JP2018034253A - Grinding device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a grinding device which can rapidly replace a workpiece.SOLUTION: A grinding device 10 supports first and second rotary tables 41, 41 rotatably, and the rotary table 41 sandwiched between a pair of rotary grindstones 13, 14 can be changed optionally by rotation of a movable support table 26. Thereby, replacement of a workpiece W can be carried out rapidly by housing the workpiece W previously in a plurality of workpiece housing holes 45 of the rotary table 41 which is not sandwiched between the pair of rotary grindstones 13, 14 and moving the rotary table 41 between the pair of rotary grindstones 13, 14. In addition, as first and second junction sleeves 57, 58 interlocking and rotating with the first and second rotary tables 41, 41 is arranged coaxially on a lower side of the movable support table 26, first and second rotary table drive sources 51, 52 for imparting rotation power to them can be fixed to a fixing part (a sub frame 21).SELECTED DRAWING: Figure 2

Description

  The present invention relates to a grinding apparatus for grinding a workpiece with a pair of rotating grindstones.

  Conventionally, as this kind of grinding apparatus, a rotary table having a plurality of work receiving holes at the outer edge, a pair of rotating grindstones facing each other with a part of the rotary table sandwiched in the vertical direction, and a work in the work receiving hole There is known a grinding apparatus having a support table that supports the base plate from below at a position deviated from between a pair of rotating grindstones (see, for example, Patent Document 1).

JP 09-295256 A (FIG. 2, paragraph [0005])

  However, the above-described conventional grinding apparatus has a problem that it takes time to replace a ground workpiece with a workpiece to be ground.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a grinding apparatus capable of quickly exchanging workpieces.

  In order to achieve the above object, the invention of claim 1 is characterized in that a rotating table having a plurality of workpiece receiving holes at an outer edge portion and a part of the rotating table that are opposed to each other from above and below are rotated, and the workpiece A pair of rotating grindstones for grinding the upper and lower ends of the workpiece in the accommodation hole and a rotary table shaft extending downward from the center of the rotary table are rotatably supported, and the workpiece in the workpiece accommodation hole is supported. A grinding apparatus having a support table supported from below at a position deviated from between the pair of rotating grindstones, constituting a part of the support table and centering on a rotation axis substantially parallel to the rotation axis of the rotation table And the rotary table shafts of the first and second rotary tables are rotatably supported at two positions away from the rotation axis, and between the pair of rotary grindstones. A movable support table that can arbitrarily change the sandwiched rotary table, a fixed base that rotatably supports the movable support table, and the movable support table together with the support table, and is fixed to the fixed base, A fixed support table that surrounds the movable support table; a first relay rotating body that is arranged on the lower coaxial side of the movable support table and has an upper end portion coupled to the first rotary table shaft so as to be capable of interlocking rotation; A second relay rotary body having a cylindrical shape and fitted to the outside of the first relay rotary body, the second rotary table shaft being coupled to the upper end portion so as to be capable of interlocking rotation, and the fixed base And a first rotary table drive source for applying rotational power to the lower end of the first relay rotating body, and the second relay mounted on the fixed base. A grinding apparatus and a second rotary table drive source to impart rotational power to the lower end portion of the rotating body.

  The invention of claim 2 is characterized in that the first relay rotator has a cylindrical shape, extends downward from the center of the movable support table, and is inserted into the first relay rotator. The grinding apparatus according to claim 1, further comprising: a support table drive source that is attached to the fixed base and applies rotational power to a lower end portion of the support table shaft.

  According to a third aspect of the present invention, the drive power source for the support table with a speed reducer is disposed coaxially below the support table shaft, and an output portion of the speed reducer is connected to the support table shaft so as to be integrally rotatable. The first rotary table drive source with a machine and the second rotary table drive source with a speed reducer are arranged on the side of the support table drive source, and the first rotary table drive source is provided. The output part of the speed reducer of the source is connected to the lower end part of the first relay rotating body so as to be capable of interlocking rotation, and the output part of the speed reducer of the driving source for the second rotary table is connected to the second relay rotation. The grinding apparatus according to claim 2, wherein the grinding apparatus is connected to a lower end portion of the body so as to be capable of interlocking rotation.

  According to a fourth aspect of the present invention, in the fixed support table, one of the first and second rotary tables is partially sandwiched between the pair of rotary wheels. The grinding apparatus according to any one of claims 1 to 3, wherein a workpiece discharge port that can be opened and closed by a lid is provided at a position where the workpiece of the other rotary table passes above.

  The invention according to claim 5 provides rotational power to the rotary table, a part of which is sandwiched between the pair of rotary grindstones of the first and second rotary tables, while the pair of rotary tables. A first control means for controlling the first and second rotary table drive sources so that rotational power is not applied to the rotary table that is not sandwiched between the rotary wheels, and between the pair of rotary wheels The grinding device according to any one of claims 1 to 4, further comprising a manual operation button for arbitrarily rotating the rotary table not sandwiched between the rotary tables.

