JP2021121563A - Rotation transmission mechanism and chain block - Google Patents

Abstract

To provide a rotation transmission mechanism and a chain block capable of reducing the occurrence of rattling and capable of attaining downsizing when a rotating body is connected to one end of a rotating shaft in a retrofitting manner.SOLUTION: A rotation transmission mechanism has a panel member 100, a driving pulley 132 attached to an end side of a shaft member 331, and a mounting member 111 fixed with a rotating body 120 and arranged on an opposite side of a gear member across the panel member 100 so as to face the panel member 100. The rotation transmission mechanism comprises an attaching mechanism 110 to attach the rotating body 120 to the panel member 100, a driven pulley 131 connected to an end side of a rotating shaft 122, and a driving belt 133 bridged between the driving pulley 132 and the driven pulley 131. The shaft member 331 and the rotating shaft 122 have an overlapping part in the axial direction, and the driving pulley 132 and the driven pulley 131 are arranged in the overlapping part.SELECTED DRAWING: Figure 4

Description

The present invention relates to a rotation transmission mechanism and a chain block.

The electric chain block that raises and lowers the load by using the driving force of the motor has a built-in gear unit having a plurality of gears, and the driving force is transmitted to the road sheave via the gear unit. As such an electric chain block, for example, there is one shown in Patent Document 1, and the driving force from the motor is transmitted to the road sheave via the gear unit.

Further, Patent Document 2 describes a configuration in which a coupling is attached to the rotating shaft of the encoder device when the encoder device is retrofitted to the shaft member, and the coupling is centered via an adapter member and a positioning pin. It is disclosed. In the configuration disclosed in Patent Document 2, the insertion boss portion of the adapter member is inserted into the mounting hole of the coupling, and the taper pin of the positioning pin is inserted into the center hole of the shaft member for centering. It is carried out.

Japanese Unexamined Patent Publication No. 7-48093 JP-A-2017-132560

By the way, in an electric chain block, a separate member such as an encoder device may be retrofitted to one end of a shaft (rotating shaft) of a predetermined gear member of the gear unit. In such a case, it is usually connected by using a coupling. However, in order to use the coupling, it is necessary to form a protruding portion for connecting the coupling to the mounting hole on the tip side of the gear member, and such a protruding portion is formed on the gear member. Usually does not exist, so it is necessary to newly process a gear member having a protruding portion on the tip side.

Therefore, in order to reduce the man-hours for processing the gear member as described above, the configuration as disclosed in Patent Document 2 is realized. However, in the configuration disclosed in Patent Document 2, rattling may occur between the adapter member and the fastening member. In that case, it is difficult to perform centering, or a separate member for centering is required.

Further, when a separate member such as an encoder device is connected to one end of the rotating shaft of the gear unit, both are basically centered by being arranged on the same axis. However, in such a configuration, since the dimension of the rotation axis in the axial direction becomes large, there is also a problem that the size of the product is increased.

The present invention has been made in view of the above circumstances, and is a rotation transmission mechanism capable of reducing rattling and miniaturization when a rotating body is connected to one end of a rotating shaft by retrofitting. And to provide chain blocks.

In order to solve the above problems, according to the first aspect of the present invention, it is a rotation transmission mechanism for transmitting rotation between a shaft member of a gear member and a rotating shaft of a rotating body, and intersects the shaft member. A panel member arranged along the direction and directly or indirectly attached to the end side of the shaft member, arranged on the side of the panel member opposite to the gear member, and integrally with the shaft member. It has a rotating drive pulley and a mounting member that is fixed to the rotating body and is arranged to face the panel member on the opposite side of the panel member from the gear member, and is mounted to mount the rotating body to the panel member. The mechanism, the driven pulley connected to the end side of the rotating shaft of the rotating body, the drive belt hung between the drive pulley and the driven pulley, and the panel member can be attached and the rotating shaft can be rotated. Provided is a rotation transmission mechanism comprising: a bearing that holds in a state.

Further, in the above-described invention, the panel member is provided with an insertion hole, and due to the presence of the insertion hole, the panel member may be subjected to the insertion portion of the pulley receiving member to which the drive pulley is attached or the insertion portion of the shaft member. It is preferable that the shaft member is provided so as to be movable in a direction orthogonal to the axial direction without interference.

Further, in the above-described invention, it is preferable that the belt mechanism is provided with a tension adjusting mechanism for applying tension to the drive belt.

Further, the present invention relating to the chain block preferably includes the rotation transmission mechanism according to each of the above-mentioned inventions.

