CN113413003B - Mounting structure, carrying tool and manufacturing method - Google Patents

Abstract

The invention relates to a mounting structure, a carrier and a manufacturing method. The mounting structure comprises a substrate, a first gap transversely arranged on the substrate, a second gap longitudinally arranged on the substrate and a hollowed-out structure arranged on the substrate; the mounting part can pass through the first gap and the hollow structure in a reciprocating manner, so that the equipment to be mounted is longitudinally mounted on the substrate; the mounting part can pass through the second gap and the hollow structure in a reciprocating manner, so that the equipment to be mounted is transversely mounted on the substrate; the first slit does not intersect the second slit. The invention can meet the mounting requirements in two directions, the mounting can be carried out on the mounting area, and the utilization rate of the mounting area is relatively balanced. Compared with the mode of only using hollowed-out parts, the mode of matching the gaps with hollowed-out parts has the advantages that the material waste of the substrate is less, and the overall strength is high.

Description

Mounting structure, carrying tool and manufacturing method

Technical Field

The invention relates to the technical field of outdoor exercises and tactical equipment, in particular to a mounting structure, a carrier and a manufacturing method.

Background

With the development of the technical field of outdoor exercises and tactical equipments, in order to facilitate the mounting of accessories, a modular lightweight load equipment system (MOLLE system) has been developed, which is a carrier, i.e. a plurality of woven belts are sewn on a substrate at a certain distance longitudinally, and each woven belt is sewn at a certain distance transversely, so that the mounting part of the equipment, such as a fixing strip on the back of the accessory, can be mounted on the substrate through the woven belt.

Although the MOLLE system can meet the mounting requirements of different equipment, the weight of the carrier is large due to the fact that a plurality of woven belts are sewn on the MOLLE system. In order to reduce the weight, the array hollowed-out parts manufactured by laser cutting are arranged on the substrate by taking the whole piece of fabric as the substrate, and the hollowed-out parts arranged in an array are arranged on the substrate by using a laser cutting technology, so that the mounting parts of the equipment can be alternately mounted on the substrate through the hollowed-out parts.

However, two kinds of mounting structures have certain problems, firstly, two kinds of mounting structures only have longitudinal mounting channels, and equipment such as accessory bags can only be mounted in an upward or downward mode under the condition that a switching device is not adopted, so that the mounting direction is limited, and the taking and placing are inconvenient. Taking an accessory bag as an example, the accessory bag mounted longitudinally can only be opened upwards or opened downwards, and the requirement of transversely taking the articles in the accessory bag can not be met. In addition, the equipment can only be longitudinally mounted, so that the utilization rate of the mounting areas at the upper part and the lower part of the base body is higher, but the utilization rate of the mounting area at the middle part of the base body is lower, and a certain degree of waste is caused. Secondly, the mode of array fretwork of laser cutting preparation can lighten weight, but the fretwork degree is too big, leads to the base material extravagant more, bulk strength is not enough, and the probability of taking place to warp because of the distortion atress improves greatly.

Disclosure of Invention

Based on the above, it is necessary to provide a mounting structure and a manufacturing method thereof, aiming at the problems of the mounting structure in the prior art that only the requirement of longitudinal mounting can be met, the utilization rate of the mounting area is unbalanced, the substrate material is wasted more and the strength is lower due to the overlarge hollowed-out degree.

The mounting structure is used for being coupled with a mounting part of equipment to be mounted and comprises a substrate, a first gap transversely formed in the substrate, a second gap longitudinally formed in the substrate and a hollowed-out structure formed in the substrate; the first gap, the second gap and the hollow structure penetrate at least part of the substrate, so that the mounting part can be longitudinally mounted on the first gap and/or the hollow structure, or the mounting part can be transversely mounted on the second gap and/or the hollow structure.

The mounting structure solves the problems that the mounting structure in the prior art can only meet the requirement of longitudinal mounting, the utilization rate of a mounting area is unbalanced, the degree of hollowing is too large, so that the waste of base materials is more and the strength is lower, and a first gap, a second gap and a hollow structure are formed in a base. The gaps distributed in the two directions are matched with the hollow structure, and a channel is provided for the mounting part of the equipment to be mounted to penetrate through the substrate. In one mode, the mounting part can be matched with the hollow structure through the first gap to longitudinally reciprocate through the substrate, so that the equipment to be mounted is longitudinally mounted on the substrate. In another mode, the mounting part can be matched with the hollow structure through the second gap to transversely reciprocate through the substrate, so that the equipment to be mounted is transversely mounted on the substrate. The mounting areas provided with the first gaps, the second gaps and the hollow structures can be mounted, and the utilization rate of the mounting areas is balanced. Compared with the mode of only using hollowed-out parts, the mode of matching the gaps with hollowed-out parts has the advantages that the material waste of the substrate is less, and the overall strength is high.

