Dry cleaning device and dry cleaning method

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram of a dry cleaning device according to a first embodiment of the present invention;

FIGS. 2A and 2B are schematic diagrams for explaining a process of removing dust from a cleaning target object shown in FIG. 1 by a flake-shaped cleaning medium;

FIGS. 3A and 3B are cross sections of a cleaning tank shown in FIG. 1;

FIG. 4 is a cross section of a circulation-air generating unit shown in FIG. 1;

FIGS. 5A and 5B are schematic diagrams of a cleaning-medium recycle unit shown in FIG. 1;

FIG. 6 is a block diagram of a drive control unit of the dry cleaning device shown in FIG. 1;

FIGS. 7A and 7B are block diagrams of a driving unit of the dry cleaning device shown in FIG. 1;

FIG. 8 is a timechart of a cleaning operation performed by the dry cleaning device shown in FIG. 1;

FIGS. 9A to 9C are schematic diagrams for explaining a state of delivery, by circulation air, of cleaning media accumulated on the cleaning-medium recycle unit shown in FIG. 1;

FIGS. 10A to 10C are schematic diagrams for explaining another state of delivery, by circulation air, of cleaning media accumulated on the cleaning-medium recycle unit shown in FIG. 1;

FIGS. 11A to 11C are schematic diagrams for explaining a process of cleaning a cleaning target object shown in FIG. 1;

FIG. 12 is a schematic diagram for explaining collision of a cleaning medium with a cleaning target object by air output from an acceleration nozzle of a cleaning-medium accelerating unit shown in FIG. 1;

FIGS. 13A to 13D are schematic diagrams of internal surfaces with circulation paths for circulating air in the cleaning tank shown in FIG. 1;

FIGS. 14A and 14B are cross sections of the cleaning tank with air rectifying unit on the circulation paths shown in FIGS. 13A to 13D;

FIGS. 15A and 15B are cross sections of the cleaning tank with an inclined surface according to the first embodiment;

FIG. 16 is a schematic diagram of a dry cleaning device according to a second embodiment of the present invention;

FIG. 17 is a block diagram of a drive control unit of the dry cleaning device shown in FIG. 16;

FIG. 18 is a block diagram of a driving unit of the dry cleaning device shown in FIG. 16;

FIG. 19 is a schematic diagram of a dry cleaning device according to a third embodiment of the present invention;

FIG. 20 is a block diagram of a drive control unit of the dry cleaning device shown in FIG. 19;

FIG. 21 is a block diagram of a driving unit of the dry cleaning device shown in FIG. 19;

FIG. 22 is a schematic diagram for explaining a state of colliding a cleaning medium with a cleaning target object in the dry cleaning device shown in FIG. 19;

FIG. 23 is a timechart of a cleaning operation including a rough cleaning and a shake-off operation according to the third embodiment;

FIGS. 24A and 24B are schematic diagrams of a dry cleaning device according to a fourth embodiment of the present invention;

FIG. 25 is a schematic diagram of a dry cleaning device including a medium-amount measuring unit and a cleaning-target detecting unit according to a fifth embodiment of the present invention;

FIG. 26 is a schematic diagram of a photoelectronic sensor constituting the medium-amount measuring unit shown in FIG. 25;

FIG. 27 is a block diagram of a drive control unit of the dry cleaning device shown in FIG. 25;

FIG. 28 is a timechart of an operation performed by the dry cleaning device shown in FIG. 25; and

FIG. 29 is a schematic diagram of a dry cleaning device according to a sixth embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Exemplary embodiments of the present invention are explained in detail below with reference to the accompanying drawings.

FIG. 1 is a schematic diagram of a dry cleaning device 1 according to a first embodiment of the present invention. The dry cleaning device 1 removes various dusts 3, such as toner, attached to a cleaning target object 2 by using a cleaning medium 4 flown by high-velocity air as shown in FIG. 2. The dry cleaning device 1 includes a cleaning tank 5, a circulation-air generating unit 6, a cleaning-medium accelerating unit 7, and a cleaning-medium recycle unit 8.

The cleaning medium 4 used in the dry cleaning device 1 can be formed in one of granular shape, stick shape, tubular shape, fibriform, flaked shape, and the like, which is made of one of metals, ceramics, synthetic resin, sponge, fabric, and the like. A shape and material of the cleaning medium 4 can be determined depending on characteristics of a shape and material of the cleaning target object 2 or a particle size or attachment strength of the dust 3 attached to the cleaning target object 2. As for the cleaning medium 4 in a flaked shape, a preferable size is such that its area is in a range between 1 square millimeter (mm²) and 1000 mm², and its thickness is in a range between 1 micrometer (μm) and 500 μm. For example, for removing, from a component made of synthetic resin or metal, toner particle having an average diameter of 5 μm to 10 μm, which is used for an electrophotographic image forming apparatus, it is preferable to use the cleaning medium 4 made of resin film, paper, or metal flake, in a flaked-shape.

When the cleaning medium 4 is in a flaked shape, when the cleaning medium 4 collides with the cleaning target object 2 at an edge portion of the cleaning medium 4, contact force is concentrated on the edge portion, enabling the cleaning medium 4 to obtain force necessary for removing the dust 3 even though mass of the cleaning medium 4 is small. Because the cleaning medium 4 gets bent and loses applied force when the contact force to the cleaning target object 2 increases, unwanted extra force is not applied to the cleaning target object 2. Accordingly, the cleaning target object 2 hardly gets damaged unlike a general blast shot material or an abrasive for barell finishing. Furthermore, inelastic collision occurs between the flaked-shaped cleaning medium 4 and the cleaning target object 2 largely due to viscous drag of air applied when the cleaning medium 4 is bent caused by collision with the cleaning target object 2. Therefore, the cleaning medium 4 is hardly bounced. When oblique collision occurs between the cleaning medium 4 and the cleaning target object 2, the cleaning medium 4 slides across a surface of the cleaning target object 2, contacting a wide area of the surface by a single collision. Due to scratching action or scrubbing action caused by the contact, a parallel force is applied to a contact surface of the dust 3 attached to the cleaning target object 2. As a result, it is possible to remove the dust 3 from the cleaning target object 2 with small force, increasing cleaning efficiency.

