JP2011016079A - Cleaning apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cleaning apparatus which can circulate and reuse a cleaning agent with a simple structure.SOLUTION: The cleaning apparatus includes a tank 10 for storing the cleaning agent, a nozzle 13 for injecting the cleaning agent to an object to be cleaned 18, a pump 11 for compressing and discharging the cleaning agent from the tank 10 to the nozzle 13, a heater 12 for heating the cleaning agent highly pressurized by the pump 11, and a cooler 14 for cooling and liquefying the cleaning agent vaporized by being injected from the nozzle 13. As the cleaning agent, a lipophobic cleaning agent which separates oil components is used, and the tank 10 is provided with a discharge port 17 for discharging the oil components from the cleaning agent stored in the tank 10, whereby when the cleaning agent is stored in the tank 10, the oil components rise to the upper layer of the cleaning agent stored in the tank 10, so that the rising oil components can easily be removed from the tank 10 through the discharge port 17.

Description

  The present invention relates to a cleaning apparatus for cleaning an object to be cleaned of precision instruments with a cleaning agent.

  Conventionally, the thing of patent document 1 is known as a washing | cleaning apparatus. That is, this cleaning device includes an outer frame in which a solvent tank and a spray booth are formed. Furthermore, a nozzle that injects high-temperature and high-pressure solvent onto the object to be cleaned at the spray booth, a spray pump that compresses and discharges the solvent in the solvent tank to the nozzle, and heat exchange that heats the solvent compressed by the spray pump A cooling vessel that cools and liquefies the solvent that has become vapor, and a distiller that distills and purifies the solvent in the solvent tank.

  The object to be cleaned attached to the chain conveyor moves in the order of the solvent tank and spray booth. Here, the object to be cleaned advances through the solvent stored in the solvent tank, so that the oils and fats adhering to the object to be cleaned are dissolved, proceed to the spray booth, and further by the high-temperature and high-pressure solvent sprayed by the nozzle. Washed.

  The cleaning agent of such a cleaning device removes the oil component adhering to the object to be cleaned by dissolving action, and in order to clean the object to be cleaned, an oleophilic solvent that dissolves the oil component, for example, on the molecular structure Chlorinated solvents containing chlorine atoms are used.

Japanese Unexamined Patent Publication No. 60-12187

  However, the chlorinated solvent used in the cleaning apparatus described in Patent Document 1 is an oleophilic solvent that dissolves the oil component. Therefore, when the solvent is circulated and reused, the oil component is separated. There is a problem that a distiller to be removed is separately required, and the cleaning apparatus becomes complicated.

  Therefore, in view of the above problems, an object of the present invention is to provide a cleaning device that can be reused by circulating a cleaning agent with a simple structure.

  In order to achieve the above object, the present invention employs the following technical means.

  The invention according to claim 1 includes a removing means (101) for removing the oil component from the object to be cleaned (18) by spraying a cleaning agent toward the object (18) to which the oil component is adhered, and a removing means. In the cleaning device having the cleaning agent sprayed in (101) and the recovery means (102) for recovering the cleaning waste liquid of the oil component removed from the object to be cleaned (18), the cleaning agent separates the oil component. Of the cleaning agent and the oil component, which are made of a material and separated from the oil component in the recovery means (102), a supply means (16a) for supplying the cleaning agent from the recovery means to the removal means (101) is provided. It is said.

  According to this, the cleaning object (18) to which the oil component is adhered can be cleaned using the cleaning agent by the removing means (101), and the cleaning agent can be removed by the recovery means (102) and the supplying means (16a). A cycle to be reused can be configured. Here, since the cleaning agent is a cleaning agent that separates the oil component, the cleaning waste liquid in which the cleaning agent and the oil component are mixed in the recovery means (102) is converted into the cleaning agent and the oil component. To be separated. Then, the supply means (16a) supplies the cleaning agent separated from the cleaning waste liquid collected in the recovery means (102) to the removing means (101) with a simple structure. It is possible to configure a cycle to be reused.

