CN115958403A

CN115958403A - Cam divider equipment push in device

Info

Publication number: CN115958403A
Application number: CN202310252442.4A
Authority: CN
Inventors: 韩志云; 李勤勇; 孙衍乐; 王培卫
Original assignee: Zhucheng Huilin Precision Machinery Co ltd
Current assignee: Zhucheng Huilin Precision Machinery Co ltd
Priority date: 2023-03-16
Filing date: 2023-03-16
Publication date: 2023-04-14

Abstract

The invention relates to the technical field of cam divider processing, and discloses a cam divider assembling and pressing-in device which comprises an assembling seat, wherein stress frames are symmetrically arranged on two sides of the upper end of the assembling seat, rotating shafts are rotatably arranged at the upper ends of two sides of each stress frame through limiting parts, a lifting mechanism used for adjusting the upper and lower positions of each rotating shaft is arranged at one end of each rotating shaft, a transmission mechanism used for driving the rotating shafts to rotate is arranged at the other end of each rotating shaft, a pressing-in mechanism used for pressing a flange ring into a cam divider shell is further arranged at the middle position of each rotating shaft, an assembling shaft is further rotatably arranged on the assembling seat, a fixing mechanism used for clamping the cam divider shell is arranged on the upper side of each assembling shaft, and a power mechanism used for driving the assembling shaft to rotate intermittently by 90 degrees is arranged on the lower side of each assembling shaft. According to the invention, the flange ring on the cam divider shell is quickly pressed in, and meanwhile, the cam divider shell can intermittently rotate by 90 degrees, so that the force of the pressing mechanism during pressing in is ensured, and the assembly precision is further improved.

Description

Cam divider equipment push in device

Technical Field

The invention relates to the technical field of cam divider processing, in particular to an assembling and pressing-in device of a cam divider.

Background

The cam divider is also called as a cam indexer and an intermittent divider in engineering. The cam indexer is a high-precision rotating device, and is especially important under the current automatic requirement.

In the production and processing process of the cam divider, a flange ring needs to be pressed on a shell of the cam divider, the existing pressing mode adopts manual hammer heads for assembly, the working mode not only can lead to higher labor intensity of workers and lower production efficiency, but also can lead to low matching precision of the assembled flange ring due to uneven pressing force, further influences the torque of a subsequent output shaft, and has poorer production quality, so that further improvement is needed.

Disclosure of Invention

The invention aims to provide a cam divider assembling and pressing device to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a cam wheel splitter equipment push in device, includes the equipment seat, stress frame is installed to equipment seat upper end bilateral symmetry, and stress frame both sides upper end is rotated through spacing portion and is installed the rotation axis, and rotation axis one end is provided with the elevating system who is used for adjusting its upper and lower position, and the other end is provided with the drive mechanism who drives the rotation axis rotation, rotation axis middle part position still is provided with the mechanism of impressing of flange circle to cam wheel splitter shell, still rotate on the equipment seat and install the equipment axle, equipment epaxial side is provided with the fixed establishment that is used for centre gripping cam wheel splitter shell, and equipment axle downside is provided with the power unit of 90 intermittent type rotations of drive equipment axle.

As a modified scheme of the invention: spacing portion has the stopper including setting up the spacing groove on the atress frame, and spacing inslot portion slidable mounting, and the stopper rotates to be installed in the rotation axis both sides, still install spacing spring between stopper bottom and the spacing inslot portion bottom side.

As a modified scheme of the invention: the lifting mechanism comprises a lifting cylinder fixed on the stress frame, the output end of the lifting cylinder is connected with a lifting shaft, and the top of the lifting shaft is rotatably installed at the end part of the rotating shaft.

As a modified scheme of the invention: the transmission mechanism comprises a transmission shaft which is rotatably arranged on the stress frame, a transmission gear is arranged at one end of the transmission shaft, a movable gear is meshed outside the transmission gear, a rotating gear fixed at the end part of the rotating shaft is meshed outside the movable gear, a transmission rod a is coaxially hinged between the rotating shaft and the movable gear, and a transmission rod b is coaxially hinged between the transmission shaft and the movable gear.

