KR20170040093A - Speed reducer for turn table - Google Patents

Abstract

The present invention relates to a speed reducer (10) for a turntable, including: a base (12); an input shaft (14) rotationally supported on the base such that the input shaft (14) rotates around a shaft by receiving driving power of a motor; a change portion (15) configured to change the direction of a rotary shaft of the input shaft (14) to a different direction; a fixing portion (42) held and supported on the base (12); a reduction portion (16) configured to be rotatable mutually based on the fixing portion (42), and having an output portion (44) configured to rotate at revolutions per minute (RPM) reduced when compared to an RPM of the change portion (15); and a turntable support portion (18) formed to protrude outward in a diametric direction from the outer circumferential surface of the output portion (44). As such, the present invention provides a speed reducer for a turntable enabling an arrangement of a turntable at a lower position.

Description

[0001] SPEED REDUCER FOR TURN TABLE [0002]

The present invention relates to a reducer for a turntable.

As disclosed in Japanese Patent Application Laid-Open Publication No. 2010-159851, a speed reducer configured to rotate the output section with the number of revolutions reduced from the number of revolutions of the motor has been conventionally known. 3, the speed reducer includes an input shaft 101 that rotates under the driving force of a motor, a conversion unit 102 that rotates around an axis in a direction different from the rotation axis of the input shaft 101, And a deceleration section 103 having a crankshaft 104 that rotates in conjunction with the rotation of the crankshaft 102. The deceleration section 103 includes a crankshaft 104, a case 106 fixed to the pedestal 105, a carrier 107, and a bearing 108 provided between the case 106 and the carrier 107 I have. The carrier 107 rotates as the crankshaft 104 rotates.

Since the upper surface of the carrier 107 of the speed reducer disclosed in Japanese Patent Laid-Open Publication No. 2010-159851 is exposed, the operator can mount the member on this upper surface. For example, when the operator mounts the turntable on the carrier 107, the speed reducer may function as a speed reducer for the turntable. However, since the turntable is mounted on the upper surface of the carrier 107 of the speed reducer, there is a problem that the position of the turntable is increased.

It is an object of the present invention to provide a reducer for a turntable capable of disposing a turntable at a low position.

A decelerator for a turntable according to one aspect of the present invention includes a base portion, an input shaft rotatably supported by the base portion to rotate around the shaft under a driving force of the motor, a conversion portion for converting the rotation axis direction of the input shaft in a different direction, A reduction portion having an output portion rotatable relative to the fixed portion and rotated at a rotation speed reduced from the rotation number of the conversion portion; And a turntable support portion formed to protrude outward.

The present invention makes it possible to dispose the turntable at a low position.

The objects, features, and advantages of the above-described reducer for a turntable will become more apparent from the following detailed description and accompanying drawings.

1 is a schematic sectional view of an exemplary turntable speed reducer;
Fig. 2 is a cross-sectional view taken along the line II-II in Fig. 1; Fig.
3 is a schematic sectional view of a conventional speed reducer;

Hereinafter, an exemplary decelerator for a turntable will be described with reference to the drawings.

1, a decelerator for a turntable (hereinafter referred to as a decelerator 10) is used in a rotating device 1 for rotating a turntable TT. The rotating apparatus 1 includes a motor 5 as a driving source in addition to the speed reducer 10. [ The speed reducer 10 is mounted on the mounting surface FP (reduction gear mounting surface), and then fixed to the mounting surface FP by a fastening member (not shown).

The speed reducer 10 includes a base portion 12, an input shaft 14 rotatably supported by the base portion 12, a conversion portion 15 interlocked with the input shaft 14, A decelerating portion 16 and a turntable support portion 18 for supporting the turntable TT.

The base 12 has a ceiling surface portion 20 and side walls 22 extending in a direction orthogonal to the ceiling surface portion 20 from the outer periphery of the ceiling surface portion 20. A space (inner space) IS defined by the ceiling surface portion 20 and the side wall 22 is formed on the inner side of the base portion 12. The ceiling surface portion 20 may be formed in a substantially circular shape or in a polygonal shape.