According to the present invention, it is possible to provide a rotation transmission mechanism and a chain block capable of reducing rattling and miniaturization when a rotating body is connected to one end of a rotating shaft by retrofitting. can.

It is a perspective view which shows the whole structure of the main body of the chain block which concerns on each embodiment of this invention. It is an exploded perspective view which shows the structure in the vicinity of a gear unit and a body among the chain blocks shown in FIG. It is a perspective view which shows the gear box part side in the body provided with the chain block shown in FIG. Of the chain blocks shown in FIG. 1, it is a cross-sectional view seen from a side surface showing a configuration in the vicinity of a panel plate. It is a front view which shows the structure of the vicinity of a panel plate among the chain blocks shown in FIG.

Hereinafter, the chain block 10 provided with the rotation transmission mechanism 12 according to the embodiment of the present invention will be described with reference to the drawings. In the following description, the XYZ Cartesian coordinate system will be used as necessary. In the XYZ Cartesian coordinate system, the X direction is the axial direction of the load sheave member 50 in FIG. 2, the X1 side refers to the upper left side in FIG. 2, and the X2 side refers to the opposite lower right side. The Z direction refers to the direction in which the load is suspended, the Z1 side refers to the back side of the paper surface in FIGS. 1 and 2, and the Z2 side refers to the front side of the paper surface opposite to that. Further, the Y direction refers to a direction orthogonal to the X direction and the Z direction, the Y1 side points to the lower left side in FIG. 2, and the Y2 side points to the opposite upper right side.

<About the overall configuration of the chain block>
FIG. 1 is a perspective view showing the overall configuration of the main body 11 of the chain block 10. FIG. 2 is an exploded perspective view showing the configuration of the chain block 10 in the vicinity of the gear unit 30 and the body 40. As shown in FIGS. 1 and 2, the chain block 10 includes a motor unit 20, a gear unit 30, a body 40, a load sheave member 50, a control unit 80, and the like.

In the chain block 10 shown in FIGS. 1 and 2, the driving force from the motor unit 20 is transmitted to the gear unit 30 and decelerated at a predetermined reduction ratio, and then the load sheave member 50 arranged in the body 40. The driving force is transmitted to the load sheave member 50, and the load sheave member 50 is rotated.

Here, a load chain (not shown) is hung around the load sheave member 50, and by winding or lowering the load chain, the distance between the hook (not shown) and the main body 11 is relative to each other. The load can be lifted by changing the target.

<About the configuration of the gear unit, body and gear case>
Next, the gear unit 30, the body 40, and the gear case 70 will be described. As shown in FIG. 2, the gear unit 30 is housed in the gear storage space GS (see FIG. 3) between the body 40 and the gear case 70. The gear unit 30 includes a pinion gear 31, a first driven gear body 32, a second driven gear body 33, and a road gear 34.

The pinion gear 31 is connected to a motor shaft (not shown) of the motor unit 20. As shown in FIG. 2, the pinion gear 31 is provided so as to be coaxial with the road gear 34. However, the rotation of the pinion gear 31 is not directly transmitted to the road gear 34. That is, the load gear 34 is spline-coupled to the end side of the load sheave member 50 having a hollow portion, so that the load gear 34 and the load sheave member 50 rotate integrally. However, although the pinion gear 31 is inserted through the hollow portion of the load sheave member 50, the load sheave member 50 and the pinion gear 31 are rotatable with each other.

The pinion gear 31 is inserted into the hollow portion of the load sheave member 50 as described above, and the load sheave member 50 is rotatably supported by bearings B1 and B2. Further, the oil seal OS1 is also attached to the outer peripheral side of the load sheave member 50 to prevent the lubricating oil supplied into the storage recess 42 described later from leaking. The load sheave member 50 includes a chain pocket 51 into which a metal ring of a load chain (not shown) can be inserted.

One end side (X1 side) of the pinion gear 31 is pivotally supported via a bearing B3 with respect to the recessed fitting portion 72 existing in the bottom portion 71 of the gear case 70 (see FIG. 2).

FIG. 3 is a perspective view showing the gearbox portion 41 side of the body 40. As shown in FIG. 3, the pinion gear 31 meshes with the first large diameter driven gear 32a of the first driven gear body 32. In addition to the first large-diameter driven gear 32a, the first driven gear body 32 is integrally and coaxially provided with a first small-diameter driven gear 32b having a smaller number of teeth and a smaller diameter than the first large-diameter driven gear 32a. ing.

