CN114263005B - Folding electromagnetic shielding conductive cloth printing overflow slurry mixing treatment equipment - Google Patents

Abstract

The invention relates to the field of electromagnetic shielding, in particular to a press-folding type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device. The technical proposal is as follows: the silicone oil of the polydimethyl silicone oil layer overflows and is mixed with the sizing agent on the polyester film layer during printing extrusion, so that the insulating silicone oil layer is damaged, and the printing extrusion device has conductivity. The technical implementation scheme of the invention is as follows: the press-folding type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment equipment comprises a portal frame, a swinging mechanism and the like; the inside of the portal frame is connected with a swinging mechanism. According to the invention, when copper-tin alloy sizing agent is printed on the polyester film layer, the folding mode is adopted firstly, so that the silicone oil moves upwards towards two sides without overflowing when being extruded, meanwhile, the redundant sizing agent is concentrated together in a swinging mode, and the sizing agent is collected after the silicone oil is stabilized, so that the silicone oil and the copper-tin sizing agent are prevented from being mixed together.

Description

Folding electromagnetic shielding conductive cloth printing overflow slurry mixing treatment equipment

Technical Field

The invention relates to the field of electromagnetic shielding, in particular to a press-folding type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device.

Background

The existing electromagnetic shielding conductive cloth is manufactured by sequentially coating a polydimethyl silicone oil layer and a polyester film layer on a fiber cloth, then printing a copper-tin alloy paste layer on the polyester film layer, applying pressure to the polyester film layer to extrude the paste onto the polyester film layer during printing, and mixing silicone oil of the polydimethyl silicone oil layer with the paste on the polyester film layer during extrusion to damage the insulating silicone oil layer, so that the insulating silicone oil layer can be conductive, and potential safety hazards exist, so that the safety of people is endangered by clothing products produced later.

In view of the foregoing, there is a need for a folded electromagnetic shielding conductive cloth print overflow slurry mixing treatment device that solves the above-mentioned problems.

Disclosure of Invention

In order to overcome the defect that the silicone oil layer with insulativity is damaged and has conductivity due to the fact that silicone oil in a polydimethyl silicone oil layer overflows and is mixed with sizing agent on a polyester film layer during printing extrusion, the invention provides a press-folding type electromagnetic shielding conductive cloth printing overflow sizing agent mixing treatment device.

The technical implementation scheme of the invention is as follows: the utility model provides a press-folding type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment equipment, includes portal frame, objective table, support frame, collection box, swing mechanism, poking mechanism and press-folding mechanism; a supporting frame is arranged in the portal frame; the upper surface of the supporting frame is connected with an objective table; the middle part of the supporting frame is connected with a collecting box which is positioned below the objective table; the inside of the portal frame is connected with a swinging mechanism for scraping and coating copper-tin alloy slurry on the surface of the conductive cloth; a removing mechanism is connected between the left inner wall and the right inner wall of the portal frame and is connected with a swinging mechanism for scraping the redundant copper-tin alloy slurry; the support frame is connected with a folding mechanism which is connected with the portal frame and used for folding the two sides of the conductive cloth.

The swinging mechanism comprises a first electric push rod, a connecting block, a first scraping and swinging assembly, a second scraping and swinging assembly, a first electric sliding rail, a third electric sliding block, a first door bracket, a driver, a first bidirectional toothed bar, a third transmission shaft, a third flat gear, a first hook plate, a second electric sliding rail, a fourth electric sliding block, a second door bracket, a second bidirectional toothed bar and a second hook plate; two first electric push rods are symmetrically and fixedly connected to the inner wall of the top of the portal frame; the telescopic parts of the two first electric push rods are fixedly connected with connecting blocks; the first scraping and swinging assembly is rotationally connected inside the connecting block; the second scraping and swinging assembly is rotationally connected to the inside of the connecting block and is positioned behind the first scraping and swinging assembly; two first electric sliding rails are symmetrically and fixedly connected to the inner wall of the right part of the portal frame; a third electric sliding block is connected to each of the two first electric sliding rails in a sliding manner; the left surfaces of the two third electric sliding blocks are fixedly connected with a first door frame; the right surface of the upper part of the first door frame is fixedly connected with a driver; the output shaft of the driver is fixedly connected with a third transmission shaft; the left end of the third transmission shaft is fixedly connected with a third flat gear; the third transmission shaft is rotationally connected with the poking mechanism; the upper surface of the first door frame is fixedly connected with a first bidirectional toothed bar; two first hook plates are symmetrically and fixedly connected to the left surface of the lower part of the first door frame; two second electric sliding rails are symmetrically and fixedly connected to the inner wall of the left part of the portal frame; the two second electric sliding rails are respectively connected with a fourth electric sliding block in a sliding way; the right surfaces of the two fourth electric sliding blocks are fixedly connected with a second portal frame; the upper surface of the second portal frame is fixedly connected with a second bidirectional toothed bar; two second hook plates are symmetrically and fixedly connected to the right surface of the lower part of the second portal frame.

