CN210259948U - Novel sorting machine with inclined wheels - Google Patents

Abstract

The utility model belongs to the technical field of the sorting machine and specifically relates to novel bevel wheel sorting machine. This sorting machine includes board, belt conveyor, gyro wheel rotary driving mechanism, initiative driving roller, driven driving roller, motor, O shape area, synchronizing wheel and hold-in range, install belt conveyor on the board, rotate on the board and be connected with the gyro wheel that the several terminal surface is parallel to each other, the board internal rotation is connected with several driven driving rollers and an initiative driving roller, all is connected with the gyro wheel that the several centre of a circle is in same sharp through O shape area on initiative driving roller and the driven driving roller. The utility model discloses a motor drive initiative driving roller is rotatory, and the initiative driving roller passes through the hold-in range and drives all the other driven driving roller transmissions, and the driving roller drives the gyro wheel through O shape area and rotates. The driven driving roller drives the belt conveying mechanism to drive through the synchronous belt. All the rollers are driven to synchronously rotate through the roller rotation driving mechanism, so that the conveying direction is adjusted. The structure is simplified, and the cost is saved.

Description

Novel sorting machine with inclined wheels

Technical Field

The utility model belongs to the technical field of the sorting machine and specifically relates to novel bevel wheel sorting machine.

Background

A sorter is a device that conveys articles in a given direction. The existing sorting machine is complex in structure and high in cost.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem described in the background art, the utility model provides a novel bevel wheel sorting machine. The driving transmission roller is driven to rotate by a motor, the driving transmission roller drives other driven transmission rollers to transmit through a synchronous belt, and the transmission rollers drive the idler wheels to rotate through an O-shaped belt. The driven driving roller drives the belt conveying mechanism to drive through the synchronous belt. All the rollers are driven to synchronously rotate through the roller rotation driving mechanism, so that the conveying direction is adjusted. The structure is simplified, and the cost is saved.

The utility model provides a technical scheme that its technical problem adopted is:

a novel oblique wheel sorting machine comprises a machine table, a belt conveying mechanism, rollers, a roller rotation driving mechanism, driving transmission rollers, driven transmission rollers, a motor, an O-shaped belt, synchronizing wheels and a synchronous belt, wherein the belt conveying mechanism is installed on the machine table, the machine table is rotatably connected with a plurality of rollers with mutually parallel end surfaces, the machine table is rotatably connected with a plurality of driven transmission rollers and a driving transmission roller, the driving transmission rollers are mutually parallel to all the driven transmission rollers, the driving transmission rollers and the driven transmission rollers are respectively connected with a plurality of rollers with the centers of circles in the same straight line through the O-shaped belt, the synchronizing wheels are respectively fixed at two ends of the driving transmission rollers and the driven transmission rollers, the motor is fixed at the bottom end of the machine table, the synchronizing wheel at one end of each driving transmission roller is connected with an output shaft of the motor through a belt, the other end of each driving roller is connected with the synchronizing wheel at one end of the adjacent driven transmission rollers through the, the synchronous wheel at one end of the driven transmission roller adjacent to the belt conveying mechanism is connected with the belt conveying mechanism through the synchronous belt, the roller rotation driving mechanism is installed in the machine table, and the roller rotation driving mechanism is connected with all rollers on the machine table.

Specifically, the board internal fixation has the connecting plate, has seted up the several arc wall on the connecting plate, and the arc wall internal fixation has the shaft hole, and the gyro wheel rotates to be connected on the support, and the axostylus axostyle of support bottom passes the shaft hole, and the arc wall is passed to the O shape area.

Specifically, the roller rotation driving mechanism comprises a rotating motor, a cam, a movable frame and connecting rods, wherein the rotating motor is fixed in the machine table, the cam is fixed on an output shaft of the rotating motor, a pin shaft is fixed on the end face of the cam and penetrates through the movable frame, two sides of the movable frame are respectively embedded into sliding grooves in the inner wall of the machine table, a plurality of connecting rods are hinged to the movable frame, and the connecting rods are fixed with a shaft rod at the bottom end of the support.

