JP2023063639A - Washing method for cleaning object - Google Patents

Abstract

To allow washing to be performed by taking into consideration safety and global environment, without using a large amount of a cleaning solvent.SOLUTION: After carrying out first washing of removing an oil content adhered to a cleaning object 27 by steam cleaning using a cleaning solvent 3, the cleaning object 27 is immersed in washing liquid 4 not requiring degreasing force, and in addition, second washing of removing dirt other than the oil content by applying physical force to the cleaning object 27 is carried out in the washing liquid, thereby suppressing a use amount of the cleaning solvent 3 and the washing liquid 4 so that emission of greenhouse effect gas is restrained.SELECTED DRAWING: Figure 1

Description

TECHNICAL FIELD The present invention relates to a cleaning method for individually removing oil and non-oil contaminants adhering to objects to be cleaned, such as mechanical parts, electronic parts, and medical equipment.

JP-A-H05-004077 When manufacturing industrial products such as metals, ceramics, and resins, press, cutting, and other processes generate heat, so it is common to cool the materials with processing oil. Common. Therefore, when such processing is performed, dirt such as oil and cutting waste adheres to the industrial product to be cleaned according to the present application, which must be removed.

Therefore, when washing such objects to be washed, it was common to use a large amount of washing solvent as shown in Patent Document 1. However, the use of such a large amount of cleaning solvent causes photochemical smog, destruction of the ozone layer, soil contamination, and public pollution. In 1995, CFC 113,1.1.1-trichloroethane was completely abolished worldwide, and in recent years, the reduction of carbon dioxide emissions has become a global issue. , it is necessary to greatly reduce the amount of cleaning solvent used during cleaning.

However, in the cleaning methods generally used today, dirt such as oil, cutting chips, cutting waste, etc. attached to the object to be cleaned is simultaneously removed from the object to be cleaned by chemical and physical methods. A large amount of cleaning solvent had to be used. In addition, when petroleum-based cleaning solvents are used, from the viewpoint of ensuring safety when handling combustible materials, it is necessary to use special equipment, which increases costs and is often prohibited by law. It will be regulated. Also, the cleaning solvent used as a substitute for freon is expensive and the running cost is high, so it is difficult to use it in large quantities. Therefore, many companies have had to use highly toxic trichlorethylene, methylene chloride, bromine solvents, etc. in order to keep costs low.

Therefore, the present application intends to solve the above-mentioned problems, without using a large amount of cleaning solvent, and to reduce the amount of cleaning solvent used to enable cleaning that is safe and environmentally friendly. is.

In order to solve the above-mentioned problems, the first invention of the present application is to perform a first cleaning to remove oil adhering to the object to be cleaned by steam cleaning using a cleaning solvent, and then remove the degreasing power from the object to be cleaned. By performing a second cleaning in which the object to be cleaned is immersed in a cleaning solution that does not accompany the washing and removes dirt other than oil by applying physical force to the object to be cleaned in the cleaning solution, the amount of the cleaning solvent and the cleaning solution used can be suppressed. This makes it possible to suppress the emission of effect gas.

In the second invention of the present application, after performing the first cleaning for removing the oil adhering to the object to be cleaned by steam cleaning using a cleaning solvent, the object to be cleaned is subjected to physical force by air blowing to remove the oil. By performing the second cleaning that removes the stains, it is possible to suppress the amount of the cleaning solvent and the cleaning liquid used, thereby suppressing the emission of greenhouse gases.

Moreover, in the first cleaning, shower cleaning with the cleaning solvent may be performed in addition to steam cleaning.

Also, the cleaning solvent may be a petroleum-based solvent, HFO, a brominated solvent, or a chlorine-based solvent.

The cleaning liquid used in the second cleaning is water, pure water, HFC, or 3-methyl-3-methoxybutanol, or a mixture of HFC or 3-methyl-3-methoxybutanol and water or pure water. may be Although these cleaning solutions have low degreasing power, they are low in toxicity, easy to handle, and have a lower environmental load than the cleaning solvent used in the first cleaning. Therefore, it is possible to reduce the load on the global environment.

Further, the dirt other than the oil content to be removed by the second cleaning may be swarf, cutting swarf, or dust.

In addition, the physical force of the second cleaning may be ultrasonic waves, up-and-down rocking motion, jet flow, or rotary rocking motion. It may be something else.

Moreover, the first washing may be performed under atmospheric pressure or under reduced pressure.

Conventionally, in the case where oil, chips, cutting waste, etc. adhere to the object to be washed, it has been common practice to wash off these contaminants at the same time. Moreover, when washing a large amount of such objects to be washed, it is common to use a washing apparatus having a plurality of tanks or a vertically moving multi-stage washing apparatus. Therefore, since it is necessary to simultaneously remove oil and chips, etc., a large amount of cleaning solvent must be used, and there is concern about the impact on the environment.

Therefore, in the first invention of the present application, as described above, the removal of oil and the removal of dirt other than oil are carried out in separate washing steps, so that the first washing for removing oil uses a conventional washing solvent. However, even a cleaning liquid that does not have a degreasing power for removing stains other than oil, even if it is a cleaning liquid with a small environmental impact such as water, can sufficiently cope with the removal of stains other than oil. Therefore, it is possible to reduce the use of cleaning solvents that have been conventionally used and have a large environmental impact. In the second cleaning, by applying physical force in the cleaning liquid, it is possible to effectively remove swarf, cutting powder, dust, etc. adhering to the object to be cleaned.

In addition, since the second cleaning is performed on the object to be cleaned from which the oil was removed during the first cleaning, the cleaning liquid used in the second cleaning is mixed with chips, cutting chips, dust, and the like. However, since almost no oil is mixed in the used cleaning liquid, it can be easily reused by removing these precipitates from the used cleaning liquid. Therefore, it can be reused many times without requiring new cleaning liquid, and the load on the environment can be reduced.

In addition, in the second invention of the present application, as described above, the removal of oil and the removal of dirt other than oil are carried out in separate washing processes, so that the first washing for removing oil uses a conventional washing solvent. However, when removing dirt other than oil, physical force is applied by air blowing, so it is possible to reduce the use of conventionally used cleaning solvents that have a large environmental impact as much as possible. Also, in the second cleaning, it is possible to effectively remove shavings, shavings, dust, etc. adhering to the object to be cleaned by applying physical force by air blowing. Therefore, in the second invention of the present application, the cleaning solvent is used only in the first cleaning, and the cleaning liquid is not used in the second cleaning, so that the load on the environment can be further reduced.

As described above, according to the first and second inventions of the present application, it is possible to reduce the amount of the cleaning solvent used, which has a strong degreasing power and a large environmental load, in the entire cleaning process of the object to be cleaned compared with the conventional one. Such a cleaning method makes it possible to reduce the load on the global environment and contributes to the achievement of carbon neutrality.

FIG. 2 is a conceptual diagram of Examples 1 and 2 showing the first invention of the present application; The conceptual diagram of Example 3 which shows 1st invention of this application. The conceptual diagram which shows the cleaning apparatus used for the conventional cleaning method.

First, a conventional general cleaning method for cleaning an object to be cleaned (51) to which stains such as oil and cutting waste have adhered after press working, cutting, etc., will be described below. In the conventional cleaning method, it is common to perform vapor cleaning after liquid cleaning of the object (51) to be cleaned. As shown in FIG. In many cases, cleaning is performed using a cleaning device (56) provided with a steam cleaning tank (54). Since it is necessary to store the same cleaning solvent (55) in each of the cleaning tanks (52), (53), and (54), a large amount of the cleaning solvent (55) is used, which is harmful to the environment. In addition to fear of adverse effects, reusing the cleaning solvent (55) is troublesome.