The technical scheme of the application is further described below:

in one embodiment, at least two first slits are arranged according to a preset array arrangement mode; and the second gaps are arranged at least two according to a preset array arrangement mode.

In one embodiment, at least one hollowed-out structure is arranged between two longitudinally adjacent first gaps; at least one hollowed-out structure is arranged between two adjacent second gaps along the transverse direction.

In one embodiment, a virtual square is defined by a straight line where the adjacent first gap is located and a straight line where the second gap is located, and the hollow structure is arranged in the virtual square; the hollow structure is a polygonal hollow structure, and the hollow area of the polygonal hollow structure is smaller than the product of the length of the first gap and the length of the second gap.

In one embodiment, each vertex angle position of the polygonal hollowed-out part is provided with a round angle; at least one end of the first gap is provided with a first expansion part so as to disperse the pulling stress generated at the end of the first gap; at least one end of the second slit is provided with a second expansion part to disperse a pulling stress generated at the end of the second slit.

In addition, the application also provides a carrier, which comprises the mounting structure.

In addition, the application also provides a manufacturing method of the mounting structure, the mounting structure comprises a substrate, a first gap, a second gap and a hollow structure, the mounting structure is used for being coupled with a mounting part of equipment to be mounted, and the manufacturing method of the mounting structure comprises the following steps:

s1, determining a first reference square with a side length of a preset unit length, and arranging the first reference square in an array manner to obtain a first group of arrays; determining a second reference square with a side length of a preset unit length, and arranging the second reference square in an array manner to obtain a second group of arrays;

superimposing the first set of arrays with the second set of arrays such that the squares in each of the first set of arrays partially coincide with the squares in at least one of the second set of arrays;

s2, deleting transverse side lines in the first group of arrays, deleting longitudinal side lines in the second group of arrays, and taking the rest side lines as channel datum lines;

s3, determining a closed cutting reference graph according to the channel reference line with the intersection point, so that the channel reference line with the intersection point is positioned in an area surrounded by the cutting reference graph; taking a transverse channel datum line outside an area surrounded by the cutting datum pattern as a first cutting datum line; taking a longitudinal channel datum line outside the area surrounded by the cutting datum pattern as a second cutting datum line;

s4, cutting the substrate by taking the first cutting datum line as a datum to obtain the first gap, cutting the substrate by taking the second cutting datum line as a datum to obtain the second gap, and cutting the substrate by taking the cutting datum pattern as a datum to obtain the hollowed-out structure.

The manufacturing method of the mounting structure can manufacture a first gap, a second gap and a hollowed-out structure; the mounting areas provided with the first gaps, the second gaps and the hollow structures can be mounted, and the utilization rate of the mounting areas is balanced. Compared with the mode of only using hollowed-out parts, the mode of matching the gaps with hollowed-out parts has the advantages that the material waste of the substrate is less, and the overall strength is high. In addition, the array arrangement and superposition modes are adopted, and the manufacturing method is simpler and is easy to repeat.

In one embodiment, the step of arranging the first reference square in the step S1 includes: arranging the first reference squares in an array manner at a preset unit length transversely spaced by one half of the preset unit length longitudinally spaced;

the step of arranging the second reference square in the step S1 includes: arranging the second reference square in an array by transversely spacing a preset unit length by one half and longitudinally spacing a preset unit length;

the step of superimposing the first set of arrays and the second set of arrays in step S1 includes: moving the second group of arrays by a preset unit length of one fourth in the transverse positive direction and by a preset unit length of one fourth in the longitudinal negative direction based on the first group of arrays;

the step S3 comprises the following steps: and sequentially connecting the endpoints of the crossed channel datum lines to form a closed cutting datum quadrilateral.

