CN220574746U - Printer spindle feeding device - Google Patents

Abstract

The utility model relates to the technical field of shaft core processing, in particular to a feeding device for a shaft core of a printer, which comprises a base, fixed plates arranged at two ends of the base, a storage bin arranged between the two fixed plates, a guide chute, a feeding mechanism and a pushing mechanism, wherein the storage bin, the guide chute and the feeding mechanism are arranged on the base, the storage bin and the guide chute are positioned between the feeding mechanism, the discharging end of the storage bin is inclined towards the direction of the feeding mechanism, a positioning groove is formed in the bottom of the guide chute, the feeding mechanism is arranged on the outer wall of the guide chute in a sliding manner, and the feeding mechanism comprises a lifting groove, a feeding block arranged in the lifting groove and a jacking component for jacking the feeding block; the utility model solves the problems of long time consumption, high labor intensity, low production efficiency and unstable product output of the traditional manual feeding mode by mutually matching the storage bin, the material guide groove, the feeding mechanism and the pushing mechanism.

Description

Printer spindle feeding device

Technical Field

The utility model relates to the technical field of shaft core processing, in particular to a feeding device for a shaft of a printer.

Background

Printers are one of office equipment and are used in many places, and the shaft core is one of the important components inside the printer, and the shaft core of the printer is usually in a long cylindrical rod shape. In the process of machining the shaft core of the printer, raw materials need to be transferred to a machining lathe, one end of the raw materials are clamped and fixed by using a polishing device or a turning tool and then are machined, the raw materials of the shaft core of the printer are manually fed in a traditional polishing or cutting mode, the operation mode is long in time consumption, a large amount of manpower resources are needed, the cost is increased along with the operation mode, in addition, the stability of the raw material transmission of the shaft core is also affected to a certain extent by the traditional feeding mode, and finally, the quality of the machined shaft core is uneven.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides a feeding device for a printer shaft core, which aims to solve the problems of long time consumption, high labor intensity, low production efficiency and unstable product output in the traditional manual feeding mode.

In order to achieve the technical purpose, the utility model provides the following technical scheme: the utility model provides a printer axle core material feeding unit, includes the base, sets up fixed plate at the base both ends, sets up storage silo, baffle box, feeding mechanism and pushing equipment between two fixed plates, storage silo, baffle box and feeding mechanism all set up on the base, storage silo and baffle box are located between the feeding mechanism, and the unloading end of storage silo inclines to feeding mechanism's direction, and the constant head tank has been seted up to the bottom of baffle box, and feeding mechanism slides and sets up on the outer wall of baffle box, feeding mechanism includes the lift groove, sets up the feed block in the lift groove and the jacking subassembly with the feed block jack-up, the top surface of feed block is the inclined plane of baffle box direction slope, and the jacking subassembly sets up in the lift groove and is located the bottom of feed block, the jacking subassembly includes the pivot, sets up a plurality of cams of pivot and the rotatory jacking actuating assembly of actuating shaft, the bottom of feed block is provided with the recess with cam quantity looks adaptation, all install the gyro wheel in the recess, the gyro wheel is inconsistent with the cam, the opposite side setting up at the baffle box including pushing equipment and pushing equipment.

Further, the jacking driving assembly comprises a driving motor and a driven bevel gear fixedly arranged at the end part of the rotating shaft, and a driving bevel gear meshed with the driven bevel gear is arranged at the output end of the driving motor.

Further, a limiting block is arranged on the outer wall of the guide chute along the lifting direction of the feeding block, and a limiting groove matched with the limiting block is arranged on the feeding block.

Further, a plurality of balls are arranged on the outer wall of the guide chute along the lifting direction of the feeding block, a groove is formed in the feeding block, and the balls are located in the groove.

Furthermore, the end face of the opening end of the guide chute is an inclined face, and the inclination angle of the inclined face is the same as that of the top face of the feeding block.

Further, the pushing driving assembly comprises a screw rod, a thread block arranged on the screw rod and a motor arranged on the outer side of the fixed plate, one end of the screw rod penetrates through the fixed plate to be connected with the motor, and the outer wall of the thread block is connected with the pushing rod through a connecting plate.

Compared with the prior art, the utility model has the beneficial effects that: the utility model has novel structure, ingenious conception and simple and convenient operation, and has the following advantages compared with the prior art: according to the utility model, the raw materials of the shaft cores are orderly placed in the storage bin in batches, the driving motor drives the cam to rotate, so that the feeding block reciprocates along the outer wall of the guide chute, when the feeding block moves to the lowest position, the feeding block transfers the shaft cores in the storage bin to the inclined plane of the feeding block, when the feeding block moves to the highest position, the raw materials of the shaft cores are slid into the guide chute, and the pushing rod pushes the raw materials of the shaft cores to a lathe to be processed for subsequent processing.

