JP2003094069A - Method and equipment for treating waste water - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for facilitating the collection and treatment of sludge by efficiently removing not only metal particles, solid particles, oils, and the like, contained in a wastewater but all sludge therein and for reducing the volume of industrial waste generated by a wastewater treatment and for efficiently removing the whole amount of sludge and suspended matters. SOLUTION: The wastewater treatment equipment 1 is provided with a wastewater tank 3, a submersible pump 5, a separation tank 7 which separates the wastewater into a sludge and a purified solution, a sludge scraping means 13 which scrapes the sludge stored at the bottom of the tank 7 to a draining tank 11, a draining bucket 15 which dips up and drains the sludge stored at the bottom of the tank 11, a sludge chute 19 which is located at a position where the sludge is directly dumped out to the chute 19 from the bucket 15 by reversing upside down, an overflow path 21 which allows a supernatant liquid in the tank 7 to overflow, a supernatant liquid storage tank 23 which stores the liquid overflowed, a surface intake device 27 which sucks a suspended matter in the tank 23 with an ejector 29 by using the driving water of the pump 5 and a feed pump 25 which sucks the liquid from the tank 23.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sewage treatment method and a sewage treatment apparatus for treating and cleaning various kinds of sewage such as a coolant liquid used in a machine tool, industrial wastewater, domestic wastewater, and civil engineering wastewater. It is a thing.

[0002]

2. Description of the Related Art Conventionally, the coolant liquid used in a machine tool is put into a sewage tank equipped with a magnet roller, and iron powder and cutting wastes in the coolant liquid are adsorbed by the magnet roller to be collected. There is known a method of cleaning and regenerating (recent technology).

Furthermore, a method is also known (prior art) in which dirty water is filtered and regenerated.

In the sewage treatment, sewage is stored in a sludge tank in order to recover sludge in the sewage.
A drain valve with a timer is used to drop into the waste water tank at regular intervals (prior art).

[0005]

However, in the prior art, the abrasive grains in the coolant cannot be recovered, and if the coolant that has not been removed from the coolant is reused, the product will be damaged and defective products will be produced. There is a problem. In addition, in the conventional technology, in order to dispose of the sludge accumulated in the sewage tank, an underwater pump is installed in the sewage tank to suck up the sludge accumulated at the bottom of the sewage tank. There is also a problem that it is difficult to dispose of sludge because only sludge can be removed. Since the sludge thus recovered has a large water content, there is a problem that the weight of industrial waste is large.

Further, in the conventional technique, since the filter is clogged, it is necessary to frequently replace the expensive filter, which causes a problem that the work is difficult and the cost is high. In addition, there is a problem that the replaced filter becomes industrial waste.

Furthermore, in the prior art, since the sludge discharged from the sludge tank has a large water content, there is a problem that the above-mentioned waste water tank becomes very large. In addition, there is a problem that the sludge accumulated in the waste water tank needs to be drained, and the process must be repeated many times.

Further, sludge that precipitates and light suspended matter are mixed in the wastewater. However, heretofore, there has been no method for efficiently removing both of these sludges and suspended matters.

Therefore, the present invention aims to efficiently remove not only iron content in wastewater but also all sludges, facilitate sludge treatment, and reduce the amount of industrial waste generated by wastewater treatment. The purpose of 1. further,
The second purpose is to efficiently remove not only sludge in wastewater but also suspended matter.

[0010]

According to a first aspect of the present invention, there is provided a sewage treatment method, wherein sewage is temporarily accumulated in a sewage tank and then put into a separation tank for precipitating sludge. Then, the sludge settled in the separation tank is introduced into the draining tank together with the liquid at the bottom, and the sludge introduced into the draining tank is scooped up by a draining bucket and lifted to the air to drain the sludge, and the sludge drained. Is introduced into the sludge reservoir, and the supernatant liquid of the separation tank is caused to overflow into the supernatant liquid storage tank.

According to the wastewater treatment method of the present invention, for example, even if there is a variation in the way wastewater is generated as a result of once collecting and accumulating all the generated wastewater in the wastewater tank. According to the processing speed in the separation tank, the wastewater can be treated and sludge residue can be eliminated at the same time. Further, since the sludge is separated by the rapid precipitation in the separation tank, not only iron content but also particles such as abrasive grains in the coolant liquid (particles having a larger specific gravity than water) can be removed from the waste water. The sludge settled in the separation tank is drained by being introduced into the draining tank, scooped up in a draining bucket and lifted up to the air, so that the water content is low and the weight of industrial waste can be reduced. Since only the clean supernatant liquid containing no sludge is stored in the supernatant liquid storage tank, it is not necessary to perform the sludge treatment on the supernatant liquid storage tank.

Further, in addition to the first object, the sewage treatment method according to claim 2 which is made to achieve a second object, is the sewage treatment method according to claim 1, further comprising the supernatant liquid. The present invention is characterized in that the suspended matter on the surface in the storage tank is sucked out and put into the draining tank.

According to the sewage treatment method of the second aspect, for example, the liquid on the surface in the supernatant liquid storage tank is sucked out, and the suspended matter floating on the surface is thrown into the draining tank. Light floating material that has entered the liquid storage tank can be transferred from the supernatant liquid storage tank to the drainer tank. The suspended matter transferred to the draining tank is scooped up when the draining bucket rises from the liquid to the air, and is thus removed together with the sludge. As a result, according to the wastewater treatment method of the second aspect, in addition to the sludge in the wastewater, suspended matters can be removed.

The sewage treatment apparatus according to the third aspect of the present invention, which has been made to achieve the first object, has a sewage tank for temporarily storing sewage, and sewage from the bottom of the sewage accumulated in the sewage tank. Taking out means, a separation tank for separating the clean liquid and sludge by depositing the wastewater taken out by the wastewater removing means, and sludge settling, and the sludge settling in the separation tank at the bottom. A drainage tank introduced with the liquid,
A drainer bucket that scoops up sludge introduced into the drainer tank and lifts it to the air to drain the sludge, and discharges the sludge that has finished draining,
A sludge reservoir for storing the sludge discharged by the draining bucket, an overflow channel for overflowing the supernatant liquid of the separation tank, and a supernatant liquid storage tank for storing the supernatant liquid overflowed through the overflow channel. It has and.