In one embodiment, the step of arranging the first reference square in the step S1 includes: arranging the first reference squares in an array manner at intervals of a preset unit length in the transverse direction;

the step of arranging the second reference square in the step S1 includes: determining a second reference square with a side length of a preset unit length, determining a first reference line segment at a position which is spaced by one half of the preset unit length of the second reference square, wherein the length of the first reference line segment is the preset unit length, and arranging the second reference square and the first reference line segment in an array at a position which is spaced by one half of the preset unit length;

the step of superimposing the first set of arrays and the second set of arrays in step S1 includes: moving the second group of arrays by a preset unit length of one fourth in the transverse positive direction and by a preset unit length of one fourth in the longitudinal positive direction based on the first group of arrays;

the step S3 comprises the following steps: at the position of the crossed channel datum line, a first longitudinal edge line which passes through one end of the transverse channel datum line and is parallel to the longitudinal channel datum line and is three-quarters of a preset unit length is formed; a second longitudinal edge line which passes through the other end of the transverse channel datum line and is parallel to the longitudinal channel datum line and is three-quarters of a preset unit length; and the first longitudinal side line, the longitudinal channel datum line with the intersection point and the midpoint of the second longitudinal side line are positioned on the same transverse straight line, and the endpoints of the first longitudinal side line, the longitudinal channel datum line with the intersection point and the second longitudinal side line are sequentially connected to form a closed cutting datum hexagon.

In one embodiment, the preset unit length is determined according to a mounting portion of the equipment to be mounted.

Drawings

FIG. 1 is a schematic diagram of a tactical vest according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a mounting structure according to an embodiment of the present invention;

FIG. 3 is a schematic view of a waistband according to another embodiment of the present invention;

FIG. 4 is a schematic view of a mounting structure according to another embodiment of the present invention;

FIG. 5 is a schematic structural diagram of the first array and the second array after stacking in step S1 according to an embodiment of the present invention;

FIG. 6 is a schematic structural diagram of a channel datum line obtained after the step S2 is completed in an embodiment of the present invention;

FIG. 7 is a schematic diagram of a structure of determining a cutting reference pattern in step S3 according to an embodiment of the present invention;

FIG. 8 is a schematic structural diagram of the first cutting reference line, the second cutting reference line and the cutting reference pattern obtained by completing the step S3 according to an embodiment of the present invention;

FIG. 9 is a schematic structural diagram of a mounting structure obtained after the step S4 is completed in an embodiment of the present invention;

FIG. 10 is a schematic diagram of the first array and the second array stacked in step S1 according to an embodiment of the present invention;

FIG. 11 is a schematic structural diagram of a channel datum line obtained after the completion of the step S2 according to another embodiment of the present invention;

FIG. 12 is a schematic diagram of a structure of determining a cutting reference pattern in step S3 according to another embodiment of the present invention;

FIG. 13 is a schematic structural diagram of the first cutting reference line, the second cutting reference line and the cutting reference pattern obtained by completing the step S3 according to another embodiment of the present invention;

fig. 14 is a schematic structural diagram of a mounting structure obtained after the completion of step S4 according to another embodiment of the present invention;

fig. 15 is a schematic structural view of a tactical vest in another embodiment of the present invention.

Reference numerals: 10. a carrier; 100. a substrate; 110. a first slit; 111. a first expansion part; 120. a second slit; 121. a second expansion part; 130. a hollow structure; 131. round corners; 132. a first reference line; 133. a second reference line; 140. a first reference square; 150. a second reference square; 151. a first reference line segment; 160. a channel datum line; 161. a first cutting reference line; 162. a second cutting reference line; 163. cutting a reference pattern; 1631. a first longitudinal edge; 1632. a second longitudinal edge; 20. and a mounting part.

Detailed Description

In order that the above objects, features and advantages of the invention will be readily understood, a more particular description of the invention will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the invention, whereby the invention is not limited to the specific embodiments disclosed below.

Referring to fig. 1-4, an embodiment of the present invention provides a mounting structure that can be provided on a variety of carriers 10, for example, the carrier 10 can be a tactical vest as shown in fig. 1 or 15, and a belt as shown in fig. 3. Or the mounting structure is arranged on other military and outdoor carrying devices 10, and the mounting structure can be coupled with the mounting part 20 of the equipment to be mounted. The equipment to be mounted can be other kinds of military and outdoor equipment besides accessory bags. The mounting structure includes a base 100, and the base 100 may be rubber, a plate material, or a cloth material meeting the strength requirement. In this embodiment, the mounting portion 20 of the to-be-mounted device is a fixing band for mounting, which is disposed on the back of the accessory bag, and the fixing band is coupled with the mounting structure and then folded and fixed, so that the accessory bag is mounted on the substrate 100. Specifically, with continued reference to fig. 1-4, the mounting structure further includes a first slit 110 that is transversely opened on the substrate 100, a second slit 120 that is longitudinally opened on the substrate 100, and a hollow structure 130 that is opened on the substrate 100; the first slit 110, the second slit 120 and the hollow structure 130 penetrate at least part of the substrate 100, so that the mounting portion 20 can be longitudinally mounted on the first slit 110 and/or the hollow structure 130, or the mounting portion 20 can be transversely mounted on the second slit 120 and/or the hollow structure 130.