Drawings

FIG. 1 is a schematic view of the feeding state of the present utility model;

FIG. 2 is a schematic view of the structure of the present utility model in an unfeeded state;

FIG. 3 is a front cross-sectional view of the present utility model;

FIG. 4 is an enlarged view of the structure of the present utility model at A;

fig. 5 is an enlarged view of the structure at B of the present utility model.

In the figure, 1, a base; 2. a fixing plate; 3. a storage bin; 4. a guide groove; 5. a feeding mechanism; 501. a lifting groove; 502. a feed block; 503. a rotating shaft; 504. a cam; 505. a groove; 506. a roller; 507. a driving motor; 508. a driven bevel gear; 509. a drive bevel gear; 510. a limiting block; 511. a limit groove; 512. a ball; 513. a chute; 6. a pushing mechanism; 601. a pushing rod; 602. a screw; 603. a screw block; 604. a motor; 7. and a positioning groove.

Detailed Description

The following are specific embodiments of the present utility model, and the technical solutions of the present utility model are further described with reference to the accompanying drawings, but the present utility model is not limited to these embodiments.

As shown in fig. 1-3, the utility model provides a feeding device for a shaft core of a printer, which comprises a base 1, fixed plates 2 arranged at two ends of the base 1, a storage bin 3 arranged between the two fixed plates 2, a guide chute 4, a feeding mechanism 5 and a pushing mechanism 6, wherein the storage bin 3, the guide chute 4 and the feeding mechanism 5 are all arranged on the base 1, the storage bin 3 and the guide chute 4 are positioned between the feeding mechanism 5, the discharging end of the storage bin 3 inclines towards the feeding mechanism 5, a positioning groove 7 is formed in the bottom of the guide chute 4, the positioning groove can enable the shaft core raw material to be stably placed in the guide chute 4, lateral movement of the shaft core raw material is prevented during pushing, stability during pushing is improved, the feeding mechanism 5 is slidably arranged on the outer wall of the guide chute 4, the feeding mechanism 5 comprises a lifting groove 501, a feeding block 502 arranged in the lifting groove 501, a lifting assembly for lifting the feeding block 502, the top surface of the guide chute 4 is an inclined surface, the lifting assembly is arranged in the lifting groove 501, the bottom of the lifting assembly is positioned at the lifting groove, the lifting assembly is arranged at the other side of the lifting assembly, the lifting assembly is arranged at the bottom of the lifting groove 503, the lifting assembly is arranged at the other side of the lifting assembly, the lifting assembly and is provided with a plurality of cams 505, the lifting assembly and is arranged at the lifting assembly 503, and is provided with the number of the lifting assembly 503, and is provided with the driving shafts 506 and the lifting assembly and is provided with the cams and 503.

As shown in fig. 1 and 2, before feeding begins, a lot of raw materials with axle cores are put in the storage bin 3 in order, when feeding begins, the driving component drives the cams 504 on the rotating shaft 503 to rotate, the cams 504 always contact with the rollers 506 installed at the bottom of the feeding block 502 when rotating, when the feeding block 502 is lowered to the lowest point by the cams 504 in the lifting groove 501, the highest point of the top surface of the feeding block 502 is slightly lower than the discharging port of the storage bin 3, so that the raw materials with axle cores near the discharging port of the storage bin 3 fall into the top surface of the feeding block 502, and because the top surface of the feeding block 502 is obliquely arranged, the raw materials with axle cores can be close to the direction of the guide groove 4 when the top surface of the feeding block 502, only one raw material with axle cores can be placed on the width of the top surface of the feeding block 502, the cams 504 continuously rotate to move the feeding block 502 to the highest point along the guide groove 4, and the raw materials with axle cores on the top surface of the feeding block 502 fall into the guide groove 4, and the pushing component drives the axle cores 601 to reach the processing area, thus completing automatic feeding operation of axle cores.

The jacking driving assembly comprises a driving motor 507 and a driven bevel gear 508 fixedly arranged at the end part of the rotating shaft 503, wherein a driving bevel gear 509 meshed with the driven bevel gear 508 is arranged at the output end of the driving motor 507.

As shown in fig. 1, the driving motor 507 drives the driving bevel gear 509 to rotate, and the driving bevel gear 509 drives the driven bevel gear 508 to rotate, thereby driving the rotating shaft 503 fixedly connected with the driven bevel gear 508 to rotate.

Limiting blocks 510 are arranged on the outer wall of the guide chute 4 along the lifting direction of the feeding block 502, and limiting grooves 511 matched with the limiting blocks 510 are formed in the feeding block 502.

As shown in fig. 3, the limiting block 510 on the outer wall of the guide chute 4 is installed in the limiting groove 511 on the outer wall of the feeding block 502, so that the linear movement direction of the feeding block 502 is ensured, and the stability of the feeding block 502 is improved.