  Moreover, in the invention which concerns on Claim 2, a removal means (101) heats the cleaning agent pressurized by the pressurization part (11) which pressurizes the cleaning agent injected, and a pressurization part (11). It has a heating part (12) and an injection part (13) for injecting a cleaning agent toward the object to be cleaned (18), and the recovery means (102) is injected by the injection part (13). A liquefying part (14) for liquefying the vaporized cleaning agent, and a storage part (10) for storing the cleaning agent liquefied in the liquefying part (14) and the oil component removed from the object to be cleaned (18). The supply means (16a) has a supply port (16a) provided in the storage section (10), and the removal means (101) separated the oil component from the supply port (16a). It is characterized by sucking only the cleaning agent and spraying the cleaning agent toward the object to be cleaned (18).

  According to this, since the cleaning agent sprayed by the spraying section (13) is pressurized by the pressurizing section (11) and heated by the heating section (12), the removing means (101) has a high temperature and high pressure. A cleaning agent can be sprayed. Also, because of the high temperature and high pressure, the cleaning agent sprayed and vaporized by the injection unit (13) is liquefied by the liquefaction unit (14), and the liquefied cleaning agent and the oil removed from the object to be cleaned (18) Since the components are stored in the storage unit (10), the recovery means (102) can recover the cleaning agent and the oil component without releasing the evaporated cleaning agent to the outside. The reservoir (10) is provided with a supply port (16a), and the removing means (101) sucks the cleaning agent from which the oil component has been separated from the supply port (16a), so that the supply means (16a) The cleaning agent can be supplied with a simple structure having the mouth (16a).

  Moreover, in the invention which concerns on Claim 3, the supply port (16a) is opening to the lower part of the storage part (10), It is characterized by the above-mentioned.

  According to this, by using a cleaning agent having a specific gravity greater than that of the oil component, the cleaning agent from which the oil component has been separated out of the cleaning waste liquid stored in the storage unit (10) is the cleaning waste liquid in the storage unit (10). Since it accumulates in the lower part on the bottom side, it becomes possible to easily supply the cleaning agent from which the oil component has been separated to the removing means (101) through the supply port (16a) opening in the lower part of the storage part (10).

  Moreover, in the invention which concerns on Claim 4, the discharge part (17) which discharges the oil component to store is provided in the storage part (10), It is characterized by the above-mentioned.

  According to this, an oil component can be discharged | emitted with the simple structure of providing the discharge port (17) for the oil component stored in a storage part (10).

  Moreover, in the invention which concerns on Claim 5, the discharge port (17) is opening to the upper part of the storage part (10), It is characterized by the above-mentioned.

  According to this, by using a cleaning agent having a specific gravity greater than that of the oil component, out of the cleaning waste liquid stored in the storage unit (10), the oil component separated into the cleaning agent is the cleaning waste liquid in the storage unit (10). Therefore, the oil component separated into the cleaning agent can be easily discharged from the reservoir (10) by the discharge port (17) opening at the upper portion of the reservoir (10). Become.

  Moreover, in the invention which concerns on Claim 6, a liquefying part (14) is located above an injection part (13), and the storage part (10) is located below the injection part (13), It is characterized by the above-mentioned. It is said.

  According to this, the liquefying part (14) can easily liquefy the cleaning agent sprayed from the spraying part (13) and vaporized. Moreover, the storage part (10) can store easily the oil component washed away by the flow rate of the cleaning agent injected from the injection part (13).

  Moreover, in the invention which concerns on Claim 7, the removal means (101) is equipped with the piping (16) through which a cleaning agent distribute | circulates, and a pressurization part (11) and a heating part (12) are provided in piping (16). And both ends of the pipe (16) are connected to the supply port (16a) and the injection section (13).

  According to this, the removing means (101) pressurizes the cleaning agent sucked from the supply port (16a) by the pressurizing unit (11) and heats it by the heating unit (12), 13).

