This application is a 371 application of PCT/JP2015/066447 having an international filing date of Jun. 8, 2015, which claims priority to JP2014-129579 filed Jun. 24, 2014, the entire contents of which are incorporated herein by reference.
The present invention pertains to a shot processing apparatus and projector.
Shot processing apparatuses are known in which surface treatment is performed by projecting a projection material onto a workpiece. In one such known shot processing apparatus, projection material is projected toward a product from a centrifugal projector (see Patent Document 1, for example).
In this type of shot processing apparatus, the amount of projection material used is relatively large.
The need therefore existed to reduce the amount of projection material used to effectively project projection material onto a workpiece.
With this need in mind, the present invention has the object of providing a shot processing apparatus and projector capable of limiting the amount of projection material used.
The present invention provides a shot processing apparatus comprising a centrifugal projector for projecting projection material onto a workpiece, and a support mechanism for supporting the workpiece at a processing position where the surface treatment can be performed by the projector;
wherein the projector comprises a control cage having a cylindrical shape, to the interior of which the projection material is supplied, and on the side wall of which an opening serving as a discharge port for the projection material is formed; and
an impeller including multiple blades disposed so as to extend in a radially outward direction of the control cage on the outside of the control cage, and rotating about the central axis of the control cage, wherein a rearward inclining portion inclining toward rotationally rearward direction is formed on the rotationally forward surface of the blades.
According to this arrangement, a rearward inclining portion inclining in the rotational rearward direction of the impeller is formed on the surface of the impeller blades.
Therefore, projection material discharged later from the control cage opening contacts the blade surface and is accelerated toward the blade tip before projection material discharged earlier from the control cage opening contacts the blade surface.
This means that at the point in time when the first-discharged projection material contacts the blade surface, subsequently-discharged projection material and earlier-discharged projection material are collected at a position adjacent to the blade surface. Since projection material collected in a limited area on the blade surface is projected, the projection distribution can be concentrated, and wasted projection toward workpieces can be limited.
In another aspect of the invention:
the opening has a rectangular shape and two sides the opening are parallel to the cylinder axial center of the control cage.
According to this arrangement, projection material can be projected onto a workpiece in a concentrated manner.
In another aspect of the invention:
viewed in the direction of the rotational axis of the impeller, an angle formed by the projection position of projection material projected by the projector relative to opposite edges of the surface of a workpiece disposed in a processing position facing to the projector is within 30°;
and the rearward inclining portion inclines by 30° to 50° toward rotationally rearward direction relative to the radial direction of the impeller.
In another aspect of the invention:
the rearward inclining portion is formed on the base end portion of the blade;
and a rearward less-inclining portion with a smaller inclining angle toward the rotationally rearward direction than the rearward inclining portion is formed on the blade tip portion.
According to this arrangement, a rearward inclining portion is formed on the base end side of the blades, and a rearward less-inclining portion is formed on the tip portion side of the blade, therefore projection material concentrated by the rearward inclining portion can be accelerated and projected by the rearward less-inclining portion.
Note that the phrase “a smaller inclining angle to the rotationally rearward side than the rearward inclining portion” includes, in addition to cases where that inclining angle is smaller than the inclining angle toward rotationally rearward direction of the rearward inclining portion, configurations in which it extends radially, and in which it inclines to the rotationally forward direction.
In another aspect of the invention:
the impeller is attached to a rotary shaft of a drive motor via a hub.
According to this arrangement, the impeller is attached to a rotary shaft of a drive motor via a hub, therefore overall apparatus size can be reduced compared to the case in which it is connected to a drive motor through a belt.
In another aspect of the invention:
the radial length of the rearward inclining portion is set to be longer than the radial length of the rearward less-inclining portion.
According to this arrangement, projection material can be accelerated and projected by the rearward less-inclining portion after sufficiently being collected in the rearward inclining portion of the blade.
In another aspect of the invention:
a curved portion is provided for gradually connecting the rearward inclining portion and the rearward less-inclining portion.
According to this arrangement, after projection material is collected by the blade rearward inclining portion, the velocity of projection material is gradually increased and projection material is projected by the curved portion and the rearward less-inclining portion.
Another aspect of the invention:
further comprising a distributor disposed inside of the control cage and rotating in the same direction as the rotational direction of the impeller;
and wherein rotation of the distributor results in movement of projection material supplied to the inside of the control cage along the inner circumferential surface of the distributor in a gap between the distributor and the control cage, and the discharge direction of the projection material from the opening in the control cage inclines toward the rotationally forward direction of the impeller relative to the radial direction from the rotational center.
According to this arrangement, the discharge direction of projection material from the opening in the control cage inclines toward the rotational direction of the impeller relative to the radial direction from the rotational center, therefore the timing at which projection material first-discharged from the control cage opening contacts the blade surface can be delayed, and projection material can be concentrated at the rearward inclining portion of the blade surface.
In another aspect of the invention:
the surface of the blades on the rotationally rearward side of the impeller comprises, at its base end portion, a inclined portion inclining larger toward the rotationally rearward direction relative to the radial direction than the rearward inclining portion.
According to this arrangement, the amount of projection material directed to the adjacent blade can be limited when projection material discharged from the opening hits the base end portion of the blade reverse surface and bounces back. Disintegration of the flow of projection material between blades can thus be constrained.
Another aspect of the invention comprises:
a cabinet having a loading/unloading zone for loading/unloading workpieces at an internal upper position, and a processing zone for performing surface treatment on the workpiece using projection material projected from the projector at an internal lower position and
a raising/lowering rotation mechanism constituting the support mechanism capable of raising and lowering the workpiece between the load/unload zone and the processing zone while supporting the workpiece, and of rotating about said raising/lowering direction.
