CN113879758A - Transfer device is used in cutter production with collision protection - Google Patents

Abstract

The invention relates to the technical field of cutter processing, in particular to a transfer device with collision protection for cutter production, which comprises a shell, a spindle motor and a spindle, wherein the shell is provided with a plurality of clamping grooves; the built-in cavity is arranged in the shell, the main shaft is arranged in the built-in cavity, two ends of the main shaft are connected with the shell in a rotating mode through bearings, one end of the main shaft is connected with an output shaft of the main shaft motor, and the main shaft motor is fixed on the outer wall of the shell through a motor support. It can play certain guard action in the cutter processing transportation, avoids the collision between cutter and the cutter to and avoid the cutter to accidentally injure the staff, improve the security that the cutter transported greatly.

Description

Transfer device is used in cutter production with collision protection

Technical Field

The invention relates to the technical field of cutter processing, in particular to a transferring device with collision protection for cutter production.

Background

The machining of the tool involves forging, cutting, edging, grinding, polishing and the like, which are not generally all performed in the same production facility, and therefore, a transfer device is required to transfer the tool from the previous process to the next process. Because it has certain danger in its existence of cutter after the edging, when transporting improper, the collision of cutter causes personnel's injury easily, and present transfer device does not have the safeguard measure, can not avoid the injury that the cutter collision caused.

Disclosure of Invention

The invention aims to overcome the defects and shortcomings of the prior art, and provides a transferring device with collision protection for cutter production, which can play a certain protection role in the cutter processing and transferring process, avoid collision between cutters, avoid accidental injury of workers by the cutters, and greatly improve the safety of cutter transfer.

In order to achieve the purpose, the invention adopts the following technical scheme: it comprises a shell, a spindle motor and a spindle; a built-in cavity is formed in the shell, the main shaft is arranged in the built-in cavity, two ends of the main shaft are connected with the shell in a rotating mode through bearings, one end of the main shaft is connected with an output shaft of a main shaft motor, and the main shaft motor is fixed on the outer wall of the shell through a motor support; it also includes:

the two T-shaped plates are symmetrically sleeved and fixed on the main shaft;

the cover plate is connected with the left T-shaped plate and the right T-shaped plate which are symmetrically arranged and is fixed on the lateral plate side wall of the T-shaped plate;

the three roller mounting plates are respectively fixed on two ends of the transverse plate and the longitudinal plate of one T-shaped plate;

the three motor mounting plates are respectively fixed on two ends of the transverse plate and the longitudinal plate of the other T-shaped plate; the motor mounting plate and the roller mounting plate are symmetrically arranged left and right;

the rotating motor is fixed in the motor mounting plate;

one end shaft of the driving roller is fixed on an output shaft of the rotating motor, and the other end shaft of the driving roller is screwed on the side wall of the motor mounting plate by using a bearing;

the driven roller is screwed in the roller mounting plate by using bearings on shafts at two ends of the driven roller;

the two ends of the conveying belt are sleeved on the driving roller and the driven roller respectively;

adsorb the magnet layer, adsorb the magnet layer be two, and polarity is opposite, its relatively fixed is seted up on the inner wall of the race on the conveyer belt area face.

Preferably, the shell diapire has been seted up and has been stepped down the groove, and this step down the inslot activity and be provided with moving mechanism, this moving mechanism contains:

the lifting push rod is fixed on the shell positioned below the built-in cavity;

the roller mounting base plate is fixed at the output end of the lifting push rod, and two sides of the roller mounting base plate are movably guided up and down in guide groove bodies arranged on two sides of the abdicating groove;

the rollers are fixed at the bottom of the roller mounting base plate at equal intervals.

Preferably, the attracting magnet layer is replaced with a tool holder, the tool holder is fixed in the belt groove, and the tool holder includes:

the belt type cutting tool comprises a tool clamp body, wherein one end of the tool clamp body, which is connected with a belt groove, is of an arc-shaped structure, and a tool clamp groove is formed in the other end of the tool clamp body;

the positioning column is movably inserted in the cutter clamp body positioned on one side of the cutter clamp groove;

the spring is sleeved on the positioning column, and two ends of the spring are respectively abutted against the outer end cap of the positioning column and the side wall of the cutter clamp body;

the movable adsorption magnetic block is fixed on the positioning column;

and the fixed adsorption magnetic block is embedded and fixed in the inner wall of the cutter clamping groove and has opposite polarity to the movable adsorption magnetic block.