According to the sewage treatment apparatus of the third aspect, sewage such as the coolant of the machine tool is temporarily accumulated in the sewage tank. Then, the sewage accumulated in the sewage tank is taken out from the bottom portion of the tank by the sewage taking-out means and put into the separation tank. In the separation tank filled with sewage, by precipitating sludge in sewage,
The clean liquid and sludge are separated. In this way, since sludge is removed by sedimentation in the separation tank, not only metal particles such as iron but also particles such as abrasive particles in the coolant can be removed from the dirty water. Since the sludge separated in this way has settled at the bottom of the separation tank, this sludge is introduced into the draining tank together with the liquid at the bottom. Then, in the draining tank, the draining is performed by scooping up the sludge with a draining bucket and lifting it up into the air. The sludge that has been drained in this way is discharged to the sludge reservoir. Since the sludge thus discharged to the sludge reservoir is drained, the water content is low and the weight of industrial waste can be reduced. On the other hand, the supernatant of the separation tank is overflowed and stored in the supernatant storage tank via the overflow channel. The liquid stored in the supernatant liquid storage tank in this way
Since the sludge is regenerated into a cleaning liquid that has been almost completely removed, it can be reused as a coolant liquid for a machine tool, for example. In addition, since only the clean supernatant liquid containing no sludge is stored in the supernatant liquid storage tank, it is not necessary to perform sludge treatment on the supernatant liquid storage tank.

The sewage treatment apparatus according to a fourth aspect is the sewage treatment apparatus according to the third aspect, wherein at least the bottom of the sewage tank is inclined like a mortar and sludge in the sewage is concentrated in the center of the bottom. It is characterized in that it is settled, and the sewage extraction means is arranged so as to take out all the sludge from the center of the bottom without leaving any sludge.

According to the sewage treatment apparatus of the present invention, in the sewage tank, the sludge is concentrated and settles in the center of the bottom, and the sewage removal means takes out the sewage from the center of the bottom. Almost all of the sludge will be transferred to a separation tank. Therefore, it is not necessary to treat the sludge tank with sludge.

Further, in addition to the first object, the sewage processing apparatus according to claim 5 which is made to achieve a second object, further comprises the sewage processing apparatus according to claim 3 or 4. A surface water intake device for sucking out suspended matter on the surface in the supernatant liquid storage tank and feeding it into the water draining tank is also provided.

According to the sewage treatment apparatus of the fifth aspect, the surface water intake device sucks out the liquid on the surface in the supernatant liquid storage tank, so that the floating substances floating therein are sucked into the draining tank. By doing so, it is possible to transfer the light floating material that has entered the supernatant liquid storage tank from the supernatant liquid storage tank to the drainer tank. The suspended matter transferred to the draining tank is scooped up when the draining bucket rises from the liquid to the air, and is thus removed together with the sludge. As a result, according to the wastewater treatment device of the fifth aspect, in addition to the sludge in the wastewater, suspended matters can be removed.

A sewage treatment apparatus according to a sixth aspect of the present invention, which is a more specific invention made to achieve the first object, is provided with a sewage tank for temporarily storing sewage, and provided in the sewage tank. , A submersible pump that sucks up the wastewater from the bottom of the wastewater tank, and the wastewater sucked up by the submersible pump is charged from above to settle the sludge in the wastewater,
A separation tank for separating sewage into sludge and clean liquid, a draining tank communicating with the separation tank through a communication port provided at the bottom of the wall surface, and a separation tank provided at the bottom of the separation tank. Sludge scraping means for scraping sludge collected at the bottom of the tank from the communication port to the draining tank, and sludge collected at the bottom of the draining tank, which is provided in the draining tank, rises by scooping up the sludge. A slant that has been turned upside down by a predetermined amount to drop the scooped sludge, and then descends and is circulated along a circulation path that moves to the bottom, and directly below the position where the draining bucket is turned over. A sludge sludge provided for receiving sludge falling from the draining bucket and dropping the sludge into a sludge reservoir. And an overflow channel provided in the upper part of the separation tank for overflowing the supernatant of the separation tank, and a supernatant liquid storage tank for storing the supernatant liquid overflowing through the overflow channel, A supply pump for sucking clean water from the supernatant liquid storage tank is provided.

According to the sewage treatment apparatus of the sixth aspect, the sewage such as the coolant of the machine tool, the industrial effluent, the domestic effluent, and the civil engineering effluent is temporarily accumulated in the sewage tank, for example. Then, the sewage accumulated in the sewage tank is sucked up from the bottom of the sewage tank by the submersible pump,
It is put into a separation tank. The separation tank, into which the waste water is fed from above, separates the waste water into sludge and clean liquid while allowing the sludge in the waste water to settle. Then, the sludge collected at the bottom of the separation tank is scraped out from the communication port to the draining tank by the sludge scraping means. The sludge that was scraped out to the drainer tank in this way
It is concentrated and collects at the bottom of the draining tank. Then, the sludge accumulated at the bottom of the draining tank is scooped up by the draining bucket and slowly raised to a predetermined amount above the liquid level. Thus, once exposed to the air, the sludge is drained. Then, the sludge that has finished draining is dropped downward by reversing the draining bucket. The sludge thus dropped falls on a sludge shooter provided immediately below the position where the draining bucket is reversed, and is naturally dropped into the sludge reservoir. On the other hand, the supernatant liquid in the upper part of the separation tank overflows via the overflow channel and is stored in the supernatant liquid storage tank. Then, the liquid stored in the supernatant liquid storage tank is sucked out by the supply pump, and if this is a processing liquid for the coolant that is being used, for example, it will be continuously reused as the coolant for the machine tool. Become. With the above operation, in the separation tank, for example, if the coolant is the processing target, it is possible to separate and remove from the dirty water such as metal particles, solid particles, and abrasive particles generated by polishing and cutting. . In addition, since the sludge thrown into the sludge reservoir is drained, the water content is low and the weight of industrial waste can be reduced. Further, since only the clean supernatant liquid containing no sludge is stored in the supernatant liquid storage tank, it is not necessary to perform the sludge treatment on the supernatant liquid storage tank. Further, according to the sewage treatment apparatus of the sixth aspect, the draining bucket that has sludge dropped onto the sludge shooter is then lowered, re-enters the liquid, and moves to the bottom, so that it is cleaned and clogged during that time. The effect of preventing is also exhibited.

