CN112571487A - Protective clothing system of processing - Google Patents

Abstract

The invention relates to cloth processing, in particular to a protective clothing processing system which comprises a device bracket, a driving mechanism I, a material conveying mechanism, a power mechanism, a driving mechanism II, a cutting bracket and a cutting mechanism, the material conveying mechanism can be driven to move at a constant speed through the driving mechanism I, the driving mechanism II is driven to move at a variable speed through the power mechanism, the cutting support is driven to move at a variable speed through the driving mechanism II, the cutting support drives the cutting mechanism to move at a variable speed, the distance between the cloth on the cutting mechanism and the cloth on the material conveying mechanism is changed by utilizing the speed difference between the cutting mechanism and the material conveying mechanism, thereby changing the relative position between the cloth on the cutting mechanism and the material conveying mechanism, when the cutting mechanism cuts, and the driving mechanism I and the driving mechanism II stop moving, so that the cutting mechanism can rapidly cut and process different positions on two sides of the cloth.

Description

Protective clothing system of processing

Technical Field

The invention relates to cloth processing, in particular to a protective clothing processing system.

Background

For example, publication No. CN111778701A discloses a component shearing device for cloth processing. The technical problem how to provide a weight shearing mechanism for cloth processing can cut the cloth automatically, reduce the knife and run the sword phenomenon, cut the cloth ration accurately, improve and cut efficiency. A component shearing device for cloth processing comprises a base, a double-shaft motor, a power rotating shaft and the like, wherein the double-shaft motor is fixedly arranged on the base; the invention has the defect that the cutting processing can not be rapidly carried out on different positions of two sides of the cloth.

Disclosure of Invention

The invention aims to provide a protective clothing processing system which can rapidly cut and process different positions on two sides of cloth.

The purpose of the invention is realized by the following technical scheme:

a protective clothing processing system comprises a device bracket, a driving mechanism I, a material conveying mechanism, a power mechanism, a driving mechanism II, a cutting bracket and a cutting mechanism, the front end sliding connection of device support has actuating mechanism I, fixedly connected with compression spring I between actuating mechanism I and the device support, be connected with fortune material mechanism on the device support, actuating mechanism I and fortune material mechanism contact, the rear end of device support is connected with power unit, actuating mechanism II is provided with two, two actuating mechanism II difference fixed connection are in the left and right sides of device support, two actuating mechanism II all are connected with the power unit transmission, sliding connection has the cutting support on the device support, fixedly connected with reset spring between cutting support and the device support, be connected with cutting mechanism on the cutting support, cutting support and II contacts of actuating mechanism, cutting mechanism and device support meshing transmission.

According to the protective clothing processing system, the device support comprises two side supports, two sliding supports, two connecting supports, a rack and a spring baffle, the sliding supports are fixedly connected to the two side supports, the connecting supports are fixedly connected between the rear ends of the two sliding supports, the rack is fixedly connected to the connecting supports, and the spring baffle is fixedly connected between the front ends of the two side supports.

As further optimization of the technical scheme, the protective clothing processing system comprises a driving mechanism I, a driving motor, vertical sliders, a driving wheel I and a sliding support ring, wherein the two ends of the driving shaft are rotatably connected with the vertical sliders, the two vertical sliders are respectively and slidably connected to the front ends of two side brackets, the driving motor is fixedly connected to one of the vertical sliders, the driving wheel I is fixedly connected to the driving shaft, the driving shaft is fixedly connected with an output shaft of the driving motor, the sliding support ring is rotatably connected to the driving shaft and is slidably connected to a spring baffle, and a compression spring I is fixedly connected between the spring baffle and the sliding support ring.

As a further optimization of the technical scheme, the protective clothing processing system comprises a material conveying mechanism, wherein the material conveying mechanism comprises a rotating cylinder, damping wheels, sliding columns, four conical clamping wheels, a material rolling cylinder and support rollers, the damping wheels are contacted on the rotating cylinder, the sliding columns are connected in the rotating cylinder in a sliding mode, the conical clamping wheels are fixedly connected on the sliding columns, compression springs II are fixedly connected between the conical clamping wheels and the rotating cylinder, the four rotating cylinders are provided, the four rotating cylinders are respectively and rotatably connected to the front end and the rear end of the two side brackets, the four damping wheels are respectively and fixedly connected to the front end and the rear end of the two side brackets, two support rollers are clamped between the four conical clamping wheels, the two support rollers are arranged, and the two support rollers are respectively and rotatably connected between the middle parts of the two side brackets.

