CN112297413A - Insulating film of electric power structure casing pastes and establishes device - Google Patents

Abstract

The invention relates to an insulating film attaching device of a power structure shell. The insulating film of electric power structure casing pastes and establishes device is including the installation component, press from both sides the subassembly, cut membrane module and pad pasting subassembly, the installation component includes the base plate, two mounting brackets and locating plate, two mounting brackets are installed perpendicularly respectively in the relative both ends of base plate, the relative both ends of locating plate are fixed in the middle part of two mounting brackets respectively, the locating plate is used for supporting location electric power structure casing, press from both sides the unit mount in the middle part of one of them mounting bracket, be used for pressing from both sides the insulating film area, so that the insulating film area is in on the top surface of electric power structure casing, cut the membrane module including the cutting motor, the connecting axle, the installation axle, the action wheel, from the driving wheel, driving strip and bar cutter, the. The cutting and film pasting efficiency of the insulating film pasting device of the electric power structure shell is higher.

Description

Insulating film of electric power structure casing pastes and establishes device

Technical Field

The invention relates to an insulating film attaching device of a power structure shell.

Background

Plastic products are made of plastics and are polymeric compounds (macromolecules) polymerized by polyaddition or polycondensation, commonly known as plastics (plastics) or resins (resins). The composition and the shape and the style can be freely changed. It is composed of synthetic resin, filler, plasticizer, stabilizer, lubricant and pigment. In electronic products, a general power structural housing is made of a plastic product, such as a plastic inner shell or a plastic outer shell, to achieve the effects of encapsulation/insulation/packaging/isolation/sealing. The insulation film is required to be attached to the power structure casing for insulation, and the operation of attaching the insulation film is generally performed manually, which is inefficient.

Disclosure of Invention

Accordingly, there is a need for an insulating film laminating apparatus for an electric power structure case with high film laminating efficiency.

An insulating film pasting device of an electric power structure shell comprises a mounting assembly, a clamping and conveying assembly, a film cutting assembly and a film pasting assembly, wherein the mounting assembly comprises a base plate, two mounting frames and a positioning plate, the two mounting frames are respectively and vertically mounted at the two opposite ends of the base plate, the two opposite ends of the positioning plate are respectively fixed at the middle parts of the two mounting frames, the positioning plate is used for supporting and positioning the electric power structure shell, the clamping and conveying assembly is mounted at the middle part of one of the mounting frames and is used for clamping and conveying an insulating film strip so that the insulating film strip is positioned on the top surface of the electric power structure shell, the film cutting assembly comprises a cutting motor, a connecting shaft, a mounting shaft, a driving wheel, a driven wheel, a transmission strip and a strip-shaped cutter, the cutting motor is mounted at the top part of one of the mounting frames, the installation axle is located the below of locating plate, install respectively in the lower part of two mounting brackets at the relative both ends of installation axle, the connecting axle is located to the action wheel fixed sleeve, locate from the driving wheel cover epaxial, the action wheel is located to the transmission strip cover and follows the driving wheel, the bar cutter is installed on the transmission strip, the pad pasting subassembly is used for pressing the insulating film area in the top surface of electric power structure casing, the cutting motor is used for driving the action wheel rotation through the connecting axle, and then drive the insulating film area of the relative both sides of top surface of electric power structure casing successively through the rotation of transmission strip, in order to form the insulating film piece of separation.

In one embodiment, a rectangular frame is formed in the middle of each mounting frame, a rectangular column is arranged at the bottom of each rectangular frame in an upward protruding mode, and two opposite ends of the positioning plate are fixed to the two rectangular columns respectively.

In one embodiment, a cross beam is transversely and convexly arranged on the top of one of the mounting frames, the film sticking assembly comprises a lifting cylinder and a holding pressure plate, the lifting cylinder is arranged at the end part of the cross beam, and the holding pressure plate is arranged on an output shaft of the lifting cylinder.

In one embodiment, the outer diameter of the driving wheel is equal to the outer diameter of the driven wheel, the width of the positioning plate is larger than the width of the positioning plate, the cross section of the transmission strip is rectangular, a connecting rod is arranged at one end of the strip-shaped cutter in a protruding mode, and the connecting rod is vertically fixed on the transmission strip.

