KR101589720B1 - apparatus for washing steel with alkaline electrolytic liquid - Google Patents

Abstract

The present invention relates to an automatic cleaning method and apparatus for regenerating used alkaline electrolytic ionized water while rapidly cleaning steel materials using strongly alkaline electrolytic water.

Description

[0001] The present invention relates to an apparatus for washing steel materials with strong alkaline electrolytic water,

The present invention relates to an apparatus for cleaning steel products such as tools using strong alkaline electrolytic water.

Metals, various types of steels are usually to be cleaned in the process or before their use in end use and protected from corrosion.

Generally, the steel has a thin film which is non-uniformly attached to the surface of the steel so that the upper layer material is easily galvanically corroded. Therefore, the thin film must be removed before it is painted on the steel or metallized with a coating or zinc or the like. The steel may contain contaminants such as rust, oil or grease, dye contaminants, chips or cutting oil, and compounds caused by polishing or buffing, and the like. All of these contaminants should normally be removed. Even stainless steels must remove excess mixed oxides on their surfaces before use.

A typical method of cleaning metal surfaces is acid cleaning (there is an environmental problem due to the disposal of the spent acidic solution, the surfactant is combined with the oil attached to the workpiece, making it difficult to regenerate the oil, Abrasive blasting, wet or dry tumbling, alkaline cleaning, and the like.

Examples of the multistage cleaning method include a burning or solvent removal method of an organic material, a sand or short-blast, and an electrolytic cleaning method for providing a smooth surface.

The multistage process is effective but expensive in terms of energy consumption and process steps and is environmentally undesirable.

In addition, another method of cleaning the metal surface is an electrolytic method. This electrolytic method performs the processing steps for galvanizing and painting the metal surface and the inner surface. Common coating materials include zinc zinc alloys, tin, copper, nickel and chromium. The electrolytic cleaning method usually uses an alkaline cleaning liquid which forms an electrolytic solution and a working material which can be an anode and an anode of the electrolytic cell (or whose polarity can be changed). Such processing methods are generally operated at a current density of the low voltage (typically 3 to 12 Volts) and from 1 to 15 Amps / dm ² ranges. Therefore, the energy consumption is about 0.01 to 0.5 kwh / m ² , which is inefficient.

A metal cleaning method for solving such a problem is a cleaning method using the strong alkaline electrolytic water disclosed in Korean Patent Laid-Open No. 10-2010-0132813 as a cleaning agent.

When electrolysis is performed by adding a small amount of electrolyte (NaCl, KCl) to water, totally different water having an electrochemical function is generated. Acidic water (hypochlorous acid) having strong sterilizing effect is generated on the anode side, Alkaline water (sodium hydroxide, potassium hydroxide) having strong reducing power cleaning effect is produced.

Unlike general water, the strong alkaline (PH 13 or more) electrolytic water is an electrolytic water having an effect of saponification of a fatty acid by decomposing a fat component attached to the surface of the object to be cleaned, Emulsion (emulsification) which separates easily. The electrolytic water has a negative charge equal to that of the contaminants adhering to the object to be cleaned, so that a repulsive force with the object to be cleaned having the same negative charge is generated and the contaminants are desorbed By this repulsive force, reattachment after desorption, desorption action to prevent re-contamination, and rust inhibition effect to prevent the generation of rust due to small amount of dissolved oxygen are performed.

In addition, the strong alkaline electrolytic water is a solution which can be used for several days without deteriorating its capability by using a water separator or the like.

Therefore, the strong alkaline electrolytic water is known as an environmentally friendly detergent which is harmless to the human body, is excellent in cleaning, detergency, detergency and antibacterial power, and contains no surfactant or alcohol at all and can replace the conventional detergent.

When the workpiece of the steel material is cleaned by using the strongly alkaline electrolytic water having such properties, since the general water is not applied to the workpiece, the workpiece can be cleaned while preventing the rust caused by the cleaning, So that the cleaning process is performed.

However, there has not been disclosed an automatic cleaning method and apparatus for regenerating used alkaline electrolytic ionized water while rapidly cleaning a steel material such as a tool by using strongly alkaline electrolytic water.

An object of the present invention is to provide an automatic cleaning method and apparatus for regenerating used alkaline electrolytic ionized water while rapidly cleaning a steel material such as a tool by using strongly alkaline electrolytic water.