As further optimization of the technical scheme, the protective clothing processing system comprises a power mechanism, a tooth-lacking gear, a power shaft I, a conical friction wheel I, a power shaft II, a conical friction wheel II, a telescopic mechanism I and a pulling clamp plate, wherein the tooth-lacking gear is fixedly connected to an output shaft of the power mechanism, the power motor is fixedly connected to side brackets on one side, the power shaft I is rotatably connected between the rear ends of the two side brackets, the conical friction wheel I is fixedly connected to the power shaft I, the power shaft I and the tooth-lacking gear are in meshing transmission, the power shaft II is rotatably connected between the rear ends of the two side brackets, the conical friction wheel II is fixedly connected to the power shaft II, the conical friction wheel II and the conical friction wheel I have equal tapers, the conical friction wheel II and the conical friction wheel I are connected through belt transmission, the pulling clamp plate is fixedly connected to the telescopic end of the telescopic mechanism I, the telescopic mechanism I is fixedly connected to the side support on one side, a transmission belt between the conical friction wheel II and the conical friction wheel I penetrates through the pulling clamping plate, and the rotating speed of the output shaft of the power motor is the same as that of the output shaft of the driving motor.

As further optimization of the technical scheme, the protective clothing processing system comprises a driving mechanism II, a driving wheel II and a friction belt, wherein the driving mechanism II comprises a driving support, the driving wheel II and the friction belt, the driving support is rotatably connected with the two driving wheels II, the two driving wheels II are in transmission connection through the friction belt, the outer sides of the two side supports are fixedly connected with the driving support, and the two driving wheels II positioned on the rear side are in transmission connection with a power shaft II.

According to the further optimization of the technical scheme, the protective clothing processing system comprises a cutting support column, two horizontal sliding blocks, a telescopic mechanism II, a friction bottom plate and cutting side edges, wherein the cutting support column is fixedly connected with the two horizontal sliding blocks which are respectively connected onto the two sliding supports in a sliding mode, a reset spring is fixedly connected between the cutting support column and the connecting support, the telescopic mechanism II is fixedly connected to two ends of the cutting support column, the friction bottom plate is fixedly connected to telescopic ends of the two telescopic mechanisms II, the two friction bottom plates are respectively in contact with the two friction belts, and the two cutting side edges are fixedly connected to the cutting support column.

As a further optimization of the technical scheme, the protective clothing processing system comprises two cutting mechanisms, two cutting gears, mounting cylinders, two telescopic mechanisms III, two adjusting bottom plates, a cutter base, locking screws and cutting cutters, wherein the two cutting rotating shafts are respectively and rotatably connected between the upper end and the lower end of two cutting side edges, the two mounting cylinders are respectively and fixedly connected to the two cutting rotating shafts, four telescopic mechanisms III are respectively and fixedly connected to each mounting cylinder, the adjusting bottom plate is fixedly connected to the telescopic end of each telescopic mechanism III, the cutter base is respectively and slidably connected to each adjusting bottom plate, the cutting cutters are respectively and fixedly connected to each cutter base, the locking screws are respectively connected to each cutter base through threads, the two cutting rotating shafts are in transmission connection, the cutting gears are fixedly connected to the cutting rotating shafts positioned on the upper side, the cutting gear is in meshed transmission with the rack.

As a further optimization of the technical scheme, the cutting tool is set to be different in shape.

The protective clothing processing system has the beneficial effects that:

according to the protective clothing processing system, the driving mechanism I can drive the material conveying mechanism to move at a constant speed, the driving mechanism II can be driven by the power mechanism to move at a variable speed, the driving mechanism II can drive the cutting support to move at a variable speed, the cutting support can drive the cutting mechanism to move at a variable speed, the distance between the cutting mechanism and the material on the material conveying mechanism is changed by utilizing the speed difference between the cutting mechanism and the material conveying mechanism, the relative position between the material on the cutting mechanism and the material on the material conveying mechanism is further changed, when the cutting mechanism performs cutting, the driving mechanism I and the driving mechanism II stop moving, and the cutting mechanism can rapidly perform cutting processing on different positions on two sides of the material.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view of the overall construction of the protective garment manufacturing system of the present invention;

FIG. 2 is a schematic view of the device support structure of the present invention;

FIG. 3 is a schematic structural diagram of a driving mechanism I of the present invention;

FIG. 4 is a schematic view of the material handling mechanism of the present invention;

FIG. 5 is a schematic diagram of a power mechanism according to the present invention;

FIG. 6 is a schematic structural diagram of a driving mechanism II of the present invention;

FIG. 7 is a schematic view of a cutting support of the present invention;

fig. 8 is a schematic view of the cutting mechanism of the present invention.