On the other hand, in Embodiment 1, which is the first invention of the present application, as shown in FIG. In addition to containing HFO as a cleaning solvent (3), the liquid cleaning tank (2) contains water as a non-degreasing cleaning liquid (4). Although HFO is used as the cleaning solvent (3) in this example and Example 2, in other different examples, it is not limited to this. Also good. In this embodiment, water is used as the cleaning liquid (4), but in other different embodiments, pure water, HFC, 3-methyl-3-methoxybutanol, or HFC or 3-methyl A mixture of -3-methoxybutanol and water or pure water may be used.

The cleaning device (25) used in the cleaning method of this embodiment will be described below. First, the vapor cleaning tank (1) is equipped with a heater (5) and a temperature sensor (6) on the bottom side. Furthermore, a cooling coil (8) is wound around the inner periphery of the steam cleaning bath (1) on the side of the opening (7). A shower head (10) is provided slightly above the central portion in the height direction of the steam cleaning bath (1). The shower head (10) is connected to a shower tank (12) through a flow pipe (11) extending outward from the steam cleaning tank (1). A pump (13) is provided in the flow pipe (11), and the same cleaning solvent (3) as the cleaning solvent (3) in the steam cleaning tank (1) is stored in the shower tank (12). It is

Further, a discharge port (14) is provided on the bottom side of the peripheral wall (30) of the steam cleaning tank (1), and a discharge pipe (15) is provided between the discharge port (14) and the shower tank (12). It is possible to communicate with Furthermore, a recovery tray (16) for recovering the cleaning solvent (3) condensed on the cooling coil (8) is provided below the cooling coil (8). is connected through a recovery pipe (18) to a moisture separator (17) provided outside the steam cleaning tank (1).

Furthermore, the moisture separator (17) is connected to the discharge pipe (15) through a connecting pipe (26). The discharge pipe (15) is provided with a first opening/closing valve (21) on the steam cleaning tank (1) side of the connecting portion (20) with the connection pipe (26), and is provided on the shower tank (12) side. is provided with a second on-off valve (22). As shown in FIG. 1, the liquid cleaning tank (2) contains water as the cleaning liquid (4), and has an ultrasonic vibrator (23) fixedly arranged at the bottom.

A cleaning method of this embodiment using the cleaning device (25) having the above configuration will be described below. First, as shown in FIG. 1, the object to be cleaned (27) is placed above the cleaning solvent (3) in the vapor cleaning tank (1) and below the shower head (10). In this state, the pump (13) of the flow pipe (11) is operated to transfer the washing solvent (3) from the shower tank (12) to the shower head (10). As a result, the cleaning solvent (3) is jetted from the shower head (10) toward the object to be cleaned (27), and shower cleaning with the cleaning solvent (3) is performed.

By performing shower cleaning in this manner, the object to be cleaned (27) is sufficiently cooled by the cleaning solvent (3), so that condensation can be efficiently performed in the next steam cleaning, and cleaning can be performed. You can improve the effect. Also, the cleaning solvent (3) used in the shower cleaning is stored in the steam cleaning tank (1) as it is, and is used for the next steam cleaning.

Next, the heater (5) in the steam cleaning tank (1) is heated to boil the cleaning solvent (3) in the steam cleaning tank (1). As a result, the cleaning vapor (28) of the cleaning solvent (3) is generated, and the object (27) to be cleaned is steam cleaned. By this steam cleaning and the shower cleaning, the oil adhering to the object to be cleaned (27) is removed by the cleaning solvent (3), thus completing the first cleaning of the present application.

The condensate cooled by the cooling coil (8) during this steam cleaning is transferred to the water separator (17) through the recovery tray (16). When the washing solvent (3) from which water is separated by the water separator (17) is collected in the steam washing tank (1), the first on-off valve (21) is opened and the second on-off valve ( By closing 22), the cleaning solvent (3) is recovered again into the steam cleaning tank (1) through the connection pipe (26) and the discharge pipe (15). When the washing solvent (3) from which water is separated by the water separator (17) is collected in the shower tank (12), the first on-off valve (21) is closed and the second on-off valve (22) is closed. By opening the valve, the washing solvent (3) is transferred into the shower tank (12) through the connection pipe (26) and the discharge pipe (15).

After finishing the first cleaning, liquid cleaning, which is the second cleaning of the present application, is performed. That is, first, the object to be cleaned (27) in the steam cleaning tank (1) that has finished the first cleaning as described above is autothermally dried in the steam cleaning tank (1). Thereafter, as shown in FIG. 1, the object to be cleaned (27) is placed above the ultrasonic vibrator (23) in the liquid cleaning tank (2) and immersed in the cleaning liquid (4). In this state, the ultrasonic vibrator (23) is operated to perform ultrasonic cleaning, and the object to be cleaned (27) is swung up and down by a vertical driving device (not shown). As a result, a physical external force is applied to the object to be cleaned (27) due to the ultrasonic wave and the up-and-down oscillation, so that chips, cutting powder, dust, etc. adhering to the object to be cleaned (27) are effectively removed. becomes possible.

In this embodiment, as described above, the object to be cleaned (27) is subjected to ultrasonic cleaning or vertical swinging of the object to be cleaned (27) as a method of applying a physical external force to the object (27). Not limited to this, by applying a jet to the object to be cleaned (27), by rotating and rocking the object to be cleaned (27) itself, or by appropriately combining these ultrasonic waves, vertical rocking, jetting, and rotating rocking. , it is also possible to apply a physical force to the object to be cleaned (27).

In addition, by performing the second cleaning as described above, the cleaning liquid (4) will contain chips, cutting chips, dust, etc., but these will settle to the bottom of the liquid cleaning tank (2) due to their own weight. will be. In addition, since most of the oil has been removed from the object to be washed (27) during the first washing, it is in a state where it is hardly mixed with the washing liquid (4). Therefore, the cleaning liquid (4) can be repeatedly reused while stored in the liquid cleaning tank (2) without the need to use a special device to separate the oil.

In this embodiment, as described above, the cleaning solvent (3) is used only for the first cleaning. and cleaning liquid (4) can be easily reused. Therefore, this embodiment can reduce the load on the global environment, and is a cleaning method that can contribute to the achievement of carbon neutrality.

Further, in Example 2, which is the second invention of the present application, a vapor cleaning tank (1) having the same configuration as in Example 1 is provided. The steam cleaning tank (1) contains HFO, which is a cleaning solvent (3) capable of removing oil.

The cleaning apparatus used in the cleaning method of this embodiment will be described below. First, a heater (5) and a temperature sensor (6) are provided on the bottom side of the steam cleaning tank (1). Furthermore, a cooling coil (8) is wound around the inner periphery on the opening (7) side. Furthermore, a shower head (10) is provided slightly above the central portion in the height direction of the steam cleaning tank (1). The shower head (10) is connected to a shower tank (12) through a flow pipe (11) extending outward from the steam cleaning tank (1). A pump (13) is provided in the flow pipe (11), and the same cleaning solvent (3) as the cleaning solvent (3) in the steam cleaning tank (1) is stored in the shower tank (12). It is

Further, a discharge port (14) is provided on the bottom side of the steam cleaning tank (1), and a discharge pipe (15) can communicate between the discharge port (14) and the shower tank (12). and Furthermore, a recovery tray (16) for recovering the cleaning solvent (3) condensed on the cooling coil (8) is provided below the cooling coil (8). is connected through a recovery pipe (18) to a moisture separator (17) provided outside the steam cleaning tank (1).

