JPS61189900A - Scum dehydrator - Google Patents

Abstract

PURPOSE:To improve working efficiency by the constitution consisting of rotating 120 deg. a turntable disposed with 3 pieces of grid-shaped cylindrical bodies at equal intervals on the same circumference at every end of stages and executing separately and simultaneously a supplying stage, dehydrating state and draining stage. CONSTITUTION:The 1st-3rd holes 1-3 are formed at equal intervals on the same circumference to a stand 4. Scum is supplied to the inside of the grid- shaped cylindrical body 8 positioned in the upper part of the 1st hole 1. A compressing member 11 of a compressing device 10 is inserted into the grid- shaped cylindrical body 8 positioned in the upper part of the 2nd hole 2 and further a discharging member 13 of a discharging device 12 is inserted into the body 8 positioned in the upper part of the 3rd hole 3. The supply stage, dehydrating stage and discharging stage are thereby separately and simultaneously executed with the three bodies 8. The above-mentioned three stages are executed simultaneously after the turntable 7 is rotated 120 deg. upon ending of the stages. Then the efficient dehydration of the scum is made possible.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a sludge dehydrator for dewatering sludge removed from sewage or the like.

Conventional technology Conventionally, a sludge dehydrator consists of a cylinder with an openable/closable lid and numerous holes for discharging filtrate, and a piston that reciprocates horizontally within the cylinder. be.

Problems to be Solved by the Invention According to the above-mentioned conventional structure, there is a supply process of supplying FIkt into the cylinder, a dewatering process of moving the piston forward and squeezing the residue, and opening the lid and further moving the piston forward. There was a problem in that efficiency was low because the dehydration process and the discharge step for discharging the residue had to be performed sequentially.

Means for Solving the Problems In order to solve the above-mentioned problems, the dewatering machine of the present invention includes a pedestal having three holes, first to third holes, formed at equal intervals in the circumferential direction; and a screen that covers the second hole, a turntable installed on the pedestal so as to be rotatable around a vertical axis, and a turntable that passes through the turntable and extends on the same circumference as the first to third holes. 3 placed at equal intervals
a lattice-shaped cylinder; a drive device that rotates the turntable by a predetermined angle so that the lattice-shaped cylinder is positioned above the first to third holes; a squeezing device having a squeezing member that can move in and out of the lattice-shaped cylinder at a position above the third hole; and a discharge device having a discharging member that can move in and out of the lattice-shaped cylinder at a position above the third hole. It is structured as follows.

Operation In the above configuration, the residue is supplied to the lattice-shaped cylinder at a position above the first hole, and the residue in the lattice-shaped cylinder is compressed and dehydrated by the squeezing device at a position above the second hole. Then, at a position above the third hole, a discharge device discharges the dehydrated grains in the p-lattice cylinder. These supply process, dehydration process, and discharge process are performed simultaneously every time the turntable rotates by a predetermined angle.

EXAMPLE Hereinafter, an example of the present invention will be described based on FIGS. 1 to 7.

FIG. 1 is a plan view of a sludge dehydrator according to an embodiment of the present invention, FIG. 2 is a front view of the same, FIG. 3 is a side view of the same, and FIG.
A schematic cross-sectional view along the N-IV line in the figure, FIG.
The sixth factor is a schematic cross-sectional view taken along the line V--■ in Figure 3, where (1) is the first hole, (2) is the second hole, ( 3) is the third hole, (4) is the mount, (5), (6) is the screen, (7) is the turntable, (8) is the lattice-shaped cylinder, (9) is the electric motor, αq is the compressing device, (B) is the pressing member, (B) is the discharge device, (to)
is a discharge member. A shaft (toward) is fixed to the pedestal (4) so as to pass through the center in the vertical direction.

An annular filtrate receiver a is fixed to the outer peripheral surface. Further, first to third holes (1) to 3 are formed in the pedestal (4) at equal intervals on a circumference centered on the shaft (to), and first and second holes (1) to 3 are formed at equal intervals on a circumference centered on the shaft (to). A slatted screen (5) (6) is installed in the hole (υ (2)). Also, a filtrate discharge pipe αη is connected to the pedestal (4) and the filtrate receiver (to). The first to third holes (1) to (3
) below the cylindrical legs (4a) of the pedestal (4).
~(4c) are located, and the first and second holes (1 bar 2
The legs (4a, 4b) located below the third hole (3) have a filtrate drain pipe (6), and the leg (4c) below the third hole (3) has a filtrate drain pipe (4). c) are connected to each other. Also, on the outer periphery of the pedestal (4), there is a placket.
An annular ray/I/port is installed through d. The turntable (7) is slidably exposed on the shaft body 05 and is supported by the pedestal (4) via a bearing, and has a bottom outer circumferential portion that abuts on the rail opening. Contacting downward bearings (7) are installed at appropriate intervals in the circumferential direction. Further, the turntable (7) has an annular pin rack installed on the upper surface of the outer circumferential portion via a bracket (E), and the first to! The three lattice-shaped cylinders (8) are arranged at equal intervals on the same circumference as the hole (υ~(3)) of 3.
is provided through each lattice-shaped cylinder (8).
An outer cylinder is provided concentrically with the ring. 1+ Each of the outer cylinders (to) is connected to two liquid discharge pipes. As shown in FIG. 7, the lattice-shaped cylinder (8) has a structure in which a large number of plates gQ are arranged in a ring shape with a gap of about 3 m between them. ＠υ is a gate-shaped frame, and the electric motor (9) with a brake as a drive device is installed on the machine base installed between this frame C311 and the column □□□. . This electric motor (9) consists of a Czech coupling, a worm reducer (to), and a pinion gear (to).
and the pin rack, and the turntable (
7) Rotate by 120 degrees so that the t-1 front lattice folding cylinder body (8) is positioned above the first to third holes (1) to (3). The squeezing device is connected to the second hole (2
) is located above the second hole (2) and connected to the piston rod of this hydraulic cylinder device (b), which is housed in the frame opening l at a position above the frame opening l. The pressing member (
6) Particularly, the discharge device @ includes a hydraulic cylinder device attached to the frame (311) at a position above the third hole (3), and a hydraulic cylinder device attached to the frame (311) at a position above the third hole (3). is connected to the piston rod of the third hole (3
) and the ejection member (roller) that can move in and out of the lattice-like cylinder (8) located above the lattice-like cylinder (8).