The end face of the side wall 22 (the end face on the opposite side of the ceiling face portion 20) is a base end face 22a opposed to the mounting face FP. The reducer 10 is mounted on the mounting surface FP such that the base end surface 22a contacts the mounting surface FP.

An opening (first opening) 22b is formed in the side wall 22 so as to communicate the inner space IS and the outside of the base portion 12.

The side wall 22 is formed with an opening (third opening) 22c through which the input shaft 14 is inserted. A bearing 24 is mounted on the periphery of the third opening 22c of the side wall 22. [ The input shaft 14 is rotatably supported on the side wall 22 of the base 12 through a bearing 24.

The third opening 22c shown in Fig. 1 is formed at a position (a 180-degree position) opposite to the first opening 22b of the side wall 22. However, the third opening 22c may be formed at another position (for example, a position at 90 degrees with respect to the first opening 22b). The principle of the present embodiment is not limited to the specific formation position of the third opening 22c.

A press-in hole 14a into which the drive shaft 5a of the motor 5 is inserted is formed on the outer end surface of the input shaft 14. [ The motor 5 is fixed to the motor support member 26 mounted on the base 12. The drive shaft 5a of the motor 5 is inserted into the press-fit hole 14a of the input shaft 14 in a posture extending in the horizontal direction (direction parallel to the ceiling surface portion 20). The motor 5 is accommodated below the ceiling surface (outer surface) of the ceiling surface portion 20 (on the mounting surface FP side). A drive side gear 14b is provided at the tip of the input shaft 14.

The ceiling surface portion 20 includes a main body portion 28 formed in a plate shape, a first convex portion 29 formed to protrude from the outer surface of the main body portion 28, And convex portions 30 are provided.

The first convex portion 29 is provided on the outer peripheral portion of the main body portion 28. The first convex portion 29 is formed in an annular shape. The first convex portion 29 is used for positioning the fixing portion 42 (described later).

The second convex portion 30 is provided at the periphery of the second opening 28a (described later). The second convex portion 30 is used for positioning the cylinder 64 (to be described later). The second convex portion 30 may be formed in a ring shape concentric with the first convex portion 29.

Two openings 28a and 28b are formed in the main body portion 28 of the ceiling surface portion 20 so as to communicate the inner space IS with the outside of the base portion 12 on the side of the reduction portion 16 have. The opening (second opening) 28a is formed in a shape that is concentric with the cylindrical body 64 (described later). The opening (fourth opening) 28b is formed at a position concentric with the crankshaft 52 (described later). As will be described later, a plurality of crankshafts 52 are provided in the speed reducer 10. Therefore, a plurality of fourth openings 28b are formed in the body portion 28. [

The base portion 12 is provided with a bottom portion 34 extending from the proximal end portion of the side wall 22 (the end on the proximal end face 22a side) to the inside of the base portion 12, 20 are connected to each other. The bottom portion (34) is formed thicker than the ceiling surface portion (20). The bottom portion (34) is formed substantially parallel to the ceiling surface portion (20).

The bottom portion 34 is formed with a support hole 34a having a circular section and a bottom at a position facing the fourth opening 28b. A bearing 38 is attached to the support hole 34a. The conversion shaft 15c (described later) supported by the bearing 38 is concentric with the shaft main body 52a of the crank shaft 52 (described later).

The bottom portion 34 has a bottom main body 34b formed integrally with the side wall 22 and a cap portion 34c assembled to the bottom main body 34b separately from the bottom main body 34b. A through hole is formed in the bottom main body 34b so as to pass through the bottom main body 34b in a direction parallel to the side wall 22. [ The stopper portion 34c closes the end portion (lower end portion in Fig. 1) of the through hole on the mounting surface FP side. Thereby, the support hole 34a having the bottom is formed. As a result, exposure of the first space IS1 to the outside of the base 12 is prevented. The bearing 38 is mounted on the inner peripheral surface of the through hole. The bottom portion 34 is formed only in a portion facing the first space IS1 described later. The second space IS2 (described later) is opened toward the lower side (the side opposite to the ceiling surface portion 20) in Fig.