The present invention relates to an electrolytic water device connected to a raw water supply line on the way of which a valve is disposed; An electrolytic water storage tank having an upstream end connected to the electrolytic water device and connected to a downstream end of an electrolytic water supply line through which a valve is interposed in the middle to receive and store the strong alkaline electrolytic water made in the electrolytic water device; The electrolytic water is supplied to the electrolytic water storage tank at an upstream end thereof and the electrolytic water is supplied to the downstream end of the primary water seawater distribution line through which the valve is interposed in the middle of the electrolytic water storage tank, A primary washing tank for washing the primary washing tank; The electrolytic water is supplied to the electrolytic water storage tank at a lower level than the electrolytic water storage tank and the electrolytic water is supplied to the downstream end of the secondary water seawater distribution line, A secondary washing tank for secondary washing the steel material; A regeneration unit for regenerating the electrolytic water used in the primary cleaning bath; An electrolytic water jetting nozzle head connected to an upstream end of the regeneration section and connected to a downstream end of a regenerated electrolytic water supply line in which a valve and a pump are interposed in the middle, Washing tank; A dehydrating tank for dehydrating the regenerated electrolytic water adhered to the object to be cleaned by incorporating an air jet nozzle header connected to a compressed air supply line interposed therebetween, the deodorized water being dried; A hot air drying tank in which a hot air spray nozzle head connected to a hot air supply line interposed with a valve is installed at the upper part to evaporate regenerated electrolytic water adhering to the object to be washed to dry the object to be washed; And a spray electrolytic water drain line connected to the spray cleaning bath through which a valve is interposed, a dehydrated electrolytic water drain line connected to the dehydrating bath through a valve in the middle thereof, and an evaporation electrolytic water drain line connected to the hot air drying bath through a valve Electrolytic water supply line connected to the downstream end of the connected converging line and having a downstream end connected to the secondary washing tank and connected to an upstream end of the sprayed electrolytic water supply line having a valve and a pump interposed therebetween, And a spray electrolytic water storage tank disposed at a lower position than the hot air drying tank.

According to the present invention, by using the ultra-strong alkaline electrolytic water of PH13 or more in place of the detergent which requires a long time for rinsing, the present invention can prevent foreign substances such as oil remaining on the surface of corrosion- And the water remaining on the surface of the steel material is dried by using hot air to remove the electrolytic water adhered to the surface of the steel material by compressed air and drying it for about 1 minute 30 seconds The washing process can be performed more than the conventional washing process. Therefore, unlike the detergent washing process for performing washing at a high temperature, the strong alkaline electrolytic water washing and rinsing processes, which are performed at room temperature, The electrolytic water used for cleaning can be regenerated by the regeneration section and the primary washing tank and the secondary washing tank 2 The electrolytic water used for rinsing, the dehydrated electrolytic water, and the electrolytic water evaporated by the hot air are collected in the spray electrolytic water storage tank and returned to the secondary cleaning bath to prevent the electrolytic water from being wasted. And the collected oil can be separated and collected to provide an action effect of recycling the collected oil. In addition, the regenerated electrolytic water is subjected to the first washing and the second washing to eliminate the low-rinsing (rinse) It is possible to provide an action effect that can reduce cost and operation cost.

1 is a conceptual diagram of a cleaning apparatus according to an embodiment of the present invention;

Hereinafter, an apparatus for cleaning a steel material according to an embodiment of the present invention by using strong alkaline electrolytic water will be described in detail with reference to FIG.

1 shows a cleaning apparatus 100 for cleaning a steel material such as a tool by using strong alkaline electrolytic water.