In one embodiment, the driving wheel and the driven wheel have the same structure, the circumferential surface of the driving wheel is a circular ring surface, one side of the circular ring surface is convexly provided with an annular rib, the transmission strip is in an annular runway shape, and two opposite ends of the transmission strip are respectively sleeved on the circular ring surface of the driving wheel and the circular ring surface of the driven wheel.

In one embodiment, the connecting rod is positioned on one side of the transmission bar far away from the annular rib, a rectangular positioning area is formed on the positioning plate, the pressure holding plate is rectangular plate-shaped, and the positioning area is positioned right below the pressure holding plate.

In one embodiment, a rectangular receiving groove is concavely formed in the middle of the upper surface of the base plate, wherein the mounting frame with the cross beam is defined as a main mounting frame, and a guide frame is convexly formed in the middle of the other mounting frame in the transverse direction and extends towards the main mounting frame.

In one embodiment, a transverse beam is vertically fixed at the end part of the guide frame, cantilever beams are vertically and convexly arranged at two opposite ends of the transverse beam respectively, and the two cantilever beams are parallel to each other and are respectively positioned below two opposite sides of the pressure holding plate.

In one embodiment, a clearance groove is concavely arranged on one side, facing the main mounting frame, of each cantilever beam, a sliding groove is concavely arranged on the top of the rectangular frame of the main mounting frame, each clamping and conveying assembly comprises a rotating motor, a lead screw, a guide sliding block, a cross rod and a clamping finger cylinder, the rotating motors are fixedly arranged at one ends of the sliding grooves, one ends of the lead screws are fixed on output shafts of the rotating motors, the other ends of the lead screws are fixed at one ends, far away from the rotating motors, of the sliding grooves, the guide sliding blocks are slidably arranged in the sliding grooves and are sleeved on the lead screws in a threaded mode, the cross rods are convexly arranged on the.

In one embodiment, the clamping finger cylinder is installed at one end, far away from the guide sliding block, of the cross rod, two clamping pieces are arranged on the clamping finger cylinder in a protruding mode, the main body of the clamping finger cylinder is aligned to the clearance groove of the cantilever beam, and the clamping finger cylinder is used for closing the two clamping pieces to clamp the insulating film strip.

When the electric power structure shell is used, the transmission mechanism is utilized to convey the electric power structure shell from the middle of one of the mounting frames to the positioning plate to be positioned, the electric power structure shell is located below the film pasting component, then the insulating film strip is clamped and conveyed by the clamping and conveying component, the insulating film strip is located on the top surface of the electric power structure shell, the film pasting component presses the insulating film strip on the top surface of the electric power structure shell to perform film pasting operation, the cutting motor drives the driving wheel to rotate through the connecting shaft, and then the strip-shaped cutters are driven to sequentially cut the insulating film strips on the two opposite sides of the top surface of the electric power structure shell through rotation of the transmission strips to form separated insulating films. Through setting up and pressing from both sides the send subassembly, cut membrane module and pad pasting subassembly to realize the automation of transmission, cutting and the pad pasting operation in insulating film area, improved cutting and pad pasting efficiency.

Drawings

Fig. 1 is a side view of an insulating film attaching apparatus of an electric power structure case according to an embodiment.

Fig. 2 is a schematic perspective view of an insulating film attaching device of an electric power structure casing according to an embodiment.

Fig. 3 is a perspective view of another view of the insulation film attaching apparatus of the power structure casing shown in fig. 2.

Fig. 4 is a partially enlarged view of a portion a in fig. 2.