As a modified scheme of the invention: the fixing mechanism comprises an assembling disc fixed at the end part of the assembling shaft, a plurality of fixing grooves are formed in the assembling disc, fixing plates are slidably mounted inside the fixing grooves, and assembling springs are further mounted between the fixing plates and the inner wall of the assembling disc.

As a modified scheme of the invention: the power mechanism comprises a power shaft which is rotatably installed at the bottom of the assembling seat, one end of the power shaft is connected with an output end of a power motor, the other end of the power shaft is connected with a driving part, the driving part comprises a driving disc fixed on the power shaft, a half-circle rotating ring is installed on one side of the edge of the outer wall of the driving disc, a stirring plate is installed on the other side of the outer wall of the driving disc, a stirring column is fixedly installed on the stirring plate, the power mechanism further comprises a driven part fixed at the bottom of the assembling shaft, the driven part comprises a driven shell, and a rotating groove matched with the rotating ring and a stirring groove matched with the stirring column are formed in the driven shell.

As a modified scheme of the invention: the power shaft is also fixedly provided with a driving belt wheel, the outer side of the driving belt wheel is provided with a belt, and the belt penetrates through the assembling seat to be connected with a driven belt wheel fixed on the transmission shaft.

As a modified scheme of the invention: the pressing-in mechanism comprises a pressing-in box, a rotating shaft is rotatably mounted at the upper end of the pressing-in box, a rotating cylinder arranged inside the pressing-in box is mounted at the bottom of the rotating shaft, a pressing-in shell is mounted on the outer side of the rotating cylinder through a sliding part, a pressing-in shaft is mounted at the bottom of the pressing-in shell, the lower end of the pressing-in shaft penetrates through the pressing-in box to be connected with a pressing-in plate, and a guide part is further arranged between the pressing-in shaft and the bottom of the pressing-in box.

As a modified scheme of the invention: the sliding part comprises sliding columns symmetrically fixed between the inner walls of the press-in shells and sliding grooves arranged on the outer walls of the rotating cylinders, and the sliding columns are arranged in the sliding grooves in a sliding mode; the guide part comprises guide cylinders fixed at the bottom of the pressing-in box, guide columns are symmetrically arranged between the inner walls of the guide cylinders, and the guide columns slide in guide grooves formed in the outer side of the pressing-in shaft.

As a modified scheme of the invention: the locating rack is symmetrically and fixedly arranged on two sides of the upper end of the press-in box, the top of the locating rack slides in the locating cylinder fixed at the top of the stress rack, the upper end of the rotating shaft penetrates through the press-in box to be connected with a driven gear, and a driving gear fixed on the rotating shaft is meshed with the outer side of the driven gear.

Compared with the prior art, the invention has the beneficial effects that:

the utility model provides a cam wheel splitter equipment push in device, rational in infrastructure, the modern design, through the mechanism of impressing that sets up, elevating system and drive mechanism mutually support, realized impressing fast of flange circle on the cam wheel splitter shell, mutually support with fixture and power unit simultaneously for 90 intermittent type rotations can be carried out to the cam wheel splitter shell, have guaranteed the dynamics of mechanism of impressing when impressing, have further improved the equipment precision, and the practicality is strong, and the reliability is high.

Drawings

FIG. 1 is a schematic overall front view of the present invention;

FIG. 2 is a schematic bottom view of the present invention;

FIG. 3 is a schematic view of the overall top view of the present invention;

FIG. 4 is a schematic view of a structure of the driving member and the driven member;

FIG. 5 is a schematic structural diagram of the driving member of the present invention;

FIG. 6 is a schematic view showing the internal structure of the pressing mechanism according to the present invention;

fig. 7 is a schematic view of the structure of the press-in housing of the present invention.