According to this arrangement, the entire circumference of multiple workpieces can be treated by stacking the multiple workpieces and causing them to be supported by the raising/lowering rotation mechanism.
Another aspect of the invention comprises:
an inner lid capable of rising and falling between a first position located at upper side of the loading/unloading zone, and a second position located between the loading/unloading zone and the processing zone;
and an elevator mechanism for raising and lowering the inner lid so that the inner lid is disposed at the first position when the workpiece is loaded/unloaded from the loading/unloading zone, and the inner lid is disposed at the second position when the workpiece is placed in the processing zone.
According to this arrangement, leakage of the projection material into the loading/unloading zone side is blocked by the inner lid even if the projector projects projection material toward the workpiece side when the workpiece is disposed in the processing zone.
In another aspect of the invention:
wherein the raising/lowering rotation mechanism has a hold-down portion which is capable of extending through the inner lid, and holds down the workpiece from the above and is rotatable with said workpiece about the raising/lowering direction.
According to this arrangement, workpieces can be stably rotated around an axis along which the workpiece is raised and lowered, even when multiple workpieces are stacked.
Another aspect of the invention further comprises:
a workpiece inspection device provided on the sidewall side at the side of the loading/unloading zone; and
wherein the workpiece inspection device is supported so as to be movable between a retracted position where workpiece inspection device can be laterally inserted between the workpiece and the inner lid/hold down portion when the inner lid and the hold down portion are separately placed in an upper direction of the apparatus from the workpiece supported by the raising/lowering rotation mechanism, and an inspection position located at a lateral position of the retracted position the position where the workpiece inspection device encompasses the side surface of the workpiece.
According to this arrangement, the status of side portion of the workpiece can thus be non-destructively inspected after projection material has been projected onto the material and before unloading the workpiece from the cabinet.
In another aspect of the invention:
the projector is disposed on the side wall of the cabinet laterally of the processing zone.
According to this arrangement, the height of the apparatus as a whole can be constrained even if the projection material supply portion etc. is disposed above the projector.
In another aspect of the invention:
the rotational direction of the impeller of the projector is set so that, viewed in the impeller rotational center line direction, the impeller blades move in the following order: the apparatus upper part direction, the processing zone direction, and the apparatus lower part direction.
This configuration can inhibit the leakage of projection material to the upper side.
Another aspect of the invention further comprises:
a circulation mechanism for circulating projection material projected by the projector back toward the projector;
wherein the circulation mechanism comprises:
a separator having an inlet at top portion thereof wherein dust is separated and removed from the projection material and dust supplied from the inlet, and projection material is discharged to the lower side thereof;
a shot tank adjacent to the inlet of the separator at its upper portion, having a shot supply port, wherein the projection material supplied to said shot supply port is stored for supply to the projector;
and a conveyor mechanism having: a first row conveyor for conveying projection material and dust from the lower portion to the upper portion and supplying projection material and dust to the separator inlet, and a second row conveyor, arranged in parallel with the first row conveyor, for conveying projection material discharged from the separator from the lower portion to the upper portion, and supplying the projection material to the shot supply port on the shot tank.
According to this arrangement, a shot tank shot supply port is provided adjacent to the separator inlet, and no separator is disposed on the upper side of the shot tank, therefore the height of the apparatus can be constrained.
In another aspect of the invention:
the conveyor mechanism comprises a bucket elevator having:
a shared motor for driving the first row conveyor and the second row conveyor;
a single endless belt rotationally driven by the motor;
multiple first buckets attached to the endless belt and constituting the first row conveyor;
and multiple second buckets attached to the endless belt juxtaposed with the first buckets and constituting the second row conveyor.
According to this arrangement, a common or shared motor and a single endless belt are used, therefore the number of parts can be reduced, and the apparatus can be made compact.
Another aspect of the invention further comprises:
a partitioning portion close to the lower portion of the endless belt, for partitioning between the first row conveyor and the second row conveyor.
According to this arrangement, the mixed material (projection material and dust) before dust is separated and removed by the separator, is prevented from mixing with the projection material from which dust had been separated and removed by the separator.
Another form of the invention provides:
a centrifugal projector for projecting projection material onto a workpiece, comprising:
a control cage having a cylindrical shape wherein projection material is supplied to the interior thereof, having an opening formed as a projection material discharge portion on the outer circumferential wall thereof, and the opening having a rectangular shape including two sides parallel to the axial center of the cylindrical shape and
an impeller having multiple blades disposed at positions in the radially outward position of the control cage, and rotating in a circumferential direction of the control cage, on which a rearward inclining portion inclining to the rearward side in the direction of rotation, is disposed on the rotationally forward surface of the blade.
In another aspect of the invention,
viewed in a direction of the impeller rotational axis, the angle formed by the projection position of projection material projected by the projector relative to the two opposite edges of the surface of a workpiece disposed in a processing position facing the projector is within 30° and
the rearward inclining portion inclines by 30° to 50° toward rotationally rearward direction relative to radial direction of the impeller.