As shown in FIGS. 2 and 3, a support plate 60 for supporting the first driven gear body 32 is attached to the inside of the gear box portion 41, for example, via a screw or the like. The support plate 60 is provided with a concave fitting portion into which the bearing B4 is fitted, and the other end side (X2 side) of the first driven gear body 32 is pivotally supported via the bearing B4.

Further, one end side (X1 side) of the first driven gear body 32 is rotatably supported via a bearing B5 on the gear case 70 side, and the bearing B5 has an existing concave portion formed in the bottom portion 71. It is fitted in the fitting portion 73. As a result, both ends of the first driven gear body 32 are rotatably supported by the shaft.

Next, the second driven gear body 33 will be described. The second large-diameter driven gear 33a of the second driven gear body 33 meshes with the first small-diameter driven gear 32b. In addition to the second large-diameter driven gear 33a, the second driven gear body 33 is integrally and coaxially provided with a second small-diameter driven gear 33b having a smaller number of teeth and a smaller diameter than the second large-diameter driven gear 33a. ing. The second driven gear body 33 corresponds to the gear member.

FIG. 4 is a partial cross-sectional view showing a state in which the second driven gear body 33 and the encoder device 120 are connected. As shown in FIG. 4, the second driven gear body 33 includes a shaft member 331. In addition to the above-mentioned second large-diameter driven gear 33a and second small-diameter driven gear 33b, the second driven gear body 33 includes a bearing B6 constituting a friction clutch, a clutch friction plate 332, a disc spring 333, and the like. Have. Of the second driven gear body 33, a second small diameter driven gear 33b is formed on the other end side (X2 side) of the shaft member 331.

Further, as shown in FIG. 4, a spline portion 331a is formed on the shaft member 331, and a pair of clutch friction plates 332 are spline-coupled to the spline portion 331a. Therefore, the clutch friction plate 332 rotates integrally with the shaft member 331.

Here, the pair of clutch friction plates 332 sandwich the second large-diameter driven gear 33a. Further, each clutch friction plate 332 is pressed by a disc spring 333, respectively. The disc spring 333 is sandwiched between the spacer SP1 and the step portion 334 to provide an urging force for pressing the clutch friction plate 332. A bearing B7 is adjacent to one end side (X1 side) of the spacer SP1, and an oil seal OS2 is attached to one end side (X1 side) of the bearing B7 via the spacer SP2. Further, the nut N1 is screwed into the screw portion 331b existing on one end side (X1 side) of the shaft member 331. Therefore, when the nut N1 is screwed into the threaded portion 331b, the screwing force is transmitted to the disc spring 333 between the stepped portions 334 via the spacer SP1, the bearing B7 and the spacer SP2, whereby the clutch friction plate 332 is moved. Be pressed.

Further, the gear case 70 is provided with a recessed fitting portion 74 for fitting the bearing B7, the spacer SP2, and the oil seal OS2 described above. The recessed portion 74 is a portion in which the bottom portion 71 of the gear case 70 is recessed so as to face one side (X1 side) in the X direction. The bottom of the recessed fitting portion 74 is provided with an insertion hole 74a for inserting the shaft member 331 and the nut N1. Therefore, one end side (X1 side) of the shaft member 331 protrudes into the electrical component storage portion 76, which will be described later. Further, a step portion 74b for receiving the oil seal OS2 is provided around the insertion hole 74a.

Further, the other end side (X2 side) of the second driven gear body 33 is pivotally supported via a bearing B8 fitted in a concave fitting portion (not shown) existing in the bottom portion 411 of the gear box portion 41.

<About the electrical component storage section and the electrical component storage section>
Next, the electrical component storage unit 76 and the control unit 80 will be described. A concave portion 75 is provided on one side (X1 side) of the gear case 70. Further, a controller cover 90 is attached so as to cover the concave portion 75, and an electrical component storage portion 76 for protecting the electrical component from the outside is formed inside the controller cover 90. In the electrical component storage unit 76, in addition to one end side (X1 side) of the shaft member 331 as described above, electrical components such as a controller, a counter for counting the number of activations, and an inverter are stored. The control unit 80 is composed of one side of the gear case 70, the controller cover 90, and various electrical components housed inside the controller cover 90.

<About rotation transmission mechanism>
Next, the rotation transmission mechanism 12 will be described. The rotation transmission mechanism 12 is a mechanism for transmitting rotation from the shaft member 331 to the rotation shaft 122 of the encoder device 120, and the panel plate 100, the mounting mechanism 110, and the belt mechanism 130 are the main components. Hereinafter, the encoder device 120 and the like will be sequentially described.

