CN221161597U

CN221161597U - Filter substrate stacks and sticiss device

Info

Publication number: CN221161597U
Application number: CN202323247369.6U
Authority: CN
Inventors: 刘远诚; 闭振运
Original assignee: Guangdong Microequation New Materials Co ltd
Current assignee: Guangdong Microequation New Materials Co ltd
Priority date: 2023-11-30
Filing date: 2023-11-30
Publication date: 2024-06-18
Anticipated expiration: 2033-11-30

Abstract

The utility model discloses a filter substrate stacking and compacting device, which belongs to the technical field of corrugated board processing, wherein a forming top die is arranged below a forming bottom die and is connected with the output end of an upper driving module; the first driving wheel is fixedly connected with an output shaft of the motor, the second driving wheel is arranged above the first driving wheel, the first driving wheel and the second driving wheel are both arranged in a closed loop of a first driving chain and are both in driving connection with the first driving chain, and the first driving chain is fixedly connected with the left side of the forming bottom die; the third driving wheel is in driving connection with an output shaft of the motor, the fourth driving wheel is arranged above the third driving wheel, the third driving wheel and the fourth driving wheel are both arranged in a closed loop of the second driving chain and are both in driving connection with the second driving chain, and the second driving chain is fixedly connected with the right side of the forming bottom die. The filter substrate stacking and compacting device solves the problem of low installation efficiency of the existing corrugated board punching machine.

Description

Filter substrate stacks and sticiss device

Technical Field

The utility model relates to the technical field of corrugated board processing, in particular to a filter substrate stacking and compacting device.

Background

By stacking a plurality of filter substrates, such as corrugated sheets, and compacting the filter substrates, a filter screen can be formed, which can be applied to a molecular sieve rotating wheel to realize the filtering function. Compression of the filter substrate is typically accomplished by a stamping device.

The Chinese patent application number 202220354442.6 discloses a stable stamping device for automobile corrugated boards, which is characterized in that a plurality of bearing grooves are formed in the inner side of a bearing base, then a hydraulic prop is arranged on each bearing groove to support and jack a forming bottom die, and then the hydraulic prop is matched with a forming top die to realize stamping. In practical production, in order to ensure that all hydraulic struts can synchronously act, an installer needs to continuously debug during installation, so that the installation efficiency is reduced.

Disclosure of utility model

In order to overcome the defects in the prior art, the utility model provides a filter substrate stacking compacting device to solve the problems.

The technical scheme adopted for solving the technical problems is as follows: a stacking and compacting device for filter substrates comprises a forming top die, a forming bottom die, a lower driving module and an upper driving module;

The forming top die is arranged below the forming bottom die, the corrugated board is arranged between the forming top die and the forming bottom die, and the forming top die is connected with the output end of the upper driving module;

The lower driving module comprises a motor, a first lifting transmission mechanism and a second lifting transmission mechanism;

The first lifting transmission mechanism comprises a first transmission wheel, a second transmission wheel and a first transmission chain, wherein the first transmission wheel is fixedly connected with an output shaft of the motor, the second transmission wheel is arranged above the first transmission wheel, the first transmission wheel and the second transmission wheel are both arranged in a closed loop of the first transmission chain and are both in transmission connection with the first transmission chain, and the first transmission chain is fixedly connected with the left side of the forming bottom die;

The second lifting transmission mechanism comprises a third transmission wheel, a fourth transmission wheel and a second transmission chain, wherein the third transmission wheel is in transmission connection with an output shaft of the motor, the fourth transmission wheel is arranged above the third transmission wheel, the third transmission wheel and the fourth transmission wheel are both arranged in a closed loop of the second transmission chain and are both in transmission connection with the second transmission chain, and the second transmission chain is fixedly connected with the right side of the forming bottom die.

It is worth to say that, lower drive module still includes control drive mechanism, control drive mechanism includes fifth drive wheel, sixth drive wheel and third drive chain, fifth drive wheel and sixth drive wheel are distributed in the left and right directions, fifth drive wheel with the output shaft fixed connection of motor, fifth drive wheel with sixth drive wheel all set up in the closed loop of third drive chain, and all with third drive chain transmission connection, sixth drive wheel with third drive wheel transmission connection.

