WO2015198844A1 - ショット処理装置及び投射機 - Google Patents
ショット処理装置及び投射機 Download PDFInfo
- Publication number
- WO2015198844A1 WO2015198844A1 PCT/JP2015/066447 JP2015066447W WO2015198844A1 WO 2015198844 A1 WO2015198844 A1 WO 2015198844A1 JP 2015066447 W JP2015066447 W JP 2015066447W WO 2015198844 A1 WO2015198844 A1 WO 2015198844A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- projector
- projection material
- workpiece
- impeller
- control cage
- Prior art date
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24C—ABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
- B24C3/00—Abrasive blasting machines or devices; Plants
- B24C3/08—Abrasive blasting machines or devices; Plants essentially adapted for abrasive blasting of travelling stock or travelling workpieces
- B24C3/10—Abrasive blasting machines or devices; Plants essentially adapted for abrasive blasting of travelling stock or travelling workpieces for treating external surfaces
- B24C3/14—Apparatus using impellers
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24C—ABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
- B24C3/00—Abrasive blasting machines or devices; Plants
- B24C3/18—Abrasive blasting machines or devices; Plants essentially provided with means for moving workpieces into different working positions
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24C—ABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
- B24C3/00—Abrasive blasting machines or devices; Plants
- B24C3/18—Abrasive blasting machines or devices; Plants essentially provided with means for moving workpieces into different working positions
- B24C3/20—Abrasive blasting machines or devices; Plants essentially provided with means for moving workpieces into different working positions the work being supported by turntables
- B24C3/24—Apparatus using impellers
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24C—ABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
- B24C5/00—Devices or accessories for generating abrasive blasts
- B24C5/06—Impeller wheels; Rotor blades therefor
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24C—ABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
- B24C5/00—Devices or accessories for generating abrasive blasts
- B24C5/06—Impeller wheels; Rotor blades therefor
- B24C5/062—Rotor blades or vanes; Locking means therefor
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24C—ABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
- B24C9/00—Appurtenances of abrasive blasting machines or devices, e.g. working chambers, arrangements for handling used abrasive material
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24C—ABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
- B24C9/00—Appurtenances of abrasive blasting machines or devices, e.g. working chambers, arrangements for handling used abrasive material
- B24C9/003—Removing abrasive powder out of the blasting machine
Definitions
- the present invention relates to a shot processing apparatus and a projector.
- a shot processing device that projects a projection material onto a workpiece to perform surface treatment is known.
- a shot processing apparatus an apparatus that projects a projection material from a centrifugal projector toward a product is known (for example, see Patent Document 1).
- the present invention has an object to provide a shot processing apparatus and a projector that can reduce the amount of projection material used in consideration of the above requirements.
- a shot processing apparatus comprising a centrifugal projector that projects a projection material onto a workpiece, and a support mechanism that supports the workpiece at a processing position where surface processing by the projector is possible
- the projector has a cylindrical shape, a projection material is supplied inside, and a control cage in which an opening serving as a discharge port of the projection material is formed on a side wall;
- An impeller comprising a plurality of blades arranged to extend outward in the radial direction of the control cage outside the control cage and rotating about a central axis of the control cage, wherein the blade has a rotational direction
- An impeller provided with a rearward inclined portion inclined rearward in the rotational direction on the front surface, and A shot processing apparatus is provided.
- the rear inclined portion that is inclined rearward in the rotational direction of the impeller is formed on the surface of the blade of the impeller. Therefore, before the projection material discharged first from the opening of the control cage contacts the blade surface, the projection material discharged later from the control cage opening contacts the blade surface toward the blade tip side. To be accelerated. Thereby, when the projection material discharged
- the opening has a rectangular shape with two sides parallel to the cylindrical axis of the control cage.
- the projecting material can be projected onto the work in a concentrated manner.
- a workpiece in which an angle formed by a projection material projecting position by the projector and both ends of a surface of the workpiece disposed at the processing position facing the projector is within 30 ° as viewed in the rotational axis direction of the impeller.
- the backward inclined portion is inclined 30 ° to 50 ° rearward in the rotational direction with respect to the radial direction of the impeller.
- the backward inclined portion is formed on the base end side of the blade,
- a non-backward tilt portion having a small tilt angle from the rearward tilt portion to the rear side in the rotation direction is formed on the tip end side of the blade.
- the rearward inclined part is formed on the base end part side of the blade, and the non-rearly inclined part is formed on the distal end part side of the blade. Projection can be accelerated at the rearward tilting part.
- a configuration extending in the direction and a configuration inclined toward the front side in the rotation direction are also included.
- the impeller is attached to the rotating shaft of the drive motor via a hub.
- the entire apparatus can be reduced in size compared to the case where it is connected to the drive motor via the belt.
- the length in the radial direction of the backward inclined portion is set longer than the length in the radial direction of the non-backward inclined portion.
- the projection material can be accelerated and projected at the non-backward tilt portion after sufficiently collecting the projection material at the rearward tilt portion of the blade.
- a bending portion that gently connects the rearward tilting portion and the non-backward tilting portion is provided.
- the speed of the projection material can be gradually increased at the curved portion and the non-backward tilt portion to be projected.
- a distributor disposed inside the control cage and further rotating in the same direction as the rotation direction of the impeller;
- the projection material supplied to the inside of the control cage moves in the gap between the distributor and the control cage along the inner peripheral surface of the distributor, and the opening of the control cage
- the discharge direction of the projection material from the tilting direction is inclined forward in the rotation direction of the impeller with respect to the radial direction from the rotation center of the impeller.
- the discharge direction of the projection material from the opening of the control cage is inclined forward in the rotation direction of the impeller with respect to the radial direction from the rotation center of the impeller.
- the timing at which the projection material discharged first from the opening comes into contact with the surface of the blade can be delayed, and the projection material can be concentrated on the backward inclined portion of the surface of the blade.
- the surface of the blade on the rear side in the rotational direction of the impeller includes an inclined portion inclined at the rear side in the rotational direction larger than the inclined portion with respect to the radial direction.
- a cabinet having a loading / unloading zone where the workpiece is loaded and unloaded at an internal upper position, and a processing zone for performing surface processing of the workpiece by the projection material projected by the projector at an internal lower position,
- An elevating / rotating mechanism that constitutes the supporting mechanism, and that elevates and lowers the work between the loading / unloading zone and the machining zone while supporting the work, and is rotatable about the elevating direction.
- An inner lid that is movable up and down between a first position located on the upper end side of the carry-in / out zone and a second position located between the carry-in / out zone and the processing zone;
- the inner lid is arranged at the first position when the workpiece is carried into and out of the loading / unloading zone, and the inner lid is arranged at the second position when the workpiece is arranged in the processing zone.
- an elevating mechanism for elevating the inner lid.
- the lifting / lowering rotation mechanism has a pressing portion that can penetrate the inner lid, press the workpiece from above, and rotate together with the workpiece in the lifting / lowering direction.
- the workpieces can be stably rotated around the axis in the ascending / descending direction.
- the workpiece inspection device comprises: When the inner lid and the pressing part are spaced apart from the work supported by the elevating and rotating mechanism, they are inserted from the side between the work and the inner lid and the pressing part. Possible retraction positions, It is supported so as to be movable between a side position of the retracted position and an inspection position surrounding the side surface of the workpiece.
- the state of the side portion of the workpiece can be inspected nondestructively after the projection material is projected onto the workpiece and before the workpiece is carried out of the cabinet.
- the projector is disposed on the side wall of the cabinet on the side of the processing zone.
- the height of the entire apparatus can be suppressed even if the projection material supply unit or the like is disposed above the projector.
- the rotation direction of the impeller is set so that the blade of the impeller moves in the order of the apparatus upper side, the processing zone side, and the apparatus lower side when viewed in the direction of the rotation center line of the impeller. Has been.
- the leakage of the projection material to the upper side can be suppressed.
- a circulation mechanism for circulating the projection material projected by the projector to the projector is A separator that has an inlet at the top and separates and removes the dust from the projection material and dust supplied from the inlet and discharges the projection material to the lower side, A shot tank that has a shot supply port adjacent to the inlet of the separator in the upper part and stores the projection material supplied to the shot supply port for supply to the projector, A first row transport unit that transports the projection material and dust from the lower side to the upper side and supplies the inlet to the separator, and a projection material that is provided in parallel with the first row transport unit and discharged from the separator.
- a transport mechanism having a second row transport unit that transports from the top to the top and supplies the shot tank to the shot supply port.
- the shot supply port of the shot tank is provided adjacent to the inlet of the separator and no separator is disposed on the upper side of the shot tank, the height of the entire apparatus can be suppressed.
- the transport mechanism is A common motor for driving the first row transport unit and the second row transport unit; A single endless belt driven to rotate by the motor; A plurality of first buckets attached to the endless belt and constituting the first row transport unit; A bucket elevator having a plurality of second buckets attached to the endless belt in parallel with the first bucket and constituting the second row transport unit.
- a partition part is further provided for partitioning the first row transport unit and the second row transport unit in proximity to a lower portion of the endless belt.
- the mixture (projection material and dust) before the dust is separated and removed by the separator and the projection material after the dust is separated and removed by the separator are prevented from being mixed. Can do.
- a centrifugal projector that projects a projection material onto a workpiece, It has a cylindrical shape, a projection material is supplied inside, and an opening is formed on the outer peripheral wall as a discharge portion of the projection material.
- the opening has a rectangular shape including two sides parallel to the cylindrical axis.
- a control cage The blade includes a plurality of blades that are disposed radially outward of the control cage and rotate in the circumferential direction of the control cage, and a rearward inclined portion that is inclined rearward in the rotational direction is provided on a surface of the blade in the rotational direction front side.
- An impeller, A projector is provided.
- a workpiece in which an angle formed by a projection material projecting position by the projector and both ends of a surface of the workpiece disposed at the processing position facing the projector is within 30 ° as viewed in the rotational axis direction of the impeller.
- the backward inclined portion is inclined 30 ° to 50 ° rearward in the rotational direction with respect to the radial direction of the impeller.
- a centrifugal projector that is installed in a shot processing device and projects a projection material by rotation of an impeller,
- the angle formed by the projection position of the projection material by the projector and both ends of the surface facing the projector of the workpiece arranged at the machining position when viewed from the rotational axis direction of the impeller is within 50 ° to 80 °
- It has a cylindrical shape, a projection material is supplied inside, and an opening is formed on the outer peripheral wall as a discharge portion of the projection material.
- the opening has a rectangular shape including two sides parallel to the cylindrical axis.
- the blade includes a plurality of blades that are disposed radially outward of the control cage and rotate in the circumferential direction of the control cage, and a rearward inclined portion that is inclined rearward in the rotational direction is provided on a surface of the blade in the rotational direction front side.
- the opening is A first through part having a rectangular shape including two sides parallel to the axis of the control cage; A second penetrating portion having a rectangular shape including two parallel sides opposite to each other parallel to the axis of the control cage and offset in the circumferential direction of the control cage with respect to the first penetrating portion; With The first penetrating portion and the second penetrating portion are overlapped by approximately half of each in the direction of the cylindrical axis of the control cage.
- a projector is provided.
- emitted previously contacts the surface of a blade the projection material discharged
- a projection material can be projected intensively.
- the projection distribution as a whole was discharged
- the projection distribution of the projection material and the projection distribution of the projection material discharged from the second penetrating portion are synthesized.
- the first penetrating part and the second penetrating part overlap substantially in the cylindrical axis direction of the control cage, the projection material discharged from the first penetrating part and the second penetrating part respectively.
- Each projection distribution also overlaps in a range that is approximately half of each distribution width. For this reason, as a whole projection distribution, a range with a high projection ratio (a range in which projections are concentrated) is expanded.
- a shot processing device and a projector that can suppress the projection amount of the projection material are provided.
- FIG. 6A is a cross-sectional view taken along the line 7A-7A in FIG. 6
- FIG. 6B is a cross-sectional view taken along the line 7B-7B in FIG. 6, and FIG.