Preferably, a cleaning mechanism is fixed on the rotating shaft 11 and arranged between the left and right T-shaped plates; the cleaning mechanism includes:

one end of the connecting column is clamped and fixed in a jack arranged on the annular wall of the rotating shaft 11 by utilizing a clamping bead embedded in the connecting column;

the brush mounting plate is fixed at the other end of the connecting column;

the brush is fixed on the brush mounting plate.

Preferably, a plurality of chip removal holes are vertically formed in the bottom wall of the built-in cavity in a penetrating mode, and a pull-out tray is movably inserted into the shell below the chip removal holes.

The working principle of the invention is as follows: after the cutter is processed in the previous process, manually inserting the cutters into the belt grooves in the conveying belt one by one, enabling the cutters to be adsorbed and fixed on the conveying belt on the adsorption magnet layers which are arranged oppositely, meanwhile, enabling the rotating motor to work to drive the driving roller to rotate, enabling the driving roller to drive the driven roller to rotate by utilizing the conveying belt, enabling the cutters to rotate downwards under the rotation of the conveying belt, starting the main shaft motor to work after one conveying belt is filled with the cutters, driving the T-shaped plate to rotate, enabling the conveying belt without the cutters to be arranged above the built-in cavity, stopping the main shaft motor, repeating the cutter placing work until the conveying belt is filled with the cutters, starting the main shaft motor to work again, repeating the rotation of the T-shaped plate and the cutter placing work, and starting the main shaft motor to work after all the conveying belts are filled with the cutters, the T-shaped plate is driven to rotate, so that the cover plate connected to the lateral wall of the T-shaped plate is horizontally arranged on the built-in cavity, and the cutters on the conveying belt are all built in the built-in cavity and are covered by the cover plate;

when a next procedure is needed, only the spindle motor needs to be started to drive the T-shaped plate to rotate, so that the conveying belt rotates to the position above the built-in cavity, the cutter is manually pulled out of the belt groove at the moment, and the cutter on the conveying belt is sequentially taken out to perform the next procedure under the work of the rotating motor.

Compared with the prior art, the invention has the beneficial effects that: the invention provides a transferring device with collision protection for cutter production, which can play a certain protection role in the cutter processing and transferring process, avoid collision between cutters, avoid accidental injury of workers by the cutters and greatly improve the safety of cutter transfer.

Description of the drawings:

fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a left side view of fig. 1.

Fig. 3 is a sectional view taken along line a-a in fig. 2.

FIG. 4 is a schematic structural view of a "T" -shaped plate, a conveyor belt, a driving roller, a driven shaft, a motor mounting plate, and a roller mounting plate according to the present invention.

Fig. 5 is a left side view of fig. 4.

Fig. 6 is a top view of fig. 4.

FIG. 7 is a schematic view showing the position of the attracted magnet layer in the present invention.

Figure 8 is a schematic view of the position of the tool holder of the present invention.

Fig. 9 is a schematic view of the construction of the tool holder of the present invention.

FIG. 10 is a schematic view of the cleaning mechanism of the present invention.

FIG. 11 is a view of the present invention fully loaded with cutters built into the built-in cavity.

Description of reference numerals:

the cutting tool comprises a shell 1, a built-in cavity 1-1, abdicating grooves 1-2, chip removing holes 1-3, a roller mounting plate 2, a driven roller 3, a cover plate 4, a conveying belt 5, a belt groove 5-1, a driving roller 6, a motor mounting plate 7, a T-shaped plate 8, a longitudinal plate 8-1, a transverse plate 8-2, a spindle motor 9, a rotating motor 10, a spindle 11, an adsorption magnet layer 12, a tool clamp 13, a tool clamp body 13-1, a fixed adsorption magnet 13-2, a tool clamp groove 13-3, a movable adsorption magnet 13-4, a positioning column 13-5, a spring 13-6, a cleaning mechanism 14, a brush mounting plate 14-1, a connecting column 14-2, a brush 14-3, a clamping bead 14-4, a moving mechanism 15, a lifting push rod 15-1, a roller mounting bottom plate 15-2, a roller 15-3, a roller, A pull tray 16.