Further, the first scraping and swinging assembly comprises a first transmission shaft, a first telescopic swinging rod, a first flat gear and a first scraping plate; the first transmission shaft is rotationally connected to the inside of the connecting block; the left end and the right end of the first transmission shaft are fixedly connected with a first flat gear respectively; the left part and the right part of the first transmission shaft are fixedly connected with a first telescopic swing rod respectively, and the two first telescopic swing rods are positioned between the two first flat gears; a first scraping plate is fixedly connected between the telescopic parts of the two first telescopic swinging rods.

Further, the second scraping and swinging assembly comprises a second transmission shaft, a second telescopic swinging rod, a second flat gear and a second scraping plate; the inside of the connecting block is rotationally connected with a second transmission shaft; the left end and the right end of the second transmission shaft are fixedly connected with a second flat gear respectively; the left part and the right part of the second transmission shaft are fixedly connected with a second telescopic swing rod respectively, and the two second telescopic swing rods are positioned between the two second flat gears; a second scraping plate is fixedly connected between the telescopic parts of the two second telescopic swinging rods.

Further, the positions of the two first telescopic swing rods and the two second telescopic swing rods are staggered, so that the two first telescopic swing rods and the two second telescopic swing rods are prevented from blocking each other during operation.

Further, the pulling mechanism comprises a first bracket, a first vertical rod, a second bracket, a second vertical rod, a bidirectional screw rod, a fourth flat gear, a pulling plate, a polish rod and a moving block; a first bracket is arranged on the inner wall of the left part of the portal frame; the lower surface of the first bracket is fixedly connected with a first vertical rod; a second bracket is arranged on the inner wall of the right part of the portal frame; the small surface of the second bracket is fixedly connected with a second vertical rod; a bidirectional screw rod is rotationally connected between the middle part of the first vertical rod and the middle part of the second vertical rod; a fourth flat gear is fixedly connected to the right end of the bidirectional screw rod; two poking plates are symmetrically screwed at the middle part of the bidirectional screw rod; a polish rod is fixedly connected between the lower part of the first vertical rod and the lower part of the second vertical rod.

Further, a sliding groove is formed in the lower portion of the second vertical rod, and a moving block is connected inside the sliding groove in a sliding mode; the movable block is rotationally connected with the third transmission shaft.

Further, the folding mechanism comprises a second electric push rod, a first guide rail, a first moving track, a first lifting plate, a first pressing rod, a first buckle plate, a third electric push rod, a second guide rail, a second moving track, a second lifting plate, a second pressing rod and a second buckle plate; two second electric push rods are symmetrically and fixedly connected to the left wall of the interior of the portal frame; the telescopic parts of the two second electric push rods are fixedly connected with a first moving track respectively; a first lifting plate is connected between the two first moving rails in a sliding manner; a first compression bar is fixedly connected between the upper parts of the two first moving rails; two first pinch plates are symmetrically and fixedly connected to the left side surface of the first lifting plate; two first guide rails are symmetrically and fixedly connected to the left part of the support frame; two third electric push rods are symmetrically and fixedly connected to the right wall of the interior of the portal frame; the telescopic parts of the two third electric push rods are fixedly connected with a second moving track respectively; a second lifting plate is connected between the two second moving rails in a sliding way; two second buckle plates are symmetrically and fixedly connected to the right side surface of the second lifting plate; a second compression bar is fixedly connected between the upper parts of the two second moving rails; two first guide rails are symmetrically and fixedly connected to the right part of the support frame.

Further, the lower surfaces of the two first moving rails and the lower surfaces of the two second moving rails are respectively provided with a sliding block for moving on the first guide rail and the second guide rail.

Further, the device also comprises a fixing mechanism, wherein the fixing mechanism is connected with the inside of the portal frame and comprises a fourth electric push rod, a first fixing rod, a fifth electric push rod and a second fixing rod; a fourth electric push rod is respectively arranged on the left wall and the right wall of the interior of the portal frame; the telescopic parts of the two fourth electric push rods are fixedly connected with a first fixed rod; a fifth electric push rod is arranged on the left wall and the right wall of the interior of the portal frame respectively, and the two fifth electric push rods are positioned behind the two fourth electric push rods; the telescopic parts of the two fifth electric push rods are fixedly connected with a second fixing rod.