Optionally, the lower driving module further comprises a direction-changing transmission mechanism, the direction-changing transmission mechanism comprises a direction-changing main gear and a direction-changing auxiliary gear, the direction-changing main gear is meshed with the direction-changing auxiliary gear, the direction-changing main gear and the sixth driving wheel are coaxially arranged and synchronously rotate, and the direction-changing auxiliary gear and the third driving wheel are coaxially arranged and synchronously rotate.

Preferably, the forming bottom die comprises a bearing base and reinforcing beams, wherein the reinforcing beams are arranged on the left side and the right side of the bearing base, the reinforcing beams on the left side are fixedly connected with the first transmission chain, and the reinforcing beams on the right side are fixedly connected with the second transmission chain.

Specifically, the upper driving module is an air cylinder, and a telescopic shaft of the upper driving module is downwards arranged and fixedly connected with the upper side of the forming top die.

The forming top die is characterized by further comprising guide rails, wherein the guide rails are distributed on the left side and the right side of the forming top die, and the left side and the right side of the forming top die are both in sliding connection with the corresponding guide rails.

The utility model has the beneficial effects that: in the filter substrate stacking and compacting device, only one motor is needed to drive a first transmission chain positioned on the left side of the forming bottom die and a second transmission chain positioned on the right side of the forming bottom die to act, so that the lifting of the forming bottom die is realized, the left side and the right side of the forming bottom die are simultaneously driven to lift simultaneously, the balanced lifting of the forming bottom die can be realized, in addition, the driving source only has one motor, and the synchronous action of the first transmission chain and the second transmission chain is not needed to be realized through debugging after the installation, so that the installation efficiency is improved.

Drawings

FIG. 1 is a schematic illustration of a filter substrate stack compression device in accordance with one embodiment of the present utility model;

FIG. 2 is an enlarged schematic view of the dashed circle A of FIG. 1;

FIG. 3 is a left side view of a first lift drive mechanism in one embodiment of the present utility model;

FIG. 4 is a right side view of a second lift transmission mechanism in one embodiment of the utility model;

In the figure: 1, forming a top die; 11 guide rails; 2, forming a bottom die; 21 a carrying base; 22 reinforcing the beam; 3, a lower driving module; 31 motor; 32 a first lifting transmission mechanism; 321 a first drive wheel; 322 a second drive wheel; 323 a first drive chain; 33 a second lifting transmission mechanism; 331 a third drive wheel; 332 fourth drive wheel; 333 second drive chain; 34 left and right transmission mechanisms; 341 a fifth drive wheel; 342 a sixth drive wheel; 343 a third drive chain; 35 a direction-changing transmission mechanism; 351 a direction-changing main gear; 352 direction change pinion; 4, an upper driving module; 5 corrugated boards; and 6, a frame.

Detailed Description

The following describes the embodiments of the present utility model further with reference to the drawings. The description of these embodiments is provided to assist understanding of the present utility model, but is not intended to limit the present utility model. In addition, the technical features of the embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

As shown in fig. 1 to 4, a filter substrate stacking and compacting device comprises a forming top die 1, a forming bottom die 2, a lower driving module 3 and an upper driving module 4;

The forming top die 1 is arranged below the forming bottom die 2, the corrugated board 5 is arranged between the forming top die 1 and the forming bottom die 2, and the forming top die 1 is connected with the output end of the upper driving module 4;

The lower driving module 3 comprises a motor 31, a first lifting transmission mechanism 32 and a second lifting transmission mechanism 33;

The first lifting transmission mechanism 32 comprises a first transmission wheel 321, a second transmission wheel 322 and a first transmission chain 323, the first transmission wheel 321 is fixedly connected with an output shaft of the motor 31, the second transmission wheel 322 is arranged above the first transmission wheel 321, the first transmission wheel 321 and the second transmission wheel 322 are both arranged in a closed loop of the first transmission chain 323 and are both in transmission connection with the first transmission chain 323, and the first transmission chain 323 is fixedly connected with the left side of the forming bottom die 2; specifically, the first driving wheel 321 and the second driving wheel 322 are gears; the first driving wheel 321 rotates, the first driving chain 323 drives the second driving wheel 322 to rotate, and the forming bottom die 2 can be driven to move in the process of the action of the first driving chain 323;