As shown in FIG. 4, a panel plate 100 is provided in the electrical component storage unit 76. The panel plate 100 is made of, for example, metal or resin, and is a member to which various electrical components such as a control unit 80 and a terminal block are attached. Further, the panel plate 100 is a member for attaching the encoder device 120 and the belt mechanism 130. The panel plate 100 is attached to the gear case 70 via screws or the like, for example. As a result, even if the controller cover 90 is removed, it does not affect the mounting state of the encoder device 120. Therefore, when the controller cover 90 is removed from the gear case 70, the drive belt 133 of the belt mechanism 130 does not need to be loosened.

In the panel plate 100, a terminal block or the like is attached to the panel plate 100 in a state where a space for attaching the encoder device 120 in the future is secured (see FIG. 5). However, without securing such a space, when mounting the encoder device 120, the mounting portion with respect to the panel plate 100 such as the terminal block may be moved.

A mounting mechanism 110 is mounted on the panel plate 100. The mounting mechanism 110 is a mechanism for mounting the encoder device 120. The mounting mechanism 110 includes a mounting plate 111, a leg member 112, and a fastening member 113. The mounting plate 111 is attached to the panel plate 100 via the leg member 112 and the fastening member 113, and a predetermined gap S1 is provided between the panel plate 100 and the mounting plate 111.

In addition, for example, three or more leg members 112 are provided. The leg member 112 includes a double-threaded bolt 112a and a spacer 112b. Then, the double-threaded bolt 112a is inserted into the spacer 112b, and the fastening member 113 such as a nut is screwed in the state where the spacer 112b is located between the panel plate 100 and the mounting plate 111, whereby the predetermined gap S1 Is maintained.

Here, the apparatus main body 121 of the encoder device 120 is attached to the attachment plate 111. The apparatus main body 121 is mounted on the surface of the mounting plate 111 opposite to the gap S1.

The end side of the rotating shaft 122 is pivotally supported by the bearing B10. The bearing B10 is fixed in the shaft hole 101 formed in the panel plate 100 in an inserted state. A driven pulley 131 is attached to the rotating shaft 122 in a rotatable state. The driven pulley 131 is a member of the belt mechanism 130 attached to the encoder device 120 side (rotating shaft 122).

The encoder device 120 is basically an optional part to be retrofitted after the assembly of the chain block 10 is completed, and corresponds to a rotating body. The encoder device 120 is for performing position detection, speed detection, and detection of ascending or descending by counting the number of pulses. The encoder device 120 of the present embodiment may be an absolute type rotary encoder or an incremental type rotary encoder.

<About the belt mechanism>
Next, the belt mechanism 130 will be described. The belt mechanism 130 includes a driven pulley 131, a drive pulley 132, a drive belt 133 spanned between them, and a tension adjusting mechanism 140.

The driven pulley 131 is attached to the rotating shaft 122 as described above. However, a spacer 123 is attached to the rotating shaft 122 in order to position the mounting position of the driven pulley 131 with respect to the rotating shaft 122. The spacer 123 is arranged closer to the apparatus main body 121 than the driven pulley 131. Therefore, the driven pulley 131 is arranged closer to the bearing B10 side (that is, the panel plate 100 side) than the device main body 121. Therefore, the driven pulley 131 and the drive pulley 132 are arranged close to the panel plate 100 side.

Here, contrary to the above configuration, consider a case where the driven pulley 131 is arranged in a state of being close to the side away from the panel plate 100 (that is, the device main body 121 side) without providing the rotating shaft 122. .. In this case, if the mounting rigidity of the leg member 112 to the panel plate 100 is not increased, the distance between the driven pulley 131 and the drive pulley 132 may fluctuate. In particular, if the tension of the drive belt 133 is increased, the mounting plate 111 itself may be moved (translated) with respect to the panel plate 100 so as to face the drive pulley 132 side. Further, when the tension of the drive belt 133 is received on the device main body 121 side, vibration is likely to occur in the device main body 121 as the drive belt 133 is driven.

On the other hand, in the present embodiment, as described above, the driven pulley 131 and the driving pulley 132 are arranged close to the panel plate 100 side due to the presence of the spacer 123. Therefore, the distance between the driven pulley 131 and the drive pulley 132 is determined based on the rigidity of the panel plate 100. Therefore, even if the tension of the drive belt 133 of the belt mechanism 130 is increased, the distance between the driven pulley 131 and the drive pulley 132 can be maintained. Further, since the tension of the drive belt 133 can be received on the side close to the panel plate 100, even if the tension of the drive belt 133 is increased, the vibration is less likely to be transmitted to the apparatus main body 121 side.

