JP2010031410A - Planetary gear type selvage device in loom - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a planetary gear type selvage device which can simplify works for attaching or detaching a planetary mechanism to or from a support frame to maintain bobbin holders and the like, and can easily perform the works in short times. <P>SOLUTION: Provided is the planetary gear type selvage device having support frames (11, 15) disposed on a beam (17) spun between the frames of a loom in a state capable of adjusting positions in the weaving width, a rotation shaft (2) supported on the support frames (11, 15) to be rotated, a planetary carrier (3) relatively non-rotatably supported on the rotation shaft (2), a solar gear (41) having a penetrated hole for relatively rotatably making the rotation shaft (2) to penetrate and coaxially disposed with the planetary carrier (3) in a state incapable of being rotated on the basis of the support frames (11, 15), and a driving mechanism having a driving transmission member (13) disposed in a state incapable of being relatively rotated on the basis of the rotation shaft (2), characterized in that the driving transmission member (13) and the rotation shaft (2) are combined in a state capable of being separated in the axial direction, and the driving transmission member (13) is supported on the support frames (11, 15) through a bearing (BR). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

The present invention relates to a planetary gear-type ear assembly device in a loom, and in particular, a rotating shaft supported by a support frame of the device and driven to rotate, and a planet carrier supported so as not to rotate relative to the rotating shaft. A planetary carrier that rotatably supports a pair of support shafts in a symmetrical arrangement with respect to the rotation shaft, and a sun gear that has a through hole that penetrates the rotation shaft in a relatively rotatable manner, and is not rotatable relative to the support frame And a planetary gear attached to the other end of each of the pair of support shafts having a bobbin holder fixed to one end thereof, and is in mesh with the sun gear indirectly. A planetary gear type comprising a pair of planetary gears and a drive mechanism for driving the rotary shaft to rotate, the drive mechanism including a drive transmission member provided so as not to rotate relative to the rotary shaft. For the set apparatus. The “indirect meshing” means that the planetary gear and the sun gear are not meshed directly, but the planetary gear is meshed with another gear that meshes with the sun gear. To express.

As a planetary gear type ear assembly device (hereinafter referred to as “planet ear assembly device”) used in a loom, there is one described in Patent Document 1, for example. The planetary ear assembly apparatus described in Patent Document 1 includes a drive shaft (rotary shaft) that is rotatably supported via a bearing with respect to a support base as a support frame, and a shaft portion that is formed integrally with the drive shaft. And a sun gear (sun gear) that is provided so as not to rotate relative to the support base and has a through hole through which a shaft portion of the rotation support passes. Note that the shaft of the rotary support is rotatably supported by a bearing in the through hole of the sun gear. That is, the rotary support and the sun gear are arranged coaxially. In addition, the drive shaft and the shaft portion of the rotation support member that are arranged coaxially (with the shaft centers aligned) are connected by a shaft joint. A driven timing pulley as a driven drive transmission member is attached to the drive shaft at the end opposite to the rotation support side, and the driven timing pulley is connected to the drive motor. And connected via a timing belt.

In the planetary ear assembly apparatus described in Patent Document 1, the driving mechanism including the driven timing pulley, the timing belt, and the driving timing pulley is disposed at the position of the loom frame (side frame) or outside the loom. It has become. Therefore, the length of the drive shaft extending from the driven timing pulley to the shaft portion of the rotating support so that the position of the planetary mechanism including the rotating support and sun gear can be adjusted according to the weaving width. Adopts a configuration that can be changed. However, in such a configuration, since the drive shaft becomes long, various problems occur.

For example, such a long drive shaft is easily bent, and the drive shaft rotates in a bent state when rotating at a high speed. For this reason, the load applied to the connecting portion between the drive shaft and the shaft portion of the rotary support, the bearing supporting the drive shaft, or the drive mechanism is increased, resulting in damage to them. Further, when connecting the drive shaft and the rotation shaft, it is difficult to connect the shafts in a state in which the shaft centers are completely matched, and there is a high possibility that the shaft centers are shifted. Even in this case, a load applied to the connecting portion, the bearing, and the like is increased, and the breakage thereof is caused. Further, since the load applied to the drive mechanism changes as the length of the drive shaft is changed, the tension of the timing belt must be adjusted every time the planetary mechanism is adjusted to the woven width.

Further, a drive shaft is formed by the pipe-shaped first shaft member and the second shaft member slidably inserted into the first shaft member, and the second shaft member is inserted into the first shaft member. Since the length is adjusted by changing the amount, in the position adjustment of the planetary mechanism, the outermost position is regulated by the length of the first shaft member, and the adjustment amount is controlled by the first shaft member. Since the length of the second shaft member that can be inserted is limited, there is a problem that the arrangement and the adjustment amount are limited. In addition, in order to increase the adjustment range, it is necessary to prepare a plurality of shaft members having different lengths, and there is a problem in terms of cost.