The cleaning apparatus 100 includes an electrolytic water device 10 connected to a raw water supply line L1 in which a valve V1 is intervened; An electrolytic water storage tank (not shown) for receiving and storing the strong alkaline electrolytic water produced by the electrolytic water system 10, the electrolytic water system being connected to a downstream end of the electrolytic water supply line L2, the upstream end of which is connected to the electrolytic water system 10, 20); An upstream end is connected to the electrolytic water storage tank 20 while a downstream end of the primary water seawater distribution line L3 via the valve V3 is connected to the electrolytic water storage tank 20 at a lower level than the electrolytic water storage tank 20, A first washing tank 30 for firstly washing steel materials to be washed by the electrolytic water; The downstream end of the secondary water seawater distribution line L4 via the valve V4 is connected to the electrolytic water storage tank 20 at an upstream end thereof connected to the electrolytic water storage tank 20 at a lower level than the electrolytic water storage tank 20, A secondary washing tank 40 for secondary washing the steel material to be washed by the electrolytic water; A regeneration unit 50 for regenerating the electrolytic water used in the primary cleaning bath 30; An electrolytic water jetting nozzle header 61 connected to an upstream end of the regeneration section 50 and connected to the downstream end of the regeneration electrolytic water supply line L6 in which the valve V6 and the pump P6 are interposed A spray cleaning tank 60 for spraying and cleaning the object to be washed with regenerated electrolytic water to be sprayed; An air jet nozzle header 71 connected to a compressed air supply line L7 in which the valve V7 is interposed is installed at the upper part to dehydrate regenerated electrolytic water adhered to the object to be washed to dry the object to be washed 70); A hot air spray nozzle (81) connected to a hot air supply line (L8) in which a valve (V8) is interposed in the middle is installed in the upper part to evaporate regenerated electrolytic water adhering to the to- 80); And a spray electrolytic water drain line L9-1 in which the valve V9-1 is interposed and connected to the spray cleaning tank 60 and a valve V9-2 is interposed between the spray electrolytic water drain line L9-1 and the dehydrating tank 70 A condensing line L9 having an upstream end connected to the dehydrated electrolytic water drain line L9-2 and the evaporation electrolytic water drain line L9-3 connected to the hot air drying tank 80 with the valve V9-3 interposed therebetween, And is connected to the upstream end of the spray electrolytic water supply line L10 in which the valve V10 and the pump P10 are interposed in the state where the downstream end is connected to the secondary washing tank 40, And a jet electrolytic water storage tank 90 disposed at a position lower than the spray cleaning tank 60, the dehydrating tank 70, and the hot air drying tank 80.

An ultrasonic oscillator and a swinging unit 31 are installed in the primary washing tank 30 and an overflow storage tank 32 for storing electrolytic water flowing in the primary washing tank 30 is connected to the circulation tank.

The overflow reservoir 32 includes a lower reservoir wall 33 having one end fixed to the ceiling of the overflow reservoir 32 and a distal end extending from the bottom of the overflow reservoir 32, And an upper flow path wall portion 34 having a base end fixed to the bottom of the reservoir 32 and having a tip extending toward the water surface of the overflow storage tank 32.

In the state where the upstream end of the primary washing tank 30 is connected to the downstream end of the overflow tank 32, the valve V3-1, the pump P3 and the filter F3 for filtering the foreign substances are interposed And is connected to the downstream end of the primary electrolytic water circulation line L3-1.

The secondary washing tank 40 includes an ultrasonic oscillator 41. The valve V4-1 and the pump P4 are connected to each other while the upstream end is connected to the lower portion of the secondary washing tank 40, And a downstream end of a secondary electrolytic water circulation line (L4-1) in which a filter (F4) for filtering foreign substances is interposed is connected to the upper part of the secondary washing tank (40).

The overflow line 42 is interposed between the secondary washing tank 40 and the primary washing tank 30 so that the electrolytic water swirled in the secondary washing tank 40 is transferred to the primary washing tank 30 .

The regeneration unit 50 is disposed at a lower position than the overflow storage tank 32 while being connected to the downstream end of the primary seawater discharge line L5 having an upstream end connected to the overflow storage tank 32, An entire treatment tank 51 for storing seawater; At the downstream end of the oil filtration line L5-1 in which the valve V5-1, the pump P5-1 and the membrane separator 52 are interposed in the state where the upstream end is connected to the treatment whole tank 51, (P5-2), the pump (P5-2) and the water separator (52) are interposed in the state where the downstream end is connected to the processing liquid tank (51) Upstream of the regeneration liquid supply line L5-3 in which the valve (V5-3) and the pump (P5-3) are intervened while the downstream end is connected to the secondary washing tank (40) A regeneration liquid storage tank 53 connected to the regeneration liquid storage tank 53; In the state where the downstream end is connected to the primary washing tank 30, a lower water number is connected to the upstream end of the oil-water separation liquid supply line L5-4 interposed between the valve V5-4 and the pump P5-4 , A water separation tank (54) connected to a downstream end of the water supply line (L5-5) to which the upstream end is connected to the treatment whole tank (51) and disposed at a lower level than the treatment water tank (51); And in a state in which the upstream end is connected to the upper oil of the water separation tank 54 and connected to the downstream end of the oil discharge line L5-6 in which the valve V5-5 and the pump P5-5 are interposed And an oil collecting tank 55 disposed at a lower level than the oil separator 54.