The specific implementation mode is as follows:

the technical solution of the present invention will be clearly and completely described below with reference to the accompanying drawings, and the preferred embodiments in the description are only examples, and all other embodiments obtained by those skilled in the art without any inventive work belong to the protection scope of the present invention.

The first embodiment is as follows:

as shown in fig. 1 to 7 and fig. 10 to 11, the following technical solutions are adopted in the present embodiment: it comprises a shell 1, a spindle motor 9 and a spindle 11; a built-in cavity 1-1 is formed in the shell 1, a main shaft 11 is arranged in the built-in cavity 1-1, two ends of the main shaft 11 are rotatably connected with the shell 1 through bearings, one end of the main shaft 11 is connected with an output shaft of a main shaft motor 9, and the main shaft motor 9 is fixed on the outer wall of the shell 1 through a motor support; it also includes:

the two T-shaped plates 8 are symmetrically sleeved and fixed on the main shaft 11 in a riveting manner through bolts;

the cover plate 4 is connected with the left T-shaped plate 8 and the right T-shaped plate 8 which are symmetrically arranged, and is welded and fixed on the side wall of the transverse plate 8-2 of the T-shaped plate 8;

the number of the roller mounting plates 2 is three, the roller mounting plates 2 are used for mounting the driven roller 3, and the driven roller is riveted and fixed to two ends of a transverse plate 8-2 and a longitudinal plate 8-1 of one T-shaped plate 8 through screws respectively;

the number of the motor mounting plates 7 is three, mounting supports are provided for the rotating motor 10, and the motor mounting plates are respectively riveted and fixed to two ends of the transverse plate 8-2 and the longitudinal plate 8-1 of the other T-shaped plate 8 by using screws; the motor mounting plate 7 and the roller mounting plate 2 are symmetrically arranged left and right;

a rotary motor 10 as a power transmission drive mechanism of the conveyor belt 5, which is fixed in the motor mounting plate 7 by riveting with bolts;

a driving roller 6 as a driving part for installing and supporting the transmission belt 5, wherein one end shaft of the driving roller is fixed on an output shaft of the rotating motor 10 by a coupler, and the other end shaft of the driving roller 6 is screwed on the side wall of the motor installing plate 7 by a bearing;

a driven roller 3 as a driven member for mounting and supporting the conveyor belt 5, which is screwed into the roller mounting plate 2 by bearings on both end shafts thereof;

the conveying belt 5 is used as a main body component for placing the cutter, and two ends of the conveying belt are respectively sleeved on the driving roller 6 and the driven roller 3 to provide a placing position for the cutter;

the two attracting magnet layers 12 are used as structural components for positioning the cutter, have opposite polarities and are relatively fixed on the inner wall of a belt groove 5-1 formed on the belt surface of the conveying belt 5 by screws.

Preferably, the bottom wall of the housing 1 is provided with a yielding groove 1-2, a moving mechanism 15 is movably disposed in the yielding groove 1-2, and the moving mechanism 15 includes:

the lifting push rod 15-1 is an electric push rod, and the lifting push rod 15-1 is embedded and riveted and fixed on the shell 1 below the built-in cavity 1-1 by using a bolt;

the roller mounting base plate 15-2 is fixed at the output end of the lifting push rod 15-1, and two sides of the roller mounting base plate 15-2 are movably arranged in guide groove bodies arranged on two sides of the abdicating groove 1-2 in an up-and-down guiding manner;

the number of the rollers 15-3 is several, and the rollers 15-3 are all universal wheels with wheel locks, and the rollers 15-3 are fixed at the bottom of the roller mounting base plate 15-2 at equal intervals.