The sewage treatment apparatus according to claim 7 is the sewage treatment apparatus according to claim 6, wherein at least the bottom of the sewage tank is inclined like a mortar and sludge in the sewage is concentrated in the center of the bottom. The submersible pump is configured to settle, and the submersible pump is installed at the center of the bottom of the waste water tank.

According to the sewage treatment apparatus of the present invention, in the sewage tank, the sludge in the sewage concentrates and concentrates at the bottom center, and the submersible pump sucks the sewage from the bottom center of the sewage tank. Almost all of the sludge inside will be introduced into the separation tank. As a result, the sludge treatment work in the wastewater tank is not required.

The sewage treatment apparatus according to claim 8 is the sewage treatment apparatus according to any one of claims 6 and 7, wherein the submersible pump is provided with a float switch so that the liquid level in the sewage tank is increased. It is characterized in that it is configured to operate only when it is within a predetermined range.

According to the sewage treatment apparatus of the eighth aspect, when the height of the liquid surface in the sewage tank decreases to a predetermined amount, the float switch operates and the operation of the submersible pump is stopped. As a result, it is possible to prevent a problem that the submersible pump sucks air and then becomes inoperable. Further, when the height of the liquid surface in the dirty water tank increases to a predetermined amount, the float switch operates and the submersible pump is started, so that overflow from the dirty water tank can be prevented.

The sewage treatment apparatus according to claim 9 is the sewage treatment apparatus according to any one of claims 6 to 8.
The supernatant liquid storage tank is partitioned into a plurality of compartments inside, each compartment communicates via a communication port at the bottom of the partition wall, and the pump is a compartment into which the liquid flows from the overflow channel. It is characterized in that it is provided in another section.

It is conceivable that floating substances are mixed in the wastewater overflowing from the separation tank. However, by adopting the above-mentioned structure, the floating substances can be converted into liquid from the overflow channel. This is because it exists only in the section where the inflow occurs and does not enter the section where the supply pump is installed. As a result, according to the sewage treatment apparatus of the ninth aspect, the liquid sucked from the supernatant liquid storage tank by the supply pump contains neither sludge nor suspended matter.

The sewage treatment apparatus according to a tenth aspect of the present invention is the sewage treatment apparatus according to the ninth aspect, in which a suspended matter on the surface is sucked into a section into which the liquid flows from the overflow passage in the supernatant liquid storage tank. A surface water intake device is provided, and the suspended matter sucked by the surface water intake device is configured to be thrown into the draining tank.

According to the sewage treatment apparatus of the tenth aspect,
The suspended matter that has entered the compartment into which the liquid flows from the overflow channel in the supernatant liquid storage tank is sucked out by the surface water intake device and put into the drainer tank. As a result, the suspended matter is scooped up at the liquid level by the draining bucket which scoops up the sludge and rises in the draining tank, and is dropped on the sludge shooter together with the sludge and discharged. As a result, according to the sewage treatment apparatus of the tenth aspect, the second purpose can be achieved in addition to the first purpose.

The sewage treatment apparatus according to an eleventh aspect is the sewage treatment apparatus according to the tenth aspect, wherein the surface water intake device sucks out the liquid by an ejector that operates by utilizing the liquid discharged from the submersible pump. It is characterized by being configured as.

According to the wastewater treatment apparatus of the eleventh aspect,
Since the power of the surface water intake device is generated by the ejector, there is no failure and maintenance-free operation can be realized as compared with the case where a centrifugal pump is used. In other words, a spiral pump stops when it sucks air, but it does not move, but the ejector can safely suck air.

The sewage treatment apparatus according to claim 12 is the sewage treatment apparatus according to claim 10 or 11, wherein the surface water intake device ascends / descends the intake port in response to the rise / fall of the liquid level. It is characterized in that it has a float that allows it.

According to the sewage treatment apparatus of claim 12,
The surface water intake device raises the liquid level due to the action of the float.
As the water intake is raised and lowered in response to lowering, always,
The suspended matter that has entered the supernatant liquid storage tank can be efficiently sucked out and put into the drainer tank.

A sewage treatment apparatus according to a thirteenth aspect is the sewage treatment apparatus according to any one of the ninth to twelfth aspects, wherein the sewage tank has a liquid from the overflow channel in the supernatant liquid storage tank. It is characterized in that it is installed at a position displaced from the liquid inflow position from the overflow channel in the inflow section.

According to the sewage treatment apparatus of the thirteenth aspect,
The entire device can be designed compactly. Here, by adopting the configuration as described above, in the unlikely event that the submersible pump fails, the sewage overflowing from the sewage tank is a section into which the liquid flows from the overflow channel in the supernatant liquid storage tank. Will flow into. Since this section is separated from the section in which the supply pump is installed, there is little risk that the sewage overflowing from the sewage tank will flow into the section in which the supply pump is installed. And even if sewage directly flows into a specific section of the supernatant storage tank,
This results in no change from the situation of the prior art described above. Rather, according to the conventional technique, sludge is accumulated in every corner of the tank, and it is very difficult to recover the sludge. However, in the wastewater treatment device of claim 13, sludge is accumulated only in a specific section. The recovery process is relatively easy. Then, as a countermeasure when a large amount of sewage is generated in a short period of time, sewage does not overflow to the outside of the device. Therefore, the sewage treatment device according to claim 13 has a problem that occurs when the entire device is made compact. It will be an effective solution.

