JPH0565204B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a filtration device that can be used in a wide range of applications, from solid/liquid separation in dredging work to filtration of drinking water.

[Prior Art] As an example of this type of device, a filtration device for dewatering sludge has been known, for example, as shown in Japanese Patent No. 1381107, which was previously proposed by the applicant of the present patent.

In this sludge dewatering filtration device, a filtration drum with a strainer stretched around its circumferential surface is rotatably supported in a filtrate container, and a suction port of a negative pressure forming means is opened in the filtration drum, and a suction port of a negative pressure forming means is opened in the filtration drum to be connected to the circumferential surface of the strainer. It is configured to adsorb solid matter and separate solid and liquid.

With such a structure, there was a problem in that the strainer clogged quickly and the strainer had to be cleaned frequently, which took time and effort, and the dehydration and filtration ability was also reduced.

In order to solve this problem, a thick pre-coat layer is formed by adsorbing the filter material to the circumferential surface of the strainer of the filter drum, and when the surface of this pre-coat layer becomes clogged, the clogged part is cut away. He invented a structure that allows dehydration and filtration to be carried out continuously for a long time until the precoat layer disappears (Japanese Patent Application No. 79544/1983).

[Problem to be solved by the invention]

Even if a precoat layer is formed on the surface of the strainer as described above, and this precoat layer is gradually cut off to allow continuous operation for a long period of time, when the precoat layer runs out, the filtration device is temporarily stopped and the strainer is removed. There was a problem in that the precoat layer had to be re-formed on the surface, and the operating time was also limited.

Moreover, when forming a pre-coat layer, the sludge in the sludge layer is once discharged, the sludge tank is filled with a filter material after being thoroughly cleaned, and the filter material is sucked onto the surface of the strainer to form the pre-coat layer. It takes a lot of time and effort to form the precoat layer,
This has caused a problem in that the operating efficiency of the filtration device is also low.

In order to deal with the above problem, for example,
As shown in Publication No. 130964, there is a scraping blade for scraping off solid matter adsorbed on the precoat layer from the sludge adsorbing part of the sludge tank to the lower side in the rotational direction of the precoat layer, and a filter medium further on the lower side. A storage tank is provided, and even if the precoat layer is scraped off with a scraping blade, the filter medium in the filter storage tank is adsorbed and the precoat layer is regenerated, so that the filtration device can be operated continuously. However, in this case, when the precoat layer is scraped off with a scraping blade, the suction force becomes high in the area where the precoat layer is scraped off, and outside air is sucked in from this area. When outside air is sucked in in this manner, the adsorption power of the precoat layer is reduced, which not only reduces the filtration ability but also causes the problem that the filter medium in the filter medium storage tank cannot be sufficiently adsorbed.

The present invention was proposed in view of the above problems, and
The purpose of this invention is to automatically form a precoat layer without reducing the filtration capacity of the rotating drum, and to enable continuous operation of the filtration device.

[Means to solve the problem]

In order to achieve the above object, the filtration device according to the present invention includes, as a first means, a filtration drum having a strainer stretched around its circumferential surface rotatably supported in a sewage tank in a filtrate container; A suction port of a negative pressure forming means is opened inside the strainer, a filter material supply tank is provided in which a part of the circumferential surface of the strainer is immersed, and the filter material in the filter material supply tank is adsorbed onto the surface of the strainer. A pre-coat layer is formed, at least a part of the pre-coat layer is immersed in the filtrate stored in the sewage tank in the filtrate container, and scraped off on the upper side in the rotational direction of the filter drum at the part of the filter media supply tank facing the pre-coat layer. A surface leveling blade is disposed in the filter medium supply tank portion on the downstream side in the rotation direction of the filter drum, and a portion near the scraping blade and on the downstream side in the rotation direction of the filter drum is formed in an airtight manner. As a second means, in addition to the first means, a partitioning blade is provided on the upper side in the rotational direction of the filter drum in the vicinity of the scraping blade, and the scraping blade is provided between the partitioning blade and the scraping blade. It is characterized by the fact that it forms a logistics entrance.

[Effect]

When the filtration drum is rotated while operating the negative pressure generating means, the filtrate is sucked into the filtration drum from the precoat layer part immersed in the filtrate in the filtrate tank, but the solids in the filtrate are absorbed by the precoat. Only the liquid that is adsorbed and supported by the layer is sucked into the filter drum, and this liquid is sucked into the negative pressure forming means from the suction port.

On the other hand, the solid matter adsorbed and held on the precoat layer is scraped off from the precoat layer by a scraping blade as the filter drum rotates.

In this way, as the solids adsorbed and held on the precoat layer are scraped off by the scraping blade, a part of the surface of the precoat layer is also scraped off.
This scraped off portion adsorbs the filter medium supplied to the filter medium supply tank and is restored to a predetermined thickness with a surface leveling blade.

At this time, a part of the precoat layer is scraped off with the blade along with the solids, and the thickness becomes thinner, and the suction power in this area becomes stronger, but this stronger suction power is used to supply the filter media to the filter media supply tank. The precoat layer is regenerated by adsorbing the filter media.

