CN218140492U - Continuous cotton feeding device - Google Patents

Abstract

The utility model relates to a rock wool composite sheet apparatus for producing, especially a continue continuous device, include and continue continuous frame and install continuous conveying mechanism in the continuous frame, continuous conveying mechanism is including the horizontal transport section and the slope transport section that link up each other, the slope transport section is arranged for horizontal plane slope, the horizontal transport section is close to relatively the one end of slope transport section and the slope transport section is close to relatively the one end of horizontal transport section all is provided with at least one and presses the material subassembly. Through setting up the slope and carrying the section and pressing the material subassembly, when the rock wool strip is carried from the horizontal transport section toward the slope, utilize and press the material subassembly to buckle the rock wool strip, guarantee that the rock wool strip is hugged closely all the time on continuing continuous cotton conveying mechanism, the output chronogenesis of the control rock wool strip of being convenient for, and then replace the manual work to lay the rock wool strip on various steel sheets, production efficiency is higher relatively.

Description

Continuous cotton device

Technical Field

The utility model relates to a rock wool composite sheet apparatus for producing, especially a continuous cotton device.

Background

The rock wool composite board, also called color steel composite board, color steel sandwich board or color steel rock wool composite board, is widely applied to various steel structure buildings because of its advantages of good fire resistance, strong heat preservation capability, high bearing capacity and flexible installation mode.

Rock wool composite sheet need lay the rock wool strip on the various steel sheet that has scribbled glue in process of production to with the rock wool strip centre gripping between two various steel sheets, at present, the above-mentioned process of laying rock wool strip relies on the manual work to accomplish totally, and production efficiency is lower relatively.

In view of the above, the present application has made an intensive study on the above problems, and has made this invention.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a production efficiency continuous device relatively higher.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a continuous cotton feeding device comprises a continuous cotton frame and a continuous cotton conveying mechanism arranged on the continuous cotton frame, wherein the continuous cotton conveying mechanism comprises a horizontal conveying section and an inclined conveying section which are connected with each other, the inclined conveying section is arranged obliquely relative to a horizontal plane, and at least one material pressing component is arranged at one end of the horizontal conveying section, which is relatively close to the inclined conveying section, and at one end of the inclined conveying section, which is relatively close to the horizontal conveying section;

the pressing assembly comprises a pressing support fixedly connected to the continuous feeding rack, two pressing cylinders fixedly connected to the pressing support respectively, and pressing rollers with two ends respectively connected to piston rods of the two pressing cylinders in a one-to-one rotating mode, pistons of the pressing cylinders are arranged downwards, and the pressing rollers are horizontally arranged and perpendicular to the conveying direction of the continuous feeding conveying mechanism.

As an improvement of the utility model, the continuous conveying mechanism is a belt conveying mechanism.

As an improvement of the utility model, the inclined conveying section is kept away from the one end of the horizontal conveying section is also provided with at least one material pressing component.

As an improvement of the utility model, continuous frame go up to rotate be connected with at least two respectively with nip rolls parallel arrangement and the unpowered conveying roller who arranges in proper order, each unpowered conveying roller form one jointly with the slope is carried the section and is kept away from the transition conveying section that the one end of horizontal transport section links up, continuous frame with the position department that the transition conveying section corresponds also is provided with press the material subassembly.

As an improvement of the present invention, the continuous feeding frame is located on one side of the transition conveying section away from the continuous feeding conveying mechanism, and at least one pressing assembly is further disposed on the one side of the transition conveying section away from the continuous feeding conveying mechanism.

As an improvement of the utility model, be located the slope is carried the section and is kept away from each of horizontal feeding section one side press the material subassembly to arrange in proper order and form and press the material combination in pressing the material combination, adjacent two press all to be provided with two direct or indirect fixed connection between the material subassembly and follow continuous frame and the guide cylinder of mutual disposition, each all fixedly connected with guide frame on the piston rod of guide cylinder, it is connected with at least one guide wheel to rotate on the guide frame.