Specifically, belt conveyors comprises conveyer belt and commentaries on classics roller, and two commentaries on classics rollers that are parallel to each other rotate to be connected on the board, and one of them one end of changeing the roller is fixed with the synchronizing wheel, and the synchronizing wheel on changeing the roller is connected with the synchronizing wheel on a driven driving roller through the hold-in range, and two commentaries on classics rollers all laminate on the conveyer belt.

The utility model has the advantages that: the utility model provides a novel oblique wheel sorting machine. The driving transmission roller is driven to rotate by a motor, the driving transmission roller drives other driven transmission rollers to transmit through a synchronous belt, and the transmission rollers drive the idler wheels to rotate through an O-shaped belt. The driven driving roller drives the belt conveying mechanism to drive through the synchronous belt. All the rollers are driven to synchronously rotate through the roller rotation driving mechanism, so that the conveying direction is adjusted. The structure is simplified, and the cost is saved.

Drawings

The present invention will be further explained with reference to the drawings and examples.

Fig. 1 is a schematic structural diagram of the present invention;

fig. 2 is a schematic structural view of the interior of the machine table of the present invention;

fig. 3 is a schematic structural view of the roller rotation driving mechanism of the present invention;

fig. 4 is a schematic structural view of the connection plate of the present invention;

fig. 5 is a schematic structural diagram of the present invention;

in the figure, 1, a machine table, 2, a belt conveying mechanism, 3, a roller, 4, a roller rotation driving mechanism, 5, a driving roller, 6, a driven driving roller, 7, a motor, 8, an O-shaped belt, 9, a synchronous wheel, 10, a synchronous belt, 11, a connecting plate, 12, an arc-shaped groove, 13, a shaft hole, 14, a support, 21, a conveying belt, 22, a rotating roller, 41, a rotating motor, 42, a cam, 43, a movable frame and 44 are connected through a connecting rod.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic drawings and illustrate the basic structure of the present invention only in a schematic manner, and thus show only the components related to the present invention.

Fig. 1 is the structural schematic diagram of the present invention, fig. 2 is the structural schematic diagram of the inside of the machine table of the present invention, fig. 3 is the structural schematic diagram of the roller rotation driving mechanism of the present invention, fig. 4 is the structural schematic diagram of the connecting plate of the present invention, fig. 5 is the structural schematic diagram of the present invention.

A novel oblique wheel sorting machine comprises a machine table 1, a belt conveying mechanism 2, rollers 3, a roller rotation driving mechanism 4, a driving transmission roller 5, driven transmission rollers 6, a motor 7, an O-shaped belt 8, synchronizing wheels 9 and a synchronous belt 10, wherein the belt conveying mechanism 2 is installed on the machine table, a plurality of rollers 3 with end surfaces parallel to each other are rotatably connected on the machine table 1, a plurality of driven transmission rollers 6 and one driving transmission roller 5 are rotatably connected on the machine table 1, the driving transmission roller 5 is parallel to all the driven transmission rollers 6, the driving transmission rollers 5 and the driven transmission rollers 6 are respectively connected with a plurality of rollers 3 with the circle centers in the same straight line through the O-shaped belt 8, the synchronizing wheels 9 are fixed at both ends of the driving transmission rollers 5 and the driven transmission rollers 6, the motor 7 is fixed at the bottom end of the machine table 1, the synchronizing wheels at one end of the driving transmission rollers 5 are connected with an output shaft of, the other end is connected with a synchronizing wheel 9 at one end of each adjacent driven transmission roller 6 through a synchronizing belt 10, the synchronizing wheels 9 at the same side of the two adjacent driven transmission rollers 6 are meshed in one synchronizing belt 10, the synchronizing wheel 9 at one end of each driven transmission roller 6 adjacent to the belt conveying mechanism 2 is connected with the belt conveying mechanism 2 through the synchronizing belt 10, a roller rotation driving mechanism 4 is installed in the machine table 1, and the roller rotation driving mechanism 4 is connected with all rollers 3 on the machine table 1.

As shown in fig. 4, a connecting plate 11 is fixed in the machine table 1, a plurality of arc-shaped grooves 12 are formed in the connecting plate 11, shaft holes 13 are fixed in the arc-shaped grooves 12, the rollers 3 are rotatably connected to the support 14, a shaft rod at the bottom end of the support 14 penetrates through the shaft holes 13, and the O-shaped belt 8 penetrates through the arc-shaped grooves 12.