The partition wall portion 36 is formed by dividing the inner space IS into a space IS1 in which the input shaft 14 is disposed and a space IS1 in which the first opening 22b and the second opening 28a are opened (Second space) IS2. The first space IS1 is communicated with the deceleration portion 16 through the fourth opening 28b. The second space IS2 is communicated with the cylinder 64 via the second opening 28a and does not communicate with the deceleration portion 16 so that the lubricating oil in the deceleration portion 16 is communicated with the second space IS2, .

The conversion section 15 includes a driven gear 15b engaged with the drive side gear 14b provided on the input shaft 14 and a conversion shaft 15c supporting the driven side gear 15b. The converting unit 15 converts the transmitting direction of the driving force along the extending direction of the input shaft 14 into the direction along the extending direction of the converting shaft 15c. The drive side gear 14b and the driven side gear 15b are made of bevel gears. The drive side gear 14b and the driven side gear 15b are not limited to bevel gears. The drive side gear 14b and the driven side gear 15b are connected from the drive side gear 14b to the driven side gear 15b under the positional relationship where the rotation axis of the input shaft 14 and the rotation axis of the conversion shaft 15c intersect It may be a gear part capable of transmitting driving force.

The conversion shaft 15c is concentric with the rotation axis of the driven gear 15b. The conversion shaft 15c is formed of a shaft member extending in a linear shape. The conversion shaft 15c is supported by the bearing 38 of the support hole 34a in such a posture that the rotation axis of the conversion shaft 15c is orthogonal to the rotation axis of the input shaft 14. [ In other words, the conversion shaft 15c is rotatably supported on the bottom portion 34. [

The rotation axis of the input shaft 14 is parallel to the ceiling surface portion 20. The rotation axis of the conversion shaft 15c is orthogonal to the ceiling surface portion 20. The principle of the present embodiment is not limited to the positional relationship in which the rotation axis of the conversion shaft 15c and the rotation axis of the input shaft 14 are orthogonal to each other. The rotation axis of the input shaft 14 may have a positional relationship other than parallel to the rotation axis of the conversion shaft 15c.

The driven gear 15b includes a disc-shaped portion protruding in the radial direction from the outer circumferential surface of the conversion shaft 15c and a tooth formed at the outer end of the disc-shaped portion. The outer end of the disk-like portion is contained in the recess 36a formed in the partition wall portion 36. [ Thereby, the conversion shaft 15c is disposed in the vicinity of the partition wall portion 36. [ The designer can design the lateral width of the base 12 to a small dimension.

The deceleration portion 16 includes a fixed portion 42 fixed to the base portion 12, an output portion 44 rotatable relative to the fixed portion 42, a fixed portion 42 and an output portion 44, A second main bearing 48 and a transmission part for transmitting the driving force for rotating the output part 44 from the converting part 15 to the output part 44 50). The transmission portion 50 has a crankshaft 52 driven by a conversion shaft 15c and a swinging gear 54 swinging in conjunction with the rotation of the crankshaft 52. [ The center of the swing gear 54 rotates around the rotation center axis of the turntable TT while the swing gear 54 swings.

The output section 44 is circular. The output section 44 has an inner peripheral surface 44a, an outer peripheral surface 44b, a first end surface 44c, and a second end surface 44d. A fixing portion 42 is disposed inside the output portion 44 in the radial direction. The first main bearing 46 and the second main bearing 48 are disposed between the inner circumferential surface 44a of the output section 44 and the outer circumferential surface of the fixing section 42. [ The first main bearing 46 and the second main bearing 48 are axially spaced from each other. The main bearings 46 and 48 are constituted by a ball bearing. Alternately, other bearing parts may be used as the main bearings 46, 48.