As an improvement of the utility model, the both sides of slope conveying section width direction are provided with sliding connection respectively and are in spacing, two in the continuous frame spacing in one side in opposite directions all rotates and is connected with a plurality of edges the spacing wheel that the direction of delivery of slope conveying section arranged in proper order, still be provided with in the continuous frame be used for with spacing with continuous frame relatively fixed connection's retaining member.

By adopting the scheme, the utility model discloses following beneficial effect has:

through setting up the slope and carrying the section and pressing the material subassembly, when the rock wool strip was carried from the horizontal transport section toward the slope, utilize to press the material subassembly to bend the rock wool strip, guarantee that the rock wool strip is hugged closely all the time on continuing continuous cotton conveying mechanism, the output chronogenesis of the rock wool strip of being convenient for control, and then replace the manual work to lay the rock wool strip on various steel sheets, production efficiency is higher relatively.

Drawings

FIG. 1 is a schematic structural diagram of rock wool charging equipment in an embodiment;

FIG. 2 is a schematic structural view of a rock wool separating device in an embodiment;

FIG. 3 is a schematic view of another view of the rock wool separating device in the embodiment, in which some parts of the separating frame are omitted;

FIG. 4 is a schematic view of another perspective of the rock wool distribution device in an embodiment, in which a portion of the material pushing blocks is omitted;

FIG. 5 is a schematic structural view of a rock wool slitting and crossing device in an embodiment;

FIG. 6 is a schematic structural view of another view angle of the rock wool slitting and crossing device in the embodiment;

FIG. 7 is a schematic view of a continuous cotton feeding device in the embodiment.

The designations in the figures correspond to the following:

100-column; 110-a platform;

120-panel conveying means; 130-a material pressing component;

131-pressing support; 132-a material pressing cylinder;

133-nip rolls; 200-a feed delivery device;

210-a feeder frame; 220-a feed delivery mechanism;

230-a spacing roller; 300-rock wool powder device;

310-a material distributing frame; 320-layered feeding component;

321-a first transport roller;

323-the crane; 324-a lifting cylinder;

325-material blocking roller; 326 — a first belt transport mechanism;

327-pushing cylinder; 328-lifting handwheel;

329-a delivery scaffold; 330-differential delivery assembly;

331-a second belt conveying mechanism; 332-a third belt conveyor;

340-pushing frame; 341-beam;

342-a pushing roller; 350-leaning frame;

351-supporting beam; 352-abutment rollers;

353-a support seat; 354-a guide bar;

355-plate; 356-lead screw;

360-a steering conveyor assembly; 361-a second conveyor roller;

363-fixed length support;

364-chain conveying mechanism; 365-a material pushing block;

366-a connecting rod; 367-standing a plate;

368-telescopic cylinder; 400-rock wool slitting and crossing device;

410-a slitting machine frame; 420-a material receiving and conveying mechanism;

440-a support assembly;

441-a first support plate; 442-a second support plate;

443-straight cutting seam; 450-a cutting assembly;

451-cutting the bracket; 452-a slide;

453-a slip motor; 454-a feed cylinder;

455-cutting motor; 456-a cutter;

457-sliding rail; 458-rack;

460-a support roll;

500-cotton feeding device; 510-cotton feeding bracket;

520-cotton feeding and conveying mechanism; 521-a horizontal conveying section;

522-inclined conveying section; 523-a limiting frame;

524-limiting wheels; 530-unpowered conveying roller;

531-a material guide frame; 532-guide wheel;

533-material guide cylinder.

Detailed Description

The invention will be further described with reference to the accompanying drawings and specific embodiments.

As shown in fig. 1-7, this embodiment provides a rock wool charging apparatus, including stand 100 and platform 110 fixedly connected on stand 100, the below of platform 110 is provided with panel conveyor 120 of horizontal arrangement, and during the actual use, panel conveyor 120 links up with the conveyor on the present color steel rock wool board composite sheet production line, and perhaps, can also directly adopt a certain section of conveyor on the present color steel rock wool composite sheet production line as panel conveyor 120. It should be noted that, because the existing color steel rock wool composite board has two structural forms, namely a single-line type (for example, a metal surface color steel composite board production line adopting a single cold-bending forming mechanism disclosed in the chinese patent application with publication number CN 110170573A) and a double-line type (for example, a color steel composite board production line disclosed in the chinese patent application with publication number CN 109263241A), only one or two panel conveying devices 120 may be provided, in this embodiment, two panel conveying devices 120 are provided for illustration, and the two panel conveying devices 120 are arranged in parallel.