  Moreover, in the invention which concerns on Claim 8, the injection part (13) enables it to inject a cleaning agent continuously toward the to-be-cleaned object (18), It is characterized by the above-mentioned.

  According to this, it is possible to simplify the injection control in the cleaning means (13) without requiring injection control for intermittent injection.

  Further, the invention according to claim 9 is characterized in that the cleaning agent is in a liquid state at atmospheric pressure.

  According to this, since a cleaning agent will be in a liquid state in atmospheric pressure, the storage part (10) can store a cleaning agent easily now.

  In the invention according to claim 10, the heating section (12) is a temperature at which the cleaning agent pressurized by the pressurizing section (11) is in a gaseous state at atmospheric pressure, and the pressurizing section ( It is characterized by being heated to the boiling point temperature or lower during pressurization according to 11).

  According to this, to-be-cleaned object (18) can be wash | cleaned using the washing | cleaning action of both the collision force by injection of an injection part (13), and the collision force by bumping of a cleaning agent.

  The invention according to claim 11 is characterized in that the cleaning agent is a fluorine-based compound.

  According to this, it is possible to use a cleaning agent that hardly dissolves the oil component.

  In addition, the code | symbol in the bracket | parenthesis of each means described in this column and the claim shows the correspondence with the specific means as described in embodiment mentioned later.

It is a schematic block diagram which shows the structure of the washing | cleaning apparatus in 1st Embodiment of this invention. It is a schematic block diagram which shows the structure of the washing | cleaning apparatus in other embodiment.

(First embodiment)
Hereinafter, the structure of the cleaning apparatus 100 according to the first embodiment of the present invention will be described with reference to FIG. FIG. 1 is a schematic configuration diagram illustrating a configuration of a cleaning apparatus 100 according to the present embodiment.

  The cleaning apparatus 100 has a box-shaped frame 20 that extends in the vertical direction. On the top surface located on the upper side of the frame body 20, the object to be cleaned 18 attached to the conveyor 19 is opened to move from the outside to the inside of the frame body 20 while being attached to the conveyor 19, An outlet 22 that is opened to move from the inside of the frame 20 to the outside is formed. The conveyor 19 is a belt-shaped transport device that transports the article to be cleaned 18, and is arranged in a U shape inside the frame body 20. The object to be cleaned 18 is preferably a precision machined part with high machining accuracy, an electronic part, or the like, and examples thereof include an injector, a pump, and a sensor.

  A tank 10 that stores a cleaning agent that cleans an object to be cleaned is formed below the frame body 20. The tank 10 is a container body that stores a predetermined amount of cleaning agent in a liquid state on the bottom side inside the frame body 20. That is, the position of the liquid surface 10a of the cleaning agent stored in the tank 10 is maintained at a constant height. The tank 10 in the present embodiment corresponds to a storage unit in the present invention.

  Further, the cleaning apparatus 100 includes a pump 11, a heater 12, a nozzle 13, and a pipe 16 as a removing unit 101 that removes an oil component from the object to be cleaned 18 by spraying a cleaning agent toward the object to be cleaned 18. Have. The tank 10, the cooler 14, and the water separator 15 are provided as the recovery unit 102 that recovers the cleaning agent sprayed by the removing unit 101 and the oil component removed from the cleaning target 18. .

  The pipe 16 is a pipe member that connects the inside of the tank 10 and the nozzle 13. An intermediate portion of the pipe 16 is exposed to the outside of the frame body 20, while both end portions of the pipe 16 are disposed inside the frame body 20. Inside the pipe 16, the cleaning agent is circulated from below to above. The end of the pipe 16 on the upstream side of the cleaning agent flow is connected to the bottom side of the tank 10, and the end of the pipe 16 on the downstream side of the cleaning agent flow is connected to the center of the frame 20 in the vertical direction.

  The pump 11 is disposed on the upstream side of the cleaning agent flow in the intermediate portion of the pipe 16. The pump 11 is a fluid device that compresses and discharges the bottom side cleaning agent stored in the tank 10 to the nozzle 13. The pump 11 in the present embodiment corresponds to the pressurizing unit of the present invention.

