CN211495657U

CN211495657U - Power differential mechanism

Info

Publication number: CN211495657U
Application number: CN201922084098.4U
Authority: CN
Inventors: 梁国墘
Original assignee: Mallet Industrial Equipment Co ltd
Current assignee: Mallet Industrial Equipment Co ltd
Priority date: 2019-11-28
Filing date: 2019-11-28
Publication date: 2020-09-15
Anticipated expiration: 2029-11-28

Abstract

The utility model discloses a power differential mechanism relates to an automatic cardboard conveying equipment field of corrugated paper trade, the loach carrying platform comprises a supporting fram, be provided with on the support frame and be used for driving the driven cardboard drive assembly of cardboard and be used for reducing the differential subassembly of moisturizing paper volume, weight reduction in the twinkling of an eye, the differential subassembly sets up the one end at cardboard drive assembly, the transmission speed of differential subassembly is faster than cardboard drive assembly's transmission speed, still is used for driving cardboard drive assembly and the driven power transmission subassembly of differential subassembly including setting up in support frame one side, the differential subassembly be used for reducing moisturizing paper volume, weight reduction in the twinkling of an eye for cardboard driven process is more smooth and easy, cardboard drive assembly is used for driving the cardboard transmission, the power transmission subassembly is used for providing power for cardboard drive assembly and differential subassembly.

Description

Power differential mechanism

Technical Field

The utility model relates to an automatic cardboard conveying equipment field of corrugated paper trade, in particular to power differential mechanism.

Background

The existing paper board transmission mechanism in the society directly feeds paper by a belt, the speed is consistent, the instantaneous paper supplement amount is too much, the weight is increased, and the production disadvantage caused by unsmooth paper board falling is caused.

SUMMERY OF THE UTILITY MODEL

The utility model provides a technical problem provide one kind can reduce in the twinkling of an eye paper supply volume, weight reduction, make the more smooth power differential mechanism of production process.

The utility model provides a technical scheme that its technical problem adopted is: power differential mechanism, including the support frame, be provided with on the support frame and be used for driving the driven cardboard transmission assembly of cardboard and be used for reducing the differential subassembly of paper supplement volume, weight reduction in the twinkling of an eye, the differential subassembly sets up the one end at cardboard transmission assembly, the transmission speed of differential subassembly is faster than the transmission speed of cardboard transmission assembly, still is used for driving cardboard transmission assembly and the driven power transmission assembly of differential subassembly including setting up in support frame one side, cardboard transmission assembly is used for driving the cardboard transmission, the differential subassembly is used for reducing paper supplement volume, weight reduction in the twinkling of an eye for the driven process of cardboard is more smooth and easy, the power transmission assembly is used for providing power for cardboard transmission assembly and differential subassembly.

Further, the method comprises the following steps: the differential subassembly includes differential drive assembly, differential driven assembly and sets up the differential belt at differential drive assembly and differential driven assembly surface, thereby the differential drive assembly drives the differential belt and rotates and drive the rotation of differential driven assembly.

Further, the method comprises the following steps: differential drive assembly includes first differential driving shaft, the surface cover of first differential driving shaft is equipped with a plurality of differential driving pulley, the surface cover of first differential driving shaft is equipped with first support rolling bearing, first support rolling bearing sets up on the support frame, thereby the rotatory differential driving pulley rotation of driving of first differential driving shaft drives differential belt drive, first support rolling bearing is used for supporting first differential driving shaft.

Further, the method comprises the following steps: the differential driven assembly comprises a differential driven support shaft, a differential driven wheel is sleeved on the outer surface of the differential driven support shaft, the differential driven support shaft is rotatably connected with the differential driven wheel, the differential driven wheel is correspondingly arranged on a differential driving belt pulley, a differential belt is arranged on the outer surface of the differential driven wheel and the differential driving belt pulley, and the differential driven support shaft drives the differential driven wheel to rotate.

