CN112444162A - Method for manufacturing conductive cloth precision target plate - Google Patents

Abstract

The invention relates to a method for manufacturing a conductive cloth precision target plate, which comprises the following steps: (1) sticking the tin foil paper on the EVA plate; (2) punching a positioning hole on the EVA plate by using a punching die; (3) positioning the EVA board by using a positioning hole, and coating tin foil paper on a laser cutting machine to form scribed lines, wherein the scribed line interval is controlled to be 2 mm; (4) sticking the lead; (5) and adhering the EVA sheets. The whole pasting laser scribing process is adopted, and the problem of accurate isolation and integrated forming of the conductive cloth area inside the target plate is solved.

Description

Method for manufacturing conductive cloth precision target plate

Technical Field

The invention belongs to the technical field of manufacturing, relates to a target plate manufacturing method, and particularly relates to a conductive cloth precision target plate manufacturing method.

Background

The current conductive cloth (that is, tinfoil paper) live ammunition area target scoring system, the conductive cloth adopts cutter cutting technology, then will cut conductive cloth paste form the conducting layer on the EVA material, this technology makes conductive cloth's position difficult accurate fixed, the interval between each region is uneven, direct influence target scoring precision, manual pasting can not carry out slight regional isolation operation, can only through increasing the target board number of piles, the functional needs that accomplish the target board of each layer (current product target board number of piles is in 6-10 layers, contains the front cover back cover) are reduced. The increase of the number of layers of the target plate directly leads to the improvement of the weight of the target plate, is not beneficial to the use of the target plate carried on various hiding and displaying devices, and improves the driving power requirement of the hiding and displaying devices. The multilayer target plate is not beneficial to conducting signals of all layers simultaneously when bullets pass through the target plate. The less the number of layers, the less the false alarm of the target plate and the less the false alarm condition.

In view of the above technical defects in the prior art, it is urgently needed to develop a new method for manufacturing a target plate with conductive cloth precision.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provides a method for manufacturing a target plate with high conductive cloth precision.

In order to achieve the above purpose, the invention provides the following technical scheme:

a method for manufacturing a conductive cloth precision target plate is characterized by comprising the following steps:

(1) sticking the tin foil paper on the EVA plate;

(2) punching a positioning hole on the EVA plate by using a punching die;

(3) positioning the EVA board by using a positioning hole, and coating tin foil paper on a laser cutting machine to form scribed lines, wherein the scribed line interval is controlled to be 2 mm;

(4) sticking the lead;

(5) and adhering the EVA sheets.

Further, the step (1) is specifically as follows: and (3) sticking the tinfoil paper on the single surface of the EVA plate with the thickness of 4mm, and sticking the tinfoil paper on the double surfaces of the EVA plate with the thickness of 7 mm.

Further, the step (2) is specifically as follows: the EVA board with the thickness of 2mm, the EVA board with the thickness of 4mm after being pasted with the tinfoil paper and the EVA board with the thickness of 7mm after being pasted with the tinfoil paper are aligned, and a punching tool is used for punching positioning holes, wherein 4 positioning holes are punched, the 4 positioning holes are arranged in a pairwise symmetrical mode, and the diameter of each positioning hole is 10 mm.

Further, wherein the step (3) specifically includes the steps of:

(3.1) inserting a positioning pin into a positioning hole of one of the EVA plates with the thickness of 2mm for fixing, and then spraying the EVA plate with the thickness of 2mm according to the shape of the target plate;

(3.2) scribing lines on the tinfoil paper of the EVA plate with the thickness of 4mm after the tinfoil paper is pasted;

(3.3) scribing lines on the tinfoil paper on one surface of the EVA plate with the thickness of 7mm after the tinfoil paper is pasted;

and (3.4) scribing lines on the tinfoil paper on the other surface of the EVA plate with the thickness of 7mm after the tinfoil paper is pasted.

And, wherein the step (4) is specifically: fixing a wire on the scribed EVA plate with the thickness of 7mm, specifically, perforating the EVA plate by using a 2mm pointed cone, enabling the 1mm wire to smoothly pass through the perforation, stripping off a wire insulating layer after the wire passes through the wire, ensuring that the length of the two sides of the target plate is 30mm, contacting the wires at two ends with the tin foil paper, and locally fixing the wires by using a tin foil adhesive tape to enable the tin foil paper layers on the front and back sides of the target plate to be conducted.