On the inner circumferential surface 44a of the output section 44, a plurality of pin grooves are formed at equal intervals in the circumferential direction. These pin grooves are located between the first main bearing 46 and the second main bearing 48. Each of the pin grooves is provided with an internal tooth pin 44e. As the internal tooth pin 44e, a cylindrical member is used. The inner tooth pin 44e is parallel to the extending direction of the rotation axis of the output section 44. [ That is, the output section 44 is an annular member having an internal value.

The first end face 44c is opposed to the ceiling face portion 20 of the base 12. The first end face 44c is the base end face of the output section 44. [ The second end surface 44d is formed on the opposite side of the first end surface 44c in the axial direction. The second end face 44d is the front end face of the output section 44. [ A slight clearance is formed between the first end face 44c and the ceiling surface portion 20. [

The fixing portion 42 is mounted on the ceiling surface portion 20 so as to be in contact with the outer surface of the ceiling surface portion 20. The fixing portion 42 is fixed to the ceiling surface portion 20 (base portion 12) by a fastener (member) (for example, bolt)

The fixing portion 42 is provided with a first member 60 and a second member 61 and a fastening member (for example, a bolt) for fastening the first member 60 and the second member 61 to each other 62. The first member 60 has a substantially disk-like base portion 60a and a shaft portion 60b integrally formed with the base portion 60a. The second member 61 has a disc shape. The second member 61 has substantially the same size as the base portion 60a in the radial direction.

One surface of the substrate portion 60a is arranged to face the main body portion 28 of the ceiling surface portion 20. [ The substrate portion 60a is inserted into the inside of the first convex portion 29 of the ceiling surface portion 20. As a result, the base portion 60a is positioned with respect to the base portion 12 (ceiling surface portion 20).

The shaft portion 60b extends from the other surface of the base portion 60a (the surface opposite to the surface contacting the base portion 12) toward the second member 61. [ The surface of the second member 61 (the surface on the substrate portion 60a side) is in contact with the tip end surface of the shaft portion 60b. The shaft portion 60b and the second member 61 are fixed to each other by a fastening member 62. [

As shown in Fig. 2, the plurality of shaft portions 60b (three in this embodiment) are spaced from each other in the circumferential direction at positions displaced from the center in the radial direction of the base portion 60a Is installed.

The fixing portion 42 is provided with a central through hole 42a formed at the center in the radial direction and a crank shaft mounting portion 42b formed at a position displaced from the center in the radial direction. The central through hole 42a penetrates the base plate portion 60a and the second member 61 (the fixing portion 42).

A cylindrical body 64 is inserted into the central through hole 42a. That is, the tubular body 64 passes through the deceleration section 16 in the direction of extension of the rotation axis of the output section 44. One end of the cylindrical body 64 is inserted into the second convex portion 30 so as to be in contact with the inner circumferential surface of the second convex portion 30 of the ceiling surface portion 20. The other end of the cylindrical body 64 protrudes from the second member 61. The inner space IS of the cylinder 64 communicates with the second space IS2 in the base 12 through the second opening 28a of the ceiling surface portion 20. [

The crankshaft mounting portion 42b is a portion for mounting the crankshaft 52. The crankshaft mounting portion 42b is a through hole penetrating the base portion 60a and the second member 61 in a direction parallel to the central through hole 42a. A crank bearing 66 is disposed on the crankshaft mounting portion 42b. The crankshaft 52 is rotatably supported by the fixed portion 42 via a crank bearing 66. [

The crankshaft 52 has a shaft main body 52a extending straight and an eccentric portion 52b eccentric to the shaft main body 52a. A crank bearing 66 is mounted on the shaft main body 52a. The crankshaft 52 has a plurality of eccentric portions 52b (FIG. 1 shows two eccentric portions 52b). The eccentric portions 52b are provided by the number corresponding to the number of the swinging gears 54 (described later).