In the figure: a device holder 1; side brackets 101; a sliding bracket 102; a connecting bracket 103; a rack 104; a spring retainer 105; a driving mechanism I2; a drive shaft 201; a drive motor 202; a vertical slider 203; a driving wheel I204; a sliding support ring 205; a material conveying mechanism 3; a rotary barrel 301; a damping wheel 302; a sliding post 303; a tapered pinch wheel 304; a winding barrel 305; a backup roller 306; a power mechanism 4; a power motor 401; a missing tooth gear 402; a power shaft I403; a conical friction wheel I404; a power shaft II 405; a conical friction wheel II 406; a telescoping mechanism I407; pulling the clamping plate 408; a driving mechanism II 5; a drive bracket 501; a driving wheel II 502; a friction belt 503; cutting the stent 6; cutting the supporting column 601; a horizontal slider 602; a telescoping mechanism II 603; a friction backing 604; cutting the side edges 605; a cutting mechanism 7; cutting the rotating shaft 701; a cutting gear 702; mounting the barrel 703; a telescoping mechanism III 704; an adjustment backplane 705; a cutter base 706; a locking screw 707; a cutter 708 is cut.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 8, and a protective clothing processing system comprises a device support 1, a driving mechanism i 2, a material conveying mechanism 3, a power mechanism 4, a driving mechanism ii 5, a cutting support 6 and a cutting mechanism 7, wherein the driving mechanism i 2 is slidably connected to the front end of the device support 1, a compression spring i is fixedly connected between the driving mechanism i 2 and the device support 1, the material conveying mechanism 3 is connected to the device support 1, the driving mechanism i 2 is in contact with the material conveying mechanism 3, the power mechanism 4 is connected to the rear end of the device support 1, two driving mechanisms ii 5 are arranged, the two driving mechanisms ii 5 are respectively and fixedly connected to the left side and the right side of the device support 1, the two driving mechanisms ii 5 are in transmission connection with the power mechanism 4, the cutting support 6 is slidably connected to the device support 1, and a return spring is fixedly connected between the cutting support 6 and the, the cutting support 6 is connected with a cutting mechanism 7, the cutting support 6 is contacted with the driving mechanism II 5, and the cutting mechanism 7 is in meshing transmission with the device support 1; can carry out the motion of constant speed through actuating mechanism I2 drive fortune material mechanism 3, power unit 4 drives actuating mechanism II 5 and carries out the motion of variable speed, actuating mechanism II 5 drive cutting support 6 carries out the motion of variable speed, cutting support 6 drives cutting mechanism 7 and carries out the motion of variable speed, utilize the speed difference between cutting mechanism 7 and the fortune material mechanism 3 to change the distance between the cloth on cutting mechanism 7 and the fortune material mechanism 3, and then change the relative position between the cloth on cutting mechanism 7 and the fortune material mechanism 3, when cutting mechanism 7 cuts, actuating mechanism I2 and the equal stop motion of actuating mechanism II 5, and then cutting mechanism 7 can be fast to the different positions of cloth both sides cutting process.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1 to 8, and the present embodiment further describes the first embodiment, where the apparatus bracket 1 includes two side brackets 101, two sliding brackets 102, two connecting brackets 103, a rack 104, and a spring stop 105, the two side brackets 101 are provided, the sliding brackets 102 are fixedly connected to the two side brackets 101, the connecting bracket 103 is fixedly connected between the rear ends of the two sliding brackets 102, the rack 104 is fixedly connected to the connecting bracket 103, and the spring stop 105 is fixedly connected between the front ends of the two side brackets 101.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 8, and the second embodiment is further described in the present embodiment, where the driving mechanism i 2 includes a driving shaft 201, a driving motor 202, vertical sliders 203, a driving wheel i 204, and a sliding support ring 205, two ends of the driving shaft 201 are rotatably connected with the vertical sliders 203, the two vertical sliders 203 are respectively slidably connected to the front ends of the two side brackets 101, the driving motor 202 is fixedly connected to one of the vertical sliders 203, the driving wheel i 204 is fixedly connected to the driving shaft 201, the driving shaft 201 is fixedly connected to the output shaft of the driving motor 202, the sliding support ring 205 is rotatably connected to the driving shaft 201, the sliding support ring 205 is slidably connected to the spring baffle 105, and a compression spring i is fixedly connected between the spring baffle 105 and the sliding support ring 205; start driving motor 202 and power motor 401, driving motor 202's output shaft drives drive shaft 201 and rotates, drive shaft 201 drives drive wheel I204 and rotates, cloth on drive wheel I204 and the winding barrel 305 contacts, and then when drive wheel I204 rotates, the winding of drive wheel I204 drive cloth is on the winding barrel 305 who is located the front side, when the cloth that twines constantly becomes many on being located the front side winding barrel 305, drive wheel I204 receives the extrusion and moves downwards, compression spring I is extruded, but I204 pivoted linear velocity of drive wheel is unchangeable, and then winding barrel 305 pivoted linear velocity is unchangeable, the linear velocity that winding barrel 305 accomodates the cloth is unchangeable, the velocity of motion of cloth is invariable.

