CN111037906A - Hot embossing polyethylene film production equipment - Google Patents

Abstract

The invention discloses a hot embossing polyethylene film production device, which structurally comprises side guard plates, an embossing hot rod, an auxiliary cylinder, a rotating box and a winding cylinder, wherein the embossing hot rod is propped between the side guard plates, the auxiliary cylinder is arranged below the embossing hot rod, a film propped against the embossing hot rod controls the total heat conduction temperature rise through a control box, the temperature of the film is conducted to an embossing head, the film is embossed, the outer layer of the layer contacted with the polyethylene film can be pressed to form marks, the corner of the layer is subjected to temperature protection through a temperature insulation angle to prevent the film from being overheated and broken, a colloid is connected with the film to perform counterforce protection, the inclination ball of the colloid limits the propping direction of the film, the integral moving range is controlled, the forward pushing angle forms a certain angle, the film adhered to the embossing head is pushed down according to the pushing change required by the movement of an external object, when the hot embossing is performed on the polyethylene film, when the adhesive tape is stuck on the pressure head, the adhesive tape is pushed down by the fixed block on the side edge in a tilting way, so that the adhesive tape cannot be stacked with an untreated surface.

Description

Hot embossing polyethylene film production equipment

Technical Field

The invention belongs to the field of polyethylene processing equipment, and particularly relates to equipment for producing a hot embossing polyethylene film.

Background

When the polyethylene film is in the embossing production process, the pressure head for processing the polyethylene film needs a certain heat degree, the polyethylene is softened and then molded, the polyethylene film recovered by the pressure head is continuously conveyed, cooled and fixed, and the whole polyethylene film is rolled up.

Based on the findings of the inventor, the existing embossed film production equipment mainly has the following defects, such as:

the original elasticity of the polyethylene film can be brought up by the pressure head through excessive softening by the residual heat in the processing process of the pressure head, so that the softened part is embossed and leveled with other parts to form wrinkles, and the wrinkles can be compacted in subsequent transportation to cause the forming effect.

Therefore, it is necessary to provide a hot embossing polyethylene film production apparatus.

Disclosure of Invention

In order to solve the problem that the original elasticity of the polyethylene film can be brought up by the pressure head due to excessive softening of residual heat in the processing process of the pressure head, so that the softened part is embossed and leveled with other parts to form wrinkles, and the wrinkles can be compacted in subsequent transportation to cause the forming effect.

The invention relates to a hot embossing polyethylene film production device, which is realized by the following specific technical means:

the structure of the device comprises a side guard plate, an embossing hot rod, an auxiliary barrel, a rotary box, a furling barrel, a supporting plate rod, a base and a control box.

The knurling hot rod supports between the side guard plate, assist a section of thick bamboo and locate knurling hot rod below, the roll-up section of thick bamboo is embedded in changeing incasement portion, the one end that the roll-up section of thick bamboo kept away from changeing the case is connected with the layer board pole, the layer board pole is installed in the base upper surface, accuse case welds in the side guard plate surface.

The embossing hot rod comprises a total thermal guide, an embossing head, a spacer ring and a resisting block, wherein the total thermal guide is embedded in the spacer ring and is positioned on the same axis, the total thermal guide is connected with the embossing head, and the resisting block is arranged on the outer side of the total thermal guide.

As a further improvement of the invention, the embossing head comprises a main guide ball, a middle uniform body, an outer protective shell, a temperature insulation angle, a temperature conduction layer, a temperature expansion body and a heat insulation connection body, wherein the main guide ball is connected with the middle uniform body, the middle uniform body is embedded in the outer protective shell, the temperature conduction layer is connected with the temperature expansion body, the outer surface of the temperature expansion body is connected with the heat insulation body, the side of the temperature expansion body is provided with the temperature insulation angle, the temperature expansion bodies are provided with four or two groups, the main guide ball is provided with two or a spherical structure, and the heat insulation bodies are provided with four or two groups.

As a further improvement of the invention, the abutting block comprises a front pushing angle, a spacing block, a push-back rod, an extending head, a spacing shell and a back tightening core, the spacing block is connected with the push-back rod, the front pushing angle abuts against the outer surface of the push-back rod, the extending head is attached to the outer surface of the push-back rod, the back tightening core is connected with the spacing shell, the number of the front pushing angles is two, the spacing shell is of a semi-arc structure, and the number of the back pushing rods is two.

As a further improvement of the invention, the push-back rod comprises extension support angles, inclined balls, a pocket shell and an unfolding stack, the extension support angles are attached to the outer surface of the pocket shell, the inclined balls are embedded into the pocket shell, the unfolding stack is arranged on the outer surface of the pocket shell, the inclined balls are of a spherical structure and are six in number, the number of the unfolding stack is three, and the extension support angles are made of rubber materials and have certain flexibility.