The shaft main body 52a of the crankshaft 52 is fixed to the conversion shaft 15c in a state of being arranged concentrically with the conversion shaft 15c. As a result, the crankshaft 52 is rotated by the rotation of the conversion shaft 15c.

As shown in Fig. 1, a gap is formed between the second member 61 and the base portion 60a. And a rocking gear 54 is disposed in the gap. The rocking gear 54 is mounted on the eccentric portion 52b with the roller bearing interposed therebetween. The rocking gear 54 is composed of external gears having external teeth. The oscillating gear 54 is engaged with the internal tooth pin 44e of the output portion 44. [ The number of external teeth of the oscillating gear 54 is slightly smaller than the number of the internal tooth pins 44e. In the present embodiment, a plurality of rocking gears 54 (two rocking gears 54 are shown in FIG. 1) are provided in the transmitting portion 50. But. The number of the oscillating gears 54 may be one, or three or more.

The rocking gear 54 is provided with a central through hole 54a formed at the center portion thereof, a first insertion through hole 54b through which the crank shaft 52 is inserted and a second insertion hole 54b through which the shaft portion 60b is inserted A hole 54c is formed. The first insertion through hole 54b and the second insertion through hole 54c are arranged alternately around the central through hole 54a.

The turntable support portion 18 is integrally formed on the outer peripheral surface 44b of the output portion 44. [ The turntable support portion 18 is formed in a flange shape protruding outward in the radial direction from the outer peripheral surface 44b. That is, the turntable support portion 18 is in the form of a flat plate extending in the direction perpendicular to the rotation axis of the output portion 44.

The turntable support portion 18 is formed on the outer peripheral surface 44b of the output portion 44 at a position near the first end surface 44c. That is, the outer peripheral surface 44b of the output section 44 includes a portion near the first end surface 44c of the turntable support portion 18 and a portion near the second end surface 44d of the turntable support portion 18 . The axial length of the portion of the outer peripheral surface 44b near the first end surface 44c is shorter than the axial length of the portion of the outer peripheral surface 44b near the second end surface 44d. The upper surface 18a of the turntable support 18 is positioned between the first end surface 44c and the second end surface 44d at a position closer to the first end surface 44c than the second end surface 44d As shown in Fig. Thus, the turntable TT supported by the turntable support portion 18 is disposed at a low position.

The upper surface 18a of the turntable support portion 18 is located between the first main bearing 46 and the second main bearing 48 in the direction of extension of the rotation axis of the output portion 44. [ The extension line TL of the turntable TT supported by the turntable support portion 18 passes between the first main bearing 46 and the second main bearing 48. [ The extension line TL of the turntable TT is also overlapped with the swing gear 54.

The turntable support portion 18 is formed with a fixing hole for fixing a fastening bolt 68 for fixing the turntable TT. The fixing hole is a screw hole.

The reducer (10) is provided with a resin cover (70) which covers the deceleration section (16). The cover 70 includes a disk-shaped flat plate portion 70a, a first projection portion 70b protruding from the outer peripheral portion of the flat plate portion 70a in the direction of extension of the rotation axis of the output portion 44, And a second protrusion 70c protruding from the periphery of the inner hole formed at the center of the flat plate portion 70a in the direction opposite to the first protrusion 70b. The first projecting portion 70b is fixed to the second end surface 44d of the output portion 44. [

The end of the cylindrical body 64 is inserted into the inside of the cover 70. The end of the cylindrical body 64 is exposed to the upper side of the cover 70 through the hollow. A sealing member is disposed between the inner peripheral surface of the second projection 70c and the outer peripheral surface of the cylinder 64. [ A sealing member is also disposed between the output section 44 and the base section 60a. Therefore, the lubricating oil in the deceleration portion 16 is prevented from leaking to the outside.