The invention has the following advantages: according to the invention, when copper-tin alloy sizing agent is printed on the polyester film layer, the folding mode is adopted firstly, so that the silicone oil moves upwards towards two sides without overflowing when being extruded, meanwhile, the redundant sizing agent is concentrated together in a swinging mode, and the sizing agent is collected after the silicone oil is stabilized, so that the silicone oil and the copper-tin sizing agent are prevented from being mixed together.

Drawings

FIG. 1 is a schematic view of a first perspective structure of a press-and-fold electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device of the present invention;

FIG. 2 is a schematic diagram of a second perspective structure of a press-folded electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device according to the present invention;

FIG. 3 is a schematic view of a partial perspective view of a press-folded electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device according to the present invention;

FIG. 4 is a schematic diagram of a first perspective structure of a swing mechanism of a printing overflow slurry mixing treatment device for a folded electromagnetic shielding conductive cloth according to the present invention;

FIG. 5 is a schematic diagram of a second perspective view of a swing mechanism of the press-and-fold electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device of the invention;

FIG. 6 is a schematic view of a first partial perspective view of a swing mechanism of a printing overflow slurry mixing treatment device for a folded electromagnetic shielding conductive cloth according to the present invention;

FIG. 7 is a schematic view of a partial second perspective structure of a swing mechanism of the press-and-fold type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device;

FIG. 8 is a schematic view of a first perspective of a mechanism for removing a printing overflow slurry mixing treatment device from a folded electromagnetic shielding conductive fabric in accordance with the present invention;

FIG. 9 is a schematic diagram of a second perspective view of a mechanism for removing overflow slurry from a roll-to-roll electromagnetic shield conductive cloth printing apparatus according to the present invention;

FIG. 10 is a schematic view of a first perspective view of a folding mechanism of a printing overflow slurry mixing treatment device for folding electromagnetic shielding conductive cloth according to the present invention;

FIG. 11 is a schematic view of a second perspective of a folding mechanism of a folding electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device according to the present invention;

FIG. 12 is a schematic view showing a first perspective structure of a fixing mechanism of a printing overflow slurry mixing treatment device for a folded electromagnetic shielding conductive cloth according to the present invention;

fig. 13 is a schematic view showing a second perspective structure of a fixing mechanism of the press-folding type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device of the present invention.

Meaning of reference numerals in the drawings: 1-portal frame, 2-objective table, 3-supporting frame, 4-collecting box, 601-first electric push rod, 602-connecting block, 603-first scraping and swinging component, 60301-first transmission shaft, 60302-first telescopic swing rod, 60303-first flat gear, 60304-first scraping plate, 604-second scraping and swinging component, 60401-second transmission shaft, 60402-second telescopic swing rod, 60403-second flat gear, 60404-second scraping plate, 605-first electric sliding rail, 606-third electric sliding block, 607-first portal frame, 608-driver, 609-first bidirectional toothed bar, 6010-third transmission shaft, 6011-third flat gear, 6012-first hook plate, 6013-second electric sliding rail, 6014-fourth electric sliding block, 6015-second portal frame, 6016-second bi-directional rack, 6017-second hook plate, 701-first bracket, 702-first vertical bar, 703-second bracket, 704-second vertical bar, 705-bi-directional screw, 706-fourth flat gear, 707-dial, 708-polished rod, 709-moving block, 801-second electric putter, 802-first guide rail, 803-first moving track, 804-first lifting plate, 805-first pressing bar, 806-first buckle, 807-third electric putter, 808-second guide rail, 809-second moving track, 8010-second lifting plate, 8011-second pressing bar, 8012-second buckle, 901-fourth electric putter, 902-first fixed rod, 903-fifth electric putter, 904-second fixation bar.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention. The driver 608 is a motor in this embodiment.

Example 1

The utility model provides a press-folding type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device, which is shown in figures 1-11, and comprises a portal frame 1, an objective table 2, a supporting frame 3, a collecting box 4, a swinging mechanism, a pulling mechanism and a press-folding mechanism; a supporting frame 3 is arranged in the portal frame 1; the upper surface of the supporting frame 3 is connected with an objective table 2; the middle part of the supporting frame 3 is connected with a collecting box 4, and the collecting box 4 is positioned below the objective table 2; the inside of the portal frame 1 is connected with a swinging mechanism; a removing mechanism is connected between the left inner wall and the right inner wall of the portal frame 1 and is connected with a swinging mechanism; the support frame 3 is connected with a folding mechanism which is connected with the portal frame 1.