A sewage treatment apparatus according to a fourteenth aspect is the sewage treatment apparatus according to any one of the sixth to twelfth aspects, wherein the scraping means is provided with respect to a horizontal bar provided on a rotary shaft extending in a vertical direction. , A plurality of scraping plates that are mounted in a state of being inclined at a predetermined angle are provided, and the scraping ranges of the scraping plates are shifted, and the scraping plates move sludge outward from the center of the bottom of the separation tank. It is characterized in that it is arranged so as to scrape out the sludge while gradually moving.

According to the sewage treatment apparatus of the fourteenth aspect,
The scraping means scrapes the sludge by gradually moving the sludge outward from the center of the bottom of the separation tank by using a plurality of scraping plates whose scraping ranges are shifted. As a result, even if the amount of sludge is large, the sludge can be smoothly scraped out, and the power for scraping out the sludge does not need to be so large. Therefore, it is effective for a compact design.

The sewage treatment apparatus according to a fifteenth aspect is the sewage treatment apparatus according to any one of the third to fourteenth aspects, wherein the separation tank has a cylindrical shape into which sewage is introduced in a tangential direction. And a solid-liquid separation section including a ring-shaped gap formed by a conical double wall that spreads toward the inside and communicates with the inside of the wastewater input section.

According to the sewage treatment apparatus of the fifteenth aspect,
The sewage that is input from the sewage tank to the separation tank forms a swirling flow by entering the sewage input section from the tangential direction,
The sludge and the liquid can be efficiently separated by settling while swirling in the ring-shaped gap of the solid-liquid separation portion formed by the divergent conical double wall.

The sewage treatment apparatus according to a sixteenth aspect is the sewage treatment apparatus according to the fifteenth aspect, wherein the sewage input section is provided with an introduction path for introducing the supernatant liquid of the sewage input section into the draining tank. It is characterized by

According to the sewage treatment apparatus of the sixteenth aspect,
The supernatant liquid of the waste water input section is introduced into the draining tank via the introduction path. As a result, the suspended matter contained in the wastewater and floating near the liquid surface of the wastewater input section is introduced into the draining tank by the swirling flow, and when the draining bucket scoops up the concentrated sludge and rises, They are scooped up together and disposed of. As a result, not only sludge but also suspended matter can be effectively treated.

The sewage treatment apparatus according to a seventeenth aspect is provided in the upper part, and has a cylindrical sewage input compartment into which sewage is input from a tangential direction, and a divergent conical double-sided passage communicating with the sewage input compartment. And a solid-liquid separation part formed of a ring-shaped gap formed by the wall, and the sewage introduced into the sewage input compartment is lowered while swirling between the conical double walls of the solid-liquid separation part. As a result, a separation tank that raises the clean liquid from which sludge has been removed while allowing the sludge in the wastewater to settle and separate, and a draining tank that communicates with the separation tank via a communication port provided at the bottom of the wall surface. And a plurality of scraping plates that are mounted at a predetermined angle with respect to a horizontal bar provided on a rotary shaft that extends vertically in the bottom of the separation tank. Are arranged so that the respective scraping ranges are shifted, and the scraping plates are scraped out from the communication port to the draining tank while gradually moving the sludge outward from the center of the bottom of the separation tank by the scraping plates. The sludge scraping means and the drainer tank are provided in the drainer tank, and the concentrated sludge accumulated at the bottom of the drainer tank is scooped up and raised, and the sludge slid up is inverted and dropped at a position above the liquid level by a predetermined amount. , A drainer bucket that is then circulated and moved along a circulation path that descends and moves to the bottom, and is provided immediately below the position at which the drainer bucket reverses, receives sludge falling from the drainer bucket, and The sludge shooter that drops the water into the sludge reservoir and the upper part of the separation tank And an overflow passage for overflowing the supernatant of the separation tank, and the sewage input section is provided with an inlet passage for introducing the supernatant of the sewage input section into the draining tank. It is characterized by

According to the wastewater treatment apparatus of the seventeenth aspect,
Sewage is tangentially injected into the sewage input section of the separation tank to form a swirling flow, and settles while swirling in the ring-shaped gap of the solid-liquid separation section formed by the conical double wall that spreads toward the end. Thus, sludge and liquid can be efficiently separated. Then, the separated sludge continues to settle to the bottom of the separation tank, and the clean liquid from which the sludge has been removed rises to the top of the separation tank. The sludge that has settled to the bottom of the separation tank is gradually moved outward from the center of the bottom of the separation tank by the plurality of scraping plates and is scraped from the communication port to the draining tank. The concentrated sludge that has been scraped out to the draining tank accumulates at the bottom of the draining tank, is scooped up by a draining bucket passing there, and is drained while rising above the liquid level by a predetermined amount, and then the draining bucket is inverted. Will be dropped on the sludge shooter. Then, the sludge dropped on the sludge shooter is dropped as it is to the sludge reservoir. On the other hand, the sludge-removed clean liquid that has risen to the upper portion of the separation tank is naturally discharged from the separation tank through the overflow channel. The clean liquid thus discharged can be stored in a storage tank and reused.
Further, the supernatant liquid of the waste water input section is introduced into the draining tank by a swirling flow through the introduction path. Therefore, the suspended matter in the dirty water will be introduced into the draining tank, scooped up the sludge and scooped up near the liquid level by the draining bucket, and it will be dropped together with the sludge to the sludge shooter and disposed of. .

[0044]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, embodiments of the present invention will be described with reference to the drawings.