In the figure: 1. assembling a base; 2. supporting legs; 3. a stress frame; 4. a drive shaft; 5. a transmission gear; 6. a movable gear; 7. a rotating gear; 8. a transmission rod a; 9. a rotating shaft; 10. a limiting block; 11. a limiting spring; 12. a limiting groove; 13. a positioning frame; 14. a positioning cylinder; 15. a driving gear; 16. a driven gear; 17. a rotating shaft; 18. pressing into a box; 19. assembling a disc; 20. a lift cylinder; 21. a lifting shaft; 22. a power motor; 23. a power shaft; 24. a driving pulley; 25. a driving member; 26. a driven member; 27. assembling a shaft; 28. a belt; 29. assembling a spring; 30. a fixing plate; 31. a sliding groove; 32. a fixing groove; 33. pressing the plate in; 34. a transmission rod b; 35. pressing into the shell; 36. pressing the shaft in; 37. a guide cylinder; 38. a guide post; 39. a guide groove; 40. a rotating drum; 41. a sliding post; 42. a driven pulley; 251. a driving disk; 252. a poking plate; 253. shifting the column; 254. a rotating ring; 261. a passive housing; 262. a shifting groove; 263. the groove is rotated.

Detailed Description

It should be noted that the embodiments and features of the embodiments of the present invention may be combined with each other without conflict.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience in describing and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore are not to be construed as limiting the present invention, and further, the terms "first", "second", and the like are used for descriptive purposes only and are not intended to indicate or imply relative importance or to implicitly indicate the number of technical features indicated, whereby the features defined as "first", "second", and the like may explicitly or implicitly include one or more such features, and in the description of the present invention, unless otherwise indicated, "plurality" means two or more than two.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; the two elements may be directly connected or indirectly connected through an intermediate medium, and the two elements may be communicated with each other, and the specific meaning of the above terms in the present invention will be understood by those skilled in the art through specific situations.

The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.

Example 1

Referring to fig. 1 to 7, in the embodiment of the invention, an assembly press-in device for a cam divider includes an assembly seat 1, stress frames 3 are symmetrically installed on two sides of the upper end of the assembly seat 1, the stress frames 3 are of an inverted U-shaped structure, rotating shafts 9 are rotatably installed at the upper ends of two sides of each stress frame 3 through limiting portions, one end of each rotating shaft 9 is provided with a lifting mechanism for adjusting the vertical position of the rotating shaft, the other end of each rotating shaft 9 is provided with a transmission mechanism for driving the rotating shaft 9 to rotate, the lifting mechanism adjusts the vertical height of the rotating shaft 9 and does not influence the normal torque transmission of the transmission mechanism, a press-in mechanism for pressing a flange ring into a cam divider shell is further arranged in the middle of each rotating shaft 9, an assembly shaft 27 is further rotatably installed on the assembly seat 1, a fixing mechanism for clamping the cam divider shell is arranged on the upper side of the assembly shaft 27, and a power mechanism for driving the assembly shaft 27 to rotate intermittently is arranged on the lower side of the assembly shaft 27. When the cam divider works, the cam divider shell of the pre-assembled flange ring is clamped and fixed through the fixing mechanism, then the cam divider shell rotates intermittently under the cooperation of the power mechanism, and when the cam divider shell does not rotate, the press-in mechanism works, so that the flange ring is pressed in the cam divider shell quickly and accurately.

And supporting legs 2 are fixedly arranged at the edge positions of four corners at the bottom of the assembling seat 1 and used for realizing the supporting and limiting purposes of the whole pressing-in device.

In addition, in order to ensure the moving precision of the rotating shaft 9 when the upper and lower positions are changed, in this embodiment, the limiting portion includes a limiting groove 12 disposed on the stress frame 3, a limiting block 10 is slidably mounted inside the limiting groove 12, the limiting block 10 is rotatably mounted on two sides of the rotating shaft 9, and a limiting spring 11 is further mounted between the bottom of the limiting block 10 and the bottom side inside the limiting groove 12. Through the mutual cooperation between spacing spring 11 and the spacing groove 12 for rotation axis 9 can also realize on-line upper and lower position control under the prerequisite of assurance at the rotation.

In one aspect of this embodiment, the lifting mechanism includes a lifting cylinder 20 fixed on the force-bearing frame 3, the output end of the lifting cylinder 20 is connected with a lifting shaft 21, and the top of the lifting shaft 21 is rotatably mounted at the end of the rotating shaft 9. During operation, the position of the rotating shaft 9 can be quickly adjusted only by starting the lifting cylinder 20 and then matching with the lifting shaft 21. The lifting cylinder 20 may be a hydraulic cylinder structure or an air cylinder structure.