Furthermore, the moisture separator (17) is connected to the discharge pipe (15) through a connecting pipe (26). The discharge pipe (15) is provided with a first opening/closing valve (21) on the steam cleaning tank (1) side of the joint (20) with the connection pipe (26), and a first on/off valve (21) on the shower tank (12) side. A second on-off valve (22) is provided. An air device (not shown) for blowing air onto the object to be cleaned (27) is provided on the side of the opening (7) of the liquid cleaning tank (2).

A cleaning method of this embodiment using the cleaning apparatus having the above configuration will be described below. First, as shown in FIG. 1, the object to be cleaned (27) is placed above the cleaning solvent (3) in the vapor cleaning tank (1) and below the shower head (10). In this state, the pump (13) of the flow pipe (11) is operated to transfer the washing solvent (3) from the shower tank (12) to the shower head (10). As a result, shower cleaning with the cleaning solvent (3) is performed by jetting the cleaning solvent (3) from the shower head (10) toward the object to be cleaned (27).

By performing shower cleaning in this manner, the object to be cleaned (27) is sufficiently cooled by the shower of the cleaning solvent (3). Therefore, it is possible to efficiently condense in the next steam cleaning, so that the cleaning effect can be improved. Also, the cleaning solvent (3) used in the shower cleaning is stored in the steam cleaning tank (1) and used for the next steam cleaning.

Next, the heater in the steam cleaning tank (1) is heated to boil the cleaning solvent (3) in the steam cleaning tank (1). As a result, the cleaning vapor (28) of the cleaning solvent (3) is generated, and the object (27) to be cleaned is steam cleaned. By this steam cleaning and the shower cleaning, the oil adhering to the object to be cleaned (27) is removed by the cleaning solvent (3), thus completing the first cleaning of the present application.

Next, the air device is operated to blow air onto the object to be cleaned (27) that has undergone the first cleaning. As a result, it is possible to physically remove chips, cutting powder, dust, etc., which could not be removed during the first cleaning, from the object to be cleaned (27). As described above, in this embodiment, unlike the first embodiment, cleaning is performed only by air blow without using a cleaning liquid in the second cleaning, so that it is possible to further reduce the load on the environment.

Further, in Examples 1 and 2, the first cleaning is performed under atmospheric pressure, but in Example 3, which is the first invention of the present application, a petroleum-based solvent is used as the cleaning solvent (33), so safety is taken into consideration. The first cleaning is performed under reduced pressure. This embodiment will be described below. As shown in FIG. 2, it is equipped with a steam cleaning tank (31) and a liquid cleaning tank (32). A heating tank (46) is provided below the bottom of the steam cleaning tank (31), and a communication valve (49) connects the heating tank (46) and the steam cleaning tank (31). A communication pipe (50) is provided to enable communication. The heating tank (46) contains a petroleum-based solvent that is a cleaning solvent (33) that can remove oil, and the liquid cleaning tank (32) contains water that is a cleaning liquid (34) that does not involve degreasing. is stored.

The inside of the heating bath (46) is hermetically sealed so that the cleaning solvent (33) contained therein does not diffuse to the outside. In addition, although water is used as the cleaning liquid (34) in this embodiment, other different embodiments are not limited to this, and pure water, HFC, 3-methyl-3-methoxybutanol, or HFC or 3-methyl A mixture of -3-methoxybutanol and water or pure water may be used.

Further, the steam cleaning tank (31) has an opening (37) of the steam cleaning tank (31) so that when the cleaning steam (47) is generated inside, the cleaning steam (47) does not leak out. The upper lid (48) can be sealed. The steam cleaning tank (31) is connected to a cooler (43) that can communicate with the steam cleaning tank (31) through a first on-off valve (40) provided in the recovery pipe (38). A vacuum release valve (42) is connected through (41). A vacuum pump (44) is connected to the cooler (43). Therefore, by sealing the upper lid (48) of the steam cleaning tank (31) and operating the vacuum pump (44), the atmosphere in the steam cleaning tank (31) can be reduced.

A heating pipe (39) and a temperature sensor (36) are provided in the heating bath (46). As shown in FIG. 2, the liquid cleaning bath (32) contains water as a cleaning liquid (34), and an ultrasonic vibrator (45) is fixedly arranged at the bottom.

A cleaning method of this embodiment using the cleaning device (25) having the above configuration will be described below. First, the vacuum release valve (42) and the communication valve (49) are closed in advance, and the first on-off valve (40) is opened. The cleaning solvent (33) in the heating bath (46) is heated by the heating pipe (39) to generate cleaning steam (47). As shown in FIG. 2, the object to be cleaned (51) is placed in the steam cleaning tank (31), and the top cover (48) is placed over the opening (37) of the steam cleaning tank (31). In this state, the vacuum pump (44) is operated to reduce the pressure in the steam cleaning tank (31).

After that, the communication valve (49) is opened to bring the heating tank (46) and the steam cleaning tank (31) into communication with each other, so that the cleaning steam (47) generated in the heating tank (46) is It is sent into the steam cleaning tank (31). In this state, the object to be cleaned (51) is steam cleaned in the steam cleaning tank (31). By this steam cleaning, oil adhering to the object to be cleaned (51) is removed by the cleaning solvent (33), thus completing the first cleaning of the present application. The cleaning steam (47) generated in the steam cleaning tank (31) during this steam cleaning is transferred through the first on-off valve (40) to the cooler (43), where it is cooled and reused as the cleaning solvent (33). be recovered.

After the object to be cleaned (51) in the vapor cleaning tank (31), which has been subjected to the first cleaning as described above, is autothermally dried, liquid cleaning, which is the second cleaning of the present application, is performed. That is, after all the cleaning steam in the steam cleaning bath (31) is transferred to the cooler (43) through the first on-off valve (40), the first on-off valve (40) is closed and the vacuum release valve (42) is opened. By opening the valve, the decompressed state in the steam cleaning tank (31) is released to atmospheric pressure, the upper lid (48) of the steam cleaning tank (31) is opened, and the steam cleaning tank (31) self-heats. Take out the object to be washed after drying. The object (51) to be cleaned is placed above the ultrasonic oscillator (45) in the liquid cleaning tank (32) as shown in FIG. 2, and the object (51) to be cleaned is immersed in the cleaning solution (34). state.

In this state, the ultrasonic vibrator (23) is operated to perform ultrasonic cleaning, and the object to be cleaned (51) is swung up and down by a vertical driving device (not shown). As a result, a physical external force is applied to the object to be cleaned (51) due to the ultrasonic waves and the up-and-down oscillation, so chips, cutting powder, dust, etc. adhering to the object to be cleaned (51) are effectively removed. It becomes possible to

Also, by performing the second cleaning as described above, the cleaning liquid (34) contains chips, cutting chips, dust, etc., which settle to the bottom of the liquid cleaning tank (32) due to their own weight. will be. Also, since most of the oil has been removed from the object to be washed (51) during the first washing, it is in a state where it is hardly mixed with the washing liquid (34). Therefore, the cleaning liquid (34) can be repeatedly reused while stored in the liquid cleaning tank (32) without the need for special equipment to separate the oil.

