JP2002085909A - Sludge raking machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sludge raking machine by which treatment load imposed on an operator and cost can be reduced and in which the projecting angle of a rake arm can be adjusted. SOLUTION: This sludge raking machine is provided with a main shaft 26 which is installed in a settling tank 22 for separating dirty water 34 into sludge 35 and supernatant water 36, driven to rotate around the vertical shaft center by a driving motor 28 and disposed vertically in the center part of the tank 22, the rake arm 50 which is pin-connected to the bottom side of the main shaft 26 to be rotated and extends almost in the horizontal direction, a rake 52 fixed on the arm 50 and a rake supporting member 54 for connecting the main shaft 26 to the arm 50 to hang/support the arm 50. The member 54 is constituted so that screw parts 60, 62 are arranged on a first rod member 56 and the second rod member 58, which are opposite to each other, respectively and the screw parts 60, 62 are connected to each other by using a nut 64 one end of which is threaded right-handedly and the other is threaded left-handedly.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sludge scraper installed in a sedimentation tank for separating wastewater into sludge and supernatant water, and for collecting sludge deposited at the bottom of the sedimentation tank to a central sludge collection pit. About.

[0002]

2. Description of the Related Art Conventionally, in a sewage treatment system for treating various kinds of wastewater (hereinafter simply referred to as "sewage") such as public sewerage, hot spring wastewater and industrial wastewater, a sedimentation tank for separating wastewater into supernatant water and sludge is generally used. It has. This sedimentation tank is provided with a so-called sludge scraper that scrapes the sludge settled at the bottom to the collection pit.

[0003] Such a sludge scraper is disclosed, for example, in Japanese Patent Application Laid-Open No. 9-299713.
FIG. 6 is a sectional view showing a sludge scraper installed in a sedimentation tank. The sludge scraper 1 has a main shaft 3 arranged vertically in the center of a settling tank 2. The main shaft 3 is driven to rotate about a vertical axis by a drive motor 4. A rake arm 5 is connected to the bottom of the main shaft 3 so as to extend substantially horizontally, and a rake 6 is fixed to the rake arm 5. The sludge scraper 1 is provided with a tension rod (stay) 7 for integrally connecting the main shaft 3 and the rake arm 5 to fix and hold the same. The sludge scraper 1 configured as described above rotates the main shaft 3 so that the rake arm 5 and the rake 6
Is rotated around the center of the vertical axis, and the sludge settled at the bottom of the settling tank 2 is raked into the sludge collection pit 8 at the center bottom.

[0004]

However, the conventional sludge scraper 1 has the following problems. Conventionally, the work of attaching the tension rod 7 to the main shaft 3 has been performed by making a hole corresponding to the bracket 9 provided on the main shaft 3, inserting the hole into the bracket 9, and connecting to the bracket 9 via a through bolt 10. . However, when the tension rod 7 is attached to the main shaft 3 in this manner, the projection angle of the rake arm 5 connected to the tension rod 7 is also determined. The overhang angle of the rake arm 5 needs to be an angle at which the rake 6 can slide on the bottom of the sedimentation tank 2. Therefore, drilling work of the tension rod 7 takes time for positioning and other processes, and the work load is large. . Further, when the adjustment of the overhang angle fails or when the size of the overhang angle is adjusted to another size, it is necessary to perform the above-described drilling processing and bolt insertion processing again. SUMMARY OF THE INVENTION An object of the present invention is to provide a sludge scraper capable of easily adjusting the overhang angle of a rake arm in a short time while reducing a processing load on an operator.

[0005]

In order to achieve the above object, a sludge scraper according to the present invention comprises a main shaft rotatably provided at the center of a sedimentation tank for separating sludge into sludge and supernatant water. A rake arm attached to a lower part of the main shaft so as to be rotatable in a vertical plane and extending in a radial direction of the sedimentation tank; and a rake attached to the rake arm and held substantially parallel to a bottom surface of the sedimentation tank. And a telescopic rake support member formed by connecting the rake arm and the main shaft, one end of which is pivotally connected to the rake arm, and the other end of which is pivotally connected to the main shaft by pin connection. The rake arm is formed in a truss structure in a horizontal plane, and the rake support member includes a first rod member and a second rod member.
And a rod member which is connected by a nut having a right-hand thread on one end and a left-hand thread on the other end.

