CN221166731U - Feeding and discharging turnover mechanism and vertical continuous coating equipment thereof - Google Patents

Abstract

The utility model relates to the field of PE film coating equipment, in particular to a feeding and discharging turnover mechanism and vertical continuous coating equipment thereof. The embodiment of the utility model provides a feeding and discharging turnover mechanism, which comprises the following components: the device comprises a fixed frame, wherein a turnover plate is rotatably arranged on the inner side of the fixed frame, a loading shaft is suitable for being installed on the turnover plate, a turnover assembly is installed on the outer side of the fixed frame, the movable end of the turnover assembly is connected with the turnover plate, and the two ends of the stroke of the turnover assembly are respectively provided with a first station and a second station; when the turnover assembly moves to the first station, the turnover plate drives the material shaft to a vertical position; when the turnover assembly moves to the second station, the turnover plate drives the material shaft to a horizontal position. Through setting up a plurality of unloading tilting mechanism for every stub bar can all independently overturn, does not need to shut down whole equipment. The fixed cylinder clamps the positioning bearing, so that the material shaft is more stable and smooth in vertical working.

Description

Feeding and discharging turnover mechanism and vertical continuous coating equipment thereof

Technical Field

The utility model relates to the field of PE film coating equipment, in particular to a feeding and discharging turnover mechanism and vertical continuous coating equipment thereof.

Background

Most PE film coating equipment in the prior art is horizontally coated, and a blank exists in the field of vertical continuous coating, wherein in the vertical coating process, the equipment is inconvenient to feed and discharge and has the problem of safety risk, so that the design of the feeding and discharging turnover device for the vertical continuous coating is necessary.

Disclosure of utility model

The utility model aims to provide a loading and unloading turnover mechanism and vertical continuous coating equipment thereof so as to solve the problems.

In order to achieve the above object, an embodiment of the present utility model provides a feeding and discharging turnover mechanism, including: the fixed frame, fixed frame inboard rotates and is provided with the upset board, be suitable for installing the loading axle on the upset board, the upset subassembly is installed to the fixed frame outside, the loose end of upset subassembly with the upset board is connected, and

The two ends of the stroke of the overturning assembly are respectively provided with a first station and a second station; wherein the method comprises the steps of

When the overturning assembly moves to the first station, the overturning plate drives the material shaft to a vertical position;

when the turnover assembly moves to the second station, the turnover plate drives the material shaft to a horizontal position.

Further, the overturning assembly comprises a fixed seat, an electric actuator and a pull rod, wherein the fixed seat is hinged to the outer side of the fixed frame, the electric actuator is arranged on the fixed seat, and two ends of the pull rod are respectively connected with the movable end of the electric actuator and the end part of the overturning plate in a rotating way; wherein the method comprises the steps of

When the pull rod rotates to the position with the maximum travel in the forward direction, the pull rod is positioned at a first station;

and when the pull rod reversely rotates to the position with the maximum travel, the pull rod is positioned at the second station.

Further, a limiter is further installed on the outer side of the fixed frame, and the distance from the limiter to the joint of the pull rod and the overturning plate is smaller than the length of the pull rod.

In addition, the utility model also provides vertical continuous coating equipment, which uses the feeding and discharging overturning assembly, wherein the vertical continuous coating equipment comprises a chassis, and a plurality of feeding and discharging overturning assemblies are arranged on the chassis;

and the two ends of the turnover plate are provided with turnover bearings.

Further, the bottom of the turnover plate is also provided with a mounting plate, a driving mechanism is suitable for being mounted on the mounting plate, and the movable end of the driving mechanism is in transmission connection with the end part of the material shaft.

Further, the driving mechanism comprises a driving motor, a speed reducer, a transmission wheel set and a clutch, wherein the driving motor is installed on the installation plate, the speed reducer is connected with the movable end of the driving motor, two sides of the transmission wheel set are respectively connected with the movable end of the speed reducer and the input end of the clutch, and the output end of the clutch is connected with the end part of the material shaft.

Further, the transmission wheel group comprises two transmission wheels and a synchronous belt sleeved on the two transmission wheels, and the two transmission wheels are respectively connected with the speed reducer and the clutch.

Further, the end part of the material shaft is sequentially provided with a supporting seat, a power shaft and a connecting flange, the supporting seat is connected with the material shaft, the connecting flange is connected with the clutch, and the power shaft is respectively connected with the supporting seat and the connecting flange.