- FIG. 8 is a cross-sectional view taken along line 8-8 in FIG. It is a schematic perspective view which shows the structure of a bucket elevator typically. It is sectional drawing of the front view which shows the projector of the shot blasting apparatus of 1st Embodiment. It is a disassembled side view of the projector of FIG. It is a side view which shows the control cage of the projector of FIG. It is a perspective view of the braid
- (B) is a top view which shows the projection range at the time of projecting using the control cage of FIG. . It is a schematic diagram for demonstrating the effect
- (D) is a side view showing a fourth modification of the control cage
- (E) is a side view showing a fifth modification of the control cage.
- (A) is a figure which shows roughly the projection distribution and projection range in a 1st, 2nd modification
- (B) shows roughly the projection distribution and projection range in a 3rd, 4th modification.
- (C) is a figure which shows roughly the projection distribution and projection range in a 5th modification. It is a perspective view which shows the blade of another shape.
- a shot blasting apparatus 10 which is a first embodiment of the shot processing apparatus of the present invention will be described with reference to FIGS.
- the arrow FR indicates the front side of the apparatus when viewed from the front
- the arrow UP indicates the upper side of the apparatus
- the arrow LH indicates the left side of the apparatus when viewed from the front.
- FIG. 1 is a right side view of the shot blasting apparatus 10, and FIG. 2 is a front view of the shot blasting apparatus 10.
- the shot blasting apparatus 10 includes a cabinet 12 formed in a box shape.
- a loading / unloading port 14 is formed in the upper part on the front side of the cabinet 12.
- FIG. 5B is a schematic configuration diagram of the inside of the cabinet 12 of the shot blasting apparatus 10 as viewed from the front side of the apparatus.
- the upper part of the internal space of the cabinet 12 shown in FIG. 5B is a loading / unloading zone 16 in which the workpiece W is loaded / unloaded.
- the lower part of the internal space of the cabinet 12 is a processing zone 18 that performs surface processing on the workpiece W.
- FIG. 5A is a left side view of a part of the shot blasting apparatus 10 including the cabinet 12.
- a centrifugal projector 20 is installed on the side wall 12 ⁇ / b> A of the cabinet 12 at the side of the processing zone 18 (FIG. 5B).
- the projector 20 can project a projection material onto the workpiece W shown in FIG. 5B (FIG. 23), and the surface processing of the workpiece W is performed by the projection material projected from the projector 20. Details of the projector 20 will be described later.
- the cabinet 12 is provided with an up-and-down rotation mechanism 22.
- the up-and-down rotation mechanism 22 constitutes a support mechanism that supports the workpiece W at a processing position (FIGS. 22 and 23) where surface processing by the projector 20 is possible, and the workpiece W is carried in and out while supporting the workpiece W. It is configured so that it can be moved up and down between the zone 16 and the processing zone 18 so as to be rotatable about an axis extending in the vertical direction.
- the elevating and rotating mechanism 22 includes a workpiece receiving portion 24 that receives the workpiece W.
- the workpiece W is configured by a plurality of (for example, five) stacked gears.
- a shaft (not shown) passes through the center holes of these gears in the vertical direction, and a cap 23 is fitted to the upper end of the shaft. Further, the lower end surface of the cap 23 abuts on the upper surface of the uppermost gear.
- the cap 23 and the workpiece W are integrally rotatable around the axis extending in the vertical direction.
- the workpiece receiver 24 is connected to a motor 28 via a driving force transmission mechanism 26 and is rotatable about an axis extending in the vertical direction by the operation of the motor 28.
- the motor 28 is fixed to the motor holding portion 30A, and the upper end portion of the motor holding portion 30A is connected to the inverted L-shaped bracket 32A via the connecting portion 30B.
- the bracket 32A can be moved up and down along a pair of guide shafts 32B extending in the vertical direction.
- An elevating member 32S is fixed to the left side of the device of the bracket 32A (the front side in FIG. 5A).
- the elevating member 32S is screwed to a ball screw 32C extending in the vertical direction of the apparatus between the pair of guide shafts 32B.
- the ball screw 32C is connected to the lift servo motor 32M.
- the elevating servo motor 32M It is possible to convert the rotation of the elevating servo motor 32M into a linear motion in the vertical direction, that is, elevate the elevating member 32S according to the forward and reverse rotations of the elevating servo motor 32M.
- the lifting servo motor 32M, the ball screw 32C, the lifting member 32S, the bracket 32A, and the guide shaft 32B constitute the lifting jack 32.
- the lifting servo motor 32M is connected to the control unit 25, and the operation is controlled by the control unit 25. That is, the control unit 25 controls normal rotation, reverse rotation, and stop of the lifting servomotor 32M based on instruction information from the operator.
- the cylinder 34A of the first cylinder mechanism 34 is fixed to the bracket 32A.
- an upper portion of the rod 34B and a piston (not shown) are arranged in the cylinder 34A.
- the rod 34B has an upper end fixed to the piston, and a lower end extending below the cylinder 34A.
- the piston and rod 34B can be moved relative to the cylinder 34A (reciprocating in the vertical direction) by the fluid pressure in the cylinder 34A (in this embodiment, air pressure).
- the inner lid 36 is fixed to the lower end of the rod 34B.
- the inner lid 36 is operated by the operation of the jack 32 and the first cylinder mechanism 34, and the first position 36 ⁇ / b> X (position shown in FIG. 5B), which is the position on the upper end side of the carry-in / out zone 16, It is configured to be movable up and down with respect to a second position 36 ⁇ / b> Y (FIG. 22) that is a position between the processing zone 18. That is, the jack 32 and the first cylinder mechanism 34 cooperate to place the inner lid 36 at the first position 36X when the workpiece W is loaded into and unloaded from the loading / unloading zone 16 and to move the workpiece W into the machining zone 18.
- An elevating mechanism 38 that raises and lowers the inner lid 36 is configured so that the inner lid 36 is arranged at the second position 36Y (FIG. 22) when arranged in the position.
- the cylinder 40A of the second cylinder mechanism 40 is fixed to the bracket 32A.
- a lower portion of the rod 40B and a piston (not shown) are disposed in the cylinder 40A.
- the lower end portion of the rod 40B is fixed to the piston, and the upper side extends to the upper side of the cylinder 40A.
- the piston and rod 40B can be moved relative to the cylinder 40A (reciprocating in the vertical direction) by the fluid pressure in the cylinder 40A (air pressure in the present embodiment).
- the upper end portion of the rod 40B is connected to the bearing 44 through the connecting portion 42.
- the bearing 44 is disposed on the right side of the second cylinder mechanism 40.
- An upper end portion of a pressing shaft 46 extending in the vertical direction is inserted into the bearing 44.
- the pressing shaft 46 cannot be moved relative to the bearing 44 in the vertical direction, but is rotatable with respect to the bearing 44 around the pressing shaft 46.
- a pressing portion 48 is attached to the lower end portion of the pressing shaft 46.
- the pressing portion 48 can rotate together with the pressing shaft 46 about an axis extending in the vertical direction, and can pass through the through hole of the inner lid 36.
- the pressing portion 48 can press the workpiece W placed on the workpiece receiving portion 24 from the upper side of the apparatus through the cap 23. When the workpiece W is pressed, the pressing portion 48 moves up and down (in the up and down direction) together with the workpiece W. ) Can be rotated around an axis extending to the center.
- the cylinder 34A of the first cylinder mechanism 34 and the cylinder 40A of the second cylinder mechanism 40 are connected to an air supply source via an air direction control device (not shown) such as a solenoid valve, respectively, and air direction control.
- the device is connected to the control unit 25.
- the control unit 25 can control the forward and backward directions of the rods 34B and 40B by controlling each air direction control device based on the instruction information from the operator.
- the cabinet 12 is provided with a workpiece inspection device 200 on the side wall of the carry-in / out zone 16.
- the workpiece inspection apparatus 200 has a cylindrical shape such as a short cylindrical shape, and is disposed so that a penetrating direction thereof is a vertical direction, and is accommodated in a housing (not shown). 1 and the like, illustration of the housing and illustration of the workpiece inspection apparatus 200 are also omitted as appropriate.
- the workpiece inspection apparatus 200 is arranged so as to surround the side surface of the workpiece W supported by the lifting and rotating mechanism 22, that is, the inner peripheral surface 200 ⁇ / b> A of the workpiece inspection apparatus 200.
- the state of the side portion of the workpiece W for example, residual stress, surface roughness, hardness, etc.
- the workpiece inspection apparatus 200 is a non-contact type inspection apparatus, and performs a nondestructive inspection of the state of the side portion of the workpiece W by a voltage change caused by an eddy current.
- the workpiece inspection apparatus may be a contact type inspection apparatus.
- the work inspection device 200 is fixed to the tip of the rotary arm 202.
- the rotation arm 202 has a base end portion installed on the cabinet 12 side, and is rotatable about an axis extending in the vertical direction.
- the workpiece inspection device 200 is fixed to the tip of the rotary arm 202, and is supported so as to be movable between a retracted position indicated by a solid line and an inspection position indicated by a two-dot chain line.
- the retracted position of the workpiece inspection apparatus 200 is such that the workpiece W and the inner lid 36 are located when the inner lid 36 and the pressing portion 48 are spaced apart from each other with respect to the workpiece W supported by the lifting and rotating mechanism 22.
- the workpiece inspection device 200 can be inserted between the presser 48 and the pressing portion 48 from the side.
- the work W, the inner lid 36, and the holding portion 48 are moved by the operation of the jack 32 so that the relative position relationship between the workpiece W and the inner lid 36 and the holding portion 48 is changed.
- the workpiece inspection device 200 in the retracted position can be inserted between the workpiece W and the inner lid 36 and the pressing portion 48 from the side.
- the retracted position of the workpiece inspection apparatus 200 is set to a position where the workpiece inspection apparatus 200 does not interfere with other members that move up and down when the workpiece W is raised and lowered by the raising and lowering rotation mechanism 22 and when the inner lid 36 is raised and lowered by the lifting mechanism 38. ing.
- the inspection position of the workpiece inspection apparatus 200 is a position on the side of the retracted position, and is a position that surrounds the side surface of the workpiece W when the elevation rotation mechanism 22 raises and lowers the workpiece W. is there. That is, the inspection position of the workpiece inspection apparatus 200 is a position outside the movement locus of the side surface of the workpiece W when the elevation rotation mechanism 22 raises and lowers the workpiece W.
- the rotating arm 202 is connected to a motor (not shown) and is rotated by the driving force of the motor.
- the motor is connected to the control unit 25 (FIG. 5A).
- the control unit 25 controls operations such as normal rotation, reverse rotation, and stop of the motor based on instruction information from the operator.
- FIG. 6 is a side view of the circulation mechanism 50 inside the shot blasting apparatus 10 as viewed from the right side.
- the circulation mechanism 50 is a mechanism for circulating the projection material projected by the projector 20 to the projector 20.
- a screw conveyor 52 is provided below the processing zone 18.
- the screw conveyor 52 is horizontally disposed so as to extend in the front-rear direction of the apparatus, and is connected to a motor 52M provided on the back side of the apparatus.
- the screw conveyor 52 rotates around the longitudinal axis by the operation of the motor 52M, and conveys the projection material dropped from the processing zone 18 to the back side of the apparatus in the longitudinal direction of the screw conveyor 52.
- a lower end portion of a bucket elevator 54 serving as a transport mechanism extending in the vertical direction is disposed on the downstream side in the transport direction of the screw conveyor 52.
- the bucket elevator 54 is a device that conveys the projection material and the like supplied from the screw conveyor 52 to the upper part of the device. The configuration of the bucket elevator 54 will be described later.
- FIG. 7A is a cross-sectional view taken along line 7A-7A in FIG. 6,
- FIG. 7B is a cross-sectional view taken along line 7B-7B in FIG. 6, and
- FIG. 7 is a cross-sectional view taken along line 7C-7C in FIG.
- FIG. 8 is a cross-sectional view taken along line 8-8 in FIG.
- the upper portion of the shot blasting apparatus 10 has an inlet 56 ⁇ / b> A of a separator 56 corresponding to the upper part of the bucket elevator 54 (the right side in FIG. 8).
- the separator 56 is a wind-selective separator, and applies a stream of air to the projection material and dust thrown out from the bucket elevator 54 and supplied from the inlet 56A, and a lightweight object placed on the stream and a heavy object falling.
- the separator 56 discharges an appropriate projecting material after separating and removing the dust from the projecting material and the dust to the lower side of the apparatus.