Preferably, a cleaning mechanism 14 is fixed on the rotating shaft 11, and the cleaning mechanism 14 is arranged between the left and right T-shaped plates 8; the cleaning mechanism 14 includes:

one end of the connecting column 14-2 is clamped and fixed in a jack arranged on the annular wall of the rotating shaft 11 by utilizing a clamping bead 14-4 embedded in the connecting column 14-2, and the mounting and the dismounting can be completed by only using little force;

the brush mounting plate 14-1 is welded and fixed at the other end of the connecting column 14-2;

the brush 14-3 is fixed on the brush mounting plate 14-1 in an adhesive manner;

a plurality of chip removal holes 1-3 are vertically arranged on the bottom wall of the built-in cavity 1-1 in a penetrating way, and a pull-out tray 16 is movably inserted in the shell 1 below the chip removal holes 1-3.

The working principle of the specific embodiment is as follows: all electric control elements in the whole equipment are electrically connected with a mobile power supply (not shown in the figure) arranged in the built-in cavity 1-1, after the cutter is processed in the previous process, the cutter is manually inserted into a belt groove 5-1 in the conveying belt 5 one by one, the cutter is adsorbed and fixed on the conveying belt 5 by an adsorption magnet layer 12 which is oppositely arranged, meanwhile, a rotating motor 10 works to drive a driving roller 6 to rotate, the driving roller 6 drives a driven roller 3 to rotate by utilizing the conveying belt 5, the cutter rotates downwards under the rotation of the conveying belt 5, when the conveying belt 5 is fully filled with the cutter, a main shaft motor 9 is started to work so as to drive a T-shaped plate 8 to rotate, the conveying belt 5 which is not provided with the cutter is arranged to the upper part of the built-in cavity 1-1, the main shaft motor 9 is stopped, and the cutter placing work is repeated until the conveying belt 5 is fully filled with the cutter, the spindle motor 9 is started again to work, the rotation of the T-shaped plate 8 and the operation of placing the cutter are repeated, when all the conveying belts 5 are fully placed with cutters, the spindle motor 9 is started to work to drive the T-shaped plate 8 to rotate, so that the cover plate 4 connected to the side wall of the transverse plate 8-2 of the T-shaped plate 8 is horizontally arranged on the built-in cavity 1-1, and the cutters on the conveying belts 5 are all built in the built-in cavity 1-1 and are covered by the cover plate 4; in the whole cutter placing process, a cutter placed on the conveying belt 5 is in contact with a cleaning mechanism 14 fixed on the main shaft 11, at the moment, the cutter brushes chips remained on the cutter in the previous process through a brush 14-3, the chips fall into a pull-out tray 16 through chip removal holes 1-3, and the pull-out tray 16 can be drawn out to intensively clean the chips at any time;

when the workpiece needs to be moved to the next station and processed, the moving mechanism 15 is started at the moment, the lifting push rod 15-1 works to push the roller mounting bottom plate 15-2 out of the abdicating groove 1-2, at the moment, a plurality of rollers 15-3 are exposed, the whole workpiece can be moved, when the workpiece needs to be moved to the required station, the spindle motor 9 is started to drive the T-shaped plate 8 to rotate, the conveying belt 5 is enabled to rotate to the position above the built-in cavity 1-1, at the moment, the cutter is manually pulled out of the belt groove 5-1, and the cutter on the conveying belt 5 is sequentially taken out under the work of the rotating motor 10 to perform the next process.

After adopting above-mentioned structure, this embodiment's beneficial effect is as follows:

1. under the action of the rotating motor, the cutter is driven to be placed in the built-in cavity, and safety problems caused by exposure of the Bieman cutter occur;

2. the cutters are inserted into the belt grooves one by one, and the cutters are limited, so that collision between the cutters is avoided, and the cutters are effectively protected;

3. the moving mechanism is arranged, so that the whole body can be conveniently carried;

4. the cleaning mechanism is arranged, so that the cutter processed in the previous process is effectively cleaned, and the machining efficiency of the cutter is improved;

5. set up the apron, effectively block that external article drops to built-in chamber in, effectively protect the cutter in the built-in chamber, can also avoid personnel's mistake to bump the injury that the cutter caused simultaneously.