Finally, the step (5) specifically comprises the following steps:

(5.1) uniformly coating fish bead glue on the area outside the scribed line on the one surface of the EVA sheet with the thickness of 7mm after scribing by using a doctor blade;

(5.2) placing the EVA plate with the glue thickness of 7mm on a tool, wherein the glue face is upward, and bonding the tinfoil paper face of the EVA plate with the thickness of 4mm with the EVA plate with the thickness of 7mm to form an EVA layer with the thickness of 11mm, namely bonding one face of the EVA plate with the thickness of 4mm, which is not pasted with the tinfoil paper, with the face of the EVA plate with the thickness of 7mm, which is coated with the fish bead glue, to form an EVA layer with the thickness of 11 mm;

(5.3) producing a flat cable with a head, and defining a port;

(5.4) using a paper cutter to open wire passing holes on two surfaces of the EVA layer with the thickness of 11mm, conducting the flat cable with the head with the cutting area, and fixing a conducting terminal by using a tin foil adhesive tape;

(5.5) uniformly coating fish bead glue on one surface of the EVA layer with the thickness of 11mm, namely the other surface of the EVA plate with the thickness of 7mm, which is not jointed with the EVA plate with the thickness of 4mm, by using a scraping blade;

(5.6) placing an EVA (ethylene vinyl acetate) layer with the thickness of 11mm on a tool, wherein the glue surface is upward, bonding one EVA plate with the thickness of 2mm with the EVA layer with the thickness of 11mm to form an EVA layer with the thickness of 13mm, and scratching the EVA plate with the thickness of 2mm at a flat cable position to pass the cable;

(5.7) placing the 13 m-thick EVA layer on the upper quadrant layer of the tool upwards, wherein the surface which is not bonded with the 2 mm-thick EVA plate, namely the surface of the original 4 mm-thick EVA plate, faces upwards, and marking along the outer edge of the tool by using a pencil;

(5.9) after scribing, uniformly brushing fish bead glue on the area outside the target plate by using a scraping blade;

(5.9) placing the EVA layer with the thickness of 13mm and brushed with the glue on a tool, wherein the glue face is upward, and bonding another EVA plate with the thickness of 2mm and the EVA layer with the thickness of 13mm together to form an EVA layer with the thickness of 15 mm;

(5.10) placing an EVA layer with the thickness of 15mm on a tool, sequentially cutting the appearance to ensure that the size is 600 multiplied by 700, and forming the conductive cloth precision target plate.

Compared with the existing manufacturing method, the manufacturing method of the conductive cloth precision target plate has the following beneficial technical effects:

1. the whole pasting laser scribing process is adopted, and the problem of accurate isolation and integrated forming of the conductive cloth area inside the target plate is solved.

2. The number of layers is small, and the precision is high.

Drawings

Fig. 1 shows a schematic diagram of the EVA sheet when pasting the tinfoil paper.

Fig. 2 shows a schematic diagram of punching positioning holes in an EVA plate.

Figure 3 shows a schematic of the spray pattern on a 2mm thick EVA sheet.

Figure 4 shows a schematic drawing of the scoring of the tinfoil paper of a 4mm thick EVA sheet.

Figure 5 shows a schematic drawing of the scoring of the tinfoil paper on one side of a 7mm thick EVA sheet.

Figure 6 shows a schematic drawing of the lines scribed on the tinfoil paper on the other side of a 7mm thick EVA sheet.

Figure 7 shows a schematic view of the wire fixation on a scribed 7mm thick EVA sheet.

Figure 8 shows a schematic of the uniform application of fish bead glue using a doctor blade to the out of score area on one side of a scribed 7mm thick EVA sheeting.

Fig. 9 shows a schematic diagram of the production of a headed ribbon.

Fig. 10 and 11 are views showing that the headed wires are connected to the dividing regions and the conductive terminals are fixed using a tin foil tape.

Figure 12 shows a schematic drawing of a uniform brush of fish bead glue using a doctor blade on one side of an 11mm thick EVA layer, i.e. the other side of the original 7mm thick EVA sheet not laminated to a 4mm thick EVA sheet.

Figure 13 shows a 13m thick EVA layer placed on the tooling quadrant level up, with the side not bonded to the 2mm thick EVA sheet, i.e. the side of the original 4mm thick EVA sheet, facing up, and using a pencil to scribe lines along the outer edge of the tooling.

FIG. 14 shows a schematic of the uniform application of bead glue to the area outside the target plate using a doctor blade.