The sewage treatment apparatus of the embodiment is shown in FIGS. Here, FIG. 1 is a plan view, FIG. 2 is a front view, and FIG.
Shows a left side view of the main part. As shown in FIGS. 1 to 3, the sewage treatment apparatus 1 of this embodiment has a cylindrical sewage tank 3 for temporarily storing sewage, and a bottom portion of the sewage tank 3 provided in the sewage tank 3. A submersible pump 5 for sucking sewage from the water, and a cylindrical separation tank 7 for injecting the sewage sucked by the submersible pump 5 from above and separating the sewage into sludge and a clean liquid while allowing the sludge in the sewage to settle. The draining tank 11 that communicates with the separation tank 7 through a communication port 9 provided at the bottom of the wall surface, and the concentrated sludge that is provided at the bottom of the separation tank 7 and collects at the bottom of the separation tank 7. Drain tank 11 from mouth 9
The sludge scraping-out means 13 for scraping out the sludge and the sludge accumulated in the bottom of the draining tank 11 provided in the draining tank 11 are scooped up and raised, and the sludge which is reversed and scooped up at a position above the liquid level by a predetermined amount Draining bucket 1 made of punching metal that is circulated along a circulation path that drops and then descends and moves to the bottom.
5 and the draining bucket 15 are provided directly below the inverted position to receive the sludge falling from the draining bucket 15 and to have the sludge shooter 19 having a sufficient inclination to drop the sludge into the sludge reservoir 17.
And an overflow channel 21 provided above the separation tank 7 for overflowing the supernatant of the separation tank 7, and a supernatant liquid storage tank 23 for storing the supernatant liquid overflowing via the overflow channel 21. And a supply pump 25 for sucking the liquid from the supernatant liquid storage tank 23.

Here, as shown in FIGS. 1 and 2, the sewage tank 3 has a structure in which at least the bottom is inclined like a mortar, and sludge in the sewage is concentrated and concentrated in the center of the bottom. The submersible pump 5 is installed at the center of the bottom of the dirty water tank 3.

The submersible pump 5, as shown in FIG.
The float switch 5a is configured to operate only when the liquid level in the dirty water tank 3 is within a predetermined range.

Further, as shown in FIGS. 1 and 2, the supernatant liquid storage tank 23 is divided into two compartments, and each compartment communicates with each other through a communication port 23b at the bottom of the partition wall 23a. The supply pump 25 is provided in a section different from the section into which the liquid flows from the overflow passage 21.

Further, as shown in FIG. 1, a surface water intake device 27 for sucking out suspended matter on the surface is provided in the section into which the liquid flows from the overflow channel 21 in the supernatant liquid storage tank 23. The liquid sucked by 27 is configured to be poured into the draining tank 11.

Further, as shown in FIGS. 1, 2 and 5, the surface water intake device 27 is constructed as a means for sucking out suspended matter by an ejector 29 which operates by utilizing the liquid discharged from the submersible pump 5. There is.

The surface water intake device 27, as shown in FIG. 5, raises and lowers the water intake 27a in response to the rise and fall of the liquid level.
It is equipped with a float 27b for lowering. Note that reference numeral 2
Reference numeral 7c is a slide type pipe that rises and falls in accordance with the rise and fall of the float 27b, and reference numeral 27d is a fixed pipe fixed to the bottom of the supernatant liquid storage tank 23.

Further, as shown in FIGS. 1 and 2, the sewage tank 3 is displaced from the liquid inflow position from the overflow channel 21 to a section in the supernatant liquid storage tank 23 into which the liquid flows. It is installed in a different position. This is the overflow channel 21
The purpose is to prevent the liquid flowing in from flowing into the wastewater tank again.

Further, as shown in FIGS. 2 and 4, the scraping means 13 is inclined at a predetermined angle (30 ° in the present embodiment) with respect to a horizontal bar 13b provided on a rotary shaft 13a extending in the vertical direction. It is equipped with three scraping plates 13c, 13c, 13c that are attached in a closed state, and the scraping plates 13c, 13c, 13c are shifted in their scraping ranges, and the scraping plates 13c, 13c are
The c and 13c are arranged so as to scrape out the sludge while gradually moving the sludge outward from the center of the bottom of the separation tank 7. Further, each scraping plate 13c is made of a steel plate, and a urethane pad is attached to the lower surface for the purpose of noise prevention and the like.

Further, as shown in FIGS. 1 and 2, the separation tank 7 has a cylindrical sewage input compartment 7a into which sewage is input from the tangential direction, and a divergent end which communicates with the sewage input compartment 7a. It is provided with a solid-liquid separation portion 7e including a ring-shaped gap 7d formed by the conical double walls 7b and 7c.

In addition, the sewage input section 7a is provided in FIGS.
As shown in FIG. 7, an introduction path 7f is provided for introducing the supernatant liquid of the waste water input section 7a into the drainer tank 11.

Further, as shown in FIG. 2, the rotary shaft 13a of the sludge scraping-out means 13 is connected to the geared motor M1 via the coupling 31 and is driven by the geared motor M1. . Reference numerals 32 and 33 are bearings.

As shown in FIG. 2, the draining buckets 15 are arranged at the top and bottom of the draining tank 11.
Four rollers in total are fixed to a pair of roller chains 44, which are a pair of two rollers, which are wound around the pair of sprockets 41, 42, and 43. As shown in FIGS. 1 and 3, the geared motor M2 drives the motor. Note that the reference numeral 45 in FIG. 2 is a control panel.

Next, the operation of the sewage treatment apparatus 1 will be described.

Wastewater such as coolant of machine tools, industrial wastewater, domestic wastewater, and civil engineering wastewater flows into the wastewater tank 3 through the gutter 51 for introducing the wastewater, and is temporarily accumulated there.
Then, the sewage accumulated in the sewage tank 3 is sucked up from the bottom of the sewage tank 5 by the submersible pump 5 and is fed into the separation tank 7. The sewage introduced from the sewage tank 3 into the separation tank 7 enters the sewage input compartment 7a from the tangential direction to form a swirl flow, and the solid-liquid separation section formed by the divergent conical double walls 7b and 7c. By being settled while rotating in the ring-shaped gap 7d, the sludge and liquid are efficiently separated. In addition,
The sludge that has left the gap 7d settles on the bottom of the separation tank 7 as it is, and the liquid that has left the gap 7d rises above the separation tank 7.