  The heater 12 is disposed on the downstream side of the cleaning agent flow from the pump 11 in the intermediate portion of the pipe 16. The heater 12 is a heat exchanger that heats the cleaning agent pressurized by the pump 11 by exchanging heat between the cleaning agent pressurized by the pump 11 and the heater 12a that is a heating element. The heater 12 in the present embodiment corresponds to the heating unit of the present invention.

  The nozzle 13 is disposed at the end of the pipe 16 on the downstream side of the flow of the cleaning agent, is the center in the vertical direction inside the frame body 20, and is the liquid level 10 a of the cleaning agent stored in the tank 10. Located above. The nozzle 13 is an injection device that continuously injects the cleaning agent pressurized by the pump 11 and heated by the heater 12 toward the object to be cleaned 18. The nozzle 13 is disposed at a position corresponding to the front end of the conveyor 19 that bends in a U-shape, and from above toward the article 18 to be cleaned attached to the upper side of the conveyor 19 at the U-shaped front end of the conveyor 19. It arrange | positions so that a washing | cleaning agent can be injected below. The nozzle 13 in the present embodiment corresponds to an injection unit in the present invention.

  The pipe 16 is provided with a filter (not shown). The filter is a member having a mesh structure that blocks dust and the like attached to the object to be cleaned 18 and allows only the cleaning agent to pass therethrough.

  The nozzle 13 injects a cleaning agent to form a saturated cleaning agent gas layer A at the center in the vertical direction inside the frame body 20. The saturated cleaning agent gas layer A is a space where the cleaning agent exists in a saturated vapor state, and extends in layers from the surface of the cleaning agent stored in the tank 10 to above the nozzle 13.

  The cooler 14 is disposed on the upper side of the frame 20 and above the nozzle 13, and is located on the uppermost side of the saturated cleaning agent gas layer A. The cooler 14 is a heat exchanger that cools the air inside the frame 20 by exchanging heat between the air inside the frame 20 and the cooling fluid that flows through the cooler 14. The cooler 14 has a structure in which a pipe member through which a cooling fluid flows is wound annularly along the inner wall surface of the frame body 20. When the cooling fluid flows through the cooler 14, the cooler 14 cools the internal air of the frame body 20 to cool and liquefy the water vapor contained in the internal air of the frame body 20. The cleaning agent sprayed from the nozzle 13 in the agent gas layer A and converted into vapor is cooled and liquefied, and the cleaning agent is collected in the tank 10. The cooler 14 in the present embodiment corresponds to a liquefaction unit of the present invention.

  The cooler 14 has a tray 14 a that extends from the inner wall surface of the frame body 20 to the inside of the frame body 20. The saucer 14 a has an annular vessel shape and is disposed below the cooler 14. The cleaning agent liquefied by the cooler 14 travels along the inner wall surface of the frame 20 and the outer peripheral surface of the cooler 14 due to its own weight, and collects in the tray 14 a below the cooler 14.

  The moisture separator 15 is disposed outside the frame body 20. The water separator 15 is a separator that separates the cleaning agent collected in the tray 14 a and the water by specific gravity and supplies the cleaning agent from which water has been removed to the tank 10.

  The cleaning agent in the present embodiment is a cleaning agent whose boiling point changes remarkably between atmospheric pressure and the time of pressurization by the pump 11, and does not contain chlorine atoms in the molecular structure, and is a sparse agent that separates oil components. An oily inert cleaning agent is used. Specifically, a fluorine compound hydrofluorocarbon (HFC) is used as the cleaning agent. Here, the fact that the boiling point changes significantly between the atmospheric pressure and the time of pressurization by the pump 11 is a change in which the boiling point rises by 10 degrees or more when pressurized by 0.1 MPa (megapascal).

