Patent Grant
6893556
The present invention relates to technique for pretreatment such as degreasing or chemical treatment to surfaces of work or metallic surfaces soiled with rust preventing oil, oil used for press forming, cutting oil, or machining oil.
Zink phosphating is widely used for metallic material such as steel or galvanized metal in order to improve the rust preventive characteristic and the paint adhesion. In general, the process of zinc phosphating includes a sequence of degreasing, rinsing, surface conditioning, chemical treatment (or zinc phosphating), rinsing, and drying. Degreasing operation, rinsing operation and surface conditioning operation may be performed a plurality of times, according to the need.
For a zinc phosphate chemical conversion coating to achieve, as a substrate layer for painting, sufficient effects of rust prevention and paint adhesion, it is desirable to obtain a uniform, fine crystalline coating having a coating weight in the range of 2˜5 g/m2. To obtain such a coating layer, one process employs a degreasing operation, and a surface condition operation with a titan colloid type treatment liquid.
However, in general, the process of zinc phosphating involves the following problems.
First, the entire process line is long, and the facilities are large and complicated. Accordingly, the entire system requires a large space to the disadvantage of cost, and requires a long time to the disadvantage of productivity.
Second, the number of items to be controlled is large. For example, the parameters to be controlled include; the alkalinity (total alkalinity, alkalinity of free alkali) of degreasing in the case of alkali degreasing, and the concentration (total alkali, the concentration of titanium) of surface conditioning liquid in the case of titanium colloid type surface conditioning. The complicated solution control and other control including many items to be monitored and controlled imposes a considerable burden on the operation and causes an increase in the manufacturing cost by consumption of chemicals at each step. The solution for degreasing is used up by being applied to a work and transferred to the next rinse step with the work, or at the time of periodical renewal of the solution. The liquid for surface conditioning is used up by being applied to work and at the time of renewal. Moreover, the liquid may be used up by continuous partial renewal (auto drain) when the liquid is renewed partially since the durability of the liquid is low.
Third, the amount of drainage of water for rinsing is increased. After each step of degreasing, a step of water rinsing is required to prevent the liquid for degreasing from being mixed into the surface conditioning liquid or the treatment liquid of zinc phosphating. Moreover, after a step of phosphating treatment, a step of water rinsing is required since the treatment liquid remaining on surfaces could cause troubles to surface conditioning and rust prevention. The large amount of rinsing liquid drained at the rinsing steps after the degreasing and chemical treatment steps is burdensome to the waste water treatment.
It is an object of the present invention to provide pretreatment apparatus for painting or coating which can shorten the process.
According to the present invention, a pretreatment apparatus for performing pretreatment before a painting process, comprises: a liquid container section including a treatment section which includes a treatment tank to be filled with a treatment liquid for degreasing and chemical conversion; a circuit section to form a circulation path for circulating the treatment liquid from the treatment tank to the liquid container section; and a purifying section to remove an unwanted constituent from the treatment liquid circulated to the container section through the circulation path.
According to another aspect of the present invention, a pretreatment apparatus comprises: a liquid container section including a treatment section which includes a treatment tank to be filled with a treatment liquid for degreasing and chemical conversion; a settling tank to receive the treatment liquid from the treatment tank; and a purifying apparatus to separate an unwanted constituent from the treatment liquid in settling tank. According to still another aspect of the present invention, a pretreatment apparatus comprises: a liquid container section including a treatment section which includes a treatment tank to be filled with a treatment liquid for degreasing and chemical conversion; and a spray zone, disposed at a stage prior to a stage of the treatment tank, and arranged to spray a spray liquid for degreasing and chemical conversion to a work to be painted.
The other objects and features of this invention will become understood from the following description with reference to the accompanying drawings.