In the above configuration, the length of the rake support member can be changed by adjusting the degree of fitting of the screw connection portion of the rake support member, thereby extending the rake arm in accordance with the inclination angle of the bottom of the settling tank. The angle can be adjusted. Therefore, when adjusting the overhang angle of the rake arm, it is not necessary to perform a heavy work as in the related art, and the processing load on the worker can be reduced and the work can be performed in a short time.

It is particularly preferable that the sludge scraper of the present invention, including the rake support member, be formed of plastic. By forming the sludge scraper, the weight of the entire sludge scraper can be reduced. For this reason, the power of the motor for rotating the main shaft can be reduced, and the cost is also high. In addition, by forming with plastic, corrosion resistance and rust prevention can be enhanced, and the life of the sludge scraper can be prolonged.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A sludge scraper according to an embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is an explanatory view when a sludge scraper according to an embodiment of the present invention is installed in a settling tank. The sedimentation tank 22 is made of concrete,
The inside has a substantially cylindrical shape. The bottom of the sedimentation tank 22 is formed in an inverted conical shape, and a sludge collection pit 24 having a concave shape is provided at the center of the bottom so that sludge 35 can be deposited. The mud collecting pit 24 is connected to a pump mechanism 23 for discharging sludge 35 to the outside.
The sludge 35 deposited on the surface 4 can be sucked out. An overflow weir 25 formed in an inverted L-shaped cross section is provided at the upper part of the inner wall surface of the sedimentation tank 22.
The supernatant water 36 can be discharged to the outside.

At the center of the settling tank 22, a main shaft 26 of the sludge scraper 20 is provided rotatably in the vertical direction. The upper end of the main shaft 26 is connected to a drive motor 28, and the main shaft 26 can be rotated around the axis by the drive motor 28.

The main shaft 26 passes through a substantially cylindrical feed well 30 provided on the upper side. Feedwell 30
Is for supplying sewage 34 to the sedimentation tank 22. A sewage inflow pipe 32 connected to the outside is inserted and arranged on the lower surface of the feed well 30, and sewage 34 flows into the feed well 30 from the sewage inflow pipe 32. A plurality of openings are formed on the side surface of the feed well 30 at regular intervals, and the scum 38 in the feed well 30 can flow out of the feed well 30 from each opening.

A scum receiving pipe 40, which will be described in detail later, is attached to the upper side of the feed well 30 so as to extend in the radial direction of the settling tank 22. Scum receiving pipe 42
Is provided such that the upper surface slightly protrudes from the surface of the supernatant water 36. The scum receiving pipe 40 has one end connected to the scum discharge pipe 42.

A scum skimmer arm 46 forming scum scraping means is mounted on the upper portion of the main shaft 26 above the feed well 30 so as to extend in the radial direction of the settling tank 22. The scum skimmer arm 46 has a rubber-made scum scraping plate 48 attached to the lower surface so as to be at a height position in contact with the upper side of the scum receiving pipe 40. For this reason,
The scum scraping plate 48 can rotate together with the scum skimmer arm 46 in the circumferential direction of the sedimentation tank 22 as the main shaft 26 rotates. Details of these will be described later.

On the other hand, as shown in FIG. 1, a pair of rake arms 50 are mounted on the bottom side of the main shaft 26 so as to form an inverted figure of eight. Each rake arm 50
Is rotatably mounted in a vertical plane with respect to the main shaft 26. FIG. 3 is an explanatory view showing a coupling portion between the main shaft 26 and the rake arm 50. A bracket 51 having a concave shape as viewed from above is provided below the main shaft 26. The bracket 51
The rake arm 50 and the bracket 51 are connected to each other by a pin 53. Therefore, the rake arm 50 can be raised and lowered with respect to the main shaft 26 in the vertical direction.

Each rake arm 50 has a rake 5
2 are attached at regular intervals. The rake 52
Each has a central portion connected to the lower surface of the rake arm 50 so as to be oblique to the axis direction of the rake arm 50 at a predetermined angle. A rubber scraper 57 is attached to the lower part of the rake 52 so as to be close to the lower surface of the sedimentation tank 22. As a result, the rake arm 5
When turning 0, the scraper 5 attached to the rake 52
7 rakes the sludge and drops it into the mud collection pit 24.