Detailed Description

Referring to fig. 1 to 4, an insulating film pasting device for an electric power structure shell comprises a mounting assembly 10, a clamping and conveying assembly 20, a film cutting assembly 30 and a film pasting assembly 40, wherein the mounting assembly 10 comprises a base plate 11, two mounting frames 13 and a positioning plate 14, the two mounting frames 13 are respectively vertically mounted at two opposite ends of the base plate 11, two opposite ends of the positioning plate 14 are respectively fixed at the middle parts of the two mounting frames 13, the positioning plate 14 is used for supporting and positioning the electric power structure shell, the clamping and conveying assembly 20 is mounted at the middle part of one of the mounting frames 13 and is used for clamping and conveying an insulating film strip 100, so that the insulating film strip 100 is positioned on the top surface of the electric power structure shell, the film cutting assembly 30 comprises a cutting motor 31, a connecting shaft 32, a mounting shaft 33, a driving wheel 34, a driven wheel 35, a transmission bar 36 and a bar-shaped cutter 37, the cutting motor 31 is mounted at the, one end of the connecting shaft 32, which is far away from the mounting frames 13, is coaxially fixed on an output shaft of the cutting motor 31, the mounting shaft 33 is located below the positioning plate 14, two opposite ends of the mounting shaft 33 are respectively installed at the lower parts of the two mounting frames 13, the driving wheel 34 is fixedly sleeved on the connecting shaft 32, the driven wheel 35 is sleeved on the mounting shaft 33, the driving wheel 34 and the driven wheel 35 are sleeved with the transmission bars 36, the bar-shaped cutters 37 are installed on the transmission bars 36, the film pasting component 40 is used for pressing the insulating film strips 100 on the top surface of the electric power structure shell, the cutting motor 31 is used for driving the driving wheel 34 to rotate through the connecting shaft 32, and then the bar-shaped cutters 37 are driven to rotate through the transmission bars 36 to sequentially cut the insulating film strips 100.

When the electric power structure shell is used, a transmission mechanism is utilized to convey the electric power structure shell from the middle of one of the mounting frames 13 to the positioning plate 14 for positioning, so that the electric power structure shell is located below the film pasting component 40, then the clamping and conveying component 20 clamps and conveys the insulating film strip 100, so that the insulating film strip 100 is located on the top surface of the electric power structure shell, then the film pasting component 40 presses the insulating film strip 100 on the top surface of the electric power structure shell to perform film pasting operation, the cutting motor 31 drives the driving wheel 34 to rotate through the connecting shaft 32, and then the driving strip 36 rotates to drive the strip-shaped cutter 37 to cut the insulating film strips 100 on the two opposite sides of the top surface of the electric power structure shell successively so as to form separated insulating films. Through the arrangement of the clamping and conveying assembly 20, the film cutting assembly 30 and the film pasting assembly 40, the automation of the transmission, cutting and film pasting operations of the insulating film strip 100 is realized, and the cutting and film pasting efficiency is improved.

For example, in order to facilitate the installation of the positioning plate 14, a rectangular frame 133 is formed at the middle portion of each mounting bracket 13, a rectangular column 135 is protruded upward from the bottom portion of each rectangular frame 133, and opposite ends of the positioning plate 14 are respectively fixed to the two rectangular columns 135. The top of one of the mounting frames 13 is transversely provided with a cross beam 138 in a protruding manner, the film sticking assembly 40 comprises a lifting cylinder 41 and a holding plate 43, the lifting cylinder 41 is mounted at the end part of the cross beam 138, and the holding plate 43 is mounted on an output shaft of the lifting cylinder 41. The outer diameter of the driving wheel 34 is equal to the outer diameter of the driven wheel 35, the width of the positioning plate 14 and the cross section of the transmission strip 36 are both larger than a rectangle, a connecting rod 375 is arranged at one end of the strip-shaped cutter 37 in a protruding mode, and the connecting rod 375 is vertically fixed on the transmission strip 36. The driving wheel 34 and the driven wheel 35 have the same structure, the circumferential surface of the driving wheel 34 is a circular ring surface 341, one side of the circular ring surface 341 is convexly provided with an annular rib 345, the transmission strip 36 is in an annular runway shape, and the opposite two ends of the transmission strip are respectively sleeved on the circular ring surface 341 of the driving wheel 34 and the circular ring surface 341 of the driven wheel 35. The connecting rod 375 is located on the side of the drive bar 36 remote from the annular rib 345. By providing rectangular posts 135 within the two rectangular frames 133, it is facilitated to secure the opposite ends of the retaining plate 14 with the two rectangular posts 135, thereby facilitating the transfer and positioning of the electrical power structural housing. And the annular rib 345 is positioned at a side far away from the strip-shaped cutter 37, so that the movement of the strip-shaped cutter 37 can be prevented from being hindered, and the transmission strip 36 can be prevented from sliding off.