Further, since the drive belt 133 can be brought closer to the panel plate 100 side, the apparatus main body 121 can be arranged to be closer to the panel plate 100 side. As a result, the axial dimension can be reduced.

The drive pulley 132 is attached to the end side of the shaft member 331 via, for example, a set screw. In order to prevent the drive pulley 132 from moving in the axial direction of the shaft member 331, a snap ring is attached to one end (X1 side) of the shaft member 331 in the axial direction (X direction). Further, a pulley receiving member 335 is attached to the other side (X2 side) of the drive pulley 132 in the axial direction (X direction), and the pulley receiving member 335 is inserted into the insertion hole 102 of the panel plate 100. There is.

The pulley receiving member 335 is a member for attaching the drive pulley 132 and a member for attaching to the end side of the shaft member 331. That is, since the shaft member 331 does not have a sufficient length for attaching the drive pulley 132, a member for substantially extending the shaft member 331 in the axial direction, such as the pulley receiving member 335, is attached. ing.

As shown in FIG. 4, such a pulley receiving member 335 has a shaft fixing portion 335a and a pulley mounting portion 335b. The shaft fixing portion 335a has a hole portion (not shown), and is a portion for fixing with a screw, for example, in a state where one end portion of the shaft member 331 is inserted into the hole portion. On the other hand, the pulley mounting portion 335b is a portion for mounting the drive pulley 132 on the outer peripheral side thereof. Therefore, the shaft fixing portion 335a is provided with a diameter larger than that of the pulley mounting portion 335b.

The pulley receiving member 335 is located in a non-contact state with the inner peripheral wall of the insertion hole 102, but the size of the insertion hole 102 is sufficiently larger than the outer diameter of the shaft fixing portion 335a of the pulley receiving member 335. It is largely provided in. Therefore, the panel plate 100 can be moved parallel to the YZ plane orthogonal to the axial direction (X direction) with the shaft fixing portion 335a inserted through the insertion hole 102. Thereby, the distance between the drive pulley 132 and the driven pulley 131 can be adjusted. In order to adjust such a distance, if the diameter of the insertion hole 102 is 1.1 times or more the outer diameter of the shaft fixing portion 335a, the above adjustment can be performed satisfactorily. It is preferably 3 times or more, more preferably 1.5 times or more, and further preferably 2.0 times or more.

A bearing may be attached to the outer peripheral side of the shaft fixing portion 335a. In this case, the outer diameter of the bearing and the diameter of the insertion hole 102 are the same size. Further, the length of the shaft member 331 may be extended without providing the pulley receiving member 335 as described above. In this case, the drive pulley 132 is directly attached to one end side (X1 side) of the shaft member 331.

As described above, in order to move the panel plate 100 parallel to the YZ plane orthogonal to the drive pulley 132 in the axial direction (X direction), the panel plate 100 is attached to the gear case 70 by a screw or the like. Is preferably provided, for example, in the shape of a long hole or a large hole. It is preferable that the elongated hole-like or large hole-like dimension is equal to or larger than the dimensional difference between the outer diameter of the shaft fixing portion 335a and the diameter of the insertion hole 102.

Here, the relationship between the driven pulley 131, the drive pulley 132, the shaft member 331, and the rotating shaft 122 is as follows. That is, the shaft member 331 and the rotating shaft 122 have a portion L1 that overlaps in the axial direction (X direction). Moreover, the driven pulley 131 and the driving pulley 132 are arranged in the overlapping portion L1.

With such an arrangement, the dimensions of the chain block 10 in the axial direction (X direction) are reduced. The rotating shaft 122 protrudes from the apparatus main body 121 of the encoder device 120, and at the protruding portion, more than half of the rotating shaft 122 overlaps the shaft member 331 in the axial direction (X direction). That is, the overlapping portion L1 occupies more than half of the protruding portion of the rotating shaft 122 from the device main body 121.

Further, in order to satisfactorily transmit the driving force from the driving pulley 132 to the driven pulley 131, the driving belt 133 is preferably a toothed timing belt. In this case, the driven pulley 131 and the drive pulley 132 are toothed timing pulleys. However, as the drive belt 133, other belts such as a flat belt may be used in addition to the timing belt. In that case, the driven pulley 131 and the drive pulley 132 also become pulleys corresponding to the drive belt 133.

Before attaching the encoder device 120, it is preferable to prepare the driven pulley 131 and the drive belt 133 as a set. In this case, the encoder device 120 can be easily assembled to the panel plate 100.