  The inside of the frame 20 is at atmospheric pressure, and the hydrofluorocarbon cleaning agent is stored in the tank 10 in a liquid state. Further, the hydrofluorocarbon cleaning agent pressurized by the pump 11 and heated by the heater 12 and sprayed from the nozzle 13 is in a pressurized overheated liquid state in a high temperature / high pressure liquid state.

  Moreover, since the hydrofluorocarbon cleaning agent is an oleophobic cleaning agent, the separated oil component having a specific gravity smaller than that of the cleaning agent is floated in the cleaning waste liquid that is stored in the tank 10, and the liquid level of the tank 10 is increased. An oil component layer 10b is formed on 10a. Therefore, the tank 10 in the present embodiment includes a discharge port 17 that discharges the oil component from the oil component layer 10b that is separated from the cleaning agent stored in the tank 10 and spreads in layers on the liquid surface 10a of the cleaning agent.

  A discharge pipe 17 a that is a pipe member is inserted into the discharge port 17. One end of the discharge pipe 17a extends to a position away from the inner wall surface of the tank 10 and opens into the oil component layer 10b. The discharge pipe 17a is provided with a valve 17b that opens and closes the flow path of the oil component flowing through the discharge pipe 17a.

  On the other hand, on the bottom side of the tank 10, a cleaning agent that does not contain an oil component is stored. Therefore, in the present embodiment, a supply port 16a that opens into the cleaning agent stored on the bottom side is provided at the bottom of the tank 10 on the bottom side. The supply port 16a is connected to the upstream end of the pipe 16 in the cleaning agent flow direction. The supply port 16 a is provided, for example, so as to open on the bottom surface of the tank 10. The supply port 16 in the present embodiment corresponds to the supply means in the present invention.

  Next, the operation of the cleaning apparatus 100 in the present embodiment will be described. The object to be cleaned 18 attached to the conveyor 19 first passes through an inlet 21 formed in the frame body 20, and then is saturated and positioned at the center in the vertical direction of the frame body 20 through the space above the frame body 20. It enters into the agent gas layer A. Then, at the tip of the conveyor 19 that bends in a U-shape, a cleaning agent in a high-temperature / high-pressure pressurized overheated liquid state is sprayed from the nozzle 13 toward the object to be cleaned 18. The object to be cleaned 18 from which the cleaning agent is injected from the nozzle 13 is not dissolved by the collision force generated by the injection of the nozzle 13 and the collision force generated by the bumping of the cleaning agent. Removed in a short time.

  Here, the collision force caused by the injection of the nozzle 13 is the kinetic energy of the cleaning agent that is injected from the nozzle 13 at a high speed and collides with the object to be cleaned 18, and the oil component adhering to the object to be cleaned 18 is Washed out with cleaning agent sprayed at high speed. The impact force caused by bumping of the cleaning agent is the physical energy due to the change in the state in which the cleaning agent in the pressurized superheated liquid state at a high temperature and high pressure is injected into the atmospheric pressure and bumps into the boiling point. Due to the movement of the agent vapor, the oil component in the minute gap is washed away together with the bumping detergent vapor. Therefore, the cleaning apparatus 100 in this embodiment does not use a chemical cleaning action in the cleaning action. The scientific cleaning action is, for example, an action in which an oil component is dissolved in a cleaning agent and cleaned.

  The object 18 to which the cleaning agent is sprayed from the nozzle 13 passes through the end of the conveyor 19 that is cleaned and bends in a U shape. Since the cleaning agent is vaporized immediately after being jetted from the nozzle 13 or after colliding with the object to be cleaned 18, the object to be cleaned 18 that has passed through the front end of the conveyor 19 is sufficiently dry. And the to-be-cleaned object 18 advances from the saturated cleaning agent gas layer A, passes through the outlet 22 formed in the frame body 20 through the space above the frame body 20, and the cleaning process by the cleaning device 100 is completed. To do.

  On the other hand, the vaporized cleaning agent is cooled and liquefied by the cooler 14 located above the nozzle 13 together with water vapor in the air. The liquefied cleaning agent and moisture gather in the receiving tray 14a, and the cleaning agent from which moisture has been removed by the moisture separator 15 is stored in the tank 10.