The treatment solution is used for carrying out three kinds of treatment, i.e. degreasing, surface conditioning and chemical conversion treatment, at a single step. For example, the treatment solution contains at least a polar organic solvent, water and an ion content. The polar organic solvent may be of the type selected from alcohols, glycol ethers and diethylene glycol ethers. In this example, the polar organic solvent comprises at least one of alcohols, glycol ethers and diethylene glycol ethers. The ion content may contain zinc ions, phosphoric acid ions, manganese ions, nickel ions and/or sodium ions. By using the treatment liquid of such a type, the apparatus according to this embodiment can carry out all of degreasing, surface conditioning and chemical treatment at a single step. Therefore, this embodiment can greatly reduce time for treatment, simplify the facilities for treatment, reduce the space required for treatment, improve the productivity, reduce the cost for the required chemicals, and simplify the control of the chemicals.
Treatment tank 1 is provided with a circulating line 11 (or treatment-side circulation path) for drawing out the treatment solution from the tank 1 by a pump 14 and returning the treatment solution to treatment tank 1, as shown in FIG. 1. In circulating line 11, there are provided a dust removing apparatus (or section) 2, a chemical sludge removing apparatus (or section) 3 and an oil removing apparatus (or section) 4 which are situated one upstream of another. A line segment 11a forms a part of the circulation line 11 by extending from pump 14 to dust removing section 2.
Dust removing apparatus 2 removes foreign matter, such as iron dust or iron powder, from the treatment solution in treatment tank 1 and the rinsing liquid in rinse tank 8. The solution from which foreign matter has been removed is conveyed to chemical sludge removing apparatus 3, while the foreign matter which has been removed is disposed of properly. More specifically, the apparatus 2 may be composed of a settling tank, or a centrifugal separator or a magnetic separator, as will hereinafter be described in detail.
A settling tank 21 is shown in
A centrifugal separator 22 is shown in
A magnetic separator 23 is shown in
Dust removing apparatus 21, 22 and 23 may be employed singly or in combination. A combination of settling tank 21 and magnetic separator 23 is preferable for its highly effective removal of foreign matter.
The dust removing apparatus is, however, not limited to these three forms as described above, or any combination thereof, but may be of any other type or construction. Although it has been described as being situated in the circulating line 11, the dust removing apparatus 2 may alternatively be situated inside treatment tank 1 or on the outside of tank 1, away from the circulating line 11.
Chemical sludge removing apparatus 3 removes a chemical sludge from the solution arriving from dust removing apparatus 2. The solution from which a chemical sludge has been removed is conveyed to oil removing apparatus 4, while the sludge is disposed of properly. The apparatus 3 may include any filter that can maintain a sludge concentration within 150 ppm in the solution in the treatment tank 1 as shown in
Oil removing apparatus 4 removes oil from the solution arriving from chemical sludge removing apparatus 3. The solution from which oil has been removed is conveyed through a line segment 11b, to a solution storage tank or supply tank 6, as well as a water-polar organic solvent separator or separating section 5.
Oil removing apparatus 4 may be of a heating type oil removing apparatus, a coalescer type oil removing apparatus, or an ultrafiltration type oil removing apparatus. The heating type apparatus is suitable for application to an aqueous solution containing a nonionic surface active agent as a degreasing substance, since a nonionic surface active agent becomes insoluble in water when heated to a temperature equal to or higher than a predetermined temperature, so that the solution may be separated into an oil phase composed of the nonionic surface active agent and a water phase.
The coalescer type oil removing apparatus collects oil drops having a size of several microns (μm) from an aqueous solution by passing them through a filter to destroy a water-oil emulsion and thereby to cause the oil drops to grow large, so that floats are collected.
The ultrafiltration type oil removing apparatus employs a filter for ultrafiltration, having a mesh size of about 0.001 to 0.01 micron (0.01˜0.001 μm) for filtration at a low pressure in the order of about 5×10−5 to 0.5 Pa (0.5˜5×10−5 Pa) or under suction to separate colloidal particles from the solvent.
These types of oil removing apparatus 4 may be employed singly or in combination, depending on the degree of oil and water separation as required.
Solution storage tank or supply tank 6, water-polar organic solvent separator 5 and ion removing apparatus 7 are situated downstream of oil removing apparatus 4 in the circulating line 11, as shown in FIG. 1.