The specific implementation is as follows:

referring to fig. 8 and 9, the present embodiment differs from the first embodiment in that:

the absorption magnet layer 12 is replaced by a cutter clamp 13, the cutter clamp 13 is fixed in the belt groove 5-1, and the cutter clamp 13 comprises:

the cutter clamp comprises a cutter clamp body 13-1, wherein one end of the cutter clamp body 13-1, which is riveted with a belt groove 5-1 through a bolt, is of an arc-shaped structure, and a cutter clamp groove 13-3 is formed in the other end of the cutter clamp body 13-1;

the positioning column 13-5 is movably inserted into the cutter clamp body 13-1 positioned on one side of the cutter clamp groove 13-3;

the spring 13-6 is sleeved on the positioning column 13-5, and two ends of the spring 13-6 are respectively abutted on the outer end cap of the positioning column 13-5 and the side wall of the cutter clamp body 13-1;

the movable adsorption magnetic block 13-4 is fixed on the positioning column 13-5;

the fixed adsorption magnetic block 13-2 is fixedly embedded in the inner wall of the cutter clamping groove 13-3, the polarity of the fixed adsorption magnetic block 13-2 is opposite to that of the movable adsorption magnetic block 13-4, and when a cutter is not installed, the movable adsorption magnetic block 13-4 and the fixed adsorption magnetic block 13-2 are in an adsorption state;

the positioning column 13-5 is pulled outwards, the cutter is placed in the cutter clamping groove 13-3 between the movable adsorption magnetic block 13-4 and the fixed adsorption magnetic block 13-2, then the positioning column 13-5 is loosened, the positioning column 13-5 is returned under the action of the spring 13-6, and the cutter is clamped under the adsorption action of the movable adsorption magnetic block 13-4 and the fixed adsorption magnetic block 13-2.

It will be appreciated by those skilled in the art that modifications and equivalents may be made to the embodiments described above, and that various modifications, equivalents, improvements and the like may be made without departing from the spirit and scope of the invention.

Claims (6)

1. A transfer device with collision protection for cutter production comprises a shell (1), a spindle motor (9) and a spindle (11); a built-in cavity (1-1) is formed in the shell (1), a spindle (11) is arranged in the built-in cavity (1-1), two ends of the spindle (11) are connected with the shell (1) in a rotating mode through bearings, one end of the spindle is connected with an output shaft of a spindle motor (9), and the spindle motor (9) is fixed on the outer wall of the shell (1) through a motor support;

it is characterized in that it also comprises:

the two T-shaped plates (8) are symmetrically sleeved and fixed on the main shaft (11);

the cover plate (4) is connected with the left T-shaped plate and the right T-shaped plate (8) which are symmetrically arranged and is fixed on the side wall of the transverse plate (8-2) of the T-shaped plate (8);

the number of the roller mounting plates (2) is three, and the three roller mounting plates (2) are respectively fixed on two ends of a transverse plate (8-2) and a longitudinal plate (8-1) of one T-shaped plate (8);

the number of the motor mounting plates (7) is three, and the three motor mounting plates (7) are respectively fixed on two ends of a transverse plate (8-2) and a longitudinal plate (8-1) of the other T-shaped plate (8); the motor mounting plate (7) and the roller mounting plate (2) are symmetrically arranged left and right;

the rotating motor (10), the said rotating motor (10) is fixed in motor mounting plate (7);

one end shaft of the driving roller (6) is fixed on an output shaft of the rotating motor (10), and the other end shaft of the driving roller (6) is screwed on the side wall of the motor mounting plate (7) by a bearing;

the driven roller (3) is screwed in the roller mounting plate (2) by using bearings on shafts at two ends of the driven roller (3);

the two ends of the conveying belt (5) are respectively sleeved on the driving roller (6) and the driven roller (3);

the magnetic adsorption device comprises two magnetic adsorption layers (12), wherein the magnetic adsorption layers (12) are opposite in polarity and are relatively fixed on the inner wall of a belt groove (5-1) formed in the belt surface of the conveying belt (5).

2. The transfer device with collision protection for cutter production according to claim 1, characterized in that: shell (1) diapire has been seted up and has been stepped down groove (1-2), and this step down groove (1-2) internalization is provided with moving mechanism (15), and this moving mechanism (15) contain:

the lifting push rod (15-1), the lifting push rod (15-1) is fixed on the shell (1) below the built-in cavity (1-1);

the roller mounting base plate (15-2), the roller mounting base plate (15-2) is fixed on the output end of the lifting push rod (15-1), and two sides of the roller mounting base plate (15-2) are movably arranged in guide groove bodies arranged on two sides of the abdicating groove (1-2) in an up-and-down guiding manner;

the number of the rollers (15-3) is several, and the rollers (15-3) are fixed at the bottom of the roller mounting base plate (15-2) at equal intervals.