In this way, the precoat layer can always filter the filtrate in the filtrate tank with a constant thickness.

〔Example〕

Hereinafter, a filtration device according to the present invention will be explained based on the drawings.

Example 1 As shown in FIG. 1, a filtration device 1 according to this example has a precoat layer 3 formed by adsorbing a filter material to the peripheral edge using a negative pressure generated inside by a negative pressure forming means 2, which will be described later. A filtration drum 4 is rotatably supported approximately at the center of a filtrate container 5 having an open top, and a filter medium supply tank 6, a sewage tank 7, and a sludge storage tank 8 are formed around the filtration drum 4. ing.

The negative pressure forming means 2 sucks up water in the water supply tank 9 with a pump 10 and sends it from the injection nozzle 11 to the protection pipe 1.
The jet pump MJP is configured to take out from the suction port 14 the negative pressure that is formed in the discharge pipe 13 when the jet water stream is injected from the protection pipe 12 to the discharge pipe 13. A suction port 14 of the jet pump MJP is connected to the filter drum 4 through a water suction pipe 15.

The suction port 16 of the water suction pipe 15 is opened downward near the strainer 17 inside the filter drum 4.

The filtration drum 4 is configured to be rotationally driven in the direction of the arrow A in the figure by a driving means (not shown) including an electric motor and a chain transmission device that decelerates and transmits the rotation of an electric moder.

The filter medium supply tank 6 is filled with a filter medium such as diatomaceous earth for forming the precoat layer 3, and is connected to a scraping blade 18 attached tangentially close to the left side of the precoat layer 3. A partition wall 20 separates the blade 18 from the surface leveling blade 19 which is disposed on the lower side in the rotational direction of the filter drum 4. A filter medium inlet 23 through which filter medium is pumped and supplied by a pump 22, and a filter medium outlet 24 through which overflowing filter medium is returned to the filter medium tank 6 are formed.

The lower part of the scraping blade 18 in the rotational direction of the filter drum 4 is formed in an airtight manner by the scraping blade 18 in contact with the precoat layer 3, the filter medium supply tank 6, etc., and this filter medium supply tank 6 is formed at the filter medium inlet. The 23 side is narrow, and the filter medium outlet 24 side, which is located on the downstream side in the rotational direction of the filter drum 4, is wide.

The sludge storage tank 8 includes a partition wall 25 supported by and suspended from the front and rear walls of the filtrate container 5 and the partition wall 2.
0 and a barrier 26 standing upright from the bottom wall 5a of the filtrate container 5 to the lower surface of the partition wall 20, and the lower end of the partition wall 25 is separated from the scraping blade 18. It is provided near the upper side of the filter drum 4 in the rotational direction and close to the surface of the lower precoat layer 3 as a partitioning blade 25a.

A scraping flow inlet 27 is formed between the lower end of the partition wall 25 and the scraping blade 18.

In addition, the reference numeral 28 in the figure is an overflow port for maintaining the liquid level of wastewater.

The filtration device 1 configured as described above operates the negative pressure forming means 2 while the filtration drum 4 is immersed in waste water stored in the filtrate container 5, and rotates the filtration drum 4 by the driving means. When this happens, the negative pressure inside the filtration drum 4 sucks sewage into the filtration drum 4 from the part of the precoat layer 3 facing the sewage in the sewage tank 7, but the solids in the sewage are absorbed into the surface of the precoat layer 3. Only the liquid portion is sucked into the filter drum 4.

The liquid sucked into the filter drum 4 is transferred to the water suction pipe 15.
After being sucked into the jet pump MJP through the water intake port, the water is returned to the water supply tank 9 through the discharge pipe 13.

The solid lumps adsorbed and held on the precoat layer 3 are further adsorbed and dehydrated while being conveyed to the scraping blade 18 along with the filtration drum by the driving means, and then scraped off from the surface of the precoat layer 3 by the scraping blade 18. be.

In this way, the precoat layer 3 is removed by the scraping blade 18.
When solids are scraped off from the surface of the filter material, the surface of the precoat layer 3 is also scraped off, the thickness becomes thinner, and the suction force in this area becomes stronger. The precoat layer 3 is regenerated by adsorbing the filter medium supplied to the supply layer 6,
The surface is leveled to a predetermined thickness by the surface leveling blade 19 and recovered.

Therefore, while the filter medium is being supplied to the filter medium supply tank 6, the precoat layer 3 is always kept at a constant thickness and can continue to filter the filtrate in the sewage tank 7 well.

Embodiment 2 As shown in FIG. 2, a filtration device 1 according to this embodiment has a filtration drum 4 driven to rotate in a direction B opposite to that of Embodiment 1, and a scraping blade 1.
8 and a surface leveling blade 19 disposed on the lower side in the rotational direction of the filter drum 4 than the scraping blade 18.
The filter medium supply tank 6 formed between the filter drum 4 and the filter drum 4 is formed above the filter drum 4, and the other configurations and functions are the same as in Example 1.
In such a case, there is an advantage that the state of the filter medium in the filter medium supply tank 6 can be visually checked and the filter medium can be manually supplied.