In this embodiment, as described above, the cleaning solvent (33) is used only for the first cleaning. and the cleaning liquid (34) can be easily reused. Therefore, this embodiment can reduce the load on the global environment, and is a cleaning method that can contribute to the achievement of carbon neutrality.

3 cleaning solvent 4 cleaning liquid 27 object to be cleaned

TECHNICAL FIELD The present invention relates to a cleaning method for individually removing oil and non-oil contaminants adhering to objects to be cleaned, such as mechanical parts, electronic parts, and medical equipment.

JP-A-H05-004077 When manufacturing industrial products such as metals, ceramics, and resins, press, cutting, and other processes generate heat, so it is common to cool the materials with processing oil. Common. Therefore, when such processing is performed, dirt such as oil and cutting waste adheres to the industrial product to be cleaned according to the present application, which must be removed.

Therefore, when washing such objects to be washed, it was common to use a large amount of washing solvent as shown in Patent Document 1. However, the use of such a large amount of cleaning solvent causes photochemical smog, destruction of the ozone layer, soil contamination, and public pollution. In 1995, CFC 113,1.1.1-trichloroethane was completely abolished worldwide, and in recent years, the reduction of carbon dioxide emissions has become a global issue. , it is necessary to greatly reduce the amount of cleaning solvent used during cleaning.

However, in the cleaning methods generally used today, dirt such as oil, cutting chips, cutting waste, etc. attached to the object to be cleaned is simultaneously removed from the object to be cleaned by chemical and physical methods. A large amount of cleaning solvent had to be used. In addition, when petroleum-based cleaning solvents are used, from the viewpoint of ensuring safety when handling combustible materials, it is necessary to use special equipment, which increases costs and is often prohibited by law. It will be regulated. Also, the cleaning solvent used as a substitute for freon is expensive and the running cost is high, so it is difficult to use it in large quantities. Therefore, many companies have had to use highly toxic trichlorethylene, methylene chloride, bromine solvents, etc. in order to keep costs down.

Therefore, the present application intends to solve the above-mentioned problems, without using a large amount of cleaning solvent, and to reduce the amount of cleaning solvent used to enable cleaning that is safe and environmentally friendly. is.

In order to solve the above-mentioned problems, the present invention performs a first cleaning for removing oil adhering to the object to be cleaned by steam cleaning using a cleaning solvent, and then performs autothermal drying of the object to be cleaned. After that, the object to be washed is immersed in a cleaning liquid that does not involve degreasing power, and a second cleaning is performed in which physical force is applied to the object to be cleaned in the cleaning liquid to remove dirt other than oil, thereby performing the cleaning. It is possible to reduce greenhouse gas emissions by suppressing the amount of solvent and cleaning liquid used.

Moreover, in the first cleaning, shower cleaning with the cleaning solvent may be performed in addition to steam cleaning.

Also, the cleaning solvent may be a petroleum-based solvent, HFO, a brominated solvent, or a chlorine-based solvent.

The cleaning liquid used in the second cleaning is water, pure water, HFC, or 3-methyl-3-methoxybutanol, or a mixture of HFC or 3-methyl-3-methoxybutanol and water or pure water. may be Although these cleaning solutions have low degreasing power, they are low in toxicity, easy to handle, and have a lower environmental load than the cleaning solvent used in the first cleaning. Therefore, it is possible to reduce the load on the global environment.

Further, the dirt other than the oil content to be removed by the second cleaning may be swarf, cutting swarf, or dust.

In addition, the physical force of the second cleaning may be ultrasonic waves, up-and-down rocking motion, jet flow, or rotary rocking motion. It may be something else.

Moreover, the first washing may be performed under atmospheric pressure or under reduced pressure.

Conventionally, in the case where oil, chips, cutting waste, etc. adhere to the object to be washed, it has been common practice to wash off these contaminants at the same time. Moreover, when washing a large amount of such objects to be washed, it is common to use a washing apparatus having a plurality of tanks or a vertically moving multi-stage washing apparatus. Therefore, since it is necessary to simultaneously remove oil and chips, etc., a large amount of cleaning solvent must be used, and there is concern about the impact on the environment.

Therefore, in the present invention , as described above, the removal of oil and the removal of dirt other than oil are carried out in separate washing steps, so that the first washing for removing oil uses a conventional washing solvent. As a cleaning liquid that does not have a degreasing power for removing stains other than oil, even a cleaning liquid that has a small environmental impact such as water can be sufficiently used to remove stains other than oil. Therefore, it is possible to reduce the use of cleaning solvents that have been conventionally used and have a large environmental impact. In the second cleaning, by applying physical force in the cleaning liquid, it is possible to effectively remove swarf, cutting powder, dust, etc. adhering to the object to be cleaned.

In addition, since the second cleaning is performed on the object to be cleaned from which the oil was removed during the first cleaning, the cleaning liquid used in the second cleaning is mixed with chips, cutting chips, dust, and the like. However, since almost no oil is mixed in the used cleaning liquid, it can be easily reused by removing these precipitates from the used cleaning liquid. Therefore, it can be reused many times without requiring new cleaning liquid, and the load on the environment can be reduced.

As described above, the present invention makes it possible to reduce the amount of the cleaning solvent used, which has a strong degreasing power and a large environmental load, in the entire cleaning process of the object to be cleaned, compared with the conventional one. Such a cleaning method makes it possible to reduce the load on the global environment and contributes to the achievement of carbon neutrality.

BRIEF DESCRIPTION OF THE DRAWINGS The conceptual diagram of Example 1 which shows this invention. The conceptual diagram of Example 2 which shows this invention . The conceptual diagram which shows the cleaning apparatus used for the conventional cleaning method.

First, a conventional general cleaning method for cleaning an object to be cleaned (51) to which stains such as oil and cutting waste have adhered after press working, cutting, etc., will be described below. In the conventional cleaning method, it is common to perform vapor cleaning after liquid cleaning of the object (51) to be cleaned. As shown in FIG. In many cases, cleaning is performed using a cleaning device (56) provided with a steam cleaning tank (54). Since it is necessary to store the same cleaning solvent (55) in each of the cleaning tanks (52), (53), and (54), a large amount of the cleaning solvent (55) is used, which is harmful to the environment. In addition to fear of adverse effects, reusing the cleaning solvent (55) is troublesome.

On the other hand, in the first embodiment, as shown in FIG. 1, a steam cleaning tank (1) and a liquid cleaning tank (2) are provided, and the steam cleaning tank (1) contains a cleaning solvent (3) capable of removing oil The liquid cleaning tank (2) contains water, which is a cleaning liquid (4) that does not have a degreasing power. Although HFO is used as the cleaning solvent (3) in this example and Example 2, in other different examples, it is not limited to this. Also good. In this embodiment, water is used as the cleaning liquid (4), but in other different embodiments, pure water, HFC, 3-methyl-3-methoxybutanol, or HFC or 3-methyl A mixture of -3-methoxybutanol and water or pure water may be used.

The cleaning device (25) used in the cleaning method of this embodiment will be described below. First, the vapor cleaning tank (1) is equipped with a heater (5) and a temperature sensor (6) on the bottom side. Furthermore, a cooling coil (8) is wound around the inner periphery of the steam cleaning bath (1) on the side of the opening (7). A shower head (10) is provided slightly above the central portion in the height direction of the steam cleaning bath (1). The shower head (10) is connected to a shower tank (12) through a flow pipe (11) extending outward from the steam cleaning tank (1). A pump (13) is provided in the flow pipe (11), and the same cleaning solvent (3) as the cleaning solvent (3) in the steam cleaning tank (1) is stored in the shower tank (12). It is

Further, a discharge port (14) is provided on the bottom side of the peripheral wall (30) of the steam cleaning tank (1), and a discharge pipe (15) is provided between the discharge port (14) and the shower tank (12). It is possible to communicate with Furthermore, a recovery tray (16) for recovering the cleaning solvent (3) condensed on the cooling coil (8) is provided below the cooling coil (8). is connected through a recovery pipe (18) to a moisture separator (17) provided outside the steam cleaning tank (1).