The fourth concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 8, and the present embodiment further describes an embodiment three, where the material transporting mechanism 3 includes a rotating cylinder 301, a damping wheel 302, a sliding column 303, a tapered clamping wheel 304, a material rolling cylinder 305, and a support roller 306, the damping wheel 302 is in contact with the rotating cylinder 301, the sliding column 303 is slidably connected to the rotating cylinder 301, the tapered clamping wheel 304 is fixedly connected to the sliding column 303, a compression spring ii is fixedly connected between the tapered clamping wheel 304 and the rotating cylinder 301, four rotating cylinders 301 are provided, the four rotating cylinders 301 are respectively rotatably connected to front and rear ends of the two side brackets 101, the four damping wheels 302 are respectively fixedly connected to front and rear ends of the two side brackets 101, two support rollers 306 are clamped between the four tapered clamping wheels 304, two support rollers 306 are provided, and both two support rollers 306 are rotatably connected between middle portions of the two side brackets 101; when the protective clothing fabric cutting device is used, protective clothing fabric to be processed is placed on the material conveying mechanism 3, one end of the fabric is wound on the material winding barrel 305 located on the rear side, the front end of the fabric is fixedly connected to the material winding barrel 305, as shown in fig. 4, a compression spring II is fixedly connected between the tapered clamping wheels 304 and the rotating barrel 301, the sliding column 303 is pulled to slide on the rotating barrel 301, the compression spring II is extruded, the material winding barrel 305 between the two corresponding tapered clamping wheels 304 can be replaced quickly, the lower end of the fabric penetrates through the two support rollers 306, the fabric is supported by the two support rollers 306, meanwhile, the damping wheel 302 provides certain damping when the rotating barrel 301 rotates, the rotating barrel 301 is placed to move due to cutting of the cutting mechanism 7 when the rotating barrel is not driven by power, and the cutting effect of the cutting mechanism 7 is further ensured.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1 to 8, where the power mechanism 4 includes a power motor 401, a tooth-missing gear 402, a power shaft i 403, a tapered friction wheel i 404, a power shaft ii 405, a tapered friction wheel ii 406, a telescoping mechanism i 407 and a pulling clamp 408, the tooth-missing gear 402 is fixedly connected to an output shaft of the power motor 401, the power motor 401 is fixedly connected to the side brackets 101 on one side, the power shaft i 403 is rotatably connected between the rear ends of the two side brackets 101, the tapered friction wheel i 404 is fixedly connected to the power shaft i 403, the power shaft i 403 and the tooth-missing gear 402 are in meshing transmission, the power shaft ii 405 is rotatably connected between the rear ends of the two side brackets 101, the tapered friction wheel ii 406 is fixedly connected to the power shaft ii 405, the tapers of the tapered friction wheel ii 406 and the tapered friction wheel i 404 are equal, the tapered friction wheel ii 406 and the tapered friction wheel i 404 are connected by a belt transmission, a pulling clamp plate 408 is fixedly connected to the telescopic end of the telescopic mechanism I407, the telescopic mechanism I407 is fixedly connected to the side support 101 on one side, a transmission belt between the conical friction wheel II 406 and the conical friction wheel I404 penetrates through the pulling clamp plate 408, and the rotating speed of the output shaft of the power motor 401 is the same as that of the output shaft of the driving motor 202; an output shaft of a power motor 401 drives a tooth-missing gear 402 to rotate, the tooth-missing gear 402 drives a power shaft I403 to rotate, the power shaft I403 drives a conical friction wheel I404 to rotate, the conical friction wheel I404 drives a conical friction wheel II 406 to rotate, the conical friction wheel II 406 drives a power shaft II 405 to rotate, the power shaft II 405 drives two driving wheels II 502 connected with the power shaft II to rotate, as shown in FIG. 1, when one telescopic mechanism III 704 moves to the lower end, the power motor 401 and the driving motor 202 are closed, the telescopic mechanism I407 and the telescopic mechanism III 704 are started, the telescopic mechanism I407, the telescopic mechanism II 603 and the telescopic mechanism III 704 can be hydraulic cylinders or electric push rods, or other mechanical mechanisms which can reciprocate and are commonly used in the field, when the telescopic end of the telescopic mechanism I407 moves, the telescopic end of the telescopic mechanism I407 drives a pulling clamp plate 408 to move, the drive belt between I404 and the II 406 of toper friction wheel of pulling splint 408 pulling toper friction wheel moves, and then change the drive ratio between I404 and the II 406 of toper friction wheel, make I404 drive toper friction wheel II 406 of toper friction wheel at every turn when rotating, II 406 pivoted number of turns of toper friction wheel are all inequality, and then II 406 drive II 502 pivoted number of turns of toper friction wheel at every turn is inequality, II 502 drive distance that drives the motion of cutting support 6 of drive wheel is different, and then after cutting at every turn, the moving speed of cutting support 6 and the cloth relative speed on the fortune material mechanism 3 all change.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1 to 8, and the fifth embodiment is further described in the present embodiment, where the driving mechanism ii 5 includes a driving bracket 501, two driving wheels ii 502 and a friction belt 503, the driving bracket 501 is rotatably connected with the two driving wheels ii 502, the two driving wheels ii 502 are in transmission connection with each other through the friction belt 503, the driving brackets 501 are fixedly connected to the outer sides of the two side brackets 101, and the two driving wheels ii 502 located at the rear side are in transmission connection with the power shaft ii 405.

