CN112265243A - Graphene film forming machine - Google Patents

Abstract

The invention discloses a graphene film forming machine which structurally comprises a feeding hopper, a bearing table, a machine body, a winding roller and a compression rod, wherein the feeding hopper is fixedly embedded at the right position of the upper end of the compression rod, the bearing table is connected with the right side of the machine body, the compression rod is arranged at the upper end of the bearing table, the winding roller is movably clamped with the upper end of the machine body, when the winding roller is closed, a linkage roller can be pushed by an elastic strip to slide out and reset outwards, an external ring can be offset by the rotating force generated when the external ring is pulled backwards by a one-way plate, so that the external ring cannot be pulled backwards and rotated backwards by the instant backwards pulling force generated by the compression rod, when the winding roller stops rotating, an external expanding plate can be pulled by an external pushing sheet to be contracted and reset, therefore, a stress plate can be contracted inwards by the inertia force generated by the outward expansion plate resetting, and a hole on the stress plate can generate suction to the bottom of graphene, therefore, the graphene film can be adsorbed by the stress plate.

Description

Graphene film forming machine

Technical Field

The invention relates to the field of graphene processing equipment, in particular to a graphene film forming machine.

Background

Graphite alkene film forming machine mainly is the equipment that is used for carrying out extrusion to graphite alkene raw materials, through pouring graphite alkene raw materials into inside the hopper, outwards extrude the film through the compression rod again, and graphite alkene film is rotated to the wind-up roll at last and is collected, based on the above-mentioned description the inventor finds that a graphite alkene film forming machine of current mainly has following not enough, for example:

because the higher difficult fracture of hardness of graphite alkene, if graphite alkene film forming machine is extruding the graphite alkene film in-process, because of emergency stops fast, then can make and tighten in the twinkling of an eye between compression pole head and the wind-up roll, and still can produce the graphite alkene film on the wind-up roll and pull backward because of the compression pole produces backward in the twinkling of an eye after tightening to when making graphite alkene film forming machine open once more, the graphite alkene film of collection on the wind-up roll can produce the condition of loosing and collapsing.

Disclosure of Invention

In order to solve the above problems, the present invention provides a graphene film forming machine.

In order to achieve the purpose, the invention is realized by the following technical scheme: a graphene film forming machine structurally comprises a feeding hopper, a bearing table, a machine body, a winding roller and a compression rod, wherein the feeding hopper is fixedly embedded at the upper end of the compression rod close to the right, the bearing table is connected with the right side of the machine body, the compression rod is arranged at the upper end of the bearing table, and the winding roller is movably clamped with the upper end of the machine body; the winding roller comprises an inner connecting ring, an outer connecting ring, a linkage roller, a sleeve frame and an elastic strip, wherein the outer connecting ring and the inner connecting ring are of an integrated structure, the linkage roller is movably clamped with the sleeve frame, the sleeve frame is connected with the inner connecting ring, and the elastic strip is arranged between the linkage roller and the sleeve frame.

As a further optimization of the invention, the inner ring comprises a contact ring, a telescopic plate, boosting sheets and an inner fixing plate, the telescopic plate is in clearance fit with the contact ring, the boosting sheets are embedded and fixed between the bottom of the telescopic plate and the outer side of the inner fixing plate, and the four telescopic plates are uniformly distributed on the contact ring in a circular shape.

As a further optimization of the invention, the telescopic plate comprises a buffer plate, a bottom plate and a combination block, the buffer plate is hinged with the upper end of the combination block, the combination block is movably clamped with the upper end of the bottom plate, and a continuous triangular groove is formed in the buffer plate.

As a further optimization of the invention, the contact ring comprises a one-way plate, a rebound piece and a bearing ring, the one-way plate is movably clamped on the outer surface of the bearing ring, the rebound piece is arranged between the one-way plate and the bearing ring, and the one-way plate is made of nitrile rubber with high density.

As a further optimization of the invention, the external ring comprises an external expansion plate, four external pushing plates and a fixing ring, the external expansion plate is movably clamped with the outer side of the fixing ring, the external pushing plates are arranged between the external expansion plate and the fixing ring, and the external surfaces of the external expansion plates are uniformly distributed in a circular manner through the matching of the external pushing plates.