The cleaning tank 5 is formed in substantially rectangular solid with a hollow body, and includes a cleaning-target loading port 9 on its top surface for loading the cleaning target object 2, an opening portion on its bottom portion, a cover 10, which can be flexibly opened and closed, on the cleaning-target loading port 9, and the cleaning-medium recycle unit 8 at an opening portion of its bottom portion. On a portion of an internal surface of one side surface of the cleaning tank 5, the circulation-air generating unit 6 is arranged as shown in FIG. 3, forming a circulation path of circulation air on internal surfaces of both side surfaces, the bottom surface, and the top surface of the cleaning tank 5. Each of corner portions of the internal surfaces constituting the circulation path is formed in R shape as shown in FIG. 3A, or with a predetermined angle θ between each of the side surfaces, the top surface, and the bottom surface as shown in FIG. 3B, so that circulation air can be effectively circulated. The predetermined angle θ is preferably determined between 120° and 150° for circulating the circulation air with less resistance.

As described above, each of the corner portions of the internal surfaces with the circulation path is formed in a circular shape or with a predetermined angle between each of adjacent side surfaces. Therefore, the cleaning medium can be delivered without colliding with the internal surfaces. As a result, it is possible to effectively deliver the cleaning medium, increasing cleaning efficiency, and to deliver the cleaning medium with less air supplied, realizing energy saving.

The circulation-air generating unit 6 includes an inlet portion 62 having an inlet opening 61 with a large diameter, and an outlet portion 64 having a compressed-air supply opening 63 arranged on a periphery of an outlet side of the inlet portion 62. The circulation-air generating unit 6 inlets air from the inlet portion 62 by high-velocity airflow supplied from the compressed-air supply opening 63 generated toward an outlet opening 65 of the outlet portion 64, and outlets air with amount of several times to dozens of times of amount of compressed air supplied from the compressed-air supply opening 63. By using the circulation-air generating unit 6, it is possible to circulate the cleaning medium with less energy, reducing amount of the compressed air to be consumed, compared to a case using a general air-blow nozzle. Furthermore, it is possible to easily maintain negative pressure inside the cleaning tank 5 and to prevent leakage of the dusts outside the cleaning tank 5. Various gasses, such as nitride gas, carbon dioxide gas, inactive gas including argon gas, instead of the compressed air, can be supplied from the compressed-air supply opening 63. In the embodiments described below, cases employing the compressed air are explained. The circulation-air generating unit 6 is arranged on a side surface constituting the circulation path near the bottom portion of the cleaning tank 5, with the inlet opening 61 side up while the outlet opening 65 side down.

The cleaning-medium accelerating unit 7 includes a plurality of acceleration nozzles 71a arrayed on a front surface orthogonal to an internal surface constituting the circulation path, and a plurality of acceleration nozzles 71b arrayed on a back surface facing the front surface with the acceleration nozzles 71a arranged. The cleaning-medium accelerating unit 7 blowouts compressed air supplied from a compressed-air source, such as a compressor and a compression tank, inside the cleaning tank 5 via each of the acceleration nozzles 71a and 71b to cause the cleaning medium 4 to collide with the cleaning target object 2. It is preferable to use a blowout nozzle, like the circulation-air generating unit 6, for the acceleration nozzles 71a and 71b.

With the cleaning-medium accelerating unit 7 arranged on a surface orthogonal to the surface constituting the circulation path of the circulation air inside the cleaning tank, and with the nozzle of the cleaning-medium accelerating unit 7 embedded inside the surface of the cleaning tank, it is possible to avoid interference in circulation of the circulation air and effectively cause the cleaning medium to collide with the cleaning target object.

The cleaning-medium recycle unit 8 includes a separation member 81 and a hood 82 arranged on an internal surface of the bottom portion of the cleaning tank 5, forming a closed space as shown in a perspective view of FIG. 5A and a partial cross section of FIG. 5B. The closed space is connected to a dust collector (not shown) including a negative-pressure generating source via a suction tube 11, such as a hose, to generate negative pressure in the hood 82. The separation member 81 includes a plurality of small poles and slits 83 in a size through which air and particles can pass while the cleaning medium 4 cannot pass, and are made of porous member, such as metal, plastic mesh, mesh, punched metal plate, and slit plate. With this configuration, the separation member 81 removes dust removed from the cleaning target object 2, and eliminates the cleaning medium 4 worn and chipped by collision with the cleaning target object 2, or the cleaning medium 4 with degraded elasticity due to long-term use.

As described above, dust and the like attached to the cleaning medium is removed by adsorption by the cleaning-medium recycle unit, so that it is possible to maintain a cleanness of the cleaning medium. Therefore, it is possible to maintain high quality in cleaning, and the cleaning medium can be used repeatedly, resulting in realizing a cleaning with low environmental burdens.

By arranging the cleaning-medium recycle unit at the bottom portion of the cleaning tank, it is possible to increase possibility that the cleaning medium, which has been fallen down the bottom portion of the cleaning tank by gravitation, passes through the cleaning-medium recycle unit, increasing efficiency of recycling the cleaning medium. As a result, the cleanness of the cleaning medium can be improved, improving quality in cleaning.

A controller 12 of the dry cleaning device 1 includes an air-circulation solenoid valve 14, an acceleration solenoid valve 15, an acceleration-switching control valve 16, and a recycling solenoid valve 17, which are connected to the controller 12 with one another, and controls each of the solenoid valves by a drive signal from a driving unit 13, as shown in a block diagram of FIG. 6 and pipeline diagrams shown in FIGS. 7A and 7B. The air-circulation solenoid valve 14 performs conduction and non-conduction of an air pipe for supplying compressed air from a compressed-air supplying device 18 to the circulation-air generating unit 6. The acceleration solenoid valve 15 performs conduction and non-conduction of an air pipe for supplying compressed air to the cleaning-medium accelerating unit 7. The acceleration-switching control valve 16 switches directions of flow of compressed air to be supplied to the acceleration nozzles 71a and 71b respectively arranged on side surfaces of the cleaning-medium accelerating unit 7. The recycling solenoid valve 17 performs conduction and non-conduction of the suction tube 11 connecting the cleaning-medium recycle unit 8 to a dust collector 19.