From the above, the mechanism for position adjustment in the planetary ear assembly apparatus described in Patent Document 1 is not practical and is hardly employed in practice. In general, a configuration as disclosed in Patent Document 2, that is, a bracket as a support frame is erected on a beam installed between the left and right frames of the loom, and the bracket is woven on the beam. A configuration that allows position adjustment in the width direction is employed.

By the way, in the planetary ear assembly device, in order to perform maintenance of the bobbin holder and the internal gear, it is necessary to remove the planetary mechanism from the support frame (bracket). On the other hand, work to remove the planetary mechanism is performed. However, as described above, a conventional planetary planetary carrier in which the planetary carrier is provided so as not to rotate relative to the rotary shaft (including the drive shaft and the support shaft integrally assembled) that is driven to rotate through the sun gear. In the ear assembly device, a drive transmission member (driven timing pulley or the like in Patent Document 1) is fixed to the end of the rotating shaft, and the driven drive transmitting member is driven only by the rotating shaft. It has a supported configuration.

Therefore, in the conventional planetary ear assembly apparatus as described above, in the attaching / detaching operation of the planetary mechanism accompanying the maintenance, the planetary mechanism must be removed from the support frame while the driven transmission member is attached to the rotating shaft. Don't be. That is, the conventional planetary ear assembly device has a configuration in which the drive transmission member on the driven side must be removed from the drive mechanism in the detachment operation.

However, in such a configuration, not only the drive drive member on the driven side needs to be removed along with the attachment / detachment work of the planetary mechanism, but the drive drive member on the driven side is connected to the drive pulley and the timing, for example. In the case of a driven pulley connected by a belt (driven timing pulley in Patent Document 1), the timing belt wound around the driven pulley must be removed or re-engaged, and the timing belt is hung. After the correction, the work of adjusting the tension of the timing belt must be redone. Also, when the driven transmission member on the driven side is a driven gear that meshes directly or indirectly with the drive gear, the backlash between the meshed gears is adjusted with reconnection after disengagement from the drive gear. You have to start over.

As described above, in the conventional planetary ear assembly apparatus of the above-described type, the work of detaching the planetary mechanism from the support frame for the maintenance becomes complicated, and the burden of time, labor and the like spent on the work is large. It has become.
JP 2002-302840 A JP 2004-190192 A

Accordingly, an object of the present invention is to simplify the operation of attaching and detaching the planetary mechanism to and from the support frame for maintenance of the bobbin holder and the gear in the planetary ear assembly apparatus of the above-described type, and the operation can be performed easily and in a short time. To provide a configuration.

The present invention provides a support frame that is erected on a beam that is installed between frames of a loom, and that is provided on the beam so as to be position-adjustable in the weaving width direction, and is supported by the support frame. A rotating shaft that is driven to rotate, a planet carrier that is supported so as not to rotate relative to the rotating shaft, and a planet carrier that rotatably supports a pair of supporting shafts in a symmetrical arrangement with respect to the rotating shaft; A sun gear having a through-hole that penetrates the rotation shaft in a relatively rotatable manner, the sun gear being arranged coaxially with the planet carrier in a non-rotatable state with respect to the support frame, and the bobbin holder fixed to one end A planetary gear attached to the other end of each of the pair of support shafts, a pair of planetary gears indirectly meshed with the sun gear, and a drive mechanism for rotationally driving the rotary shaft, the rotation It assumes planetary selvage device that includes a drive mechanism including a drive transmission member provided in a relatively non-rotatable manner with respect.

And in the planetary ear assembly apparatus of the present invention, the drive transmission member and the rotary shaft are combined so as to be separable in the axial direction of the rotary shaft, and the drive transmission member has a bearing. It is characterized by being supported by the support frame.

In the present invention, the support frame includes an outer peripheral wall that defines a space for accommodating the drive mechanism and a front side wall that supports the planetary mechanism, and the front side wall supports the planetary mechanism. In the state in which a through hole into which a part of the outer peripheral surface of the planetary mechanism is inserted is formed, and the planetary mechanism is fitted into the through hole at a part of the outer peripheral surface. The rotating shaft is supported in the planetary mechanism such that the rotating shaft of the rotating shaft is located at the same position as seen in the axial direction of the rotating shaft of the driving transmission member in the driving mechanism. It is preferable to do this. Further, in that case, the planetary mechanism has a circular outer peripheral surface as viewed in the axial direction of the rotating shaft and has a circular outer peripheral surface centered on the rotating axis of the rotating shaft, The through hole is preferably a circular through hole into which the circular outer peripheral surface of the planetary mechanism is fitted. In the present invention, it is preferable that the rotating shaft is formed as an integral shaft member.

Further, in the case where the drive transmission member is a driven pulley connected to a drive pulley provided on the drive shaft via a timing belt, at least a part of a bearing for supporting the drive transmission member is provided. It is preferable to arrange so as to overlap with the drive transmission member in the axial direction.