The input shaft 14 is disposed on the base end surface 22a side of the base 12 with respect to the turntable support portion 18. [ The input shaft 14 is disposed between the base end surface 22a of the base portion 12 and the turntable support portion 18. The rotation axis of the input shaft 14 is orthogonal to the rotation axis of the output section 44. The rotation axis of the input shaft 14 is parallel to the turntable support portion 18. [

The input shaft 14 is disposed at a position closer to the base end face 22a of the base portion 12 than the end face (upper end face) of the output portion 44. [ The distance D1 between the rotation axis of the input shaft 14 and the base end face 22a is smaller than the distance D2 between the rotation axis of the input shaft 14 and the front end face of the output portion 44. [

The input shaft 14 is disposed so that the distance D3 between the rotation axis of the input shaft 14 and the lower surface of the turntable support portion 18 is smaller than the distance D1 between the rotation axis of the input shaft 14 and the base end face 22a.

The motor 5 has a dimension that is received below the lower surface 18b of the turntable support portion 18. [ That is, the motor 5 is accommodated below the plane including the lower surface 18b of the turntable support portion 18. [ Therefore, the flattened turntable TT does not interfere with the motor 5.

The decelerator 10 according to the present embodiment is fixed to a flat mounting surface FP. In this state, the turntable TT is loaded on the upper surface 18a of the turntable support portion 18. [ The turntable TT is fixed to the turntable support portion 18 by a fastening bolt 68. [

With respect to the rotating apparatus 1 having the speed reducer 10, when the motor 5 is driven, the input shaft 14 of the speed reducer 10 rotates. As a result, the driven gear 15b engaged with the drive side gear 14b provided on the input shaft 14 is driven and the conversion shaft 15c of the conversion portion 15 is rotated around the axis. When the crankshaft 52 coupled to the conversion shaft 15c rotates, the rocking gear 54 revolves while changing the engaging position with the rotation of the eccentric portion 52b. At this time, the swing gear 54 rotates slowly. The output portion 44 rotates relative to the fixed portion 42 in accordance with the swinging of the oscillating gear 54. Thereby, the turntable TT rotates.

As described above, the turntable support portion 18 is formed on the outer peripheral surface 44b of the output portion 44 of the deceleration portion 16. Therefore, the operator can easily and surely control the turntable TT at a position close to the mounting surface FP on which the base 12 is fixed, as compared with the configuration in which the turntable TT is mounted on the end face (front end face) Can be fixed. That is, the turntable TT is fixed to the turntable support portion 18 in a state where the output portion 44 is inserted into the insertion hole formed in the turntable TT. The end face (front end face) of the output section 44 protrudes from the turntable TT. The turntable TT is located at a position apart from the end face of the output section 44 by an amount corresponding to the amount of protrusion of the end face of the output section 44. [ Therefore, when the turntable speed reducer 10 with the turntable TT mounted on the turntable support portion 18 is mounted on the mounting surface FP, the turntable TT is disposed at a lower position.

The input shaft 14 is disposed at the position between the base end face 22a and the turntable support portion 18 so that the design of the input shaft 14 is facilitated by the configuration in which the input shaft 14 is disposed outside the turntable support portion 18 in the radial direction. The size of the reducer 10 in the radial direction can be reduced.

A space for arranging a member for rotatably supporting the input shaft 14 is ensured between the input shaft 14 and the mounting surface FP while the input shaft 14 is disposed closer to the mounting surface FP do. The distance between the turntable supporter 18 and the mounting surface FP is shortened because the turntable supporter 18 is disposed near the input shaft 14. [ Therefore, the turntable TT is disposed at a low position.

The worker passes the wiring located on the mounting surface FP side with respect to the turntable TT through the first opening 22b and the inner space IS of the base portion 12 and the second opening 28a, (64). Since the cylinder 64 passes through the deceleration portion 16, the operator can draw the wire drawn into the inside of the cylinder 64 from the deceleration portion 16. As a result, the operator can pull the turntable TT on the side opposite to the mounting surface FP.