Another form of the invention provides:
A centrifugal projector installed on a shot processing apparatus and projecting projection material by the rotation of an impeller;
intended for surface treatment of a workpiece, such that when viewed in the direction of the rotational axis of the impeller, the angle formed between the position at which projection material is projected by the projector and two opposite edges of the surface of a workpiece disposed in a processing position facing the projector is within 50° to 80°;
the centrifugal projector comprising: a control cage having a cylindrical shape, wherein projection material is supplied to the interior thereof, and an opening is formed as a projection material discharge portion on the outer circumferential wall, and the opening has a rectangular shape including two opposite sides parallel to the axial center of the cylindrical shape;
and an impeller comprising multiple blades disposed at positions in the radial outward direction of the control cage, and rotating in the control cage circumferential direction, on which a rearward inclining portion inclining toward rotationally rearward direction, is disposed on the rotationally forward surface of the blade;
wherein the opening comprises:
a first opening portion having a rectangular shape including two sides parallel to the central axis of the control cage;
and a second opening portion having a rectangular shape including two parallel sides, parallel to the control cage axial center and opposing one another, and offset from the circumferential direction of the control cage relative to the first opening portion;
wherein the first opening portion and the second opening portion are approximately half overlapped in the direction of the cylinder axial center of the control cage.
According to this arrangement, projection material discharged later from the control cage opening contacts the blade surface and is accelerated toward the blade tip end before projection material discharged earlier from the control cage opening contacts the blade surface. This means that at the point in time when the first-discharged projection material contacts the blade surface, subsequently-discharged projection material and earlier-discharged projection material are collected at a limited area on the blade surface. Projection material can in this way be projected in a concentrated manner.
In addition, projection material respectively discharged from the first opening portion and the second opening portion are discharged from offset positions in the circumferential direction of the control cage, therefore the projection distribution as a whole is the combination of the projection distribution of projection material discharged from the first opening portion and the projection distribution of projection material discharged from the second opening portion.
Here, approximately half of the first opening portion and the second opening portion overlap in the control cage cylinder axis center direction, so the respective projection distributions of projection material discharged from the first opening portion and the second opening portion also overlap in approximately half the respective distribution widths. Thus as an overall projection distribution, the range over which the projection fraction is high (the range in which a concentrated projection was sought) is broadened.
The present invention provides a shot processing apparatus and projector with which the amount of projected projection material can be constrained.
Referring to
The upper portion of the internal space in the cabinet 12 shown in
As shown in
A raising/lowering rotation mechanism 22 is disposed in the cabinet 12. The raising/lowering rotation mechanism 22 constitutes a support mechanism for supporting the workpiece W at a processing position (
The raising/lowering rotation mechanism 22 comprises a work receiving portion 24 for receiving workpiece W. In the present embodiment, the workpiece W is constituted by multiple stacked gears (e.g., 5 gears). A shaft (not shown) extending through the center hole of these gears, and a cap 23 is fitted onto the top end portion of the shaft. The bottom end surface of the cap 23 contacts the top surface of the upper-most gear. With the cap 23 held down so as to rotate about a vertical axis, the cap 23 and the workpiece W are able to rotate as an integral unit about the vertical axis. The work receiving portion 24 is connected through a drive force transmission mechanism 26 to a motor 28, and by operation of the motor 28 is able to rotate about a vertical axis.
The motor 28 is fixed to a motor holding portion 30A, and an L-shaped bracket 32A is coupled through coupling portion 30B to the top end portion of the motor holding portion 30A. As shown in
Thus the elevator servo motor 32M, the ball screw 32C, the elevator member 32S, the bracket 32A, and the guide shafts 32B constitute a jack 32 for raising and lowering. The elevator servo motor 32M is connected to a control unit 25, and operation is controlled by the control unit 25. In other words, the control unit 25 controls the forward rotation, reverse rotation, and stopping of the elevator servo motor 32M in response to the instruction from an operator.
As shown in
An inner lid 36 is fixed at the bottom end portion of the rod 34B. By the operation of the jack 32 and the first cylinder mechanism 34, the inner lid 36 is able to move up and down between a first position 36X, which is a position of the top end side of the loading/unloading zone 16 (the position shown in
There is also a second cylinder mechanism 40 cylinder 40A fixed to the bracket 32A. In the second cylinder mechanism 40, the lower portion of a rod 40B and a piston (not shown) are disposed inside the cylinder 40A. The rod 40B is fixed to the piston at its bottom end portion, and the top portion side extends above the cylinder 40A. The piston and the rod 40B are able to move (move reciprocally in an up and down direction) relative to the cylinder 40A under the fluid pressure (air pressure in this embodiment) inside the cylinder 40A.
The top end portion of rod 40B is coupled to a bearing 44 through a coupling portion 42. The bearing 44 is disposed at the right side of the second cylinder mechanism 40 in the apparatus. The top end portion of a vertically extending hold-down shaft 46 is pressed into this bearing 44. The hold-down shaft 46 is rendered incapable of vertical movement relative to the bearing 44, but is able to rotate about the hold-down shaft 46 relative to the bearing 44. A hold-down portion 48 is attached to the bottom end portion of the hold-down shaft 46. The hold-down portion 48 is able to rotate about a vertical axis together with the hold-down shaft 46, and is able to extending in a through hole in the inner lid 36. The hold-down portion 48 is able to hold down a workpiece W loaded onto a work receiving portion 24 through a cap 23, and with the workpiece W held down, is able to rotate about an axis extending in the vertical direction (the raising/lowering direction) together with the workpiece W.
Note that the cylinder 34A of the first cylinder mechanism 34 and the cylinder 40A of the second cylinder mechanism 40 are respectively connected through an air direction control device such as a solenoid valve (not shown) to an air supply source, and the air direction control device is connected to the control unit 25. The control unit 25, by controlling each air direction control device in response to the instruction from the operator, enables the control of the rods 34B and 40B in the advancing and retracting directions.