  According to a sixth aspect of the present invention, the rotary table partially sandwiched between the pair of rotary wheels among the first and second rotary tables is disengaged from between the pair of rotary wheels. A length measuring device that is stacked from above at a position to measure the length of the workpiece, and the length of the workpiece of the entire rotary table measured by the length measuring device is set to a predetermined reference length. 6. The grinding apparatus according to claim 1, further comprising: a second control unit that moves the rotary table to the outside between the pair of rotary whetstones on the condition that the rotary table is reached. is there.

  According to a seventh aspect of the present invention, the rotary table that is partially sandwiched between the pair of rotary wheels among the first and second rotary tables is disengaged from between the pair of rotary wheels. A length measuring device for measuring the length of the workpiece, a measuring position at which the length of the workpiece can be measured, and a portion rotating with the movable support table. A length measuring device support mechanism that is movably supported between an interference avoidance position that avoids interference, and provided in the length measuring device support mechanism, and operates in synchronization with the rotation and stop of the movable support table, The grinding apparatus according to any one of claims 1 to 6, further comprising a length measuring device moving drive source that moves the length measuring device to the interference avoidance position when the movable support table rotates.

[Invention of Claim 1]
In the grinding apparatus according to claim 1, the first and second rotary tables are rotatably supported by the movable support table, and the rotary table sandwiched between the pair of rotary grindstones is arbitrarily changed by the rotation of the movable support table. be able to. As a result, workpieces are accommodated in advance in a plurality of workpiece accommodation holes of the rotary table that are not sandwiched between the pair of rotary wheels, and the workpiece is changed by moving the rotary table between the pair of rotary wheels. Can be done quickly. Moreover, in the grinding apparatus of the present invention, the first and second relay rotating bodies that rotate in conjunction with the first and second rotating tables are arranged on the lower coaxial side of the movable support table, so that the rotational power is given to them. The first and second rotary table drive sources to be applied can be fixed to the fixed base. This makes the entire grinding apparatus compact.

  Note that the grinding apparatus of the present invention only needs to include two or more rotary table drive sources including the first and second rotary tables, and the grinding apparatus having three or more rotary table drive sources is also included in the present invention. Included in the grinding machine.

[Inventions of Claims 2 and 3]
The movable support table described above may be manually rotated, or may be rotationally driven by the rotational power of the support table drive source as in the second aspect of the invention. In the case where the support table drive source is provided, for example, an annular gear may be provided on the outer edge of the movable support table, and the rotational power of the support table drive source may be applied to the pinion gear meshing therewith. As shown in the configuration, the first relay rotating body is formed into a cylindrical shape, and a support table shaft extending from the center of the movable support table is inserted inside the first rotation rotating body. It is good also as a structure which provides rotational power. According to the structure of Claim 2, it becomes cheap and compact.

  Further, as in the configuration of claim 3, the support table drive source with a speed reducer is arranged coaxially below the support table shaft, and the first and second rotary table drive sources with the speed reducer are for the support table. By disposing on the side of the drive source, an arrangement in which a plurality of drive sources are combined is achieved, and the size is further reduced.

[Invention of claim 4]
According to the configuration of claim 4, while the work of one rotary table of the first and second rotary tables is being ground by the pair of rotary grindstones, The workpiece can be discharged from the workpiece discharge port.

[Invention of claim 5]
According to the structure of Claim 5, the rotary table which is not pinched | interposed between a pair of rotary grindstones among the 1st and 2nd rotary tables is not normally rotating, but is rotated by operation of a manual operation button. Therefore, when the work is accommodated in the work accommodating portion of the rotary table manually, the work can be efficiently performed.

[Invention of claim 6]
According to the configuration of the sixth aspect, the length of the workpiece is measured by the length measuring device at a position deviated from between the pair of rotating wheels with respect to the rotating table partially sandwiched between the pair of rotating wheels. The workpiece is moved to the outside between a pair of rotating grindstones on the condition that the measured length of the workpiece of the entire rotating table has reached the reference length. It is possible to prevent a situation where excessive grinding occurs.

[Invention of Claim 7]
In the structure of Claim 7, when a movable support table rotates, a length measuring device is moved so that interference with the site | part which rotates with a movable support table and a length measuring device may be avoided. In other words, the movable region of the part that rotates together with the movable support table can be effectively used, and the entire grinding apparatus can be made compact.