Further, in the present invention, the position of the drive transmission member in the axial direction is fixed by a position restricting member fixed to the rotation shaft by a screw member on the rear end side of the drive transmission member, The support frame may have a through hole for allowing the screw member to be operated from the outside on a wall surface facing a hole into which the screw member of the position regulating member is inserted. In this case, the screw member may be screwed into the rear end surface of the rotating shaft.

According to the present invention, the drive transmission member in the drive mechanism that is provided so as not to rotate relative to the rotation shaft (the drive transmission member on the driven side) is supported by the support frame via the bearing. For this reason, even in the state where the rotating shaft does not exist, the position connected to the drive-side drive transmission member (drive pulley, drive gear, etc.) can be maintained. In addition, the drive transmission member on the driven side is combined with the rotating shaft so as to be separable in the axial direction. Therefore, it is possible to separate the rotation shaft from the driven drive transmission member while maintaining the connection state between the driven drive transmission member and the drive transmission member in the drive mechanism. With this configuration, the planetary mechanism can be detached from the support frame without releasing the connection state between the driven drive transmission member and the drive drive drive member in the attachment / detachment operation of the planetary mechanism for the maintenance. In this detachment operation, the connection and release of the driven drive transmission member with respect to the drive transmission member on the drive side and the adjustment associated therewith are not required, and the detachment operation of the planetary mechanism is simplified. As a result, the desorption operation can be performed easily and in a short time.

Further, the support frame is assumed to have a through-hole for supporting the planetary mechanism formed by inserting a part of the outer peripheral surface of the planetary mechanism, and the planetary mechanism is inserted into the through-hole. A structure in which the rotation shaft is supported so that the rotation axis of the rotation shaft is in the same position as viewed in the axial direction of the rotation shaft of the drive transmission member on the driven mechanism in the drive mechanism in the fitted state. Thus, when the planetary mechanism is remounted on the support frame, the rotational axis of the rotating shaft of the planetary mechanism and the rotational axis of the drive transmission member on the driven side of the driving mechanism can be easily matched, and the misalignment of the axes of both It is possible to prevent the bearing and the drive transmission member from being damaged due to the above.

Further, in the configuration in which the planetary mechanism is supported by the through hole of the support frame as described above, the planetary mechanism is a circular outer peripheral surface when viewed in the axial direction of the rotating shaft and has a center on the rotating axis of the rotating shaft. Even if the angle of the warp line is changed in the loom, the through hole in the support frame is a circular through hole in which the circular outer surface of the planetary mechanism is fitted. This makes it possible to easily adjust the phase of the planetary mechanism.

In addition, since the rotating shaft is formed of an integral shaft member, the rotating shaft is supported on the support frame via the drive transmission member and the bearing on the drive mechanism side in addition to the support in the planetary mechanism. It becomes a supported state. Therefore, the radial support of the rotating shaft becomes stable, and the swinging of the rotating shaft (particularly, displacement at the end) accompanying high-speed rotation can be suppressed.

Further, in the case where the drive transmission member is a driven pulley connected to a drive pulley provided on a drive shaft via a timing belt, at least one bearing for supporting the drive transmission member (driven pulley) is provided. By providing the portion overlapping with the drive transmission member in the axial direction of the rotating shaft, the tension of the timing belt can be received by the support frame via the bearing, and is applied to the bearing and the rotating shaft by the tension of the timing belt. The influence of the load can be reduced.

Further, the position restricting member fixed to the rotating shaft with the screw member is fixed on the rotating shaft of the drive transmission member, and the support frame allows the screw member to be operated from the outside. By having the through hole, the work of separating the rotating shaft and the drive transmission member can be performed more easily.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 and 2 show an embodiment of the present invention. FIG. 1 is a partial cross-sectional side view of a planetary ear assembly device to which the present invention is applied. FIG. It is a back surface sectional view of a planetary mechanism part. The planetary mechanism portion of FIG. 1 is shown as a view of the BB cross section of FIG. 2 as seen in the direction of the arrow, and FIG. 2 is a view of the AA cross section of FIG. 1 in the direction of the arrow. It is shown as a diagram. However, in FIG. 2, only the planetary mechanism portion is shown, and pulleys, which will be described later, which are not originally shown, are indicated by virtual lines for reference.

As described above, the planetary ear assembly device 1 to which the present invention is applied includes a bracket 11 as a support frame erected on a beam 17 mounted between left and right frames (not shown) of a loom, And a planetary mechanism 10 supported by the bracket 11. The planetary mechanism 10 includes a rotating shaft 2, a planet carrier 3, a sun gear forming member 4 including a sun gear 41, a pair of planetary gears 5, 5, a pair of relay gears 6 and 6, and a pair of bobbin holders BH. The bobbin holder BH is a known one disclosed in, for example, Japanese Patent Application Laid-Open No. 9-137334. Therefore, below, the description regarding a bobbin holder is abbreviate | omitted. In the following description, the front (front side) refers to the bobbin holder BH side (right side of the drawing in FIG. 1) in the axial direction of the rotary shaft 2, and the rear (rear side) refers to the side opposite to the bobbin holder BH (FIG. 1). Left side of the drawing). Further, the axial direction refers to a direction (regardless of the direction) parallel to the central axis (rotational axis) of the rotary shaft 2, and the radial direction refers to a direction orthogonal to the axial direction.