Further, the tension adjusting mechanism 140 is a mechanism for applying tension to the drive belt 133. The tension adjusting mechanism 140 includes an arm support portion 141, an arm member 142, an idle roller 143, a spacer 144, and an urging spring 145. By assembling each component of the tension adjusting mechanism 140, the unit is unitized as one unit, so that the workability when assembling the tension adjusting mechanism 140 to the panel plate 100 is improved. However, the tension adjusting mechanism 140 does not have to be unitized into one unit.

The arm support portion 141 includes a support shaft portion 141a, and the support shaft portion 141a is inserted into the panel plate 100 while being inserted into the panel plate 100 so as not to move in the insertion direction. The support shaft portion 141a is inserted through a shaft hole (not shown) of the shaft support portion 142a of the arm member 142, and further inserted through the spacer 144. Further, the nut 141b is screwed into the threaded portion on one end side of the support shaft portion 141a while protruding toward the gear unit 30 side of the panel plate 100, and the snap ring R2 is on the other end side of the support shaft portion 141a. Is locked. Therefore, the support shaft portion 141a supports the arm member 142 in a state where the arm member 142 is rotatable and does not move in the axial direction of the support shaft portion 141a.

The arm member 142 has a shaft support portion 142a supported by the support shaft portion 141a described above, and a roller support portion 142b. The roller support portion 142b is provided integrally with the shaft support portion 142a, but in the present embodiment, the shaft support portion 142a is provided so as to be located closer to the panel plate 100 than the roller support portion 142b. In other words, when the arm member 142 is viewed from the side, the shaft support portion 142a and the roller support portion 142b are provided in a stepped shape, but the roller support portion 142b is farther from the panel plate 100 than the shaft support portion 142a. .. Therefore, among the roller support portions 142b, the idle roller 143 can be positioned on the panel plate 100 side. Further, since the arm member 142 has the stepped shape as described above, it prevents the size of the arm member 142 from becoming large in the axial direction (X direction).

A roller shaft 146 is inserted through a shaft hole (not shown) of the roller support portion 142b, and the roller shaft 146 is prevented from coming off from the shaft hole by a nut or the like. An idle roller 143 is inserted through the roller shaft 146. The idle roller 143 is a member that comes into contact with the drive belt 133, and is rotatably provided with respect to the roller shaft 146. As such an idle roller 143, a bearing or the like can be used in order to reduce the number of parts, but it is of course possible to use a member other than the bearing as the idle roller 143.

Here, the winding portion of the urging spring 145 is located on the outer peripheral side of the spacer 144 described above. One end 145a of the urging spring 145 is locked to a hole or the like of the panel plate 100, and the other end 145b is locked to a shaft support 142a. The urging spring 145 is, for example, a torsion spring, and gives an urging force for pressing the idle roller 143 against the drive belt 133. Such a tension adjusting mechanism 140 is configured to transmit a driving force from the driving pulley 132 to the driven pulley 131 in a state where the driving belt 133 is not loosened.

A protective cover 150 is also attached to the panel plate 100. The protective cover 150 is a member that covers most of the drive pulley 132 and the tension adjusting mechanism 140 from the other side (X2 side) in the axial direction (X direction). Here, the driven pulley 131 is covered by the mounting plate 111 from one side (X1 side) in the axial direction (X direction). Therefore, the driven pulley 131 and the drive pulley 132 are protected from one side (X1 side) in the axial direction (X direction).

<About the effect>
In the rotation transmission mechanism 12 having the above configuration, rotation is transmitted between the shaft member 331 of the gear member (second driven gear body 33) and the rotation shaft 122 of the rotating body (encoder device 120). The rotation transmission mechanism 12 includes a panel member (panel plate 100) arranged along a direction intersecting the shaft member 331. Further, the rotation transmission mechanism 12 is attached to the end side of the shaft member 331, and is a gear member (second driven gear body) of the panel member (panel plate 100) through the insertion hole 102 of the panel member (panel plate 100). A drive pulley 132 that is arranged on the opposite side of 33) and that rotates integrally with the shaft member 331 is provided. Further, in the rotation transmission mechanism 12, the rotating body (encoder device 120) is fixed, and the panel member (panel plate 100) is sandwiched between the panel member (panel plate 100) on the opposite side of the gear member (second driven gear body 33). A mounting mechanism 110 for mounting a rotating body (encoder device 120) to a panel member (panel plate 100) having a mounting member (mounting plate 111) arranged to face the 100), and a rotating body (encoder device 120). ) Is provided with a driven pulley 131 connected to the end side of the rotating shaft 122. Further, the rotation transmission mechanism 12 includes a drive belt 133 that is hung between the drive pulley 132 and the drive belt 133. Further, the bearing B10 is attached to the panel member (panel plate 100) and holds the rotating shaft 122 in a rotatable state.