The working process comprises the following steps: when the printing machine works, the portal frame 1 and the support frame 3 are horizontally placed on the ground, then an external power supply is connected, an operator places fiber cloth covered with a polydimethylsiloxane oil layer and a polyester film layer on the object stage 2, after fixing, copper-tin alloy slurry is smeared on the polyester film layer, then the folding mechanism is controlled to move to the left side and the right side of the fiber cloth covered with the polydimethylsiloxane oil layer and the polyester film layer, then the swinging mechanism is controlled to carry out imprinting operation on the copper-tin alloy slurry on the polyester film layer, the slurry is printed on the film layer through the swinging mechanism, meanwhile, redundant slurry is gathered in the middle of the polyester film layer, the swinging mechanism drives the folding mechanism to fold the two sides of the fiber cloth covered with the polydimethylsiloxane oil layer and the polyester film layer, so that silicone oil covered with the polydimethylsiloxane oil layer and the polyester film layer cannot overflow, and then the swinging mechanism drives the removing mechanism to move the redundant slurry towards the left side and the right side, and simultaneously controls the folding mechanism to withdraw the two sides of the fiber cloth covered with the polydimethylsiloxane oil layer and the polyester film layer, and finally, the redundant slurry is gathered in the collecting box 4, and finally printing operation is carried out on the copper alloy slurry; according to the invention, when copper-tin alloy sizing agent is printed on the polyester film layer, the folding mode is adopted firstly, so that the silicone oil moves upwards towards two sides without overflowing when being extruded, meanwhile, the redundant sizing agent is concentrated together in a swinging mode, and the sizing agent is collected after the silicone oil is stabilized, so that the silicone oil and the copper-tin sizing agent are prevented from being mixed together.

Example 2

On the basis of embodiment 1, according to fig. 1 and fig. 4 to 11, the swinging mechanism comprises a first electric push rod 601, a connecting block 602, a first scraping and swinging assembly 603, a second scraping and swinging assembly 604, a first electric sliding rail 605, a third electric sliding block 606, a first door frame 607, a driver 608, a first bidirectional toothed bar 609, a third transmission shaft 6010, a third flat gear 6011, a first hook plate 6012, a second electric sliding rail 6013, a fourth electric sliding block 6014, a second door frame 6015, a second bidirectional toothed bar 6016 and a second hook plate 6017; two first electric push rods 601 are symmetrically and fixedly connected to the inner wall of the top of the portal frame 1; the telescopic parts of the two first electric push rods 601 are fixedly connected with connecting blocks 602; the first scraping and swinging component 603 is rotatably connected to the inside of the connecting block 602; the second scraping and swinging assembly 604 is rotatably connected to the inside of the connecting block 602, and the second scraping and swinging assembly 604 is located behind the first scraping and swinging assembly 603; two first electric sliding rails 605 are symmetrically and fixedly connected to the inner wall of the right part of the portal frame 1; a third electric sliding block 606 is connected on each of the two first electric sliding rails 605 in a sliding way; the left surfaces of the two third electric sliding blocks 606 are connected with a first portal frame 607 through bolts; a driver 608 is fixedly connected to the right surface of the upper part of the first portal frame 607; the output shaft of the driver 608 is fixedly connected with a third transmission shaft 6010; the left end of the third transmission shaft 6010 is fixedly connected with a third flat gear 6011; the third transmission shaft 6010 is rotationally connected with the removing mechanism; the upper surface of the first portal 607 is welded with a first bidirectional toothed bar 609; two first hook plates 6012 are symmetrically welded on the left surface of the lower part of the first portal frame 607; two second electric sliding rails 6013 are symmetrically and fixedly connected to the inner wall of the left part of the portal frame 1; the two second electric sliding rails 6013 are respectively connected with a fourth electric sliding block 6014 in a sliding way; the right surfaces of the two fourth electric sliding blocks 6014 are connected with a second door frame 6015 through bolts; the upper surface of the second portal frame 6015 is welded with a second bi-directional gear rod 6016; two second hook plates 6017 are symmetrically welded to the lower right surface of the second door frame 6015.

The first scraping and swinging assembly 603 includes a first transmission shaft 60301, a first telescopic swinging rod 60302, a first flat gear 60303 and a first scraping plate 60304; a first transmission shaft 60301 is rotatably connected to the inside of the connection block 602; the left end and the right end of the first transmission shaft 60301 are fixedly connected with a first flat gear 60303 respectively; the left part and the right part of the first transmission shaft 60301 are fixedly connected with a first telescopic swing rod 60302 respectively, and the two first telescopic swing rods 60302 are positioned between the two first flat gears 60303; a first scraping plate 60304 is fixedly connected between the telescopic parts of the two first telescopic swinging rods 60302.