The seventh embodiment:

the following describes the present embodiment with reference to fig. 1 to 8, and the sixth embodiment is further described, where the cutting support 6 includes a cutting support pillar 601, a horizontal slider 602, a telescopic mechanism ii 603, a friction bottom plate 604 and a cutting side 605, two horizontal sliders 602 are fixedly connected to the cutting support pillar 601, two horizontal sliders 602 are respectively slidably connected to two sliding supports 102, a return spring is fixedly connected between the cutting support pillar 601 and the connecting support 103, two ends of the cutting support pillar 601 are both fixedly connected to the telescopic mechanism ii 603, telescopic ends of two telescopic mechanisms ii 603 are both fixedly connected to the friction bottom plate 604, two friction bottom plates 604 are respectively in contact with two friction bands 503, and two cutting sides 605 are fixedly connected to the cutting support pillar.

The specific implementation mode is eight:

the following describes the present embodiment with reference to fig. 1 to 8, and the seventh embodiment is further described in the present embodiment, where the cutting mechanism 7 includes two cutting rotating shafts 701, two cutting gears 702, two mounting cylinders 703, four telescoping mechanisms iii 704, two adjusting bottom plates 705, two cutter bases 706, two locking screws 707, and two cutting rotating shafts 701, the two cutting rotating shafts 701 are respectively rotatably connected between the upper and lower ends of two cutting sides 605, the two cutting rotating shafts 701 are both fixedly connected with the two mounting cylinders 703, each mounting cylinder 703 is fixedly connected with four telescoping mechanisms iii 704, the telescopic end of each telescoping mechanism iii 704 is fixedly connected with the adjusting bottom plate 705, each adjusting bottom plate 705 is slidably connected with the cutter base 706, each cutter base 706 is fixedly connected with the cutting cutter 708, each cutter base 706 is connected with the locking screw 707 through a thread, the two cutting rotating shafts 701 are in transmission connection, a cutting gear 702 is fixedly connected to the cutting rotating shaft 701 on the upper side, and the cutting gear 702 is in meshing transmission with the rack 104.

The specific implementation method nine:

the present embodiment will be described with reference to fig. 1 to 8, and the eighth embodiment will be further described with reference to the present embodiment, in which the cutting blade 708 is provided in a different shape.