For example, in order to facilitate gripping and conveying the insulating film tape 100, the positioning plate 14 is formed with a rectangular positioning region, the holding plate 43 has a rectangular plate shape, and the positioning region is located directly below the holding plate 43. A rectangular receiving groove 115 is concavely formed in the middle of the upper surface of the base plate 11, wherein the mounting bracket 13 having the cross beam 138 is defined as a main mounting bracket 13, and a guide bracket 139 is convexly formed in the middle of the other mounting bracket 13 in the lateral direction, the guide bracket 139 extending toward the main mounting bracket 13. The end of the guiding frame 139 is vertically fixed with a transverse beam 132, two opposite ends of the transverse beam 132 are respectively vertically provided with a cantilever beam 134, and the two cantilever beams 134 are parallel to each other and are respectively located below two opposite sides of the pressure holding plate 43. Each cantilever beam 134 is provided with a clearance groove 1341 in a concave manner on one side facing the main mounting frame 13, a sliding groove 1335 is provided in a concave manner on the top of the rectangular frame 133 of the main mounting frame 13, the clamping and conveying assembly 20 comprises a rotating motor 21, a screw rod 22, a guide slider (not shown), a cross rod 23 and a clamping finger cylinder 24, the rotating motor 21 is fixedly arranged at one end of the sliding groove 1335, one end of the screw rod 22 is fixed on an output shaft of the rotating motor 21, the other end of the screw rod is fixed at one end of the sliding groove 1335 far away from the rotating motor 21, the guide slider is slidably arranged in the sliding groove 1335 and is sleeved on the screw rod 22 in a threaded manner, the cross rod 23 is convexly arranged on. The clamping finger cylinder 24 is installed at one end, far away from the guide sliding block, of the cross rod 23, the clamping finger cylinder 24 is convexly provided with two clamping pieces 25, a main body of the clamping finger cylinder 24 is aligned with the clearance groove 1341 of the cantilever beam 134, and the clamping finger cylinder 24 is used for closing the two clamping pieces 25 to clamp the insulating film strip 100. The clamping finger cylinder 24 clamps the insulating film strip 100 by combining the two clamping pieces 25, then the rotating motor 21 drives the screw rod 22 to rotate so as to drive the guide slider to slide along the sliding slot 1335, and then the clamping pieces 25 drive the insulating film strip 100 to move forward, so that the insulating film strip 100 moves and covers the top surface of the electric power structure shell.

For example, it is particularly important that, in order to prevent the cantilever beams 134 from blocking the forward movement of the insulating film strip 100, each cantilever beam 134 is further provided with a transverse cutting groove 140 and a longitudinal cutting groove 145, the transverse cutting groove 140 and the longitudinal cutting groove 145 both extend along the length direction of the cantilever beam 134, the transverse cutting groove 140 penetrates through the left and right side walls of the cantilever beam 134, the longitudinal cutting groove 145 penetrates through the upper and lower side walls of the cantilever beam 134, the end portions of the transverse cutting groove 140 and the longitudinal cutting groove 145 both communicate with the clearance groove 1341, the transverse cutting grooves 140 of the two cantilever beams 134 correspondingly communicate, the clamping sheet 25 is an elongated sheet, and the clamping finger cylinder 24 is used for passing through the clearance groove 1341 of the cantilever beam 134, so that the two clamping sheets 25 clamp the insulating film strip. A film pasting space is formed between the two cantilever beams 134, the film pasting space is located above the top surface of the electric power structure shell, and the top surface of the electric power structure shell is square. The drive strap 36 is disposed through the longitudinal slots 145 of the two cantilevered beams 134 and at an end of the longitudinal slot 145 remote from the primary mount 13. By providing two transverse cutting grooves 140, it is convenient to further advance the holding sheet 25 holding the insulating film tape 100, and by providing one longitudinal cutting groove 145, it is convenient to perform the cutting operation by the bar-shaped cutter 37 passing through the cantilever beam 134 in the up-down direction.