Further, the method comprises the following steps: cardboard transmission unit includes the transmission driving shaft, the surface cover of transmission driving shaft is equipped with the transmission action wheel, the surface of transmission action wheel is provided with driving belt, still keeps away from the transmission driven shaft of transmission driving shaft one end at cardboard transmission unit including setting up, the surface cover of transmission driven shaft is equipped with the transmission from the driving wheel, the transmission corresponds the setting with the transmission action wheel from the driving wheel, driving belt sets up the surface from the driving wheel at transmission action wheel and transmission, thereby the rotatory transmission action wheel that drives of transmission driving shaft drives the transmission belt transmission, driving belt drives the transmission and rotates for the transmission driven shaft from the driving wheel.

Further, the method comprises the following steps: the power transmission assembly comprises a first motor, an output shaft of the first motor is sleeved with a first gear used for driving the transmission of the paperboard transmission assembly and a second gear used for driving the rotation of the differential assembly, the power transmission assembly further comprises a third gear arranged on the transmission driving shaft, a first chain used for transmitting torque is arranged on the outer surface of the first gear and the outer surface of the third gear, a fourth gear arranged on the first differential driving shaft is further arranged, a second chain used for transmitting torque is arranged on the outer surface of the second gear and the outer surface of the fourth gear, the first motor rotates to drive the first gear and the second gear to rotate, the first gear drives the first chain to drive the third gear to rotate, and the second gear rotates to drive the second chain to drive the fourth gear to rotate.

Further, the method comprises the following steps: the differential subassembly is including setting up the second differential driving shaft on the support frame, the surface cover of second differential driving shaft is equipped with the differential sun gear, still supports rolling bearing including the cover establishes the second that second differential driving shaft surface supports rolling bearing, the second supports rolling bearing and sets up on the support frame, the rotation of second differential driving shaft drives the rotation of differential sun gear and drives the cardboard transmission, the second supports rolling bearing and is used for supporting second differential driving shaft.

Further, the method comprises the following steps: the power transmission assembly comprises a second motor, a fifth gear is arranged on an output shaft of the second motor, a sixth gear and a seventh gear are sleeved on the outer surface of the transmission driving shaft, a third chain for transmitting torque is arranged on the outer surfaces of the fifth gear and the sixth gear, an eighth gear is arranged on one side of the seventh gear, which is far away from the fifth gear, the seventh gear is meshed with the eighth gear, a ninth gear is arranged on one side of the eighth gear, which is far away from the seventh gear, in a meshed manner, the ninth gear is sleeved on the outer surface of the second differential driving shaft, the second motor rotates to drive the third chain to drive the sixth gear to rotate, the sixth gear rotates to drive the transmission driving shaft to rotate so as to drive the paperboard transmission assembly to transmit, meanwhile, the transmission driving shaft rotates to drive the seventh gear to rotate, the seventh gear rotates to drive the eighth gear to rotate so as to drive the ninth gear to rotate, and the ninth gear rotates to drive the second differential driving shaft to rotate so as to drive the differential assembly to transmit and further drive the paper board to transmit.

Further, the method comprises the following steps: the transmission speed of the differential assembly is 1.3-1.5 times of that of the paperboard transmission assembly.

The utility model has the advantages that: the utility model provides a differential subassembly is used for reducing paper supply volume, weight reduction in the twinkling of an eye for the driven process of cardboard is more smooth and easy, cardboard transmission assembly is used for driving the cardboard transmission, power transmission assembly is used for providing power for cardboard transmission assembly and differential subassembly.