The side view of the grinding device concerning one embodiment of the present invention. Front sectional drawing of the table unit in the AA cut surface of FIG. Sectional drawing of the sub-frame in the CC cut surface of FIG. Sectional drawing of the grinding apparatus in the BB cut surface of FIG. Enlarged side sectional view around the rotary table Partially enlarged side sectional view of rotating wheel and rotating table Flow chart of processing by control unit of grinding device

  Hereinafter, a grinding apparatus 10 according to an embodiment of the present invention will be described with reference to FIGS. As shown in FIG. 1, the grinding apparatus 10 according to this embodiment includes a table unit 20 on the front surface of a grinding apparatus body 11. The main body 11 of the grinding apparatus includes a main frame 12 having a vertically long casing structure, and a pair of rotating grindstones 13 and 14 are vertically arranged in the main frame 12 so as to face each other. The pair of rotating grindstones 13 and 14 are both disk-shaped, and their rotational axes are arranged substantially coaxially. The rotating grindstones 13 and 14 are, for example, driven to rotate in the same direction at the same rotational speed, and can be moved to arbitrary positions in the vertical direction. In addition, a front opening 15 is formed in the central portion of the front surface of the main frame 12 in the vertical direction, and a rotary table 41 and a fixed support table 25 described later are received in the main frame 12 from the front opening 15. .

  As described above, the table unit 20 is provided on the front surface of the grinding apparatus body 11. Hereinafter, in the table unit 20, the grinding apparatus body 11 side is referred to as “rear side” and the opposite side is referred to as “front side”. The table unit 20 includes a substantially rectangular parallelepiped subframe 21 (corresponding to the “fixed base” of the present invention), and the horizontal width of the subframe 21 is substantially the same as the horizontal width of the main frame 12.

  As shown in FIGS. 2 and 3, a pair of hinge arms 21 </ b> H and 21 </ b> H are provided on one side of the rear surface of the subframe 21. As shown in FIG. 1, the sub-frame 21 is overlapped at a lower position on the front surface of the main frame 12, and the hinge arms 21 </ b> H and 21 </ b> H are hinged to the front surface of the main frame 12. The other side portions of the subframe 21 and the main frame 12 are fixed to a lock mechanism (not shown). Further, the entire table unit 20 is floating from the floor surface. Then, if necessary, the lock mechanism can be unlocked and the table unit 20 can be rotated with respect to the grinding apparatus body 11.

  As shown in FIG. 3, the planar shape of the subframe 21 is substantially square and is open in both the upper and lower directions. Further, a plurality of support plates 23 shown in FIGS. 2 and 3 protrude in four directions from the outer surface of the upper end portion of the subframe 21. The upper surfaces of the support plates 23 are flush with each other, and the fixed support table 25 according to the present invention shown in FIG. The fixed support table 25 has an octagonal shape as a whole, for example. In addition, as shown in FIG. 4, in the fixed support table 25, on the grinding apparatus body 11 side, in order to avoid interference with the lower rotating grindstone 14, an arc-shaped notch that swells inward from the outer peripheral surface side. 25B is formed. The inner surface of the notch 25B faces the outer peripheral surface of the lower rotating grindstone 14 with a slight gap. Some of the support plates 23 are supported from below by ribs 23L (see FIG. 3).

  As shown in FIG. 2, a support beam 22 is bridged between inner surfaces facing in the lateral direction of the subframe 21 at a position near the lower end inside the subframe 21 (in FIG. 2, The state where the rotary tables 41 and 41, which will be described later, are retracted from the main frame 12 is shown). As shown in FIG. 3, the support beam 22 is located at the center in the front-rear direction of the subframe 21, and the horizontal center position of the support beam 22 (that is, a square centroid that is a planar shape of the subframe 21 and Center hole 50A penetrates vertically. As shown in FIG. 2, the support table shaft 29 is rotatably supported by the center hole 50A via a bearing. Further, the support table shaft 29 extends upward to a position near the upper surface of the subframe 21, and a rotation bar 27 is attached to an upper end portion thereof so as to be integrally rotatable. As shown in FIG. 4, the rotating bar 27 has a prismatic shape and rotates within the subframe 21 while drawing a circle slightly smaller than the circular opening 25 </ b> A of the fixed support table 25.

  A disk-shaped table main body 26H is fixed to the upper surface of the rotary bar 27 via circular spacers 26S and 26S (see FIGS. 4 and 5), and the rotary bar 27 and the table main body 26H are used in accordance with the present invention. A movable support table 26 is configured. The table body 26H is loosely fitted in the circular opening 25A of the fixed support table 25 with a slight gap. Furthermore, the upper surface of the table body 26H and the upper surface of the fixed support table 25 are disposed substantially flush with each other. The movable support table 26 and the fixed support table 25 constitute a support table 10T according to the present invention.

  As shown in FIG. 2, the lower end portion of the support table shaft 29 has a cylindrical shape, and an output shaft 50J of the support table drive source 50 is connected to the support table shaft 29 by a key (not shown) so as to be integrally rotatable. The support table drive source 50 corresponds to the “support table drive source with a speed reducer” according to the present invention. As shown in FIG. 1, the speed reducer 50G is mounted on one end of the motor 50M on the same axis. The main body of the machine 50G is fixed to the lower surface of the support beam 22, and the output shaft 50J of the speed reducer 50G is connected to the support table shaft 29 as described above, as shown in FIG. Then, the output of the motor 50M is decelerated and transmitted to the output shaft 50J of the speed reducer 50G and applied to the support table shaft 29, whereby the movable support table 26 is rotationally driven.