  The oil component washed away from the article to be cleaned 18 by the cleaning agent is washed away by the oil component vaporized by the heat received from the cleaning agent and the jetting force of the nozzle 13, and the tank 10 located below the nozzle 13. The vaporized oil component also liquefies and falls to the tank 10 because the temperature of the vaporized oil component decreases as it approaches the cooler 14. As a result, cleaning waste liquid of the cleaning agent from which moisture has been removed and the oil component removed from the object to be cleaned 18 is stored in the tank 10.

  And since the washing | cleaning waste liquid stored in the tank 10 uses the cleaning agent which isolate | separates an oil component, it isolate | separates into an oil component and a cleaning agent. In the present embodiment, since a cleaning agent having a specific gravity greater than that of the oil component is used, the oil component forms the oil component layer 10b at the top of the cleaning waste liquid, and the cleaning agent is the bottom side of the cleaning waste liquid. Accumulate at the bottom of the. And the cleaning agent which isolate | separated the oil component is attracted | sucked by the piping 16 by the supply port 16a opened to the lower part of the bottom side of the tank 10, and is reused.

  In the cleaning apparatus 100 according to this embodiment, hydrofluorocarbon of a fluorine compound is used as a cleaning agent. Therefore, since the harmfulness is low as compared with the chlorinated solvent, the safety in using the cleaning agent can be ensured.

  Moreover, the cleaning agent sprayed from the nozzle 13 in the present embodiment is sprayed into the atmospheric pressure in a pressurized overheating state that is higher than the boiling point in the atmospheric pressure. As a result, the object to be cleaned 18 can be cleaned using the cleaning action of both the collision force caused by the injection of the nozzle 13 and the collision caused by bumping of the cleaning agent. Further, since the cleaning agent sprayed from the nozzle 13 is immediately vaporized, there is no need for a drying process for drying the cleaning object 18 separately from the cleaning process for cleaning the cleaning object 18, and the cleaning apparatus 100 can be downsized. Therefore, simplification can be achieved.

  Further, as the cleaning agent in the present embodiment, an inert cleaning agent that is in a liquid state at atmospheric pressure is used. Therefore, the cleaning agent can be easily stored in the tank 10. Also. The cleaning agent in this embodiment is an oleophobic cleaning agent. Therefore, the oil component removed from the cleaning object 18 in the tank 10 under atmospheric pressure is separated from the cleaning agent in the tank 10 to form the oil component layer 10b on the liquid surface 10a. The oil component can be easily removed from the tank 10 by opening the oil component layer 10b. Therefore, when a lipophilic solvent such as a chlorinated solvent is used, a recirculation device for reusing the cleaning agent such as a distiller that removes the oil component dissolved in the cleaning agent is not required, and the cleaning device 100 It becomes possible to achieve miniaturization and simplification.

  Further, the nozzle 13 in the present embodiment continuously injects the cleaning agent. Therefore, when a lipophilic solvent such as a chlorinated solvent is used, it is not necessary to perform the injection control for intermittently injecting the cleaning agent from the nozzle 13 in order to reduce the load on the recirculation device. It is possible to simplify the injection control.

  Further, as a case where a chlorine-based solvent is not used as a cleaning agent for a cleaning apparatus, it is conceivable that water vapor is used. However, when water vapor is used, drying cannot be performed sufficiently and a large amount of heating energy is required. There are problems such as the point that the electronic parts are easily corroded and the necessity of ancillary equipment for condensate treatment. However, since the cleaning agent in this embodiment has a lower latent heat of vaporization than water, it has good drying properties. Moreover, since specific heat is smaller than water, it can heat easily and can reduce the consumption of heating energy. In addition, no recirculation equipment such as incidental equipment for condensate treatment is required. As a result, the cleaning device 100 can be reduced in size and simplified even when compared with the case where water vapor is used as the cleaning agent of the cleaning device.