The invention relates to a protective clothing processing system, which has the working principle that:

when the protective clothing fabric is used, protective clothing fabric to be processed is placed on the material conveying mechanism 3, one end of the fabric is wound on the material winding barrel 305 located on the rear side, the front end of the fabric is fixedly connected to the material winding barrel 305, as shown in fig. 4, a compression spring II is fixedly connected between the conical clamping wheels 304 and the rotating barrel 301, the sliding column 303 is pulled to slide on the rotating barrel 301, the compression spring II is extruded, the material winding barrel 305 between the two corresponding conical clamping wheels 304 can be replaced quickly, the lower end of the fabric penetrates through the two support rollers 306, the fabric is supported by the two support rollers 306, meanwhile, the damping wheel 302 provides certain damping when the rotating barrel 301 rotates, and when the rotating barrel 301 is placed without being driven by power, the fabric moves due to cutting of the cutting mechanism 7, so that the cutting effect of the cutting mechanism 7 is ensured; the driving motor 202 and the power motor 401 are started, an output shaft of the driving motor 202 drives the driving shaft 201 to rotate, the driving shaft 201 drives the driving wheel I204 to rotate, the driving wheel I204 is in contact with the cloth on the material winding barrel 305, when the driving wheel I204 rotates, the driving wheel I204 drives the cloth to be wound on the material winding barrel 305 located on the front side, when the cloth wound on the material winding barrel 305 located on the front side continuously changes, the driving wheel I204 is extruded downwards to move, the compression spring I is extruded, but the linear speed of the driving wheel I204 is unchanged, so that the linear speed of the material winding barrel 305 is unchanged, the linear speed of the material winding barrel 305 for accommodating the cloth is unchanged, and the movement speed of the cloth is constant; an output shaft of a power motor 401 drives a tooth-missing gear 402 to rotate, the tooth-missing gear 402 and a power shaft I403 are in intermittent transmission, the tooth-missing gear 402 drives the power shaft I403 to rotate, the power shaft I403 drives a conical friction wheel I404 to rotate, the conical friction wheel I404 drives a conical friction wheel II 406 to rotate, the conical friction wheel II 406 drives a power shaft II 405 to rotate, and the power shaft II 405 drives two driving wheels II 502 connected with the power shaft II to rotate, as shown in FIG. 1, when a telescopic mechanism III 704 needing cutting moves to the lower end, the power motor 401 and the driving motor 202 are both closed, the telescopic mechanism I407 and the telescopic mechanism III 704 are started, the telescopic mechanism I407, the telescopic mechanism II 603 and the telescopic mechanism III 704 can be hydraulic cylinders or electric push rods, and can also be other mechanical mechanisms which can perform reciprocating motion commonly used in the technical field, when the telescopic end of the telescopic mechanism I407 moves, the telescopic end of the telescopic mechanism I407 drives the pulling clamp plate 408 to move, the pulling clamp plate 408 pulls the transmission belt between the conical friction wheel I404 and the conical friction wheel II 406 to move, and then the transmission ratio between the conical friction wheel I404 and the conical friction wheel II 406 is changed, so that when the conical friction wheel I404 drives the conical friction wheel II 406 to rotate each time, the rotating turns of the conical friction wheel II 406 are different, the rotating turns of the driving wheel II 502 driven by the conical friction wheel II 406 are different each time, the distances of the driving wheel II 502 driving the cutting bracket 6 to move are different, and further after each cutting, the moving speed of the cutting bracket 6 and the relative speed of the cloth on the material conveying mechanism 3 are changed; the driving wheel II 502 drives the friction belt 503 to move, the friction belt 503 drives the friction bottom plate 604 to move, the friction bottom plate 604 drives the telescopic mechanism II 603 to move, the telescopic mechanism II 603 drives the cutting support column 601 and the horizontal slider 602 to move, the reset spring is stretched, the cutting support 6 drives the cutting mechanism 7 to move forward, the driving motor 202 drives the cloth to move at a constant speed, the power motor 401 drives the cutting mechanism 7 to move at a variable speed, the cutting gear 702 is in meshing transmission with the rack 104, the rack 104 drives the cutting gear 702 to rotate, when the cutting mechanism 7 moves forward at a specified position, the telescopic mechanism III 704 moves to a cutting position, the power motor 401 and the driving motor 202 are both closed, as shown in FIG. 8, the telescopic end of the telescopic mechanism III 704 at the lower side moves upwards, and the telescopic mechanisms 704 III at the upper side and the lower side move, the telescopic end of the telescopic mechanism III 704 drives the adjusting bottom plate 705 to move, the adjusting bottom plate 705 drives the cutter base 706 to move, the cutter base 706 drives the cutting cutter 708 to move, the cutting cutters 708 on the upper side and the lower side are matched with each other to cut the cloth, meanwhile, the cutters which are cut by the cutting cutters 708 on the upper side and the lower side can be set to be different shapes, it needs to be noted that the cutters which are cut by the cutting cutters 708 on the upper side and the lower side are matched with each other to be set to be different shapes, so that the cutting mechanism 7 can cut two sides of the cloth to be different shapes, meanwhile, when the cutting mechanism 7 cuts, the telescopic mechanism I407 is started to adjust the transmission ratio between the conical friction wheel I404 and the conical friction wheel II 406 according to the use requirement, the time when the next telescopic mechanism III 704 moves to the cutting position is changed, the moving speed of the cloth is constant, and the distance from, however, the time changes, and the cutting position of the telescopic mechanism iii 704 on the cloth is adjusted by the change of the cloth movement distance corresponding to the changed time, as shown in fig. 8, when the cutting of the four telescopic mechanisms iii 704 on each mounting cylinder 703 is completed by one cycle, the telescopic mechanism ii 603 is started, the telescopic end of the telescopic mechanism ii 603 drives the friction bottom plate 604 to move upwards, so that the friction bottom plate 604 and the friction belt 503 are withdrawn from the friction transmission, and the reset spring drives the cutting support 6 and the cutting mechanism 7 to reset for the next cutting cycle, so that the periodic cutting of the shapes on the two sides of the cloth is circularly formed, and the patterns on the two sides of the cloth are periodically changed; the position of the cutter base 706 on the adjustment base 705 can be adjusted by the locking screw 707, and the position of the cutting cutter 708 can be adjusted to meet the requirements of dark turning and use.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (9)