An operation is explained below with reference to a timechart shown in FIG. 8, of removing the dust 3 attached to the cleaning target object 2 by loading the cleaning target object 2 held by a work holding unit 20 into the cleaning tank 5 by a work moving unit 21 in the dry cleaning device 1.

As descried above, the circulation-air generating unit generates the circulation air that flows along the surface of the cleaning medium accumulated on the cleaning-medium recycle unit. Therefore, it is possible to apply large force for flowing up the accumulated cleaning medium to a large amount of the cleaning media, and circulate the cleaning medium along the internal surfaces of the cleaning tank. As a result, cleaning efficiency can be improved.

In other words, by flowing the circulation air generated by the circulation-air generating unit along the cleaning-medium recycle unit, it is possible to assuredly remove, from the cleaning-medium recycle unit, the cleaning medium stuck to the cleaning-medium recycle unit, and deliver the cleaning medium in the cleaning tank. Furthermore, it is possible to maintain performance of the cleaning-medium recycle unit, of recycling the cleaning medium.

Moreover, by generating the circulation air from the circulation-air generating unit along the longitudinal direction of the cleaning tank, the circulation air is not dispersed and its force is not lost upon flowing. Therefore, it is possible to effectively apply the force of the circulation air to the cleaning medium accumulated on the bottom portion of the cleaning tank. Furthermore, it is possible to deliver and flow up the cleaning medium even with small number of the circulation-air generating units and small amount of air supplied to the circulation-air generating unit. As a result, it is possible to suppress amount of energy necessary for cleaning.

For delivering and flowing up the accumulated flaked-shaped cleaning medium 4 by air as described above, when the air is applied in a direction orthogonal to a longitudinal direction of the accumulated cleaning medium 4 by a nozzle 22 to the flaked-shaped cleaning medium 4 accumulated on the separation member 81 as shown in FIG. 10A, it is necessary to supply compressed air with energy sufficient for flowing up entire portion of the cleaning medium 4 where the compressed air is applied. Accordingly, as shown in FIG. 10B, it becomes difficult to flow the cleaning medium 4 as accumulation amount of the cleaning medium 4 increases. In addition, although it is possible to flow up the cleaning medium 4 accumulated on a portion right over the nozzle 22 that outputs air, because flowability of the accumulated flaked-shaped cleaning medium 4 is low, it is difficult to flow up entire portion of the accumulated cleaning medium 4 even when the separation member 81 is inclined toward the nozzle 22 as shown in FIG. 10C. As a result, the cleaning medium accumulated on a portion around the nozzle 22 is left without being flown up. On the contrary, when air is applied from a longitudinal direction of the cleaning medium 4 accumulated on the separation member 81 by generating, by the circulation-air generating unit 6, circulation air that flows along the circulation path on the internal surface of the cleaning tank 5, it is possible to assuredly flow up the cleaning medium 4 with less energy. As a result, it is possible to reduce consumption of the amount of compressed air supplied to the circulation-air generating unit 6. If the cleaning medium 4 is delivered by air using a duct or a hose, the cleaning medium 4 may be clogged in the duct or the hose. However, the circulation path of the circulation air is formed on the internal surfaces of the cleaning tank 5 in the first embodiment, it is possible to avoid clogging the cleaning medium 4 in the circulation path, resulting in flowing up the cleaning medium 4 in the cleaning tank 5.

According to the embodiments, circulation air for delivering and flowing up the flaked-shaped flexible cleaning medium flows along the internal surfaces of the cleaning tank, so that the circulation air is not dispersed and its force is not lost. Therefore, it is possible to effectively apply force of the circulation air to the cleaning medium accumulated on the cleaning tank, delivering and flowing up a large amount of the cleaning media with less amount of air supplied. As a result, energy consumption necessary for cleaning can be suppressed. Furthermore, even when once-removed dust is re-attached to the internal surfaces of the cleaning tank, the internal surfaces can be continuously cleaned because a large amount of the cleaning media is circulating. Therefore, it is possible to reduce operations in maintenance, such as cleaning, of the cleaning tank.

The circulation-air generating unit 6 that generates circulation air is arranged with the inlet opening 61 side up and the outlet opening 65 side down, around the bottom portion of a side surface constituting the circulation path in the cleaning tank 5. Therefore, it is possible to apply air with strong force to the cleaning medium 4 accumulated on the separation member 81 on the bottom portion of the cleaning tank 5, along a bottom surface of the cleaning tank 5. As a result, it is possible to deliver the cleaning medium 4 along the internal surfaces of the cleaning tank 5 to an area away from the outlet opening 65. In addition, the cleaning media 4 introduced into the inlet opening 61 are dispersed, reducing space density. Therefore, the cleaning medium 4 hardly clogs the inlet opening 61, resulting in stably generating the circulation air. In other words, when the inlet opening 61 is arranged around the bottom portion of the cleaning tank with its opening side down, the force of suction air is exclusively applied to the cleaning medium 4 around the inlet opening 61. Therefore, it is difficult to deliver large amounts of the cleaning media 4 accumulated on the bottom portion of the cleaning tank 5. In addition, when large amounts of the accumulated cleaning media 4 are adsorbed by the inlet opening 61, space density in the inlet opening 61 increases by the cleaning media 4. Therefore, the inlet opening 61 is clogged. However, with the configuration described in the first embodiment, it is possible to avoid such problems.

The controller 12 closes the air-circulation solenoid valve 14 when a predetermined time elapsed, and causes the circulation-air generating unit 6 to stop generating the circulation air. Subsequently, the controller 12 causes the work moving unit 21 to move down the cleaning target object 2 from the initial position, opens the acceleration solenoid valve 15 to supply compressed air to the cleaning-medium accelerating unit 7 via the acceleration-switching control valve 16, so that compressed air is blown out from the acceleration nozzle 71a of the cleaning-medium accelerating unit 7. The controller 12 opens the recycling solenoid valve 17 to conduct the cleaning-medium recycle unit 8 to the dust collector 19, and generates negative pressure in the hood 82. When the circulation air generated by the circulation-air generating unit 6 is stopped, the cleaning medium 4 flown by the circulation air is fallen down. The falling down cleaning medium 4 is caused to collide with the cleaning target object 2 by the compressed air blown from the acceleration nozzle 71a, removing the dust 3 attached to a surface of the cleaning target object 2.