- the discharge position 56Z of the projection material by the separator 56 is set on the front side of the apparatus at the lower end portion of the bucket elevator 54 (the left side in FIG. 8).
- FIG. 3 shows the shot blasting apparatus 10 in a plan view. As shown in FIG. 3, the settling chamber 58 is connected to a sieve portion 60 and a dust collector 62. As shown in FIG. 3 and FIG. 4, which is a rear view of the shot blasting apparatus 10, a control panel 64 is disposed on the back side of the dust collector 62.
- the settling chamber 58 shown in FIG. 3 separates the dust contained in the mixture containing the projection material thrown out from the upper part of the bucket elevator 54 into fine powder and coarse powder.
- the separated fine powder is sucked together with air to the dust collector 62, and the coarse powder flows to the sieve unit 60.
- the dust collector 62 filters the air containing fine powder and exhausts only the air into the atmosphere.
- the sieving unit 60 is configured to sieve coarse powder and return the projection material that can be used for sieving to the front side of the apparatus at the lower end of the bucket elevator 54.
- a shot supply port 66 ⁇ / b> A of the shot tank 66 is provided adjacent to the inlet 56 ⁇ / b> A of the separator 56 in the upper part of the shot blasting apparatus 10.
- the shot supply port 66A is disposed at a position corresponding to the front side of the apparatus (the left side in FIG. 8) of the upper part of the bucket elevator 54.
- the shot tank 66 stores the projection material supplied to the shot supply port 66A as a projection material for supply to the projector 20 (FIG. 6).
- the shot tank 66 is connected to the projector 20 via a flow rate adjusting device 68 and an introduction tube 70.
- the flow rate adjusting device 68 is a device for adjusting the flow rate of the projection material, and includes a shot gate (not shown) that can open and close the opening for supplying the projection material.
- FIG. 9 is a schematic schematic perspective view showing the configuration of the bucket elevator 54.
- the bucket elevator 54 includes pulleys 54A and 54B arranged at the upper and lower portions of the shot blasting apparatus 10, and the upper pulley 54A is It is connected to a driving motor 54M (FIG. 9) and can be driven to rotate.
- a single endless belt 54C is wound around the pair of upper and lower pulleys 54A and 54B, and the endless belt 54C is configured to rotate by a motor 54M via the pulley 54A.
- a plurality of first buckets 54X arranged at regular intervals in the longitudinal direction of the endless belt 54C are attached to one end in the width direction of the endless belt 54C.
- a plurality of second buckets 54Y arranged in parallel with the first bucket 54X are attached to the other end in the width direction of the endless belt 54C so as to be arranged at regular intervals in the longitudinal direction of the endless belt 54C.
- the first row conveyance unit 55A configured by the plurality of first buckets 54X conveys the projection material and dust from the apparatus lower side to the apparatus upper side, and enters the inlet 56A of the separator 56. It becomes a conveyance part to supply to.
- the second row transport unit 55B configured by the plurality of second buckets 54Y allows the projection material discharged from the separator 56 to be moved from the apparatus lower side to the apparatus upper side. It becomes a conveyance part which conveys to and supplies to the shot supply port 66A of the shot tank 66.
- the first row transport unit 55A and the second row transport unit 55B are driven by a common motor 54M.
- a partition portion 57 is provided in the vicinity of the lower portion of the endless belt 54C.
- the partition 57 partitions the first row transport unit 55A and the second row transport unit 55B (FIG. 7A).
- the projector 20 of this embodiment is a centrifugal projection that projects a projection material onto a small work W (for example, a gear having a diameter of 100 mm to 200 mm, a height of about 45 to 50 mm, and a stacking height of about 250 mm).
- a small work W for example, a gear having a diameter of 100 mm to 200 mm, a height of about 45 to 50 mm, and a stacking height of about 250 mm.
- the spread (projection angle) of the projected projection material is about 30 ° when viewed from the direction of the rotation axis of the impeller 100.
- the projection position of the projection material by the projector 20 is the vertex, and the vertex when the both ends of the surface of the workpiece W arranged at the processing position facing the projector 20 is connected.
- the size, position, etc. of the workpiece W are set so that the angle (center angle) of the workpiece W is within 30 °, and the work surface of the workpiece W is sufficiently processed by the projection material from the projection material 20. Is done.
- the small workpiece W used in the shot blasting apparatus 10 of the present embodiment is the same size as a workpiece that is shot with an air-type injection device that is an apparatus that injects compressed air containing a projection material from a nozzle.
- FIG. 10 is a front view of the projector 20, and FIG. 11 is an exploded side view of the projector 20.
- the vertical cross-section of the projector 20 in a side view is the same as the vertical cross-section shown in FIG. 24 showing the projector 21 of the second embodiment to be described later, except for the assembly portion of the drive motor 76. Therefore, FIG. 24 will be referred to as appropriate in the description of this embodiment.
- the projector 40 includes a case main body 72.
- the case main body 72 is formed in a trapezoidal cone shape in outer shape, and the bottom side (the lower side in FIG. 10) is opened to become the projection portion side of the projection material.
- the base 72 ⁇ / b> A extends from the bottom side of the case main body 72 in a direction away from each other, and is fixed to the side wall 12 ⁇ / b> A (FIG. 1) of the cabinet 12.
- a through hole through which the hub 82 and the like are inserted is formed in one side portion 72B of the case main body 72.
- a through hole through which the introduction tube 70 is inserted is formed in the other side portion 72 ⁇ / b> C of the case main body 72.
- a lid 80 is attached to the top of the case main body 72, and a through hole through which an upper portion of the liner 78 is inserted is formed in the lid 80.
- the liner 78 is attached to the inside of the case main body 72.
- a control cage 92 is disposed in the center of the inside of the case main body 72.
- the control cage 92 is attached to the side portion 72 ⁇ / b> C of the case main body 72 via a front cover 88.
- the control cage 92 has a cylindrical shape, is arranged concentrically with the rotation shaft 76X of the drive motor 76, and is configured such that the projection material is supplied from the introduction cylinder 70 to the inside.
- An annular bracket 96 and a seal member 98 are disposed between the inner periphery of the control cage 92 and the end of the introduction tube 70. A part of the introduction cylinder 70 is pressed by an introduction cylinder holder 86 (FIG. 11).
- one opening 92X is formed in the outer peripheral wall 92A of the control cage 92 so as to penetrate the outer peripheral wall 92A and serve as a discharge portion for the projection material.
- FIG. 12 which is a side view of the control cage 92
- the opening 92X of the control cage 92 is set in a rectangular shape including two sides parallel to the cylindrical axis CL.
- a cylindrical portion 82A of a hub 82 which is a flanged cylindrical body, is fixed to the outer periphery of the rotary shaft 76X of the drive motor 76 shown in FIG.
- a center plate 90 is fixed to the hub 82 with bolts.
- the distributor 94 is fixed to the front end portion 76 ⁇ / b> A of the rotating shaft 76 ⁇ / b> X of the drive motor 76 with a bolt 84 via the center plate 90.
- the cylindrical distributor 94 includes a plurality of radially extending blades 94 ⁇ / b> A and a plurality of openings arranged at equal intervals in the circumferential direction. It is arranged inside the control cage 92 so as to form a gap.
- the distributor 94 is rotated by the operation of the drive motor 76 (see FIG. 11), and rotates inside the control cage 92.
- the projection material supplied from the introduction cylinder 70 to the inside of the control cage 92 is stirred in the distributor 94, and is distributed through the opening of the distributor 94 by centrifugal force from the opening of the rotating distributor 94. 94 and supplied to the gap between the control cage 92.
- the projection material supplied to the gap moves in the rotation direction along the inner circumferential surface of the control cage 92, and is discharged radially outward from the opening 92X of the control cage 92.
- the discharge direction of the projection material from the opening 92X of the control cage 92 is the rotation direction of the impeller 100 (arrow) with respect to the radial direction from the rotation center of the distributor 94 (the same as the rotation center C of the impeller 100 described later). R direction).
- a flange 82B extending radially outward from one axial end of the cylindrical portion 82A of the hub 82 is fixed to the annular first side plate 102A of the side plate unit 102 with a bolt. .
- the side plate unit 102 constitutes a part of the impeller 100 disposed on the outer peripheral side of the control cage 92.
- the impeller 100 is attached to a rotation shaft 76 ⁇ / b> X of the drive motor 76 via a hub 82.
- the impeller 100 includes a first side plate 102A and an annular second side plate 102B disposed to face the first side plate 102A at an interval.
- the first side plate 102A and the second side plate 102B are connected by a connecting member 102C.
- the impeller 100 includes a plurality of blades (blades) 104 disposed so as to extend radially outward of the control cage 92 between the first side plate 102A and the second side plate 102B.
- the impeller 100 is rotated in the circumferential direction of the control cage 92 by obtaining a rotational force by the operation of the drive motor 76 (FIG. 11).
- the rotation direction of the impeller 100 and the rotation direction of the distributor 94 are set in the same direction.
- Each blade 104 is disposed so as to be inclined such that the radially outer end is located on the rear side in the rotational direction (arrow R direction) of the impeller 100 with respect to the radial direction from the radially inner end. It is arranged along the outer periphery of 92.
- the blade 104 of the impeller 100 is seen on the upper side of the apparatus, the processing zone 18 side, and the lower side of the apparatus when viewed in the direction of the rotation center line of the impeller 100.
- the rotation direction of the impeller 100 (see the direction of arrow R) is set so as to move sequentially.
- FIG. 13 is a perspective view of the blade 104
- FIG. 14 is a cross-sectional view of the impeller 100 as viewed from the front.
- the surface 106 on the rotational direction side of the blade 104 is provided with a rearward inclined portion 110 that is inclined toward the rear side in the rotational direction at a radially inward (base end) side portion.
- the rearwardly inclined portion 110 is preferably inclined rearward in the rotational direction by an angle of 30 ° to 50 ° with respect to the radial direction of the impeller 100, and is inclined 40 ° in this embodiment.
- a non-backward inclined portion extending from the rotation center C of the impeller 110 in a substantially radial direction (radial direction line L2 direction). 114 is formed on the front end side of the surface 106 of the blade 104 (that is, the radially outward side of the backward inclined portion 110).
- the length in the radial direction of the backward inclined portion 110 is set longer than the length in the radial direction of the non-backward inclined portion 114.
- a curved portion 112 is formed between the backward inclined portion 110 and the non-backward inclined portion 114.
- the non-backward tilting portion 114 only needs to be set to have an inclination angle backward in the rotation direction smaller than that of the rearward tilting portion 110.
- the back surface 108 opposite to the front surface 106 of the blade 104 is provided with an inclined portion 116 inclined at the rear side in the rotational direction larger than the rear inclined portion 110 with respect to the radial direction.
- a raised portion 118 is formed to project in the radially intermediate portion. In the raised portion 118, the concave curved portion on the radially outer side of the impeller 100 is in contact with the connecting member 102C.
- side wall portions 120 extending from the surface 106 toward the outer side in the thickness direction of the blade 104 are formed on both sides of the surface 106 of the blade 104.
- a base end side step portion 122 that protrudes stepwise outward in the width direction of the side wall portion 120 is formed on the side wall portion 120 at the base end of the blade 104.
- a front end side step portion 124 that protrudes stepwise outward in the width direction of the side wall portion 120 is formed on the side of the front end portion of the side wall portion 120.
- the base end side stepped portion 122 and the front end side convex portion 124 extend while slightly tilting toward the base end portion side (lower side in the figure) in the direction from the back surface 108 side toward the front surface 106 side.
- the side wall 120 is a part of the blade 104 that is fitted into the groove of the first side plate 102A and the second side plate 102B shown in FIG. Further, the base end side stepped portion 122 and the distal end side convex portion 124 of the side wall portion 120 shown in FIG. 13 are the portions of the blade 104 that come into contact with the groove bottom surfaces of the first side plate 102A and the second side plate 102B shown in FIG. Become.
- FIG. 21 to FIG. FIGS. 21 and 22 are cross-sectional views from the same direction as FIG. 5B, showing each step of shot processing by the shot blasting apparatus.
- the workpiece W is loaded into the loading / unloading zone 16 and set in the workpiece receiving unit 24.
- the inner lid 36 is lowered by operating the first cylinder mechanism 34.
