CN220593335U - Slitting device for antistatic master batch production - Google Patents

Abstract

The utility model relates to the field of antistatic master batch processing equipment, in particular to a cutting device for producing antistatic master batch, which comprises: a device body; the device body is symmetrically provided with sliding rails, and the sliding rails are provided with cutters in a sliding manner; a slot is further formed in one side of the device body, a driving assembly is arranged at the position of the slot, and the lower end of the driving assembly is connected with the cutter through a transmission assembly; the cutting device for producing the antistatic master batch replaces the original mode that the electric push rod pushes the cutter to operate with the mode that the driving component is combined with the transmission component to push the cutter to reciprocate up and down, the designed driving component adopts the mode that the output motor is combined with the turntable, and the installed transmission component adopts the mode that the upper connecting column, the crank and the lower connecting column are combined; therefore, when the formed particle size needs to be shortened, the output speed of the output motor only needs to be increased.

Description

Slitting device for antistatic master batch production

Technical Field

The utility model relates to the field of antistatic master batch processing equipment, in particular to a slitting device for antistatic master batch production.

Background

The antistatic master batch raw material is extruded and granulated in the granulator and is discharged in a strip shape at the position of a granulating disc, and the strip-shaped antistatic master batch is generally not in accordance with the granulating requirement, so that a cutting device is additionally arranged at the position of the granulating disc and is used for carrying out granulating and forming operation on the strip-shaped antistatic master batch;

at present, most of cutting devices additionally arranged at the position of a granulating disc are in a mode of combining a cutter with an electric push rod, the cutter is positioned at the upper end of the granulating disc, the position of the cutting edge of the cutter is aligned with the granulating disc, and meanwhile, the electric push rod is arranged at the upper end of the cutter;

after the anti-static master batch is extruded and discharged from the position of the granulating disc, then an electric push rod is started, the electric push rod operates to push a cutter to rapidly descend and displace, the anti-static master batch is cut into granules along the surface of the granulating disc to be formed, and the granules are scattered in a collecting hopper; the cutting device combining the electric push rod with the cutter has the advantages of simple structural design and convenient operation; however, the disadvantages are also obvious, for example, when smaller antistatic master batches need to be cut, the output speed of the electric push rod needs to be increased, the output principle of the electric push rod is that the electric push rod is output to the screw nut through the motor, the rotary motion of the motor is changed into linear motion, if the linear motion of the electric push rod needs to be increased, the output speed of the motor needs to be increased, the abrasion of the screw nut is further increased, and the service life of the whole cutting device is reduced.

Aiming at the problems in the background technology, the utility model aims to provide a slitting device for producing antistatic master batches.

Disclosure of Invention

The utility model aims to provide a slitting device for antistatic master batch production, which is used for solving the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

cutting device is used in antistatic masterbatch production, antistatic masterbatch production is with cutting device includes:

the device comprises a device body, wherein sliding rails are symmetrically arranged and fixed on the device body, and cutters are slidably arranged on the sliding rails; the left side and the right side of the upper end of the cutter are provided with sliding blocks, and the sliding blocks arranged on the left side and the right side of the upper end of the cutter are slidably arranged on a fixed sliding rail arranged on the device body;

the device is characterized in that a slot is further formed in one side of the device body, a driving assembly is arranged at the position of the slot, and the lower end of the driving assembly is connected with the cutter through a transmission assembly.

As a further scheme of the utility model: the guide wheel grooves are formed in two sides of the sliding rail, guide wheels are symmetrically and movably mounted in the sliding block through pin shafts, and one side of each guide wheel movably mounted in the sliding block is attached to the outer side surface of each guide wheel groove.

As a further scheme of the utility model: the device is characterized in that a sliding rod is fixedly arranged on the device body, a movable block is arranged on one side of the sliding block, the movable block arranged on one side of the sliding block is slidably arranged on the sliding rod fixedly arranged on the device body, and meanwhile, compression springs are sleeved on the sliding rod at positions on the upper side and the lower side of the movable block.

As a further scheme of the utility model: the driving assembly comprises an output motor and a rotary table, the output motor is positioned at one side of the device body, a driving shaft is arranged at the output end of the output motor, and the rotary table is arranged at the tail end part of one end of the driving shaft, which penetrates through the inner wall of the device body and then stretches into the slot; the lower end of the turntable is connected with the transmission component.

As a further scheme of the utility model: the transmission assembly comprises an upper connecting column, a crank and a lower connecting column, the upper connecting column is fixedly arranged on the rotary table, the lower connecting column is positioned at the middle position of the upper end of the cutter, and movable installation is realized between the lower connecting column arranged at the upper end of the cutter and the upper connecting column fixedly arranged on the rotary table through the crank.