In a preferable aspect of this embodiment, the transmission mechanism includes a transmission shaft 4 rotatably installed on the stress frame 3, a transmission gear 5 is installed at one end of the transmission shaft 4, a movable gear 6 is engaged outside the transmission gear 5, a rotating gear 7 fixed at the end of the rotation shaft 9 is engaged outside the movable gear 6, a transmission rod a8 is coaxially hinged between the rotation shaft 9 and the movable gear 6, and a transmission rod b34 is coaxially hinged between the transmission shaft 4 and the movable gear 6. By arranging the transmission rod a8 and the transmission rod b34, under the condition that the positions of the transmission gear 5, the movable gear 6 and the rotating gear 7 are changed, the gear meshing state among the transmission gear 5, the movable gear 6 and the rotating gear 7 is not influenced, and the reliability of the transmission mechanism is further improved.

In order to ensure that the cam divider housing does not shake in a large range when the flange ring is assembled, so as to improve the assembly precision, a fixing mechanism is provided in the embodiment, the fixing mechanism includes an assembly disc 19 fixed at the end of the assembly shaft 27, a plurality of fixing grooves 32 are provided on the assembly disc 19, a fixing plate 30 is slidably mounted inside the fixing grooves 32, and an assembly spring 29 is further mounted between the fixing plate 30 and the inner wall of the assembly disc 19. Through the cooperation between the fixing plate 30 and the assembly spring 29, the cam divider housing is not vertically shaken during assembly.

In this embodiment, the power mechanism includes a power shaft 23 rotatably installed at the bottom of the assembly seat 1, one end of the power shaft 23 is connected with the output end of the power motor 22, the other end of the power shaft 23 is connected with an active part 25, the power mechanism further includes a passive part 26 fixed at the bottom of the assembly shaft 27, and the active part 25 and the passive part 26 are in clamping connection type intermittent matching. In operation, the power motor 22 is started, then the driving part 25 rotates under the action of the power shaft 23, and then the driving part and the driven part 26 cooperate with each other, so that the assembly shaft 27 rotates intermittently.

In order to ensure the effective transmission of the torque on the power shaft 23 to the transmission mechanism, in this embodiment, a driving pulley 24 is further fixedly mounted on the power shaft 23, a belt 28 is mounted on the outer side of the driving pulley 24, and the belt 28 penetrates through the assembly base 1 and is connected with a driven pulley 42 fixed on the transmission shaft 4.

In one case of this embodiment, the press-in mechanism includes a press-in box 18, a rotating shaft 17 is rotatably mounted on the upper end of the press-in box 18, a rotating cylinder 40 disposed inside the press-in box 18 is mounted at the bottom of the rotating shaft 17, a press-in shell 35 is mounted on the outer side of the rotating cylinder 40 through a sliding portion, a press-in shaft 36 is mounted at the bottom of the press-in shell 35, a press-in plate 33 is connected to the lower end of the press-in shaft 36 through the press-in box 18, and a guide portion is further disposed between the press-in shaft 36 and the bottom of the press-in box 18. During operation, the rotating shaft 17 rotates, then the rotating cylinder 40 synchronously rotates, and then the press-in shell 35 drives the press-in shaft 36 to only perform telescopic reset movement at the up-down position under the matching of the sliding part and the guide part, and finally the press-in action of the flange ring on the cam divider shell is ensured.

Wherein, the sliding part includes that the symmetry is fixed sliding column 41 between the shell 35 inner wall of impressing and sets up at the sliding tray 31 of a rotating cylinder 40 outer wall, sliding column 41 slides and sets up inside sliding tray 31, rotates a 40 rotation in-process at a rotating cylinder for sliding tray 31 rotates in step, later cooperates with sliding column 41, turns into the upper and lower rectilinear motion of impressing shell 35, the guide part is including fixing the guide cylinder 37 in the case 18 bottom of impressing, and guide column 38 is installed to the symmetry between the guide cylinder 37 inner wall, and guide column 38 slides in setting up the guide way 39 in the axle 36 outside of impressing, utilizes guide way 39 and guide column 38 further joint cooperation, makes the axle 36 of impressing only take place rectilinear motion and can not take place rotary motion, has further improved the reliability of mechanism of impressing.