A plurality of balls 512 are arranged on the outer wall of the guide chute 4 along the lifting direction of the feeding block 502, a chute 513 is arranged on the feeding block 502, and the balls 512 are positioned in the chute 513.

As shown in fig. 3, the balls 512 may increase the mobility of the feedblock 502.

The end face of the opening end of the guide chute 4 is an inclined face, and the inclination angle of the inclined face is the same as that of the top face of the feeding block 502.

As shown in fig. 2, the purpose of the inclined design of the open end face of the guide chute 4 is to facilitate the raw material of the shaft core on the feed block 502 to fall into the guide chute 4 along the inclined face.

The pushing driving assembly comprises a screw 602, a threaded block 603 arranged on the screw 602 and a motor 604 arranged on the outer side of the fixed plate 2, one end of the screw 602 penetrates through the fixed plate 2 to be connected with the motor 604, and the outer wall of the threaded block 603 is connected with the pushing rod 601 through a connecting plate.

As shown in fig. 1, the pushing rod 601 performs reciprocating linear motion along the screw direction along with the rotation of the screw 602, so as to realize the pushing work of the shaft core raw material.

The use principle is as follows: before feeding begins, a batch of axle core raw materials are orderly placed in the storage bin 3, when feeding begins, a driving motor 507 is started, a driving motor 506 drives a plurality of cams 504 on a rotating shaft 503 to rotate, the cams 504 always contact with rollers 506 arranged at the bottom of a feeding block 502 when rotating, when the feeding block 502 is lowered to the lowest point by the cams 504 in a lifting groove 501, the axle core raw materials near a discharging port of the storage bin 3 fall onto the top surface of the feeding block 502, the cams 504 continue to rotate to move the feeding block 502 to the highest point along a guide groove 4, the axle core raw materials which are positioned on the top surface of the feeding block 502 and near the guide groove 4 fall into the guide groove 4, a motor 604 is started, a pushing rod 601 is driven to move along the direction of a screw 602, and the axle core raw materials are pushed to reach a processed area, so that automatic feeding operation of the axle core is completed.

The specific embodiments described herein are offered by way of example only to illustrate the spirit of the utility model. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions, without departing from the spirit of the utility model or exceeding the scope of the utility model as defined in the accompanying claims.

Claims (6)

1. The utility model provides a printer axle core material feeding unit, includes base (1), sets up fixed plate (2) at base (1) both ends, its characterized in that: still including setting up storage silo (3), baffle box (4), feeding mechanism (5) and pushing mechanism (6) between two fixed plates (2), storage silo (3), baffle box (4) and feeding mechanism (5) all set up on base (1), storage silo (3) and baffle box (4) are located between feeding mechanism (5), and constant head tank (7) have been seted up to the bottom of baffle box (4), and feeding mechanism (5) slide and set up on the outer wall of baffle box (4), feeding mechanism (5) include lift groove (501), feed block (502) of setting in lift groove (501) and with feed block (502) jack-up jacking component, the top surface of feed block (502) is the inclined plane of baffle box (4) direction slope, jacking component sets up in lift groove (501) and is located the bottom of feed block (502), jacking component includes pivot (503), sets up a plurality of cams (504) and drive block (506) on pivot (503) rotatory, the quantity of the corresponding cams (506) of drive block (506) in the pivot (503) is provided with in the recess (505), the quantity of the cams (505) are all installed in the recess (505), the pushing mechanism (6) is arranged on the other side of the guide chute (4), and the pushing mechanism (6) comprises a pushing rod (601) and a pushing driving assembly.

2. The printer spindle feed apparatus of claim 1, wherein: the jacking driving assembly comprises a driving motor (507) and a driven bevel gear (508) fixedly arranged at the end part of the rotating shaft (503), and a driving bevel gear (509) meshed with the driven bevel gear (508) is arranged at the output end of the driving motor (507).

3. The printer spindle feed apparatus of claim 1, wherein: limiting blocks (510) are arranged on the outer wall of the guide groove (4) along the lifting direction of the feeding block (502), and limiting grooves (511) matched with the limiting blocks (510) are formed in the feeding block (502).

4. A printer spindle feed apparatus as claimed in claim 3, wherein: a plurality of balls (512) are arranged on the outer wall of the guide chute (4) along the lifting direction of the feeding block (502), a chute (513) is formed in the feeding block (502), and the balls (512) are located in the chute (513).

5. The printer spindle feed apparatus of claim 1, wherein: the end face of the opening end of the guide chute (4) is an inclined face, and the inclined angle of the inclined face is the same as that of the top face of the feeding block (502).

6. The printer spindle feed apparatus of claim 1, wherein: the pushing driving assembly comprises a screw (602), a thread block (603) arranged on the screw (602) and a motor (604) arranged on the outer side of the fixed plate (2), one end of the screw (602) penetrates through the fixed plate (2) to be connected with the motor (604), and the outer wall of the thread block (603) is connected with the pushing rod (601) through a connecting plate.