The second scraping and swinging assembly 604 includes a second transmission shaft 60401, a second telescopic swinging rod 60402, a second flat gear 60403 and a second scraping plate 60404; a second transmission shaft 60401 is rotatably connected inside the connecting block 602; the left end and the right end of the second transmission shaft 60401 are fixedly connected with a second flat gear 60403 respectively; a second telescopic swing rod 60402 is fixedly connected to the left part and the right part of the second transmission shaft 60401 respectively, and two second telescopic swing rods 60402 are positioned between two second flat gears 60403; a second scraping plate 60404 is fixedly connected between the telescopic parts of the two second telescopic swinging rods 60402.

The positions of the two first telescopic swing rods 60302 and the two second telescopic swing rods 60402 are staggered, so that the two telescopic swing rods are prevented from blocking each other during operation.

The pulling mechanism comprises a first bracket 701, a first vertical rod 702, a second bracket 703, a second vertical rod 704, a bidirectional screw rod 705, a fourth flat gear 706, a pulling plate 707, a polish rod 708 and a moving block 709; a first bracket 701 is arranged on the inner wall of the left part of the portal frame 1; the lower surface of the first bracket 701 is welded with a first vertical rod 702; a second bracket 703 is arranged on the inner wall of the right part of the portal frame 1; the small surface of the second bracket 703 is welded with a second vertical rod 704; a bidirectional screw rod 705 is rotatably connected between the middle part of the first vertical rod 702 and the middle part of the second vertical rod 704; a fourth flat gear 706 is fixedly connected to the right end of the bidirectional screw rod 705; two poking plates 707 are symmetrically screwed on the middle part of the bidirectional screw rod 705; a polish rod 708 is fixedly connected between the lower part of the first vertical rod 702 and the lower part of the second vertical rod 704.

The lower part of the second vertical rod 704 is provided with a chute, and a moving block 709 is connected inside the chute in a sliding way; the moving block 709 is rotatably connected to the third transmission shaft 6010.

The folding mechanism includes a second electric push rod 801, a first guide rail 802, a first moving rail 803, a first lifting plate 804, a first pressing rod 805, a first buckle plate 806, a third electric push rod 807, a second guide rail 808, a second moving rail 809, a second lifting plate 8010, a second pressing rod 8011 and a second buckle plate 8012; two second electric push rods 801 are symmetrically and fixedly connected to the left wall of the interior of the portal frame 1; the telescopic parts of the two second electric push rods 801 are fixedly connected with a first moving track 803 respectively; a first lifting plate 804 is slidably connected between the two first moving rails 803; a first compression bar 805 is welded between the upper parts of the two first moving tracks 803; two first buckle plates 806 are symmetrically welded on the left side surface of the first lifting plate 804; two first guide rails 802 are symmetrically and fixedly connected to the left part of the support frame 3; two third electric push rods 807 are symmetrically and fixedly connected to the right wall of the interior of the portal frame 1; the telescopic parts of the two third electric pushing rods 807 are fixedly connected with a second moving track 809 respectively; a second lifting plate 8010 is slidably connected between the two second moving rails 809; two second buckle plates 8012 are symmetrically welded on the right side surface of the second lifting plate 8010; a second compression bar 8011 is welded between the upper parts of the two second moving rails 809; two first guide rails 802 are symmetrically and fixedly connected to the right part of the support frame 3.

The lower surfaces of the two first moving rails 803 and the lower surfaces of the two second moving rails 809 are provided with a sliding block for moving on the first guide rail 802 and the second guide rail 808, respectively.