Drawings

FIG. 1 is a schematic structural view of a first embodiment of a powered differential mechanism;

FIG. 2 is a schematic structural view of a second embodiment of the powered differential mechanism;

FIG. 3 is a schematic structural view of the differential assembly of the first embodiment;

FIG. 4 is a schematic view of the structure of the paperboard drive assembly;

FIG. 5 is a schematic structural view of a power transmission assembly of the first embodiment;

FIG. 6 is a schematic structural view of a differential assembly according to a second embodiment;

FIG. 7 is a schematic structural view of a power transmission assembly of the second embodiment;

labeled as: 1. a support frame; 2. a paperboard drive assembly; 3. a differential assembly; 4. a power transmission assembly; 21. a transmission driving shaft; 22. a transmission driving wheel; 23. a drive belt; 24. a driven shaft is driven; 25. a driven wheel is driven; 33. a differential belt; 301. a second differential drive shaft; 302. a differential sun gear; 303. a second support rotational bearing; 311. a first differential drive shaft; 312. a differential drive pulley; 313. a first support rotating bearing; 321. a differential driven support shaft; 322. a differential driven wheel; 401. a first motor; 402. a first gear; 403. a second gear; 404. a third gear; 405. a first chain; 406. a fourth gear; 407. a second chain; 411. a second motor; 412. a fifth gear; 413. a sixth gear; 414. a seventh gear; 415. a third chain; 416. an eighth gear; 417. a ninth gear.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the following detailed description.

The power differential mechanism shown in fig. 1 and 2 comprises a support frame 1, wherein a paperboard transmission assembly 2 used for driving the paperboard transmission and a differential assembly 3 used for reducing the instant paper supplement amount and the weight are arranged on the support frame 1, the differential assembly 3 is arranged at one end of the paperboard transmission assembly 2, the transmission speed of the differential assembly 3 is higher than that of the paperboard transmission assembly 2, the power transmission assembly 4 arranged on one side of the support frame 1 and used for driving the paperboard transmission assembly 2 and the differential assembly 3 to transmit is further included, the paperboard transmission assembly 2 is used for driving the paperboard transmission, the differential assembly 3 is used for reducing the instant paper supplement amount and the weight to enable the process of the paperboard transmission to be smoother, and the power transmission assembly 4 is used for providing power for the paperboard transmission assembly 2 and the differential assembly 3.

On the basis, the differential assembly 3 comprises a differential driving assembly, a differential driven assembly and a differential belt 33 arranged on the outer surfaces of the differential driving assembly and the differential driven assembly, and the differential driving assembly drives the differential belt 33 to rotate so as to drive the differential driven assembly to rotate.

On the basis, as shown in fig. 3, the differential driving assembly includes a first differential driving shaft 311, the outer surface of the first differential driving shaft 311 is sleeved with a plurality of differential driving belt pulleys 312, the outer surface of the first differential driving shaft 311 is sleeved with a first supporting rotating bearing 313, the first supporting rotating bearing 313 is arranged on the support frame 1, the first differential driving shaft 311 rotates to drive the differential driving belt pulleys 312 to rotate so as to drive the differential belt 33 to transmit, and the first supporting rotating bearing 313 is used for supporting the first differential driving shaft 311.

On the basis, the differential driven assembly comprises a differential driven support shaft 321, a differential driven wheel 322 is sleeved on the outer surface of the differential driven support shaft 321, the differential driven support shaft 321 is rotatably connected with the differential driven wheel 322, the differential driven wheel 322 is correspondingly arranged with the differential driving pulley 312, the differential belt 33 is arranged on the outer surfaces of the differential driven wheel 322 and the differential driving pulley 312, and the differential driven support shaft 321 rotates to drive the differential driven wheel 322 to rotate.

On above-mentioned basis, as shown in fig. 4, cardboard transmission assembly 2 includes transmission driving shaft 21, the surface cover of transmission driving shaft 21 is equipped with transmission action wheel 22, the surface of transmission action wheel 22 is provided with driving belt 23, still including setting up the transmission driven shaft 24 of keeping away from transmission driving shaft 21 one end at cardboard transmission assembly 2, the surface cover of transmission driven shaft 24 is equipped with the transmission and follows driving wheel 25, the transmission corresponds the setting with transmission action wheel 22 from driving wheel 25, driving belt 23 sets up the surface at transmission action wheel 22 and transmission driven wheel 25, thereby the rotatory transmission action wheel 22 rotation of drive shaft 21 drives the transmission of driving belt 23, driving belt 23 drives the transmission and follows driving wheel 25 and rotate for transmission driven shaft 24.