The mounting structure solves the problems of more waste of substrate materials and lower strength caused by unbalanced utilization rate and overlarge hollowed-out degree of a mounting area, which only can meet the requirement of longitudinal mounting, of the mounting structure in the prior art, and the substrate 100 is provided with the first gap 110, the second gap 120 and the hollowed-out structure 130. Referring to fig. 2 and fig. 4, the two slots (the first slot 110 and the second slot 120) are matched with the hollow structure 130 to provide a channel for the mounting portion 20 of the device to be mounted to pass through the substrate 100. In one manner, the mounting portion 20 can be matched with the hollow structure 130 through the first gap 110, so that the mounting portion 20 longitudinally reciprocates through the substrate 100, and the equipment to be mounted is longitudinally mounted on the substrate 100. In another way, the mounting portion 20 may be matched with the hollow structure 130 through the second gap 120, so that the mounting portion 20 may traverse through the substrate 100 in a transverse direction, and the device to be mounted is mounted on the substrate 100 in a transverse direction. The mounting areas provided with the first gap 110, the second gap 120 and the hollow structure 130 can be mounted, and the utilization rate of the mounting areas is balanced. Compared with the hollow mode, the hollow mode is adopted by the mounting structure, and the material waste of the substrate 100 is less and the overall strength is higher. The first slit 110 and the second slit 120 may be provided as curved lines or broken lines in addition to straight lines, so as to improve compatibility of the first slit 110 and the second slit 120 with the mounting portions 20 having different thicknesses. When the first slit 110/the second slit 120 are provided in a curve, chords connecting both ends of the curve are laid in the lateral/longitudinal direction. When the first slit 110/the second slit 120 are provided as a folding line, line segments connecting both end points of the folding line are laid in the lateral/longitudinal direction. The widths of the first and second slits 110, 120 may be set as needed, and appropriately increasing the widths of the first and second slits 110, 120 can improve compatibility of the two with the mounting portions 20 having different thicknesses.

With continued reference to fig. 2 and fig. 4, in some embodiments, at least two first slits 110 are arranged according to a preset array arrangement manner; the second slits 120 are provided in at least two according to a preset array arrangement manner. It should be noted that, the preset array arrangement mode is set according to the area of the substrate, the substrate material and the requirement, the array arrangement mode includes an array direction and an array quantity, wherein the array direction can be only arranged in a transverse direction, only arranged in a longitudinal direction, or arranged in both the transverse direction and the longitudinal direction; the number of arrays may be a natural number greater than zero, and preferably the number of arrays takes an even number greater than zero. For example, with continued reference to fig. 1 and 2, in one embodiment, the mounting structure is disposed on the tactical back, and the first slits 110 are arranged in an equally spaced array in the lateral direction and in an equally spaced array in the longitudinal direction; the second slits 120 are arranged in an equally spaced array in the lateral direction and in an equally spaced array in the longitudinal direction. With continued reference to fig. 3-4, in one embodiment, the mounting structure is disposed on the waistband, and the first slits 110 are disposed in two rows longitudinally spaced apart from the array, and laterally spaced apart from the array; the second slits 120 are arranged in an array at equal intervals only in the lateral direction due to the width limitation of the waistband. When the mounting structure is arranged on a relatively wide waist seal (not shown), the second slits 120 may also be arranged in two rows at a longitudinally spaced array.

Further, in an embodiment, at least one hollow structure 130 is disposed between two longitudinally adjacent first slits 110; at least one hollow structure 130 is disposed between two adjacent second slits 120 along the transverse direction. For example, with continued reference to fig. 1 and 2, in an embodiment, two hollowed structures 130 are disposed between two longitudinally adjacent first slits 110, and two hollowed structures 130 are disposed between two laterally adjacent second slits 120. With continued reference to fig. 3 and fig. 4, in an embodiment, a hollowed-out structure 130 is disposed between two adjacent first slits 110, and two hollowed-out structures 130 are disposed between two adjacent second slits 120. It should be noted that the number of the hollow structures 130 is determined according to the substrate area, the substrate material and the requirement.