Be provided with the feeding conveyor 200 that links up in proper order, rock wool feed divider 300, rock wool on the platform 110 and cut cross arrangement 400 and continue cotton device 500, and platform 110 is provided with the rock wool storage area in the position department that lies in the feed end that is close to feeding conveyor 200 to deposit range upon range of rock wool strip temporarily, it is specific, range upon range of rock wool strip can transport the rock wool storage area through fork truck. In addition, the platform 110 is provided with a through hole at a position corresponding to the continuous cotton device 500.

The feeding conveyor 200 includes a feeding frame 210 and a feeding conveyor 220 mounted on the feeding frame 210 and horizontally arranged, wherein the feeding conveyor 220 is a mechanism adopted by a conventional roller conveyor or a belt conveyor, and will not be described in detail herein. The feeding frame 210 is rotatably connected with a plurality of limiting rollers 230 which are vertically arranged and are sequentially arranged along the conveying direction of the feeding conveying mechanism 220 at positions on two sides of the feeding conveying mechanism 220, so that the stacked rock wool strips can be prevented from collapsing in the conveying process, and meanwhile, because the limiting rollers 230 are rotatably connected, the friction (rolling friction) between the limiting rollers and the rock wool strips is relatively small, and the stacked rock wool strips are not easy to shift under the action of friction force. In use, the rock wool strips prevented from being stacked in the rock wool storage area are manually or by a stacking device (which is not part of this embodiment and needs to be additionally arranged in use) and the entire stack is transported to the feed end of the feed conveyor mechanism 220 so that the feed conveyor 200 feeds the entire stack of rock wool strips to the rock wool distribution device 300.

The rock wool feed divider 300 can adopt conventional devices, such as an electric gripper and the like, and the embodiment provides the rock wool feed divider 300 with relatively high efficiency, and the rock wool feed divider can also be independently applied to other equipment, namely, the embodiment substantially provides the rock wool feed divider.

The rock wool separating device 300 provided by this embodiment includes a separating frame 310, a layered feeding assembly 320, a differential conveying assembly 330 and a steering conveying assembly 360 which are sequentially arranged are arranged on the separating frame 310, wherein the layered feeding assembly 320 includes a plurality of first conveying rollers 321 which are parallel to each other and respectively rotatably connected to the separating frame 310, a first conveying motor (not shown in the figure) for driving each first conveying roller 321 to rotate, a lifting frame 323 vertically and slidably connected to the separating frame 310, and a lifting cylinder 324 for driving the lifting frame 323 to slide, wherein a specific transmission connection structure between the first conveying motor and each first conveying roller 321 is the same as a transmission connection structure between each conveying roller and a conveying motor in a conventional roller conveyor, for example, a chain assembly is used to realize transmission connection, and details are not described here. Each first conveying roller 321 is a horizontal straight line and arranges in proper order to form a first conveying section, the input of rock wool feed divider 300 is regarded as to the one end of first conveying section, link up with the output section of feeding conveyor mechanism 220, and first conveying section and feeding conveyor mechanism 220 are located same straight line, it is connected with vertical fender material roller 325 of arranging to rotate on the crane 323, keep off material roller 325 and be located the direction that its input was kept away from to first conveying section's one end, in order to avoid sending the rock wool that first conveying section was last to be exported from the one end that its input was kept away from to first conveying section.