In the cabinet 12, a workpiece inspection apparatus 200 is provided on the side wall portion of the loading/unloading zone 16. The workpiece inspection apparatus 200 has a cylindrical shape, such as a short cylinder shape; and is disposed so that the extending direction thereof is the up/down direction, and is housed in a housing (not shown). The housing and the workpiece inspection apparatus 200 are omitted in
As shown in
The workpiece inspection apparatus 200 is fixed to the tip portion of a rotary arm 202. The base end portion of the rotary arm 202 is disposed on the cabinet 12 side, and is able to rotationally move about a vertical axis. The workpiece inspection apparatus 200, by being fixed to the tip portion of the rotary arm 202, is movably supported between the retracted position shown by the solid line, and the inspection position shown by the double dot and dash line.
Here the retracted position of the workpiece inspection apparatus 200 is a position at which the workpiece inspection apparatus 200 can be inserted from the side direction between the workpiece W and the inner lid 36 and hold-down portion 48 when the inner lid 36 and hold-down portion 48 are disposed at a distance from a workpiece W, supported by the raising/lowering rotation mechanism 22.
In the present embodiment, when the workpiece W and the inner lid 36 and hold-down portion 48 are lowered by the activation of the jack 32 from the state shown in
In addition, the retracted position of the workpiece inspection apparatus 200 is set to a position at which raised or lowered other members and the workpiece inspection apparatus 200 do not interfere with one another when the workpiece W is raised or lowered by the raising/lowering rotation mechanism 22, or when the inner lid 36 is raised and lowered by an elevator mechanism 38.
In contrast, the inspection position of the workpiece inspection apparatus 200 is lateral of the retracted position, and becomes the position at which the side surface of the workpiece W is surrounded when it has been raised or lowered by the raising/lowering rotation mechanism 22. I.e., when the raising/lowering rotation mechanism 22 raises and lowers the workpiece W, the inspection position of the workpiece inspection apparatus 200 is located outside of the moving path of the side surface of the workpiece W.
The rotary arm 202 is connected to a motor (not shown), and moves rotationally, driven by a motor. The motor is connected to a control unit 25 (
The bottom end portion of a bucket elevator 54 is disposed on the downstream side of the screw conveyor 52 as a vertically extending conveyor mechanism. The bucket elevator 54 is an apparatus for conveying projection material and the like supplied from the screw conveyor 52 to the top portion of the apparatus. The arrangement of the bucket elevator 54 is described elsewhere below.
As shown in
A settling chamber 58 is placed on rear side relative to the projection portion of the upper portion bucket elevator 54 in the apparatus.
The settling chamber 58 shown in
As shown in
Next, the bucket elevator 54 will be explained.
As shown in
As shown in
As shown in
As shown in
Projector Configuration
Next, referring to
The projector 20 is a centrifugal projector for projecting projection material onto a small workpiece W (as an example, gear approximately 100 mm to 200 mm diameter and 45 to 50 mm high, stacked to a height of 250 mm).
In the projector 20 of the present embodiment, viewed from the direction of rotation of the impeller 100, the spread (projection angle) of projected projection material is about 30°. In the shot blasting apparatus 10 of the present embodiment, using the position of projection of projection material by the projector 20 as the highest point, the dimensions, position, etc. of the workpiece W are selected so that the angle (center angle) at the peak point, when both edges are joined on the surface facing the projector 20 of a workpiece W disposed in the processing position, is within 30°, and so that the treated surface of the workpiece W is fully processed by the projection material from the projector 20.
A small workpiece W used in the shot blasting apparatus 10 of the present embodiment is of a size equal to a workpiece processed by an air-type jetting apparatus, which is an apparatus for jetting compressed air containing projection material from a nozzle.
Note that the vertical cross section of the projector 20 viewed from lateral direction is the same as the vertical cross section shown in
As shown in
A through hole into which the hub 82 and the like are inserted, is formed on the side portion 72B on one side of the case main unit 72. Also, a through hole into which the introducing tube 70 is inserted is formed on the side portion 72C on the other side of the case main unit 72. Further, a cover 80 is attached at the top of the case main unit 72, and a through hole is formed in the cover 80 into which hole the upper part of a liner 78 is inserted. The liner 78 is attached to the inside of the case main unit 72.
A control cage 92 is disposed at center position in the case main unit 72. The control cage 92 is attached to a side portion 72C of the case main unit 72 through a front surface cover 88. The control cage 92 has a cylindrical shape and is disposed concentrically with the shaft 76X of the drive motor 76, so that projection material is supplied from the introducing tube 70 to the interior. A ring-shaped bracket 96 and a seal member 98 are disposed between the inner circumferential portion of the control cage 92 and the end portion of the introducing tube 70. Note that part of the introducing tube 70 is held down by an introducing tube hold-down 86 (
Also, a single opening 92X is formed on the outer perimeter wall 92A of the control cage 92, extending through the outer perimeter wall 92A and serving as a projection material discharge portion. As shown in
The cylinder portion 82A of the hub 82, which is a flanged cylindrical body, is fixed by a key to the outer circumference of the rotary shaft 76X of the drive motor 76 shown in
As shown in
The distributor 94 rotates by the operation of the drive motor 76 (see
At this point the discharge direction of projection material from the opening 92X in the control cage 92 is inclined in the rotational direction of the impeller 100 (the direction of arrow R) relative to the radial direction from the rotational center of the distributor 94 (same as the rotational center C of the impeller 100, described below).