The dust 3 removed from the cleaning target object 2 and the cleaning medium 4 with the dust attached due to collision with the cleaning target object 2 are fallen by gravity, and accumulated on the separation member 81 of the cleaning-medium recycle unit 8 that is vacuuming air due to the negative pressure inside the hood 82. The dust fallen on the separation member 81 and the dust attached to the cleaning medium 4 are vacuumed into the hood 82 due to the negative pressure inside the hood 82, and collected by the dust collector 19. As a result, the cleaning medium 4 with the dust attached can be effectively recycled.

Upon blowing compressed air from the acceleration nozzle 71a for a predetermined time period, the controller 12 closes the acceleration solenoid valve 15 and the recycling solenoid valve 17, and stops operations of the cleaning-medium accelerating unit 7 and the cleaning-medium recycle unit 8. When the recycling solenoid valve 17 is closed, the negative pressure inside the hood 82 is released, so that vacuum force of the hood 82 to the cleaning medium 4 accumulated on the separation member 81 is lost. Therefore, the cleaning medium 4 is removed from the separation member 81 by subsequent flow of the circulation air. Accordingly, the dust can be continuously removed from the cleaning medium 4 without causing the cleaning medium 4 to cover and seal a mesh portion of the separation member 81. Therefore, it is not required to replace all the cleaning media 4, making it possible to effectively use the cleaning medium 4 by supplying deficient amounts due to damage. As a result, maintenance efficiency can be improved.

As described above, by intermittently operating the cleaning-medium recycle unit, it is possible to remove, from the cleaning-medium recycle unit, the cleaning medium stuck to the cleaning-medium recycle unit. Therefore, performance of the cleaning-medium recycle unit can be maintained.

It is difficult for the cleaning medium to move when the cleaning-medium recycle unit is vacuuming the cleaning medium for recycling because retaining force is applied to the cleaning medium. However, because the cleaning medium is not recycled during circulation of the cleaning medium according to the first embodiment, it is possible to realize effective circulation of the cleaning medium. As a result, it is possible to load a large number of the cleaning media to the cleaning-medium accelerating unit, improving cleaning efficiency.

The controller 12 re-opens the air-circulation solenoid valve 14 to cause the circulation-air generating unit 6 to generate circulation air, flows the cleaning medium 4 recycled and accumulated on the separation member 81 of the cleaning-medium recycle unit 8 for a predetermined time period T1. Subsequently, the controller 12 opens the acceleration solenoid valve 15 and the recycling solenoid valve 17 to switch the acceleration-switching control valve 16 to the acceleration nozzle 71b, and performs a process of removing dust from the cleaning target object 2 and a process of recycling the cleaning medium 4 for a predetermined time period. The time for performing the processes of removing dust from the cleaning target object 2 and recycling the cleaning medium 4 are set longer than a time for generating the circulation air, so that wide range of the cleaning target object 2 can be cleaned. Because compressed air is blown out alternately from each of the acceleration nozzles 71a and 71b, it is possible to avoid interference between air blown out from each of the acceleration nozzles 71a and 71b. Therefore, it is possible to assuredly cause the cleaning medium 4 to collide with the cleaning target object 2. As a result, cleaning efficiency of the cleaning medium 4 can be improved.

The processes of generating the circulation air, removing dust from the cleaning target object 2, and recycling the cleaning medium 4 are repeatedly performed while the cleaning target object 2 gradually moves down from the initial position. As shown in FIG. 11B, when the cleaning target object 2 reaches a turn-round position, the work moving unit 21 stops moving down the cleaning target object 2, and gradually moves up the cleaning target object 2. The controller 12 alternately performs each of the processes of generating the circulation air, removing dust from the cleaning target object 2, and recycling the cleaning medium 4 when the cleaning target object 2 is gradually moving up, removing the dust 3 from an entire surface of the cleaning target object 2. As shown in FIG. 11C, when the cleaning target object 2 reaches an upper end portion of the cleaning tank 5, i.e., the initial position, the controller 12 stops a cleaning operation. When the cleaning operation is stopped, the controller 12 opens the cover 10 of the cleaning tank 5 to discharge the cleaning target object 2 held by the work holding unit 20 from the cleaning tank 5 using the work moving unit 21. Subsequently, the cleaning target object 2 is replaced with new cleaning target object and the cleaning operation is restarted.

As described above, by intermittently operating the cleaning-medium circulating unit and the cleaning-medium accelerating unit or the cleaning-medium recycle unit, it is possible to avoid interference between each of operations of accelerating, vacuuming, and circulating the cleaning medium. Therefore, it is possible to effectively move the cleaning medium, and cause the cleaning medium to collide with the cleaning target object. As a result, cleaning performance can be improved and energy consumption can be reduced.

Although it is explained that the compressed air is alternately blown out from each of the acceleration nozzles 71a and 71b of the cleaning-medium accelerating unit 7 to clean an entire surface of the cleaning target object 2, it is possible to simultaneously blow out compressed air from each of the acceleration nozzles 71a and 71b by adjusting an angle for blowing air. When dust is attached to exclusively on one surface of the cleaning target object 2, it is sufficient to blow compressed air from one of the acceleration nozzles 71a and 71b.

By arranging the cleaning-medium accelerating unit in such a manner that generated air and circulation air generated by the circulation-air generating unit do not flow in the same plane, avoiding interference between the circulation air and the air for accelerating the cleaning medium. As a result, it is possible to realize stable cleaning performance.