- the second cylinder mechanism 40 is operated to lower the pressing part 48, and the work W is pressed from above by the pressing part 48 through the cap 23.
- the jack 32 is operated to lower the work W and the inner lid 36.
- the workpiece W is arranged at the first projection position 18A, which is the first machining position in the machining zone 18, and the inner lid 36 is arranged at the second position 36Y so that the carry-in / out zone 16 and the machining zone 18 are separated. Partition.
- the motor 28 operates in this state, the workpiece W rotates about the vertical axis, and when the drive motor 76 (FIG. 11) operates, the impeller 100 shown in FIG. 23A rotates and projects. The material is projected.
- surface processing is performed on the entire circumference of the workpiece W.
- the workpiece W arranged mainly at the lower part is shot.
- the inner lid 36 partitions the carry-in / out zone 16 and the processing zone 18, thereby preventing the projection material from leaking to the carry-in / out zone 16 side.
- the impeller 100 moves in the order of the apparatus upper side, the processing zone 18 side, and the apparatus lower side when viewed in the direction of the rotation center line of the impeller 100.
- the rotation direction (see the arrow R direction) is set. Even with such a configuration, leakage of the projection material to the upper side of the apparatus can be suppressed.
- the pressing portion 48 provided in the lifting / lowering rotation mechanism 22 can penetrate the inner lid 36, and can press the work W from the upper side and rotate with the work W around the vertical axis. Yes. For this reason, even if a plurality of workpieces W supported by the lifting / lowering rotation mechanism 22 are stacked, the workpieces W can be stably rotated around the axis in the lifting / lowering direction.
- the shot gate of the flow rate adjusting device 68 (see FIG. 6) is closed, and the projection of the projection material is stopped. Then, while rotating the workpiece W about the vertical axis, the workpiece W is lowered by the operation of the jack 32 as shown in FIG. 22B, and is the second machining position in the machining zone 18. It arrange
- the shot gate of the flow rate adjusting device 68 (FIG. 6) is closed, and the projection of the projection material is stopped again. Then, while rotating the workpiece W about the vertical axis, as shown in FIG. 22C, the workpiece W is lowered by the operation of the jack 32 and is the third machining position in the machining zone 18. Arranged at three projection positions 18C.
- a shot material is projected from the projector 20 shown in FIG. 23C by opening the shot gate of the flow rate adjusting device 68 (FIG. 6).
- a portion of the plurality of stacked workpieces W arranged mainly at the upper portion is shot.
- the jack 32 is operated, and the pressing portion 48, the inner lid 36, and the workpiece W are raised while maintaining the relative positional relationship between the pressing portion 48 and the inner lid 36 and the workpiece W. And the jack 32 is stopped when the height position of the clearance gap between the holding
- the rotary arm 202 is operated, and the workpiece inspection device 200 in the retracted position is inserted into the gap between the pressing portion 48 and the inner lid 36 and the workpiece W, and the inspection position (FIG. 5B). To the position indicated by the two-dot chain line).
- the jack 32 is operated to raise the uppermost gear (object) of the workpiece W to a position surrounded by the workpiece inspection apparatus 200, and then the jack 32 is stopped. Then, the workpiece inspection device 200 performs a nondestructive inspection of the state of the side of the uppermost gear of the workpiece W.
- the jack 32 is operated to raise the second gear from the top of the workpiece W to a position surrounded by the workpiece inspection device 200, and then the jack 32 is stopped. Then, the workpiece inspection device 200 performs a nondestructive inspection of the state of the side portion of the second gear from the top of the workpiece W.
- FIG. 5B shows a state in which the workpiece inspection apparatus 200 indicated by a two-dot chain line surrounds the side surface of the lowermost gear of the workpiece W.
- the non-destructive inspection of the workpiece W by the workpiece inspection device 200 is performed after the surface processing of the workpiece W by the projector 20.
- the workpiece W is carried out.
- the procedure up to is as follows.
- the shot gate of the flow rate adjusting device 68 (FIG. 6) is closed at the timing when the desired surface processing is performed on the workpiece W, and the projection of the projection material is stopped. Further, the drive motor 76 (FIG. 11) of the projector 20 is stopped. Thereafter, by operating the jack 32 (FIG. 21B), the workpiece W, the pressing portion 48, and the inner lid 36 are raised as shown in FIG. 21B. Then, the workpiece W, the pressing portion 48 and the inner lid 36 are arranged in the carry-in / out zone 16.
- the projector 20 is installed on the side wall 12 ⁇ / b> A of the cabinet 12 on the side of the processing zone 18. That is, since the projector 20 is arranged on the lower side of the cabinet 12 (the apparatus lower side), even if the shot tank 66 and the like shown in FIG. Can be suppressed.
- the projection material that has been projected and dropped by the projector 20 is conveyed to the lower end side of the bucket elevator 54 by the screw conveyor 52.
- the screw conveyor 52 conveys dust generated by the pulverization of the projection material, in addition to the reusable projection material.
- the first row conveyance unit 55A of the bucket elevator 54 shown in FIG. 7B and FIG. 9 conveys the projection material and dust from the apparatus lower side to the apparatus upper side, and FIG. 7B and FIG. Supply to the inlet 56A of the separator 56 shown.
- the separator 56 separates and removes dust from the projection material and dust supplied from the inlet 56 ⁇ / b> A, and discharges the projection material to the lower end side of the second row conveyance unit 55 ⁇ / b> B of the bucket elevator 54.
- the second row conveyance section 55B of the bucket elevator 54 conveys the projection material discharged from the separator 56 (FIG. 7B) from the apparatus lower side to the apparatus upper side, and the shot tank 66 shown in FIG. 7A.
- the shot tank 66 stores the projection material supplied to the shot supply port 66 ⁇ / b> A for supply to the projector 20.
- the shot tank 66 supplies the projection material to the projector 20 via the flow rate adjusting device 68 and the introduction cylinder 70.
- the opening 92 ⁇ / b> X of the control cage 92 is set to a rectangular shape including two sides parallel to the cylindrical axis CL of the control cage 92. . For this reason, the projection material is intensively discharged from the same circumferential position of the control cage 92.
- the impeller 100 disposed on the outer peripheral side of the control cage 92 is discharged from the opening 92 ⁇ / b> X of the control cage 92 because the plurality of blades 104 rotate in the circumferential direction of the control cage 92.
- the projected material is accelerated by the blade 104 and projected toward the workpiece W.
- FIG. 15A shows a projection distribution when projected using the control cage 92 of FIG.
- the distribution of the projection material is along a projection distribution curve having one peak at the center of the distribution width.
- FIG. 15B is a plan view showing a projection range when projected using the control cage 92 of FIG.
- the shot blasting device 10 of the above embodiment after the surface 106 of the blade 104 of the impeller 100 is inclined backward in the rotation direction (arrow R direction) with respect to the radial direction (radial direction line L1) of the impeller 100. An inclined portion 110 is formed. Thereby, the projection material can be collected on the surface 106 of the blade 104.
- FIG. 16 is a schematic diagram for explaining the action of the impeller I1 in which the blade B1 is inclined backward (inclined from the radial direction of the impeller I1 to the rotation direction (arrow R direction) rear side).
- FIG. 17 is a schematic diagram for explaining the operation of the proportional impeller I2 in which the blade B2 extends in the radial direction. 16A and 16B, (A) to (G) are arranged in time series.
- the proportional action will be described with reference to FIG.
- the projecting material a, the projecting material b, and the projecting material c are rotated from the opening of the control cage C2 in the rotational direction of the impeller 100 with respect to the radial direction. It is assumed that the discharge is sequentially performed at regular intervals in a direction inclined in the direction of arrow R.
- each of the projection materials a, b, and c is accelerated toward the tip side of the blade B2, but the timing of hitting the blade B2 is as described above, and the acceleration of the projection material increases toward the tip side of the blade B2. For this reason, as shown in FIG. 17F, the projection materials a, b, and c cannot be collected on the blade B2. And the projection material a discharged
- the projection material s1, the projection material s2, and the projection are projected from the opening of the control cage C1.
- the material s3 is discharged sequentially.
- the blade is inclined rearward in the rotation direction of the impeller, the discharge direction of the projection material is inclined in the rotation direction of the impeller 100, and further, the surface of the blade Since the rearwardly inclined portion is provided, the first ejected projection material s1 and the second ejected projection material s2 hit the surface of the blade B1 before the last ejected projection material s3 It hits the surface and is accelerated toward the tip side of the blade B1.
- the second ejected projection material s2 hits the surface of the blade B1.
- the radial position on the blade B1 of the projection material s3 already accelerated on the blade B1 is substantially the same position as the radial position on the blade B1 of the projection material s2.
- the projecting materials s3 and s2 are generally accelerated together toward the tip side of the blade B1.
- the projection material s1 discharged first hits the surface of the blade B1.
- the radial positions on the blade B1 of the projection materials s3 and s2 already accelerated on the blade B1 are substantially the same positions as the radial positions on the blade B1 of the projection material s1.
- the projection materials s3, s2, and s1 are accelerated toward the front end side of the blade B1 in a mass.
- the projecting materials s3, s2, and s1 are generally made into one lump and simultaneously projected.
- the projection materials s3, s2, and s1 collected on the blade B1 are projected, so that the projection distribution can be concentrated. For this reason, useless projection with respect to the workpiece
- the inclination angle of the rearward inclined portion By setting the inclination angle of the rearward inclined portion to the rear side in the rotation direction to 30 ° or more, a sufficient time difference between the projection material and the blade can be ensured, so that the degree of concentration of the projection distribution can be increased. Furthermore, by making the rotation direction rear side inclination angle of the rearward tilt part 50 ° or less, the time difference when the projection material rides on the blade can be made a more preferable time difference in concentrating the projection material on the blade, The length of the blade can be reduced. If the length of the blade is suppressed, the weight of the blade and the cost of parts are suppressed, and there are advantages in terms of workability at the time of assembly.
- FIG. 18 shows a case where the blade extends along the radial direction from the rotation center of the impeller (hereinafter simply referred to as “the blade is not inclined”), and a case where the blade is relative to the radial direction of the impeller.
- a projection distribution graph comparing the case of tilting backward in the rotational direction (arrow R direction) (hereinafter simply referred to as “the blade is tilted backward”).
- the vertical axis indicates the projection ratio
- the horizontal axis indicates the projection range at the processing position of the plane and its extended position at an angle where the straight line along the projection center is 0 ° from the projection position of the projection material by the projector. Is shown.
- a diagram shown by a solid line shows the case of the present embodiment
- a diagram shown by a dotted line shows a case where the blade is not tilted.
- the projection distribution is concentrated in the vicinity of 0 ° compared to the case of comparison (see the dotted line).
- the projection ratio is higher in the case of the present embodiment (see the solid line) than in the case of the proportionality (see the dotted line).
- positioned in a process position is 30 degrees by the rotary shaft direction view of an impeller.
- the proportion of projection effective for surface processing can be increased as compared with the case of comparison (see the dotted line).
- an air-type injection device that injects compressed air containing a projection material from a nozzle.
- the air-type injection device has an extremely small amount that can be projected by accelerating the projection material compared to the power consumption for generating compressed air, and the power efficiency for projection is poor. That is, in the case of an air-type injection device, power consumption increases.
- the projector 20 of this embodiment is a centrifugal projector, it can project a projection material more efficiently than power consumption. For this reason, if it replaces with an air type injection device and the projector 20 of this embodiment is applied, power consumption and by extension, running cost can be reduced significantly.
- a non-backwardly inclined portion 114 extending in the substantially radial direction (radial direction line L2 direction) from the rotation center C of the impeller 100 is formed on the front end side of the surface 106 of the blade 104.
- FIG. 19 is a schematic diagram for explaining the projection speed.
- FIG. 19A shows a case where the blade B3 is not inclined
- FIG. 19B shows a case where the blade B1 is inclined backward by 40 °.
- f4 is the speed in the direction of centrifugal acceleration
- f5 is the speed in the tangential direction of the tip of the blade B3
- f6 is the combined speed of f4 and f5.
- f1 is the speed in the direction of centrifugal acceleration
- f2 is the speed in the tangential direction of the tip of the blade B1
- f3 is the combined speed of f1 and f2.
- the rotating outer diameter and the rotating peripheral speed of the blade are the same.