Furthermore, the moisture separator (17) is connected to the discharge pipe (15) through a connecting pipe (26). The discharge pipe (15) is provided with a first opening/closing valve (21) on the steam cleaning tank (1) side of the connecting portion (20) with the connection pipe (26), and is provided on the shower tank (12) side. is provided with a second on-off valve (22). As shown in FIG. 1, the liquid cleaning tank (2) contains water as the cleaning liquid (4), and has an ultrasonic vibrator (23) fixedly arranged at the bottom.

A cleaning method of this embodiment using the cleaning device (25) having the above configuration will be described below. First, as shown in FIG. 1, the object to be cleaned (27) is placed above the cleaning solvent (3) in the vapor cleaning tank (1) and below the shower head (10). In this state, the pump (13) of the flow pipe (11) is operated to transfer the washing solvent (3) from the shower tank (12) to the shower head (10). As a result, the cleaning solvent (3) is jetted from the shower head (10) toward the object to be cleaned (27), and shower cleaning with the cleaning solvent (3) is performed.

By performing shower cleaning in this manner, the object to be cleaned (27) is sufficiently cooled by the cleaning solvent (3), so that condensation can be efficiently performed in the next steam cleaning, and cleaning can be performed. You can improve the effect. Also, the cleaning solvent (3) used in the shower cleaning is stored in the steam cleaning tank (1) as it is, and is used for the next steam cleaning.

Next, the heater (5) in the steam cleaning tank (1) is heated to boil the cleaning solvent (3) in the steam cleaning tank (1). As a result, the cleaning vapor (28) of the cleaning solvent (3) is generated, and the object (27) to be cleaned is steam cleaned. By this steam cleaning and the shower cleaning, the oil adhering to the object to be cleaned (27) is removed by the cleaning solvent (3), thus completing the first cleaning of the present application.

The condensate cooled by the cooling coil (8) during this steam cleaning is transferred to the water separator (17) through the recovery tray (16). When the washing solvent (3) from which water is separated by the water separator (17) is collected in the steam washing tank (1), the first on-off valve (21) is opened and the second on-off valve ( By closing 22), the cleaning solvent (3) is recovered again into the steam cleaning tank (1) through the connection pipe (26) and the discharge pipe (15). When the washing solvent (3) from which water is separated by the water separator (17) is collected in the shower tank (12), the first on-off valve (21) is closed and the second on-off valve (22) is closed. By opening the valve, the washing solvent (3) is transferred into the shower tank (12) through the connection pipe (26) and the discharge pipe (15).

After finishing the first cleaning, liquid cleaning, which is the second cleaning of the present application, is performed. That is, first, the object to be cleaned (27) in the steam cleaning tank (1) that has finished the first cleaning as described above is autothermally dried in the steam cleaning tank (1). Thereafter, as shown in FIG. 1, the object to be cleaned (27) is placed above the ultrasonic vibrator (23) in the liquid cleaning tank (2) and immersed in the cleaning liquid (4). In this state, the ultrasonic vibrator (23) is operated to perform ultrasonic cleaning, and the object to be cleaned (27) is swung up and down by a vertical driving device (not shown). As a result, a physical external force is applied to the object to be cleaned (27) due to the ultrasonic wave and the up-and-down oscillation, so that chips, cutting powder, dust, etc. adhering to the object to be cleaned (27) are effectively removed. becomes possible.

In this embodiment, as described above, the object to be cleaned (27) is subjected to ultrasonic cleaning or vertical swinging of the object to be cleaned (27) as a method of applying a physical external force to the object (27). Not limited to this, by applying a jet to the object to be cleaned (27), by rotating and rocking the object to be cleaned (27) itself, or by appropriately combining these ultrasonic waves, vertical rocking, jetting, and rotating rocking. , it is also possible to apply a physical force to the object to be cleaned (27).

In addition, by performing the second cleaning as described above, the cleaning liquid (4) will contain chips, cutting chips, dust, etc., but these will settle to the bottom of the liquid cleaning tank (2) due to their own weight. will be. In addition, since most of the oil has been removed from the object to be washed (27) during the first washing, it is in a state where it is hardly mixed with the washing liquid (4). Therefore, the cleaning liquid (4) can be repeatedly reused while stored in the liquid cleaning tank (2) without the need to use a special device to separate the oil.

In this embodiment, as described above, the cleaning solvent (3) is used only for the first cleaning. and cleaning liquid (4) can be easily reused. Therefore, this embodiment can reduce the load on the global environment, and is a cleaning method that can contribute to the achievement of carbon neutrality.

Further, in Example 1, the first cleaning is performed under atmospheric pressure, but in this Example 2, a petroleum-based solvent is used as the cleaning solvent (33), so the first cleaning is performed under reduced pressure in consideration of safety. It is used for cleaning. This embodiment will be described below. As shown in FIG. 2, it is equipped with a steam cleaning tank (31) and a liquid cleaning tank (32). A heating tank (46) is provided below the bottom of the steam cleaning tank (31), and a communication valve (49) connects the heating tank (46) and the steam cleaning tank (31). A communication pipe (50) is provided to enable communication. The heating tank (46) contains a petroleum-based solvent that is a cleaning solvent (33) that can remove oil, and the liquid cleaning tank (32) contains water that is a cleaning liquid (34) that does not involve degreasing. is stored.

The inside of the heating bath (46) is hermetically sealed so that the cleaning solvent (33) contained therein does not diffuse to the outside. In addition, although water is used as the cleaning liquid (34) in this embodiment, other different embodiments are not limited to this, and pure water, HFC, 3-methyl-3-methoxybutanol, or HFC or 3-methyl A mixture of -3-methoxybutanol and water or pure water may be used.

Further, the steam cleaning tank (31) has an opening (37) of the steam cleaning tank (31) so that when the cleaning steam (47) is generated inside, the cleaning steam (47) does not leak out. The upper lid (48) can be sealed. The steam cleaning tank (31) is connected to a cooler (43) that can communicate with the steam cleaning tank (31) through a first on-off valve (40) provided in the recovery pipe (38). A vacuum release valve (42) is connected through (41). A vacuum pump (44) is connected to the cooler (43). Therefore, by sealing the upper lid (48) of the steam cleaning tank (31) and operating the vacuum pump (44), the atmosphere in the steam cleaning tank (31) can be reduced.

A heating pipe (39) and a temperature sensor (36) are provided in the heating bath (46). As shown in FIG. 2, the liquid cleaning bath (32) contains water as a cleaning liquid (34), and an ultrasonic vibrator (45) is fixedly arranged at the bottom.

A cleaning method of this embodiment using the cleaning device (25) having the above configuration will be described below. First, the vacuum release valve (42) and the communication valve (49) are closed in advance, and the first on-off valve (40) is opened. The cleaning solvent (33) in the heating bath (46) is heated by the heating pipe (39) to generate cleaning steam (47). As shown in FIG. 2, the object to be cleaned (51) is placed in the steam cleaning tank (31), and the top cover (48) is placed over the opening (37) of the steam cleaning tank (31). In this state, the vacuum pump (44) is operated to reduce the pressure in the steam cleaning tank (31).