The outer expansion plate comprises a contact reducing groove, a plate block and an outer expansion plate, wherein the contact reducing groove and the outer expansion plate are of an integrated structure, the outer expansion plate is movably clamped with the plate block, and the outer expansion plate can slide outwards along the plate block through inertia force generated by outward extension of a mechanism.

As a further optimization of the invention, the overhanging plate comprises a deformation frame, a complex spring plate and a stress plate, wherein the deformation frame is fixedly embedded at the bottom of the inner wall of the stress plate, the complex spring plate is arranged between the stress plate and the deformation frame, and the stress plate is provided with a through hole inside and outside.

The invention has the following beneficial effects:

1. when the wind-up roll was closed, can promote the outside roll-off of linkage roller through the elastic strip and reset, and can promote the expansion plate through the boosting piece and reset to make the buffer board upper surface on the expansion plate closely laminate with the inboard concave surface of outer joint ring, the rethread unidirectional plate can offset outer joint ring pivoted power when being dragged backward, thereby make outer joint ring can not be by the compression pole production in the twinkling of an eye rearward dragging power rearward dragging the rotation.

2. Rotation that can follow the wind-up roll through expanding the board outward carries out one section distance expand outward, when the wind-up roll stall, can stimulate outward through outer kicking plate and expand the board and contract and reset, the institute makes the atress board can receive the inertia force that the outward flange resets and produces to the internal contraction, so that the hole that the atress board can be gone up can produce suction to the bottom of graphite alkene, thereby make graphite alkene film can be adsorbed by the atress board, when the effectual wind-up roll stall of having avoided, not hard up condition can appear in the graphite alkene film of wind-up roll surface.

Drawings

Fig. 1 is a schematic structural diagram of a graphene film forming machine according to the present invention.

FIG. 2 is a schematic structural view of a side-view half-section of the wind-up roll of the present invention.

FIG. 3 is a schematic side view of a linkage roller according to the present invention.

FIG. 4 is a side view of a half-section of the retractable plate of the present invention.

FIG. 5 is a schematic side view of a contact ring according to the present invention.

FIG. 6 is a schematic side view of the outer ring of the present invention.

FIG. 7 is a schematic structural diagram of a side view cross section of the outer expanding plate of the present invention.

FIG. 8 is a side view of the outrigger plate of the present invention.

In the figure: the device comprises a feeding hopper-1, a plummer-2, a machine body-3, a wind-up roll-4, a compression rod-5, an inner connecting ring-41, an outer connecting ring-42, a linkage roll-43, a sleeve frame-44, an elastic strip-45, a contact ring-a 1, a telescopic plate-a 2, a boosting sheet-a 3, an inner fixing plate-a 4, a buffer plate-a 21, a bottom plate-a 22, a combination block-a 23, a unidirectional plate-b 1, a rebound sheet-b 2, a bearing ring-b 3, an outer expansion plate-c 1, an outer push sheet-c 2, a fixing ring-c 3, a contact reduction groove-c 11, a plate-c 12, an outer extension plate-c 13, a deformation frame-d 1, a complex elastic sheet-d 2 and a stress plate-d 3.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

As shown in fig. 1-5:

the invention provides a graphene film forming machine which structurally comprises a feeding hopper 1, a bearing table 2, a machine body 3, a winding roller 4 and a compression rod 5, wherein the feeding hopper 1 is embedded at the upper end of the compression rod 5 close to the right, the bearing table 2 is connected with the right side of the machine body 3, the compression rod 5 is arranged at the upper end of the bearing table 2, and the winding roller 4 is movably clamped with the upper end of the machine body 3; the wind-up roll 4 includes an inner ring 41, an outer ring 42, a linking roll 43, a jacket frame 44, and an elastic strip 45, the outer ring 42 and the inner ring 41 are integrally formed, the linking roll 43 is movably engaged with the jacket frame 44, the jacket frame 44 is connected with the inner ring 41, and the elastic strip 45 is installed between the linking roll 43 and the jacket frame 44.