For example, in order to accurately guide the strip-shaped cutting blade 37 into the longitudinal cutting slot 145, two guide plates 1348 are disposed at one end of each cantilever beam 134 adjacent to the main mounting bracket 13, the two guide plates 1348 fix opposite sides of the longitudinal cutting slot 145, and a distance between the two guide plates 1348 gradually increases in a direction away from the clearance slot 1341. Two guide plates 1348 on one of the cantilever beams 134 are on the lower side and two guide plates 1348 on the other cantilever beam 134 are on the upper side. The two guide plates 1348 are used for guiding one end of the strip-shaped cutter 37, which is far away from the transmission strip 36, to enter the longitudinal cutting groove, so that the strip-shaped cutter 37 is driven by the transmission strip 36 to pass through the longitudinal cutting groove, and then the insulating film strip 100 is cut off. Two guide plates 1348 are arranged on the cantilever beam 134, so that the strip-shaped cutter 37 can be conveniently guided into the longitudinal cutting groove 145 of the cantilever beam 134, and the cutting precision is improved.

For example, in order to improve the smoothness of cutting, the driving bar 36 has flexibility, and the flexibility of the driving bar 36 is used to enable the free end of the bar-shaped cutter 37 to incline to a certain degree under the action of its own weight, so as to contact the insulating film strip 100 first or later, and guide the bar-shaped cutter 37 to cut off the insulating film strip 100 gradually from one side. The above-mentioned action of gradually cutting from one side to the other side can reduce the resistance of cutting the insulating film tape 100, improves the smoothness of cutting the insulating film tape 100, namely when descending, the free end of the bar cutter 37 cuts one side of the insulating film tape 100 first, then gradually takes turns to one end of the connecting rod 375 department to cut the insulating film tape 100. And vice versa when rising. For example, the two clamping pieces 25 and the thickness of the insulating film tape 100 are then smaller than the longitudinal dimension of the transverse groove 140. Through setting up two guide plates 1348 for bar cutter 37 can aim at vertical cutting groove 145 accurately, avoids bar cutter 37 dislocation. And the two holding pieces 25 can hold the insulating film tape 100 and pass through the two transverse slots 140. By providing two cantilever beams 134, the edges of the separated insulating films will not be randomly bumped after cutting the insulating film strip 100, but will remain aligned with the top edge of the power structure housing. For example, the two side edges are pressed and attached to the edge of the electric power structure shell in the subsequent process.

For example, to further prevent the driving belt 36 from slipping off, the annular surface 341 of the driving pulley 34 and the annular surface 341 of the driven pulley 35 are each recessed with an annular groove (not shown) disposed adjacent to the annular rib 345. The opposite ends of the transmission strip 36 are respectively sleeved in the annular groove of the driving wheel 34 and the annular groove of the driven wheel 35. The connecting rod 375 is fixed to the surface of the driving bar 36 and is intended to be slidingly held against the annular surface of the driving wheel 34/driven wheel 35. Through setting up two annular grooves to be convenient for the card establishes transmission strip 36, and then avoid the arbitrary landing of transmission strip 36, improved the location effect. And the connecting rod 375 is fixed to the surface of the driving bar 36, so that interference of the driving bar 36 with the interference of the annular groove with the annular rib 345 can be avoided.

Claims (10)

1. An insulating film pasting device of an electric power structure shell is characterized by comprising a mounting assembly, a clamping and conveying assembly, a film cutting assembly and a film pasting assembly, wherein the mounting assembly comprises a base plate, two mounting frames and a positioning plate, the two mounting frames are respectively and vertically mounted at the two opposite ends of the base plate, the two opposite ends of the positioning plate are respectively fixed at the middle parts of the two mounting frames, the positioning plate is used for supporting and positioning the electric power structure shell, the clamping and conveying assembly is mounted at the middle part of one of the mounting frames and is used for clamping and conveying an insulating film strip so that the insulating film strip is positioned on the top surface of the electric power structure shell, the film cutting assembly comprises a cutting motor, a connecting shaft, a mounting shaft, a driving wheel, a driven wheel, a transmission strip and a strip-shaped cutter, the cutting motor is mounted at the top part of one of the mounting frames, the installation axle is located the below of locating plate, install respectively in the lower part of two mounting brackets at the relative both ends of installation axle, the connecting axle is located to the action wheel fixed sleeve, locate from the driving wheel cover epaxial, the action wheel is located to the transmission strip cover and follows the driving wheel, the bar cutter is installed on the transmission strip, the pad pasting subassembly is used for pressing the insulating film area in the top surface of electric power structure casing, the cutting motor is used for driving the action wheel rotation through the connecting axle, and then drive the insulating film area of the relative both sides of top surface of electric power structure casing successively through the rotation of transmission strip, in order to form the insulating film piece of separation.