(Other embodiments)
In the first embodiment, the cleaning device 100 includes the box-shaped frame 20 that extends in the vertical direction. However, the present invention is not limited to this, and the cleaning device has a plurality of box-shaped frames, and has a plurality of box-shaped frames, and has a storage section and a reservoir. The part may be a separate body.

  In the first embodiment, an inlet 21 and an outlet 22 are formed on the top surface of the frame body 20. However, the present invention is not limited to this. For example, the object to be cleaned 18 attached to the conveyor on the top surface of the frame body is attached to the conveyor from the outside to the inside, and An entrance for moving from the inside to the outside may be provided.

  In the first embodiment, the intermediate portion of the pipe 16 is exposed to the outside of the frame body 20. However, the present invention is not limited to this, and an intermediate portion of the pipe 16 is disposed inside the frame body 20, and a pump and a heater disposed in the intermediate portion of the pipe 16 are provided in a frame. The structure accommodated in the pump chamber formed in the inside of a body may be sufficient.

  In the first embodiment, the nozzle 13 continuously injects the cleaning agent. However, the present invention is not limited to this, and the nozzle may be controlled to intermittently inject the cleaning agent.

  Moreover, in the said 1st Embodiment, the nozzle 13 is 1 in the position which can inject a cleaning agent from the upper direction toward the to-be-cleaned object 18 attached to the upper side of the conveyor 19 in the U-shaped front-end | tip of the conveyor 19. One is arranged. However, the present invention is not limited to this, and the nozzle may be arranged at a position for injecting the cleaning agent in the horizontal direction, and the nozzle for injecting the cleaning agent has a shape of an object to be cleaned. Depending on the shape of the conveyor, a plurality may be provided.

  In the first embodiment, hydrofluorocarbon is used as the cleaning agent. However, the present invention is not limited to this, and may be, for example, a hydrofluoroether (HFE), perfluorocarbon (PFC), or perfluoroamine of a fluorine compound. A cleaning agent whose boiling point changes significantly between atmospheric pressure and pressure applied by a pump, does not contain chlorine atoms due to its molecular structure, has high oleophobicity, and is inactive in a liquid state at atmospheric pressure A cleaning agent is preferred.

  In the first embodiment, the cleaning agent sprayed from the nozzle 13 is a cleaning agent in a liquid state pressurized by the pump 11 and heated by the heater 12. However, the present invention is not limited to this, and at the time of pressurization by the pump, it is further heated by a heater up to the boiling point or more at the time of pressurization, and the cleaning agent is jetted from the nozzle in a gaseous state. Also good.

  In the first embodiment, the supply port 16 a is provided in the lower part on the bottom side of the tank 10, and the discharge port 17 is provided at a height located in the upper layer portion of the cleaning waste liquid stored in the tank 10. Yes. However, the present invention is not limited to this. For example, when a cleaning agent that is oleophobic and has a specific gravity lower than that of the oil component is used, the supply port is cleaned in a tank. It is provided at a height located in the upper layer part of the waste liquid, and the discharge port is provided in the lower part on the bottom side of the tank.

  In the first embodiment, the removing unit 101 includes the heater 12, and the recovery unit 102 includes the cooler 14. However, the present invention is not limited to this, and for example, the cleaning agent may be sprayed from the nozzle to the object to be cleaned in the liquid state without using the heater and the cooler. In this case, the cleaning action is a cleaning action due to the collision force of the injection by the nozzle, and the cleaning agent after the injection falls toward the tank.

  In the first embodiment, the supply port 16 a is provided so as to open to the bottom surface of the tank 10. However, the present invention is not limited to this, and the supply port may be provided at a predetermined height position from the bottom surface of the tank. The predetermined height is preferably equal to or higher than the accumulation height at which dust adhered to the object to be cleaned accumulates on the bottom surface of the tank.