The inner ring 41 comprises a contact ring a1, a telescopic plate a2, a boosting sheet a3 and an inner fixed plate a4, the telescopic plate a2 is in clearance fit with the contact ring a1, the boosting sheet a3 is embedded and fixed between the bottom of the telescopic plate a2 and the outer side of the inner fixed plate a4, four telescopic plates a2 are arranged and evenly distributed on the contact ring a1 in a circular shape, and the boosting sheet a3 can push the telescopic plate a2 to be always attached to the inner side of an object.

Wherein, expansion plate a2 includes buffer board a21, bottom plate a22, combination piece a23, buffer board a21 and combination piece a 23's upper end hinged joint, combination piece a23 and bottom plate a 22's upper end activity block, be equipped with continuous triangle-shaped recess on the buffer board a21, can strengthen the power of grabbing to the object inner wall.

The contact ring a1 comprises a one-way plate b1, a rebound piece b2 and a bearing ring b3, the one-way plate b1 is movably clamped on the outer surface of the bearing ring b3, the rebound piece b2 is installed between the one-way plate b1 and the bearing ring b3, the one-way plate b1 is made of nitrile rubber with high density, and the rotation of an object can be rapidly stopped through the one-way plate b 1.

The detailed use method and action of the embodiment are as follows:

in the invention, the expansion plate a2 can be contracted inwards along the contact ring a1 by the extrusion of the expansion plate a2 on the linkage roller 43 when the external ring 42 on the winding roller 4 rotates, and the continuous pressing of the outer ring 42 against the linkage roller 43 can cause the linkage roller 43 to contract inwardly along the jacket frame 44, so that the external ring 42 can normally rotate, when the wind-up roll 4 is closed, the linkage roll 43 can be pushed by the elastic strip 45 to slide outwards and reset, and the expansion plate a2 can be pushed by the boosting sheet a3 to reset, so that the upper surface of the buffer plate a21 on the expansion plate a2 can be tightly attached to the inner concave surface of the outer ring 42, the force of the external ring 42 which rotates continuously due to inertia can be swung and buffered by the buffer plate a21, the force of the external ring 42 which rotates when pulled backwards can be offset by the one-way plate b1, so that the circumscribing ring 42 is not pulled rotationally rearward by the momentary rearward pulling force generated by the compression rod 5.

Example 2

As shown in fig. 6-8:

the outer ring 42 comprises an outer expansion plate c1, an outer pushing plate c2 and a fixing ring c3, the outer expansion plate c1 is movably clamped with the outer side of the fixing ring c3, the outer pushing plate c2 is installed between an outer expansion plate c1 and a fixing ring c3, the number of the outer expansion plates c1 is four, the outer surfaces of the fixing ring c3 are uniformly distributed in a circular shape through the matching of the outer pushing plate c2, and the outer expansion plate c1 can be expanded through the throwing force generated by rotation of the mechanism.

The outward expansion plate c1 comprises a contact reducing groove c11, a plate c12 and an outward expansion plate c13, the contact reducing groove c11 and the outward expansion plate c13 are of an integrated structure, the outward expansion plate c13 is movably clamped with the plate c12, the outward expansion plate c13 can slide out along the plate c12 due to the inertia force generated by outward expansion of the mechanism, and the outward expansion plate c13 can be synchronously reset along with the mechanism when the mechanism is contracted and reset.

The overhanging plate c13 comprises a deformation frame d1, a double-spring sheet d2 and a stress plate d3, the deformation frame d1 is embedded at the bottom of the inner wall of the stress plate d3, the double-spring sheet d2 is installed between the stress plate d3 and the deformation frame d1, an inner through hole and an outer through hole are formed in the stress plate d3, the stress plate d3 is squeezed by an object, the stress plate d3 can contract inwards, and therefore inward air flow can be generated to adsorb the bottom of the object when the double-spring sheet d2 pushes the stress plate d3 to reset upwards.