The rotating shaft 2 is a shaft that is rotationally driven by a drive mechanism that will be described later. The rotating shaft 2 passes through a through hole 44 formed in the sun gear forming member 4 and is located in the through hole 44 with respect to the sun gear forming member 4 via a bearing. It is supported rotatably.

The sun gear forming member 4 is a portion located on the front side and is a gear portion having gear teeth formed on the outer peripheral portion, a shaft portion 42 extending rearward from the sun gear 41, and a radius from the shaft portion 42. And a flange portion 43 formed so as to expand radially in the direction. The flange portion 43 has a circular disk shape with its outer peripheral surface viewed in the axial direction, and is formed such that the center of the outer peripheral circle is located on the central axis of the through hole 44. . The through hole 44 is formed through the shaft portion 42 and the sun gear 41.

A cylindrical gear cover 7 is attached to the sun gear forming member 4. The gear cover 7 is provided so as to surround the sun gear 41, the planetary gears 5, 5 and the relay gears 6, 6 and the planet carrier 3. The gear cover 7 has a through hole 74 into which the shaft portion 42 of the sun gear forming member 4 is inserted. The through hole 74 and the shaft portion 42 of the sun gear forming member 4 are fitted together, and a flange is formed. While being in contact with the front surface of the portion 43, it is integrally fixed to the sun gear forming member 4 by a screw member 45 screwed through the flange portion 43.

The sun gear forming member 4 and the gear cover 7 integrated as described above are supported by a bracket 11. The bracket 11 has a box shape so as to accommodate a drive mechanism described later, and is configured in such a manner that the front surface of the region surrounded by the outer peripheral wall 11d is closed by the front side wall 11a. Further, a through hole 11 b into which the flange portion 43 of the sun gear forming member 4 is fitted is formed in the front side wall 11 a of the bracket 11.

Further, the bracket 11 has a base portion 11c formed integrally with the outer peripheral wall 11d and the front side wall 11a, and on the slide rail 18 provided on the upper surface of the beam 17 installed between the frames of the loom (not shown). It is erected with the base 11c placed thereon. And the fixed pieces 19 and 19 are attached to the both sides | surfaces extended in the axial direction of the base 11c with the screw member, The position on the slide base 18 of the bracket 11 is fixed by these fixed pieces 19 and 19. It becomes the composition which is done. In other words, the bracket 11 can be moved on the slide base 18 by loosening the screw member that attaches the fixing pieces 19, 19 to the base portion 11c, and the weaving width direction of the planetary ear assembly device 1 (the extending direction of the beam 17). ) Position can be adjusted.

In the sun gear forming member 4 and the gear cover 7, the flange portion 43 of the sun gear forming member 4 is fitted into a through hole 11 b formed in the front side wall 11 a of the bracket 11, and the rear surface around the through hole 74 of the gear cover 7 is a bracket. 11 is fixed to the bracket 11 by a plurality of screw members (not shown) screwed through the front side wall 11a of the bracket 11 while being positioned in contact with the front surface around the through hole 11. Therefore, the sun gear forming member 4 (sun gear 41) and the gear cover 7 are provided in the planetary ear assembly device 1 in a non-rotatable state. Further, the rotating shaft 2 supported by the sun gear forming member 4 via a bearing is in a state of being rotatably supported by the bracket 11 via the sun gear forming member 4.

In the illustrated example, the planet carrier 3 has a disk shape with a rim formed on the outer periphery, and a through hole 31 into which the rotary shaft 2 is inserted is formed at the center. Further, in the planetary carrier 3, the part where the through hole 31 is formed (the part where the rotating shaft 2 is fitted) and the part where the support shaft that supports the planetary gear 5, which will be described later, is supported are compared to the other parts. It is formed as a thick boss. The through hole 31 into which the rotary shaft 2 is inserted is formed with a key groove 34 into which the key 23 attached to the rotary shaft 2 is fitted. Therefore, the planet carrier 3 is not rotatable relative to the rotating shaft 2 and is supported so as to be rotatable together with the rotating shaft 2 with respect to the sun gear forming member 4. That is, in the planetary ear assembly device 1, the planet carrier 3 is provided so as to be rotatable around the axis of the rotation axis (center axis) 2.

The planet carrier 3 supports two pairs of support shafts 51, 51 and 61, 61, each of which is a pair and is disposed at a symmetrical position with respect to the axis of the rotation shaft.