  First support holes 30 </ b> A and 30 </ b> A penetrating the rotation bar 27 vertically are formed at both ends of the rotation bar 27 that are symmetrical with respect to the support table shaft 29. The movable support table 26 is formed with support holes 26A and 26A communicating with the first support hole 30A of the rotary bar 27.

  The rotary table shafts 31 and 32 are rotatably supported by the first support holes 30A and 30A of the rotary bar 27 through bearings, respectively. Then, the rotary table shafts 31 and 32 pass through the support holes 26A and 26A of the movable support table 26 and protrude upward from the movable support table 26. Further, the rotary table shafts 31 and 32 also protrude below the rotary bar 27, and the rotary table shafts 31 and 32 have the same structure except that their downward protruding amounts are different.

  Intermediate flanges 31F and 32F protrude laterally from the intermediate positions in the vertical direction of the rotary table shafts 31 and 32, respectively, and the intermediate flanges 31F and 32F support the rotary table shafts 31 and 32, respectively. It is in contact with the inner of the bearing.

  A rotary table 41 is mounted on each rotary table shaft 31, 32 from above. As shown in FIG. 5, the rotary table 41 is formed by inserting a support sleeve 44 through a through hole formed in the center of a disk-shaped table main body 43. The support sleeve 44 has a structure in which a lower end flange 44F protrudes laterally from the lower end of the cylindrical body, and the table main body 43 is fixed to the lower end flange 44F with a bolt B1. The support sleeve 44 is fitted and key-connected to the upper part of the rotary table shafts 31 and 32 above the intermediate flanges 31F and 32F, and the upper end portion of the support sleeve 44 is covered by the lid body 44W. The support sleeve 44 is fixed by a bolt B3. Further, the lid 44W is provided with an adjustment bolt B2 that is connected to the rotary table shafts 31 and 32 so as not to be able to move linearly and to be rotatable, and a fixing bolt B4 is provided on the side of the support sleeve 44. It is. Thereby, the clearance gap between the table main body 43 and the movable support table 26 can be adjusted, and the table main body 43 can be supported in the state slightly floated from the fixed support table 25 and the movable support table 26. The upper surface of the lower end flange 44F is disposed in a state slightly above the upper surfaces of the fixed support table 25 and the movable support table 26.

  As shown in FIG. 4, a plurality of work receiving holes 45 are formed in the outer edge portion of the rotary table 41 (specifically, the outer edge portion of the table main body 43). Then, as shown in FIG. 6, a compression coil spring is accommodated as a work W in each work accommodation hole 45. Further, as shown in FIG. 4, the rotary table 41 is accommodated in the fixed support table 25 and has a size such that the rotary tables 41 and 41 do not interfere with each other. Then, due to the rotation of the movable support table 26, a part of one of the rotary tables 41 is arranged between the pair of rotary grindstones 13 and 14, and the workpieces W in the workpiece receiving holes 45 of the rotary table 41 are arranged. The upper and lower ends are ground by the rotating grindstones 13 and 14.

  Hereinafter, in FIG. 4, the rotary table 41 in a state where the straight line connecting the rotation center of the rotary grindstones 13 and 14 and the rotation center of the rotary table 41 is located at the shortest position is located on the rotary grindstones 13 and 14 side. It is referred to as “rotation table 41 at the origin position”, and the rotation table 41 on the opposite side is referred to as “the rotation table 41 at the origin facing position”. When the rotary table shafts 31 and 32 are distinguished from each other, as shown in FIG. 2, the rotary table shaft 31 having a small downward projection from the rotary bar 27 is referred to as a “first rotary table shaft 31”. The rotary table shaft 32 having a large value is referred to as a “second rotary table shaft 32”. Furthermore, only when distinguishing between the rotary tables 41, 41, the rotary table 41 mounted on the rotary table shaft 31 is referred to as a “first rotary table 41”, and the rotary table mounted on the rotary table shaft 32. 41 is referred to as a “second rotary table 41”.

  As shown in FIG. 2, in order to rotationally drive the first rotary table 41, the “first rotation with a speed reducer” according to the present invention is provided on the left side of the support beam drive source 50 among the support beams 22. A first rotary table drive source 51 corresponding to “table drive source” is attached. Further, in order to rotationally drive the second rotary table 41, a position of the support beam 22 that is symmetrical to the first rotary table drive source 51 across the support table drive source 50 is related to the present invention. A second rotary table drive source 52 corresponding to a “second rotary table drive source with a speed reducer” is attached. Similarly to the support table drive source 50, the first and second rotary table drive sources 51 and 52 are configured by attaching speed reducers 51G and 52G on one end of the motors 51M and 52M, and the speed reducers 51G and 52G. Is fixed to the lower surface of the support beam 22.