Each rake arm 50 is formed to have a truss structure in a horizontal plane. FIG. 4 is a plan view showing a main part of the sludge scraper according to the present embodiment. As shown in FIG. 4, a pair of overhang members 82 are connected to the lower end side of the main shaft 26 so as to be orthogonal to the rake arm 50. Then, the distal end of the overhang member 82 and the distal end of the rake arm 50 are connected to the connecting member 8 respectively.
4 to form a substantially rhombic shape when viewed from above. By forming such a truss structure, the rake arm 50 can be supported and the force applied to the rake arm 50 during turning can be dispersed. For this reason,
It is possible to prevent bending or the like when the rake arm 50 turns.

One end of a rake support member 54 is pivotally connected to the upper end of each rake arm 50 by pin connection. The other end of each rake support member 54 is connected to the center of the main shaft 26. It is pivotally connected to the provided connecting portion 55 by pin connection. As shown in FIG. 1, the rake arm 50 and the rake support member 54 are formed in a substantially diamond shape. The rake support member 54 in the present embodiment includes:
The first rod member 56 and the second rod member 58 are connected to each other by a nut 64 having a right-hand thread on one end and a left-hand thread on the other end to form a substantially linear shape. As shown in FIG. 2, the first rod member 56 and the second rod member 58 are formed with thread portions 60 and 62, respectively, and the thread directions of the thread portions 60 and 62 are opposite to each other. It is formed as follows. Thus, when the nut 64 is rotated in one direction, the distance between the first rod member 56 and the second rod member 58 is reduced, and the rake support member 54 is rotated.
The overall length can be reduced. The nut 6
When the 4 is rotated in the opposite direction, the distance between the first rod member 56 and the second rod member 58 increases, and the entire length of the rake support member 54 can be increased. Because of this, when mounting the conventional rake arm 50 to the main shaft 26, it is not necessary to perform a very troublesome positioning operation for drilling, and the mounting operation can be facilitated. Further, both ends of the rake support member 54 are pivotally connected to each other by pin connection.
Since the length of the rake arm 50 can be easily changed, the overhang angle of the rake arm 50 can be easily changed. Therefore, the position can be easily adjusted so that the rake 52 can slide on the bottom surface of the sedimentation tank 22.

As described above, when adjusting the overhang angle of the rake arm 50, it is not necessary to perform a heavy work as in the related art, and the processing load on the operator can be reduced and the work can be performed in a short time. In the present embodiment, the rake support member 54 has a configuration in which the first rod member 56 and the second rod member 58 are connected by a nut 64 having a right-hand thread on one end and a left-hand thread on the other end. However, the present invention is not limited to this as long as the structure is extendable.

The sludge scraper 20 in another embodiment (the same members as those in the previous embodiment are denoted by the same reference numerals and description thereof is omitted) is formed of plastic, including the rake support member 54. I do. By forming the sludge scraper 20 from plastic, the weight of the entire sludge scraper 20 can be reduced. For this reason, a drive motor 28 that rotationally drives the main shaft 26
Power can be reduced, and the cost is high. In addition, by forming with plastic, corrosion resistance and rust prevention can be enhanced, and the life of the sludge scraper 20 can be lengthened.

FIG. 5 is a perspective view showing the main part of the scum removing mechanism of the sludge scraper 20. The scum receiving pipe 40 is rotatably connected to the support rod 39 at a side end shown in FIG. 5 via a rotary joint 68a. The support rod 39 has the other end connected to the side surface of the feed well 30.
Further, the lower end portion of the scum receiving pipe 40 shown in FIG. 5 is integrally connected to the connecting pipe 41 via a joint 68b.
The other end of the connection pipe 41 is rotatably connected to the scum discharge pipe 42 via a rotation joint (not shown). The joints 68a and 68b and the bearing 68c contain a gland packing, and form respective seals.

On one side surface of the scum receiving pipe 40, a scum introduction port 66, which is an opening formed long in the axial direction, is provided. As described above, the scum receiving pipe 40 is arranged so that the upper surface is slightly higher than the surface of the supernatant water 36.
For this reason, the supernatant water 3 is supplied to the scum inlet 66 facing upward.
6 can be prevented from flowing.

The connecting pipe 41 rotatably passes through a cylindrical rail body 70 via a bearing 68c. The rail body 70 is formed concentrically with the main shaft 26 and is for guiding the scum skimmer arm 46. A roller 72 serving as an arm receiver is rotatably attached to the lower end of the lower surface of the scum skimmer arm 46.
6 can be swiveled in the circumferential direction of the sedimentation tank 22.