An upstream end of the drain line L11 in which the valves V11-1 and V11-2 and the drain pump P11 are interposed is connected to the first and second washing tanks 30 and 40 at an intermediate position.

In addition, a drain line in which a valve is interposed is connected to another set other than the first and second washing tanks 30, 40.

The cleaning apparatus 100 configured as described above can be operated as follows.

First, the electrolytic water system 10 is operated to produce strong alkaline electrolytic water and store it in the electrolytic water storage tank 20.

The electrolytic water in the electrolytic water storage tank 20 is supplied to the first and second washing tanks 30 and 40 arranged at a lower level than the electrolytic water storage tank 20 by opening the valves V3 and V4, And then the valves V3 and V4 are closed.

When the ultrasonic oscillator and the oscillating part 31 are operated after putting the steel material to be washed into the electrolytic water of the primary cleaning bath 30, the electrolytic water is swung in all directions by the oscillation of the electrolytic water and by the ultrasonic oscillator Foreign matter such as oil adhered to the steel material is removed by the cavitation phenomenon and the one-piece ultrasonic cleaning that is contained in the electrolytic water of the primary cleaning bath 30 is performed.

The pump P3 is operated in a state where the valve V3-1 is opened and the electrolytic water at the downstream end of the overflow storage tank 32 is circulated through the first electrolytic water circulation line L3-1 When the electrolytic water of the primary washing tank 30 is stored at a predetermined level or higher, the electrolytic water is overflowed into the overflow storage tank 32. When the electrolytic water is overflowed, Only the electrolytic water that has been subjected to the primary filtration treatment because it can not pass through the wall portion 33 and the water level wall portion 34 is allowed to flow into the lower end side of the overflow storage tank 32, The electrolytic water of the electrolytic water 30 is circulated while being filtered, and the foreign material is partially filtered by the filter F3 during the circulation of the electrolytic water.

Since the electrolytic water in the above-mentioned overflow storage tank 32 is contaminated when it is involved in ultrasonic cleaning for a certain period of time, it flows into the treatment whole tank 51 by natural drop in the case of the above-mentioned primary sea water discharge line L5, And electrolytic water in the treatment liquid tank 51 is supplied to the membrane separator 52 as the pumps P5-1 and P5-2 are operated while the valves V5-1 and V5-2 are opened, And the electrolytic water in the regeneration liquid storage tank 53 flows into the treatment liquid tank 51 while backwashing the membrane separator 52.

Since the electrolytic water in the treatment liquid tank 51 contains a large amount of oil by the membrane separator 52, the electrolytic water in the treatment tank 51 flows into the water separator tank 54 by natural dropping, The oil floated on the surface of the electrolytic water and the oil floated on the surface of the electrolytic water flows through the oil discharge line L5-6 by the operation of the pump P5-5 with the valve V5-5 opened, And the electrolytic water of the water separation tank 54 under the oil is returned to the primary washing tank 30 as the pump P5-4 is operated with the valve V5-4 open.

Then, when the first washed steel material is taken out of the first washing tank 30 and put in the electrolytic water of the second washing tank 40, when the ultrasonic oscillator 41 is operated, the cavitation phenomenon by the ultrasonic oscillator So that foreign matter such as oil adhered to the steel material subjected to the primary washing is removed and the secondary ultrasonic rinse which is contained in the electrolytic water of the secondary washing tank 40 is performed.

In the secondary ultrasonic rinsing step, the pump P4 is operated in a state where the valve V4-1 is open and the electrolytic water in the lower part of the secondary washing tank 40 is discharged through the secondary electrolytic water circulation line L4-1 to 2 The foreign matter is partially filtered by the filter F4 during the circulation of the electrolytic water and the pump P5-3 is operated in a state where the valve V5-3 is opened, The electrolytic water in the regeneration liquid storage tank 53 is supplied to the secondary washing tank 40 via the liquid supply line L5-3.

When the electrolytic water in the regeneration liquid storage tank 53 continuously flows into the secondary washing tank 40 and the water level of the electrolytic water in the secondary washing tank 40 becomes high, The electrolytic water is transferred to the primary washing tank 30. [

Then, the rinsed steel material is taken out of the secondary washing tank 40 and loaded into the spray cleaning tank 60. Then, the pump P6 is operated in a state in which the valve V6 is opened to supply the regeneration electrolytic water supply The electrolytic water in the regeneration liquid storage tank 53 is injected through the electrolytic water spray nozzle head 61 to the loaded steel stream via the line L6 to perform the third spray shower rinse.