  The support beam 22 is provided with support holes 51A and 52A that vertically penetrate the upper positions of the first and second rotary table drive sources 51 and 52. The first and second support holes 51A and 52A are provided with first and second support holes 51A and 52A, respectively. First stage shafts 53 and 54 are rotatably supported via bearings. Similarly to the connection between the support table shaft 29 and the support table drive source 50, the output shaft 51J of the first rotary table drive source 51 is connected to the first first stage shaft 53 so as to be integrally rotatable, and the second The output shaft 52J of the second rotary table drive source 52 is coupled to the first stage shaft 54 so as to be integrally rotatable.

  The first-stage gear 55 having the same shape is fixed to the upper end portions of the first and second first-stage shafts 53 and 54 so as to be integrally rotatable. Further, the second first stage shaft 54 protrudes greatly upward from the first first stage shaft 53, so that the first stage gear 55 of the second first stage shaft 54 is more than the first stage gear 55 Y of the first first stage shaft 53. It is arranged above.

  The first and second relay sleeves 57 and 58 corresponding to the first and second first-stage shafts 53 and 54 (the “first and second relay sleeves” according to the present invention) (Corresponding to “relay rotating body”) is rotatably fitted. Specifically, the first relay sleeve 57 has a cylindrical shape and is rotatably supported on the outside of the support table shaft 29 via a bearing. Further, a second gear 57G1 projects laterally from the lower end of the first relay sleeve 57, and a third gear 57G2 projects laterally from the upper end.

  On the other hand, the second relay sleeve 58 is formed in a cylindrical shape shorter than the first relay sleeve 57, and between both ends of the first relay sleeve 57 (that is, the second gear 57G1 and the third gear 57G2). And is rotatably supported via a bearing. Similarly to the first relay sleeve 57, the second gear 58G1 projects laterally from the lower end of the second relay sleeve 58, and the third gear 58G2 projects laterally from the upper end. . The second stage gears 57G1 and 58G1 and the third stage gears 57G2 and 58G2 all have the same specifications. The first stage gear 55 of the first first stage shaft 53 meshes with the second stage gear 57G1 of the first relay sleeve 57, and the first stage gear 55 of the second first stage shaft 54 is the second stage of the second relay sleeve 58. It meshes with the gear 58G1.

  A pair of second support holes 30B and 30B penetrates in the vertical direction at positions closer to the center than the first and second rotary table shafts 31 and 32 in the rotary bar 27 described above. First and second idle shafts 59 and 60 corresponding to the first and second relay sleeves 57 and 58 are rotatably supported by the bearings 30B and 30B via bearings.

  The first and second idle shafts 59 and 60 protrude below the rotary bar 27, and the same fourth-stage gears 61 are fixed to the lower end portions of the first and second idle shafts 59 and 60, respectively. Further, the second idle shaft 60 on the second turntable shaft 32 side has a larger amount of protrusion downward from the rotation bar 27 than the first idle shaft 59 on the first turntable shaft 31 side, The fourth gear 61 of the second idle shaft 60 is disposed below the fourth gear 61 of the first idle shaft 59. The fourth gear 61 of the first idle shaft 59 is engaged with the third gear 57G2 of the first relay sleeve 57, and the fourth gear 61 of the second idle shaft 60 is engaged with the second relay sleeve 58. Is engaged with the third gear 58G2. In place of the above configuration, the first and second idle shafts 59, 60 are fixed to the second support holes 30B, 30B of the rotary bar 27, and the first gears 61, 61 are assembled with bearings. The fourth gears 61 and 61 may be rotatably supported by the second idle shafts 59 and 60, and only the fourth gears 61 and 61 may be rotated.

  Furthermore, the last-stage gear 62 having the same shape is fixed to the lower ends of the first and second rotary table shafts 31 and 32 so as to be integrally rotatable. The amount of protrusion of the second rotary table shaft 32 downward from the rotary bar 27 is larger, so that the final gear 62 of the second rotary table shaft 32 is the final of the first rotary table shaft 31. It is arranged below the step gear 62. Then, the final gear 62 of the first rotary table shaft 31 is engaged with the fourth gear 61 of the first idle shaft 59, and the final gear 62 of the second rotary table shaft 32 is the second idle shaft 60. Is engaged with the fourth gear 61.

  With the above structure, the rotary power of the first rotary table drive source 51 is transmitted to the first rotary table shaft 31 at the arbitrary rotational position of the movable support table 26, and the first rotary table 41 is driven to rotate. The rotational power of the second rotary table drive source 52 is transmitted to the second rotary table shaft 32, and the second rotary table 41 is rotationally driven.

  Further, by rotating the rotation table 41 at the origin position, the plurality of workpieces W accommodated in the plurality of workpiece accommodation holes 45 of the rotation table 41 are uniformly ground. Then, a length measuring device 65 for determining whether or not the axial length of the plurality of workpieces W has reached a predetermined reference length is provided on a support arm 80 extending from the grinding apparatus body 11 as shown in FIG. It is supported.