Each of the pair of support shafts 51, 51 has a bobbin holder BH attached to one end thereof, penetrates a through hole 32 formed in the planet carrier 3, and supports the planetary gear 5 on the other end side. Each support shaft 51 supports the bobbin holder BH and the planetary gear 5 so as not to rotate relative to each other, and is supported rotatably with respect to the planetary carrier 3 via a bearing provided in the through hole 32. Therefore, each bobbin holder BH and each planetary gear 5 are rotatably supported with respect to the planet carrier 3 via the support shaft 51.

The planetary gears 5 and 5 are arranged at positions where they are not engaged with the sun gear 41 of the sun gear forming member 4 while being supported by the support shaft 51. In other words, the arrangement of the support shaft 51 on the planet carrier 3 is such that the distance between the axes of the rotation shaft 2 and the axis of the sun gear 41 and the planet gear 5 is larger than the combined dimension. Set to position.

Further, the pair of support shafts 61 and 61 are for supporting the relay gear 6. Each support shaft 61 is supported by being inserted into a through-hole 33 formed in the planetary carrier 3 at a position where the relay gear 6 supported thereby engages with both the sun gear 41 and the planetary gear 5. ing. Each support shaft 61 is supported so as not to rotate with respect to the planet carrier 3, and the relay gear 6 is supported rotatably with respect to the support shaft 61 via a bearing. Accordingly, the relay gear 6 is supported by the planet carrier 3 via the support shaft 61 in a state of being rotatable with respect to the planet carrier 3.

In the planetary mechanism 10 configured as described above, the planetary carrier 3 is driven to rotate about the axis of the rotary shaft 2, so that a pair of the planetary carrier 3 supported by the planetary carrier 3 at a position eccentric from the axis of the rotary shaft 2. The planetary gears 5 and 5 and the pair of relay gears 6 and 6 revolve around the axis of the rotary shaft 2. At that time, each relay gear 6 performs the revolution while meshing with the sun gear 41, and therefore rotates around the axis of the support shaft 61 along with the revolution. As a result, the planetary gear 5 that meshes with the relay gear 6 also rotates (rotates) around the axis of the support shaft 51 as the relay gear 6 rotates. As a result, the bobbin holder BH attached to the support shaft 51 that supports the planetary gear 5 in a relatively non-rotatable manner rotates while revolving around the axis of the rotary shaft 2 as the rotary shaft 2 (planet carrier 3) rotates. Perform planetary motion.

Regarding the drive mechanism of the rotary shaft 2 for causing the bobbin holder BH to perform a planetary motion, in the illustrated example, rotation of the drive shaft 12 that rotates using a main shaft (primary motor) of a loom (not shown) as a drive source is applied to the rotary shaft 2. A transmission mechanism is adopted. Specifically, a driven pulley 13 as a drive transmission member referred to in the present invention is assembled to the rotating shaft 2 at the rear end thereof. The rotary shaft 2 and the driven pulley 13 are combined together by a key 24 so that they cannot be rotated relative to each other in a state where the rotary shaft 2 is fitted in a through hole formed in the base portion 13 b of the driven pulley 13. The driven pulley 13 is connected to a driving pulley 14 provided on the driving shaft 12 by a timing belt 16. Thereby, the rotation of the drive shaft 12 is transmitted to the rotation shaft 2 via the drive pulley 14, the timing belt 16, and the driven pulley 13, and the rotation shaft 2 is driven to rotate, so that the planet carrier 3 rotates.

More specifically, the rotary shaft 2 has a small diameter portion 21 having a small diameter at a portion to be inserted into the driven pulley 13, and a step portion 22 is formed by expanding the front side thereof. Accordingly, the driven pulley 13 fitted from the rear end side of the rotating shaft 2 is positioned by contacting the stepped portion 22 of the rotating shaft 2. A washer 25 serving as a position restricting member having a diameter larger than that of the rotating shaft 2 is attached to the rotating shaft 2 by a screw member 26 screwed into the rear end surface of the rotating shaft 2. However, the small-diameter portion 21 of the rotating shaft 2 has a length dimension smaller than the axial dimension of the base portion 13b of the driven pulley 13, so that the washer 25 is in contact with the rear end surface of the base portion 13b of the driven pulley 13. There is a slight gap between the rotating shaft 2 and the washer 25. Then, the screw member 26 is tightened against the rear end surface of the rotating shaft 2, and the driven pulley 13 is sandwiched between the step portion 22 and the washer 25 of the rotating shaft 2, and the axial direction with respect to the rotating shaft 2. The position of is fixed. Further, the phase of the driven pulley 13 with respect to the rotating shaft 2 is fixed by the key 24.

Incidentally, in the illustrated drive mechanism, the drive shaft 12 passes through the bracket 11 via a bearing bush, and the drive pulley 14 can be fixed at an arbitrary position in the axial direction of the drive shaft 12 by a cleaving structure. It is attached to the drive shaft 12 via a pulley support member 14a, and is provided in a state in which the center of rotation coincides with the axis of the drive shaft 12.