The detailed use method and action of the embodiment are as follows:

in the invention, when the graphene film is collected by the rotation of the wind-up roll 4, the graphene film on the wind-up roll 4 is low in mass just before the wind-up roll 4 starts to rotate, so that the gripping force of the film on the surface of the wind-up roll 4 is reduced, if the wind-up roll 4 stops rotating, the graphene film is easy to loosen on the wind-up roll 4, the outward expansion plate c1 can expand for a certain distance along with the rotation of the wind-up roll 4, so that the outward extending plate c13 can slide out along the plate c12 along with the outward expanding inertial force of the outward expanding plate c1, when the wind-up roll 4 stops rotating, the outward extending plate c1 can be pulled by the outward pushing sheet c2 to contract and reset, so that the outward extending plate c13 can also synchronously reset, and the stressed plate d3 can contract inwards under the inertial force generated by the outward extending plate c13 resetting, so that the holes on the stressed plate d3 can generate suction force to the bottom of the graphene, thereby make the graphite alkene film can be adsorbed by atress board d3 and live, when the effectual wind-up roll 4 stall of having avoided, not hard up condition can appear in the graphite alkene film of 4 surfaces of wind-up roll.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims (7)

1. The utility model provides a graphite alkene film forming machine, its structure includes goes into hopper (1), plummer (2), organism (3), wind-up roll (4), compression pole (5), go into hopper (1) and inlay in the upper end of compression pole (5) and lean on right position, plummer (2) are connected with the right side of organism (3), the upper end position in plummer (2), its characterized in that are installed in compression pole (5): the winding roller (4) is movably clamped with the upper end of the machine body (3);

the winding roller (4) comprises an inner connecting ring (41), an outer connecting ring (42), a linkage roller (43), a sleeve frame (44) and an elastic strip (45), the outer connecting ring (42) and the inner connecting ring (41) are of an integrated structure, the linkage roller (43) is movably clamped with the sleeve frame (44), the sleeve frame (44) is connected with the inner connecting ring (41), and the elastic strip (45) is installed between the linkage roller (43) and the sleeve frame (44).

2. The graphene film forming machine according to claim 1, wherein: the inner ring (41) comprises a contact ring (a1), an expansion plate (a2), a boosting sheet (a3) and an inner fixing plate (a4), wherein the expansion plate (a2) is in clearance fit with the contact ring (a1), and the boosting sheet (a3) is embedded between the bottom of the expansion plate (a2) and the outer side of the inner fixing plate (a 4).

3. The graphene film forming machine according to claim 2, wherein: the expansion plate (a2) comprises a buffer plate (a21), a bottom plate (a22) and a combination block (a23), wherein the buffer plate (a21) is hinged with the upper end of the combination block (a23), and the combination block (a23) is movably clamped with the upper end of the bottom plate (a 22).

4. The graphene film forming machine according to claim 2, wherein: the contact ring (a1) comprises a one-way plate (b1), a rebound sheet (b2) and a bearing ring (b3), the one-way plate (b1) is movably clamped at the outer surface position of the bearing ring (b3), and the rebound sheet (b2) is installed between the one-way plate (b1) and the bearing ring (b 3).

5. The graphene film forming machine according to claim 1, wherein: the external ring (42) comprises an external expanding plate (c1), an external pushing sheet (c2) and a fixing ring (c3), the external expanding plate (c1) is movably clamped with the outer side of the fixing ring (c3), and the external pushing sheet (c2) is installed between the external expanding plate (c1) and the fixing ring (c 3).

6. The graphene film forming machine according to claim 5, wherein: the outward expansion plate (c1) comprises a contact reduction groove (c11), a plate (c12) and an outward expansion plate (c13), wherein the contact reduction groove (c11) and the outward expansion plate (c13) are of an integrated structure, and the outward expansion plate (c13) is movably clamped with the plate (c 12).

7. The graphene film forming machine according to claim 6, wherein: the outer extending plate (c13) comprises a deforming frame (d1), a complex spring plate (d2) and a stress plate (d3), the deforming frame (d1) is embedded in the bottom position of the inner wall of the stress plate (d3), and the complex spring plate (d2) is installed between the stress plate (d3) and the deforming frame (d 1).

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