The lifting frame 323 is fixedly connected with a plurality of conveying brackets 329 respectively positioned between two adjacent first conveying rollers 321, the conveying brackets 329 are arranged in parallel, in the embodiment, the conveying bracket 329 is arranged between two adjacent first conveying rollers 321, each conveying bracket 329 is provided with a first belt conveying mechanism 326, and the first belt conveying mechanisms 326 are also arranged in parallel. The first belt conveying mechanism 326 and each of the belt conveying mechanisms to be mentioned below are conventional structures and can be purchased directly from the market, and include two driven pulleys arranged in parallel and located on the same horizontal plane, a driving pulley located between the two driven pulleys and having a horizontal position lower than the horizontal position of the two driven pulleys, a synchronous belt wound between the driving pulley and each driven pulley and a driving motor for driving the driving pulley to rotate, the synchronous belt being located on the conveying surface of the belt segment type belt conveying mechanism between the two driven pulleys. It should be noted that each first belt conveyor 326 may share a single drive motor (i.e., drive pulleys are mounted on the same transmission shaft, and the transmission shaft is then connected to the drive motor), or a separate drive motor may be provided for each first belt conveyor 326.

The conveying surfaces of the first belt conveying mechanisms 326 are located on the same horizontal plane, and the conveying direction of each first belt conveying mechanism 326 is the same as the length direction of the first conveying roller 321, so that in use, each first belt conveying mechanism 326 can be driven by the lifting frame 323 to move according to actual needs, and the conveying surface is higher than or lower than the horizontal position of the first conveying section.

A pushing frame 340 and a leaning frame 350 which are arranged in parallel are arranged above the first conveying section, the pushing frame 340 and the leaning frame 350 are simultaneously arranged above only one first belt conveying mechanism 326, the length directions of the pushing frame 340 and the leaning frame 350 are the same as the conveying direction of the first conveying section, meanwhile, a pushing cylinder 327 for driving the pushing frame 340 to horizontally move along the length direction of the first conveying roller 321 and a lifting hand wheel 328 or a lifting motor for driving the leaning frame 350 to move up and down are arranged on the lifting frame 323, and the lifting hand wheel 328 is taken as an example in the embodiment for explanation. Preferably, the pushing frame 340 includes a cross beam 341 and a plurality of pushing rollers 342 rotatably connected to the cross beam 341 and vertically arranged, each pushing roller 342 is sequentially arranged along the length direction of the cross beam 341, and a piston rod of the pushing cylinder 327 is fixedly connected to the cross beam 341; the leaning frame 350 comprises a supporting beam 351 and a plurality of leaning rollers 352 which are rotatably connected to the supporting beam 351 and are vertically arranged, each leaning roller 352 is sequentially arranged along the length direction of the supporting beam 351, two ends of the supporting beam 351 are respectively and fixedly connected with a supporting seat 353, the structures of the two supporting seats 353 are the same, for example, a vertically arranged guide rod 354 is slidably connected to each supporting seat 353, the lower end of each guide rod 354 is fixedly connected to the lifting frame 323, the upper end of each guide rod is fixedly connected with a supporting plate 355, a vertically arranged lead screw 356 is rotatably connected to each supporting plate 355, a lead screw nut (not shown in the figure) fixedly connected to each supporting seat 353 is sleeved on each lead screw 356, a lifting hand wheel 328 or a lifting motor is in transmission connection with the lead screw 326, specific transmission connection structures can be conventional structures such as direct connection or connection through a coupling, and the like, so that the lifting hand wheel 328 or the lifting motor can drive the lead screw to rotate 326, and further drive the two supporting beams 351 to move up and down, before use, the height positions of the two supporting beams 351 are adjusted through the lifting hand wheel 328 or the lifting motor, after the conveying surface of the first belt conveying mechanism rises to the limiting position 326, the conveying surface, the distance between the conveying rock wool is larger than one supporting beam 351, and the thickness of one rock wool is smaller than that the rock wool can be smaller than that one rock wool can be conveyed. Since the abutment roller 352 and the pushing roller 342 are rotatably connected, the rock wool strips are not easily damaged.