Further, the top of the fixed frame is also provided with a fixed cylinder, the top of the material shaft is provided with a positioning bearing, and the movable end of the fixed cylinder is arranged towards the positioning bearing.

Further, a supporting frame is sleeved outside the material shaft, and the bottom of the supporting frame is connected with the overturning plate.

Compared with the prior art, the embodiment of the utility model has the following beneficial effects: through setting up a plurality of unloading tilting mechanism for every stub bar can all independently overturn, does not need to shut down whole equipment. The fixed cylinder clamps the positioning bearing, so that the material shaft is more stable and smooth in vertical working.

Drawings

The utility model will be further described with reference to the drawings and examples.

FIG. 1 shows a perspective view of a vertical continuous coating apparatus of the present utility model;

FIG. 2 shows an enlarged partial view of portion A of FIG. 1;

FIG. 3 shows a side view of the vertical continuous coating apparatus of the present utility model;

FIG. 4 shows a schematic view of the feed shaft of the present utility model;

fig. 5 shows a schematic view of the position of the stationary cylinder of the present utility model.

In the figure:

1. A fixed frame; 11. a limiter; 12. a fixed cylinder;

2. A turnover plate; 21. a turnover bearing; 22. a mounting plate;

3. A material shaft; 31. a support base; 32. a power shaft; 33. a connecting flange; 34. positioning a bearing; 35. a support frame;

4. a flip assembly; 41. a fixing seat; 42. an electric actuator; 43. a pull rod;

5. a chassis;

6. A driving mechanism; 61. a driving motor; 62. a speed reducer; 63. a synchronous belt; 64. a clutch.

Detailed Description

The utility model will now be described in further detail with reference to the accompanying drawings. The drawings are simplified schematic representations which merely illustrate the basic structure of the utility model and therefore show only the structures which are relevant to the utility model.

As shown in fig. 1 to 5, this embodiment provides a loading and unloading overturning assembly 4, including: the fixed frame 1, the inboard of fixed frame 1 is suitable for installing the roll-over plate 2, is suitable for installing loading axle 3 on the roll-over plate 2, the upset subassembly 4 is installed to the fixed frame 1 outside. The fixed frame 1 is the mounting base of unloading upset subassembly 4 in going up that this embodiment shows, and the stable installation of material axle 3 is inside fixed frame 1. The two ends of the turnover plate 2 are respectively connected with the fixed frame 1 in a rotating way, so that the turnover plate 2 can drive the material shaft 3 to turn to be horizontal or vertical. In this embodiment, the material shaft 3 is in a working state when vertical, and the material shaft 3 can be fed and discharged when horizontal. In order to achieve the above effect, the movable end of the turnover assembly 4 is connected with the turnover plate 2, and the stroke two ends of the turnover assembly 4 are respectively provided with a first station and a second station. When the turnover assembly 4 is in the first station, the material shaft 3 is in the vertical position, and when the turnover assembly 4 is in the second station, the material shaft 3 is in the horizontal position. The turnover assembly 4 drives the turnover plate 2 to rotate, so that the material shaft 3 can be driven to switch between two working states.

The structure of the flipping assembly 4 will be specifically described, and the flipping assembly 4 includes a fixing base 41, an electric actuator 42, and a pull rod 43. The fixing seat 41 is hinged to the outer side of the fixing frame 1, the electric actuator 42 is installed on the fixing seat 41, the fixing seat 41 is an installation base of the overturning assembly 4, and meanwhile the fixing seat 41 can drive the electric actuator 42 to rotate around the joint of the fixing seat 41 and the fixing frame 1. Both ends of the pull rod 43 are respectively and rotatably connected with the movable end of the electric actuator 42 and the end part of the turnover plate 2. The optional linear moving pair of the electric actuator 42 can extend outwards when the electric actuator 42 is started to push the pull rod 43 to rotate around the joint with the turnover plate 2, and meanwhile, the pull rod 43 acts against the electric actuator 42, so that the electric actuator 42 drives the fixed seat 41 to rotate around the fixed frame 1. The pull rod 43 is in the first position when it is rotated forward to the maximum stroke. The pull rod 43 is in the second position when it is rotated in the opposite direction to the maximum stroke. The outer side of the fixed frame 1 is also provided with a limiter 11, and the distance from the limiter 11 to the joint of the pull rod 43 and the turnover plate 2 is smaller than the length of the pull rod 43. When the pull rod 43 rotates to be in abutting connection with the limiter 11, the pull rod 43 reaches the position with the maximum travel, namely the second station, and the material shaft 3 is in a horizontal state; conversely, when the electric actuator 42 is contracted to the minimum length, the pull rod 43 reaches the maximum stroke in the reverse direction, i.e., the first station, and the material shaft 3 is in the vertical state. Through the mode, the working position of the material shaft 3 can be conveniently switched, so that feeding and discharging are realized.