Compared with the prior art, the utility model has the beneficial effects that:

the cutting device for antistatic masterbatch production is designed through technical innovation, the original mode that an electric push rod pushes a cutter to operate is replaced and designed to push the cutter to reciprocate up and down in a mode that a driving assembly is combined with a transmission assembly, the designed driving assembly adopts a mode that an output motor is combined with a rotary table, the transmission assembly is installed in a mode that an upper connecting column, a crank and a lower connecting column are combined, kinetic energy is output to the rotary table through the output motor, the rotary table is pushed to rotate, and then the rotary table pushes the cutter to reciprocate up and down through the crank, so that the granule cutting forming operation of the strip antistatic masterbatch is realized, when the forming particle size is required to be shortened, only the output speed of the output motor is required to be quickened, and all components are movably installed, so that the abrasion degree is small.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the following description will briefly introduce the drawings that are needed in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are only some embodiments of the present utility model.

Fig. 1 is a front view of a slitting device for producing antistatic master batches according to an embodiment of the utility model.

Fig. 2 is a front view of a slitting device for producing antistatic master batches according to an embodiment of the utility model.

Fig. 3 is a side view of a slitting device for producing antistatic master batches according to an embodiment of the utility model.

In the figure: 1-baffle, 2-device body, 3-slotting, 4-turntable, 5-driving shaft, 6-upper connecting column, 7-sliding rail, 8-sliding rod, 9-crank, 10-pin shaft, 11-sliding block, 12-cutter, 13-lower connecting column, 14-movable block, 15-compression spring, 16-guide wheel, 17-guide wheel slot and 18-output motor.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Examples

Referring to fig. 1, fig. 2 and fig. 3, in an embodiment of the present utility model, a slitting device for producing antistatic masterbatch includes:

the device comprises a device body 2, wherein slide rails 7 are symmetrically arranged and fixed on the device body 2, cutters 12 are slidably arranged on the slide rails 7, and the cutters 12 are used for carrying out slitting operation on the granulating and forming antistatic master batches; the left side and the right side of the upper end of the cutter 12 are provided with sliding blocks 11, and the sliding blocks 11 arranged on the left side and the right side of the upper end of the cutter 12 are slidably arranged on a sliding rail 7 which is fixedly arranged on the device body 2;

a slot 3 is further formed in one side of the device body 2, a driving component is arranged at the position of the slot 3, and the lower end of the driving component is connected with a cutter 12 through a transmission component; meanwhile, the device body 2 is provided with baffle plates 1 at the positions of two sides for installing the driving components, and the arranged baffle plates 1 are used for shielding and protecting two sides of the driving components installed on the device body 2 during operation;

in the embodiment of the utility model, when the slitting device for producing the antistatic master batch is used, after the whole device body 2 is installed and fixed at the outlet position of a granulating disc of a granulator, after the granulator is extruded into strip-shaped antistatic master batches at the position of the granulating disc through thermoplastic extrusion, a driving assembly is started, and the driving assembly operates to push a cutter 12 to reciprocate and slide on a sliding rail 7 which is installed and fixed on the device body 2 through the driving assembly so as to carry out slitting granulation operation on the strip-shaped antistatic master batches;

in one embodiment of the utility model, two sides of the sliding rail 7 are provided with guide wheel grooves 17, guide wheels 16 are symmetrically and movably arranged in the sliding block 11 through pin shafts 10, and one side of the guide wheel 16 movably arranged in the sliding block 11 is attached to the outer side surface of the guide wheel groove 17;

when the transmission component drives the cutter 12 to reciprocate on the surface of the slide rail 7 for sliding displacement, the guide wheel 16 movably arranged in the slide block 11 rolls along the surface of the guide wheel groove 17 arranged on the outer side of the slide rail 7, the slide block 11 which is originally in sliding friction installation with the slide rail 7 is replaced and designed into rolling friction, so that the friction force on the slide rail 7 when the cutter 12 reciprocates up and down is reduced, and the abrasion is reduced;

in the embodiment of the utility model, the device body 2 is also provided with and fixed with a slide bar 8, one side of the slide block 11 is provided with a movable block 14, the movable block 14 arranged on one side of the slide block 11 is slidably arranged on the slide bar 8 which is arranged and fixed on the device body 2, and meanwhile, the slide bar 8 is also sleeved with a compression spring 15 at the position of the upper side and the lower side of the movable block 14;

when the sliding block 11 arranged at the upper end of the cutter 12 slides up and down along the sliding rail 7, the movable block 14 connected with one side of the sliding block 11 slides up and down on the sliding rod 8, and the sliding displacement on the sliding rod 8 is synchronous through the movable block 14 arranged at one side of the sliding block 11, so that the sliding displacement of the sliding block 11 on the sliding rail 7 is not easy to generate position deviation; the movable block 14 can also squeeze the compression spring 15 to deform to generate elastic force when sliding and displacing on the slide bar 8, so as to limit the speed of the slide block 11 which rapidly slides and displaces, and avoid impact damage to the device body 2 at the position where the slide rail 7 and the slide bar 8 are arranged when the displacement speed of the slide block 11 is too high;