  The support arm 80 corresponds to a “length measuring device support mechanism” according to the present invention. The support arm 80 is fixed to one side surface from the grinding device main body 11 and protrudes horizontally forward from the front end portion of the first arm 81. The rotary shaft 83 is suspended, and the second arm 82 extends horizontally from the lower end of the rotary shaft 83, and a length measuring device 65 is attached to the tip of the second arm 82. Further, an air actuator 85 (corresponding to the “length measuring device moving drive source” according to the present invention) is attached to the upper surface of the distal end portion of the first arm 81. The air actuator 85 has a rotation output section (not shown) on the lower surface, and the rotation output section is fixed to the upper portion of the rotation shaft 83 so as to be integrally rotatable. Further, the air actuator 85 is provided with a pair of nozzles (not shown). Then, an air valve (not shown) is switched between a state in which air is supplied to one nozzle and a state in which air is supplied to the other nozzle, the second arm 82 is turned, and the length detector 65 is turned on. It moves between a measurement position, which will be described later, and an interference avoidance position.

  The length measuring device 65 has a rod 66 that can move up and down, and a contact disk 67 is provided at the lower end of the rod 66. The outer edge portion of the lower surface of the contact disk 67 is tapered, and the entire lower surface except the outer edge portion is a flat surface. The length measuring device 65 is provided with a lifting device (not shown) (corresponding to the “length measuring device moving drive source” according to the present invention) capable of moving the contact disk 67 to an arbitrary height. ing. The lifting device restricts the contact disk 67 from moving downward from an arbitrary height position, and allows upward movement. When the length measuring device 65 is arranged at the measurement position, the contact disk 67 is held on the movable support table 26 at a height position slightly lower than the reference length from the upper surface of the movable support table 26. Then, a plurality of (for example, 2 to 3) work receiving holes 45 of the turntable 41 at the origin position are covered. When the rotary table 41 rotates in this state, the workpiece W that has passed between the pair of rotary grindstones 13 and 14 sequentially sinks below the contact disk 67, and the contact disk 67 is pushed up at that time. The axial length of the workpiece W is measured by the amount to be measured.

  When the axial lengths of the plurality of workpieces W measured by the length detector 65 reach the reference length, it is determined that the grinding of the plurality of workpieces W on the rotary table 41 at the origin position has been completed. And the process shown in FIG. 7 is performed by the control part (not shown) with which the grinding apparatus 10 was equipped.

  That is, when the grinding of the one rotary table 41 at the origin position is completed (YES in S1), the contact disk 67 is moved to a position away from the workpiece W by the lifting device of the length measuring device 65 (S2). In order to avoid interference between the support sleeve 44 (see FIG. 1) of the rotary table 41 and the length measuring device 65, the length measuring device 65 is moved to the interference avoidance position above the fixed support table 25 by the air actuator 85. It is turned (S3). In this state, the movable support table 26 is rotated by 180 degrees, the one rotary table 41 located at the origin position is moved to the origin facing position, and the other rotating table 41 located at the origin facing position is moved to the origin position. (S4). Next, the length measuring device 65 is pivoted from the interference avoidance position to the measurement position (S5), and the contact disk 67 is at a height position slightly lower than the reference length described above from the upper surface of the movable support table 26 as described above. This is held (S6), whereby the grinding of the plurality of workpieces W held by the other rotary table 41 is started (S7), and length measurement is started. When the axial lengths of the plurality of workpieces W measured by the length measuring device 65 reach the reference length, the above-described processing is repeated. In addition, while the above-described process is repeated, the pair of rotating grindstones 13 and 14 are maintained in a rotated state.

  The control unit when executing the processes of the above-described symbols S1 to S4 corresponds to “second control means” according to the present invention.

  As shown in FIG. 4, the fixed support table 25 is provided with a work discharge port 70 for discharging the work W downward from the work receiving hole 45 of the rotary table 41 at the position facing the origin. The work discharge port 70 is formed by cutting the position of the fixed support table 25 farthest from the grinding apparatus body 11 into a substantially rectangular shape. Further, the work discharge port 70 is normally closed by a lid body 68 having the same shape as that of the work discharge port 70. The lid body 68 is hinge-connected to the opening edge of the work discharge port 70 at the center side edge of the fixed support table 25, and pivots downward to open the work discharge port 70. Further, when the lid 68 is closed, the upper surface of the lid 68 and the upper surface of the fixed support table 25 are flush with each other. Further, as shown in FIG. 1, an air cylinder 69 as a drive source for opening and closing the lid 68 is provided below the work discharge port 70. The air cylinder 69 is rotatably connected at its lower end to a rib protruding from the outer front surface of the subframe 21, and the linear rod 69 </ b> R of the air cylinder 69 is rotatably connected to a rib provided on the lower surface of the lid 68. Has been. Then, the lid body 68 is opened and closed by the linear motion of the linear motion rod 69R.