In a second embodiment, the present embodiment is implemented on the basis of the first embodiment, and the present embodiment provides a vertical continuous coating apparatus, using the loading/unloading flipping assembly 4 shown in the first embodiment. The vertical continuous coating equipment comprises a bottom frame 5, and a plurality of feeding and discharging overturning assemblies 4 are arranged on the bottom frame 5. The processing efficiency of the vertical continuous coating equipment can be accelerated by simultaneously working the plurality of groups of feeding and discharging overturning assemblies 4. The two ends of the turnover plate 2 are provided with turnover bearings 21 for connecting the turnover plate 2 with the fixed frame 1.

In order to drive the material shaft 3 to rotate, the material shaft 3 can normally unwind the film material. The bottom of the turnover plate 2 is further provided with a mounting plate 22, the mounting plate 22 is suitable for being provided with a driving mechanism 6, the movable end of the driving mechanism 6 is in transmission connection with the end part of the material shaft 3, and the driving mechanism 6 can drive the material shaft 3 to rotate so as to enable the material shaft 3 to unreel film materials, and corresponding processing procedures are completed.

The structure of the drive mechanism 6 is specifically described below, and the drive mechanism 6 includes a drive motor 61, a speed reducer 62, a transmission wheel group, and a clutch 64. The driving motor 61 is installed on the installation plate 22, and the driving motor 61 is a power source for rotating the material shaft 3. The speed reducer 62 is connected to the movable end of the driving motor 61, and the speed reducer 62 can transmit the torque of the driving motor 61, and reduce the speed of the torque and increase the torque, so that the speed reducer 62 outputs a torque sufficient to rotate the material shaft 3. The two sides of the transmission wheel set are respectively connected with the movable end of the speed reducer 62 and the input end of the clutch 64, and the output end of the clutch 64 is connected with the end part of the material shaft 3. The clutch 64 can act as a switch to transmit or interrupt the torque supplied to the shaft 3. The transmission wheel set comprises two transmission wheels and a synchronous belt 63 sleeved on the two transmission wheels, and the two transmission wheels are respectively connected with the speed reducer 62 and the clutch 64. The driving motor 61 can drive the corresponding driving wheel to rotate, and drives the other driving wheel to rotate through the synchronous belt 63, so that the two material shafts 3 are driven to synchronously rotate.

In order to ensure reliable connection between the material shaft 3 and the clutch 64, in this embodiment, a support seat 31, a power shaft 32 and a connection flange 33 are sequentially disposed at an end portion of the material shaft 3, and the support seat 31 is connected to the material shaft 3. The connecting flange 33 is connected to the clutch 64, and the power shaft 32 is connected to the support base 31 and the connecting flange 33, respectively. Through the above arrangement, the torque can be transmitted from the clutch 64 to the connecting flange 33, the power shaft 32 and the supporting seat 31 in order, and finally to the material shaft 3 to drive the material shaft 3 to rotate.

It should be noted that, in the above-mentioned setting, only the bottom of the material axle 3 is located and connected, when the material axle 3 works vertically, the top of the material axle 3 still needs to be located, in order to achieve the above-mentioned effect, in this embodiment, the top of the fixed frame 1 is also provided with the fixed cylinder 12, the top of the material axle 3 is provided with the locating bearing 34, the movable end of the fixed cylinder 12 is towards the locating bearing 34 sets up. The top of the fixed frame 1 is also provided with a fixed block, the fixed block corresponds to the fixed cylinder 12, when the material shaft 3 is in the vertical position, the positioning bearing 34 is positioned between the fixed cylinder 12 and the fixed block, the fixed cylinder 12 is started, and the positioning bearing 34 is clamped from two sides by matching with the fixed block so as to position the top end of the material shaft 3.