The extension line TL of the turntable TT passes between the first main bearing 46 and the second main bearing 48. This prevents the load exerted by the turntable support portion 18 from the turntable TT from being applied to the outside of the first and second main bearings 46 and 48 (overhang). As a result, the driving force transmission efficiency between the fixing portion 42 and the output portion 44 is improved. Therefore, the driving force required to rotate the turntable TT is reduced.

Since the rocking gear 54 is located on the extension line TL of the turntable TT, the rocking gear 54 is positioned on the action line of the force from the turntable TT. As a result, the driving force transmission efficiency between the fixing portion 42 and the output portion 44 is improved. Therefore, the driving force required to rotate the turntable TT is reduced.

The present invention is not limited to the above-described embodiments, and various modifications and improvements can be made without departing from the spirit of the present invention. The cylinder 64 is passed through the central portion of the deceleration portion 16 and a plurality of crankshafts 52 are arranged around the cylinder 64. In this embodiment, In general, the deceleration section 16 may be constituted by the eccentrically oscillating type speed reducer 10 of the center crank system. In this case, the cylinder 64 is omitted, and the crankshaft 52 is disposed at the center of the fixed portion 42 in the radial direction. And the swing gear 54 is mounted on the eccentric portion 52b of the crank shaft 52. A plurality of shaft portions (60b) are provided around the crankshaft (52).

In the above-described embodiment, the speed reducer 10 is constituted by an eccentric oscillation type gear device. In general, the conversion section 15 may be connected to a sun gear (not shown) instead of the crankshaft 52. The rotation of the sun gear causes the planetary gear (not shown) to revolve, and the output portion 44 comprising the internal gear is rotated.

The input shaft 14 is disposed between the turntable support portion 18 and the base end face 22a of the side wall 22. In this embodiment, In general, the input shaft 14 may be disposed at a position displaced outward in the radial direction from this position.

The distance D3 between the rotation axis of the input shaft 14 and the lower surface 18b of the turntable support portion 18 is smaller than the distance D1 between the rotation axis of the input shaft 14 and the base end face 22a. In general, the distance D3 may be equal to or greater than the distance D1.

In the embodiment described above, the speed reducer 10 is mounted on a mounting surface FP extending in the horizontal direction. In general, the speed reducer 10 may be fixed to the mounting surface for the speed reducer 10 extending in a direction other than horizontal.

The reducer for a turntable described in connection with the above-described embodiment mainly includes the following features.

The reducer for a turntable according to one aspect of the above-described embodiments includes a base, an input shaft that is rotatably supported by the base to rotate around the shaft under the driving force of the motor, A deceleration section having an output section which is rotatable relative to the fixed section and which is rotated at a rotation speed reduced from the rotation number of the conversion section; And a turntable support portion formed to protrude outward in the radial direction.

According to the above configuration, the turntable support portion is formed on the outer peripheral surface of the output portion of the deceleration portion. Therefore, as compared with the configuration in which the turntable is mounted on the end face (front end face) of the output portion, the operator can fix the turntable at a position close to the mounting surface where the base is fixed. That is, the turntable is fixed to the turntable support portion in a state where the output portion is inserted into the insertion hole formed in the turntable. As a result, the end face (front end face) of the output portion protrudes from the turntable. The turntable is located at a position spaced apart from the end face of the output section by an amount of projection of the end face of the output section. Therefore, when the turntable speed reducer having the turntable mounted on the turntable support portion is loaded on the mounting surface, the turntable is disposed at a lower position.

With respect to the above configuration, the base portion may have a base end face opposed to the mounting face. The input shaft may be disposed at a position between the base end surface and the turntable support portion.

According to the above configuration, the designer can reduce the size in the radial direction of the reducer as compared with the configuration in which the input shaft is arranged radially outward of the turntable support portion.