The second lifting transmission mechanism 33 comprises a third transmission wheel 331, a fourth transmission wheel 332 and a second transmission chain 333, wherein the third transmission wheel 331 is in transmission connection with an output shaft of the motor 31, the fourth transmission wheel 332 is arranged above the third transmission wheel 331, the third transmission wheel 331 and the fourth transmission wheel 332 are both arranged in a closed loop of the second transmission chain 333 and are both in transmission connection with the second transmission chain 333, and the second transmission chain 333 is fixedly connected with the right side of the forming bottom die 2; specifically, the third driving wheel 331 and the fourth driving wheel 332 are gears; the third driving wheel 331 rotates, the second driving chain 333 drives the fourth driving wheel 332 to rotate, and the second driving chain 333 can drive the forming bottom die 2 to move during the movement process.

In the filter substrate stacking and compacting device, only one motor 31 is needed to drive the first transmission chain 323 positioned at the left side of the forming bottom die 2 and the second transmission chain 333 positioned at the right side of the forming bottom die 2 to act simultaneously, so that the lifting of the forming bottom die 2 is realized, the left side and the right side of the forming bottom die 2 are simultaneously driven to lift simultaneously, the balanced lifting of the forming bottom die 2 can be realized, in addition, the driving source only has one motor 31, and the synchronous action of the first transmission chain 323 and the second transmission chain 333 is not needed to be realized through debugging after the installation, so that the installation efficiency is improved.

It should be noted that, the lower driving module 3 further includes a left and right driving mechanism 34, the left and right driving mechanism 34 includes a fifth driving wheel 341, a sixth driving wheel 342, and a third driving chain 343, the fifth driving wheel 341 and the sixth driving wheel 342 are distributed in a left and right direction, the fifth driving wheel 341 is fixedly connected with an output shaft of the motor 31, the fifth driving wheel 341 and the sixth driving wheel 342 are both disposed in a closed loop of the third driving chain 343, and are both in driving connection with the third driving chain 343, and the sixth driving wheel 342 is in driving connection with the third driving wheel 331.

The fifth driving wheel 341 and the sixth driving wheel 342 are gears. The motor 31 can drive the first driving wheel 321 to rotate and can also drive the fifth driving wheel 341 to rotate, the fifth driving wheel 341 can drive the sixth driving wheel 342 to rotate through the third driving chain 343 when rotating, and the third driving wheel 331 can be driven to rotate through the turning driving mechanism 35 when the sixth driving wheel 342 rotates, so that the first driving chain 323 and the second driving chain 333 can be driven to act simultaneously through one motor 31.

Preferably, as shown in fig. 2 and 4, the lower driving module 3 further includes a direction-changing transmission mechanism 35, the direction-changing transmission mechanism 35 includes a direction-changing main gear 351 and a direction-changing auxiliary gear 352, the direction-changing main gear 351 and the direction-changing auxiliary gear 352 are meshed, the direction-changing main gear 351 is coaxially arranged with and synchronously rotates with the sixth driving wheel 342, and the direction-changing auxiliary gear 352 is coaxially arranged with and synchronously rotates with the third driving wheel 331. Specifically, the direction-changing main gear 351 and the sixth driving wheel 342 are fixed on the same rotation shaft, and the direction-changing auxiliary gear 352 and the third driving wheel 331 are fixed on the same rotation shaft.

By providing the direction-changing main gear 351 and the direction-changing sub gear 352 which are engaged with each other, the direction-changing sub gear 352 can be rotated in the opposite direction to the direction of rotation of the direction-changing main gear 351. In this embodiment, the rotation directions of the first driving wheel 321, the second driving wheel 322, the fifth driving wheel 341, the sixth driving wheel 342 and the turning main gear 351 are the same, and the rotation directions of the third driving wheel 331, the fourth driving wheel 332 and the turning auxiliary gear 352 are the same, so that the rotation directions of the second driving wheel 322 and the fourth driving wheel 332 are opposite, and the left side and the right side of the forming bottom die 2 can be driven to be lifted or lowered simultaneously.