- the combined speed f3 when the blade B1 is tilted backward is smaller than the combined speed f6 when the blade B3 is not tilted. For this reason, when the conditions other than the inclination of the blade are the same, when the blade B1 is inclined backward, the projection speed becomes slower than when the blade B3 is not inclined.
- FIG. 20 shows a graph comparing the power consumption when the projection speed is equivalent to 70 m / s between the case where the blade is not inclined and the case where the blade is inclined backward.
- the vertical axis represents power consumption
- the horizontal axis represents the projection amount per unit time.
- a diagram indicated by a solid line indicates a case where the blade is inclined backward
- a diagram indicated by a one-dot chain line indicates a case where the blade is not inclined. As shown in this figure, simply tilting the blade backward is disadvantageous in terms of power consumption.
- the impeller 100 is attached to the rotating shaft 76 ⁇ / b> X of the drive motor 76 via the hub 82. For this reason, for example, the whole apparatus is reduced in size compared with the case where it is connected to the drive motor via a belt.
- the projection material is projected after increasing the speed at the non-backward inclined portion 114, an increase in the number of revolutions per unit time of the impeller 100 can be suppressed, and an increase in power consumption can be suppressed. Can do.
- the length of the rearwardly inclined portion 110 is set to be longer than the length of the non-backwardly inclined portion 114 when viewed from the direction of the rotation axis of the impeller 100. For this reason, the speed of the projection material can be sufficiently increased by the non-backward inclined portion 114.
- the surface 106 of the blade 104 is formed with a curved portion 112 that gently connects the backward inclined portion 110 and the non-backward inclined portion 114. For this reason, after collecting the projection material by the backward inclined portion 110 of the blade 104, the speed of the projection material can be gradually increased.
- the direction in which the projection material is discharged from the opening 92 ⁇ / b> X of the control cage 92 is inclined to the front side in the rotational direction of the impeller 100. For this reason, the timing at which the projection material discharged first from the opening 92X of the control cage 92 contacts the surface 106 of the blade 104 can be delayed, and the projection material is more effective at the rearwardly inclined portion 110 of the surface 106 of the blade 104. Can be focused.
- the inclined portion 116 is provided on the back surface 108 of the blade 104.
- the projection material discharged from the opening 92X hits the base end portion of the back surface 108 of the blade 104 and is reflected, the reflection direction of the projection material is deflected by the inclined portion 116, and the amount of reflection between the blades 104 can be suppressed. . For this reason, disturbance of the flow of the projection material between the blades 104 can be suppressed.
- the shot supply port 66A of the shot tank 66 is set adjacent to the inlet 56A of the separator 56, and the separator 56 is disposed above the shot tank 66. Since it is not arranged, the height of the entire apparatus can be suppressed. Further, as shown in FIG. 9, the bucket elevator 54 uses a common motor 54M and a single endless belt 54C, so that the number of parts can be reduced and the apparatus can be miniaturized.
- the first row transport unit 55A and the second row transport unit 55B (see FIG. 7 (A)) is provided. For this reason, it is possible to prevent the mixture (projection material and dust) before the dust is separated and removed by the separator 56 and the projection material after the dust is separated and removed by the separator 56 from being mixed.
- the partition part of 55 A of 1st row conveyance parts and 55B of 2nd row conveyance parts (FIG. 7 (A)) is provided in the full height part of the bucket elevator 54, the structure of the bucket elevator 54 will become complicated, but this implementation This is not the case in the form.
- the projection material is contained in each of the 1st bucket 54X and the 2nd bucket 54Y in the intermediate part of the bucket elevator 54, it can be said that a partition part is unnecessary.
- the projection amount can be reduced.
- FIGS. 24 and 25 may be used instead of the projector 20 shown in FIGS. 10 and 11.
- FIG. 24 is a longitudinal sectional view of the projector 21 according to the modification in a side view
- FIG. 25 is an exploded side view of the projector 21.
- the projector 21 is different from the configuration of the first embodiment in that the rotating shaft of the drive motor is not directly fixed to the hub 82.
- Other configurations are the same as those in the first embodiment. Therefore, the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.
- a through hole through which the tip of the bearing unit 74 and the like is inserted is formed in the right side portion 72B of the case main body 72 in the drawing, and the bearing unit 74 is formed in the inner central portion on the right side of the case main body 72 in the drawing.
- the distal end portion 74A is disposed.
- a tip end portion 74 ⁇ / b> A of the bearing unit 74 is attached to the side portion 72 ⁇ / b> B on the right side of the case main body 72 in the drawing.
- the bearing unit 74 includes a bearing 74B and rotatably supports the rotary shaft 77X.
- a second pulley 79 is fixed to the base end side of the rotary shaft 77X.
- a belt 81 is wound around the second pulley 79 and a first pulley (not shown).
- the first pulley is fixed to a rotating shaft of a drive motor (not shown). As a result, the rotational force of the drive motor is transmitted to the rotation shaft 77X.
- a cylindrical portion 82A of a flanged cylindrical hub 82 is disposed on the outer peripheral side of the distal end portion 77A of the rotating shaft 77X.
- a center plate 90 is fixed to the hub 82 with bolts.
- the hub 82 is fixed to the tip 77A of the rotation shaft 77X with a key.
- the projection amount can be reduced. Further, in the case of such a modification, the size of the entire apparatus is increased, but it is advantageous in terms of suppressing power consumption.
- FIG. 26 is a schematic configuration diagram in plan view of the shot peening apparatus 130 according to the present embodiment.
- examples of the work W of the shot peening process of the present embodiment include products such as gears. The surface roughness of the workpiece W is reduced by the shot peening treatment, and the fatigue strength is improved.
- the shot peening apparatus 130 includes a cabinet 132.
- a centrifugal projector 20 similar to the shot blasting apparatus of the first embodiment is installed on a side portion in the cabinet 132.
- the rotation center C of the impeller 100 extends in the vertical direction.
- a product placement unit 134 is provided as a support mechanism that supports the workpiece W at a processing position where surface processing by the projector 20 is possible.
- the product placement unit 134 includes a large table 138, and a plurality of small tables 142 are arranged on the large table 138 at positions on the concentric circle of the large table 138 at equal intervals in the circumferential direction.
- the large table 138 can be rotated (revolved) about a rotary shaft 136 in the vertical direction, and is disposed at a position including a projection range in which the projection material is projected by the centrifugal projector 20.
- the small table 142 has a diameter smaller than that of the large table 138, and is provided with a rotation shaft 140 parallel to the rotation shaft 136 of the large table 138 so that the small table 142 can rotate (spin), and the workpiece W is placed thereon.
- a mechanism for holding the workpiece W is provided at a position on the large table 138 corresponding to the projection range from the projector 20.
- This mechanism includes a pressing portion that can press the work W on the small table 142 from above and rotate together with the work W.
- FIGS. 10 and 11 the same configuration as the projector 20 (FIGS. 10 and 11) used in the shot blasting apparatus of the first embodiment except that the shape of the opening of the control cage is different.
- the control cages 150, 152, 154, 156, 158 shown in FIGS. 27A to 27E are formed in a cylindrical shape and supplied with a projection material therein.
- the centrifugal projector provided with the control cages 150, 152, 154, 156, 158 is a projector that is installed in a shot processing apparatus and projects a projection material.
- the projector provided with the control cages 150, 152, 154, and 156 shown in FIGS. 27A to 27D is a projector according to the embodiment of the present invention, and FIG.
- the projector provided with the control cage 158 shown is a projector according to a reference example not included in the present invention.
- the projection position of the projection material by the projector is the apex as viewed from the rotational axis direction of the impeller.
- the dimension and position of the workpiece W so that the angle of the vertex (vertical angle) when connecting both ends of the surface facing the projector of the workpiece W arranged at the machining position is 50 ° to 80 °. Etc. are set.
- a first penetrating portion 160 and a second penetrating portion 162 are formed as a projection material discharge portion. Both the first penetration part 160 and the second penetration part 162 constitute an opening of the control cage 150.
- the first through portion 160 is set between two parallel sides 160A and 160B that are parallel to the cylindrical axis CL of the control cage 150 and face each other.
- the second penetrating portion 162 is offset with respect to the first penetrating portion 160 in the circumferential direction of the outer peripheral wall 150A of the control cage 150 and in the direction of the cylindrical axis CL, and the second parallel two sides 162A and 162B. Is set between.
- the first penetrating portion 160 and the second penetrating portion 162 are separated from each other in the direction of the cylindrical axis CL of the control cage 150, and approximately half of each overlaps when viewed in the direction of the cylindrical axis CL of the control cage 150. Yes.
- an opening 164 is formed through the outer peripheral wall 152A of the control cage 152 shown in FIG.
- the opening 164 includes a first through part 166 and a second through part 168.
- the first penetrating portion 166 is set between first parallel two sides 166A and 166B that are parallel to the direction perpendicular to the cylindrical axis CL of the control cage and that face each other.
- the second penetrating portion 168 is parallel to and opposed to the first penetrating portion 166, being offset in the circumferential direction of the outer peripheral wall 152 ⁇ / b> A of the control cage 152 and the cylindrical axis CL of the control cage 152.
- the second two sides 168A and 168B are set.
- the first penetrating portion 166 and the second penetrating portion 168 are in communication with each other, and approximately half of each overlaps when viewed in the direction of the cylindrical axis CL of the control cage 152.
- an opening 170 is formed through the outer peripheral wall 154A of the control cage 154 shown in FIG.
- the opening 170 includes a first through part 172 and a second through part 174.
- the first penetrating portion 172 is set between first parallel two sides 172A and 172B which are parallel to the cylindrical axis CL of the control cage and face each other.
- the second penetrating portion 174 is offset in parallel to the first penetrating portion 172 in the circumferential direction of the outer peripheral wall 154A of the control cage 154 and in the direction of the cylindrical axis CL of the control cage 154, and is opposed to each other. It is set between the second two sides 174A and 174B.
- the first penetration part 172 and the second penetration part 174 are communicated with each other by a third penetration part 176.
- the third penetrating part 176 linearly connects the terminal of the side 172A of the first penetrating part 172 and the terminal of the side 174A of the second penetrating part 174, and the second penetrating part 172 and the terminal of the side 172B of the first penetrating part 172.
- the end of side 174B of penetration part 174 is connected with the shape of a straight line.
- the first penetrating portion 172 and the second penetrating portion 174 overlap each other substantially in half when viewed in the direction of the cylindrical axis CL of the control cage 154.
- an opening 178 is formed through the outer peripheral wall 156A of the control cage 156 shown in FIG.
- the opening 178 includes a first through part 180 and a second through part 182.
- the first penetrating portion 180 is set between first parallel sides 180A and 180B that are parallel to the cylindrical axis CL of the control cage and face each other.
- the second penetrating portion 182 is parallel to and opposed to the first penetrating portion 180 in the circumferential direction of the outer peripheral wall 156A of the control cage 156 and the cylindrical axis CL of the control cage 156.
- the second parallel sides 182A and 182B are set.
- the first penetrating portion 180 and the second penetrating portion 182 are slightly separated in the direction of the cylindrical axis CL when viewed in the direction perpendicular to the cylindrical axis CL of the control cage 156 (as viewed in the direction of FIG. 27D). As seen from the direction of the cylindrical axis CL of the control cage 156, substantially half of each overlaps.
- the third penetrating part 184 connects the terminal of the side 180A of the first penetrating part 180 and the terminal of the side 182A of the second penetrating part 182 in a stepwise manner, and the terminal of the side 180B of the first penetrating part 180 and the second penetrating part.
- the terminal of the side 182B of the part 182 is connected stepwise.
- the first through portions 160, 166, 172, 180 and the second through portions 162, 168 are discharged from positions shifted in the circumferential direction of the control cages 150, 152, 154 and 156. For this reason, the projection distribution from these projectors was discharged from the projection distribution of the projection material discharged from the first through portions 160, 166, 172, 180 and the second through portions 162, 168, 174, 182. It includes a distribution obtained by combining the projection distribution of the projection material.
- the first penetrating portions 160, 166, 172, 180 and the second penetrating portions 162, 168, 174, 182 are almost half over in the direction of the cylindrical axis CL of the control cages 150, 152, 154, 156. Since it is wrapped, each projection distribution of the projection material discharged from each of the first through portions 160, 166, 172, 180 and the second through portions 162, 168, 174, 182 is also approximately half of each distribution width. Overlapping in range. For this reason, as a whole projection distribution, a range with a large projection amount (a range in which projections are concentrated) is expanded.