Detailed Description

The present invention is further described with reference to the following drawings and examples, which are not intended to limit the scope of the present invention.

The invention relates to a method for manufacturing a target plate with conductive cloth precision, which is used for manufacturing the target plate of a live ammunition precision area target-scoring system. The method for manufacturing the conductive cloth precision target plate is described in detail below, and comprises the following steps:

firstly, purchasing EVA coiled materials. Three thicknesses of EVA coiled materials are required to be purchased, and the thicknesses of the three thicknesses of EVA coiled materials are respectively 2mm, 4mm and 7 mm. Wherein the number ratio of the EVA coiled materials with the three thicknesses is 2:1: 1. And the width of various EVA coiled materials is more than 1250mm +/-10 mm, the length is determined according to batch requirements, and the hardness of the materials is 45-50 degrees.

And secondly, cutting the EVA coiled materials with the three thicknesses into required sizes by adopting a paper cutter to form the EVA sheet material. Specifically, three thicknesses of EVA web were cut into EVA sheets 720mm in length and 620mm in width with a tolerance of ± 5 mm.

Thirdly, sticking the tinfoil paper on the single surface of the EVA plate with the thickness of 4mm, and sticking the tinfoil paper on the double surfaces of the EVA plate with the thickness of 7 mm. Wherein, the width of tinfoil paper is 600mm, length is 720mm to the 600mm direction of tinfoil paper is required to be unanimous with the 620mm direction of EVA panel, and the center symmetry is surveyed to the eye, pastes smoothly. Specifically, as shown in fig. 1, the sheet with a width of 600mm is a tinfoil paper, and the sheet with a width of 620mm is an EVA sheet.

Fourthly, aligning the EVA plate with the thickness of 2mm, the EVA plate with the thickness of 4mm after being pasted with the tin foil paper and the EVA plate with the thickness of 7mm after being pasted with the tin foil paper, and punching the positioning holes by using a punching tool. In the present invention, preferably, as shown in fig. 2, 4 positioning holes are punched, the 4 positioning holes are arranged two by two symmetrically, and the positions of the four positioning holes are shown in fig. 2. More preferably, the diameter of the pilot hole is 10 mm. In fig. 2, reference numeral 1 denotes a positioning hole.

Fifthly, inserting a positioning pin into a positioning hole of one of the EVA plate materials with the thickness of 2mm for fixing, and then spraying and drawing on the EVA plate material with the thickness of 2mm according to the shape of the target plate shown in figure 3. Preferably, the color of the spray pattern is greenish black.

Sixthly, lines are scribed on the tinfoil paper of the EVA plate with the thickness of 4mm after the tinfoil paper is pasted. Specifically, the method comprises the following steps: positioning pins are inserted into the positioning holes to perform positioning, and scribing is performed in the shape shown in fig. 4. During scribing, the cutting depth of the cutter is controlled, and the cutter is required to cut off the tin foil paper but cannot cut through the EVA plate. And for the breakpoints left after cutting by some cutters, connecting breakpoints are manually cut through, and the scribed tin foil paper is manually removed.

Seventhly, lines are marked on the tin foil paper on one surface of the EVA plate with the thickness of 7mm after the tin foil paper is pasted. Specifically, the method comprises the following steps: positioning pins are inserted into the positioning holes to perform positioning, and scribing is performed in the shape shown in fig. 5. During scribing, the cutting depth of the cutter is controlled, and the cutter is required to cut off the tin foil paper but cannot cut through the EVA plate. And for the breakpoints left after cutting by some cutters, connecting breakpoints are manually cut through, and the scribed tin foil paper is manually removed.

Eighthly, scribing lines on the tinfoil paper on the other side of the 7 mm-thick EVA plate after the tinfoil paper is pasted. Specifically, the method comprises the following steps: positioning pins are inserted into the positioning holes to perform positioning, and scribing is performed in the shape shown in fig. 6. During scribing, the cutting depth of the cutter is controlled, and the cutter is required to cut off the tin foil paper but cannot cut through the EVA plate. And for the breakpoints left after cutting by some cutters, connecting breakpoints are manually cut through, and the scribed tin foil paper is manually removed.