The input shaft is disposed closer to the base end surface of the base than the output end surface of the output section and the distance between the rotation axis and the turntable support section is longer than the distance between the rotation axis and the base end surface Or may be arranged so as to be smaller.

According to the configuration described above, the input shaft is disposed at a position closer to the mounting surface, and a space is provided between the input shaft and the mounting surface for arranging a member for rotatably supporting the input shaft. When the turntable support portion is disposed at a position close to the input shaft, the distance between the turntable support portion and the mounting surface is shortened. Thus, the turntable is placed at a low position.

With respect to the above-described configuration, the deceleration section may be provided with a cylinder passing through the fixing section. The base portion may be provided with a first opening and a second opening. A space communicating with the outside of the base through the first opening and communicating with the inside of the tubular body through the second opening may be formed in the inside of the base.

According to the configuration described above, the operator can draw the wiring located on the mounting surface side with respect to the turntable into the cylinder through the first opening, the space, and the second opening. Since the cylinder passes through the deceleration section, the operator can draw out the wire drawn into the inside of the cylinder from the deceleration section. As a result, the operator can pull the turntable to the side opposite to the mounting surface.

In the above configuration, a first main bearing and a second main bearing may be disposed between the output portion and the fixed portion. The turntable support portion may be provided so that an extension of the turntable supported by the turntable support portion passes between the first main bearing and the second main bearing.

According to the above configuration, it is possible to prevent the load that the turntable support portion receives from the turntable from being applied to the outside of the first and second main bearings (overhang). As a result, the driving force transmission efficiency between the fixed portion and the output portion is improved. Therefore, the driving force required to rotate the turntable is reduced.

With respect to the above-described configuration, the deceleration section may have a rocking gear. The rocking gear may be located on an extension of a turntable supported by the turntable support.

According to the above configuration, since the rocking gear is positioned on the extension line of the turntable, the rocking gear is located on the line of force. As a result, the driving force transmission efficiency between the fixed portion and the output portion is improved. Therefore, the driving force required to rotate the turntable is reduced.

In the above-described configuration, the turntable speed reducer may include a cover for covering the deceleration section. The cover may be made of resin.

According to the above configuration, the deceleration portion is protected by the cover. Since the cover is made of resin, the reducer for the turntable does not become excessively heavy.

The principles of the above-described embodiments are applicable to the design of various turntables.

Claims (7)

Donations,
An input shaft rotatably supported on the base portion to rotate around an axis in response to a driving force of the motor;
A conversion unit for converting the rotation axis direction of the input shaft into different directions;
A deceleration section having an output section that is rotatable relative to the fixed section and that is rotated at a rotation speed reduced from the rotation number of the conversion section;
And a turntable support portion formed to protrude outward in the radial direction from the outer peripheral surface of the output portion. The method according to claim 1,
Wherein the base portion has a base end face opposed to the reducer mounting face,
And the input shaft is disposed at a position between the base end surface and the turntable support portion. 3. The method of claim 2,
Wherein the input shaft is disposed at a position closer to the base end face of the base than the output end face of the output section and the distance between the rotation axis and the turntable support section is smaller than the distance between the rotation axis and the base end face, Reducer for turntable. 3. The method of claim 2,
Wherein the deceleration portion is provided with a cylinder passing through the fixing portion,
The base has a first opening and a second opening,
And a space communicating with the outside of the base through the first opening and communicating with the inside of the cylinder through the second opening is formed in the base of the base. The method according to claim 1,
A first main bearing and a second main bearing are disposed between the output portion and the fixed portion,
Wherein the turntable support portion is provided so that an extension of a turntable supported by the turntable support portion passes between the first main bearing and the second main bearing. The method according to claim 1,
Wherein the deceleration section has a rocking gear,
Wherein the rocking gear is located on an extension of a turntable supported by the turntable support portion. The method according to claim 1,
And a cover for covering the deceleration portion,
Wherein the cover is made of resin.

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