A striker (not shown) is connected to the scum receiving pipe 40, and the striker is arranged so as to protrude so as to cross the turning path of the scum skimmer arm 46. Because of this, when the scum skimmer arm 46 pushes down and tilts the striker, the scum receiving tube 40 can be rotated so as to face the scum scraping plate 48. The connecting pipe 41 is provided with a weight 74 so that the scum receiving pipe 40 rotated by the weight of the weight 74 can be returned to the original position together with the connecting pipe 41.

In the scum removing mechanism configured as described above, the rotation of the main shaft 26 causes the scum scraping plate 48 to rotate about the main shaft 26 integrally with the scum skimmer arm 46 and float on the surface of the supernatant water 36. The scum 38 that is present. When the scum skimmer arm 46 approaches the scum receiving pipe 40 and comes into contact with the striker projecting on the swivel line of the scum skimmer arm 46, the striker is pushed down and inclined. With the inclination of the striker, the scum receiving pipe 40 connected to the striker is rotated, and the scum introduction port 66 faces the scum scraping plate 48 side. This allows
The scum 38 raked by the scum scraping plate 48 can be poured into the scum inlet 66. Scum inlet 6
The scum 38 that has flowed into 6 is discharged to the outside through a scum discharge pipe 42. Then, when the scum scraping plate 48 passes through the scum receiving pipe 40, the scum receiving pipe 40 is returned to the original position by the weight 74 so that the scum introduction port 66 faces upward, and the supernatant water 36 is supplied to the scum introduction port 66. Can be prevented from flowing.

[0024]

As described above, according to the present invention, it is not necessary to perform a burdensome work as in the prior art and to increase the number of parts when adjusting the overhang angle of the rake arm. In addition, the processing load and cost of the worker can be reduced.

[Brief description of the drawings]

FIG. 1 is a sectional view of a sludge scraper according to an embodiment of the present invention.

FIG. 2 is a sectional view showing a main part of the rake support member.

FIG. 3 is a perspective view showing a joint between a rake arm and a main shaft.

FIG. 4 is a plan view showing a main part of the sludge scraper according to the embodiment of the present invention.

FIG. 5 is a perspective view showing a main part of a scum removal mechanism of the sludge scraper according to the embodiment of the present invention.

FIG. 6 is a sectional view showing a conventional sludge scraper.

[Explanation of symbols]

1 sludge scraper, 2 sedimentation tank, 3 spindle
4 ... Drive motor, 5 ... Rake arm, 6 ...
Rake, 7 ... Rake arm, 8 ... Mud collection pit,
9 Bracket, 10 Through bolt, 20
... sludge scraper, 22 ... sedimentation tank, 23 ... pump mechanism, 24 ... mud collection pit, 25 ... overflow weir, 26 ...
... Spindle, 28 ... Drive motor, 30 ... Feed well, 32 ... Sewage inflow pipe, 34 ... Sewage, 35
... sludge, 36 ... supernatant water, 38 ... scum, 3
9 Support rod, 40 Scum receiving pipe, 42
… Scum discharge pipe, 46… scum gap arm, 4
8 ... scum scraping plate, 50 ... rake arm,
51 Bracket, 52 Rake, 53
Pin, 54, rake support member, 55, connecting portion,
56 first rod member, 57 scraper, 5
8 Second rod member 60 Screw part 62
... Screw part, 64 ... Nut, 66 ... Scum introduction port, 68a ... Rotary joint, 68b ... Joint, 68c
... bearing, 70 ... rail body, 72 ... arm receiver, 74 ... weight, 82 ... overhanging member, 8
4 ... connecting member,

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Mitsuru Hatanaka 537, Kamigongo, Matsudo-shi, Chiba F-term, Hitachi Plant Construction Machinery Engineering Co., Ltd. 2D063 DB01 DB07

Claims (1)

[Claims] A main shaft rotatably provided at the center of a sedimentation tank for separating sewage into sludge and supernatant water; a main shaft rotatably mounted on a lower part of the main shaft in a vertical plane;
A rake arm extending in the radial direction of the settling tank; a rake attached to the rake arm and held substantially parallel to a bottom surface of the settling tank; and connecting the rake arm and the main shaft, one end of which is A retractable rake support member pivotally connected to the rake arm and the other end pivotally connected to the main shaft by pin connection, and the rake arm is formed in a truss structure in a horizontal plane, and The rake support member has a first rod member and a second rod member, and both are connected by a nut having a right-hand thread on one end and a left-hand thread on the other end. Machine.