As shown in
In addition, the impeller 100 comprises multiple blades 104, disposed to extend in the radially outward direction of the control cage 92, between the first side plate 102A and the second side plate 102B. The impeller 100 obtains rotational force from the operation of the drive motor 76 (
Each of the blades 104 is oriented in inclined manner such that the radially outward end thereof is positioned rearward of the radially inward end relative to the rotational direction of the impeller 100 (arrow R direction), and disposed along the outside circumference of the control cage 92.
As shown in
As shown in
Also, a rearward less-inclining portion 114 extending in approximately the radial direction (the radial line L2 direction) from the rotational center C of the impeller 100 is formed on the tip end portion in the surface 106 of the blades 104 (i.e., on the radially outward of the rearward inclining portion 110). The radial length of the rearward inclining portion 110 is set to be longer than the radial length of the rearward less-inclining portion 114. A curved portion 112 is formed between the rearward inclining portion 110 and the rearward less-inclining portion 114.
In the rearward less-inclining portion 114, it is sufficient for the inclination angle thereof toward the rotational rearward direction to be set smaller than that of the rearward inclining portion 110.
Also, the reverse surface 108 on the opposite to the surface 106 of the blade 104 has at its base portion a inclined portion 116, which inclines larger than the rearward inclining portion 110 in rotational rearward direction relative to the radial direction. A projection 118 is raised on the radial middle portion of the surface 108 of the blades 104. On this projection 118, the indented curved portion on the radial outer side of the impeller 100 contacts the linking member 102C.
As shown in
The side wall portion 120 is a portion which is fitted into the channel portion of the first side plate 102A and the second side plate 102B shown in
Next, referring to
First, as shown in
Next, as shown in
As a result, surface treatment is performed on the entire circumference of the workpiece W. In a state shown in
Because the inner lid 36 partitions the loading/unloading zone 16 and the processing zone 18, leakage of projection material to the loading/unloading zone 16 side is prevented. In the present embodiment, as shown in
Moreover, in the present embodiment the hold-down portion 48 provided in the raising/lowering rotation mechanism 22 can extending through the inner lid 36, and can rotate about the vertical axis together with the workpiece W, holding the workpiece W from above. Hence even if multiple workpieces W supported by the raising/lowering rotation mechanism 22 are stacked, the workpiece W can be stably rotated about axis extending in a raising/lowering direction.
Next, the shot gate on the flow quantity adjustment device 68 (see
Next, projection of projection material from the projector 20 is restarted by opening the shot gate on the flow quantity adjustment device 68 (
Next, the shot gate on the flow quantity adjustment device 68 (
Next, by opening the shot gate on the flow quantity adjustment device 68 (
Thus, by the operation of the raising/lowering rotation mechanism 22 jack 32, workpieces W is sequentially lowered in the processing zone 18 so that shot processing is applied to all of the multiple stacked workpieces W.
In this embodiment, projection of projection material by the projector 20 is stopped when the workpiece W is lowered in
Next the procedure up to conveyance of the workpiece W will be explained. As shown in
Next, the second cylinder mechanism 40 shown in
Next, the jack 32 is operated, and the hold-down portion 48, the inner lid 36, and the workpiece W is raised while maintaining the relative positional relationships between the hold-down portion 48, the inner lid 36, and the workpiece W. The jack 32 is stopped when the height of the gap between the hold-down portion 48/inner lid 36 and the workpiece W reach the same height as the workpiece inspection apparatus 200 height.
In this state, the rotary arm 202 is operated, the workpiece inspection apparatus 200 which had been in a retracted position is inserted into the gap between the hold-down portion 48/inner lid 36 and the workpiece W, then moved to an inspection position (the position shown by the double dot and dash line in
Next, after the jack 32 is operated and the top-most gear (the target object) in the workpiece W is raised to a position at which it is surrounded by the workpiece inspection apparatus 200, the jack 32 is stopped. The workpiece inspection apparatus 200 then non-destructively inspects the condition of the side portion of the top-most gear within the workpiece W.
After completion of inspection of the top-most gear, the jack 32 is operated to raise the second gear from the top of the workpiece W to a position at which it is surrounded by the workpiece inspection apparatus 200, whereupon the jack 32 is stopped. The workpiece inspection apparatus 200 then non-destructively inspects the condition of the side portion of the second gear down within the workpiece W.
Thereafter non-destructive inspection of each workpiece W is similarly conducted in sequence.
After that, by operating the jack 32, the hold-down portion 48/inner lid 36 and the workpiece W can, without changing their relative positional relationship, be raised and placed at the position in the loading/unloading zone 16 shown in
Note also that in the present embodiment, the workpiece W is non-destructively inspected by the workpiece inspection apparatus 200 after being surface treated by the projector 20, but in an alternative embodiment in which no workpiece inspection apparatus 200 is provided, the procedure up to workpiece W unloading is as follows.
I.e., as shown in
Next, the hold-down portion 48 is raised by operating the second cylinder mechanism 40, as shown in
Note that in the present embodiment, as shown in
Next, referring to
Projection material which has been projected by the projector 20 and has fallen, is conveyed by a screw conveyor 52 to the bottom end of a bucket elevator 54. At that time, in addition to reusable projection material, the screw conveyor 52 also conveys dust produced by the breakup of the projection material, etc. The first row conveyor 55A of the bucket elevator 54 shown in
The separator 56 separates and excludes dust from the projection material and dust supplied from the inlet 56A and discharges the projection material to the bottom end of the second row conveyor 55B on the bucket elevator 54. The second row conveyor 55B of the bucket elevator 54 conveys projection material discharged from the separator 56 (
The shot tank 66 stores projection material supplied to the shot supply port 66A for use in supplying the projector 20. The shot tank 66 supplies projection material to the projector 20 through the flow quantity adjustment device 68 and the introducing tube 70.