referring to fig. 1, 2 and 3, in one embodiment of the present utility model, the driving assembly includes an output motor 18 and a turntable 4, the output motor 18 is located at one side of the device body 2, an output end of the output motor 18 is provided with a driving shaft 5, and a terminal portion of one end of the driving shaft 5 extending into the slot 3 after passing through an inner wall of the device body 2 is provided with the turntable 4; the lower end of the turntable 4 is connected with a transmission assembly;

in the embodiment of the utility model, when the driving assembly is used, the output motor 18 is started, the rotary table 4 is driven to rotate by the driving shaft 5 after the output motor 18 is powered on, and when the rotary table 4 rotates, the cutter 12 is driven by the transmission assembly to reciprocate up and down so as to realize slitting and granulating operation on the anti-static master batch strips after being extruded into strips;

in one embodiment of the utility model, the transmission assembly comprises an upper connecting column 6, a crank 9 and a lower connecting column 13, wherein the upper connecting column 6 is fixedly arranged on the turntable 4, the lower connecting column 13 is positioned at the middle position of the upper end of the cutter 12, and the lower connecting column 13 arranged at the upper end of the cutter 12 is movably arranged with the upper connecting column 6 fixedly arranged on the turntable 4 through the crank 9;

in the embodiment of the utility model, when the transmission component is used for pushing the cutter 12 to reciprocate up and down along the sliding rail 7, when the turntable 4 rotates, the upper connecting column 6 arranged on the turntable 4 also rotates at the same time, the rotating upper connecting column 6 can change the up and down position, and the lower end of the upper connecting column 6 and the lower connecting column 13 arranged at the upper end in the middle of the cutter 12 are movably arranged through the crank 9, so that when the up and down position of the upper connecting column 6 changes, the lower connecting column 13 which is movably arranged with the upper connecting column 6 through the crank 9 also simultaneously changes the up and down position, and further drives the cutter 12 to reciprocate up and down position, thereby forming the cut antistatic master batch;

in the description of the present utility model, unless explicitly stated and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (5)

1. The utility model provides an antistatic masterbatch production is with cutting device which includes: a device body (2); the method is characterized in that:

the device body (2) is symmetrically provided with sliding rails (7), and the sliding rails (7) are provided with cutters (12) in a sliding manner; the left side and the right side of the upper end of the cutter (12) are provided with sliding blocks (11), and the sliding blocks (11) arranged on the left side and the right side of the upper end of the cutter (12) are slidably arranged on a sliding rail (7) which is fixedly arranged on the device body (2);

a slot (3) is further formed in one side of the device body (2), a driving assembly is arranged at the position of the slot (3), and the lower end of the driving assembly is connected with a cutter (12) through a transmission assembly.

2. The slitting device for antistatic master batch production according to claim 1, wherein: guide wheel grooves (17) are formed in two sides of the sliding rail (7), guide wheels (16) are symmetrically and movably mounted in the sliding block (11) through pin shafts (10), and one side of each guide wheel (16) movably mounted in the sliding block (11) is attached to the outer side surface of each guide wheel groove (17).

3. The slitting device for antistatic master batch production according to claim 2, wherein: the device body (2) is also provided with and fixed with a slide bar (8), one side of the slide block (11) is provided with a movable block (14), the movable block (14) arranged on one side of the slide block (11) is slidably arranged on the slide bar (8) which is fixedly arranged on the device body (2), and meanwhile, the slide bar (8) is also sleeved with a compression spring (15) at the positions on the upper side and the lower side of the movable block (14).

4. The slitting device for antistatic master batch production according to claim 1, wherein: the driving assembly comprises an output motor (18) and a rotary table (4), the output motor (18) is positioned at one side of the device body (2), a driving shaft (5) is arranged at the output end of the output motor (18), one end of the driving shaft (5) penetrates through the inner wall of the device body (2) and then stretches into the rotary table (4) at the tail end part inside the slot (3); the lower end of the turntable (4) is connected with a transmission component.

5. The slitting device for antistatic master batch production according to claim 4, wherein: the transmission assembly comprises an upper connecting column (6), a crank (9) and a lower connecting column (13), wherein the upper connecting column (6) is fixedly arranged on the rotary table (4), the lower connecting column (13) is positioned at the middle position of the upper end of the cutter (12), and movable installation is realized between the lower connecting column (13) arranged at the upper end of the cutter (12) and the upper connecting column (6) fixedly arranged on the rotary table (4) through the crank (9).