- FIG. 28A schematically shows a projection distribution (upper part in the figure) and a projection range (lower part in the figure) by a projector equipped with control cages 150 and 152 (FIGS. 27A and 27B).
- FIG. 28B shows the projection distribution (upper part in the figure) and the projection range (lower part in the figure) by the projector provided with the control cages 154 and 156 (FIGS. 27C and 27D). It is shown schematically. From these figures, it can be seen that the range in which the projection amount is large is widened.
- the projector equipped with the control cages 150, 152, 154, and 156 shown in FIGS. 27A to 27D has a wide angle of 50 ° to 80 ° with respect to the projection material by the above configuration. Can be projected onto the workpiece.
- FIG. 18 a diagram indicated by a two-dot chain line shows a case of a projector provided with the control cage 152 shown in FIG. 27B (hereinafter referred to as “the case of the present embodiment”).
- the projection rate at 0 ° is lower than that in the case of comparison (see dotted line), but 0 ° in the case of this embodiment.
- the projection ratio at is higher than the projection ratio at ⁇ 25 ° and + 25 ° in the case of comparison.
- the present embodiment is more effective in the range of ⁇ 25 ° to ⁇ 40 ° and the range of + 25 ° to + 40 °.
- the projection ratio is higher than the proportional case.
- the projection is performed in the direction of the rotation axis of the impeller.
- the angle between the projection position of the projection material by the machine and the positions of both ends of the surface of the workpiece arranged at the machining position facing the projector is 50 ° to 80 ° ( It can be seen that the solid line) can increase the proportion of projection effective for surface processing, as compared to the case of proportionality (dotted line).
- FIG. 28C schematically shows a projection distribution (upper part in the figure) and a projection range (lower part in the figure) of the projector provided with the control cage 158 (FIG. 27E).
- a blade 190 shown in FIG. 29 may be used instead of the blade 104 shown in FIG. In FIG. 29, components that are substantially the same as the blade 104 in FIG.
- the back inclination part 110 shown by FIG. 14 inclines 40 degrees in the rotation direction back side with respect to the radial direction from the rotation center C of the impeller 100, and the inclination angle of a back inclination part Is preferably 30 ° to 50 °, but the inclination angle of the rearward inclined portion may be another angle such as 25 ° or 55 °, for example.
- the non-backward tilted portion formed on the tip end side on the surface of the blade may be any as long as the tilt angle from the rearward tilted portion to the rear side in the rotational direction is smaller.
- “the inclination angle to the rear side in the rotational direction is smaller than that of the rearward inclined portion” means that the inclination angle is smaller than the inclination angle to the rearward side in the rotational direction of the rearward inclined portion, or in the radial direction. Since the structure which extends and the structure which inclines in the rotation direction front side are also included, the non-rearly inclined part extends with respect to the radial direction from the rotation center of the impeller, or the rotation direction front side with respect to the radial direction. May be inclined. Moreover, the structure which does not provide a non-back inclination part may be sufficient.
- the radial length of the rearwardly inclined portion and the radial length of the non-backwardly inclined portion may be set equal. Furthermore, the structure which the back inclination part and the non-rear inclination part were directly connected without the curved part may be sufficient. Furthermore, the structure in which an inclination part is not formed may be sufficient.
- the inner lid may not be provided.
- the projector may be installed on the side wall of the cabinet on the side of the intermediate zone. Moreover, you may set the rotation direction of the impeller of the projector 20 contrary to the said embodiment.
- the pressing portion 48 shown in FIG. 5 presses the work W via the cap 23, but a form in which the pressing portion 48 directly presses the work may be employed.
- a mechanism for holding the workpiece on the workpiece receiving portion 24 side without providing the pressing portion 48 may be provided.
- the conveyance mechanism provided with the 1st row conveyance part and the 2nd row conveyance part, you may provide the screw conveyor corresponding to each of a 1st row conveyance part and a 2nd row conveyance part.
- the structure which provides separately the endless belt which comprises a 1st row conveyance part, and the endless belt which comprises a 2nd row conveyance part, and drives each endless belt with a separate drive motor may be sufficient.
- Shot blasting equipment (shot processing equipment) 12 Cabinet 12A Side wall of cabinet 16 Loading / unloading zone 18 Processing zone 18A First projection position (processing position) 18B Second projection position (processing position) 18B Third projection position (processing position) 20 Projector 21 Projector 22 Elevating and rotating mechanism (support mechanism) 36 Inner lid 36X First position 36Y Second position 38 Elevating mechanism 48 Holding part 50 Circulating mechanism 54 Bucket elevator (conveyance mechanism) 54C Endless Belt 54M Motor 54X First Bucket 54Y Second Bucket 55A First Row Transport Unit 55B Second Row Transport Unit 56 Separator 56A Inlet 57 Partition Portion 66 Shot Tank 66A Shot Supply Port 76 Drive Motor 82 Hub 92 Control Cage 92A Outer Wall 92X opening 94 distributor 100 impeller 104 blade 110 rearward tilting portion 112 bending portion 116 tilting portion 130 shot peening device (shot processing device) 134 Product Placement (Support Mechanism) 150, 152, 154, 156 Control cage 150A,
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Abstract
Description
ワークに投射材を投射する遠心式の投射機と、前記投射機による表面加工が可能な加工位置でワークを支持する支持機構とを備えたショット処理装置であって、
前記投射機が、円筒形状を有し、内部に投射材が供給され、側壁に前記投射材の排出口となる開口が形成されたコントロールケージと、
前記コントロールケージの外方で前記コントロールケージの径方向外方に延びるように配置された複数のブレードを備え前記コントロールケージの中心軸線を中心に回転する羽根車であって、前記ブレードには回転方向前方側の表面に回転方向後方側に傾斜した後傾部が設けられている、羽根車と、を備えている、
ことを特徴とするショット処理装置が提供される。
このため、コントロールケージの開口から先に排出された投射材がブレードの表面に接触する前に、コントロールケージの開口から後に排出された投射材がブレードの表面に接触してブレードの先端側へ向けて加速される。
これにより、先に排出された投射材がブレードの表面に接触する時点では、後から排出された投射材と先に排出された投射材とがブレードの表面の隣接した位置に集められる。そして、ブレードの表面の隣接した位置に集められた投射材が投射されるので、投射分布を集中させることができ、ワークに対する無駄な投射を抑えることができる。
前記開口は、二辺が前記コントロールケージの円筒軸心に平行な矩形形状を備えている。
前記羽根車の回転軸方向視で、前記投射機による投射材の投出位置と、前記加工位置に配置されたワークの前記投射機に向く面の両端との成す角度が30°以内となるワークの表面加工用とされ、
