame 120. Outer tube 121. Receiving tube
122. Discharge tube 130. Center axis
140. First driving means 150. Impeller 160. Second driving means
170. Clutch means 180. Bearing block
C. Integrated Con- troller C1, C2. Individual controller
141. Pulley 142. Belt 143. First drive motor
161. Rotation shaft 162. First gear 163. Second gear
164. Third gear 165. Drive shaft 166. Second drive motor
171. Guide bushing 172. Seesaw bar 173. Hinge shaft
174. Support bar 175. Cylinder
181. Block 182. Tightening Bolts 183. Ball Bearings

Claims (3)

A plurality of centrifugal separator interlocking methods configured to control operations by interlocking a plurality of centrifugal separators (100)
A plurality of centrifuges 100 are sequentially driven to start preliminary driving of the next car centrifuge 100 before the operation of the driving centrifuge 100 is stopped, Wherein the wastewater to be supplied to the centrifugal separator (100) is supplied to a centrifugal separator (100) after the centrifugal separator (100).
The method according to claim 1,
Each of the plurality of centrifuges 100 is provided with respective individual controllers C1 and C2 and can be individually driven and controlled when the centrifugal separators 100 are interlocked with each other And a plurality of centrifugal separators interlocked with each other.
The method according to claim 1,
The centrifuge 100 includes a frame 110;
A drain pipe (122) which is supported in a vertical direction on the bottom surface by the frame (110) and in which an internal space is formed, and a drain pipe (121) An outer cylinder 120 formed with a cylinder block;
A center shaft 130 formed at an upper center portion of the outer cylinder 120;
A first driving means (140) for rotationally driving the central axis;
An impeller 150 rotating along the rotation of the outer cylinder 120 in the outer cylinder 120;
Second driving means for driving the impeller (150);
Wherein the centrifugal separator is composed of a plurality of centrifugal separators.

Images