And ninthly, fixing a lead on the scribed EVA plate with the thickness of 7 mm. Specifically, a 2mm tip cone was used to pierce the hole at the location shown in FIG. 7, allowing a 1mm wire to pass through smoothly. After the wire passes through the wire, the wire insulating layer is stripped off, and the length of the two sides of the target plate is ensured to be 30 mm. And (3) contacting the wires at two ends with the tin foil paper, and fixing the local part by using a tin foil adhesive tape to conduct the tin foil paper layers on the front and back surfaces of the target plate. And finally, sequentially measuring the conduction states of the two sides of the target plate by using a universal meter.

Tenthly, uniformly coating fish bead glue on the area, outside the scribed line, of the one side of the scribed EVA sheet with the thickness of 7mm by using a doctor blade.

Eleven, placing the EVA board with the glue brushing thickness of 7mm on the tool, wherein the glue face is upward, and bonding the tinfoil paper face of the EVA board with the thickness of 4mm with the EVA board with the thickness of 7mm to form an EVA layer with the thickness of 11 mm. That is, one side of the 4mm thick EVA sheet, to which no tinfoil paper is attached, and the one side of the 7mm thick EVA sheet, to which the fish bead glue is applied, are bonded together to form an 11mm thick EVA layer.

And twelfth, producing a flat cable with a head, and defining a port. In the present invention, a specific flat headed wire is shown in fig. 9.

Thirteen, the wire holes are opened on the two sides of the EVA layer with the thickness of 11mm by using a paper cutter, the flat cable with the head is conducted with the segmentation area, and the terminals are fixedly conducted by using a tinfoil adhesive tape. Specifically, a wire hole is formed at the position shown in fig. 10 and 11, and the leading flat cable is conducted with the dividing area according to the following sequence: a-8, B-9, C-10, D-11, E-12, F-13, G-14, H-15, O-3, P-1(2), Q-4, R-5, S-6 and T-7.

Fourteen, brush one side of the EVA layer with the thickness of 11mm, namely, the other side of the EVA plate with the thickness of 7mm, which is not jointed with the EVA plate with the thickness of 4mm, with the fish bead glue uniformly by using a scraping piece. As shown in particular in fig. 12.

Fifteen, placing an EVA (ethylene vinyl acetate) layer with the thickness of 11mm on a tool, wherein the glue surface is upward, bonding one EVA plate with the thickness of 2mm with the EVA layer with the thickness of 11mm to form the EVA layer with the thickness of 13mm, and scratching the EVA plate with the thickness of 2mm at a flat cable position to pass the cable.

Sixthly, the 13 m-thick EVA layer is placed on the tool with the upper quadrant layer upward, wherein the surface which is not bonded with the 2 mm-thick EVA plate, namely the surface of the original 4 mm-thick EVA plate, faces upward, and a pencil is used for marking along the outer edge of the tool. A specific scribe line shape may be as shown in fig. 13.

Seventhly, after scribing, as shown in fig. 14, the fish bead glue is uniformly brushed on the area outside the target plate by using a doctor blade.

Eighteen, place the 13mm thick EVA layer of brush glue on the frock, wherein, glue the face upwards to with another 2mm thick EVA panel with 13mm thick EVA layer bonds together, forms the 15mm thick EVA layer.

Nineteen, place 15mm thick EVA layer on the frock, cut the appearance in proper order, guarantee that the size is 600X 700, form the electrically conductive cloth precision target board. Note that: the Chinese medicinal materials are prevented from winding during cutting.

The manufacturing method of the conductive cloth precision target plate adopts an integral bonding laser scribing process, and solves the problem of accurate isolation and integral forming of the conductive cloth area in the target plate.

The above examples of the present invention are merely examples for clearly illustrating the present invention and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. Not all embodiments are exhaustive. All obvious changes and modifications which are obvious to the technical scheme of the invention are covered by the protection scope of the invention.

Claims (6)

1. A method for manufacturing a conductive cloth precision target plate is characterized by comprising the following steps:

(1) sticking the tin foil paper on the EVA plate;

(2) punching a positioning hole on the EVA plate by using a punching die;

(3) positioning the EVA board by using a positioning hole, and coating tin foil paper on a laser cutting machine to form scribed lines, wherein the scribed line interval is controlled to be 2 mm;

(4) sticking the lead;

(5) and adhering the EVA sheets.

2. The method for manufacturing the conductive cloth precision target plate as claimed in claim 1, wherein the step (1) is specifically as follows: and (3) sticking the tinfoil paper on the single surface of the EVA plate with the thickness of 4mm, and sticking the tinfoil paper on the double surfaces of the EVA plate with the thickness of 7 mm.