On the basis of the above, as shown in fig. 5, the power transmission assembly 4 includes a first electric motor 401, the output shaft of the first motor 401 is sleeved with a first gear 402 for driving the paper board transmission component 2 to transmit, a second gear 403 for driving the differential component 3 to rotate, and a third gear 404 arranged on the transmission driving shaft 21, the outer surfaces of the first gear 402 and the third gear 404 are provided with a first chain 405 for transmitting torque, and further comprises a fourth gear 406 provided on the first differential driving shaft 311, the outer surfaces of the second gear 403 and the fourth gear 406 are provided with a second chain 407 for transmitting torque, the first motor 401 rotates to rotate the first gear 402 and the second gear 403, the first gear 402 drives the first chain 405 to rotate and thus the third gear 404, the second gear 403 rotates to drive the second chain 407 to rotate, so as to drive the fourth gear 406 to rotate.

On the basis, as shown in fig. 6, the differential assembly 3 comprises a second differential driving shaft 301 arranged on the support frame 1, a differential sun gear 302 is sleeved on the outer surface of the second differential driving shaft 301, a second supporting rolling bearing 303 sleeved on the outer surface of the second differential driving shaft 301 is further included, the second supporting rolling bearing 303 is arranged on the support frame 1, the second differential driving shaft 301 rotates to drive the differential sun gear 302 to rotate so as to drive the paper board to transmit, and the second supporting rolling bearing 303 is used for supporting the second differential driving shaft 301.

On the basis, the power transmission assembly 4 includes a second motor 411, a fifth gear 412 is disposed on an output shaft of the second motor 411, a sixth gear 413 and a seventh gear 414 are sleeved on an outer surface of the transmission driving shaft 21, a third chain 415 for transmitting torque is disposed on outer surfaces of the fifth gear 412 and the sixth gear 413, an eighth gear 416 is disposed on one side of the seventh gear 414 away from the fifth gear 412, the seventh gear 414 is meshed with the eighth gear 416, a ninth gear 417 is meshed with one side of the eighth gear 416 away from the seventh gear 414, the ninth gear 417 is sleeved on an outer surface of the second differential driving shaft 301, the second motor 411 rotates to drive the third chain 415 to drive the sixth gear 413 to rotate, the sixth gear 413 rotates to drive the transmission driving shaft 21 to rotate to drive the cardboard transmission assembly 2 to transmit, meanwhile, the transmission driving shaft 21 rotates to drive the seventh gear 414 to rotate, the seventh gear 414 rotates to drive the eighth gear 416 to rotate so as to drive the ninth gear 417 to rotate, and the ninth gear 417 rotates to drive the second differential driving shaft 301 to rotate so as to drive the differential assembly 3 to transmit and further drive the paper board to transmit.

On the basis of the above, the transmission speed of the differential assembly 3 is 1.3-1.5 times of that of the paperboard transmission assembly 2.

The above-mentioned embodiments, further detailed description of the objects, technical solutions and advantages of the present invention, it should be understood that the above-mentioned embodiments are only specific embodiments of the present invention, and are not intended to limit the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims

1. Power differential mechanism, including support frame (1), its characterized in that: be provided with on support frame (1) and be used for driving driven cardboard transmission assembly (2) of cardboard and be used for reducing differential subassembly (3) of moisturizing paper volume, weight reduction in the twinkling of an eye, differential subassembly (3) set up the one end in cardboard transmission assembly (2), the transmission speed of differential subassembly (3) is faster than the transmission speed of cardboard transmission assembly (2), still including setting up and be used for driving driven power transmission assembly (4) of cardboard transmission assembly (2) and differential subassembly (3) in support frame (1) one side.