The rinsed steel material is then taken out of the spray cleaning tank 60 and loaded in the dewatering tank 70. The valve V7 is then opened to allow the compressed air to flow through the compressed air supply line L7, The water is injected into the steel material loaded in the dewatering tank 70 through the nozzle header 71 and the electrolytic water attached to the steel material is jetted out by the high-pressure air.

Then, the dehydrated steel product is taken out of the dehydrating tank 70 and loaded in the hot air drying tank 80. Then, the valve V8 is opened to supply hot air through the hot air supply line L8, And is adhered to the steel material loaded in the hot air drying tank 80 through the header 81 to perform the fifth hot air drying in which the fine moisture attached to the steel material is dried by the hot hot air.

The valves V9-1, V9-2 and V9-3 are opened in the spray shower rinsing step, the dewatering step and the hot-air drying step to open the spray cleaning tank 60, The electrolytic water in the tank 70 and the hot air drying tank 80 is stored in the sprayed electrolytic water storage tank 90 and the pump P10 is activated in a state in which the valve V10 is opened to discharge the sprayed electrolytic water supply line L10, The electrolytic water of the sprayed electrolytic water storage tank 90 is supplied to the secondary washing tank 40 via the electrolytic water supply pipe 40.

The apparatus configured as described above is capable of removing foreign matter such as oil remaining on the surface of the corrosion-resistant steel material by ultrasonic cleaning in electrolytic water and electrolytic water spraying by using super strong alkaline electrolytic water of pH 13 or more instead of detergent which requires a long time for rinsing , And the electrolytic water adhered to the surface of the steel material is dehydrated by using compressed air and the water remaining on the surface of the steel material is dried by hot air to clean and fix it in about 1 minute and 30 seconds The cleaning time can be reduced as compared with the conventional method. In contrast to the detergent cleaning process which performs cleaning at a high temperature, energy waste required for cleaning is reduced by cleaning with strong alkaline electrolytic water and rinsing at a room temperature Further, the electrolytic water used for cleaning is regenerated by the regeneration unit 50, and the electrolytic water used in the first washing tank and the second washing tank is regenerated. The electrolytic water used for rinsing, the dehydrated electrolytic water, and the electrolytic water evaporated by the hot air are collected in the sprayed electrolytic water storage tank 90 and returned to the secondary cleaning bath 40 to prevent the electrolytic water from being wasted, The oil contained in the electrolytic water can be separated and collected to provide the effect of recycling the collected oil. In addition, the regenerated electrolytic water is subjected to the first washing and the second washing to eliminate the low-rinsing process, It is possible to provide an operation effect that can reduce the manufacturing cost and operation cost of the apparatus.

In addition, an unexpected effect in which rust does not occur even when the corrosion-resistant steel material washed by the apparatus and method configured as described above is allowed to stand for one month or more can be provided.

10; Electrolytic water system, 20; Electrolytic water storage tank, 30; Primary washing tank, 40; Secondary washing tank, 50; Reproducing unit, 60; Spray cleaning tank, 70; Dehydrating bath, 80; Hot air drying tank, 90; Sprayed electrolytic water storage tank

Claims (3)