前記後傾部は、前記羽根車の径方向に対して回転方向後方側に30°~50°傾斜している。
前記後傾部は、前記ブレードの基端部側に形成され、
前記ブレードの先端部側には、前記後傾部より回転方向後方側への傾斜角が小さな非後傾部が形成されている。
前記羽根車は、駆動モータの回転軸にハブを介して取り付けられている。
前記後傾部の径方向長さが前記非後傾部の径方向長さよりも長く設定されている。
前記後傾部と前記非後傾部とをなだらかに繋ぐ湾曲部が設けられている。
前記コントロールケージの内側に配置され前記羽根車の回転方向と同じ方向に回転するディストリビュータを更に備え、
前記ディストリビュータが回転することで、前記コントロールケージの内側に供給された投射材が、前記ディストリビュータとコントロールケージとの間の間隙中を前記ディストリビュータの内周面に沿って移動し、前記コントロールケージの開口からの前記投射材の排出方向が前記羽根車の回転中心からの径方向に対して前記羽根車の回転方向前方側に傾く。
前記ブレードの前記羽根車の回転方向後方側の表面は、基端部に、径方向に対して傾斜部より大きく回転方向後方側に傾斜した傾斜部を備えている。
前記ワークが搬入出される搬入出ゾーンを内部の上方位置に、前記投射機により投射された投射材によって前記ワークの表面加工を施す加工ゾーンを内部の下方位置に、それぞれ有しているキャビネットと、
前記支持機構を構成し、前記ワークを支持しながら前記ワークを前記搬入出ゾーンと前記加工ゾーンとの間で昇降させ且つ該昇降方向を中心に回転可能な昇降回転機構と、を備えている。
前記搬入出ゾーンの上端側の位置する第一位置と、前記搬入出ゾーンと前記加工ゾーンとの間に位置する第二位置との間で昇降可能な内蓋と、
前記ワークを前記搬入出ゾーンに搬入出するとき前記内蓋を前記第一位置に配置し、前記ワークが前記加工ゾーンに配置されたとき前記内蓋を前記第二位置に配置するように、前記内蓋を昇降させる昇降機構と、を備えている。
前記昇降回転機構は、前記内蓋を貫通可能であり前記ワークを上方側から押さえて該ワークと共に前記昇降方向を中心に回転可能な押さえ部を有している。
前記搬入出ゾーンの側方側の側壁側にワーク検査装置をさらに備え、
該ワーク検査装置は、
前記昇降回転機構に支持されたワークに対して前記内蓋及び前記押さえ部が装置上方側に離間して配置されたとき、前記ワークと前記内蓋及び押さえ部との間に側方側から挿入可能な退避位置と、
前記退避位置の側方側の位置であって前記ワークの側面を包囲する検査位置と、の間で移動可能に支持されている。
前記投射機は、前記加工ゾーンの側方側において前記キャビネットの側壁部に配置されている。
前記投射機は、前記羽根車のブレードが、羽根車の回転中心線の方向に見て、装置上方側、前記加工ゾーンの側、装置下方側の順に移動するように羽根車の回転方向が設定されている。
前記投射機によって投射された投射材を前記投射機へ循環させる循環機構をさらに備え、
前記循環機構は、
上部に入口を有し該入口から供給された投射材及び粉塵から粉塵を分離除去して投射材を下部側に排出するセパレータと、
上部において前記セパレータの前記入口と隣接するショット供給口を有し該ショット供給口に供給された投射材を前記投射機への供給用として貯留するショットタンクと、
前記投射材及び粉塵を下部側から上部側へ搬送し前記セパレータの入口に供給する第一列搬送部と、前記第一列搬送部と並列に設けられ前記セパレータから排出された投射材を下部側から上部側へ搬送して前記ショットタンクのショット供給口に供給する第二列搬送部とを有する搬送機構と、を備えている。
前記搬送機構は、
前記第一列搬送部及び前記第二列搬送部を駆動する共通のモータと、
前記モータによって回転駆動される単一の無端ベルトと、
前記無端ベルトに取付けられ前記第一列搬送部を構成する複数の第一バケットと、
前記無端ベルトに前記第一バケットと並列して取付けられ前記第二列搬送部を構成する複数の第二バケットと、を有しているバケットエレベータと、備えている。
前記無端ベルトの下部に近接して前記第一列搬送部と前記第二列搬送部とを仕切る仕切部をさらに備えている。
投射材をワークに対して投射する遠心式の投射機であって、
円筒形状を有し、内部に投射材が供給され外周壁には投射材の排出部として開口が形成され、前記開口は前記円筒形状の軸心に平行な二辺を含む矩形形状を有しているコントロールケージと、
前記コントロールケージの径方向外方位置に配置され前記コントロールケージの周方向に回転する複数のブレードを備え、前記ブレードの回転方向前方側の表面に回転方向後方側に傾斜した後傾部が設けられている羽根車と、を備えている、
ことを特徴とする投射機が提供される。
前記羽根車の回転軸方向視で、前記投射機による投射材の投出位置と、前記加工位置に配置されたワークの前記投射機に向く面の両端との成す角度が30°以内となるワークの表面加工用とされ、
前記後傾部は、前記羽根車の径方向に対して回転方向後方側に30°~50°傾斜している。
ショット処理装置に設置されて羽根車の回転により投射材を投射する遠心式の投射機であって、
前記羽根車の回転軸方向視で、前記投射機による投射材の投出位置と、加工位置に配置されたワークの前記投射機に向く面の両端との成す角度が50°~80°以内となるワークの表面加工用とされ、
円筒形状を有し、内部に投射材が供給され外周壁には投射材の排出部として開口が形成され、前記開口は前記円筒形状の軸心に平行な二辺を含む矩形形状を有しているコントロールケージと、
前記コントロールケージの径方向外方位置に配置され前記コントロールケージの周方向に回転する複数のブレードを備え、前記ブレードの回転方向前方側の表面に回転方向後方側に傾斜した後傾部が設けられている羽根車と、を備え、
前記開口は、
前記コントロールケージの軸心に平行な二辺を含む矩形形状を有している第一貫通部と、
前記コントロールケージの軸心に平行かつ互いに対向する第二の平行な二辺を含む矩形形状を有し、前記第一貫通部に対し前記コントロールケージの周方向にオフセットしている第二貫通部と、を備え、
前記第一貫通部と前記第二貫通部とは、前記コントロールケージの円筒軸心の方向に各々の略半分がオーバーラップしている、
ことを特徴とする投射機が提供される。
図1~図23に沿って、本発明のショット処理装置の第1の実施形態であるショットブラスト装置10について説明する。なお、これらの図において、矢印FRは装置正面視の手前側を示しており、矢印UPは装置上方側を示しており、矢印LHは装置正面視の左側を示している。
図5(B)に示されるキャビネット12の内部空間の上部は、ワークWが搬入出される搬入出ゾーン16とされている。これに対して、キャビネット12の内部空間の下部は、ワークWに表面加工を施す加工ゾーン18とされている。
図5に示されるように、加工ゾーン18(図5(B))の側方にはキャビネット12の側壁部12Aに遠心式の投射機20が設置されている。投射機20は、図5(B)に示されるワークWに対して投射材を投射可能であり(図23)、ワークWの表面加工は、投射機20から投射された投射材によって行われる。なお、投射機20の詳細は、後述する。
このように、昇降サーボモータ32M、ボールネジ32C、昇降部材32S、ブラケット32A、及びガイド軸32Bが、昇降用のジャッキ32を構成している。昇降サーボモータ32Mは制御部25に接続されており、制御部25によって作動が制御されている。すなわち、制御部25は、操作者からの指示情報に基づいて、昇降サーボモータ32Mの正転、逆転、及び停止の制御を行う。
本実施形態では、図5(B)に示される状態から、ジャッキ32の作動によって、ワークW、内蓋36及び押さえ部48が、ワークWと内蓋36及び押さえ部48との相対位置関係を変えずに降下されると、退避位置のワーク検査装置200が、ワークWと内蓋36及び押さえ部48との間に側方側から挿入可能となっている。
さらに、ワーク検査装置200の退避位置は、昇降回転機構22によるワークWの昇降時及び昇降機構38による内蓋36の昇降時に、昇降する他の部材とワーク検査装置200が干渉しない位置に設定されている。
図7(A)、図7(B)及び図9に示されるように、バケットエレベータ54は、ショットブラスト装置10の上部及び下部に配置されたプーリ54A、54Bを備え、上側のプーリ54Aは、駆動用のモータ54M(図9)に接続されて回転駆動可能とされている。上下一対のプーリ54A、54Bには、単一の無端ベルト54Cが巻回され、無端ベルト54Cは、プーリ54Aを介してモータ54Mにより回転するように構成されている。
図7(B)に示されるように、複数の第一バケット54Xによって構成された第一列搬送部55Aは、投射材及び粉塵を装置下部側から装置上部側へ搬送してセパレータ56の入口56Aに供給する搬送部となる。これに対して、図7(A)に示されるように、複数の第二バケット54Yによって構成された第二列搬送部55Bは、セパレータ56から排出された投射材を装置下部側から装置上部側へ搬送してショットタンク66のショット供給口66Aに供給する搬送部となる。そして、図9に示されるように、第一列搬送部55A及び第二列搬送部55Bは、共通のモータ54Mで駆動力される。
次に、図10~図20を参照して、投射機20について詳細に説明する。
本実施形態の投射機20は、小型のワークW(一例として、直径100mm~200mm、高さ45~50mm程度のギヤ、積み重ね高さ250mm程度)に対して、投射材を投射する遠心式の投射機である。
なお、投射機20の側面視の縦断面は、駆動モータ76の組付部分を除き、後述する第2実施形態の投射機21を示す図24に示す縦断面と同様である。したがって、本実施形態の説明においても、適宜、図24を参照する。
図10および図11に示されるように、投射機40は、ケース本体72を備えている。ケース本体72は、外形が概ね台形錐状に形成され、底部側(図10の下方側)が開放されて投射材の投射部側となっている。図10に示されるように、ケース本体72の底部側からはベース72Aが互いに離反する方向に延出されており、キャビネット12の側壁部12A(図1)へ固定されている。
ディストリビュータ94は、駆動モータ76(図11参照)の作動によって回転し、コントロールケージ92の内側で回転する。ディストリビュータ94が回転することで、導入筒70からコントロールケージ92の内側に供給された投射材が、ディストリビュータ94内でかき混ぜられ、回転するディストリビュータ94の開口から遠心力で、ディストリビュータ94の開口を通して、ディストリビュータ94とコントロールケージ92の間の間隙に供給される。この間隙に供給された投射材は、間隙中を、コントロールケージ92の内周面に沿って回転方向に移動し、コントロールケージ92の開口92Xから径方向外方に排出される。
このとき、コントロールケージ92の開口92Xから投射材の排出方向が、ディストリビュータ94の回転中心(後述する羽根車100の回転中心Cと同じ)からの径方向に対して羽根車100の回転方向(矢印R方向)に傾斜した方向となる。
各ブレード104は、径方向外方端が、径方向内方端より、径方向に対して羽根車100の回転方向(矢印R方向)後方側に位置するように傾斜して配置され、コントロールケージ92の外周に沿って配置されている。
また、図23に示されるように、投射機20では、羽根車100のブレード104が、羽根車100の回転中心線の方向に見て、装置上方側、加工ゾーン18の側、装置下方側の順に移動するように羽根車100の回転方向(矢印R方向参照)が設定されている。
非後傾部114は、回転方向後方への傾斜角度が、後傾部110より小さく設定されていればよい。
この結果、ワークWの全周に表面加工がなされる。図23(A)の状態では、積み重ねられた(段積みされた)複数のワークWのうち、主として下部に配置されたワークWがショット処理される。
さらに、本実施形態では、昇降回転機構22に設けられた押さえ部48が内蓋36を貫通可能で、かつワークWを上方側から押さえてワークWと共に上下方向軸線を中心に回転可能となっている。このため、昇降回転機構22で支持されるワークWが複数個積み重ねられても、ワークWを昇降の方向の軸回りに安定的に回転させることができる。
本実施形態では、図22及び図23においてワークWの降下させる際に投射機20による投射材の投射を停止させているが、投射機20による投射材の投射を継続しながらワークWを降下させてもよい。
次に、図22(C)に示される第二シリンダ機構40を作動させ、押さえ部48を上昇させる。次に、第一シリンダ機構34を作動させ、内蓋36を上昇させる。これにより、押さえ部48及び内蓋36と、ワークWと、の間に隙間(空間)が形成される。
次に、ジャッキ32を作動させ、ワークWの最上段のギヤ(対象物)をワーク検査装置200に包囲される位置まで上昇させた後、ジャッキ32を停止させる。そして、ワーク検査装置200がワークWの最上段のギヤの側部の状態を非破壊検査する。
ショットタンク66は、ショット供給口66Aに供給された投射材を投射機20への供給用として貯留する。そして、ショットタンク66は、流量調整装置68及び導入筒70を介して投射機20に投射材を供給する。
次に、上記実施形態のショットブラスト装置10の作用及び効果について説明する。
上記実施形態のショットブラスト装置10によれば、図12に示されるように、コントロールケージ92の開口92Xが、コントロールケージ92の円筒軸心CLに平行な二辺を含む矩形状に設定されている。このため、投射材はコントロールケージ92の周方向の同じ位置から集中的に排出される。
これに対して、図17は、ブレードB2が径方向に延びている対比例の羽根車I2の作用を説明するための模式図である。なお、図16及び図17のいずれにおいても、(A)~(G)は時系列順に並べられている。
次に、図16(E)に示されるように、二番目に排出された投射材s2がブレードB1の表面に当たる。このとき、既にブレードB1上で加速されている投射材s3のブレードB1上の径方向位置は、投射材s2のブレードB1上の径方向位置とほぼ同様の位置になっている。その結果、投射材s3、s2は、概ね一塊となってブレードB1の先端側へ向けて加速される。
なお、ブレードの長さが抑えられると、ブレードの重量及び部品コストが抑えられると共に組付時の作業性等の面でもメリットがある。
これに対して、本実施形態の投射機20は、遠心式の投射機であるため、消費電力に比べて投射材を効率的に投射できる。このため、エア式の噴射装置に代えて、本実施形態の投射機20を適用すれば、消費電力、ひいてはランニングコストを大幅に削減することができる。
このため、コントロールケージ92の開口92Xから先に排出された投射材がブレード104の表面106に接触するタイミングを、遅らせることができ、ブレード104の表面106の後傾部110で投射材をより効果的に集中させることができる。
図24は、変形例に係る投射機21の側面視の縦断面図であり、図25は、投射機21の分解側面図である。
次に、本発明の第2の実施形態に係るショット処理装置としてのショットピーニング装置130について、図26に沿って説明する。図26は、本実施形態に係るショットピーニング装置130の平面視の概略的な構成図である。
大テーブル138は、上下方向の回転軸136を中心に回転(公転)可能とされており、遠心式の投射機20により投射材が投射される投射範囲を含む位置に配置されている。
また、小テーブル142は、大テーブル138よりも小径であり、大テーブル138の回転軸136と平行な回転軸140を備えて回転(自転)可能とされ、ワークWが載せられる。