In the illustrated drive mechanism, the driven pulley 13 as the drive transmission member is supported by the bracket 11 as the support frame via the bearing BR in the range where the driven pulley 13 is present in the axial direction.

Specifically, the driven pulley 13 is formed with a ring-shaped groove 13a that opens to the rear side between a base portion 13b fitted to the rotary shaft 2 and an outer peripheral portion 13c around which the timing belt 16 is wound. On the other hand, a bearing case 15 in which a cylindrical portion 15 a extending to the front side (pulley side) is formed is attached to the rear end surface of the bracket 11, and the cylindrical portion 15 a is a state in which the bearing case 15 is assembled to the bracket 11. In FIG. 5, the groove 13a of the driven pulley 13 is invaded. A bearing is interposed between the inner peripheral surface of the cylindrical portion 15 a of the bearing case 15 and the outer peripheral surface of the base portion 13 b of the driven pulley 13.

With this configuration, the driven pulley 13 is rotatably supported with respect to the bracket 11 via the bearing case 15 and the bearing. That is, in the illustrated configuration, the driven drive transmission member (driven pulley 13) in the drive mechanism is not supported only by the rotary shaft 2 as in the prior art, but is also supported by the support frame (bracket 11). Has been. In other words, the driven pulley 13 is configured to be able to maintain a connected state with the drive pulley 14 in the drive mechanism even when the rotary shaft 2 is not present.

In the configuration shown in the figure, the bearing case 15 is assembled to the bracket 11 so that the central axis of the cylindrical portion 15a is positioned on the extension line of the central axis of the through hole 11b formed in the front side wall 11a of the bracket 11. ing. Accordingly, when the bearing case 15 is also considered as a part of the support frame, the support frame constituted by the bracket 11 and the bearing case 15 includes the inner peripheral surface of the through hole 11a having the center on the same straight line and the cylindrical portion 15a. An inner peripheral surface is formed.

According to the configuration of the planetary ear assembly apparatus 1 as described above, when it becomes necessary to remove the planetary mechanism 10 from the planetary ear assembly apparatus 1 (bracket 11) for maintenance of the bobbin holder BH, the internal gear mechanism, and the like. Then, the screw member 26 and the washer 25 are removed, and the fixed position of the driven pulley 13 with respect to the rotating shaft 2 is released. As a result, the rotary shaft 2 becomes displaceable in the axial direction with respect to the driven pulley 13 supported by the bracket 11. Therefore, by removing the screw member that fixes the gear cover 7 to the bracket 11, the planetary mechanism 10 including the planetary carrier 3, the sun gear forming member 4, and the rotating shaft 2 can be separated from the bracket 11, and the planetary mechanism. Can be removed from the bracket 11.

In addition, with the above configuration, even if the planetary mechanism 10 is removed from the bracket 11, the driven pulley 13 can remain in the drive mechanism in the bracket 11. In other words, the planetary mechanism 10 can be detached from the bracket 11 while maintaining the connected state between the driven pulley 13 and the driving pulley 14. Accordingly, when the planetary mechanism 10 is removed for maintenance or the like, it is not necessary to remove the driven drive transmission member from the drive mechanism. Therefore, the driven drive transmission member and the drive side drive when the planetary mechanism 10 is attached or detached are removed. The connection release and reconnection work with the transmission member and the adjustment work can be omitted, and the attaching / detaching work of the planetary mechanism 10 is simplified.

Further, in the illustrated configuration, when the planetary mechanism 10 is mounted on the bracket 11, the flange portion 43 of the sun gear forming member 4 that forms a part of the outer peripheral surface of the planetary mechanism 10 is formed on the front side wall of the bracket 11. Thus, the shaft center of the rotating shaft 2 in the planetary mechanism 10 and the shaft center of the driven pulley 13 on the drive mechanism side can be easily aligned with each other. Can be prevented from being combined in a state in which the shaft centers of the two are shifted.

Specifically, as described above, the support frame including the bearing case 15 and the bracket 11 is formed with the inner peripheral surface of the through hole 11b and the inner peripheral surface of the cylindrical portion 15a having the center on the same straight line. The driven pulley 13 is coaxially supported via a bearing on the inner peripheral surface of the cylindrical portion 15a. Therefore, the driven pulley 13 is arranged coaxially with the inner peripheral surface of the through hole 11b. On the other hand, in the planetary mechanism 10, the flange portion 43 of the sun gear forming member 4 is formed such that the center of the outer peripheral surface is located on the central axis of the through hole 44, and the rotary shaft 2 is formed in the through hole 44. It is supported by a bearing inside and is supported in a state where the axis is aligned with the central axis of the through hole 44. Therefore, the rotating shaft 2 is arranged coaxially with respect to the outer peripheral surface of the flange portion 43 with respect to the sun gear forming member 4 in the planetary mechanism 10.