As a further improvement of the invention, the forward pushing angle comprises a hard head, a stable core, a swing strip, an arc strip, a connecting colloid and all-position receptors, wherein the stable core is abutted against the inner wall of the hard head, the swing strip is connected with the stable core, the connecting colloid is attached to the outer surface of the all-position receptors, the all-position receptors are embedded in the arc strip, the stable core is of a spherical structure, and the all-position receptors are of an elliptical structure and are four in number.

As a further improvement of the invention, the return core comprises a stable protection arc, a stable core angle and a variable layer, wherein the stable core angle is embedded in the variable layer, the variable layer is connected with the stable protection arc, and the number of the stable protection arc is two.

Compared with the prior art, the invention has the following beneficial effects:

the film which is abutted against the embossing hot rod controls the total heat conduction to be heated through the control box, the temperature is conducted to the embossing head, embossing the film to make the contact surface between the outer layer and the polyethylene film have marks, and the corners are protected by the insulating angle to prevent the film from being broken due to overheating, when the polyethylene film is embossed and needs to be conveyed away from the embossing head, the full-position receptor swings together with the pulling change of the full-position receptor, the colloid is connected with the rubber body to carry out counter force protection, the inclined ball can limit the collision direction of the colloid, the whole moving range is controlled, the forward pushing angle is in a certain angle, the film adhered on the embossing head is pushed down according to the pushing change required by the movement of the foreign object, when the hot embossing is carried out on the polyethylene film and the polyethylene film is stuck on the pressure head, the polyethylene film is pushed down by the fixed block on the side edge in a tilting manner, so that the polyethylene film cannot be stacked with an untreated surface.

Drawings

FIG. 1 is a schematic structural diagram of a hot embossing polyethylene film production apparatus according to the present invention.

FIG. 2 is a schematic diagram of the right-view internal structure of an embossing hot bar according to the present invention.

FIG. 3 is a front view of an embossing head according to the present invention.

Fig. 4 is a schematic front view of an internal structure of a block according to the present invention.

Fig. 5 is a schematic front view of an internal structure of a push rod according to the present invention.

FIG. 6 is a schematic view of an elevation view of an internal structure of a push-forward angle of the present invention.

Fig. 7 is a schematic front view of the internal structure of the core for elastic tightening.

In the figure: side guard plate-11, embossing hot rod-22, auxiliary barrel-33, rotating box-44, winding barrel-55, supporting plate rod-66, base-77, control box-88, total heat conduction-aa 1, embossing head-aa 2, spacer ring-aa 3, supporting block-aa 4, total guide ball-w 1, middle even body-w 2, outer protective shell-w 3, temperature insulation angle-w 4, temperature conduction layer-w 5, temperature expansion body-w 6, insulation body-w 6, forward push angle-qw 6, spacer block-qw 6, push back rod-qw 6, extension head-qw 6, insulation shell-qw 6, tightening core-w 6, extension angle-z 6, inclination ball-z 6, pocket shell-z 6, folding-z 6, hard head-g 6, stable core-g 6, stable bar-tt 6, stable bar-6, stable arc connection layer 6 and stable bar-tt-6.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example (b):

as shown in figures 1 to 7:

the invention provides hot embossing polyethylene film production equipment which structurally comprises a side guard plate 11, an embossing hot rod 22, an auxiliary barrel 33, a rotating box 44, a winding barrel 55, a supporting plate rod 66, a base 77 and a control box 88.

The embossing hot rod 22 is abutted between the side guard plates 11, the auxiliary drum 33 is arranged below the embossing hot rod 22, the winding drum 55 is embedded in the rotating box 44, one end, far away from the rotating box 44, of the winding drum 55 is connected with the supporting plate rod 66, the supporting plate rod 66 is installed on the upper surface of the base 77, and the control box 88 is welded on the outer surface of the side guard plates 11.

The embossing hot rod 22 comprises a total thermal guide aa1, an embossing head aa2, a spacer ring aa3 and a resisting block aa4, wherein the total thermal guide aa1 is embedded inside the spacer ring aa3 and is positioned on the same axis, the total thermal guide aa1 is connected with the embossing head aa2, and the resisting block aa4 is installed on the outer side of the total thermal guide aa 1.