Solution storage tank 6 temporarily stores the treatment solution purified by the removal section of dust, chemical sludge and oil removing apparatus 2, 3 and 4. The treatment solution is conveyed to solution storage tank 6 by a line segment 11c. Solution storage tank 6 is connected with line segment 11c for supplying the treatment liquid from oil removing apparatus 4 to solution storage tank 6, a line segment 111a for conveying a polar organic solvent from the water-polar organic solvent separator 5 to solution storage tank 6, and a line segment 121a for conveying water from ion removing apparatus 7, as will hereinafter be described. Solution storage tank 6 returns the solution to treatment tank 1 with a fresh solution supplied from a solution reservoir 15 through a pump 16.
Water-solvent separator 5 separates the solution received from oil removing apparatus 4, into a water content and a polar organic solvent content, and delivers the water content to ion removing apparatus 7 through a line segment 12a, and the polar organic solvent content to solution storage tank 6 through a line segment 11a.
Water-solvent separator 5 is preferably arranged to carry out an efficient and inexpensive separation of water from a polar organic solvent of the type selected from alcohols, glycol ethers or diethylene glycol ethers as stated before. One example is a separating method called pervaporation, employing a separating membrane having selective permeability, i.e. showing a markedly different rate of diffusion from one kind of substance to another. Referring to
Specific examples of such membrane 51 are: a composite membrane formed by placing a PVA film crosslinked with maleic acid on a supporting film (shown in Japanese Published Patent Application Publication No. S59(1984)-109204); a membrane formed from a mixture containing 80% of carboxymethyl cellulose and 20% of polyacrylate, and treated with a K salt [J. Memb. Sci., 32, 207 (1987)], a composite membrane formed by placing a crosslinked PVA film on a supporting film of PNA [J. Memb. Sci., 36, 463 (1988)], a membrane formed from hollow yarns of a chitosan derivative [Annual Meeting of The Japan Chemical Society (1989)], a cobalt alginate membrane (Japanese Published Patent Application Publication No. S61(1986)-404), a membrane of a sulfate of chitosan [The International Membrane Society (1987)], and a composite membrane of a polyion complex of polyacrylic acid and ionene type polycation as formed by hydrolyzing the surface of a base film of PNA (Japanese Published Patent Application Publication No. H01(1989)-224003).
Ion removing apparatus 7 removes ions from the water delivered from water-solvent separator 5. The ions are disposed of properly and the remaining water is supplied to the solution storage tank 6 by a line segment 121a and the rinse tank 8 by a line segment 12b. Ion removing apparatus 7 need not be special apparatus, but may be of the type shown in FIG. 6. Ion removing apparatus 7 shown in
The thus-constructed pretreatment apparatus according to one embodiment of the present invention as described above includes a plurality of circulating lines or circuits, as shown in FIG. 1 and as stated below.
First circulation line 11 (or treatment-side circulation path) is a circuit for circulating the treatment solution through treatment tank 1, dust removing apparatus 2, chemical sludge removing apparatus 3, oil removing apparatus 4, and solution storage tank 6, and returning it to the tank 1, as described before.
A second circulating line 12 (or rinse-side circulation path) is a circuit for circulating the treatment solution through treatment tank 1, dust removing apparatus 2, chemical sludge removing apparatus 3, oil removing apparatus 4, water-solvent separator 5, ion removing apparatus 7, and rinse tank 8.
A third circulating line 13 (or rinse return path) is a circuit for conveying the liquid from rinse tank 8 to dust removing apparatus 2 through a pipeline 17 and a pump 18, and circulating the liquid through dust, chemical sludge and oil removing apparatus 2, 3 and 4.
Five more circulating lines are provided as shown in
A fifth circulating line 121 (or water circuit path) is a circuit defined by adding solution storage tank 6 to the closed circuit defined by the second circulating line 12, so that part of pure water or deionized water obtained by removing ions in the ion removing apparatus 7 is delivered to tank 6.
A sixth circulating line 131 is a circuit defined by adding water-solvent separator 5 to the closed circuit defined by the third circulating line 13, so that the polar organic solvent leaving the separator 5 may be delivered to the solution storage tank 6.