The differential conveying device 330 includes a plurality of second belt conveying mechanisms 331 arranged alternately with the respective first belt conveying mechanisms 326, and a plurality of third belt conveying mechanisms 332 arranged alternately with the respective second belt conveying mechanisms 331, conveying surfaces of the respective second belt conveying mechanisms 331 and the respective third belt conveying mechanisms 332 being located on the same plane, and the respective second belt conveying mechanisms 331 being located between the respective first belt conveying mechanisms 326 and the respective third belt conveying mechanisms 332. The second belt feeding mechanisms 331 and the third belt feeding mechanisms 332 are arranged in parallel, and a straight line formed by the arrangement of the second belt feeding mechanisms 331 and the third belt feeding mechanisms 332 is arranged in parallel with a straight line formed by the arrangement of the first wind feeding mechanisms 326. During the use, third belt conveyor 332's transmission speed is greater than second belt conveyor 331's transmission speed, and specific velocity ratio can set up according to actual need, and the rock wool strip carries third belt conveyor 332's in-process from second belt conveyor 331 like this, and the clearance between two adjacent rock wool strips can be pulled open (specific clearance size depends on the velocity ratio), and then realizes the automation of rock wool strip and divide the strip.

The turning and conveying device 360 includes a plurality of second conveying rollers 361 parallel to each other and rotatably connected to the material separating rack 310, and a second conveying motor (not shown in the figure) for driving each second conveying roller 361 to rotate, wherein a specific transmission connection structure between the second conveying motor and each second conveying roller 361 is the same as a transmission connection structure between each conveying roller and each conveying motor in a conventional roller conveyor, for example, a chain assembly is used for realizing transmission connection, and the like, and details thereof are not described herein. Each second conveying roller 361 is a horizontal straight line and arranges in proper order to form the second conveying section, and the direction of delivery of second conveying section is arranged perpendicularly with third belt conveyor 332's direction of delivery, and the conveying face of second conveying section is less than third belt conveyor 332's conveying face with third belt conveyor 332's conveying face parallel and level or the conveying face of second conveying section to guarantee that the rock wool strip can be carried smoothly.

The material distributing frame 310 is provided with a plurality of fixed-length supports 363 respectively located between two adjacent second conveying rollers 361, each fixed-length support 363 is provided with a chain conveying mechanism 364, each chain conveying mechanism 364 is a conventional mechanism and can be directly purchased and obtained from the market, the chain conveying mechanism comprises a driving sprocket, a driven sprocket, a chain wound between the driving sprocket and the driven sprocket and a motor (not shown in the figure) for driving the driving sprocket to rotate, and similar to the belt conveying mechanism, each chain conveying mechanism 364 can be respectively provided with one motor and can also share one motor. Each chain conveying mechanism 364 is located on the side of each third belt conveying mechanism 332 far away from the second belt conveying mechanism 331, each chain conveying mechanism 364 and each third belt conveying mechanism 331 are arranged in a staggered manner, each chain conveying mechanism 364 is arranged in parallel, and the straight line formed by the arrangement of each chain conveying mechanism 364 is arranged in parallel with the straight line formed by the arrangement of each third belt conveying mechanism 332. The conveying surface of each chain conveying mechanism 364 is lower than the conveying surface of the second conveying section, and a plurality of pushing blocks 365 are arranged on the chain of each chain conveying mechanism 364 at equal intervals. The conveying surfaces of the chain conveying mechanisms 164 are preferably located on the same horizontal plane, but may not be located on the same horizontal plane, as long as the upper end of the pusher 365 is higher than the second conveying section when the pusher 365 moves to the position corresponding to the second conveying section.

Preferably, the material separating frame 310 is fixedly connected with two connecting rods 366 which are respectively arranged in parallel with the second conveying rollers 361 at positions below the second conveying rollers 361, and the connecting rods 366 are positioned at one side of each fixed-length support 363 facing the conveying direction of the second conveying section. The same plurality of vertical plates 367 arranged perpendicular to the second conveying roller 361 are slidably connected to the two connecting rods 366, that is, the plurality of vertical plates 367 are simultaneously slidably connected to the two connecting rods 366, so that the vertical plates 367 can be prevented from rotating relative to the connecting rods 366. Each vertical plate 367 is provided with an execution part which penetrates out of the space between two adjacent second conveying rollers 361 to the position above the second conveying section, a telescopic cylinder 368 is connected between two adjacent vertical plates 367, specifically, the telescopic cylinder 368 between two adjacent vertical plates 367 is fixedly connected onto one vertical plate 367, and a cylinder body of the telescopic cylinder 368 is fixedly connected onto the other vertical plate 367, so that the vertical plates 367 can be controlled to slide relative to the connecting rod 366 through the action of the piston rod of the telescopic cylinder 368, and the position of the rock wool strips on the second conveying belt can be adjusted through the execution part, so that the rock wool strips can be laid on the color steel plate in the subsequent process.