1. The utility model provides a protective clothing system of processing, includes device support (1), actuating mechanism I (2), fortune material mechanism (3), power unit (4), actuating mechanism II (5), cutting support (6) and cutting mechanism (7), its characterized in that: the front end of the device support (1) is connected with a driving mechanism I (2) in a sliding manner, a compression spring I is fixedly connected between the driving mechanism I (2) and the device support (1), the device support (1) is connected with a material conveying mechanism (3), the driving mechanism I (2) is contacted with the material conveying mechanism (3), the rear end of the device support (1) is connected with a power mechanism (4), two driving mechanisms II (5) are arranged, the two driving mechanisms II (5) are respectively and fixedly connected to the left side and the right side of the device support (1), the two driving mechanisms II (5) are in transmission connection with the power mechanism (4), the device support (1) is connected with a cutting support (6) in a sliding manner, a reset spring is fixedly connected between the cutting support (6) and the device support (1), the cutting support (6) is connected with a cutting mechanism (7), and the cutting support (6) is contacted with the driving mechanism II (5), the cutting mechanism (7) is in meshing transmission with the device bracket (1).

2. The protective garment processing system of claim 1, wherein: the device support (1) comprises side supports (101), sliding supports (102), connecting supports (103), racks (104) and spring baffles (105), the number of the side supports (101) is two, the sliding supports (102) are fixedly connected to the two side supports (101), the connecting supports (103) are fixedly connected to the rear ends of the two sliding supports (102), the racks (104) are fixedly connected to the connecting supports (103), and the spring baffles (105) are fixedly connected to the front ends of the two side supports (101).

3. A protective garment processing system as claimed in claim 2, wherein: actuating mechanism I (2) is including drive shaft (201), driving motor (202), vertical slider (203), drive wheel I (204) and slip support ring (205), the both ends of drive shaft (201) are all rotated and are connected with vertical slider (203), two vertical slider (203) sliding connection respectively are at the front end of two collateral branch framves (101), driving motor (202) fixed connection is on one of them vertical slider (203), the last fixedly connected with drive wheel I (204) of drive shaft (201), the output shaft fixed connection of drive shaft (201) and driving motor (202), it is connected with slip support ring (205) to rotate on drive shaft (201), slip support ring (205) sliding connection is on spring baffle (105), fixedly connected with compression spring I between spring baffle (105) and slip support ring (205).