The sludge collected at the bottom of the separation tank 7 is communicated with the communication port 9 by the sludge scraping means 13.
Is drained from the drainage tank 11 to the drainer tank 11. The concentrated sludge thus scraped out to the draining tank 11 is
Collect at the bottom of the draining tank 11. Then, the sludge accumulated at the bottom of the draining tank 11 is scooped up by the draining bucket 15 and raised to a predetermined amount above the liquid level. Thus, once exposed to the air, the sludge is drained.

Then, the sludge that has been drained is dropped downward by reversing the draining bucket 15. The sludge that has fallen in this way is drained from the bucket 1.
5 falls on a sludge shooter 19 having a sufficient inclination provided just below the position where the sludge 5 is inverted,
Will be dropped naturally.

On the other hand, the supernatant liquid above the separation tank 7 is
It overflows through the overflow passage 21 and is dropped into the right compartment (see FIGS. 1 and 2) of the supernatant liquid storage tank 23. The supernatant liquid thus dropped into the right-side compartment of the supernatant liquid storage tank 23 flows into the left-side compartment via the communication port 23b opening at the bottom of the partition wall 23a. Then, the liquid that has flowed into the left-side compartment is sucked out by the supply pump 25 and can be reused as it is as the coolant of the machine tool as it is for a period of three times or more that in the conventional technique. Become.

Further, the supernatant liquid of the waste water input section 7a is introduced into the draining tank 11 via the introduction path 7f. As a result, the suspended matter contained in the sewage water that has just been added to the sewage supply section 7a is supplied to the draining tank 11. Further, the suspended matter that has entered the compartment (right compartment) into which the liquid flows from the overflow passage 21 of the supernatant liquid storage tank 23 is sucked out by the surface water intake device 27,
It is thrown into the draining tank 11.

In this way, the suspended matter thrown into the water draining tank 11 is scooped up at the liquid level by the water draining bucket 15 which scoops up sludge in the water draining tank 11 and is dropped to the sludge shooter 19 together with the sludge and discharged to the outside. To be done.

When the height of the liquid surface in the dirty water tank 3 is reduced to a predetermined amount during the execution of these series of operations, the float switch 5a is actuated and the operation of the submersible pump 5 is stopped. As a result, it is possible to prevent a problem that the submersible pump 5 sucks air and then becomes inoperable. When the height of the liquid level in the dirty water tank 3 increases to a predetermined amount, the float switch operates and the submersible pump 5 is activated, so that overflow from the dirty water tank 3 can be prevented.

With the above-described operation, not only metal particles but also particles such as abrasive particles in the coolant can be removed from the contaminated water in the separation tank 3. Further, since the sludge thrown into the sludge reservoir 17 is drained, the water content is low and the weight of industrial waste can be reduced. Furthermore, in the compartment on the left side of the supernatant liquid storage tank 23, only a clean liquid containing neither sludge nor suspended matter is stored. Therefore, when the coolant liquid of the machine tool is treated, even if it is reused, there is no problem that the product is scratched or has a strange odor due to dirt. Further, it is not necessary to perform sludge treatment on the left section of the supernatant liquid storage tank 23. Also,
The draining bucket 15 that has dropped the sludge onto the sludge shooter 19 then descends, re-enters the liquid, and moves to the bottom, so that the effect of being cleaned and preventing clogging during that time is also exhibited.

Further, in the sewage tank 3, sludge in the sewage concentrates on the center of the bottom and the submersible pump 5 sucks the sewage from the center of the bottom of the sewage tank 3, so that the sludge in the sewage tank 3 is almost entirely removed. Will be introduced into the separation tank 7. As a result, it is not necessary to treat the sludge in the dirty water tank 7.

Further, the reason why the supernatant liquid storage tank 23 is divided into two compartments by the partition wall 23 is that floating matters may be mixed in the supernatant liquid overflowing from the separation tank 7. This is because by adopting such a configuration, the suspended matter exists only in the section into which the liquid has flowed in from the overflow channel 21, and does not enter the section in which the supply pump 25 is installed. As a result, the liquid sucked from the supernatant liquid storage tank 23 by the supply pump 25 contains neither sludge nor suspended matter.

Further, since the power of the surface water intake device 27 is generated by the ejector 29, there is no trouble and maintenance-free operation can be realized as compared with the case of using the centrifugal pump. That is, if the centrifugal pump sucks air, it becomes impossible to discharge the air, but the ejector 29 can suck the air.

The surface water intake device 27 is a float 27.
Intake 2 corresponding to the rise and fall of the liquid level by the action of b
Since 7a is moved up and down, it is always possible to efficiently suck up the suspended matter that has entered the supernatant liquid storage tank 23 and add it to the drainer tank 11.

Further, by disposing the waste water tank 3 in the compartment on the right side of the supernatant liquid storage tank 23,
The entire device can be designed compactly. Also,
By adopting such a configuration, if the submersible pump 5 should fail, the sewage overflowing from the sewage tank 3 will be
It will flow into the compartment on the right side of the supernatant liquid storage tank 23. Since this section is partitioned from the section in which the supply pump 25 is installed, there is little possibility that the sewage overflowing from the sewage tank 3 will flow into the section in which the supply pump 25 is installed. Then, the supernatant liquid storage tank 23
Even if the sewage flows directly into the compartment on the right side of the, this results in no change from the state of the art described above. Rather, in the prior art, sludge was accumulated in every corner of the tank, and it was very difficult to recover the sludge. However, in the sewage treatment apparatus 1, sludge is accumulated only in the right section, so the treatment is comparative. It is easy. Then, as a countermeasure when a large amount of wastewater is generated in a short period of time, the wastewater does not overflow to the outside of the device, so this wastewater treatment device 1 effectively solves the problem that occurs when the entire device is made compact. It is supposed to do.

The scraping means 17 is composed of three scraping plates 13 whose scraping ranges are shifted.
While gradually moving the sludge from the center of the bottom of the separation tank 7 to the outside by c, 13c, 13c,
Execute sludge scraping. As a result, even if the amount of sludge is large, the sludge can be smoothly scraped out, and the power for scraping out the sludge does not need to be so large. Therefore, it is effective for a compact design.