Operation/Effect
Next the operation and effect of a shot blasting apparatus 10 according to the embodiment above will be explained.
In the shot blasting apparatus 10 of the embodiment above, as shown in
Also, in the impeller 100, disposed on the radially outward position of the control cage 92 as shown in
Using the shot blasting apparatus 10 of the above embodiment, a rearward inclining portion 110, inclining rearward in the rotational direction (the arrow R direction) relative to the radial direction (the radiating direction line L1), is formed on the surface 106 of the impeller 100 blades 104. This enables projection material to be collected on the surface 106 of blades 104.
In this regards, explanation will be made by comparison to a comparative example, referring to
First, referring to
As shown in
Projection materials a, b, and c are respectively accelerated toward the tip end of the blade B2, however because the timing at which each of them hits the blade B2 is as described above, and the degree of acceleration of projection material increases as it moves toward the blade B2 tip end, projection materials a, b, and c cannot be collected on the blade B2, as shown in
On the other hand, even in the configuration shown in
In this arrangement, as shown in
Next, as shown in
Next, as shown in
Then, as shown in
In the projector 20 of the present embodiment, the surface 106 on the rotational direction of the impeller 100 comprises, on the inward part in the radial direction (base end portion) thereof, a rearward inclining portion 110 rearwardly inclining 40° in the rotational direction relative to the radial direction.
By reducing an inclining angle of the rearward inclining portion toward the rotationally rearward direction to 30° or greater, a sufficient time difference can be secured for projection material to get onto the blade, thereby enabling the concentration of the projection distribution to be improved. In addition, by adopting an angle of 50° or less for the rotational direction rearward inclining angle of the rearward inclining portion, the time difference for projection material getting onto the blade can be a much more preferable time difference; projection material is concentrated on the blade, and the length of the blade can be constrained.
Note that constraining blade length not only results in constraining blade weight and parts cost, but also has the advantage of easier workability during assembly, etc.
This point will be explained concretely referring to
In
As shown in
In the case of the comparative example (see dotted line) shown in
Here further explanation from another standpoint will be added. Air jetting machines for jetting compressed air containing projection material from a nozzle are known for concentrating projection material in a narrow projection distribution range. However with air jetting machines, the quantity of projection material which can be accelerated and projected is extremely small relative to the power consumed to produce the compressed air, so electrical power efficiency for projection is poor. I.e., power consumption increases with an air jetting machine.
By contrast, the projector 20 of the present embodiment is a centrifugal projector, so projection material can be efficiently projected relative to power consumption. Therefore, by applying the projector 20 of the present embodiment instead of an air jetting machine, power consumption and by extension running costs can be greatly reduced.
In the present embodiment, a rearward less-inclining portion 114, extending in approximately the radial direction from the rotational center of the impeller 100 (the radial line L2 direction), is formed at the tip end of the surface 106 on the blade 104. This rearward less-inclining portion enables the velocity of projection material concentrated at the rearward inclining portion 110 to be accelerated for projection.
This point will be explained in detail using
In
On the other hand, if the impeller is turned at a higher speed by the drive motor in order to increase the projection velocity, both noise and power consumption will increase. It also happens that when the drive motor rpm is increased, no-load power also rises.
However in the present embodiment, projection material concentrated by the rearward inclining portion 110 shown in
Also, in the present embodiment, as shown in
Also, in the present embodiment, the projection material is projected after the projection material has been accelerated by the rearward less-inclining portion 114, therefore the increase in impeller 100 rpm per unit time can be constrained, as can the increase in power consumption.
In the present embodiment, viewed in the direction of the impeller 100 rotary shaft, the length of the rearward inclining portion 110 is set to be longer than the length of the rearward less-inclining portion 114. Therefore the velocity of the projection material can be fully increased by the rearward less-inclining portion 114.
Also, in the present embodiment a curved portion 112 for smoothly connecting the rearward inclining portion 110 and the rearward less-inclining portion 114 is formed on the surface 106 of blades 104. Thus the velocity of the projection material can be gradually increased after projection material has been collected by the rearward inclining portion 110 of the blades 104.
In the present embodiment, the direction along which projection material is discharged from the opening 92X in the control cage 92 is inclined to the impeller 100 in rotationally forward direction.
Therefore the timing at which projection material discharged earlier from the opening 92X of the control cage 92 contacts the surface 106 of the blade 104 can be delayed, and projection material more effectively concentrated by the rearward inclining portion 110 on the surface 106 of the blade 104.
Also, in the present embodiment an inclined portion 116 is placed on the reverse surface 108 of the blades 104. When projection material discharged from the opening 92X contacts the base end portion of the reverse surface 108 of the blades 104 and is bounced back, the direction of the projection material bounce is deflected by the inclined portion 116, and the amount of bounce between blades 104 can be constrained. Disintegration of the flow of projection material between the blades 104 can thus be constrained.
In the shot blasting apparatus of the present embodiment, as shown in
In the shot blasting apparatus of the present embodiment, as shown in
As explained above, the amount of projection can be reduced using the shot blasting apparatus 10 of the present embodiment.