With continued reference to fig. 2 and fig. 4, in an embodiment, a line where the adjacent first slit 110 and a line where the second slit 120 are located define a virtual square, and the hollow structure 130 is disposed in the virtual square; the hollow structure 130 is configured as a polygonal hollow, and the hollow area of the polygonal hollow is smaller than the product of the length of the first slit 110 and the length of the second slit 120. To better describe the present embodiment, a line segment where the maximum width of the hollow structure 130 in the transverse direction is taken as the first reference line 132, and a line segment where the maximum width of the hollow structure 130 in the longitudinal direction is taken as the second reference line 133; the hollow structure 130 is disposed in a right angle included angle range between a straight line where the first slit 110 is located and a straight line where the second slit 120 is located, the first reference line 132 is equal to the first slit 110, and the second reference line 133 is equal to the second slit 120; the hollow structure 130 is configured as a polygonal hollow, and the hollow area of the polygonal hollow is smaller than the product of the length of the first slit 110 and the length of the second slit 120.

Above-mentioned mounting structure, in order to satisfy under horizontal and vertically mounting demand's the prerequisite, reduce the fretwork area, and then reduce the waste of basement, improve bulk strength. In order to meet the requirement of mounting in the transverse and longitudinal directions, if the hollow structure 130 is configured as a square hollow, the area of the square hollow needs to be greater than or equal to the product of the length of the first reference line 132 and the length of the second reference line 133, that is, the product of the length of the first slit 110 and the length of the second slit 120. The mounting structure sets the hollow structure 130 as a polygonal hollow, and the polygonal hollow is an inscribed polygon of the square, i.e. the hollow area of the polygonal hollow is smaller than the product of the length of the first slit 110 and the length of the second slit 120. The mounting structure has less material waste of the substrate 100 and larger overall strength. In addition, the hollow structure 130 is arranged as a polygonal hollow structure, so that stress can be dispersed, and the durability of the mounting structure is improved. In particular, referring to fig. 1-4, polygons include, but are not limited to, being provided as isosceles trapezoids, hexagons.

Referring to fig. 2 and 4, in an embodiment, the length of the first slot 110 is equal to the width of the mounting portion 20 of the equipment to be mounted; the length of the second slit 120 is equal to the width of the mounting portion 20 of the equipment to be mounted. The maximum size of the hollow structure 130 in the transverse direction is equal to the width of the mounting part 20 of the equipment to be mounted; the maximum dimension of the hollowed-out structure 130 in the longitudinal direction is equal to the width of the mounting part 20 of the equipment to be mounted. In this way, the mounting portion 20 of the to-be-mounted device can just penetrate into/out of the mounting portion to reduce the possibility of shaking in the first gap 110, the second gap 120 or the hollow structure 130, and improve the reliability of mounting. It should be noted that, the corresponding dimensions of the first gap 110, the second gap 120, and the hollow structure 130 may be slightly larger than the width of the mounting portion 20. With continued reference to fig. 1 and 2, further, in an embodiment, each vertex angle position of the polygonal hollow is provided with a rounded corner 131; the first expansion part 111 is provided at both ends of the first slit 110; the second slit 120 is provided at both ends with a second expansion portion 121. The first expansion portion 111 and the second expansion portion 121 include, but are not limited to, circular holes, elliptical holes, or partial circular arc structures. The first expansion part 111 and the second expansion part 121 are not limited to be provided on the tactical back as shown in fig. 1 and 2, but may be provided on other types of carriers as needed. Compared with the mode without round corners and round holes, the mounting structure is more beneficial to dispersing pulling stress and improves the durability of the structure.

In addition, the present application also provides a carrier 10 including the mounting structure as described above. The carrier 10 includes, but is not limited to, a tactical vest, a belt.

In addition, the application also provides a manufacturing method of the mounting structure, wherein the mounting structure is used for being coupled with the mounting part 20 of the equipment to be mounted. The mounting structure is generally manufactured by drawing a cutting reference line with a tool such as drawing software, and then cutting on the substrate 100 with the cutting reference line as a reference by using a laser cutting technology, so as to obtain the mounting structure with a mounting channel. The mounting portion 20 of the equipment to be mounted, for example, a fixing band for mounting provided on the back of the accessory bag, may sequentially/selectively pass through a channel cut on the base 100, and be folded and fixed for mounting purposes. Referring to fig. 5 to 14, the mounting structure includes a substrate 100, a first slit 110, a second slit 120, and a hollow structure 130, and the manufacturing method of the mounting structure includes the following steps:

step S1, referring specifically to FIG. 5, a first reference square 140 with a side length being a preset unit length is determined, and the first reference square 140 is arranged in an array manner to obtain a first group of arrays (refer to the solid square array in FIG. 5); a second reference square 150 having a side length of a predetermined unit length is determined, and the second reference square 150 is arranged in an array to obtain a second group of arrays (refer to the array of broken line squares in fig. 5). For clarity of illustration of the stacking process, the solid lines in the figure represent the first set of arrays, the dashed lines in the figure represent the second set of arrays, and the two may not be distinguished during actual identification. The first and second sets of arrays are stacked such that the squares in each first set of arrays partially coincide with the squares in at least one second set of arrays. It should be noted that, the preset unit length is determined according to the mounting portion 20 of the device to be mounted. Preferably, the preset unit length is equal to the mounting portion 20 of the equipment to be mounted, so that the mounting structure manufactured by the method is conveniently coupled with the mounting portion 20. In addition, the first reference square 140 and the second reference square 150 are arranged in an array manner according to the substrate area, the substrate material or the requirement.