In order to ensure reliable connection of the material shaft 3 and the turnover plate 2, a supporting frame 35 is sleeved outside the material shaft 3, and the bottom of the supporting frame 35 is connected with the turnover plate 2.

It should be noted that, technical features such as other components of the vertical continuous coating apparatus according to the present utility model should be considered as the prior art, and specific structures, working principles, and control manners and spatial arrangements of the technical features may be selected conventionally in the art, and should not be considered as the point of the utility model of the present utility model, which is not further specifically described in detail.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (10)

1. Feeding and discharging turnover mechanism is characterized by comprising:

Fixed frame (1), fixed frame (1) inboard rotates and is provided with turnover plate (2), be suitable for installing loading axle (3) on turnover plate (2), turnover assembly (4) are installed in fixed frame (1) outside, the expansion end of turnover assembly (4) with turnover plate (2) are connected, and

The two ends of the stroke of the overturning assembly (4) are respectively provided with a first station and a second station; wherein the method comprises the steps of

When the overturning assembly (4) moves to the first station, the overturning plate (2) drives the material shaft (3) to a vertical position;

when the overturning assembly (4) moves to the second station, the overturning plate (2) drives the material shaft (3) to a horizontal position.

2. The loading and unloading turnover mechanism of claim 1, wherein,

The turnover assembly (4) comprises a fixed seat (41), an electric actuator (42) and a pull rod (43), wherein the fixed seat (41) is hinged to the outer side of the fixed frame (1), the electric actuator (42) is arranged on the fixed seat (41), and two ends of the pull rod (43) are respectively connected with the movable end of the electric actuator (42) and the end part of the turnover plate (2) in a rotating way; wherein the method comprises the steps of

When the pull rod (43) rotates to the position with the maximum travel in the forward direction, the pull rod is positioned at a first station;

and when the pull rod (43) reversely rotates to the position with the maximum travel, the pull rod is positioned at the second station.

3. The loading and unloading turnover mechanism of claim 2, wherein,

And a limiter (11) is further arranged on the outer side of the fixed frame (1), and the distance from the limiter (11) to the joint of the pull rod (43) and the turnover plate (2) is smaller than the length of the pull rod (43).

4. A vertical continuous coating equipment, which uses the feeding and discharging turnover mechanism as set forth in any one of claims 1-3,

The vertical continuous coating equipment comprises a bottom frame (5), wherein a plurality of feeding and discharging overturning assemblies (4) are arranged on the bottom frame (5);

both ends of the turnover plate (2) are provided with turnover bearings (21).

5. The vertical continuous coating apparatus according to claim 4, wherein,

The bottom of the turnover plate (2) is also provided with a mounting plate (22), the mounting plate (22) is suitable for being provided with a driving mechanism (6), and the movable end of the driving mechanism (6) is in transmission connection with the end part of the material shaft (3).

6. The vertical continuous coating apparatus according to claim 5, wherein,

The driving mechanism (6) comprises a driving motor (61), a speed reducer (62), a transmission wheel set and a clutch (64), wherein the driving motor (61) is installed on the installation plate (22), the speed reducer (62) is connected with the movable end of the driving motor (61), two sides of the transmission wheel set are respectively connected with the movable end of the speed reducer (62) and the input end of the clutch (64), and the output end of the clutch (64) is connected with the end of the material shaft (3).

7. The vertical continuous coating apparatus according to claim 6, wherein,

The transmission wheel set comprises two transmission wheels and a synchronous belt (63) sleeved on the two transmission wheels, and the two transmission wheels are respectively connected with the speed reducer (62) and the clutch (64).

8. The vertical continuous coating apparatus according to claim 6, wherein,

The end part of the material shaft (3) is sequentially provided with a supporting seat (31), a power shaft (32) and a connecting flange (33), the supporting seat (31) is connected with the material shaft (3), the connecting flange (33) is connected with the clutch (64), and the power shaft (32) is respectively connected with the supporting seat (31) and the connecting flange (33).

9. The vertical continuous coating apparatus according to claim 4, wherein,

The top of the fixed frame (1) is also provided with a fixed cylinder (12), the top of the material shaft (3) is provided with a positioning bearing (34), and the movable end of the fixed cylinder (12) is arranged towards the positioning bearing (34).

10. The vertical continuous coating apparatus according to claim 4, wherein,

The material shaft (3) is sleeved with a supporting frame (35), and the bottom of the supporting frame (35) is connected with the turnover plate (2).