3. The transfer device with collision protection for cutter production according to claim 1, characterized in that: the attracted magnet layer (12) is replaced by a cutter clamp (13), the cutter clamp (13) is fixed in the belt groove (5-1), and the cutter clamp (13) comprises:

the cutter clamp comprises a cutter clamp body (13-1), one end, connected with the belt groove (5-1), of the cutter clamp body (13-1) is of an arc-shaped structure, and a cutter clamp groove (13-3) is formed in the other end of the cutter clamp body (13-1);

the positioning column (13-5), the positioning column (13-5) is movably inserted into the cutter clamp body (13-1) positioned on one side of the cutter clamp groove (13-3);

the spring (13-6) is sleeved on the positioning column (13-5), and two ends of the spring (13-6) are respectively abutted against the outer end cap of the positioning column (13-5) and the side wall of the cutter clamp body (13-1);

the movable adsorption magnetic block (13-4), the movable adsorption magnetic block (13-4) is fixed on the positioning column (13-5);

the fixed adsorption magnetic block (13-2) is embedded and fixed in the inner wall of the cutter clamping groove (13-3) and is opposite to the movable adsorption magnetic block (13-4) in polarity.

4. The transfer device with collision protection for cutter production according to claim 1, characterized in that: a cleaning mechanism (14) is fixed on the rotating shaft 11, and the cleaning mechanism (14) is arranged between the left T-shaped plate and the right T-shaped plate (8); the cleaning mechanism (14) comprises:

one end of the connecting column (14-2) is clamped and fixed in a jack arranged on the annular wall of the rotating shaft 11 by utilizing a clamping bead (14-4) embedded in the connecting column (14-2);

the brush mounting plate (14-1), the brush mounting plate (14-1) is fixed at the other end of the connecting column (14-2);

the brush (14-3), the brush (14-3) is fixed on the brush mounting plate (14-1).

5. The transfer device with collision protection for cutter production according to claim 3, characterized in that: a plurality of chip removal holes (1-3) are vertically formed in the bottom wall of the built-in cavity (1-1) in a penetrating mode, and a pull-out tray (16) is movably inserted into the shell (1) below the chip removal holes (1-3).

6. The working principle of the transfer device with collision protection for cutter production according to claim 1 is characterized in that: after the cutter is processed in the previous process, the cutter is manually inserted into a belt groove (5-1) in a conveying belt (5) one by one, the cutter is adsorbed and fixed on the conveying belt (5) in an adsorption magnet layer (12) which is arranged oppositely, meanwhile, a rotating motor (10) works to drive a driving roller (6) to rotate, the driving roller (6) drives a driven roller (3) to rotate by utilizing the conveying belt (5), the cutter rotates downwards under the rotation of the conveying belt (5), after the cutter is fully loaded on one conveying belt (5), a main shaft motor (9) is started to work so as to drive a T-shaped plate (8) to rotate, the conveying belt (5) without the cutter is enabled to be positioned above a built-in cavity (1-1), the main shaft motor (9) is stopped, and the cutter placing work is repeated until the conveying belt (5) is fully loaded with the cutter, the spindle motor (9) is started again to work, the rotation of the T-shaped plate (8) and the operation of placing the cutter are repeated, when all the conveying belts (5) are fully placed with cutters, the spindle motor (9) is started to work to drive the T-shaped plate (8) to rotate, so that the cover plate (4) connected to the side wall of the transverse plate (8-2) of the T-shaped plate (8) is horizontally arranged on the built-in cavity (1-1), and the cutters on the conveying belts (5) are all arranged in the built-in cavity (1-1) and are covered by the cover plate (4);

when the next procedure is needed, only the spindle motor (9) needs to be started to drive the T-shaped plate (8) to rotate, the conveying belt (5) is made to rotate to the position above the built-in cavity (1-1), the cutter is manually pulled out of the belt groove (5-1), and the cutter on the conveying belt (5) is sequentially taken out under the operation of the rotating motor (10) to perform the next procedure.

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