After that, the communication valve (49) is opened to bring the heating tank (46) and the steam cleaning tank (31) into communication with each other, so that the cleaning steam (47) generated in the heating tank (46) is It is sent into the steam cleaning tank (31). In this state, the object to be cleaned (51) is steam cleaned in the steam cleaning tank (31). By this steam cleaning, oil adhering to the object to be cleaned (51) is removed by the cleaning solvent (33), thus completing the first cleaning of the present application. The cleaning steam (47) generated in the steam cleaning tank (31) during this steam cleaning is transferred through the first on-off valve (40) to the cooler (43), where it is cooled and reused as the cleaning solvent (33). be recovered.

After the object to be cleaned (51) in the vapor cleaning tank (31), which has been subjected to the first cleaning as described above, is autothermally dried, liquid cleaning, which is the second cleaning of the present application, is performed. That is, after all the cleaning steam in the steam cleaning bath (31) is transferred to the cooler (43) through the first on-off valve (40), the first on-off valve (40) is closed and the vacuum release valve (42) is opened. By opening the valve, the decompressed state in the steam cleaning tank (31) is released to atmospheric pressure, the upper lid (48) of the steam cleaning tank (31) is opened, and the steam cleaning tank (31) self-heats. Take out the object to be washed after drying. The object (51) to be cleaned is placed above the ultrasonic oscillator (45) in the liquid cleaning tank (32) as shown in FIG. 2, and the object (51) to be cleaned is immersed in the cleaning solution (34). state.

In this state, the ultrasonic vibrator (23) is operated to perform ultrasonic cleaning, and the object to be cleaned (51) is swung up and down by a vertical driving device (not shown). As a result, a physical external force is applied to the object to be cleaned (51) due to the ultrasonic waves and the up-and-down oscillation, so chips, cutting powder, dust, etc. adhering to the object to be cleaned (51) are effectively removed. It becomes possible to

Also, by performing the second cleaning as described above, the cleaning liquid (34) contains chips, cutting chips, dust, etc., which settle to the bottom of the liquid cleaning tank (32) due to their own weight. will be. Also, since most of the oil has been removed from the object to be washed (51) during the first washing, it is in a state where it is hardly mixed with the washing liquid (34). Therefore, the cleaning liquid (34) can be repeatedly reused while stored in the liquid cleaning tank (32) without the need for special equipment to separate the oil.

In this embodiment, as described above, the cleaning solvent (33) is used only for the first cleaning. and the cleaning liquid (34) can be easily reused. Therefore, this embodiment can reduce the load on the global environment, and is a cleaning method that can contribute to the achievement of carbon neutrality.

3 cleaning solvent 4 cleaning liquid 27 object to be cleaned

TECHNICAL FIELD The present invention relates to a cleaning method for individually removing oil and non-oil contaminants adhering to objects to be cleaned, such as mechanical parts, electronic parts, and medical equipment.

JP-A-H05-004077 When manufacturing industrial products such as metals, ceramics, and resins, press, cutting, and other processes generate heat, so it is common to cool the materials with processing oil. Common. Therefore, when such processing is performed, dirt such as oil and cutting waste adheres to the industrial product to be cleaned according to the present application, which must be removed.

Therefore, when washing such objects to be washed, it was common to use a large amount of washing solvent as shown in Patent Document 1. However, the use of such a large amount of cleaning solvent causes photochemical smog, destruction of the ozone layer, soil contamination, and public pollution. In 1995, CFC 113,1.1.1-trichloroethane was completely abolished worldwide, and in recent years, the reduction of carbon dioxide emissions has become a global issue. , it is necessary to greatly reduce the amount of cleaning solvent used during cleaning.

However, in the cleaning methods generally used today, dirt such as oil, cutting chips, cutting waste, etc. attached to the object to be cleaned is simultaneously removed from the object to be cleaned by chemical and physical methods. A large amount of cleaning solvent had to be used. In addition, when petroleum-based cleaning solvents are used, from the viewpoint of ensuring safety when handling combustible materials, it is necessary to use special equipment, which increases costs and is often prohibited by law. It will be regulated. Also, the cleaning solvent used as a substitute for freon is expensive and the running cost is high, so it is difficult to use it in large quantities. Therefore, many companies have had to use highly toxic trichlorethylene, methylene chloride, bromine solvents, etc. in order to keep costs low.

Therefore, the present application intends to solve the above-mentioned problems, without using a large amount of cleaning solvent, and to reduce the amount of cleaning solvent used to enable cleaning that is safe and environmentally friendly. is.

In order to solve the above-mentioned problems, the present invention performs a first cleaning for removing oil adhering to the object to be cleaned by steam cleaning using a cleaning solvent, then performs autothermal drying of the object to be cleaned, and then performs this cleaning. The object to be washed is immersed in a cleaning liquid that does not involve degreasing power, and the object to be washed is subjected to a second cleaning in which a physical force is applied to the object to be cleaned in the cleaning liquid to remove dirt other than oil, thereby removing the cleaning solvent and the This makes it possible to suppress the emission of greenhouse gases by suppressing the amount of cleaning liquid used.

The cleaning liquid used in the second cleaning is water, pure water, HFC, or 3-methyl-3-methoxybutanol, or a mixture of HFC or 3-methyl-3-methoxybutanol and water or pure water. is. Although these cleaning solutions have low degreasing power, they are low in toxicity, easy to handle, and have a lower environmental load than the cleaning solvent used in the first cleaning. Therefore, it is possible to reduce the load on the global environment.

Moreover, in the first cleaning, shower cleaning with the cleaning solvent may be performed in addition to steam cleaning.

Also, the cleaning solvent may be a petroleum-based solvent, HFO, a brominated solvent, or a chlorine-based solvent.

Further, the dirt other than the oil content to be removed by the second cleaning may be swarf, cutting swarf, or dust.

In addition, the physical force of the second cleaning may be ultrasonic waves, up-and-down rocking motion, jet flow, or rotary rocking motion. It may be something else.

Moreover, the first washing may be performed under atmospheric pressure or under reduced pressure.

Conventionally, in the case where oil, chips, cutting waste, etc. adhere to the object to be washed, it has been common practice to wash off these contaminants at the same time. Moreover, when washing a large amount of such objects to be washed, it is common to use a washing apparatus having a plurality of tanks or a vertically moving multi-stage washing apparatus. Therefore, since it is necessary to simultaneously remove oil and chips, etc., a large amount of cleaning solvent must be used, and there is concern about the impact on the environment.

Therefore, in the present invention, as described above, the removal of oil and the removal of dirt other than oil are carried out in separate washing steps. As a cleaning liquid that does not have a degreasing power for removing dirt other than oil, even a cleaning liquid that has a small environmental impact such as water can be sufficiently used to remove dirt other than oil. Therefore, it is possible to reduce the use of cleaning solvents that have been conventionally used and have a large environmental impact. In the second cleaning, by applying physical force in the cleaning liquid, it is possible to effectively remove swarf, cutting powder, dust, etc. adhering to the object to be cleaned.

In addition, since the second cleaning is performed on the object to be cleaned from which the oil was removed during the first cleaning, the cleaning liquid used in the second cleaning is mixed with chips, cutting chips, dust, and the like. However, since almost no oil is mixed in the used cleaning liquid, it can be easily reused by removing these precipitates from the used cleaning liquid. Therefore, it can be reused many times without requiring new cleaning liquid, and the load on the environment can be reduced.