  Further, a work discharge duct 71 is provided in front of the outer surface of the subframe 21 so as to surround the air cylinder 69. The upper end portion of the work discharge duct 71 is abutted against the opening edge of the work discharge port 70 from below, and the lower end portion of the work discharge duct 71 is open downward. When the workpiece W is discharged from the workpiece receiving hole 45 of the rotary table 41 to the workpiece discharging port 70 in a state where the workpiece receiving box 72 is disposed below the workpiece discharging duct 71, the workpiece W is guided to the workpiece discharging duct 71. And stored in the work storage box 72.

  The control unit of the grinding apparatus 10 completes the grinding of the work W of the one rotary table 41 and turns the movable support table 26 by 180 degrees, then opens the lid 68 and rotates the rotary table 41 at the position facing the origin. After all the workpieces W on the rotary table 41 are discharged to the workpiece discharge port 70, the lid 68 is closed, and the rotation of the rotary table 41 at the position facing the origin is stopped. The control unit when executing the above-described processing corresponds to the “first control unit” according to the present invention.

  Further, the control unit is provided with a manual operation button (not shown) for arbitrarily rotating the rotary table 41 at the position facing the origin. Thus, when a new workpiece W is manually inserted into the workpiece accommodation hole 45 after the workpiece W is discharged, the operator arbitrarily rotates the rotary table 41 to insert the workpiece into the workpiece accommodation hole 45. Can be performed efficiently.

  This completes the description of the configuration and operation of the grinding apparatus 10 of the present embodiment. The effects of the grinding apparatus 10 are summarized as follows. That is, as described above, according to the grinding device 10, the first and second rotary tables 41 and 41 are rotatably supported, and the movable support table 26 is rotated so that the pair of rotary grindstones 13 and 14 are interposed. The rotary table 41 sandwiched between the two can be arbitrarily changed. Thereby, the workpiece | work W is previously accommodated in the some workpiece | work accommodation hole 45 of the rotary table 41 which is not pinched | interposed between a pair of rotary grindstones 13 and 14, The rotary table 41 is accommodated in a pair of rotary grindstones 13, 14, the workpiece W can be exchanged quickly. Moreover, in the grinding apparatus 10 of the present embodiment, the first and second relay sleeves 57 and 58 that rotate in conjunction with the first and second rotary tables 41 and 41 are disposed on the lower coaxial side of the movable support table 26. The first and second rotary table drive sources 51 and 52 for applying rotational power to them can be fixed to the fixing portion (subframe 21). As a result, the entire grinding apparatus 10 can be made compact as compared with the case where the first and second rotary table drive sources 51 and 52 are fixed to the movable part (for example, the movable support table 26), and the cable Easy handling. Further, a support table shaft 29 that rotates integrally with the movable support table 26 passes through the inside of the first relay sleeve 57, and a support table drive source 50 is disposed below the support table shaft 29 in the subframe 21. Since it is fixed, the grinding apparatus 10 can be made compact in this respect as well.

  Further, the length of the workpiece W is measured by the length measuring device 65 at a position deviated from between the pair of rotary wheels 13 and 14 with respect to the rotary table 41 partially sandwiched between the pair of rotary wheels 13 and 14. The rotation table 41 is moved to the outside between the pair of rotating grindstones 13 and 14 on the condition that the measured length of the workpiece W of the entire rotation table 41 has reached the reference length. Therefore, it is possible to prevent the workpiece W from being excessively ground beyond the reference length.

  Further, since the length measuring device 65 is moved so as to avoid the interference between the length measuring device 65 and the support sleeve 44 that rotates together with the movable support table 26 when the movable support table 26 rotates, the support sleeve 44 is movable. Effective use of the area is achieved, and in this respect as well, the entire grinding apparatus 10 can be made compact.

  In addition, while the workpiece W of one rotary table 41 is being ground by the pair of rotary grindstones 13 and 14, the workpiece W of the other rotary table 41 that has been ground is discharged to the workpiece discharge port 70. be able to.

[Other Embodiments]
The present invention is not limited to the above-described embodiment. For example, the embodiments described below are also included in the technical scope of the present invention, and various modifications are possible within the scope of the invention other than the following. It can be changed and implemented.

  (1) In the above embodiment, the first and second rotating shafts 31 and 32 are connected to the first and second relay sleeves 57 and 58 by gears. The structure connected with the friction wheel etc. may be sufficient.

  (2) In the above embodiment, the length measuring device 65 is configured to move from the measurement position above the movable support table 26 to the interference avoidance position above the fixed support table 25 in the support table 10H. For example, the length measuring device 65 may be moved up and down on the movable support table 26 to avoid interference with the support sleeve 44 of the rotary table 41.