3. The method for manufacturing the conductive cloth precision target plate as claimed in claim 2, wherein the step (2) is specifically as follows: the EVA board with the thickness of 2mm, the EVA board with the thickness of 4mm after being pasted with the tinfoil paper and the EVA board with the thickness of 7mm after being pasted with the tinfoil paper are aligned, and a punching tool is used for punching positioning holes, wherein 4 positioning holes are punched, the 4 positioning holes are arranged in a pairwise symmetrical mode, and the diameter of each positioning hole is 10 mm.

4. The method for manufacturing the conductive cloth precision target plate as claimed in claim 3, wherein the step (3) specifically comprises the steps of:

(3.1) inserting a positioning pin into a positioning hole of one of the EVA plates with the thickness of 2mm for fixing, and then spraying the EVA plate with the thickness of 2mm according to the shape of the target plate;

(3.2) scribing lines on the tinfoil paper of the EVA plate with the thickness of 4mm after the tinfoil paper is pasted;

(3.3) scribing lines on the tinfoil paper on one surface of the EVA plate with the thickness of 7mm after the tinfoil paper is pasted;

and (3.4) scribing lines on the tinfoil paper on the other surface of the EVA plate with the thickness of 7mm after the tinfoil paper is pasted.

5. The method for manufacturing the conductive cloth precision target plate as claimed in claim 4, wherein the step (4) is specifically as follows: fixing a wire on the scribed EVA plate with the thickness of 7mm, specifically, perforating the EVA plate by using a 2mm pointed cone, enabling the 1mm wire to smoothly pass through the perforation, stripping off a wire insulating layer after the wire passes through the wire, ensuring that the length of the two sides of the target plate is 30mm, contacting the wires at two ends with the tin foil paper, and locally fixing the wires by using a tin foil adhesive tape to enable the tin foil paper layers on the front and back sides of the target plate to be conducted.

6. The method for manufacturing the conductive cloth precision target plate according to claim 5, wherein the step (5) specifically comprises the steps of:

(5.1) uniformly coating fish bead glue on the area outside the scribed line on the one surface of the EVA sheet with the thickness of 7mm after scribing by using a doctor blade;

(5.2) placing the EVA plate with the glue thickness of 7mm on a tool, wherein the glue face is upward, and bonding the tinfoil paper face of the EVA plate with the thickness of 4mm with the EVA plate with the thickness of 7mm to form an EVA layer with the thickness of 11mm, namely bonding one face of the EVA plate with the thickness of 4mm, which is not pasted with the tinfoil paper, with the face of the EVA plate with the thickness of 7mm, which is coated with the fish bead glue, to form an EVA layer with the thickness of 11 mm;

(5.3) producing a flat cable with a head, and defining a port;

(5.4) using a paper cutter to open wire passing holes on two surfaces of the EVA layer with the thickness of 11mm, conducting the flat cable with the head with the cutting area, and fixing a conducting terminal by using a tin foil adhesive tape;

(5.5) uniformly coating fish bead glue on one surface of the EVA layer with the thickness of 11mm, namely the other surface of the EVA plate with the thickness of 7mm, which is not jointed with the EVA plate with the thickness of 4mm, by using a scraping blade;

(5.6) placing an EVA (ethylene vinyl acetate) layer with the thickness of 11mm on a tool, wherein the glue surface is upward, bonding one EVA plate with the thickness of 2mm with the EVA layer with the thickness of 11mm to form an EVA layer with the thickness of 13mm, and scratching the EVA plate with the thickness of 2mm at a flat cable position to pass the cable;

(5.7) placing the 13 m-thick EVA layer on the upper quadrant layer of the tool upwards, wherein the surface which is not bonded with the 2 mm-thick EVA plate, namely the surface of the original 4 mm-thick EVA plate, faces upwards, and marking along the outer edge of the tool by using a pencil;

(5.8) after scribing, uniformly brushing fish bead glue on the area outside the target plate by using a scraping blade;

(5.9) placing the EVA layer with the thickness of 13mm and brushed with the glue on a tool, wherein the glue face is upward, and bonding another EVA plate with the thickness of 2mm and the EVA layer with the thickness of 13mm together to form an EVA layer with the thickness of 15 mm;

(5.10) placing an EVA layer with the thickness of 15mm on a tool, sequentially cutting the appearance to ensure that the size is 600 multiplied by 700, and forming the conductive cloth precision target plate.

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