Furthermore, although it is explained that the circulation path of the circulation air generated by the circulation-air generating unit is formed on a flat surface inside the cleaning tank 5, it is possible to arrange a plurality of grooves 23 formed in a square shape or in a curved surface along a direction of flow of the circulation air, on a surface 51 constituting the circulation path in the cleaning tank 5 as shown in FIGS. 13A and 13B. It is preferable to arrange the groove 23 with a width smaller than a face size of the cleaning medium 4, so that the cleaning medium 4 hardly falls into the groove 23. By arranging the groove 23 as described above, a space is formed between the surface 51 of the cleaning tank 5 and the cleaning medium 4, so that contact resistance between the surface 51 and the cleaning medium 4 can be reduced. Furthermore, by flowing the circulation air in the groove 23, it is possible to effectively deliver the cleaning medium 4, realizing delivery of large amounts of the cleaning media 4. Moreover, because circulation air is rectified by a plurality of the grooves 23, occurrence of turbulence can be avoided, preventing degradation of air force. Therefore, it is possible to effectively deliver and flow up the cleaning medium 4, resulting in improving cleaning efficiency. A height of the groove 23 is sufficient as long as air can pass through the groove 23. For example, if the height is set in a range between 0.1 millimeter (mm) and 1 mm, the groove 23 can be easily processed.

It is acceptable to form the surface 51, on which the circulation path is formed in the cleaning tank 5, on a concavely curved surface as shown in FIGS. 13C and 13D. With the surface 51 formed on the concavely curved surface, it is possible to prevent dispersion of the circulation air. Accordingly, a large amount of the cleaning media 4 can be delivered, making it possible to disperse large amounts of the cleaning media 4 in the cleaning tank 5. As a result, cleaning efficiency can be improved.

As shown in FIGS. 14A and 14B, it is preferable to arrange an air rectifying unit 24 that leads the cleaning medium 4 toward the cleaning-medium accelerating unit 7, on an upper surface or an upper portion of a side surface of the cleaning tank 5, where the circulation path is formed. By arranging the air rectifying unit 24 on the circulation path, it is possible to disperse a large amount of the cleaning media 4 between the cleaning-medium accelerating unit 7 and the cleaning target object 2, resulting in improving cleaning efficiency. Furthermore, it is possible to directly cause the cleaning medium 4, of which flowing direction is changed by the air rectifying unit 24, to collide with the cleaning target object 2 to perform cleaning. It is preferable to adjust an angle of flowing air by the air rectifying unit 24 depending on a shape or a position of the cleaning target object 2.

As described above, by arranging, in the cleaning tank, the air rectifying unit that leads the circulation air toward a path of blowing high-velocity air from the cleaning-medium accelerating unit, it is possible to assuredly cause the cleaning medium to collide with the cleaning target object even when the air flow speed for delivering the cleaning medium increases. Therefore, it is possible to reduce such a loss that the cleaning medium circulates without colliding with the cleaning target object. As a result, it is possible to effectively use the cleaning medium. Furthermore, it is possible to use kinetic energy delivered through the circulation path in addition to energy from the cleaning-medium accelerating unit to cause the cleaning medium to collide with the cleaning target object. Therefore, cleaning efficiency can be improved.

As shown in FIGS. 15A and 15B, it is possible to arrange an inclined surface 52 including an opening portion on a bottom portion of the cleaning tank 5, without forming the cleaning tank in a rectangular shape. It is possible to arrange the cleaning-medium recycle unit 8 on the inclined surface 52, the circulation-air generating unit 6 on the lower portion of the inclined surface 52, and flows the circulation air along the inclined surface from the circulation-air generating unit 6. With such configuration, when the cleaning medium 4 falls on the separation member 81 of the cleaning-medium recycle unit 8 after removing the dust from the cleaning target object 2 by a collision with the cleaning target object 2, the cleaning medium 4 can be easily collected around the outlet opening 65 of the circulation-air generating unit 6. By generating the circulation air from the circulation-air generating unit 6 to the collected cleaning medium 4, it is possible to deliver a large number of the cleaning media 4 by less amount of compressed air, realizing energy saving. Furthermore, by using the area where the cleaning-medium recycle unit 8 is arranged as an area for collecting the cleaning medium 4, it is possible to take longer time for recycling the cleaning medium 4. As a result, efficiency of recycling the cleaning medium 4 can be improved.

It is explained in the first embodiment that the circulation-air generating unit 6 is singularly arranged in the cleaning tank 5. However, in a second embodiment of the present invention, it is possible to symmetrically arrange two circulation-air generating units 6a and 6b around each of bottom portions of side surfaces of the cleaning tank 5, in such a manner that the circulation-air generating units 6a and 6b sandwich the separation member 81 of the cleaning-medium recycle unit 8. In the example shown in FIG. 16, the circulation-air generating units 6a and 6b are arranged outside of the cleaning tank 5, the outlet opening 65 is arranged at the lower portion of the cleaning tank 5, and the inlet opening 61 is connected to an upper portion of the cleaning tank 5 via a duct hose 25. In this case, the controller 12 controls an operation of a circulation-switching control valve 26 that switches supply of compressed air to the circulation-air generating units 6a and 6b as shown in a block diagram of FIG. 18, in addition to the air-circulation solenoid valve 14, the acceleration solenoid valve 15, the acceleration-switching control valve 16, and the recycling solenoid valve 17 as shown in a block diagram of FIG. 17. When flowing the cleaning medium 4 by generating the circulation air inside the cleaning tank 5, the controller 12 controls the circulation-switching control valve 26 to alternately generate the circulation air from each of the circulation-air generating units 6a and 6b. Accordingly, the cleaning media 4 are hardly accumulated inside the cleaning tank 5. Therefore, it is possible to effectively use the cleaning medium 4 inside the cleaning tank 5, increasing possibility of collision between the cleaning medium 4 and the cleaning target object 2. As a result, cleaning efficiency can be improved.