For example, in a first manner, see fig. 5, when the substrate area is large, such as a tactical vest.

The step of arranging the first reference square 140 in the step S1 includes: the first reference squares 140 are laterally spaced apart by a predetermined unit length and arranged in an array at a predetermined unit length spaced apart by one half in the longitudinal direction. The step of arranging the second reference square 150 in the step S1 includes: the second reference squares 150 are arranged in an array with a predetermined unit length laterally spaced by one half and a predetermined unit length longitudinally spaced.

The step of superimposing the first array with the second array in step S1 includes: the second group of arrays is moved by a preset unit length of one fourth in the transverse positive direction and by a preset unit length of one fourth in the longitudinal negative direction based on the first group of arrays. The positive direction in the transverse direction is directed horizontally to the right, and the negative direction in the transverse direction is directed horizontally to the left; the positive direction in the longitudinal direction is directed vertically upwards and the negative direction in the longitudinal direction is directed vertically downwards. In addition, the second set of arrays is referenced to the first set of arrays by moving the second reference square 150 relative to the first reference square 140, and moving the other squares in the arrays synchronously, in the same direction, and equidistantly. Specifically, referring to fig. 5, in one embodiment, the preset unit length is 1 inch, and step S1 includes drawing 1 inch long and 1 inch high squares on the substrate 100, and arranging the squares in an array with a lateral spacing of 1 inch and a longitudinal spacing of 0.5 inch, where the number of lateral arrays is an integer multiple of 2, and the number of longitudinal arrays is an integer multiple of 2, to obtain a first set of arrays. Squares 1 inch long and 1 inch high are drawn on the substrate 100 and arranged in arrays spaced 0.5 inch apart in the transverse direction and 1 inch apart in the longitudinal direction, with the number of transverse arrays being an integer multiple of 2 and the number of longitudinal arrays being an integer multiple of 2, resulting in a second set of arrays. The overlapping mode in the step S1 is as follows: the first grid from the top left of the second set of arrays is stacked with the first grid from the top left of the first set of arrays shifted 0.25 inches laterally to the right and 0.25 inches longitudinally downward.

In a second manner, referring to fig. 10, when the substrate 100 is an elongated substrate, such as a belt.

The step of arranging the first reference square 140 in the step S1 includes: arranging the first reference squares 140 in an array with a preset unit length therebetween in the lateral direction;

the step of arranging the second reference square 150 in the step S1 includes: a second reference square 150 with a side length of a preset unit length is determined, a first reference line segment 151 is determined at a position which is spaced by one half of the preset unit length of the second reference square 150, the length of the first reference line segment 151 is the preset unit length, and the second reference square 150 and the first reference line segment 151 are arranged in an array at a lateral interval of one half of the preset unit length.

Specifically, referring to fig. 10, in one embodiment, a preset unit length is 1 inch, squares 1 inch long and 1 inch high are drawn on the substrate 100, and arranged in arrays spaced 1 inch apart in the lateral direction, the number of arrays being an integer multiple of 2, resulting in a first set of arrays. Square grids with a length of 1 inch and a height of 1 inch are drawn on the substrate 100, transverse lines with a length of 1 inch are drawn right under the square grids, the distance between the lines and the bottom edges of the square grids is 0.5 inch, and the lines are arranged in an array mode according to the transverse interval of 0.5 inch, and the number of the arrays is an integral multiple of 2, so that a second group of arrays is obtained. The overlapping mode in the step S1 is as follows: the first square from the left of the second set of arrays is stacked 0.25 inches upward and 0.25 inches to the right from the first square from the left of the first set of arrays.

In step S2, referring to fig. 6 and 11, the lateral edge lines in the first set of arrays are deleted, the longitudinal edge lines in the second set of arrays are deleted, and the remaining edge lines are used as channel reference lines 160.