The working process comprises the following steps: when in operation, the second electric push rod 801 and the third electric push rod 807 are controlled to extend, the second electric push rod 801 drives the first moving track 803 to move on the first guide rail 802, the first moving track 803 drives the first lifting plate 804 and the first pressing rod 805 to move rightwards until the first pressing rod 805 presses the left side of the fiber cloth covered with the polydimethylsiloxane oil layer and the polyester film layer, at the moment, the first buckle plate 806 is directly above the second hook plate 6017, meanwhile, the third electric push rod 807 drives the second moving track 809 to move on the second guide rail 808, the second moving track 809 drives the second lifting plate 8010 and the second pressing rod 8011 to move leftwards until the second pressing rod 8011 presses the right side of the fiber cloth covered with the polydimethylsiloxane oil layer and the polyester film layer, at the moment, the second buckle plate 8012 is directly above the first hook plate 6012, then the first electric push rod 601 is controlled to extend to drive the connecting block 602 to descend, the connecting block 602 drives the first scraping swing component 603 and the second scraping swing component 604 to descend until the first scraping plate 60304 and the second scraping plate 60404 are in contact with the polyester film layer, then the first electric sliding rail 605 is controlled to drive the third electric sliding block 606 to move upwards, the third electric sliding block 606 drives the first door frame 607 to move upwards, the first door frame 607 drives the first hook plate 6012 to move upwards, the first hook plate 6012 drives the second buckle plate 8012 to move upwards, the second buckle plate 8012 drives the second lifting plate 8010 to move upwards on the second moving track 809, the right side of the fiber cloth covered with the polydimethylsiloxane oil layer and the polyester film layer is lifted and folded, meanwhile, the first door frame 607 drives the first bidirectional toothed bar 609 to move upwards, the first flat gear 60303 and the second flat gear 60403 which are positioned on the right side are driven to rotate by the upward movement of the first bidirectional toothed bar 609, and the rotation directions of the first flat gear 60303 and the second flat gear 60403 are opposite, at the same time, the second electric sliding rail 6013 controls the fourth electric sliding block 6014 to move upwards, the fourth electric sliding block 6014 drives the second portal 6015 to move upwards, the second portal 6015 drives the second hook plate 6017 to move upwards, the second hook plate 6017 drives the first buckle plate 806 to move upwards, the first buckle plate 806 drives the first lifting plate 804 to move upwards on the first moving track 803, the first lifting plate 804 lifts and folds the left side of the fiber cloth covered with the polydimethylsiloxane oil layer and the polyester film layer, the second portal 6015 drives the second bidirectional toothed bar 6016 to move upwards, the second bidirectional toothed bar 6016 meshes and drives the left side first flat gear 60303 and the second flat gear 60403 to rotate, and the rotation directions of the first flat gear 60303 and the second flat gear 60403 are opposite, so that the two first flat gears 60303 drive the first transmission shaft 60301 to rotate anticlockwise by taking the right side of the connection block 602 as the front, the first transmission shaft 60301 drives the first telescopic swinging rod 60302 to swing, the first telescopic swinging rod 60302 drives the first scraping plate 60304 to swing on the polyester film layer, meanwhile, the second flat gear 60403 drives the second transmission shaft 60401 to rotate clockwise by taking the right side surface of the connecting block 602 as the front surface, the second transmission shaft 60401 drives the second telescopic swinging rod 60402 to swing, the second telescopic swinging rod 60402 drives the second scraping plate 60404 to swing on the polyester film layer, copper-tin paste is printed on the polyester film layer under the swinging of the first scraping plate 60304 and the second scraping plate 60404 and the redundant paste is concentrated in the middle part of the polyester film layer, at this time, the first portal frame 607 drives the driver 608, the third transmission shaft 6010 and the third flat gear 6011 to move upwards, the third flat gear 6011 is meshed with the fourth flat gear 706, then the driver 608 is controlled to drive the third transmission shaft 6010 to rotate, the third transmission shaft 6010 drives the third flat gear 6011 to rotate, the third flat gear 6011 drives the fourth flat gear 706 to rotate, the fourth flat gear 706 drives the bidirectional screw rod 705 to rotate, the bidirectional screw rod 705 drives the two poking plates 707 to move back to back on the polished rod 708, redundant slurry is poked and scraped towards the left side and the right side, meanwhile, the second electric push rod 801 and the third electric push rod 807 are controlled to shrink and reset, the second electric push rod 801 and the third electric push rod 807 shrink to respectively drive the first compression rod 805 and the second compression rod 8011 to withdraw from the left side and the right side of the fiber cloth covered with the polydimethylsiloxane oil layer and the polyester film layer, and the poked slurry can fall into the collecting box 4 to be collected; the mechanism completes the printing of the polyester film.

Example 3

On the basis of the embodiment 2, according to fig. 1 and 12-13, a fixing mechanism is further included, and the inside of the portal frame 1 is connected with the fixing mechanism, and the fixing mechanism includes a fourth electric push rod 901, a first fixing rod 902, a fifth electric push rod 903 and a second fixing rod 904; a fourth electric push rod 901 is respectively arranged on the left wall and the right wall of the interior of the portal frame 1; the telescopic parts of the two fourth electric push rods 901 are fixedly connected with a first fixing rod 902; a fifth electric push rod 903 is respectively arranged on the left wall and the right wall of the interior of the portal frame 1, and the two fifth electric push rods 903 are positioned behind the two fourth electric push rods 901; the telescopic parts of the two fifth electric push rods 903 are fixedly connected with a second fixing rod 904.