As described above, the present invention makes it possible to reduce the amount of the cleaning solvent used, which has a strong degreasing power and a large environmental load, in the entire cleaning process of the object to be cleaned, compared with the conventional one. Such a cleaning method makes it possible to reduce the load on the global environment and contributes to the achievement of carbon neutrality.

BRIEF DESCRIPTION OF THE DRAWINGS The conceptual diagram of Example 1 which shows this invention. The conceptual diagram of Example 2 which shows this invention. The conceptual diagram which shows the cleaning apparatus used for the conventional cleaning method.

First, a conventional general cleaning method for cleaning an object to be cleaned (51) to which stains such as oil and cutting waste have adhered after press working, cutting, etc., will be described below. In the conventional cleaning method, it is common to perform vapor cleaning after liquid cleaning of the object (51) to be cleaned. As shown in FIG. In many cases, cleaning is performed using a cleaning device (56) provided with a steam cleaning tank (54). Since it is necessary to store the same cleaning solvent (55) in each of the cleaning tanks (52), (53), and (54), a large amount of the cleaning solvent (55) is used, which is harmful to the environment. In addition to fear of adverse effects, reusing the cleaning solvent (55) is troublesome.

On the other hand, in the first embodiment, as shown in FIG. 1, a steam cleaning tank (1) and a liquid cleaning tank (2) are provided, and the steam cleaning tank (1) contains a cleaning solvent (3) capable of removing oil. In addition to storing a certain HFO, the liquid cleaning tank (2) stores water, which is a cleaning liquid (4) that does not involve degreasing. Although HFO is used as the cleaning solvent (3) in this example and Example 2, in other different examples, it is not limited to this. Also good. In this embodiment, water is used as the cleaning liquid (4), but in other different embodiments, pure water, HFC, 3-methyl-3-methoxybutanol, or HFC or 3-methyl A mixture of -3-methoxybutanol and water or pure water may be used.

The cleaning device (25) used in the cleaning method of this embodiment will be described below. First, the vapor cleaning tank (1) is equipped with a heater (5) and a temperature sensor (6) on the bottom side. Furthermore, a cooling coil (8) is wound around the inner periphery of the steam cleaning bath (1) on the side of the opening (7). A shower head (10) is provided slightly above the central portion in the height direction of the steam cleaning bath (1). The shower head (10) is connected to a shower tank (12) through a flow pipe (11) extending outward from the steam cleaning tank (1). A pump (13) is provided in the flow pipe (11), and the same cleaning solvent (3) as the cleaning solvent (3) in the steam cleaning tank (1) is stored in the shower tank (12). It is

Further, a discharge port (14) is provided on the bottom side of the peripheral wall (30) of the steam cleaning tank (1), and a discharge pipe (15) is provided between the discharge port (14) and the shower tank (12). It is possible to communicate with Furthermore, a recovery tray (16) for recovering the cleaning solvent (3) condensed on the cooling coil (8) is provided below the cooling coil (8). is connected through a recovery pipe (18) to a moisture separator (17) provided outside the steam cleaning tank (1).

Furthermore, the moisture separator (17) is connected to the discharge pipe (15) through a connecting pipe (26). The discharge pipe (15) is provided with a first opening/closing valve (21) on the steam cleaning tank (1) side of the connecting portion (20) with the connection pipe (26), and is provided on the shower tank (12) side. is provided with a second on-off valve (22). As shown in FIG. 1, the liquid cleaning tank (2) contains water as the cleaning liquid (4), and has an ultrasonic vibrator (23) fixedly arranged at the bottom.

A cleaning method of this embodiment using the cleaning device (25) having the above configuration will be described below. First, as shown in FIG. 1, the object to be cleaned (27) is placed above the cleaning solvent (3) in the vapor cleaning tank (1) and below the shower head (10). In this state, the pump (13) of the flow pipe (11) is operated to transfer the washing solvent (3) from the shower tank (12) to the shower head (10). As a result, the cleaning solvent (3) is jetted from the shower head (10) toward the object to be cleaned (27), and shower cleaning with the cleaning solvent (3) is performed.

By performing shower cleaning in this manner, the object to be cleaned (27) is sufficiently cooled by the cleaning solvent (3), so that condensation can be efficiently performed in the next steam cleaning, and cleaning can be performed. You can improve the effect. Also, the cleaning solvent (3) used in the shower cleaning is stored in the steam cleaning tank (1) as it is, and is used for the next steam cleaning.

Next, the heater (5) in the steam cleaning tank (1) is heated to boil the cleaning solvent (3) in the steam cleaning tank (1). As a result, the cleaning vapor (28) of the cleaning solvent (3) is generated, and the object (27) to be cleaned is steam cleaned. By this steam cleaning and the shower cleaning, the oil adhering to the object to be cleaned (27) is removed by the cleaning solvent (3), thus completing the first cleaning of the present application.

The condensate cooled by the cooling coil (8) during this steam cleaning is transferred to the water separator (17) through the recovery tray (16). When the washing solvent (3) from which water is separated by the water separator (17) is collected in the steam washing tank (1), the first on-off valve (21) is opened and the second on-off valve ( By closing 22), the cleaning solvent (3) is recovered again into the steam cleaning tank (1) through the connection pipe (26) and the discharge pipe (15). When the washing solvent (3) from which water is separated by the water separator (17) is collected in the shower tank (12), the first on-off valve (21) is closed and the second on-off valve (22) is closed. By opening the valve, the washing solvent (3) is transferred into the shower tank (12) through the connection pipe (26) and the discharge pipe (15).

After finishing the first cleaning, liquid cleaning, which is the second cleaning of the present application, is performed. That is, first, the object to be cleaned (27) in the steam cleaning tank (1) that has finished the first cleaning as described above is autothermally dried in the steam cleaning tank (1). Thereafter, as shown in FIG. 1, the object to be cleaned (27) is placed above the ultrasonic vibrator (23) in the liquid cleaning tank (2) and immersed in the cleaning liquid (4). In this state, the ultrasonic vibrator (23) is operated to perform ultrasonic cleaning, and the object to be cleaned (27) is swung up and down by a vertical driving device (not shown). As a result, a physical external force is applied to the object to be cleaned (27) due to the ultrasonic wave and the up-and-down oscillation, so that chips, cutting powder, dust, etc. adhering to the object to be cleaned (27) are effectively removed. becomes possible.

In this embodiment, as described above, the object to be cleaned (27) is subjected to ultrasonic cleaning or vertical swinging of the object to be cleaned (27) as a method of applying a physical external force to the object (27). Not limited to this, by applying a jet to the object to be cleaned (27), by rotating and rocking the object to be cleaned (27) itself, or by appropriately combining these ultrasonic waves, vertical rocking, jetting, and rotating rocking. , it is also possible to apply a physical force to the object to be cleaned (27).

In addition, by performing the second cleaning as described above, the cleaning liquid (4) will contain chips, cutting chips, dust, etc., but these will settle to the bottom of the liquid cleaning tank (2) due to their own weight. will be. In addition, since most of the oil has been removed from the object to be washed (27) during the first washing, it is in a state where it is hardly mixed with the washing liquid (4). Therefore, the cleaning liquid (4) can be repeatedly reused while stored in the liquid cleaning tank (2) without the need to use a special device to separate the oil.