By connecting the inlet opening 61 to the upper portion of the cleaning tank 5 via the duct hose 25, it is possible to generate ascending air current inside the cleaning tank 5. Therefore, floating duration of the cleaning medium 4 can be increased, increasing the number of the flowing cleaning medium 4. As a result, it is possible to increase the number of the cleaning media 4 that collide with the cleaning target object 2 by compressed air blown out from the acceleration nozzles 71a and 71b, improving cleaning performance. Although the inlet opening 61 is connected to the cleaning tank 5 via the duct hose 25, because the duct hose 25 is connected to the upper portion of the cleaning tank 5, where space density due to the cleaning medium 4 is small, it is possible to prevent the cleaning medium 4 from clogging the duct hose 25 or the circulation-air generating units 6a and 6b.

Although it is explained that the cleaning-medium recycle unit 8 is singularly arranged in the cleaning tank 5, it is possible to arrange a plurality of the cleaning-medium recycle units 8 in a third embodiment of the present invention. For example, as shown in FIG. 19, it is possible to arrange a plurality of cleaning-medium recycle units 8a to 8d, which sandwich the arrayed acceleration nozzles 71a and 71b, in addition to the cleaning-medium recycle unit 8 arranged on the bottom portion of the cleaning tank 5. In this case, the controller 12 controls operations of each of a suction-switching control valve 27 that switches a suction operation performed to the cleaning-medium recycle unit 8, and a suction-switching control valve 28 that switches a suction operation performed to each of the cleaning-medium recycle units 8a to 8d as shown in a block diagram of FIG. 21, in addition to the air-circulation solenoid valve 14, the acceleration solenoid valve 15, the acceleration-switching control valve 16, the recycling solenoid valve 17, and the circulation-switching control valve 26 as shown in a block diagram of FIG. 20. As shown in FIG. 22, when cleaning the cleaning target object 2 by blowing compressed air from the acceleration nozzle 71a arranged on a front surface of the cleaning tank 5, the controller 12 connects the suction-switching control valve 28 to the cleaning-medium recycle unit 8, and connects the suction-switching control valve 28 to the cleaning-medium recycle units 8c and 8.d arranged on a back surface of the cleaning tank 5. On the other hand, when cleaning the cleaning target object 2 by blowing compressed air from the acceleration nozzle 71b arranged on the back surface of the cleaning tank 5, the controller 12 connects the suction-switching control valve 28 to the cleaning-medium recycle units 8a and 8b arranged on the front surface of the cleaning tank 5. In this manner, the dust 3 and the cleaning medium 4 flown up by the compressed air blown from the acceleration nozzle 71a are stuck to the cleaning-medium recycle units 8c and 8d. When the dust 3 and the cleaning medium 4 are stuck to the cleaning-medium recycle units 8c and 8d, air-flow from the acceleration nozzle 71a acts on the dust 3 and the cleaning medium 4, in addition to suction air from the cleaning-medium recycle units 8c and 8d. Therefore, it is possible to largely increase flow speed at a mesh portion of the separation member 81 of each of the cleaning-medium recycle units 8c and 8d, improving performance of removing the dust 3 attached to the cleaning medium 4. As a result, the cleaning medium 4 can be assuredly recycled. When blowing of the compressed air from the acceleration nozzle 71a is stopped, the cleaning-medium recycle units 8c and 8d terminates a suction operation after a predetermined time elapsed. Therefore, it is possible to assuredly remove, from the cleaning-medium recycle units 8c and 8b, the cleaning medium stuck to the cleaning-medium recycle units 8c and 8b.

As described above, by alternately switching an operation of recycling the cleaning medium performed by each of the cleaning-medium recycle units, action for sucking the cleaning medium is continuously performed in one of the cleaning-medium recycle units in the cleaning tank. As a result, it is possible to maintain recyclability of the cleaning medium and negative pressure inside the cleaning tank.

It is possible to prevent unwanted situation in which the flown cleaning medium 4 falls down without being accelerated by the acceleration nozzles 71a and 71b. Furthermore, it is possible to supply large amounts of the cleaning media 4 between the acceleration nozzles 71a, 71b, and the cleaning target object 2 when the acceleration nozzles 71a and 71b blow out compressed air. As a result, cleaning efficiency can be improved. In other words, when cleaning the cleaning target object 2 by colliding the flaked-shaped cleaning target 4 with the cleaning target object 2, quality in cleaning is substantially proportional to frequency of collision of the cleaning medium 4 with the cleaning target object 2 at a predetermined speed or faster. Therefore, if supply amount of the cleaning media 4 increases, quality in cleaning is improved, resulting in reducing cleaning time and energy consumption.

It is possible to clean the cleaning target object 2 using the cleaning medium 4 after performing rough cleaning using the acceleration nozzles 71a, 71b, and the cleaning-medium recycle units 8a to 8b. An operation of performing the rough cleaning is explained with reference to a timechart shown in FIG. 23.

The flaked-shaped cleaning medium 4 is introduced into the cleaning tank 5 and accumulated on the separation member 81 of the cleaning-medium recycle unit 8. Subsequently, the cleaning target object 2 held by the work holding unit 20 is loaded from the cleaning-target loading port 9 by the work moving unit 21, and set at an initial position. The cover 10 is closed to seal off the cleaning tank 5. Upon receiving a cleaning start signal by an operation of the driving unit 13, the controller 12 opens the acceleration solenoid valve 15 to switch the acceleration-switching control valve 16 at a predetermined interval, so that each of the acceleration nozzles 71a and 71b alternately blows compressed air. The controller 12 switches the acceleration-switching control valve 16 in synchronization with switching of blowing compressed air from each of the acceleration nozzles 71a and 71b, to switch adsorption performed by each pair of the cleaning-medium recycle units 8a, 8b, and 8c, 8d, arranged on surfaces facing each of the acceleration nozzles 71a and 71b. In other words, when the acceleration nozzle 71a arranged on the front surface of the cleaning tank 5 blows compressed air, the cleaning-medium recycle units 8c and 8d arranged on the back surface of the cleaning tank 5 performs suction operation. With this operation, the compressed air blown out from the acceleration nozzle 71a collides with the cleaning target object 2, so that a large part of the dust 3 or weakly-attached stain on the cleaning target object 2 are removed, completing rough cleaning of the cleaning target object 2. Subsequently, the circulation-air generating unit 6 generates circulation air to deliver and flow up the cleaning medium 4 accumulated on the separation member 81 of the cleaning-medium recycle unit 8, and the cleaning target object 2 is cleaned using the flowing cleaning medium 4. After the cleaning by the flowing cleaning medium 4 is finished, each of the acceleration nozzles 71a and 71b alternately blows compressed air, so that the controller 12 switches the acceleration-switching control valve 16 in synchronization with switching of blowing compressed air from each of the acceleration nozzles 71a and 71b. Accordingly, suction performed by each pair of the cleaning-medium recycle units 8a, 8b, and 8c, 8d, which are arranged on surfaces respectively facing the acceleration nozzles 71a and 71b, can be switched from one another. Subsequently, the controller 12 shakes off the cleaning medium 4 attached by static electricity to the cleaning target object 2, and terminates a cleaning operation. Thereafter, the controller 12 opens the cover 10 of the cleaning tank 5 to take off the cleaning target object 2 from the cleaning tank 5 by the work moving unit 21, and replaces the cleaning target object with a new cleaning target object to restart the cleaning operation. By performing shake off cleaning of the cleaning medium 4 as described above, it is possible to increase cleaning speed and improve cleaning quality.