  Moreover, in the said 1st Embodiment, the to-be-cleaned object 18 is attached to the conveyor 19, and is moving. However, the present invention is not limited to this, and as shown in FIG. 2, a plurality of objects to be cleaned are accommodated in a box-shaped cleaning basket 219, and from above the frame body 220 to the upper side of the frame body 220. The cleaning object may be cleaned by allowing the cleaning basket 219 to enter the inside of the frame body 220 through the opening 221 formed in FIG. FIG. 2 is a schematic configuration diagram illustrating a configuration of a cleaning apparatus 200 according to another embodiment. According to this, a plurality of objects to be cleaned accommodated in the cleaning basket 219 can be cleaned together.

  DESCRIPTION OF SYMBOLS 10 ... Tank (storage part, collection | recovery means), 10a ... Liquid level, 10b ... Oil component layer, 11 ... Pump (pressurization part, removal means), 12 ... Heater (heating part, removal means), 13 ... Nozzle ( Injection unit, removal unit), 14 ... cooler (liquefaction unit, recovery unit), 15 ... moisture separator, 16 ... pipe (removal unit), 16a ... supply port (supply unit), 17 ... discharge port, 18 ... covered Cleaning object, 19 ... conveyor, 20, 220 ... frame.

Claims (11)

Removing means (101) for removing the oil component from the object to be cleaned (18) by spraying a cleaning agent toward the object (18) to which the oil component is adhered;
In the cleaning apparatus comprising: the cleaning agent sprayed by the removing means (101) and the recovery means (102) for recovering the cleaning waste liquid of the oil component removed from the object to be cleaned (18),
The cleaning agent is made of a material that separates the oil component,
Supply means (16a) for supplying the cleaning agent from the recovery means to the removal means (101) out of the cleaning agent and the oil component separated from the oil component in the recovery means (102). A cleaning apparatus characterized by that. The removing means (101) includes a pressurizing part (11) for pressurizing the sprayed cleaning agent,
A heating unit (12) for heating the cleaning agent pressurized by the pressurizing unit (11);
An injection part (13) for injecting the cleaning agent toward the object to be cleaned (18),
The recovery means (102) includes a liquefaction unit (14) for liquefying the cleaning agent sprayed and vaporized by the spray unit (13).
The cleaning part liquefied in the liquefaction part (14), and a storage part (10) for storing the oil component removed from the object to be cleaned (18),
The supply means (16a) has a supply port (16a) provided in the reservoir (10),
The removing means (101) sucks only the cleaning agent from which the oil component has been separated from the supply port (16a) and injects the cleaning agent toward the object to be cleaned (18). The cleaning apparatus according to claim 1.   The cleaning apparatus according to claim 2, wherein the supply port (16a) opens at a lower portion of the storage section (10).   The cleaning device according to claim 2 or 3, wherein the storage part (10) is provided with a discharge port (17) for discharging the stored oil component.   The cleaning apparatus according to claim 4, wherein the discharge port (17) is opened at an upper portion of the storage portion (10). The liquefaction part (14) is located above the injection part (13),
The cleaning device according to any one of claims 2 to 5, wherein the storage part (10) is located below the injection part (13). The removing means (101) includes a pipe (16) through which the cleaning agent flows,
In the pipe (16), the pressurizing part (11) and the heating part (12) are arranged,
The both ends of the said pipe (16) are connected to the said supply port (16a) and the said injection part (13), The washing | cleaning apparatus as described in any one of Claim 2 thru | or 6 characterized by the above-mentioned.   The cleaning device according to any one of claims 2 to 7, wherein the spray unit (13) can continuously spray the cleaning agent toward the object to be cleaned (18).   The cleaning apparatus according to claim 2, wherein the cleaning agent is in a liquid state at atmospheric pressure.   The heating unit (12) is a temperature at which the cleaning agent pressurized by the pressurizing unit (11) is in a gaseous state at atmospheric pressure, and is pressurized by the pressurizing unit (11). The cleaning apparatus according to claim 2, wherein the cleaning apparatus is heated to a temperature equal to or lower than a boiling point temperature.   The cleaning apparatus according to claim 2, wherein the cleaning agent is a fluorine-based compound.

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