A seventh circulating line 132 is a circuit defined by adding ion removing apparatus 7 in the closed circuit defined by the sixth circulating line 131, so that ions may be removed from water separated by the water-solvent separator 5 and the resulting water may be delivered to the rinse tank 8.
An eighth circulating line 133 is a circuit defined by adding ion removing apparatus 7 to the closed circuit defined by sixth circulating line 131, so that ions may be removed from water separated by the water-solvent separator 5 and the resulting water may be delivered to the solution storage tank 6.
Owing to its first to third circulating lines as its main circulating lines, or a total of eight circulating lines, the apparatus according to the embodiment of this invention can stabilize the composition of the treatment solution in treatment tank 1, and thereby form an excellent chemical conversion coating of uniform quality even in a continuous operation.
With third circulating line 13, this embodiment makes it possible to maintain the electric conductivity of water in rinse tank 8 at a level equal to or lower than 20 μS/cm and thereby prevent any foreign matter, such as oil, solution or iron dust, from adhering to the surface of any treated product and being carried forward to any later work station.
In this example, a circuit section to form a circulation path includes items 11a, 11b, 11c, 12a, 12b, 14, 17, 18, 111a and 121a, and a purifying section to remove an unwanted constituent from the treatment liquid includes items 2, 3, 4, 5 and 7.
The pretreatment apparatus according to the second embodiment employs a vacuum distillation apparatus 20 in place of dust, sludge and oil removing apparatus 2 to 4, water-solvent separator 5 and ion removing apparatus 7 shown in FIG. 1.
The treatment solution of treatment tank 1 and the rinsing liquid of rinse tank 8 are sucked, respectively, by pumps 14 and 18, and supplied, respectively, to vacuum distillation apparatus 20, which separates the polar organic solvent and water from each other and from other substances. The solvent and a part of water as separated are delivered to solution storage tank or supply tank 6, and the remaining water to rinse tank 8.
The other substances include solid matter, such as iron dust, chemical sludge and oil, and are discharged from vacuum distillation apparatus 20 and disposed of properly.
The first vacuum distillation apparatus 201 separates only the polar organic solvent from the solution and delivers the solvent to solution storage tank 6 shown in FIG. 7. The second vacuum distillation apparatus 202 separates only water from the solution arriving from first apparatus 201 and delivers the water content to solution storage tank 6 and rinse tank 8. The dust, sludge and oil as separated in vacuum distillation apparatus 202 are disposed of properly.
The lowering of the boiling point by the reduction of the pressure makes it possible to reduce the required amount of heat energy supplied to each heater 205 as compared to the distillation at a normal pressure. Specifically, it is desirable to employ waste heat from a paint drying furnace or oven as a source of heat energy for the heaters 205.
The pretreatment apparatus of the second embodiment can recover and regenerate the liquids for treatment tank 1 and rinse tank 8 only with vacuum distillation apparatus 20, so that the system is simplified and the cost is reduced, as compared with the first embodiment.
The embodiments explained above are described not for limiting the invention but the purpose of the help to understand the invention. Accordingly, each element disclosed in the embodiments described above is to be understood that it includes any alternation of the design belonging to the invention and equivalents thereof.
The invention will now be described in further detail by way of a few specific examples to confirm the effects.
A treatment solution for degreasing and zinc phosphate treatment was prepared by mixing 500 g of water, 500 g of diethyleneglycol monoethyl ether, 100 g of sodium nitrate, 4.3 g of orthophosphoric acid, 15.9 g of zinc nitrate, 6.2 g of nickel nitrate, 4.1 g of manganese nitrate and 6.2 g of lithium nitrate.
Dust removing apparatus 2 which was employed was a combination of a settling tank and a magnetic separator (made by Brin Co., Ltd.). The chemical sludge removing apparatus 3 was a total filter (made by Nitto Denko Co., Ltd.) having a filtering capacity to maintain a sludge concentration not exceeding 150 ppm in the treatment tank 1. The oil removing apparatus 4 was Pearlcomb oil removing apparatus (made by Central Filter Manufacturing Co., Ltd.) having a combination of coalescent and ultrafiltration type apparatus.