The working process comprises the following steps: firstly, an operator places fiber cloth covered with a polydimethylsiloxane oil layer and a polyester film layer on an object stage 2, then controls a fourth electric push rod 901 and a fifth electric push rod 903 to extend, the fourth electric push rod 901 drives a first fixing rod 902 to press down, the fifth electric push rod 903 extends to drive a second fixing rod 904 to press down, and finally, the front end and the rear end of the fiber cloth covered with the polydimethylsiloxane oil layer and the polyester film layer are fixed, so that slurry at the front end and the rear end is prevented from overflowing and mixing with silicone oil when slurry is scraped; the mechanism completes the fixation of the fiber cloth covered with the polydimethylsiloxane oil layer and the polyester film layer.

Finally, it should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present invention may be modified or substituted equally without departing from the spirit and scope of the technical solution of the present invention.

Claims (6)

1. The utility model provides a press-folding type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment equipment, which comprises a portal frame (1), an objective table (2), a supporting frame (3) and a collecting box (4); a supporting frame (3) is arranged in the portal frame (1); the upper surface of the supporting frame (3) is connected with an objective table (2); the middle part of the supporting frame (3) is connected with a collecting box (4), and the collecting box (4) is positioned below the objective table (2); the method is characterized in that: the device also comprises a swinging mechanism, a pulling mechanism and a folding mechanism; the inside of the portal frame (1) is connected with a swinging mechanism for scraping copper-tin alloy slurry on the surface of the conductive cloth; a removing mechanism is connected between the left inner wall and the right inner wall of the portal frame (1), and the removing mechanism is connected with a swinging mechanism and is used for scraping off the redundant copper-tin alloy slurry; the support frame (3) is connected with a folding mechanism which is connected with the portal frame (1) and is used for folding the two sides of the conductive cloth;

the swinging mechanism comprises a first electric push rod (601), a connecting block (602), a first scraping and swinging assembly (603), a second scraping and swinging assembly (604), a first electric sliding rail (605), a third electric sliding block (606), a first door frame (607), a driver (608), a first bidirectional toothed bar (609), a third transmission shaft (6010), a third flat gear (6011), a first hook plate (6012), a second electric sliding rail (6013), a fourth electric sliding block (6014), a second door frame (6015), a second bidirectional toothed bar (6016) and a second hook plate (6017); two first electric push rods (601) are symmetrically and fixedly connected to the inner wall of the top of the portal frame (1); the telescopic parts of the two first electric push rods (601) are fixedly connected with connecting blocks (602); the inside of the connecting block (602) is rotationally connected with a first scraping and swinging component (603); the second scraping and swinging assembly (604) is rotatably connected to the inside of the connecting block (602), and the second scraping and swinging assembly (604) is positioned behind the first scraping and swinging assembly (603); two first electric sliding rails (605) are symmetrically and fixedly connected to the inner wall of the right part of the portal frame (1); a third electric sliding block (606) is connected to each of the two first electric sliding rails (605) in a sliding way; the left surfaces of the two third electric sliding blocks (606) are fixedly connected with a first door frame (607); the right surface of the upper part of the first portal frame (607) is fixedly connected with a driver (608); the output shaft of the driver (608) is fixedly connected with a third transmission shaft (6010); the left end of the third transmission shaft (6010) is fixedly connected with a third flat gear (6011); the third transmission shaft (6010) is rotationally connected with the pulling mechanism; the upper surface of the first portal frame (607) is fixedly connected with a first bidirectional toothed bar (609); two first hook plates (6012) are symmetrically and fixedly connected to the left surface of the lower part of the first portal frame (607); two second electric sliding rails (6013) are symmetrically and fixedly connected to the inner wall of the left part of the portal frame (1); the two second electric sliding rails (6013) are respectively connected with a fourth electric sliding block (6014) in a sliding way; the right surfaces of the two fourth electric sliding blocks (6014) are fixedly connected with a second portal frame (6015); the upper surface of the second portal frame (6015) is fixedly connected with a second bidirectional toothed bar (6016); two second hook plates (6017) are symmetrically and fixedly connected to the right surface of the lower part of the second portal frame (6015);

the pulling mechanism comprises a first bracket (701), a first vertical rod (702), a second bracket (703), a second vertical rod (704), a bidirectional screw rod (705), a fourth flat gear (706), a pulling plate (707), a polish rod (708) and a moving block (709); a first bracket (701) is arranged on the inner wall of the left part of the portal frame (1); the lower surface of the first bracket (701) is fixedly connected with a first vertical rod (702); a second bracket (703) is arranged on the inner wall of the right part of the portal frame (1); the small surface of the second bracket (703) is fixedly connected with a second vertical rod (704); a bidirectional screw rod (705) is rotationally connected between the middle part of the first vertical rod (702) and the middle part of the second vertical rod (704); a fourth flat gear (706) is fixedly connected at the right end of the bidirectional screw rod (705); two poking plates (707) are symmetrically screwed at the middle part of the bidirectional screw rod (705); a polish rod (708) is fixedly connected between the lower part of the first vertical rod (702) and the lower part of the second vertical rod (704);