In order to prevent the press-in box 18 from shaking when the press-in box is adjusted up and down along with the whole press-in mechanism, in the embodiment, positioning frames 13 are symmetrically and fixedly installed on two sides of the upper end of the press-in box 18, the tops of the positioning frames 13 slide in positioning cylinders 14 fixed on the tops of the stress frames 3, in order to transmit the torque of the rotating shaft 9 to the press-in mechanism, the upper end of the rotating shaft 17 is connected with a driven gear 16 through the press-in box 18, and the driving gear 15 fixed on the rotating shaft 9 is meshed outside the driven gear 16.

Example 2

In another embodiment of the present invention, the embodiment is different from the above-mentioned embodiments in that the driving member 25 includes a driving disk 251 fixed on the power shaft 23, a half-turn rotating ring 254 is installed on one side of the outer wall edge of the driving disk 251, a toggle plate 252 is installed on the other side, and a toggle column 253 is fixedly installed on the toggle plate 252. The driven member 26 includes a driven shell 261, and the driven shell 261 is provided with a rotating groove 263 matched with the rotating ring 254 and a toggle groove 262 matched with the toggle column 253.

Specifically, during operation, the power shaft 23 rotates under the action of the power motor 22, and then the driving disk 251 rotates synchronously, and when the toggle column 253 on the toggle plate 252 is clamped on the toggle groove 262, the driven shell 261 rotates 90 °, and then the driven shell is maintained after rotating by a rotation angle under the cooperation between the rotating ring 254 and the rotating groove 263, and this is repeated, so that 90 ° intermittent rotation of the whole assembly shaft 27 is realized.

The working principle of the invention is as follows: during the equipment, cam wheel splitter shell with the flange circle of pre-assembling is fixed through the clamping action between fixed plate 30, later started motor power 22, make the good cam wheel splitter shell of centre gripping carry out 90 intermittent type formula rotations on the one hand, on the other hand under the cooperation between a plurality of gears and a plurality of band pulleys, make the mechanism of impressing work, thereby make impress board 33 constantly reciprocate, finally impress the flange circle inside the cam wheel splitter shell completely, at the in-process of impressing, the regulation of upper and lower originated impressed position can be realized through lift cylinder 20, the precision of impressing and the quality of impressing have further been improved. The whole operation process is quick and convenient, and is worth popularizing and using.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and should not be taken as limiting the scope of the present invention, which is intended to cover any modifications, equivalents, improvements, etc. within the spirit and scope of the present invention.

Claims

1. The utility model provides a cam divider equipment push in device, includes equipment seat (1), its characterized in that: stress frames (3) are symmetrically arranged on two sides of the upper end of the assembling seat (1), rotating shafts (9) are rotatably arranged at the upper ends of two sides of each stress frame (3) through limiting portions, one ends of the rotating shafts (9) are provided with lifting mechanisms used for adjusting the upper and lower positions of the rotating shafts, the other ends of the rotating shafts are provided with transmission mechanisms used for driving the rotating shafts (9) to rotate, pressing mechanisms used for pressing flange rings into the shells of the cam dividers are further arranged in the middle of the rotating shafts (9), assembling shafts (27) are further rotatably arranged on the assembling seat (1), fixing mechanisms used for clamping the shells of the cam dividers are arranged on the upper sides of the assembling shafts (27), and power mechanisms used for driving the assembling shafts (27) to rotate at 90 degrees intermittently are arranged on the lower sides of the assembling shafts (27).

2. The cam divider assembling and pressing device according to claim 1, wherein the limiting portion comprises a limiting groove (12) arranged on the stress frame (3), a limiting block (10) is slidably arranged in the limiting groove (12), the limiting block (10) is rotatably arranged on two sides of the rotating shaft (9), and a limiting spring (11) is further arranged between the bottom of the limiting block (10) and the bottom side of the limiting groove (12).