4. A protective garment processing system as claimed in claim 3, wherein: the material conveying mechanism (3) comprises a rotating cylinder (301), a damping wheel (302), a sliding column (303), a cone-shaped clamping wheel (304), a material rolling cylinder (305) and a support roller (306), the damping wheel (302) is contacted on the rotating cylinder (301), the sliding column (303) is connected in the rotating cylinder (301) in a sliding mode, the tapered clamping wheels (304) are fixedly connected on the sliding column (303), the compression springs II are fixedly connected between the tapered clamping wheels (304) and the rotating cylinder (301), the number of the rotating cylinders (301) is four, the four rotating cylinders (301) are respectively and rotatably connected to the front end and the rear end of the two side brackets (101), the four damping wheels (302) are respectively and fixedly connected to the front end and the rear end of the two side brackets (101), two supporting rollers (306) are clamped between the four tapered clamping wheels (304), the number of the supporting rollers (306) is two, and the two supporting rollers (306) are respectively and rotatably connected between the middles of the two side brackets (101).

5. The protective garment processing system according to claim 4, wherein: the power mechanism (4) comprises a power motor (401), a tooth-missing gear (402), a power shaft I (403), a conical friction wheel I (404), a power shaft II (405), a conical friction wheel II (406), a telescopic mechanism I (407) and a pulling clamp plate (408), the tooth-missing gear (402) is fixedly connected to an output shaft of the power motor (401), the power motor (401) is fixedly connected to the side brackets (101) on one side, the power shaft I (403) is rotatably connected between the rear ends of the two side brackets (101), the conical friction wheel I (404) is fixedly connected to the power shaft I (403), the power shaft I (403) and the tooth-missing gear (402) are in meshing transmission, the power shaft II (405) is rotatably connected between the rear ends of the two side brackets (101), the conical friction wheel II (406) is fixedly connected to the power shaft II (405), the conical friction wheel II (406) is equal to the conical friction wheel I (404), the conical friction wheel II (406) is in transmission connection with the conical friction wheel I (404) through a belt, the telescopic end of the telescopic mechanism I (407) is fixedly connected with a pulling clamp plate (408), the telescopic mechanism I (407) is fixedly connected to the side support (101) on one side, the transmission belt between the conical friction wheel II (406) and the conical friction wheel I (404) penetrates through the pulling clamp plate (408), and the rotating speed of the output shaft of the power motor (401) is the same as that of the output shaft of the driving motor (202).

6. The protective garment processing system according to claim 5, wherein: the driving mechanism II (5) comprises a driving support (501), two driving wheels II (502) and a friction belt (503), the driving support (501) is connected with two driving wheels II (502) in a rotating mode, the two driving wheels II (502) are connected through the friction belt (503) in a transmission mode, the outer sides of the two side supports (101) are fixedly connected with the driving support (501), and the two driving wheels II (502) located on the rear side are connected with the power shaft II (405) in a transmission mode.

7. The protective garment processing system of claim 6, wherein: cutting support (6) are including cutting support column (601), horizontal slider (602), telescopic machanism II (603), friction bottom plate (604) and cutting side (605), two horizontal slider (602) of fixedly connected with are gone up in cutting support column (601), two horizontal slider (602) sliding connection respectively are on two sliding support (102), fixedly connected with reset spring between cutting support column (601) and linking bridge (103), the equal fixedly connected with telescopic machanism II (603) in both ends of cutting support column (601), the equal fixedly connected with friction bottom plate (604) of the flexible end of two telescopic machanism II (603), two friction bottom plate (604) contact with two friction areas (503) respectively, two cutting side (605) of fixedly connected with on cutting support column (601).

8. The protective garment processing system according to claim 7, wherein: the cutting mechanism (7) comprises cutting rotating shafts (701), cutting gears (702), mounting cylinders (703), telescopic mechanisms III (704), an adjusting bottom plate (705), a cutter base (706), locking screws (707) and cutting cutters (708), two cutting rotating shafts (701) are arranged, the two cutting rotating shafts (701) are respectively and rotatably connected between the upper end and the lower end of two cutting side edges (605), two mounting cylinders (703) are respectively and fixedly connected on the two cutting rotating shafts (701), four telescopic mechanisms III (704) are respectively and fixedly connected on each mounting cylinder (703), the adjusting bottom plate (705) is respectively and fixedly connected on the telescopic end of each telescopic mechanism III (704), the cutter base (706) is respectively and slidably connected on each adjusting bottom plate (705), the cutting cutters (708) are respectively and fixedly connected on each cutter base (706), the locking screws (707) are respectively and threadedly connected on each cutter base (706), the two cutting rotating shafts (701) are in transmission connection, a cutting gear (702) is fixedly connected to the cutting rotating shaft (701) on the upper side, and the cutting gear (702) is in meshing transmission with the rack (104).

9. The protective garment processing system of claim 8, wherein: the cutting tools (708) are provided in different shapes.

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