As shown in fig. 3, the roller rotation driving mechanism 4 comprises a rotating motor 41, a cam 42, a movable frame 43 and a connecting rod 44, the rotating motor 41 is fixed in the machine table 1, the cam 42 is fixed on an output shaft of the rotating motor 41, a pin shaft is fixed on an end surface of the cam 42, the pin shaft penetrates through the movable frame 43, two sides of the movable frame 43 are respectively embedded into sliding grooves in the inner wall of the machine table 1, the movable frame 43 is hinged with a plurality of connecting rods 44, and the connecting rods 44 are fixed with a shaft rod at the bottom end of the support 14. The belt conveying mechanism 2 is composed of a conveying belt 21 and rotating rollers 22, the two rotating rollers 22 which are parallel to each other are rotatably connected to the machine table 1, one end of one of the rotating rollers 22 is fixed with a synchronizing wheel 9, the synchronizing wheel 9 on the rotating roller 22 is connected with the synchronizing wheel 9 on one driven driving roller 6 through a synchronous belt 10, and the two rotating rollers 22 are attached to the conveying belt 21.

Referring to fig. 1 and 2, a plurality of rollers 3 are arranged in a rectangular array. The driving rollers 5 are connected with a row of idler wheels 3 through O-shaped belts 8, and each driven roller 6 is connected with a row of idler wheels 3 through the O-shaped belts 8. A plurality of annular grooves are formed in the driving transmission roller 5 and the driven transmission roller 6, and an O-shaped belt 8 is embedded into one annular groove. An annular groove is formed in the middle of the roller 3, and an O-shaped belt 8 is embedded into the annular groove in the roller 3.

Show in attached figure 1 and attached figure 2 that the quantity of driven driving roller 6 is 5, the output shaft that 5 axle heads of the initiative driving roller that are located the 1 front side of board pass through the belt and motor 7, 6 axle heads of first driven driving roller that are located the 1 front side of board link together through hold-in range 10 with the 6 axle heads of second driven driving roller, 6 axle heads of third driven driving roller link together through hold-in range 10 with the 6 axle heads of fourth driven driving roller, the 6 axle heads of fifth driven driving roller link together through the axle head of hold-in range 10 with a commentaries on classics roller 22.

As shown in the attached drawing 5, the shaft end of the driving roller 5 located at the rear side of the machine table 1 is connected with the shaft end of the first driven roller 6 located at the rear side of the machine table 1 through the synchronous belt 10, the shaft end of the second driven roller 6 located at the rear side of the machine table 1 is connected with the shaft end of the third driven roller 6 through the synchronous belt 10, and the shaft end of the fourth driven roller 6 is connected with the shaft end of the fifth driven roller 6 through the synchronous belt 10.

When the motor 7 is started, the rotating output shaft drives the driving rollers 5 through the belt, and the driving rollers 5 drive all the driven rollers 6 to rotate through the synchronous belt 10. The friction force when the rotating driving roller 5 and the driven roller 6 are driven by the O-shaped belt 8 drives the roller 3 to rotate along the bracket 14. All the rollers 3 are in the same direction, the rollers 3 are arranged according to a rectangular array to form a complete transmission surface, articles are placed on the transmission surface, and the articles can be transmitted by utilizing the friction force of the rotating rollers 3.

The rotating driven roller 6 drives the rollers 22 to rotate through the synchronous belt 10, the two rollers 22 are tensioned on the conveying belt 21, and the rollers 22 drive the conveying belt 21 to drive by friction. The conveyor belt 21 drives the object placed thereon in the direction of the rollers 3 by friction.