In this embodiment, as described above, the cleaning solvent (3) is used only for the first cleaning. and cleaning liquid (4) can be easily reused. Therefore, this embodiment can reduce the load on the global environment, and is a cleaning method that can contribute to the achievement of carbon neutrality.

Further, in Example 1, the first cleaning is performed under atmospheric pressure, but in this Example 2, a petroleum-based solvent is used as the cleaning solvent (33), so the first cleaning is performed under reduced pressure in consideration of safety. It is something to do. This embodiment will be described below. As shown in FIG. 2, it is equipped with a steam cleaning tank (31) and a liquid cleaning tank (32). A heating tank (46) is provided below the bottom of the steam cleaning tank (31), and a communication valve (49) connects the heating tank (46) and the steam cleaning tank (31). A communication pipe (50) is provided to enable communication. The heating tank (46) contains a petroleum-based solvent, which is a cleaning solvent (33) capable of removing oil, and the liquid cleaning tank (32) contains water, which is a cleaning liquid (34) without degreasing power. is stored.

The inside of the heating bath (46) is hermetically sealed so that the cleaning solvent (33) contained therein does not diffuse to the outside. In addition, although water is used as the cleaning liquid (34) in this embodiment, other different embodiments are not limited to this, and pure water, HFC, 3-methyl-3-methoxybutanol, or HFC or 3-methyl A mixture of -3-methoxybutanol and water or pure water may be used.

Further, the steam cleaning tank (31) has an opening (37) of the steam cleaning tank (31) so that when the cleaning steam (47) is generated inside, the cleaning steam (47) does not leak out. The upper lid (48) can be sealed. The steam cleaning tank (31) is connected to a cooler (43) that can communicate with the steam cleaning tank (31) through a first on-off valve (40) provided in the recovery pipe (38). A vacuum release valve (42) is connected through (41). A vacuum pump (44) is connected to the cooler (43). Therefore, by sealing the upper lid (48) of the steam cleaning tank (31) and operating the vacuum pump (44), the atmosphere in the steam cleaning tank (31) can be reduced.

A heating pipe (39) and a temperature sensor (36) are provided in the heating bath (46). As shown in FIG. 2, the liquid cleaning bath (32) contains water as a cleaning liquid (34), and an ultrasonic vibrator (45) is fixedly arranged at the bottom.

A cleaning method of this embodiment using the cleaning device (25) having the above configuration will be described below. First, the vacuum release valve (42) and the communication valve (49) are closed in advance, and the first on-off valve (40) is opened. The cleaning solvent (33) in the heating bath (46) is heated by the heating pipe (39) to generate cleaning steam (47). As shown in FIG. 2, the object to be cleaned (51) is placed in the steam cleaning tank (31), and the top cover (48) is placed over the opening (37) of the steam cleaning tank (31). In this state, the vacuum pump (44) is operated to reduce the pressure in the steam cleaning tank (31).

After that, the communication valve (49) is opened to bring the heating tank (46) and the steam cleaning tank (31) into communication with each other, so that the cleaning steam (47) generated in the heating tank (46) is It is sent into the steam cleaning tank (31). In this state, the object to be cleaned (51) is steam cleaned in the steam cleaning tank (31). By this steam cleaning, oil adhering to the object to be cleaned (51) is removed by the cleaning solvent (33), thus completing the first cleaning of the present application. The cleaning steam (47) generated in the steam cleaning tank (31) during this steam cleaning is transferred through the first on-off valve (40) to the cooler (43), where it is cooled and reused as the cleaning solvent (33). be recovered.

After the object to be cleaned (51) in the vapor cleaning tank (31), which has been subjected to the first cleaning as described above, is autothermally dried, liquid cleaning, which is the second cleaning of the present application, is performed. That is, after all the cleaning steam in the steam cleaning bath (31) is transferred to the cooler (43) through the first on-off valve (40), the first on-off valve (40) is closed and the vacuum release valve (42) is opened. By opening the valve, the decompressed state in the steam cleaning tank (31) is released to atmospheric pressure, the upper lid (48) of the steam cleaning tank (31) is opened, and the steam cleaning tank (31) self-heats. Take out the object to be washed after drying. The object (51) to be cleaned is placed above the ultrasonic oscillator (45) in the liquid cleaning tank (32) as shown in FIG. 2, and the object (51) to be cleaned is immersed in the cleaning solution (34). state.

In this state, the ultrasonic vibrator (23) is operated to perform ultrasonic cleaning, and the object to be cleaned (51) is swung up and down by a vertical driving device (not shown). As a result, a physical external force is applied to the object to be cleaned (51) due to the ultrasonic waves and the up-and-down oscillation, so chips, cutting powder, dust, etc. adhering to the object to be cleaned (51) are effectively removed. It becomes possible to

Also, by performing the second cleaning as described above, the cleaning liquid (34) contains chips, cutting chips, dust, etc., which settle to the bottom of the liquid cleaning tank (32) due to their own weight. will be. Also, since most of the oil has been removed from the object to be washed (51) during the first washing, it is in a state where it is hardly mixed with the washing liquid (34). Therefore, the cleaning liquid (34) can be repeatedly reused while stored in the liquid cleaning tank (32) without the need for special equipment to separate the oil.

In this embodiment, as described above, the cleaning solvent (33) is used only for the first cleaning. and the cleaning liquid (34) can be easily reused. Therefore, this embodiment can reduce the load on the global environment, and is a cleaning method that can contribute to the achievement of carbon neutrality.

3 cleaning solvent 4 cleaning liquid 27 object to be cleaned

Claims (8)

After performing the first cleaning for removing the oil adhering to the object to be cleaned by steam cleaning using a cleaning solvent, the object to be cleaned is immersed in a cleaning liquid that does not involve degreasing and the cleaning target is washed in the cleaning liquid. By applying a physical force to the object to perform a second cleaning that removes dirt other than oil, the amount of the cleaning solvent and the cleaning liquid used can be suppressed, and the emission of greenhouse gases can be suppressed. Washing method of washing. After first cleaning to remove oil adhering to the object to be cleaned by vapor cleaning using a cleaning solvent, second cleaning to remove dirt other than oil by applying physical force to the object to be cleaned by air blowing. A method for cleaning an object to be cleaned, wherein the amount of the cleaning solvent 3 and the cleaning liquid 4 to be used can be suppressed, thereby suppressing the emission of greenhouse gases. 3. A method for cleaning an object to be cleaned according to claim 1, wherein said first cleaning includes performing shower cleaning with said cleaning solvent in addition to steam cleaning. 4. A method of cleaning an object to be cleaned according to claim 1, 2 or 3, wherein said cleaning solvent is a petroleum solvent, HFO, a bromine solvent or a chlorine solvent. The cleaning liquid used in the second cleaning is water, pure water, HFC, 3-methyl-3-methoxybutanol, or a mixture of HFC or 3-methyl-3-methoxybutanol and water or pure water. 5. The method for cleaning an object to be cleaned according to claim 1, 2, 3, or 4. 3. A method for cleaning an object to be cleaned according to claim 1 or 2, wherein the contaminants other than oil to be removed in said second cleaning are swarf, cutting swarf or dust. 5. The method for cleaning an object to be cleaned according to claim 1 or 4, wherein the physical force for said second cleaning is ultrasonic waves, vertical oscillation, jet flow, or rotary oscillation. 4. The method for cleaning an object to be cleaned according to claim 1, wherein said first cleaning is carried out under atmospheric pressure or under reduced pressure.

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