Water-solvent separator 5 was of the type having a separating membrane of a chitosan derivative (product of LIGNYTE Co., Ltd.), and was operated by employing a temperature of 50 deg. C. and a pressure of 0.01 mHg on its permeation or low pressure side. Ion removing apparatus 7 was of the type employing a chelate type cation exchange resin (DIAION CR10 of Mitsubishi Chemical Corportaion), a styrenic strongly basic anion exchange resin (DIAION SA20A of Mitsubishi Chemical Corporation) and a styrenic strong acidic cation exchange resin (DIAION SK1B of Mitsubishi Chemical Corporation).
A mixture containing three kinds of rustproofing oil, Rust Clean K (product of Cosmo Oil Co., Ltd.), Idemitsu NR3 (product of Idemitsu Kosan Co., Ltd.) and NonRust PN-1 (product of Nisseki Mitsubishi Co., Ltd.), in equal proportions was employed to form an oil coating having any of three amounts (a weight of 0.5 g/m2, 1 g/m2, 2 g/m2) on each of 2000 SPCC-SD steel sheets having a width of 70 mm, a length of 150 mm and a thickness of 0.8 mm, and each sheet was subjected to treatment by employing the solution and apparatus as described above. The examples were designated as Examples 1 to 3 respectively to the weight of the oil coating. The results are shown in Table 1 placed at the end of “Detailed Description of the Invention”.
As Comparative Example 1, a test was conducted by employing the above-described rustproofing oil to form an oil coating having a weight of 0.5 g/m2 on each sheet and then subjecting them to treatment in a beaker filled with the above-described solution. The results are shown in Table 1.
As Comparative Example 2, a test was conducted by dipping each sheet in acetone after coating it with the oil mixture, and wiping it with a piece of cloth or gauze for degreasing, and then subjecting them to treatment in a beaker filled with the above-described solution. The results are shown in Table 1.
The results shown in Table 1 were obtained by examining the appearance of a zinc phosphate film on each of 2000 sheets in a SEM photograph of 1000 magnifications. In Table 1, each double circle indicates very good results, each circle indicates good results, each triangle indicates poor results, and each x indicates bad results.
As is obvious from Table 1, the apparatus according to each of the preceding embodiments was found capable of maintaining high quality of zinc phosphate treatment even for a large number of oil-coated steel sheets, while acetone wiping according to Comparative Example 2 was equally effective. It was also confirmed that these embodiments made it possible to carry out any such treatment in a closed circuit.
An ultrasonic vibrating machine 51 is provided to apply ultrasonic vibration to settling tank 50. After the treatment liquid is conveyed from treatment tank 1 to settling tank 50, ultrasonic vibrating machine 51 is driven, and settling tank 50 undergoes ultrasonic vibration. By this vibration, the oil content in the treatment liquid moves upward and floats on the liquid surface, whereas the chemical sludge moves downward and settles down to the bottom of the tank 50. Thus, ultrasonic vibrating machine 51 can promote separation of oil, chemical sludge and dust particles in the treatment liquid. Therefore, settling tank 50 can remove these unwanted substances during a downtime of one or two days.
Settling tank 50 of this example is further provided with an oil removing apparatus 52 for sucking oil floating on the liquid surface and removing the oil. Piping 53 is arranged to suck the treatment liquid at the level near the liquid surface in settling tank 50 and to return the treatment liquid to settling tank 50 through oil removing apparatus 52. A pump 54 for sucking the treatment liquid is disposed in the piping 53. As oil removing apparatus 52, it is possible to employ any one or more of the above-mentioned heating oil removing apparatus, coalescer oil removing apparatus, and ultrafiltration oil removing apparatus.