As shown in fig. 3, the roller rotation driving mechanism 4 operates such that an output shaft of a motor 41 drives a cam 42 to rotate, the cam 42 is connected to a movable frame 43 through a pin, the cam 42 drives the pin to rotate eccentrically, and thus the rotating cam 42 drives the movable frame 43 to swing on a horizontal plane. The two sides of the movable frame 43 are respectively arranged in the horizontal grooves of the two side plates of the machine table 1, so that the movable frame 43 can swing to a certain degree in the horizontal grooves of the two side plates of the machine table 1. The movable frame 43 is connected with the shaft rod at the bottom of the bracket 14 through the connecting rod 44, when the movable frame 43 swings in an arc shape, the bracket 14 is driven to rotate along the shaft hole 13 on the connecting plate 11 through the connecting rod 44, and the movable frame 43 is connected with all the brackets 14, so that all the rollers 3 can be driven to perform synchronous direction adjustment. The O-belt 8 can be twisted along the arc-shaped slot 12 on the web 11 when the roller 3 is rotated.

This application orders about all gyro wheels 3 and band feeding mechanism 2 through a motor 7 and conveys, has realized the conveying and the reposition of redundant personnel of article on a sorting machine, and need not increase alone like current sorting machine and carry the platform. Thereby simplifying the structure and saving the cost.

In light of the foregoing, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (4)

1. A novel oblique wheel sorting machine is characterized by comprising a machine table (1), a belt conveying mechanism (2), rollers (3), a roller rotation driving mechanism (4), a driving transmission roller (5), a driven transmission roller (6), a motor (7), an O-shaped belt (8), synchronizing wheels (9) and a synchronous belt (10), wherein the belt conveying mechanism (2) is installed on the machine table, the machine table (1) is rotatably connected with the rollers (3) with mutually parallel end surfaces, the machine table (1) is rotatably connected with a plurality of driven transmission rollers (6) and one driving transmission roller (5), the driving transmission rollers (5) are mutually parallel with all the driven transmission rollers (6), the driving transmission rollers (5) and the driven transmission rollers (6) are respectively connected with the rollers (3) with a plurality of circle centers in the same straight line through the O-shaped belt (8), and the synchronizing wheels (9) are fixed at two ends of the driving transmission rollers (5) and the driven transmission rollers (6), the bottom end of the machine table (1) is fixed with a motor (7), a synchronizing wheel at one end of the driving transmission roller (5) is connected with an output shaft of the motor (7) through a belt, the other end of the driving transmission roller is connected with a synchronizing wheel (9) at one end of the adjacent driven transmission roller (6) through a synchronous belt (10), the two adjacent driven transmission rollers (6) are meshed with the synchronizing wheel (9) at the same side of the belt (10), the driven transmission roller (6) adjacent to the belt conveying mechanism (2) is connected with the belt conveying mechanism (2) through the synchronous belt (10), a roller rotation driving mechanism (4) is installed in the machine table (1), and all rollers (3) on the roller rotation driving mechanism (4) and the machine table (1) are connected.

2. The new inclined wheel sorter of claim 1 wherein: the machine table (1) is internally fixed with a connecting plate (11), a plurality of arc-shaped grooves (12) are formed in the connecting plate (11), shaft holes (13) are formed in the arc-shaped grooves (12), the idler wheels (3) are rotatably connected to the support (14), a shaft rod at the bottom end of the support (14) penetrates through the shaft holes (13), and the O-shaped belt (8) penetrates through the arc-shaped grooves (12).

3. The new inclined wheel sorter of claim 1 wherein: the roller wheel rotation driving mechanism (4) is composed of a rotating motor (41), a cam (42), a movable frame (43) and a connecting rod (44), the rotating motor (41) is fixed in the machine table (1), the cam (42) is fixed on an output shaft of the rotating motor (41), a pin shaft is fixed on the end face of the cam (42), the pin shaft penetrates through the movable frame (43), two sides of the movable frame (43) are respectively embedded into sliding grooves in the inner wall of the machine table (1), a plurality of connecting rods (44) are hinged to the movable frame (43), and the connecting rods (44) are fixed together with a shaft rod at the bottom end of the support (14).

4. The new inclined wheel sorter of claim 1 wherein: the belt conveying mechanism (2) is composed of a conveying belt (21) and rotating rollers (22), the two rotating rollers (22) which are parallel to each other are rotatably connected to the machine table (1), one end of one of the rotating rollers (22) is fixed with a synchronizing wheel (9), the synchronizing wheel (9) on the rotating roller (22) is connected with the synchronizing wheel (9) on one driven transmission roller (6) through a synchronous belt (10), and the two rotating rollers (22) are attached to the conveying belt (21).

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