3. The cam divider assembling and pressing-in device is characterized in that the lifting mechanism comprises a lifting cylinder (20) fixed on the stress frame (3), the output end of the lifting cylinder (20) is connected with a lifting shaft (21), and the top of the lifting shaft (21) is rotatably installed at the end position of the rotating shaft (9).

4. The cam divider assembling and pressing device according to claim 3, wherein the transmission mechanism comprises a transmission shaft (4) rotatably mounted on the stress frame (3), a transmission gear (5) is mounted at one end of the transmission shaft (4), a movable gear (6) is meshed with the outer side of the transmission gear (5), a rotating gear (7) fixed at the end of a rotating shaft (9) is meshed with the outer side of the movable gear (6), a transmission rod a (8) is coaxially hinged between the rotating shaft (9) and the movable gear (6), and a transmission rod b (34) is coaxially hinged between the transmission shaft (4) and the movable gear (6).

5. The cam divider assembling and pressing-in device according to claim 4, wherein the fixing mechanism comprises an assembling disc (19) fixed at the end of the assembling shaft (27), a plurality of fixing grooves (32) are formed in the assembling disc (19), a fixing plate (30) is slidably mounted inside the fixing grooves (32), and an assembling spring (29) is further mounted between the fixing plate (30) and the inner wall of the assembling disc (19).

6. The cam divider assembling and pressing-in device is characterized in that the power mechanism comprises a power shaft (23) rotatably mounted at the bottom of the assembling seat (1), one end of the power shaft (23) is connected with an output end of a power motor (22), the other end of the power shaft is connected with a driving part (25), the driving part (25) comprises a driving disc (251) fixed on the power shaft (23), one side of the edge of the outer wall of the driving disc (251) is provided with a half-circle rotating ring (254), the other side of the outer wall of the driving disc (251) is provided with a stirring plate (252), a stirring column (253) is fixedly mounted on the stirring plate (252), the power mechanism further comprises a driven part (26) fixed at the bottom of the assembling shaft (27), the driven part (26) comprises a driven shell (261), and the driven shell (261) is provided with a rotating groove (263) mutually matched with the rotating ring (254) and a stirring groove (262) mutually matched with the stirring column (253).

7. The cam divider assembling and pressing device according to claim 6, wherein a driving pulley (24) is fixedly mounted on the power shaft (23), a belt (28) is mounted on the outer side of the driving pulley (24), and the belt (28) penetrates through the assembling seat (1) to be connected with a driven pulley (42) fixed on the transmission shaft (4).

8. The cam divider assembling and pressing-in device according to claim 7, wherein the pressing-in mechanism comprises a pressing-in box (18), a rotating shaft (17) is rotatably mounted at the upper end of the pressing-in box (18), a rotating cylinder (40) arranged inside the pressing-in box (18) is mounted at the bottom of the rotating shaft (17), a pressing-in shell (35) is mounted on the outer side of the rotating cylinder (40) through a sliding part, a pressing-in shaft (36) is mounted at the bottom of the pressing-in shell (35), the lower end of the pressing-in shaft (36) penetrates through the pressing-in box (18) to be connected with a pressing-in plate (33), and a guide part is further arranged between the pressing-in shaft (36) and the bottom of the pressing-in box (18).

9. The cam divider assembling and pressing-in device according to claim 8, wherein the sliding part comprises sliding columns (41) symmetrically fixed between the inner walls of the pressing-in shell (35) and sliding grooves (31) arranged on the outer walls of the rotating cylinders (40), the sliding columns (41) are slidably arranged inside the sliding grooves (31); the guide part comprises guide cylinders (37) fixed at the bottom of the press-in box (18), guide columns (38) are symmetrically arranged between the inner walls of the guide cylinders (37), and the guide columns (38) slide in guide grooves (39) arranged on the outer side of the press-in shaft (36).

10. The cam divider assembling and pressing device as claimed in claim 9, wherein locating frames (13) are symmetrically and fixedly mounted on two sides of the upper end of the pressing box (18), the tops of the locating frames (13) slide in locating cylinders (14) fixed on the tops of the stress frames (3), a driven gear (16) penetrates through the pressing box (18) and is connected to the upper end of the rotating shaft (17), and a driving gear (15) fixed on the rotating shaft (9) is meshed on the outer side of the driven gear (16).