A pressing assembly 130 is arranged above the second conveying section at a position between each vertical plate 367 and each chain conveying mechanism 364, the pressing assembly 130 comprises a pressing support 131 fixedly connected to the material separating rack 310, two pressing cylinders 132 respectively fixedly connected to the pressing support 131, and pressing rollers 133 with two ends respectively rotatably connected to piston rods of the two pressing cylinders 132 in a one-to-one manner, wherein pistons of the pressing cylinders 132 are arranged downward, and the pressing rollers 133 are horizontally arranged and are perpendicular to the conveying direction of the second conveying section.

When the rock wool strip stacking machine is used, after the conveying device 200 conveys a whole stack of rock wool strips to the first conveying section, the lifting frame 323 moves upwards to enable the conveying surface of each first belt conveying mechanism 326 to move upwards and jack up the rock wool strips on the first conveying section upwards, then the whole stack of rock wool strips are tightly pressed on the leaning frame 350 by the movement of the pushing frame 340 to ensure that the rock wool strips are stacked orderly, then the first belt conveying mechanism 326 is used for conveying the rock wool strips to the second belt conveying mechanism 331 from bottom to top in sequence, and then the conveying intervals of the rock wool strips are pulled by the speed difference existing in the process of conveying the rock wool strips from the second belt conveying mechanism 331 to the third belt conveying mechanism 332, so that when the rock wool strips are conveyed to the chain conveying mechanism 365, only one rock wool strip 364 is arranged between two adjacent pushing blocks 364 on the same chain conveying mechanism; when the chain conveying mechanism 364 works, the pressure roll 133 of the pressure component 130 on the second conveying section moves downwards to prevent the rock wool strips from moving under the drive of the second conveying section, after all the rock wool strips with preset number are driven by the chain conveying mechanism 364 to move onto the second conveying belt, the chain conveying mechanism 364 stops moving, meanwhile, the pressure component 130 on the second conveying section resets, and each telescopic cylinder 368 pushes each vertical plate 367 to move to a preset position, so as to ensure that each rock wool strip is arranged corresponding to a channel formed by two adjacent vertical plates 367; and then the second conveying section drives the rock wool strips to move to the positions corresponding to the vertical plates 367, at the moment, the telescopic cylinders 368 act again to push the rock wool strips to be arranged according to the required laying distance, and the rock wool strips in the arrangement number are conveyed to the rock wool slitting and crossing device 400 under the driving of the second conveying section.

The rock wool slitting and crossing device 400 can adopt a conventional device, for example, two mechanical arms are arranged, a cutting mechanism is arranged at the tail end of one mechanical arm, a gripping mechanism is arranged at the tail end of the other mechanical arm, and the like.

The rock wool slitting and crossing device 400 provided by the embodiment comprises a slitting frame 410, a material receiving and conveying mechanism 420 and a material discharging and conveying mechanism which are arranged in the slitting frame 410 in a straight line in sequence, a supporting assembly 440 positioned between the material receiving and conveying mechanism 420 and the material discharging and conveying mechanism, and a cutting assembly 450 positioned above the supporting assembly 440, wherein the material receiving and conveying mechanism 420 and the material discharging and conveying mechanism are conventional belt conveying mechanisms and can be directly purchased from the market, and the material receiving and conveying mechanism 420 and the material discharging and conveying mechanism are arranged in a straight line in sequence.