Therefore, it is possible to realize a configuration in which rattling does not occur by utilizing the flexibility of the drive belt 133. In addition, there is no need to perform time-consuming centering.

Here, in the current rotation transmission mechanism, the shaft member 331 and the rotation shaft 122 are connected by using an adapter member or a fastening member. In this case, rattling occurs, and it becomes difficult to center the rattling to eliminate the rattling. However, the rotation transmission mechanism 12 of the present embodiment uses the belt mechanism 130, and the drive belt 133 of the belt mechanism 130 has flexibility. Therefore, as compared with the configuration in which the shaft member 331 and the rotating shaft 122 are connected by using an adapter member or a fastening member, it is possible to realize a configuration in which rattling does not occur as described above, and it is troublesome. There is no need to perform such centering.

Further, the bearing B10 is attached to the panel member (panel plate 100), and the bearing B10 holds the rotating shaft 122 in a rotatable state. Therefore, even when the tension of the drive belt 133 acts, the load can be received by the bearing B10, and the rotation of the rotating shaft 122 can be stabilized.

Further, in the present embodiment, the panel member (panel plate 100) is provided with an insertion hole 102, and due to the presence of the insertion hole 102, the panel member (panel plate 100) is a pulley to which the drive pulley 132 is attached. It is provided so as to be movable in a direction orthogonal to the axial direction (X direction) of the shaft member 331 without interfering with the insertion portion of the receiving member 335.

Therefore, the tension of the drive belt 133 can be adjusted by moving the panel member (panel plate 100) in the direction orthogonal to the axial direction (X direction).

In the present embodiment, of the rotating shaft 122, the spacer 123 is arranged on the device main body 121 side of the rotating body (encoder device 120) with respect to the driven pulley 131, and the drive pulley 132 is the device main body 121. It is arranged on the panel member (panel plate 100) side rather than the side.

Here, when the driven pulley 131 is close to the device main body 121 side, the distance between the driven pulley 131 and the drive pulley 132 may fluctuate unless the mounting rigidity of the leg member 112 with respect to the panel plate 100 is increased. be. Further, when the tension of the drive belt 133 is received on the device main body 121 side, vibration is likely to occur in the device main body 121 as the drive belt 133 is driven.

On the other hand, in the present embodiment, as described above, the spacer 123 is arranged on the apparatus main body 121 side, so that the driven pulley 131 and the drive pulley 132 are arranged close to the panel plate 100 side. There is. Therefore, since the rigidity of the panel plate 100 can be utilized, the distance between the driven pulley 131 and the drive pulley 132 can be maintained even if the tension of the drive belt 133 of the belt mechanism 130 is increased. Further, since the tension of the drive belt 133 can be received on the side close to the panel plate 100, even if the tension of the drive belt 133 is increased, the vibration is less likely to be transmitted to the apparatus main body 121 side.

Further, since the drive belt 133 can be brought closer to the panel plate 100 side, the apparatus main body 121 can be arranged to be closer to the panel plate 100 side. Thereby, it is possible to reduce the dimension in the axial direction (X direction).

Further, in the present embodiment, the belt mechanism 130 is provided with a tension adjusting mechanism 140 for applying tension to the drive pulley 132. Therefore, the tension adjusting mechanism 140 can be used to apply tension to the drive belt 133, and it is possible to prevent the drive belt 133 from loosening.

<Modification example>
Although each embodiment of the present invention has been described above, the present invention can be variously modified in addition to the above. This will be described below.

In the above-described embodiment, the panel plate 100 is described as the panel member. However, the panel member is not limited to the plate-shaped panel plate 100. For example, a panel member different from the plate-shaped member, such as a net-like member, a columnar member, and a block-shaped member, may be used as the panel member. Further, in the above-described embodiment, the panel plate 100 is arranged along the direction orthogonal to the shaft member 331. However, the panel plate 100 is not limited to the arrangement in the direction orthogonal to the shaft member 331, and may be arranged along a slightly inclined direction (that is, an intersecting direction other than the orthogonal direction).

Further, in the above-described embodiment, the second driven gear body 33 may be configured to have the function of a mechanical brake. When equipped with a mechanical brake function, ratchet teeth (not shown) are coaxially attached in addition to the second large-diameter driven gear 33a and the second small-diameter driven gear 33b, and the ratchet teeth are locked while being urged by a spring member. A claw member (not shown) is rotatably attached to the gearbox portion 41. By doing so, it is possible to configure a mechanical brake that rotates in one direction but can prevent unintended reversal.