the folding mechanism comprises a second electric push rod (801), a first guide rail (802), a first moving rail (803), a first lifting plate (804), a first pressing rod (805), a first buckle plate (806), a third electric push rod (807), a second guide rail (808), a second moving rail (809), a second lifting plate (8010), a second pressing rod (8011) and a second buckle plate (8012); two second electric push rods (801) are symmetrically and fixedly connected to the left wall of the interior of the portal frame (1); the telescopic parts of the two second electric push rods (801) are fixedly connected with a first moving track (803) respectively; a first lifting plate (804) is connected between the two first moving rails (803) in a sliding way; a first compression bar (805) is fixedly connected between the upper parts of the two first moving rails (803); the left side surface of the first lifting plate (804) is symmetrically and fixedly connected with two first pinch plates (806); two first guide rails (802) are symmetrically and fixedly connected to the left part of the support frame (3); two third electric push rods (807) are symmetrically and fixedly connected to the right wall of the interior of the portal frame (1); the telescopic parts of the two third electric push rods (807) are fixedly connected with a second moving track (809) respectively; a second lifting plate (8010) is connected between the two second moving rails (809) in a sliding way; two second buckle plates (8012) are symmetrically and fixedly connected to the right side surface of the second lifting plate (8010); a second compression bar (8011) is fixedly connected between the upper parts of the two second moving rails (809); two first guide rails (802) are symmetrically and fixedly connected to the right part of the support frame (3);

the portal frame (1) is internally connected with a fixing mechanism, and the fixing mechanism comprises a fourth electric push rod (901), a first fixing rod (902), a fifth electric push rod (903) and a second fixing rod (904); a fourth electric push rod (901) is respectively arranged on the left wall and the right wall of the interior of the portal frame (1); the telescopic parts of the two fourth electric push rods (901) are fixedly connected with a first fixed rod (902); a fifth electric push rod (903) is arranged on the left wall and the right wall of the interior of the portal frame (1), and the two fifth electric push rods (903) are positioned behind the two fourth electric push rods (901); the telescopic parts of the two fifth electric push rods (903) are fixedly connected with a second fixed rod (904).

2. The folding type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device according to claim 1, wherein the device is characterized in that: the first scraping and swinging assembly (603) comprises a first transmission shaft (60301), a first telescopic swinging rod (60302), a first flat gear (60303) and a first scraping plate (60304); a first transmission shaft (60301) is rotatably connected inside the connecting block (602); the left end and the right end of the first transmission shaft (60301) are fixedly connected with a first flat gear (60303) respectively; the left part and the right part of the first transmission shaft (60301) are fixedly connected with a first telescopic swing rod (60302) respectively, and the two first telescopic swing rods (60302) are positioned between the two first flat gears (60303); a first scraping plate (60304) is fixedly connected between the telescopic parts of the two first telescopic swinging rods (60302).

3. The folding type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device according to claim 1, wherein the device is characterized in that: the second scraping and swinging assembly (604) comprises a second transmission shaft (60401), a second telescopic swinging rod (60402), a second flat gear (60403) and a second scraping plate (60404); a second transmission shaft (60401) is rotatably connected inside the connecting block (602); the left end and the right end of the second transmission shaft (60401) are fixedly connected with a second flat gear (60403) respectively; the left part and the right part of the second transmission shaft (60401) are fixedly connected with a second telescopic swing rod (60402) respectively, and two second telescopic swing rods (60402) are positioned between two second flat gears (60403); a second scraping plate (60404) is fixedly connected between the telescopic parts of the two second telescopic swinging rods (60402).

4. A folded electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device according to claim 2 or 3, characterized in that: the positions of the two first telescopic swing rods (60302) and the two second telescopic swing rods (60402) are staggered, so that the two first telescopic swing rods and the two second telescopic swing rods are prevented from blocking each other during operation.

5. The folding type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device according to claim 1, wherein the device is characterized in that: the lower part of the second vertical rod (704) is provided with a chute, and a moving block (709) is connected inside the chute in a sliding way; the moving block (709) is rotatably connected with a third transmission shaft (6010).

6. The folding type electromagnetic shielding conductive cloth printing overflow slurry mixing treatment device according to claim 1, wherein the device is characterized in that: the lower surfaces of the two first moving rails (803) and the lower surfaces of the two second moving rails (809) are respectively provided with a sliding block for moving on the first guide rail (802) and the second guide rail (808).