Note that as an alternative embodiment of the first embodiment above, it is also possible to use the projector 21 shown in
As shown in these figures, the projector 21 differs in construction from the first embodiment in that the rotary shaft of the drive motor is not directly fixed to the hub 82. In other respects, it has the same arrangement as the first embodiment. Hence for those constituent parts which are the same as the first embodiment, the same reference numerals are applied and an explanation thereof will be omitted.
A through hole, through which the tip portion of the bearing unit 74 or the like is inserted, is formed on the side portion 72B on the middle right side of the case main unit 72, and a tip portion 74A of a bearing unit 74 is disposed in the center portion in the case main unit 72 shown in the right portion of the diagram. The tip portion 74A of the bearing unit 74 is attached to the side portion 72B of the case main unit 72 shown in the right side of the diagram. The hub unit 74 comprises a bearing 74B, and rotatably supports the rotary shaft 77X.
A second pulley 79 is fixed to the base end portion of 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 the rotary shaft of a drive motor, not shown. The rotational force of the drive motor is thus transferred to the rotary shaft 77X.
The cylinder portion 82A of the hub 82 on the flanged cylindrical body is disposed on the radially outward of the tip portion 77A of the rotary shaft 77X. A center plate 90 is bolt-fixed to the hub 82. The hub 82 is fixed by a key to the tip portion 77A of the rotary shaft 77X.
The amount of projection material can also be reduced in a shot blasting apparatus of such an alternative embodiment. Also, in this type of the alternative embodiment the size of the apparatus as a whole increases, but an advantage is gained in reduced power consumption.
Next, referring to
Note that for elements which are substantially the same as those in the first embodiment, the same reference numerals will be applied and an explanation thereof will be omitted. The workpiece W processed by shot peening in this embodiment may be a product such as a gear, for example. The surface roughness of the workpiece W is reduced and the fatigue strength improved by shot peening.
As shown in
Inside the cabinet 132, a product mounting portion 134 is provided as a support mechanism to support the workpiece W in a processing position where surface treatment by the projector 20 is can be conducted. The product mounting portion 134 comprises a large table 138; multiple small tables 142 are disposed at equal spacing in the circumferential direction on the large table 138, at positions concentric with the large table 138.
The large table 138 is rotatable (orbit) about a vertical rotary shaft 136, and is disposed at a position which includes the projection range over which projection material is projected by the centrifugal projector 20.
Also, the small tables 142 have a smaller diameter than the large table 138, and comprise rotary shafts 140 parallel to the large table 138 rotary shaft 136; they can rotate (spin), and the workpiece W is placed on them.
A mechanism for holding down the workpiece W is provided at a position on the large table 138 corresponding to the projection range from the projector 20. This mechanism comprises a hold-down portion capable of holding down a workpiece W on the small tables 142 from above, and of rotating together with the workpiece W.
According to the present embodiment, as well, wasteful projection of projection material can be constrained, and the amount of projection can be reduced.
Next, referring to
The control cages 150, 152, 154, 156, and 158 shown in
Note that the projector comprising the control cage 150, 152, 154, and 156 shown in
In a projector comprising the control cages 150, 152, 154, and 156 shown in
A first opening portion 160 and a second opening portion 162 serving as projection material discharge portions are through-formed on the outer circumferential wall 150A of a control cage 150 shown in
The first opening portion 160 and second opening portion 162 both constitute openings in the control cage 150. The first opening portion 160 is placed between two mutually opposing parallel sides 160A and 160B, which are parallel to the cylinder axial center CL of the control cage 150.
The second opening portion 162 is set between two second parallel sides 162A and 162b, which are offset relative to the first opening portion 160 in the circumferential direction of the control cage 150 outer circumferential wall 150A and in the direction of the cylinder axial center CL.
The first opening portion 160 and second opening portion 162 are separated in the direction of the control cage 150 cylinder axial center CL, and approximately half of each overlap when viewed in the direction of the control cage 150 cylinder axial center CL.
Also, an opening 164 is through-formed as a projection material discharge portion on the outer circumferential wall 152A of the control cage 152 shown in
The opening 164 comprises a first opening portion 166 and a second opening portion 168. The first opening portion 166 is set between two mutually opposing first parallel sides 166A and 166B, which are parallel to the direction perpendicular to the control cage cylinder axial center CL.
The second opening portion 168 is set between mutually opposing second two parallel sides 168A and 168B, which are offset relative to the first opening portion 166 on the outer circumferential wall 152A of the control cage 152 in a circumferential direction and in a direction of the cylinder axial center CL of the control cage 152.
The first opening portion 166 and the second opening portion 168 communicate, and approximately half of each overlaps as viewed in a direction along the cylinder axial center CL of the control cage 152.
Also, an opening 170 is through-formed as a projection material discharge portion on the outer circumferential wall 154A of the control cage 154 shown in
The opening 170 comprises a first through opening portion 172 and a second opening portion 174. The first opening portion 172 is formed between mutually opposing first parallel sides 172A and 172B, which are parallel to the cylinder axial center CL of the control cage.
Also, the second opening portion 174 is set between mutually opposing second two parallel sides 174A and 174B, which are offset relative to the first opening portion 172 on the outer circumferential wall 154A in circumferential direction and in a direction of the cylinder axial center CL of the control cage 154.
The first opening portion 172 and second opening portion 174 communicate through a third opening portion 176. The third opening portion 176 links the terminus of the side 172A of the first opening portion 172 to the terminus of the side 174A of the second opening portion 174 in a straight line, and links the terminus of the side 172B of the first opening portion 172 to the terminus of the side 174B of the second opening portion 174 in a straight line.
Approximately half of each of the first opening portion 172 and the second opening portion 174 overlaps as seen in a direction along the cylinder axial center CL of the control cage 154.