Step S3, referring to FIGS. 7 and 12, a closed cutting reference pattern 163 is determined according to the channel reference line 160 having the intersection point, so that the channel reference line 160 having the intersection point is located within the area surrounded by the cutting reference pattern 163; taking a lateral channel reference line 160 outside the area surrounded by the cutting reference pattern 163 as a first cutting reference line 161; a longitudinal channel reference line 160 outside the area surrounded by the cutting reference pattern 163 is taken as a second cutting reference line 162.

For example, in a first manner, see fig. 7, when the substrate area is large, such as a tactical vest. The step S3 comprises the following steps: the endpoints of the crisscrossed channel reference line 160 are sequentially connected to form a closed cut reference quadrilateral. With continued reference to fig. 7, in one embodiment, step S3 includes: the lines connect the longitudinal lines of columns 2, 3, 5, 6, 8, 9 and … (columns other than 3 n-2) of the first array with the lines of rows 1, 3, 4, 6, 7, 9 and 10 … (rows other than 3 n-1) of the second array to form a closed isosceles trapezoid pattern, and the isosceles trapezoid pattern is used as the cutting reference pattern 163.

In a second way, see fig. 12, when the substrate is an elongated substrate, such as a belt. The step S3 comprises the following steps: a first longitudinal edge 1631 of a predetermined unit length of three-quarters passing through one end (point a in the figure) of the transverse channel reference line 160a and the channel reference line 160b parallel to the longitudinal direction at the position of the crisscross channel reference line 160; a second longitudinal edge 1632 of a predetermined unit length passing through the other end (point b in the figure) of the transverse channel reference line 160a and parallel to the longitudinal channel reference line 160b by three quarters; the first longitudinal side line 1631, the longitudinal channel reference line 160b having the intersection point, and the midpoint (points c, d, e in the drawing) of the second longitudinal side line 1632 are on the same transverse straight line, and the end points of the first longitudinal side line 1631, the longitudinal channel reference line 160b having the intersection point, and the second longitudinal side line 1632 are sequentially connected to form a closed cut reference hexagon. With continued reference to fig. 12, in one embodiment, step S3 includes: in each crisscrossed pattern, a 0.75 inch long longitudinal line was drawn parallel to the longitudinal line through one end of the transverse line, a 0.75 inch long longitudinal line was drawn parallel to the longitudinal line through the other end of the transverse line, three longitudinal line midpoints (points c, d, e in the figure) were maintained at the same horizontal line, and six ends of the three longitudinal lines were connected by lines to form a hexagonal pattern, and the hexagonal pattern was used as the cutting reference pattern 163.

In step S4, referring to fig. 8, 9, 13 and 14, the first slit 110 is cut on the substrate 100 with the first cutting reference line 161 as a reference, the second slit 120 is cut with the second cutting reference line 162 as a reference, and the hollowed-out structure 130 is cut with the cutting reference pattern 163 as a reference. Further, referring to fig. 7 and 12, in one embodiment, step S4 includes a step of deleting the lateral and longitudinal lines in the closed figure. Further, the resulting pattern may be modified as appropriate, including but not limited to slightly lengthening each line, or adding round holes, rounded corners at the end points of the pattern, the top corners of the pattern, to disperse the stress.

The method for manufacturing the mounting structure can manufacture the substrate 100 with the first gap 110, the second gap 120 and the hollow structure 130; the mounting areas provided with the first gap 110, the second gap 120 and the hollow structure 130 can be mounted, and the utilization rate of the mounting areas is balanced. Compared with the mode of only using hollowed-out parts, the mode of matching the gaps with hollowed-out parts has the advantages that the material waste of the substrate is less, and the overall strength is high. In addition, the array arrangement and superposition modes are adopted, and the manufacturing method is simpler and is easy to repeat.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present invention, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present invention, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

It will be understood that when an element is referred to as being "fixed" or "disposed" on another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (10)

1. The manufacturing method of the mounting structure is used for being coupled with a mounting part of equipment to be mounted, and the mounting structure comprises a substrate, a first gap, a second gap and a hollowed-out structure, and is characterized by comprising the following steps:

s1, determining a first reference square with a side length of a preset unit length, and arranging the first reference square in an array manner to obtain a first group of arrays; determining a second reference square with a side length of a preset unit length, and arranging the second reference square in an array manner to obtain a second group of arrays;

superimposing the first set of arrays with the second set of arrays such that the squares in each of the first set of arrays partially coincide with the squares in at least one of the second set of arrays;

s2, deleting transverse side lines in the first group of arrays, deleting longitudinal side lines in the second group of arrays, and taking the rest side lines as channel datum lines;

s3, determining a closed cutting reference graph according to the channel reference line with the intersection point, so that the channel reference line with the intersection point is positioned in an area surrounded by the cutting reference graph; taking a transverse channel datum line outside an area surrounded by the cutting datum pattern as a first cutting datum line; taking a longitudinal channel datum line outside the area surrounded by the cutting datum pattern as a second cutting datum line;

s4, cutting the substrate by taking the first cutting datum line as a datum to obtain the first gap, cutting the substrate by taking the second cutting datum line as a datum to obtain the second gap, and cutting the substrate by taking the cutting datum pattern as a datum to obtain the hollowed-out structure.