Furthermore, the sewage treatment apparatus 1 of the present embodiment
The ejector 29 and the geared motors M1 and M in the power unit.
2 is adopted, and the submersible pump 5 is adapted to be started / stopped according to the liquid level by the float switch 5a, so that there is no failure and maintenance-free use is possible.

Next, the design criteria of the ring-shaped gap 7d formed by the conical double walls 7b and 7c will be described with reference to FIG. As shown, the conical walls 7b, 7c
The inclination of is preferably 60 °. Further, the diameter of the outer conical wall 7b is Φ1, and the diameter of the inner conical wall 7c is Φ1.
2, the size h of the gap 7d between the conical walls 7b and 7c
(Mm) is preferably determined so as to satisfy the following formula.

[0075]

[Formula 1] h = Φ1 / (25 to 30)

The exit flow velocity v2 (vm / sec) from between the conical walls 7b and 7c is the throughput Q1 (liter / m).
In), the area F2 (cm ² ) of the outlet is determined so as to be ^{2 to} 5 cm / sec. Therefore, as the processing amount Q1 increases, the main body also increases in size.

Although the embodiment of the present invention has been described in detail above, the present invention is not limited to this.

For example, the dirty water tank 3 may be installed outside the supernatant liquid storage tank 23. As for the structure of the separation tank 7, any other structure may be adopted as long as it can separate the sludge from the liquid and settle the sludge on the bottom. Further, for example, even in the case where the means for introducing the wastewater from the wastewater tank 3 to the separation tank 7 does not use the submersible pump but adopts a configuration in which the drain valve or the like is opened to introduce the wastewater, the gist of the present invention It does not deviate. In addition, the sludge shooter 19 may be omitted, and the sludge may be dropped into the sludge reservoir 17 by a conveyor such as a belt conveyor. In addition, the supernatant liquid storage tank 2
Regarding the means for taking out the clean liquid from 3, it is also possible to change to a configuration in which the valve is opened and taken out without using the supply pump 25. Furthermore, the inside of the supernatant liquid storage tank 23 may be partitioned into three or more sections. In that case, a section between the section in which the supply pump 25 is installed and the section in which the dirty water tank 3 is installed may be a section for performing some chemical treatment or electromagnetic treatment on the treated water. . The sewage that can be treated by the method and apparatus of the present invention is not limited to the coolant, but includes various industrial effluents, agricultural effluents, civil effluents, sewage, and the like.

[0079]

As described in detail above, according to the present invention, not only metal particles, solid particles, and oil components in wastewater but also all sludges are efficiently removed, and sludge treatment is facilitated. In addition, the amount of industrial waste generated by wastewater treatment can be reduced. Further, not only the sludge in the wastewater but also the suspended matter can be efficiently removed.

[Brief description of drawings]

FIG. 1 is a plan view of a sewage treatment apparatus as an embodiment.

FIG. 2 is a front view of a sewage treatment apparatus as an embodiment.

FIG. 3 is a left side view of a main part of the sewage treatment apparatus according to the embodiment.

FIG. 4 is a plan view showing a configuration of sludge scraping means adopted in the sewage treatment apparatus according to the embodiment.

FIG. 5 is a front view showing a configuration of a surface water intake device adopted in the sewage treatment apparatus according to the embodiment.

FIG. 6 is an explanatory diagram for explaining design criteria in the embodiment.

[Explanation of symbols]

1 ... Sewage treatment device, 3 ... Sewage tank, 5 ...
Submersible pump, 5a ... Float switch, 7 ... Separation tank, 7a ... Waste water input section, 7b, 7c ...
Double wall (conical wall), 7d ... Ring-shaped gap, 7e
..Solid-liquid separation section, 7f ... Introduction path, 9 ... Communication port,
11 ... Draining tank, 13 ... Sludge scraping means, 13a ... Rotating shaft, 13b ... Horizontal bar, 1
3c ... Scraping plate, 15 ... Draining bucket, 17 ... Sludge reservoir, 19 ... Sludge shooter, 21 ... Overflow passage, 23 ... Supernatant storage tank, 23a ... Partition Wall, 23b ... communication port, 2
5 ... Supply pump, 27 ... Surface water intake device, 27a
... Intake port, 27b ... Float, 27c ... Sliding pipe, 27d ... Fixed pipe, 29 ... Ejector, 31 ... Coupling, 32, 33 ... Bearing, 41 , 42, 43 ... Sprocket, 44
..Roller chain, 45 ... control panel, 51 ... gutter for introducing dirty water, M1, M2 ... geared motor

Claims (17)