DESCRIPTION OF SYMBOLS 10 Grinding device 10T Support table 11 Grinding device main body 12 Main frame 13, 14 Rotary grindstone 21 Sub frame (fixed base)
DESCRIPTION OF SYMBOLS 25 Fixed support table 26 Movable support table 29 Support table shaft 31,32 Rotary table shaft 41 Rotary table 44 Support sleeve 45 Work accommodation hole 50 Support table drive source 51 1st rotary table drive source 52 2nd rotary table use Drive source 57 First relay sleeve (first relay rotor)
58 Second relay sleeve (second relay rotor)
65 Length measuring device 68 Lid 70 Work discharge port 80 Support arm (length measuring device support mechanism)
85 Pneumatic actuator (length measuring device movement drive source)
W Work

Claims (7)

A rotary table having a plurality of workpiece receiving holes in the outer edge portion;
A pair of rotating grindstones that rotate in a state of facing a part of the rotary table from above and below, and grind the upper and lower ends of the work in the work receiving hole;
A support table that rotatably supports a rotary table shaft that extends downward from the center of the rotary table, and that supports the workpiece in the workpiece accommodation hole from below at a position that is separated from between the pair of rotary wheels. In a grinding apparatus having
The rotation of the first and second rotary tables is a part of the support table, rotates about a rotation axis substantially parallel to the rotation axis of the rotation table, and at two positions away from the rotation axis. A movable support table that supports each of the table shafts so as to be rotatable, and can arbitrarily change the rotary table sandwiched between the pair of rotary whetstones;
A fixed base that rotatably supports the movable support table;
The fixed support table that constitutes the support table together with the movable support table, is fixed to the fixed base, and surrounds the movable support table;
A first relay rotator disposed on the lower coaxial side of the movable support table and having an upper end connected to the first rotary table shaft so as to be capable of interlocking rotation;
A second relay rotator which is formed in a cylindrical shape and is fitted to the outside of the first relay rotator, and the second rotary table shaft is coupled to the upper end portion so as to be capable of interlocking rotation;
A first rotary table drive source attached to the fixed base and applying rotational power to a lower end of the first relay rotator;
A grinding apparatus comprising: a second rotary table drive source attached to the fixed base and applying rotational power to a lower end portion of the second relay rotary body. The first relay rotating body has a cylindrical shape,
A support table shaft extending downward from the center of the movable support table and inserted inside the first relay rotating body;
The grinding apparatus according to claim 1, further comprising: a support table drive source that is attached to the fixed base and applies rotational power to a lower end portion of the support table shaft. The support table drive source with a speed reducer is disposed coaxially below the support table shaft, and an output portion of the speed reducer is coupled to the support table shaft so as to be integrally rotatable,
The first rotary table drive source with a speed reducer and the second rotary table drive source with a speed reducer are arranged on the side of the support table drive source, and are used for the first rotary table. The output part of the reduction gear of the drive source is connected to the lower end part of the first relay rotating body so as to be able to rotate together, and the output part of the reduction gear of the second rotary table drive source is connected to the second relay. The grinding device according to claim 2, wherein the grinding device is connected to a lower end portion of the rotating body so as to be capable of interlocking rotation.   In the fixed support table, one of the first and second rotary tables has a work piece of the other rotary table in a state where a part of the rotary table is sandwiched between the pair of rotary grindstones. The grinding apparatus according to any one of claims 1 to 3, wherein a work discharge port that can be opened and closed by a lid is provided at a position where the upper part passes through the upper part. Among the first and second rotary tables, a part of the rotary table is sandwiched between the pair of rotary wheels, while the rotary table is provided with rotational power, while being sandwiched between the pair of rotary wheels. First control means for controlling the first and second rotary table drive sources so as not to apply rotational power to the rotary table that is not,
The grinding device according to any one of claims 1 to 4, further comprising a manual operation button for arbitrarily rotating and driving the rotary table not sandwiched between the pair of rotary grindstones. . Of the first and second rotary tables, the rotary table, which is partially sandwiched between the pair of rotary whetstones, is overlapped from above at a position deviated from between the pair of rotary whetstones. A length measuring device for measuring the length of the workpiece,
On the condition that the length of the workpiece of the entire rotary table measured by the length measuring instrument has reached a predetermined reference length, the rotary table is placed outside the pair of rotary grindstones. The grinding device according to any one of claims 1 to 5, further comprising: a second control unit that moves to the center. Of the first and second rotary tables, the rotary table, which is partially sandwiched between the pair of rotary whetstones, is overlapped from above at a position deviated from between the pair of rotary whetstones. A length measuring device for measuring the length of the workpiece,
Length measuring device support mechanism for supporting the length measuring device movably between a measurement position capable of measuring the length of the workpiece and an interference avoidance position for avoiding interference with a portion rotating together with the movable support table. When,
A length detector movement provided in the length detector support mechanism, which operates in synchronization with the rotation and stop of the movable support table, and moves the length detector to the interference avoidance position when the movable support table rotates. The grinding apparatus according to any one of claims 1 to 6, further comprising a drive source.

Images