Also, an opening 178 is through-formed as a projection material discharge portion on the outer circumferential wall 156A of the control cage 156 shown in
The opening 178 comprises a first through opening portion 180 and a second opening portion 182. The first opening portion 180 is set between mutually opposing first parallel sides 180A and 180B, which are parallel to the cylinder axial center CL of the control cage.
The second opening portion 182 is set between mutually opposing second two parallel sides 182A and 182B, which are offset relative to the first opening portion 180 in a circumferential direction of the outer circumferential wall 156A of the control cage 156 and in a direction along the cylinder axial center CL direction of the control cage 156.
A first opening portion 180 and second opening portion 182 are somewhat separated in a direction of the cylinder axial center CL when viewed in the direction perpendicular to the cylinder axial center CL of control cage 156 (the direction in
The first opening portion 180 and second opening portion 182 communicate by means of a third opening portion 184. The third opening portion 184 links the terminus of the side 180A of the first opening portion 180 and the terminus of the side 182A of the second opening portion 182 in a stepped shape, and links the terminus of the side 180B of the first opening portion 180 and the terminus of the side 182B of the second opening portion 182 in a stepped shape.
In a projector comprising the control cages 150, 152, 154, and 156 shown in
In a direction of the cylinder axial center CL of the control cages 150, 152, 154, and 156, approximately half of the first opening portions 160, 166, 172, and 180 and the second opening portions 162, 168, 174, and 182 overlap, therefore the projection distributions of projection material respectively discharged from the first opening portions 160, 166, 172, and 180 and the second opening portions 162, 168, 174, and 182 also overlap in approximately half the range of their respective distribution widths. Thus as an overall projection distribution, there is a broadening of the range over which projection quantity is high (the range in which concentrated projection was sought).
Also
Using the above arrangement, a projector comprising the control cages 150, 152, 154, and 156 shown in
This concretely will be explained with reference to the projection distribution graph shown in
As shown in
Taking that total workpiece processing time is the time until desired polishing and cleaning of the part with the lowest projection fraction is accomplished, and the above analysis, into consideration, it can be seen that when the angle connecting the position of projection material projection by the projector to the position of both edges of the surface facing the projector on a workpiece disposed in the processing position is 50° to 80° when viewed in the impeller rotational direction, the projection fraction effective for surface treatment can be raised more in the present embodiment (solid line) than in the comparative example (dotted line).
When seeking to perform shot processing over a wide area using an air jetting apparatus for jetting compressed air containing projection material from a nozzle, the number of nozzles may increase, or relative movement between the jetting apparatus and the workpiece may increase. This leads to an extremely large increase in power consumption. By contrast, in the present embodiment a centrifugal projector is used, therefore power consumption can be constrained.
Next, a projector (a reference example not included in the present invention) comprising the control cage 158 shown in
An opening 186 is through-formed as a projection material discharge portion on the outer circumferential wall 158A of the control cage 158 shown in
The opening 186 is a parallelepiped opening portion defined by two parallel sides 186A and 186B extending in a direction perpendicular to the cylinder axial center CL of the control cage 158 and opposing one another.
As the alternatives of each of the embodiments above, it is also possible to use blades 190 shown in
In the embodiment above, the rearward inclining portion 110 shown in
The rearward less-inclining portion on the tip end of the blade surface may be of any type so long as the inclining angle toward the rotationally rearward direction is smaller than that of the rearward inclining portion. In the present specification, the phrase “the inclining angle toward the rotationally rearward direction is smaller than that of the rearward inclining portion” includes cases in which that inclining angle is smaller than the inclining angle of the rearward inclining portion toward the rotationally rearward direction, as well as configurations extending in a radial direction, and configurations inclining toward the rotationally forward direction, therefore a rearward less-inclining portion may be one which extends relative to the radial direction from the impeller rotational center, or one which inclines toward the rotational forward direction relative to the radial direction. It is also acceptable not to provide a rearward less-inclining portion.
Also, the radial length of the rearward inclining portion may be set to be the same as the radial length of the rearward less-inclining portion.
An arrangement in which the rearward inclining portion and the rearward less-inclining portion are directly linked without mediation by a curved portion is also acceptable.
In addition, an arrangement in which no inclining portion is formed is also acceptable.
An arrangement is possible in which no inner lid is provided, such as in cases where an intermediate zone can be established between the loading/unloading zone and the processing zone.
When an intermediate zone can be established between the loading/unloading zone and the processing zone, the projector may be installed on the cabinet side wall portion on the side of the intermediate zone.
The projector 20 impeller may also be set to rotate in the opposite direction from the embodiments above.
In the first embodiment above, the hold-down portion 48 shown in
In a conveyor mechanism comprising a first row conveyor and a second row conveyor, screw conveyors respectively corresponding to the first row conveyor and the second row conveyor may be provided.
It is also acceptable to separately provide an endless belt constituting a first row conveyor, and an endless belt constituting a second row conveyor, driving each endless belt with separate drive motors.
An arrangement is also acceptable in which no partitioning portion 57, shown in
Note that the above-described embodiments or multiple variant examples may be combined as appropriate.
The invention above in reference to embodiments has been explained, but the present invention is not limited to the above embodiments or the like, and may be changed or varied in numerous ways within the scope of the claims.
Number | Date | Country | Kind |
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2014-129579 | Jun 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2015/066447 | 6/8/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/198844 | 12/30/2015 | WO | A |
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Number | Date | Country | |
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20170144269 A1 | May 2017 | US |