[Claims] 1. After the wastewater is once accumulated in the wastewater tank,
Put the sludge in the separation tank for settling, introduce the sludge settling in the separation tank together with the liquid at the bottom into the draining tank, and scoop up the sludge introduced in the draining tank with a draining bucket and lift it to the air. A drainage treatment method is characterized in that the drainage is carried out by the above method, the drained sludge is introduced into a sludge reservoir, and the supernatant liquid of the separation tank is made to overflow into a supernatant liquid storage tank. 2. The sewage treatment method according to claim 1, further comprising: sucking out suspended matter on the surface of the supernatant liquid storage tank and introducing the suspended matter into the draining tank. 3. A sewage tank for temporarily storing sewage, sewage removal means for removing the sewage accumulated in the sewage tank from the bottom, and sewage extracted by the sewage removal means for precipitating sludge. The separation tank for separating the clean liquid and the sludge, the drainer tank in which the sludge settled in the separation tank is introduced together with the liquid at the bottom, and the sludge introduced in the drainer tank is scooped up in the air. Drainage by discharging the sludge that has finished draining, a sludge reservoir for storing the sludge discharged by the draining bucket, and an overflow for overflowing the supernatant liquid of the separation tank. And a supernatant liquid storage tank for storing the supernatant liquid overflowing through the overflow passage. And that sewage treatment equipment. 4. The sewage treatment apparatus according to claim 3, wherein the sewage tank has a structure in which at least a bottom portion is inclined like a mortar, and sludge in the sewage is concentrated and concentrated in the center of the bottom portion. The sewage treatment apparatus is characterized in that the means is arranged so as to take out sewage from the center of the bottom. 5. The sewage treatment apparatus according to claim 3 or 4, further comprising a surface water intake device that sucks out suspended matter on the surface in the supernatant liquid storage tank and inputs it into the drainer tank. A sewage treatment device characterized by the above. 6. A sewage tank for temporarily storing sewage, a submersible pump provided in the sewage tank for sucking sewage from the bottom of the sewage tank, and the sewage sucked by the submersible pump is introduced from above, A separation tank for separating the sludge into sludge and a clean liquid while allowing the sludge in the wastewater to settle; a draining tank communicating with the separation tank through a communication port provided at the bottom of the wall surface; Sludge scraping means provided at the bottom of the tank and scraping sludge collected at the bottom of the separation tank from the communication port to the draining tank, and sludge provided at the bottom of the draining tank provided in the draining tank. Scoop up to rise, flip over at a position above the liquid level by a predetermined amount to drop the scooped sludge, and then descend to the bottom. A draining bucket that is circulated and moved along a moving circulation path, and is provided immediately below the position where the draining bucket reverses, receives sludge falling from the draining bucket, and drops the sludge to a sludge reservoir A sludge shooter, an overflow channel provided above the separation tank for overflowing the supernatant of the separation tank, and a supernatant liquid storage tank for storing the supernatant liquid overflowing via the overflow channel. A sewage treatment apparatus comprising a supply pump for sucking a liquid from the supernatant liquid storage tank. 7. The sewage treatment apparatus according to claim 6, wherein the sewage tank has a structure in which at least a bottom part is inclined like a mortar, and sludge in the sewage is concentrated and settled in the center of the bottom part. The submersible pump is installed at the center of the bottom of the sewage tank. 8. The sewage treatment apparatus according to claim 6 or 7, wherein the submersible pump is operated by a float switch only when the liquid level in the sewage tank is within a predetermined range. A sewage treatment device characterized by being configured to. 9. The sewage treatment apparatus according to any one of claims 6 to 8, wherein the supernatant liquid storage tank is partitioned into a plurality of compartments, and each compartment is a communication port at the bottom of a partition wall. The sewage treatment apparatus is characterized in that the pump is provided in a compartment different from the compartment into which the liquid flows from the overflow channel. 10. The sewage treatment apparatus according to claim 9, wherein a compartment into which the liquid flows from the overflow channel in the supernatant liquid storage tank is provided with a surface water intake device for sucking the surface liquid. The sewage treatment apparatus is configured such that the liquid sucked by the apparatus is introduced into the draining tank. 11. The sewage treatment apparatus according to claim 10, wherein the surface water intake device is configured as a unit that sucks out the liquid by an ejector that operates by using the liquid discharged by the submersible pump. Sewage treatment equipment. 12. The sewage treatment apparatus according to claim 10 or 11, wherein the surface water intake device includes a float that raises and lowers an intake port in response to rise and fall of a liquid level. Sewage treatment equipment to be. 13. The sewage treatment apparatus according to any one of claims 9 to 12, wherein the sewage tank is provided in a section into which liquid flows from the overflow channel in the supernatant liquid storage tank. The sewage treatment apparatus is installed at a position displaced from the liquid inflow position from the. 14. The sewage treatment apparatus according to any one of claims 6 to 12, wherein the scraping-out means is attached at a predetermined angle with respect to a horizontal bar provided on a rotary shaft extending in a vertical direction. A plurality of scraping plates to be provided are provided, and the scraping ranges of the scraping plates are shifted, and the scraping plates are gradually moved toward the outside from the center of the bottom of the separation tank by the scraping plates. A sewage treatment apparatus, which is arranged to perform scraping. 15. The sewage treatment apparatus according to any one of claims 3 to 14, wherein the separation tank has a cylindrical sewage input compartment into which sewage is input in a tangential direction at an upper portion thereof, and the sewage input. And a solid-liquid separation part formed of a ring-shaped gap formed by a conical double wall that spreads toward the end and communicates with the inside of the compartment. 16. The sewage treatment apparatus according to claim 15, wherein the sewage input section is provided with an introduction path for introducing a supernatant liquid of the sewage input section into the draining tank. apparatus. 17. A ring-shaped gap formed by a cylindrical sewage input compartment provided in the upper part and into which sewage is input from a tangential direction, and a divergent conical double wall communicating with the sewage input compartment. And a solid-liquid separation section consisting of, by lowering the sewage introduced into the sewage input section while swirling between the conical double walls of the solid-liquid separation section,
A separation tank that rapidly raises the sludge-removed clean liquid while rapidly settling sludge in the wastewater; and a draining tank that communicates with the separation tank through a communication port provided at the bottom of the wall surface, It is equipped with a plurality of scraping plates that are mounted at a predetermined angle with respect to a horizontal bar that is provided at the bottom of the separation tank and that is installed on a vertically extending rotating shaft. Sludge scraping means for scraping the sludge from the center of the bottom of the separation tank to the outside while gradually moving the sludge from the center of the bottom of the separation tank to the draining tank, and the draining tank. Inside the drainage tank, the concentrated sludge accumulated at the bottom of the drainage tank is scooped up and raised, The sludge picked up by turning over at a position protruding upward by a predetermined amount and dropping the sludge, and then descending to circulate along a circulation path that moves to the bottom, and directly below the position at which the draining bucket reverses. A sludge shooter provided for receiving sludge falling from the draining bucket and dropping the sludge into a sludge reservoir, and a sludge shooter provided at an upper portion of the separation tank for overflowing a supernatant liquid of the separation tank. A sewage treatment apparatus, comprising: an overflow channel, and the sewage input section is provided with an introduction path for introducing a supernatant liquid of the sewage input section into the draining tank.