2. The powered differential mechanism as defined in claim 1 wherein: the differential assembly (3) comprises a differential driving assembly, a differential driven assembly and a differential belt (33) arranged on the outer surfaces of the differential driving assembly and the differential driven assembly.

3. The powered differential mechanism as defined in claim 2 wherein: the differential driving assembly comprises a first differential driving shaft (311), a plurality of differential driving belt pulleys (312) are sleeved on the outer surface of the first differential driving shaft (311), a first supporting rotating bearing (313) is sleeved on the outer surface of the first differential driving shaft (311), and the first supporting rotating bearing (313) is arranged on the supporting frame (1).

4. The powered differential mechanism as defined in claim 3 wherein: the differential driven assembly comprises a differential driven support shaft (321), the outer surface sleeve of the differential driven support shaft (321) is provided with a differential driven wheel (322), the differential driven support shaft (321) is rotatably connected with the differential driven wheel (322), the differential driven wheel (322) corresponds to the differential driving pulley (312), and the differential belt (33) is arranged on the outer surface of the differential driven wheel (322) and the differential driving pulley (312).

5. The powered differential mechanism as defined in claim 1 wherein: cardboard transmission assembly (2) are including transmission driving shaft (21), the surface cover of transmission driving shaft (21) is equipped with transmission action wheel (22), the surface of transmission action wheel (22) is provided with driving belt (23), still including setting up transmission driven shaft (24) of keeping away from transmission driving shaft (21) one end in cardboard transmission assembly (2), the surface cover of transmission driven shaft (24) is equipped with the transmission from driving wheel (25), the transmission corresponds the setting with transmission action wheel (22) from driving wheel (25), driving belt (23) set up the surface from driving wheel (25) and transmission at transmission action wheel (22).

6. The powered differential mechanism as defined in claim 5 wherein: the power transmission assembly (4) comprises a first motor (401), an output shaft of the first motor (401) is sleeved with a first gear (402) used for driving the paperboard transmission assembly (2) to transmit and a second gear (403) used for driving the differential assembly (3) to rotate, the power transmission assembly further comprises a third gear (404) arranged on the transmission driving shaft (21), first chains (405) used for transmitting torque are arranged on the outer surfaces of the first gear (402) and the third gear (404), the power transmission assembly further comprises a fourth gear (406) arranged on the first differential driving shaft (311), and second chains (407) used for transmitting torque are arranged on the outer surfaces of the second gear (403) and the fourth gear (406).

7. The powered differential mechanism as defined in claim 1 wherein: differential subassembly (3) are including setting up second differential driving shaft (301) on support frame (1), the surface cover of second differential driving shaft (301) is equipped with differential sun gear (302), still supports rolling bearing (303) including the cover second that establishes at second differential driving shaft (301) surface, second supports rolling bearing (303) and sets up on support frame (1).

8. The powered differential mechanism as defined in claim 7 wherein: the power transmission assembly (4) comprises a second motor (411), a fifth gear (412) is arranged on an output shaft of the second motor (411), the power transmission assembly further comprises a sixth gear (413) and a seventh gear (414) which are sleeved on the outer surface of the transmission driving shaft (21), a third chain (415) used for transmitting torque is arranged on the outer surfaces of the fifth gear (412) and the sixth gear (413), an eighth gear (416) is arranged on one side, far away from the fifth gear (412), of the seventh gear (414), the seventh gear (414) is meshed with the eighth gear (416), a ninth gear (417) is arranged on one side, far away from the seventh gear (414), of the eighth gear (416) and meshed with the ninth gear (417), and the outer surface of the second differential driving shaft (301) is sleeved with the ninth gear (417).

9. The powered differential mechanism as defined in claim 1 wherein: the transmission speed of the differential assembly (3) is 1.3-1.5 times of that of the paperboard transmission assembly (2).