Although it is explained that the cleaning-medium recycle units 8a to 8d are arranged on the front and the back surfaces of the cleaning tank 5, it is possible to arrange differently. In a forth embodiment of the present invention, as shown in FIGS. 24A and 24B, inclined surfaces 52a and 52b including respective openings, which make V-shaped bottom portion of the cleaning tank 5, are arranged on a bottom portion of the cleaning tank 5, the cleaning-medium recycle units 8 is arranged on each of the inclined surfaces 52a and 52b, the circulation-air generating units 6a and 6b are arranged at respective lower end portions of the inclined surfaces 52a and 52b, and the circulation air flows alternately from each of the circulation-air generating units 6a and 6b along the inclined surfaces 52a and 52b. In this case, it is preferable to arrange the air rectifying unit 24 that leads the cleaning medium 4 toward the cleaning-medium accelerating unit 7, on a top surface or a top portion of a side surface of the cleaning tank 5 constituting the circulation path of the circulation air.

As described above, with a configuration in which a V-shaped inclined surfaces including the cleaning-medium recycle unit are arranged at the bottom portion of the cleaning tank, the circulation-air generating unit that generates circulation air along each of the inclined surfaces is arranged on the lower end portion of each of the inclined surfaces, and each of the circulation-air generating unit arranged on each of the lower end portions of the inclined surfaces are alternately operated, the cleaning medium can be collected at one area on the circulation path. Furthermore, the circulation air is intermittently generated along the internal surfaces of the cleaning tank to circulate the collected cleaning medium along the internal surfaces of the cleaning tank. Thus, it is possible to deliver a large amount of the cleaning media at one time with less amounts of air. As a result, energy saving can be realized and cleaning efficiency can be improved.

When the cleaning media 4 are flown up to clean the cleaning target object 2 by colliding with the cleaning target object 2, part of the cleaning media 4 are discharged to the dust collector 19 through the mesh portion included in the separation member 81 of the cleaning-medium recycle unit 8. Accordingly, the number of the cleaning media 4 in the cleaning tank 5 decreases during cleaning. When amount of the flowing cleaning medium 4 decreases in the cleaning tank 5 due to a decrease of the number of the cleaning media 4 in the cleaning tank 5, cleaning effect decreases. In some cases, a plurality of the cleaning target objects 2 held by the work holding unit 20 are loaded into the cleaning tank 5 for cleaning. In this case, it is preferable to arrange a medium-amount measuring unit 29 inside the cleaning tank 5, and arrange cleaning-target detecting units 30a and 30b sandwiching the acceleration nozzles 71a and 71b with a predetermined interval, as shown in FIG. 25. This configuration is described below as a fifth embodiment of the present invention. The medium-amount measuring unit 29 is constituted of a photoelectronic sensor 291 arranged in such a manner that an optical axis of the photoelectronic sensor 291 becomes orthogonal to a direction of circulation of the cleaning medium 4 as shown in FIG. 26. The cleaning-target detecting units 30a and 30b are constituted of a photoelectronic sensor including a light projecting/receiving unit 301 and a reflecting plate 302. The light projecting/receiving unit 301 is attached to either the front surface or the back surface of the cleaning tank 5 via a transparent window for preventing interference with the cleaning medium 4. The reflecting plate 302 is attached to an internal surface that faces the light projecting/receiving unit 301, and arranged in such a manner that its optical axis crosses the cleaning tank 5 in a longitudinal direction. The medium-amount measuring unit 29, and the cleaning-target detecting units 30a, 30b are connected to the controller 12 as shown in FIG. 27. The controller 12 measures how many times the optical axis of the photoelectronic sensor 291 as the medium-amount measuring unit 29 is blocked, quantifies amounts of the flowing cleaning medium 4 during a predetermined time period, and controls the cleaning operation when one of the cleaning-target detecting units 30a and 30b detects the cleaning target object 2.

The cleaning operation performed by a cleaning device in which the medium-amount measuring unit 29, and the cleaning-target detecting units 30a, 30b are arranged in the cleaning tank 5 is described with reference to a timechart shown in FIG. 28.

After a plurality of the cleaning target objects 2 held by the work holding unit 20 are loaded into the cleaning tank 5 as shown in FIG. 25, and when receiving a cleaning start signal, the circulation-air generating unit 6 generates circulation air for delivering the cleaning medium 4 accumulated on the cleaning-medium recycle unit 8 and flowing up the cleaning medium 4 inside the cleaning tank 5. The photoelectronic sensor 291 as the medium-amount measuring unit 29 detects the amount of the flowing cleaning medium 4 and inputs measured amount to the controller 12. The controller 12 compares input amount of the flowing cleaning medium 4 in a predetermined time period with a predetermined threshold. When the amount of the flowing cleaning medium 4 exceeds the threshold, the controller 12 starts a cleaning operation. When the amount of the flowing cleaning medium 4 is equal to or smaller the threshold, the controller 12 issues a warning indicating scarcity of the cleaning medium 4, and terminates the cleaning operation. Subsequently, when the cleaning medium 4 with a predetermined amount or an amount corresponding to the scarcity is supplied from a hopper or the like. When the cleaning medium 4 is flown up in response to the reception of the cleaning start signal, and the amount of the flowing cleaning medium 4 exceeds the threshold, the controller 12 restarts the cleaning operation.