With these configurations, the rotating shaft 2 coaxially arranged with respect to the outer peripheral surface of the flange portion 43 and the driven pulley 13 positioned coaxially with respect to the inner peripheral surface of the through hole 11b are connected to the through hole 11b of the bracket 11. In a state where the flange portion 43 of the sun gear forming member 4 is fitted together, the shaft centers coincide with each other. In this manner, the driven pulley 13 is provided in a state where the shaft center coincides with the through hole 11b that supports the planetary mechanism 10 in the support frame, and the outer peripheral surface (flange portion 43) that is inserted into the through hole 11b in the planetary mechanism 10. In order to attach the planetary mechanism 10 to the support frame (bracket 11), the flange portion 43 is inserted into the through hole 11b. By just doing, the axis of rotation axis 2 and driven pulley 13 can be made to correspond.

And according to such a structure, even if it is a case where the backlash exists between the through-hole formed in the base part 13b of the driven pulley 13, and the small diameter part 21 of the rotating shaft 2, the driven pulley 13 and Since both shaft centers of the rotating shaft 2 can be made coincident with each other, the load applied to the bearing and the driven pulley 13 is increased due to the displacement between both shaft centers, and they are damaged. A situation can be prevented from occurring.

In the illustrated configuration, the rotary shaft 2 is formed as a single unitary shaft member. When the planetary mechanism is assembled to the bracket 11, the rotary shaft 2 is a sun gear fixed to the bracket 11. In addition to the forming member 4, not only the position of the driven pulley 13 in the axial direction but also a structure supported by the bracket 11 via a bearing BR or the like. Thereby, the radial support of the rotating shaft 2 becomes stable, and vibration (shaking of the shaft) associated with high-speed rotation of the rotating shaft 2 can be sufficiently suppressed.

Further, in the illustrated configuration, the bearing case 15 is formed with a through-hole having a diameter larger than that of the washer 25 around the central axis of the cylindrical portion 15a. That is, a through hole is formed in the wall surface of the bearing case 15 facing the hole for inserting the screw member 26 in the washer 25. According to this configuration, the screw member 26 for fixing the washer 25 as the position restricting member can be operated from the outside, and the planetary mechanism can be easily attached and detached.

In addition, this invention is not limited to what was demonstrated in the above Example, It can implement also in the aspect changed as follows.

(1) In the embodiment, in the drive mechanism, the mechanism for transmitting the rotation of the drive shaft 12 to the rotary shaft 2 is replaced with the drive pulley 14 on the drive shaft 12 and the driven pulley as a drive transmission member assembled to the rotary shaft 2. However, instead of this, the drive transmission member may be a driven gear, and the rotation of the drive shaft 12 may be transmitted to the rotary shaft 2 by a gear train.

(2) In the above embodiment, the washer 25 that is pressed in the axial direction by the screw member 26 is used as the position restricting member that fixes the position in the axial direction of the drive transmission member (driven pulley 13). The position restricting member may be a cylindrical member that is provided on the rear end side of the drive transmission member of the rotating shaft 2 and whose position is fixed by a split tightening mechanism, a set screw, or the like. Further, when such a position restricting member is employed, the screw member and the push screw of the split tightening mechanism are opposed to the screw members (holes into which the screw members are inserted) in order to be operable from the outside. A through hole is preferably formed in the wall surface of the bracket 11.

(3) In the above-described embodiment, a part of the outer peripheral surface of the planetary mechanism 10 (the outer peripheral surface of the flange portion 43 of the sun gear forming member 4) is fitted into the circular through hole 11b in the bracket 11 (support frame) to be connected to the planet. Although the mechanism 10 is configured to be supported, the shape of the through hole formed in the support frame and the outer peripheral surface of the planetary mechanism that is inserted into the through hole is not limited to the circular shape as in the above embodiment, but an elliptical shape. Or a polygon etc. may be sufficient.

However, when the through hole or the like is formed in a circular shape as in the above embodiment, there is an advantage that the phase adjustment of the planetary mechanism with respect to the support frame is not limited. In other words, if the circular outer peripheral surface of the planetary mechanism is inserted into the circular through hole of the support frame, the planetary mechanism is rotatable with respect to the support frame even when both are fitted together. The phase of the mechanism (sun gear forming member, and hence the sun gear) is not limited by the fit. Therefore, for example, the hole for inserting the screw member formed in the bracket 11 for fixing the sun gear forming member 4 (gear cover 7) in the above-described embodiment has an arc shape whose center coincides with the through hole 11b. By using a long hole, the phase of the planetary mechanism 10 (sun gear forming member 4) with respect to the bracket 11 can be freely changed. Incidentally, the change of the phase of the planetary mechanism (sun gear) relative to the support frame is, for example, when the opening of the ear thread drawn from the pair of bobbin holders is closed when the angle of the warp line is changed in the loom. This is done to change the angle of the ear thread according to the warp line. In addition, when changing the phase of the planetary mechanism with respect to the support frame, it is also necessary to change the phase of the drive transmission member (drive pulley) on the drive side with respect to the drive shaft accordingly.