2. The insulating film attaching apparatus for electric power structural shells as claimed in claim 1, wherein a rectangular frame is formed at the middle portion of each mounting frame, a rectangular post is formed at the bottom of each rectangular frame to protrude upward, and opposite ends of the positioning plate are fixed to the two rectangular posts, respectively.

3. The insulating film pasting device of the electric power structural shell as claimed in claim 2, wherein a cross beam is transversely protruded from the top of one of the mounting frames, the pasting module comprises a lifting cylinder and a holding plate, the lifting cylinder is mounted at the end of the cross beam, and the holding plate is mounted on the output shaft of the lifting cylinder.

4. The insulating film pasting device of the electric power structural shell as claimed in claim 3, wherein the outer diameter of the driving wheel is equal to the outer diameter of the driven wheel, the outer diameters of the driving wheel and the driven wheel are both larger than the width of the positioning plate, the cross section of the transmission strip is rectangular, one end of the strip-shaped cutter is convexly provided with a connecting rod, and the connecting rod is vertically fixed on the transmission strip.

5. An insulating film attaching device for an electric power structural shell according to claim 4, wherein the driving wheel and the driven wheel have the same structure, the circumferential surface of the driving wheel is a circular ring, one side of the circular ring is convexly provided with an annular rib, the transmission strip is in an annular runway shape, and opposite ends of the transmission strip are respectively sleeved on the circular ring of the driving wheel and the circular ring of the driven wheel.

6. The insulation film attaching device for an electric power structural shell according to claim 5, wherein the connecting rod is located on a side of the transmission bar away from the annular rib, a rectangular positioning region is formed on the positioning plate, the holding plate has a rectangular plate shape, and the positioning region is located right below the holding plate.

7. An insulating film attaching apparatus for an electric power structural casing according to claim 6, wherein a rectangular receiving groove is concavely provided in a middle portion of an upper surface of the base plate, wherein the mounting frame having the cross beam is defined as a main mounting frame, and a guide frame is convexly provided in a middle portion of the other mounting frame in a lateral direction, the guide frame extending toward the main mounting frame.

8. The insulation film attaching apparatus for electric power structural shell according to claim 7, wherein a transverse beam is vertically fixed to an end of the guide frame, cantilever beams are vertically protruded from opposite ends of the transverse beam, respectively, and the two cantilever beams are parallel to each other and located below opposite sides of the holding plate, respectively.

9. The insulation film attaching device for the electric power structural shell according to claim 8, wherein a clearance groove is concavely formed on one side of each cantilever beam facing the main mounting frame, a sliding groove is concavely formed on the top of the rectangular frame of the main mounting frame, the clamping and conveying assembly comprises a rotary motor, a screw rod, a guide slider, a cross rod and a clamping finger cylinder, the rotary motor is fixedly installed at one end of the sliding groove, one end of the screw rod is fixed on an output shaft of the rotary motor, the other end of the screw rod is fixed at one end of the sliding groove far away from the rotary motor, the guide slider is slidably installed in the sliding groove and sleeved on the screw rod in a threaded manner, the cross rod is convexly arranged on the guide slider, and the cross rod.

10. The insulating film attaching device for the electric power structural shell according to claim 9, wherein the clamping finger cylinder is installed at one end of the cross bar away from the guide slider, two clamping pieces are protruded from the clamping finger cylinder, a main body of the clamping finger cylinder is aligned with the clearance groove of the cantilever beam, and the clamping finger cylinder is used for closing the two clamping pieces to clamp the insulating film strip.

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