As described above, because the amount of the flowing cleaning medium 4 is detected and cleaning is performed using the cleaning medium 4 with a predetermined amount or larger, it is possible to perform cleaning in desired quality. The amount of the cleaning medium 4 that collides with the cleaning target object 2 is proportional to the amount of the flowing cleaning medium 4. Therefore, it is possible for the controller 12 to determine cleaning quality from the amount of the flowing cleaning medium 4 for each predetermined time period. Furthermore, it is possible to assuredly quantify the cleaning quality and cleaning performance by recording variation of the amount of the flowing cleaning medium 4.

Upon starting a cleaning operation, a plurality of the cleaning target objects 2 held by the work holding unit 20 is moved up and down by the work moving unit 21. When the first cleaning target object 2 reaches a position where the optical axis of a cleaning-target detecting unit 29a arranged on the acceleration nozzles 71a and 71b is blocked by the cleaning target object 2, and a cleaning-target detection signal is input from the cleaning-target detecting unit 29a to the controller 12, the controller 12 determines a timing of performing an operation of blowing compressed air from the acceleration nozzle 71a and a suction operation by the cleaning-medium recycle unit 8. The timing is determined to include a delayed time taken by the cleaning target object 2 to reach a position of the acceleration nozzles 71a and 71b based on a moving speed of the cleaning target object 2 and a distance between the cleaning-target detecting unit 30a and the acceleration nozzles 71a and 71b. Subsequently, the controller 12 stops flowing circulation air at the timing, blows compressed air from the acceleration nozzle 71a, and cleans the first cleaning target object 2 by causing the cleaning-medium recycle unit 8 to start the suction operation. When input of the cleaning-target detection signal from the cleaning-target detecting unit 30a is stopped, the controller 12 terminates the operation of blowing the compressed air from the acceleration nozzle 71a and the suction operation of the cleaning-medium recycle unit 8, at a timing including a delayed time taken by the cleaning target object 2 to reach a position of the acceleration nozzles 71a and 71b, which is obtained from a moving speed of the cleaning target object 2 and a distance between the cleaning-target detecting unit 30a and the acceleration nozzles 71a and 71b. Subsequently, the controller 12 causes the circulation-air generating unit 6 to generate circulation air. The controller 12 repeats the above control operation every time the cleaning-target detection signal is input from the cleaning-target detecting unit 30a, and sequentially cleans each of the cleaning target objects 2. When the cleaning target object 2 reaches a turn-round position and starts moving up, the controller 12 repeats the above control operation every time the cleaning-target detection signal is input from the cleaning-target detecting unit 30b arranged under the acceleration nozzles 71a and 71b to blow compressed air from the acceleration nozzle 71b. Accordingly, the entire surfaces of the cleaning target objects 2 can be cleaned.

As described above, because compressed air is blown from the acceleration nozzles 71a and 71b that consume large amounts of compressed air depending on a position of the cleaning target object 2, it is possible to reduce usage of the compressed air, realizing energy consumption.

Although it is explained that the photoelectronic sensor 291 is used as the medium-amount measuring unit 29, it is possible to employ a method of accumulating impact force of the cleaning medium 4 to the cleaning target object 2 by a force sensor, weight measurement at a time of termination of a process by a weight sensor, or a method of measuring accumulation amount at a bottom portion of the cleaning tank 5 by a distance sensor or the like. When accumulating the impact force of the cleaning medium 4, it is possible to determine a cleaning quality from the number of accumulated impact.

In a sixth embodiment of the present invention shown in FIG. 29, it is possible to include a work-position changing unit 31 that rotates the work holding unit 20 in a direction of rotation of an axis in a longitudinal direction by a motor or an air cylinder, between the work moving unit 21 and the work holding unit 20. In addition, it is possible to arrange a plurality of pairs, e.g., three pairs, of the arrayed acceleration nozzles 71 as the cleaning-medium accelerating unit 7 on a side surface of the cleaning tank 5, which constitutes circulation path, in such a manner that a direction of blow of air from each of the acceleration nozzle 71 differs from one another, e.g., horizontal direction and vertical direction. The cleaning target object 2 held by the work holding unit 20 and loaded into the cleaning tank 5 is rotated by the work-position changing unit 31 to move up and down in the cleaning tank 5, and cleaned by alternately blowing compressed air from a plurality of pairs of the acceleration nozzles 71. As described above, the cleaning target object 2 is rotated when moving up and down, and compressed air is blown to the cleaning target object 2 from each different direction. Therefore, it is possible to assuredly clean an entire surface of the cleaning target object 2 even when the cleaning target object 2 is in a complicated shape.

According to an aspect of the present invention, the circulation-air generating unit directly generates circulation air that flows along an internal surface of the cleaning tank, generated circulation air is applied to the cleaning medium from a direction orthogonal to a direction of a face of the cleaning medium accumulated in the cleaning tank, so that the cleaning medium is delivered and flown up. Accordingly, it is possible to apply effective force for flowing the accumulated cleaning medium by the circulation air, resulting in flowing large number of the cleaning media and increasing frequency of collision of the cleaning medium with the cleaning target object. As a result, it is possible to realize desired quality in cleaning.

According to another aspect of the present invention, the cleaning-medium recycle unit removes attachment on the cleaning medium by suction. Therefore, cleanness of the cleaning medium can be maintained, maintaining desired quality in cleaning. Furthermore, the cleaning medium can be repeatedly used, realizing to perform a cleaning with low environmental burdens.

Although the invention has been described with respect to specific embodiments for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.

Number	Date	Country	Kind
2006-240920	Sep 2006	JP	national
2006-240948	Sep 2006	JP	national
2006-240971	Sep 2006	JP	national

Dry cleaning device and dry cleaning method

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Priority Claims (3)