In addition, if a rotatable "L"-shaped liquid level adjustment pipe 29 is provided at the overflow port 28 as shown by the imaginary line in the figure, the liquid level of the sewage can be adjusted by rotating the liquid level adjustment pipe 29. By adjusting it, it can be set to any desired position.

Embodiment 3 As shown in FIG. 3, the filtration device 1 according to this embodiment rotates the rotation direction of the filtration drum 4 in the clockwise direction B, which is the same as in Embodiment 2, and the filter medium supply tank 6 is moved to the lower left of the filtration drum 4. The filter medium input port 30 is located above the filtrate container 5, and the water purification tanks 31 and 32 are formed on the sides of the filter medium supply tank 6, and the water purification tanks 31 and 32 are relatively close to each other. rough filter 3
3, the filter medium supply tank 6 and the water purification tank 32
is communicated with through a fine-mesh filter 34.

With this structure, each filter 3
The purified water is sucked into the filter medium supply tank 6 through 3 and 34, and the filter medium in the filter medium supply tank 6 is stirred and mixed with the purified water, which has advantages such as being able to prevent the filter medium from clumping.

In addition, in this embodiment, the partitioning blade 25a in the above embodiments 1 and 2 is also used as the scraping blade 18, and the scraping material inlet 27 and sludge storage tank 8 are omitted, and the partitioning blade 25a is used for scraping. The collected solid matter settles and accumulates at the bottom of the sewage tank 7.

In each of the embodiments described above, the filter drum 4 is driven while being submerged in the waste water, but if it is set to be located below the flow inlet 27 for scraping the liquid level of the waste water, the scraping blade 18 The solidified material scraped off can be taken out in the form of a cake with a humidity of about 50% or less.

Furthermore, in each of the above embodiments, the negative pressure forming means 2 is constructed of a jet pump MJP.
It goes without saying that this may be formed using a vacuum forming pump such as a plunger pump.

〔Effect of the invention〕

As explained above, even if a part of the precoat layer that has adsorbed solids is scraped off together with the solids by the scraping blade, the filter medium is still supplied to the filter medium supply tank immediately after the scraping blade. Since the precoat layer is recovered by adsorbing it and leveling its surface to a predetermined thickness with a leveling blade, there is an advantage that the filtration device can be operated continuously just by supplying the filter medium to the filter medium supply tank.

It also automatically restores the pre-coat layer, so
It also has the effect of greatly improving the operating efficiency of the filtration device without requiring a lot of time and effort to form the precoat layer as in the case of conventional methods.In addition, part of the precoat layer along with the solids is removed by the blades. When it is scraped off, its thickness becomes thinner and the suction power in this area becomes stronger, but this stronger suction power adsorbs the filter media being supplied to the filter media supply tank and regenerates the precoat layer. Another advantage is that filtration can be performed with a strong suction force without reducing the negative pressure on the surface of the precoat layer by suctioning outside air from the area scraped off by the blade as in the conventional method.

[Brief explanation of the drawing]

The drawings show an embodiment of the filtration device according to the present invention, FIG. 1 is a vertical side view of the filtration device of the first embodiment, FIG. 2 is a vertical side view of the filtration device of the second embodiment, and FIG. 3 is a side view of the filtration device of the second embodiment. FIG. 7 is a longitudinal cross-sectional side view of a filtration device according to a third embodiment. 1... Filtration device, 2... Negative pressure forming means, 3...
Pre-coat layer, 4... Filter drum, 5... Filtrate container, 6... Filter medium supply tank, 7... Sewage tank, 16...
... Suction port, 17 ... Strainer, 18 ... Scraping blade, 19 ... Surface leveling blade, 25a
...Blade for compartment, 27...Scraping distribution entrance.

Claims (1)

[Scope of Claims] 1. A filtration drum with a strainer stretched around its circumferential surface is rotatably supported in a sewage tank in a filtrate container, a suction port of a negative pressure generating means is opened in the filtration drum, and a strainer is attached to the strainer. A filter medium supply tank is provided in which a part of the peripheral surface of the strainer is immersed, the filter medium in the filter medium supply tank is adsorbed onto the surface of the strainer to form a precoat layer, and at least a part of the precoat layer is filtered. The scraping blade is immersed in the filtrate stored in the sewage tank in the liquid container, and the scraping blade is placed on the upper side in the rotational direction of the filtration drum at the part facing the precoat layer of the filtering medium supply tank, and the filtering medium is supplied on the lower side in the rotational direction of the filtration drum. A filtration device characterized in that a surface leveling blade is disposed in each tank portion, and a portion near the scraping blade and on the downstream side in the rotational direction of the filtration drum is formed in an airtight manner. 2. Claim 1, characterized in that a partitioning blade is provided on the upper side in the rotational direction of the filter drum near the scraping blade, and a scraping flow inlet is formed between the partitioning blade and the scraping blade. The filtration device described in section.