A hopper 50a is formed at the bottom of settling tank 50, for collecting and sucking the chemical sludge sinking toward the bottom. A pump 57 sucks the treatment liquid replete with chemical sludge through piping 56, and delivers the liquid to a sludge removing apparatus 55 for removal of the chemical sludge. As sludge removing apparatus 55 like sludge removing apparatus 3, it is possible to employ any filter as long as it can maintain the sludge concentration within 150 ppm in the treatment liquid without contaminating the treatment liquid. After removal of the chemical sludge, the treatment liquid is returned to settling tank 50 through piping 56. Dust having greater specific gravity such as iron powder settles down to the bottom of settling tank 50, and hence the chemical sludge removing apparatus 55 removes heavy dust together with chemical sludge.
The addition of settling tank 50 as in the third and fourth embodiments is effective for removing oil, chemical sludge, and dust or dust particles such as iron particles, and maintaining the treatment liquid clean while the production line is not operating. The third and fourth embodiments can improve the performance of the degreasing and chemical conversion treatment, and hence improve the quality of work to be painted. The addition of settling tank 50 functions to lighten the load on the dust removing section 2, sludge removing section 3 and oil removing section 4 used while the production line is operating.
As shown in
A degreased content tank 421 temporarily stores the polar organic solvent separated by vacuum distillation apparatus 420. A first spray zone 424 sprays this polar organic solvent to a vehicle body 9 at a stage prior to the stage of treatment tank 1.
A water recovery tank 422 temporarily stores the water separated by vacuum distillation apparatus 420. A second spray zone 425 sprays this water to vehicle body 9 at a stage following the stage of treatment tank 1. Oil and sludge remaining after the separation of the polar organic solvent and water are collected in an oil recovery tank 423.
Thus, the polar organic solvent, water and remaining component of the treatment liquid are separated, and conveyed by the following three different flows. The flow of the polar organic solvent is: treatment tank 1→vacuum distillation apparatus 420→degreased component tank 421→first spray zone 424. The flow of water is: treatment tank 1→vacuum distillation apparatus 420→water recovery tank 422→second spray zone 425 (or rinse tank 8 or to treatment liquid supply tank 6). The flow of the remaining component including oil component is: treatment tank 1→vacuum distillation apparatus 420→oil recovery tank 423.
Vacuum distillation apparatus 420 of this example is identical in construction to vacuum distillation apparatus 20 shown in FIG. 8. In the pretreatment apparatus of
The lowering of the boiling point by the reduction of the pressure makes it possible to reduce the required amount of heat energy supplied to each heater 205 as compared to the distillation at a normal pressure. Specifically, it is desirable to employ waste heat from a paint drying furnace or oven as a source of heat energy for the heaters 205.
At first spray zone 424, the degreased component containing polar organic solvent is sprayed by shower nozzles to vehicle body 9 to be dipped in treatment tank 1 at the next stage. The degreased component is applied to the inside and outside of vehicle body 9, to remove oil from the surfaces. First spray zone 424 for spraying polar organic solvent to work before the operation of treatment tank 1 is effective to promote the degreasing operation and thereby to prevent failure in chemical conversion coating.
At second spray zone 425, water is sprayed by shower nozzles to vehicle body 9 taken out from treatment tank 1. Water reaches the inside and outside of the vehicle body 9, and washes out the treatment liquid from the surfaces. Second spray zone 425 for spraying water to vehicle body 9 after the pretreatment at treatment tank 1 is effective to clean off the treatment liquid before the next dipping step at rinse tank 8, and thereby to prevent the treatment liquid from entering rinse tank 8.
Oil separated and recovered can be subjected to fractional distillation to separate components of different boiling points, which can be used as fuel or rust preventing agent. Vacuum distillation apparatus 420 is advantageous in simplifying the system and reducing the cost.
Spray zone 850 of the example shown in
The treatment liquid sprayed at high pressure zone 850a tends to contain a large amount of oil and dust particles. Therefore, the floor of high pressure spray zone 850a has sloping surfaces meeting at a deepest center to collect the treatment liquid sprayed to vehicle body 9, and convey the treatment liquid to the before-mentioned dust removing section 2. Low pressure spray zone 850b may be arranged to collect the treatment liquid and convey the treatment liquid to dust removing section 2 in the same manner, or may be arranged to return the treatment liquid used in low pressure spray zone 850b directly to treatment tank 1 because the content of oil and dust in the treatment liquid used in low pressure zone is relatively low.