2. The method of manufacturing a mounting structure according to claim 1, wherein,

the step of arranging the first reference square in the step S1 includes: arranging the first reference squares in an array manner at a preset unit length transversely spaced by one half of the preset unit length longitudinally spaced;

the step of arranging the second reference square in the step S1 includes: arranging the second reference square in an array by transversely spacing a preset unit length by one half and longitudinally spacing a preset unit length;

the step of superimposing the first set of arrays and the second set of arrays in step S1 includes: moving the second group of arrays by a preset unit length of one fourth in the transverse positive direction and by a preset unit length of one fourth in the longitudinal negative direction based on the first group of arrays;

the step S3 comprises the following steps: and sequentially connecting the endpoints of the crossed channel datum lines to form a closed cutting datum quadrilateral.

3. The method of manufacturing a mounting structure according to claim 1, wherein,

the step of arranging the first reference square in the step S1 includes: arranging the first reference squares in an array manner at intervals of a preset unit length in the transverse direction;

the step of arranging the second reference square in the step S1 includes: determining a second reference square with a side length of a preset unit length, determining a first reference line segment at a position which is spaced by one half of the preset unit length of the second reference square, wherein the length of the first reference line segment is the preset unit length, and arranging the second reference square and the first reference line segment in an array at a position which is spaced by one half of the preset unit length;

the step of superimposing the first set of arrays and the second set of arrays in step S1 includes: moving the second group of arrays by a preset unit length of one fourth in the transverse positive direction and by a preset unit length of one fourth in the longitudinal positive direction based on the first group of arrays;

the step S3 comprises the following steps: at the position of the crossed channel datum line, a first longitudinal edge line which passes through one end of the transverse channel datum line and is parallel to the longitudinal channel datum line and is three-quarters of a preset unit length is formed; a second longitudinal edge line which passes through the other end of the transverse channel datum line and is parallel to the longitudinal channel datum line and is three-quarters of a preset unit length; and the first longitudinal side line, the longitudinal channel datum line with the intersection point and the midpoint of the second longitudinal side line are positioned on the same transverse straight line, and the endpoints of the first longitudinal side line, the longitudinal channel datum line with the intersection point and the second longitudinal side line are sequentially connected to form a closed cutting datum hexagon.

4. A method of manufacturing a mounting structure according to any one of claims 1 to 3, wherein the predetermined unit length is determined in accordance with a mounting portion of the equipment to be mounted.

5. A mounting structure manufactured by the manufacturing method of the mounting structure according to any one of claims 1 to 4, for coupling with a mounting portion of equipment to be mounted, characterized in that the mounting structure comprises:

the device comprises a substrate, a first gap transversely formed in the substrate, a second gap longitudinally formed in the substrate and a hollow structure formed in the substrate;

the first gap, the second gap and the hollow structure penetrate at least part of the substrate, so that the mounting part can be longitudinally mounted on the first gap and/or the hollow structure, or the mounting part can be transversely mounted on the second gap and/or the hollow structure.

6. The mounting structure of claim 5, wherein the first slots are arranged in at least two predetermined array arrangements; and the second gaps are arranged at least two according to a preset array arrangement mode.

7. The mounting structure of claim 6, wherein at least one hollowed-out structure is disposed between two longitudinally adjacent first slits; at least one hollowed-out structure is arranged between two adjacent second gaps along the transverse direction.

8. Mounting structure according to any one of claims 5-7, characterized in that,

the straight line where the adjacent first gap is located and the straight line where the second gap is located define a virtual square, and the hollow structure is arranged in the virtual square; the hollow structure is a polygonal hollow structure, and the hollow area of the polygonal hollow structure is smaller than the product of the length of the first gap and the length of the second gap.

9. The mounting structure of claim 8, wherein each vertex angle position of the polygonal hollowed-out is provided with a fillet; at least one end of the first gap is provided with a first expansion part so as to disperse the pulling stress generated at the end of the first gap; at least one end of the second slit is provided with a second expansion part to disperse a pulling stress generated at the end of the second slit.

10. A carrier comprising a mounting structure as claimed in any one of claims 5 to 9.