delete An electrolytic water device 10 connected to a raw water supply line L1 in which a valve V1 is interposed;
An electrolytic water storage tank (not shown) for receiving and storing the strong alkaline electrolytic water produced by the electrolytic water system 10, the electrolytic water system being connected to a downstream end of the electrolytic water supply line L2, the upstream end of which is connected to the electrolytic water system 10, 20);
An upstream end is connected to the electrolytic water storage tank 20 while a downstream end of the primary water seawater distribution line L3 via the valve V3 is connected to the electrolytic water storage tank 20 at a lower level than the electrolytic water storage tank 20, A first washing tank 30 for firstly washing steel materials to be washed by the electrolytic water;
The downstream end of the secondary water seawater distribution line L4 via the valve V4 is connected to the electrolytic water storage tank 20 at an upstream end thereof connected to the electrolytic water storage tank 20 at a lower level than the electrolytic water storage tank 20, A secondary washing tank 40 for secondary washing the steel material to be washed by the electrolytic water;
A regeneration unit 50 for regenerating the electrolytic water used in the primary cleaning bath 30;
An electrolytic water jetting nozzle header 61 connected to an upstream end of the regeneration section 50 and connected to the downstream end of the regeneration electrolytic water supply line L6 in which the valve V6 and the pump P6 are interposed A spray cleaning tank 60 for spraying and cleaning the object to be washed with regenerated electrolytic water to be sprayed;
An air jet nozzle header 71 connected to a compressed air supply line L7 in which the valve V7 is interposed is installed at the upper part to dehydrate regenerated electrolytic water adhered to the object to be washed to dry the object to be washed 70);
A hot air spray nozzle (81) connected to a hot air supply line (L8) in which a valve (V8) is interposed in the middle is installed in the upper part to evaporate regenerated electrolytic water adhering to the to- 80); And
The spray electrolytic water drain line L9-1 in which the valve V9-1 is interposed in the middle and connected to the spray cleaning tank 60 and the valve V9-2 in the middle is connected to the dehydrating tank 70, The electrolytic water drain line L9-2 and the valve V9-3 are interposed and the evaporating electrolytic water drain line L9-3 connected to the hot air drying tank 80 is connected to an upstream end of the converging line L9 Is connected to the upstream end of the spray electrolytic water supply line (L10) connected to the downstream end and having the downstream end connected to the secondary washing tank (40) and the valve (V10) and the pump (P10) interposed therebetween, And a spray electrolytic water storage tank 90 disposed at a lower position than the spray washing tank 60, the dehydrating tank 70, and the hot air drying tank 80,
The first washing tank 30 has an ultrasonic oscillator and a swinging unit 31. The first washing tank 30 has an overflow storage tank 32 for storing electrolytic water overflowed,
The overflow reservoir 32 includes a lower reservoir wall 33 having one end fixed to the ceiling of the overflow reservoir 32 and a distal end extending from the bottom of the overflow reservoir 32, And an upper flow path wall portion 34 having a base end fixed to the bottom of the reservoir 32 and having a tip extending toward the water surface of the overflow storage tank 32,
The primary washing tank 30 is provided with a valve V3-1, a pump P3 and a filter F3 for filtering a foreign substance while the upstream end is connected to the downstream end of the overflow tank 32 Is connected to the downstream end of the cold electrolytic water circulation line (L3-1)
The secondary washing tank 40 includes an ultrasonic oscillator 41. The valve V4-1 and the pump P4 are connected to each other while the upstream end is connected to the lower portion of the secondary washing tank 40, And a downstream end of a secondary electrolytic water circulation line (L4-1) in which a filter (F4) for filtering foreign matter is interposed are connected to the upper part of the secondary washing tank (40)
Characterized in that an overflow line (42) is interposed between the secondary washing tank (40) and the primary washing tank (30), thereby cleaning the steel material with strong alkaline electrolytic water. 3. The method of claim 2,
The reproducing unit (50)
And is connected to a downstream end of a first primary seawater discharge line L5 connected to an upstream end of the overflow storage tank 32 and is disposed at a position lower than the overflow storage tank 32 to store first order seawater, 51);
At the downstream end of the oil filtration line L5-1 in which the valve V5-1, the pump P5-1 and the membrane separator 52 are interposed in the state where the upstream end is connected to the treatment whole tank 51, (P5-2), the pump (P5-2) and the water separator (52) are interposed in the state where the downstream end is connected to the processing liquid tank (51) Upstream of the regeneration liquid supply line L5-3 in which the valve (V5-3) and the pump (P5-3) are intervened while the downstream end is connected to the secondary washing tank (40) A regeneration liquid storage tank 53 connected to the regeneration liquid storage tank 53;
In the state where the downstream end is connected to the primary washing tank 30, a lower water number is connected to the upstream end of the oil-water separation liquid supply line L5-4 interposed between the valve V5-4 and the pump P5-4 , A water separation tank (54) connected to a downstream end of the water supply line (L5-5) to which the upstream end is connected to the treatment whole tank (51) and disposed at a lower level than the treatment water tank (51); And
In a state in which the upstream end is connected to the upper oil of the water separation tank 54 and the valve V5-5 and the pump P5-5 are connected to the downstream end of the oil discharge line L5-6, And an oil collecting tank (55) disposed at a lower height than the oil separator (54).

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