In the example of
In this example, the preceding high pressure spray zone 850a mainly functions to remove oil from outside panels of vehicle body 9, and the next low pressure spray zone 850b mainly performs surface conditioning and chemical treatment. Accordingly, the discharge pressure of the nozzles 853 in high pressure spray zone 850a is at a high level of about 3.92 MPa, whereas the discharge pressure of the nozzles 853 in low pressure spray zone 850b is in a low pressure range of 294 kPa˜490 kPa. The high pressure spray of the treatment liquid in high pressure spray zone 850a is effective to wash away oil and dust from the outside panels of vehicle body, and the low pressure spray in low pressure spray zone 850b is effective to condition the surfaces of vehicle body 9 properly and to form chemical conversion coating.
In this way, spray zone 850 performs the degreasing and chemical treatment before the dipping operation in treatment tank 1. Therefore, in treatment tank 1, the degreasing and chemical conversion proceed in remaining outside panels and inside panels of vehicle body 9. Spray zone 850 improves the performance of degreasing and chemical conversion in treatment tank 1. Each of high pressure spray zone 850a and low pressure spray zone 850b can be achieved only in a space of a length corresponding to the length of a single vehicle body. The addition of spray zone 850 does not increase the length of the entire pretreatment process so much. A pipe or conduit member 859 shown in
In the seventh and eighth embodiments, the spray zone 850 may be arranged to include only one spray zone of a single discharge pressure, instead of including high pressure and low pressure spray zones of two different discharge pressures. In the seventh and eighth embodiment, the treatment liquid collected in spray zone 850 is led to the before-mentioned first circulation path 11. However, it is optional to provide an additional circulation path for spray zone 850 and to provide, in this additional circulation path, an impurity removing section including a dust removing section similar to section 2, a chemical sludge removing section similar to section 3 and an oil removing section similar to section 4.
In the illustrated embodiments of the present invention, first (or treatment-side) circulation path 11 functions to circulate the treatment liquid in a closed circuit, and by so doing, contributes to reduction in material cost. By the use of treatment liquid or solution combining the function of degreasing and the function of chemical conversion, the pretreatment apparatus can achieve the degreasing operation and chemical treatment simultaneously at one step. Therefore, the pretreatment apparatus can reduce the space required for the equipment, reduce the cost of equipment and improve the productivity by shortening the time for the pretreatment. Moreover, the use of this multifunction treatment liquid makes it possible to reduce the manhour for control and management of conditions of the pretreatment. Furthermore, it is possible to simplify the water rinsing step, to reduce the required amount of rinsing liquid and to reduce the burden on the waste water treatment. Dust removing apparatus 2 may be provided in first circulation path 11 or may be outside first circulation path, for example, inside or outside treatment tank 1. Oil removing apparatus may be placed outside circulation path. It is possible to arrange the dust removing apparatus 2, sludge removing apparatus 3 and oil removing apparatus 4 in various orders other than the order shown in FIG. 1.
Second (rinse-side) circulation path 12 functions to circulate the treatment liquid in a closed circuit, and by so doing, contributes to reduction in material cost, and reduction in burden on the waste water treatment. Third circulation path 13 functions to circulate the rinsing liquid in a closed circuit, and by so doing, contributes to reduction in material cost, and reduction in burden on the waste water treatment.
Treatment tank 1 corresponds to means for storing the treatment liquid for degreasing and chemical conversion. At least one of items 11a, 11b, 11c, 12a, 12b, 14, 17, 18, 111a and 121a corresponds to means for defining a circulation path or a circuit section. At least one of items 2, 3, 4, 5, 7, 20 and 420 corresponds to means for removing at least one of dust, chemical sludge and oil content from the treatment liquid, or to a purifying section.
Although the invention has been described above by reference to certain embodiments of the invention, the invention is not limited to the embodiments described above. Modifications and variations of the embodiments described above will occur to those skilled in the art in light of the above teachings. The scope of the invention is defined with reference to the following claims.
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