Hereinafter, the effects of the above configuration will be explained.

The inside of the lattice-shaped cylinder (8) located above the first hole (1) is supplied with persimmon liquid by a permeate supply device (not shown).

Also, a lattice-shaped cylinder (8) located above the second hole (2)
Inside, there is a hydraulic cylinder device and a pressing member (6).
is inserted, and the tube is squeezed and dehydrated.

In these steps, the lattice-shaped cylinder (8) is located above the screens (5) and (6), so the filtrate flowing downward is discharged through the screens (5) and (6). It is discharged through tube aQgD. In addition, the lattice-shaped cylinder (8)
The filtrate that has passed between the plate ■ is connected to the filtrate discharge pipe 4 and the filtrate receiver α.
Q and the filtrate discharge pipe (to). Also the third
A discharge member (2) is inserted into the lattice-shaped cylinder (8) located above the hole (3) by a hydraulic cylinder; (8) It is pushed out from inside and is discharged through the drainage pipe @t-. Each of the above steps is performed simultaneously, and the turntable (7) is rotated 120 degrees by the electric motor (9) every time the step is completed. In other words, the above-mentioned supply process, dehydration process, and discharge process are performed separately and simultaneously for three lattice-shaped cylinders (8), and one lattice-shaped cylinder (8) K. Considering this, the Uami supply process, the dehydration process, and the discharge process are sequentially performed every 120 degrees of rotation of the turntable (7). Note that while the turntable (7) is rotating, the lower end of the porous cylindrical body (8) slides on an annular plate (top) provided on the turntable (7). The law will never fall. The filtrate flowing out at this time is discharged through the turntable (7) and the filtrate discharge pipe (b).

As described above, according to this embodiment, the supply process, dehydration process, and discharge process can be performed simultaneously, so that dewatering can be performed in an efficient manner. Also, compared to the case where three conventional sludge dehydrators are installed in parallel, the sludge supply and discharge positions are each at one location, which is advantageous in terms of the structure of the sludge supply device and the sludge dehydrator. . Further, as in this embodiment, it is preferable to provide the rail at a position above the upper surface of the turntable (7), since it is possible to prevent sand and the like from getting caught.

Effects of the Invention As described above, according to the present invention, the supply process, dehydration process, and discharge process can be performed simultaneously, so that dewatering can be carried out in an efficient manner.

[Brief explanation of drawings]

FIG. 1 is a plan view of a sludge dehydrator according to an embodiment of the present invention, FIG. 2 is a front view of the same, FIG. 3 is a side view of the same, and FIG.
A schematic cross-sectional view along the N-IV line in the figure, FIG.
6 is a schematic sectional view taken along the line v--v in FIG. 3, and FIG. 7 is an enlarged cross-sectional plan view of the main part of the lattice-shaped cylinder. (1)...first hole, (2)...second hole, (3)
...Third hole, (4) ... Frame, (5) (6)
... Screen, (7) ... Turntable, (8)
...Porous cylindrical body, (9)...Electric motor, Extractor...Compressing device, αυ...Compressing member, @...Discharge device, U...
Discharged parts agent Yoshihiro Morimoto tl-11 Natsume Deshiki Fig. 5b--Screen Fig. 5 3f 1-han 1gu 几

Claims (1)

[Claims] 1. A pedestal having three holes, first to third, formed at equal intervals in the circumferential direction, a screen that covers the first and second holes, and a pedestal that is rotatable around a vertical axis on the pedestal. a turntable installed in the turntable; three lattice-shaped cylinders passing through the turntable and installed at equal intervals on the same circumference as the first to third holes; a drive device that rotates the lattice-shaped cylinder by a predetermined angle so that it is positioned above the first to third holes; and a compressor that can move in and out of the lattice-shaped cylinder at a position above the second hole. A sludge dehydrator comprising: a squeezing device having a member; and a discharging device having a discharging member that can move in and out of the lattice-shaped cylinder at a position above the third hole.