Moreover, in the said Example, the outer peripheral surface (outer peripheral surface of the flange part 43) of the sun gear formation member 4 containing the sun gear 4 and the one part outer peripheral surface of the planetary mechanism 10 inserted by the through-hole 11b in the bracket 11 However, the present invention is not limited to this, and for example, a configuration in which a part of the outer peripheral surface of the gear cover 7 in the above-described embodiment is fitted into the through hole 11b can be employed.

(4) In the above-described embodiment, the drive shaft 12 uses the main shaft of the loom as the drive source. However, the planetary ear assembly device of the present invention is not limited to this, and the drive shaft 12 is driven by a dedicated motor. It may be. Further, the rotary shaft 2 may be directly driven by a dedicated motor.

Furthermore, the present invention is not limited to any of the embodiments described above, and various modifications can be made without departing from the spirit of the present invention.

The partial cross section side view which shows one Embodiment of the planetary ear assembly apparatus with which this invention is applied The rear view by the AA cross section of the planetary ear assembly apparatus shown in FIG.

Explanation of symbols

1 Planetary ear assembly device (Planet gear type ear assembly device)
10 Planetary mechanism 11 Bracket (support frame)
11b Through-hole 12 Drive shaft 13 Driven pulley 14 Drive pulley 15 Bearing case 16 Timing belt 17 Beam 18 Slide rail 19 Gear train 2 Rotating shaft 3 Planet carrier 4 Sun gear forming member 41 Sun gear 42 Shaft portion 43 Flange portion 5 Planet gear 51 Support shaft 6 Relay gear 61 Support shaft 7 Gear cover BR Bearing

Claims (7)

A support frame erected on a beam laid between the frames of the loom, the support frame provided on the beam so as to be positionally adjustable in the weaving width direction, and a planetary mechanism supported by the support frame; A planetary gear type ear assembly device including a drive mechanism provided in the support frame, wherein the planetary mechanism is rotatably supported with respect to the support frame, and relative to the rotation shaft. A planetary carrier that is supported in a non-rotatable manner and has a symmetrical arrangement with respect to the rotational axis, and a planetary carrier that rotatably supports a pair of support shafts, and a sun gear that has a through hole through which the rotational shaft penetrates in a relatively rotatable manner. A sun gear coaxially arranged with the planet carrier in a non-rotatable state with respect to the support frame, and attached to the other end of each of the pair of support shafts having a bobbin holder fixed to one end. A planetary gear that indirectly meshes with the sun gear, and the drive mechanism includes a drive transmission member provided so as not to rotate relative to the rotation shaft, and the drive mechanism In the planetary gear type ear assembly device that rotates the planet carrier by rotating the rotation shaft,
The drive transmission member and the rotary shaft are combined so as to be separable in the axial direction of the rotary shaft, and the drive transmission member is supported by the support frame via a bearing,
A planetary gear type ear assembly device in a loom characterized by the above. The support frame includes an outer peripheral wall that defines a space for housing the drive mechanism and a front side wall that supports the planetary mechanism, and the front side wall includes an outer periphery of the planetary mechanism for supporting the planetary mechanism. A through hole into which a part of the surface is inserted is formed,
When the planetary mechanism is fitted in the through hole at a part of the outer peripheral surface, the rotation axis of the rotation shaft is in the axial direction of the rotation axis of the drive transmission member and the rotation axis of the drive mechanism. The rotating shaft is supported in the planetary mechanism so as to be in the same position as seen.
The planetary gear-type ear assembly device in the loom according to claim 1. The planetary mechanism has a circular outer peripheral surface that is a circular outer peripheral surface when viewed in the axial direction of the rotating shaft and has a center on the rotational axis of the rotating shaft;
The through hole in the support frame is a circular through hole into which the circular outer peripheral surface of the planetary mechanism is fitted.
The planetary gear-type ear assembly device for a loom according to claim 2. The rotating shaft is formed as an integral shaft member.
The planetary gear-type ear assembly device in a loom according to any one of claims 1 to 3, wherein The drive transmission member is a driven pulley connected to a drive pulley provided on a drive shaft via a timing belt;
The bearing is disposed at a position where at least a part thereof overlaps the drive transmission member in the axial direction.
The planetary gear-type ear assembly device in a loom according to any one of claims 1 to 4, wherein The position of the drive transmission member in the axial direction is fixed by a position restricting member fixed by a screw member on the rear end side of the drive transmission member with respect to the rotation shaft,
The support frame has a through hole for enabling the screw member to be operated from the outside on a wall surface facing a hole into which the screw member of the position regulating member is inserted.
The planetary gear-type ear assembly device in a loom according to any one of claims 1 to 5, wherein The screw member is screwed into a rear end surface of the rotation shaft.
The planetary gear-type ear assembly device for a loom according to claim 6.

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