次に、上記実施形態で使用された投射機とは異なる、他の投射機について、図27及び図28を用いて説明する。なお、この投射機は、コントロールケージの開口の形状が異なる点を除き、第1の実施形態のショットブラスト装置で使用された投射機20(図10及び図11)と同じ構成となっている。
なお、図27(A)~図27(D)に示されるコントロールケージ150、152、154、156を備えた投射機は、本発明の実施形態に係る投射機であり、図27(E)に示されるコントロールケージ158を備えた投射機は、本発明に含まれない参考例に係る投射機である。
第一貫通部160及び第二貫通部162は、いずれもコントロールケージ150の開口を構成している。第一貫通部160は、コントロールケージ150の円筒軸心CLに平行でかつ互いに対向する平行な二辺160A、160Bの間に設定されている。
また、第二貫通部162は、第一貫通部160に対し、コントロールケージ150の外周壁150Aの周方向および円筒軸心CLの方向にオフセットしている、第二の平行な二辺162A、162Bの間に設定されている。
第一貫通部160と第二貫通部162とは、コントロールケージ150の円筒軸心CLの方向に離間し、コントロールケージ150の円筒軸心CLの方向に見て各々の略半分がオーバーラップしている。
開口164は、第一貫通部166及び第二貫通部168を備えている。第一貫通部166は、コントロールケージの円筒軸心CLに直交する方向に平行でかつ互いに対向する第一の平行な二辺166A、166Bの間に設定されている。
また、第二貫通部168は、第一貫通部166に対して、コントロールケージ152の外周壁152Aの周方向およびコントロールケージ152の円筒軸心CLの方向にオフセットしている、平行で且つ互いに対向する第二の二辺168A、168Bの間に設定されている。
第一貫通部166と第二貫通部168とは、連通していると共に、コントロールケージ152の円筒軸心CLの方向に見て各々の略半分がオーバーラップしている。
開口170は、第一貫通部172及び第二貫通部174を備えている。第一貫通部172は、コントロールケージの円筒軸心CLに平行で且つ互いに対向する第一の平行二辺172A、172Bの間に設定されている。
また、第二貫通部174は、第一貫通部172に対して、コントロールケージ154の外周壁154Aの周方向およびコントロールケージ154の円筒軸心CLの方向にオフセットしている、平行で且つ互いに対向する第二の二辺174A、174Bの間に設定されている。
開口178は、第一貫通部180及び第二貫通部182を備えている。第一貫通部180は、コントロールケージの円筒軸心CLに平行でかつ互いに対向する第一の平行二辺180A、180Bの間に設定されている。
また、第二貫通部182は、第一貫通部180に対して、コントロールケージ156の外周壁156Aの周方向およびコントロールケージ156の円筒軸心CLの方向にオフセットしている、平行でかつ互いに対向する第二の平行二辺182A、182Bの間に設定されている。
第一貫通部180と第二貫通部182とは、コントロールケージ156の円筒軸心CLに直交する方向に見て(図27(D)の方向視で)円筒軸心CLの方向に若干離れており、コントロールケージ156の円筒軸心CLの方向に見て各々の略半分がオーバーラップしている。
また、図28(B)には、コントロールケージ154、156(図27(C)、(D))を備えた投射機による投射分布(図中の上段)及び投射範囲(図中の下段)が概略的に示されている。これらの図からも、投射量が多い範囲が広げられていることが判る。
図18に示されるように、本実施形態の場合(二点鎖線)は、対比例の場合(点線参照)に比べると、0°での投射割合が低いものの、本実施形態の場合の0°での投射割合は、対比例の場合の-25°、+25°での投射割合よりも高い値を示す。また、-25°よりもグラフの左側、及び+25°よりもグラフの右側に着目すると、-25°~-40°の範囲及び+25°~+40°の範囲では、本実施形態の場合のほうが対比例の場合よりも投射割合が高い。
開口186は、コントロールケージ158の円筒軸心CLに直交する方向に延びる互いに一部が対向する平行な二辺186A、186Bを備えた平行四辺形の貫通部とされている。図28(C)には、コントロールケージ158(図27(E))を備えた投射機の投射分布(図中上段)及び投射範囲(図中下段)が概略的に示されている。
さらに、後傾部と非後傾部とが湾曲部を介さずに直接、連結された構成でもよい。
さらにまた、傾斜部が形成されない構成でもよい。
また、搬入出ゾーンと加工ゾーンとの間に中間ゾーンを設定できる場合には、投射機は、中間ゾーンの側方側においてキャビネットの側壁部に設置されてもよい。
また、投射機20の羽根車の回転方向を、上記実施形態と逆に設定してもよい。
また、第一列搬送部を構成する無端ベルトと第二列搬送部を構成する無端ベルトとを別々に設け、それぞれの無端ベルトを別個の駆動用モータで駆動する構成でもよい。
12 キャビネット
12A キャビネットの側壁部
16 搬入出ゾーン
18 加工ゾーン
18A 第一投射位置(加工位置)
18B 第二投射位置(加工位置)
18B 第三投射位置(加工位置)
20 投射機
21 投射機
22 昇降回転機構(支持機構)
36 内蓋
36X 第一位置
36Y 第二位置
38 昇降機構
48 押さえ部
50 循環機構
54 バケットエレベータ(搬送機構)
54C 無端ベルト
54M モータ
54X 第一バケット
54Y 第二バケット
55A 第一列搬送部
55B 第二列搬送部
56 セパレータ
56A 入口
57 仕切部
66 ショットタンク
66A ショット供給口
76 駆動モータ
82 ハブ
92 コントロールケージ
92A 外周壁
92X 開口
94 ディストリビュータ
100 羽根車
104 ブレード
110 後傾部
112 湾曲部
116 傾斜部
130 ショットピーニング装置(ショット処理装置)
134 製品載置部(支持機構)
150,152,154,156 コントロールケージ
150A,152A,154A,156A 外周壁
160 第一貫通部(開口)
162 第二貫通部(開口)
164,170,178 開口
166,172,180 第一貫通部
168,174,182 第二貫通部
190 ブレード
200 ワーク検査装置
C 羽根車の回転中心
CL 円筒軸心
W ワーク
Claims (21)
- ワークに投射材を投射する遠心式の投射機と、前記投射機による表面加工が可能な加工位置でワークを支持する支持機構とを備えたショット処理装置であって、
前記投射機が、円筒形状を有し、内部に投射材が供給され、側壁に前記投射材の排出口となる開口が形成されたコントロールケージと、
前記コントロールケージの外方で前記コントロールケージの径方向外方に延びるように配置された複数のブレードを備え前記コントロールケージの中心軸線を中心に回転する羽根車であって、前記ブレードには回転方向前方側の表面に回転方向後方側に傾斜した後傾部が設けられている、羽根車と、を備えている、
ことを特徴とするショット処理装置。 - 前記開口は、二辺が前記コントロールケージの円筒軸心に平行な矩形形状を備えている、
請求項1に記載のショット処理装置。 - 前記羽根車の回転軸方向視で、前記投射機による投射材の投出位置と、前記加工位置に配置されたワークの前記投射機に向く面の両端との成す角度が30°以内となるワークの表面加工用とされ、
前記後傾部は、前記羽根車の径方向に対して回転方向後方側に30°~50°傾斜している、
請求項1又は2に記載のショット処理装置。 - 前記後傾部は、前記ブレードの基端部側に形成され、
前記ブレードの先端部側には、前記後傾部より回転方向後方側への傾斜角が小さな非後傾部が形成されている、
請求項1ないし3のいずれか1項に記載のショット処理装置。 - 前記羽根車は、駆動モータの回転軸にハブを介して取り付けられている、
請求項1ないし4のいずれか1項に記載のショット処理装置。 - 前記後傾部の径方向長さが前記非後傾部の径方向長さよりも長く設定されている、
請求項4又は5に記載のショット処理装置。 - 前記後傾部と前記非後傾部とをなだらかに繋ぐ湾曲部が設けられている、
請求項4ないし6のいずれか1項に記載のショット処理装置。 - 前記コントロールケージの内側に配置され前記羽根車の回転方向と同じ方向に回転するディストリビュータを更に備え、
前記ディストリビュータが回転することで、前記コントロールケージの内側に供給された投射材が、前記ディストリビュータとコントロールケージとの間の間隙中を前記ディストリビュータの内周面に沿って移動し、前記コントロールケージの開口からの前記投射材の排出方向が前記羽根車の回転中心からの径方向に対して前記羽根車の回転方向前方側に傾く、
請求項1ないし6のいずれか1項に記載のショット処理装置。 - 前記ブレードの前記羽根車の回転方向後方側の表面は、基端部に、径方向に対して後傾部より大きく回転方向後方側に傾斜した傾斜部を備えている、
請求項8に記載のショット処理装置。 - 前記ワークが搬入出される搬入出ゾーンを内部の上方位置に、前記投射機により投射された投射材によって前記ワークの表面加工を施す加工ゾーンを内部の下方位置に、それぞれ有しているキャビネットと、
前記支持機構を構成し、前記ワークを支持しながら前記ワークを前記搬入出ゾーンと前記加工ゾーンとの間で昇降させ且つ該昇降方向を中心に回転可能な昇降回転機構と、を備えている、
請求項1ないし9のいずれか1項に記載のショット処理装置。 - 前記搬入出ゾーンの上端側の位置する第一位置と、前記搬入出ゾーンと前記加工ゾーンとの間に位置する第二位置との間で昇降可能な内蓋と、
前記ワークを前記搬入出ゾーンに搬入出するとき前記内蓋を前記第一位置に配置し、前記ワークが前記加工ゾーンに配置されたとき前記内蓋を前記第二位置に配置するように、前記内蓋を昇降させる昇降機構と、を備えている、
請求項10に記載のショット処理装置。 - 前記昇降回転機構は、前記内蓋を貫通可能であり前記ワークを上方側から押さえて該ワークと共に前記昇降方向を中心に回転可能な押さえ部を有している、
請求項11に記載のショット処理装置。 - 前記搬入出ゾーンの側方側の側壁側にワーク検査装置をさらに備え、
該ワーク検査装置は、
前記昇降回転機構に支持されたワークに対して前記内蓋及び前記押さえ部が装置上方側に離間して配置されたとき、前記ワークと前記内蓋及び押さえ部との間に側方側から挿入可能な退避位置と、
前記退避位置の側方側の位置であって前記ワークの側面を包囲する検査位置との間で移動可能に支持されている、
請求項12に記載のショット処理装置。 - 前記投射機は、前記加工ゾーンの側方側において前記キャビネットの側壁部に配置されている、
請求項10ないし13のいずれか1項に記載のショット処理装置。 - 前記投射機は、前記羽根車のブレードが、羽根車の回転中心線の方向に見て、装置上方側、前記加工ゾーンの側、装置下方側の順に移動するように羽根車の回転方向が設定されている、
請求項14に記載のショット処理装置。 - 前記投射機によって投射された投射材を前記投射機へ循環させる循環機構をさらに備え、
前記循環機構は、
上部に入口を有し該入口から供給された投射材及び粉塵から粉塵を分離除去して投射材を下部側に排出するセパレータと、
上部において前記セパレータの前記入口と隣接するショット供給口を有し該ショット供給口に供給された投射材を前記投射機への供給用として貯留するショットタンクと、
前記投射材及び粉塵を下部側から上部側へ搬送し前記セパレータの入口に供給する第一列搬送部と、前記第一列搬送部と並列に設けられ前記セパレータから排出された投射材を下部側から上部側へ搬送して前記ショットタンクのショット供給口に供給する第二列搬送部とを有する搬送機構と、を備えている、
請求項1ないし15のいずれか1項に記載のショット処理装置。 - 前記搬送機構は、
前記第一列搬送部及び前記第二列搬送部を駆動する共通のモータと、
前記モータによって回転駆動される単一の無端ベルトと、
前記無端ベルトに取付けられ前記第一列搬送部を構成する複数の第一バケットと、
前記無端ベルトに前記第一バケットと並列して取付けられ前記第二列搬送部を構成する複数の第二バケットと、を有しているバケットエレベータと、備えている、
請求項16に記載のショット処理装置。 - 前記無端ベルトの下部に近接して前記第一列搬送部と前記第二列搬送部とを仕切る仕切部をさらに備えている、
請求項17に記載のショット処理装置。 - 投射材をワークに対して投射する遠心式の投射機であって、
円筒形状を有し、内部に投射材が供給され外周壁には投射材の排出部として開口が形成され、前記開口は前記円筒形状の軸心に平行な二辺を含む矩形形状を有しているコントロールケージと、
前記コントロールケージの径方向外方位置に配置され前記コントロールケージの周方向に回転する複数のブレードを備え、前記ブレードの回転方向前方側の表面に回転方向後方側に傾斜した後傾部が設けられている羽根車と、を備えている、
ことを特徴とする投射機。 - 前記羽根車の回転軸方向視で、前記投射機による投射材の投出位置と、前記加工位置に配置されたワークの前記投射機に向く面の両端との成す角度が30°以内となるワークの表面加工用とされ、
前記後傾部は、前記羽根車の径方向に対して回転方向後方側に30°~50°傾斜している、
請求項19に記載の投射機。 - ショット処理装置に設置されて羽根車の回転により投射材を投射する遠心式の投射機であって、
前記羽根車の回転軸方向視で、前記投射機による投射材の投出位置と、加工位置に配置されたワークの前記投射機に向く面の両端との成す角度が50°~80°以内となるワークの表面加工用とされ、
円筒形状を有し、内部に投射材が供給され外周壁には投射材の排出部として開口が形成され、前記開口は前記円筒形状の軸心に平行な二辺を含む矩形形状を有しているコントロールケージと、
前記コントロールケージの径方向外方位置に配置され前記コントロールケージの周方向に回転する複数のブレードを備え、前記ブレードの回転方向前方側の表面に回転方向後方側に傾斜した後傾部が設けられている羽根車と、を備え、
前記開口は、
前記コントロールケージの軸心に平行な二辺を含む矩形形状を有している第一貫通部と、
前記コントロールケージの軸心に平行かつ互いに対向する第二の平行な二辺を含む矩形形状を有し、前記第一貫通部に対し前記コントロールケージの周方向にオフセットしている第二貫通部と、を備え、
前記第一貫通部と前記第二貫通部とは、前記コントロールケージの円筒軸心の方向に各々の略半分がオーバーラップしている、
ことを特徴とする投射機。
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CN201580034332.4A CN106457518B (zh) | 2014-06-24 | 2015-06-08 | 抛丸处理装置和投射机 |
MX2016017406A MX2016017406A (es) | 2014-06-24 | 2015-06-08 | Dispositivo de procesamiento de disparo y proyector. |
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US10035241B2 (en) | 2018-07-31 |
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