Further, in each of the above-described embodiments, a case where a rotating body such as the encoder device 120 or the like is retrofitted is described. However, the present invention can be applied not only when the rotating body is retrofitted but also when the rotating body is attached to the chain block at an early stage. Further, in each of the above-described embodiments, the case where the second driven gear body 33 is used as the gear member is described. However, the gear member may be a gear member other than the second driven gear body 33 in the gear unit 30 (for example, the first driven gear body 32), or may be a gear member additionally provided in the gear unit 30.

Further, in the above-described embodiment, the encoder device 120 is described as a rotating body. However, the rotating body is not limited to the encoder device 120. For example, various objects such as a rotary level switch, a rotary potentiometer, a rotary torque sensor, and the like may be used as a rotating body.

10 ... Chain block, 11 ... Main body, 12 ... Rotation transmission mechanism, 20 ... Motor unit, 30 ... Gear unit, 31 ... Pinion gear, 32 ... 1st driven gear body, 32a ... 1st large diameter driven gear, 32b ... 1st Small diameter driven gear, 33 ... 2nd driven gear body (corresponding to gear member), 33a ... 2nd large diameter driven gear, 33b ... 2nd small diameter driven gear, 34 ... Road gear, 40 ... Body, 41 ... Gear box part, 42 ... Storage recess, 50 ... Road sheave member, 51 ... Chain pocket, 60 ... Support plate, 70 ... Gear case, 71 ... Bottom, 72, 73, 74 ... Recessed fitting part, 74a ... Insertion hole, 74b ... Step part, 75 ... Concave shape part, 76 ... Electrical component storage part, 80 ... Control unit, 90 ... Controller cover, 100 ... Panel plate (corresponding to panel member), 101 ... Shaft hole, 102 ... Insertion hole, 110 ... Mounting mechanism, 111 ... Mounting Plate (corresponding to mounting member), 112 ... Leg member, 112a ... Double screw bolt, 112b ... Spacer, 113 ... Fastening member, 120 ... Encoder device (corresponding to rotating body), 121 ... Device body, 122 ... Rotating shaft, 123 ... Spacer, 130 ... Belt mechanism, 131 ... Driven pulley, 132 ... Drive pulley, 133 ... Drive belt, 140 ... Tension adjustment mechanism, 141 ... Arm support, 141a ... Support shaft, 141b ... Nut, 142 ... Arm member, 142a ... shaft support, 142b ... roller support, 143 ... idle roller, 144 ... spacer, 145 ... urging spring, 145a ... one end, 145b ... other end, 146 ... roller shaft, 150 ... protective cover, 331 ... shaft Member, 331a ... Spline part, 331b ... Screw part, 332 ... Clutch friction plate, 333 ... Belleville spring, 334 ... Step part, 335 ... Pulley receiving member, 335a ... Shaft fixing part, 335b ... Pulley mounting part, 411 ... Bottom, B1 to B10 ... Bearing, GS ... Gear storage space, L1 ... Overlapping part, N1 ... Nut, OS1, OS2 ... Oil seal, S1 ... Gap, SP1, SP2 ... Spacer

Claims (4)

A rotation transmission mechanism that transmits rotation between the shaft member of the gear member and the rotation shaft of the rotating body.
Panel members arranged along the direction intersecting the shaft member, and
A drive pulley that is directly or indirectly attached to the end side of the shaft member, is arranged on the side of the panel member opposite to the gear member, and rotates integrally with the shaft member.
The rotating body is fixed and has a mounting member arranged opposite to the panel member on the side opposite to the gear member with the panel member sandwiched therein, and mounting for mounting the rotating body to the panel member. Mechanism and
A driven pulley connected to the end side of the rotating shaft of the rotating body, and
A drive belt spanned between the drive pulley and the driven pulley,
A bearing that is attached to the panel member and holds the rotating shaft in a rotatable state.
A rotation transmission mechanism characterized by being provided with. The rotation transmission mechanism according to claim 1.
The panel member is provided with an insertion hole.
Due to the presence of the insertion hole, the panel member moves in a direction orthogonal to the axial direction of the shaft member without interfering with the insertion portion of the pulley receiving member to which the drive pulley is attached or the insertion portion of the shaft member. Possible,
A rotation transmission mechanism characterized by that. The rotation transmission mechanism according to claim 1 or 2.
The belt mechanism is provided with a tension adjusting mechanism for applying tension to the drive belt.
A rotation transmission mechanism characterized by that. The rotation transmission mechanism according to any one of claims 1 to 3 is provided.
A chain block that features that.

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