The embossing head aa2 comprises a total guide ball w1, a middle uniform body w2, an outer protective shell w3, a heat insulation angle w4, a heat conduction layer w5, a temperature expansion body w6 and a heat insulation connection body w7, wherein the total guide ball w1 is connected with the middle uniform body w2, the middle uniform body w2 is embedded inside the outer protective shell w3, the heat conduction layer w5 is connected with a temperature expansion body w6, the outer surface of the temperature expansion body w6 is connected with the heat insulation connection body w7, the heat insulation angle w4 is arranged on the lateral side of the temperature expansion body w6, four temperature expansion bodies w6 are arranged in a group, two temperature expansion bodies w 53 are arranged in a spherical structure, four temperature insulation bodies w7 are arranged in a group, the temperature generated inside the outer protective shell w3 is isolated from the outside, the total guide ball w1 conducts certain temperature contact, the temperature of the inner guide ball w 7377 is converged to a certain degree, and the temperature of the heat insulation bodies w 8472 can be uniformly contacted with the temperature expansion angle w 8458 and can be reduced.

The resisting block aa4 comprises a forward pushing angle qw1, a spacer qw2, a push-back rod qw3, a delaying head qw4, a spacer qw5 and a tightening core qw6, the spacer qw2 is connected with the push-back rod qw3, the forward pushing angle qw1 abuts against the outer surface of the push-back rod qw3, the delaying head qw4 abuts against the outer surface of the push-back rod qw3, the tightening core qw6 is connected with the spacer qw5, the number of the forward pushing angles qw1 is two, the spacer qw5 is of a semi-arc structure, the number of the push-back rod qw3 is two, the spacer qw2 limits the moving range of the inner part, the push-back rod qw3 generates qdeformation according to the abutting force, the tightening core is timely abutted when the resistance is lost, the forward pushing angle w1 generates the required pushing change according to the movement of an object, the tightening core is timely pushed back at the tightening state when the tightening resistance is lost, and the tightening core 6 is timely at the boundary.

The jacking rod qw3 comprises a support angle z01, an inclined ball z02, a pocket shell z03 and an unfolding angle z04, wherein the support angle z01 is attached to the outer surface of the pocket shell z03, the inclined ball z02 is embedded into the pocket shell z03, the unfolding angle z04 is installed on the outer surface of the pocket shell z03, the inclined ball z02 is of a sphere structure and is six, the number of the unfolding angle z04 is three, the support angle z01 is made of rubber materials and has certain flexibility, the inclined ball z02 controls the whole moving range, the pocket shell z03 changes together according to the swinging of the inner part, the unfolding angle z04 extends according to the change of external force collision, and the support angle z01 plays a role in protecting the joint part of the support angle z 01.

The front pushing angle qw1 comprises a hard head g11, a stable core g22, a swinging strip g33, an arc strip g44, a connecting colloid g55 and an all-position receptor g66, the stable core g22 abuts against the inner wall of the hard head g11, the swinging strip g33 is connected with the stable core g22, the connecting colloid g55 is attached to the outer surface of the all-position receptor g66, the all-position receptor g66 is embedded into the arc strip g44, the stable core g22 is of a spherical structure, the all-position receptor g66 is of an oval structure and is provided with four, the hard head g11 provides overall holding force for abutting against the outside, the stable core g22 swings according to the direction of force, the swinging strip g33 plays a role in buffering and following when moving to the connected position, and the all-position receptor g66 can hold the external force abutting against each position.

The elastic core qw6 comprises a stable protection arc tt1, a stable core angle tt2 and a variable layer tt3, wherein the stable core angle tt2 is embedded in the variable layer tt3, the variable layer tt3 is connected with the stable protection arc tt1, two stable protection arcs tt1 are arranged, the stable core angle tt2 can stabilize the bearing force of the outer layer, the stable protection arc tt1 plays a role in buffering and protection when the joint part moves, and the variable layer tt3 changes together according to the change of the inner part.

The specific use mode and function of the embodiment are as follows:

in the invention, a polyethylene film is wound on the auxiliary cylinder 33, is wound by the winding cylinder 55 around the position between the embossing hot rods 22, is continuously wound by the winding cylinder 55, and simultaneously, the film abutted against the embossing hot rods 22 is heated by the total heat conduction aa1 controlled by the control box 88, the temperature of the film is guided to the embossing head aa2, embossing processing is carried out on the film, the middle uniform body w2 in contact with the total heat conduction aa1 transmits the temperature to the total guide ball w1, the temperature of the outer layer is diffused by the temperature expansion body w6 and the temperature guide layer w5, the layer surface of the outer layer in contact with the polyethylene film can be stamped, the corners are protected by the temperature isolation angle w4 to prevent the film from being overheated and broken, when the polyethylene film is conveyed to the embossing head aa2, some films which are excessively softened and are adhered by the embossing head qaa 2, and when the abutting block 4 continuously rotates, the corners are pushed forward to the adhered to the parts 1, the all-position receptor g66 swings together with the pulling change of the all-position receptor g66, the colloid g55 is connected with the colloid g55 for counter force protection, when the collision force is exerted on the swing strip g33 by the arc strip g44, the stable core g22 collides the hard head g11, the hard head g11 is limited by the spacer qw2, the hard head g11 skims in the direction of the push-back rod qw3, the collision direction of the stable core g22 is limited by the inclined ball z02, the stable core g 04 moves along the unfolding z04 to compress the unfolding z04, the forward push angle qw1 pulls the stretching core qw6, the follow-up layer tt3 gives the whole body to the stable core g 6324, and the forward push angle qw1 forms a certain counter force and pushes down the film adhered to the embossing head aa 2.

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 (6)

1. The utility model provides a hot knurling polyethylene film production facility, its structure includes side guard plate (11), knurling hot rod (22), assists a section of thick bamboo (33), changes case (44), a roll-up section of thick bamboo (55), layer board pole (66), base (77), accuse case (88), its characterized in that:

the embossing hot rod (22) abuts between the side guard plates (11), the auxiliary drum (33) is arranged below the embossing hot rod (22), the winding drum (55) is embedded in the rotating box (44), one end, far away from the rotating box (44), of the winding drum (55) is connected with the supporting plate rod (66), the supporting plate rod (66) is installed on the upper surface of the base (77), and the control box (88) is welded on the outer surface of the side guard plates (11);

the embossing hot rod (22) comprises a total thermal guide (aa1), an embossing head (aa2), a spacer ring (aa3) and a resisting block (aa4), wherein the total thermal guide (aa1) is embedded in the spacer ring (aa3) and is positioned on the same axis, the total thermal guide (aa1) is connected with the embossing head (aa2), and the resisting block (aa4) is installed on the outer side of the total thermal guide (aa 1).

2. The apparatus for producing a thermally embossed polyethylene film according to claim 1, wherein: the embossing head (aa2) comprises a main guide ball (w1), a middle uniform body (w2), an outer protective shell (w3), a temperature insulation angle (w4), a temperature insulation layer (w5), a temperature expansion body (w6) and a temperature insulation body (w7), wherein the main guide ball (w1) is connected with the middle uniform body (w2), the middle uniform body (w2) is embedded into the outer protective shell (w3), the temperature insulation layer (w5) is connected with the temperature expansion body (w6), the outer surface of the temperature expansion body (w6) is connected with the temperature insulation body (w7), and the side of the temperature expansion body (w6) is provided with the temperature insulation angle (w 4).

3. The apparatus for producing a thermally embossed polyethylene film according to claim 1, wherein: the resisting block (aa4) comprises a forward pushing angle (qw1), a spacer block (qw2), a push-back rod (qw3), a delaying head (qw4), a spacer shell (qw5) and a pull-back core (qw6), the spacer block (qw2) is connected with the push-back rod (qw3), the forward pushing angle (qw1) is abutted against the outer surface of the push-back rod (qw3), the delaying head (qw4) is attached to the outer surface of the pull-back rod (qw3), and the pull-back core (qw6) is connected with the spacer shell (qw 5).

4. The apparatus for producing a thermally embossed polyethylene film according to claim 3, wherein: the jacking rod (qw3) comprises an extension angle (z01), an inclination ball (z02), a pocket shell (z03) and an unfolding device (z04), wherein the extension angle (z01) is attached to the outer surface of the pocket shell (z03), the inclination ball (z02) is embedded in the pocket shell (z03), and the unfolding device (z04) is mounted on the outer surface of the pocket shell (z 03).

5. The apparatus for producing a thermally embossed polyethylene film according to claim 3, wherein: it includes hard head (g11), steady core (g22), pendulum strip (g33), arc (g44), connects colloid (g55), all-position acceptor (g66) to push forward angle (qw1), steady core (g22) is supported at hard head (g11) inner wall, pendulum strip (g33) is connected with steady core (g22), connect colloid (g55) to laminate in all-position acceptor (g66) surface, all-position acceptor (g66) imbeds inside arc (g 44).

6. The apparatus for producing a thermally embossed polyethylene film according to claim 3, wherein: the back tightening core (qw6) comprises a stable protection arc (tt1), a stable core angle (tt2) and a variable layer (tt3), wherein the stable core angle (tt2) is embedded in the variable layer (tt3), and the variable layer (tt3) is connected with the stable protection arc (tt 1).

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