Optionally, the molding bottom die 2 includes a load-bearing base 21 and a reinforcing beam 22, the reinforcing beam 22 is disposed on the left and right sides of the load-bearing base 21, the reinforcing beam 22 on the left side is fixedly connected with the first transmission chain 323, and the reinforcing beam 22 on the right side is fixedly connected with the second transmission chain 333. Specifically, the first driving chain 323 passes through the reinforcing beam 22 and is fixedly connected with the reinforcing beam 22, and the second virus inspecting chain 333 passes through the reinforcing beam 22 and is fixedly connected with the reinforcing beam 22.

The reinforcing beam 22 is arranged on the bearing base 21 to play a reinforcing role. During punching, the corrugated boards 5 are stacked on the bearing base 21, the bearing base 21 faces the lower surface of the forming top die 1, and then the forming top die 1 is matched, namely, the bearing base 21 drives the corrugated boards 5 to lift upwards, and the forming top die 1 presses downwards, so that punching can be completed.

Specifically, the upper driving module 4 is an air cylinder, and the telescopic shaft of the upper driving module 4 is downward arranged and fixedly connected with the upper side of the forming top die 1. The upper driving module 4 can drive the forming top die 1 to lift through a telescopic shaft of the upper driving module. The cylinder body of the upper driving module 4 is arranged on the frame 6.

It should be noted that the forming die further comprises guide rails 11, the guide rails 11 are distributed on the left side and the right side of the forming die 1, and the left side and the right side of the forming die 1 are slidably connected with the corresponding guide rails 11. Specifically, the guide rail 11 is fixedly connected with the frame 6. The guide rail 11 plays a role of guiding, so that the forming top mold 1 can stably perform lifting motion on a vertical plane.

The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings, but the present utility model is not limited to the described embodiments. It will be apparent to those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the utility model, and yet fall within the scope of the utility model.

Claims

1. A filter substrate stacking compaction device, characterized by: the device comprises a forming top die, a forming bottom die, a lower driving module and an upper driving module;

2. A filter substrate stack compacting apparatus as set forth in claim 1, wherein: the lower driving module further comprises a left driving mechanism and a right driving mechanism, the left driving mechanism comprises a fifth driving wheel, a sixth driving wheel and a third driving chain, the fifth driving wheel and the sixth driving wheel are distributed in the left-right direction, the fifth driving wheel is fixedly connected with an output shaft of the motor, the fifth driving wheel and the sixth driving wheel are arranged in a closed loop of the third driving chain and are in driving connection with the third driving chain, and the sixth driving wheel is in driving connection with the third driving wheel.

3. A filter substrate stack compacting apparatus as set forth in claim 2, wherein: the lower driving module further comprises a direction-changing transmission mechanism, the direction-changing transmission mechanism comprises a direction-changing main gear and a direction-changing auxiliary gear, the direction-changing main gear is meshed with the direction-changing auxiliary gear, the direction-changing main gear and the sixth driving wheel are coaxially arranged and synchronously rotate, and the direction-changing auxiliary gear and the third driving wheel are coaxially arranged and synchronously rotate.

4. A filter substrate stack compacting apparatus as set forth in claim 1, wherein: the forming bottom die comprises a bearing base and reinforcing beams, wherein the reinforcing beams are arranged on the left side and the right side of the bearing base, the reinforcing beams on the left side are fixedly connected with the first transmission chain, and the reinforcing beams on the right side are fixedly connected with the second transmission chain.

5. A filter substrate stack compacting apparatus as set forth in claim 1, wherein: the upper driving module is an air cylinder, and a telescopic shaft of the upper driving module is downwards arranged and fixedly connected with the upper side of the forming top die.

6. A filter substrate stack compacting apparatus as set forth in claim 1, wherein: the forming die further comprises guide rails, the guide rails are distributed on the left side and the right side of the forming die, and the left side and the right side of the forming die are both in sliding connection with the corresponding guide rails.