The supporting assembly 440 includes a first supporting plate 441 and a second supporting plate 442 located on the same horizontal plane as the conveying surfaces of the material receiving conveying mechanism 420 and the material discharging conveying mechanism, a straight slit 443 is formed between the first supporting plate 441 and the second supporting plate 442, and an acute angle is formed between the straight slit 443 and the conveying direction of the material receiving conveying mechanism 420 or the material discharging conveying mechanism, that is, the straight slit 443 is obliquely arranged, and the specific inclination angle needs to be set according to the actual conveying speed of the material receiving conveying mechanism 420. The cutting assembly 450 comprises a cutting support 451 fixedly connected to the cutting frame 410, a slide seat 452 horizontally slidably connected to the cutting support 451, a sliding motor 453 for driving the slide seat 452 to slide, a feeding cylinder 454 fixedly connected to the slide seat 452 and with a piston rod arranged vertically downwards, a cutting motor 455 fixedly connected to a piston rod of the feeding cylinder 454, and a cutter 456 fixedly connected to an output shaft of the cutting motor 455, wherein the specific connection structure between the slide seat 452, the cutting support 451, and the sliding motor 453 may be a conventional structure, in this embodiment, a slide rail 457 and a rack 458 arranged in parallel to each other are fixedly connected to the cutting support 451, the slide seat 452 is indirectly slidably connected to the cutting support 451 through a sliding connection, a housing of the sliding motor 453 is fixedly connected to the slide seat 152, and a gear (not shown) meshed with the rack 458 is fixedly connected to an output shaft of the sliding motor 453. In addition, the sliding direction of the sliding base 452 is the same as the length direction of the straight cutting slot 443, and the cutting knife 456 and the straight cutting slot 443 are located on the same vertical plane, so that the cutting knife 456 can penetrate into the straight cutting slot 443 to avoid touching the supporting component 440 during cutting. When the cutting device is used, the feeding cylinder 454 drives the cutting motor 455 with the cutting knife 456 to move downwards, so that the cutting knife is inserted into the straight cutting slot 443, meanwhile, the cutting motor 455 drives the cutting knife 456 to rotate, then the sliding motor 453 drives the sliding seat 452 to move, and further, the cutting knife 456 moves in the straight cutting slot, and cutting is achieved.

A pressing assembly 130 is arranged above the material receiving and conveying mechanism 420, a pressing bracket 313 of the pressing assembly 130 is fixedly connected to the slitting rack 410, and a pressing roller 133 is horizontally arranged and is perpendicular to the conveying direction of the material receiving and conveying mechanism 420.

Preferably, in this embodiment, the slitting machine frame 410 is rotatably connected with supporting rollers 460 at positions between the receiving and conveying mechanism 420 and the supporting assembly 440 and between the supporting assembly 440 and the discharging and conveying mechanism, so as to better support the rock wool strips, which are clamped on the supporting assembly 440 during conveying.

When the device is used, the rock wool strips are conveyed to the material receiving and conveying mechanism 420 under the driving of the second conveying section, at the moment, if the production process needs to arrange the rock wool strips on the color steel plate in a crossed manner, when the rock wool strips are conveyed to the material receiving and conveying mechanism 420 for the first time, the material pressing roller 133 of the material pressing assembly 130 is used for moving downwards to prevent the rock wool strips from being conveyed on the material receiving and conveying mechanism 420 continuously, then, part of the rock wool strips are manually cut short, so that the length of each rock wool strip conveyed to the material receiving and conveying mechanism 420 for the first time is sequentially and alternately arranged, one end of each rock wool strip, facing the conveying direction of the material receiving and conveying mechanism 420, is arranged in a flush manner, and the other end of each rock wool strip is arranged at intervals; then, the next batch of rock wool strips are conveyed to the material receiving and conveying mechanism 420 through the second conveying section, part of rock wool strips in the rock wool strips conveyed to the material receiving and conveying mechanism 420 in the later process can firstly abut against the end parts of the rock wool strips with relatively longer length in the rock wool strips conveyed to the material receiving and conveying mechanism 420 in the previous batch (namely the end parts of the rock wool strips which are not manually cut short), and the other part of rock wool strips can continue to move under the pushing of the second conveying section until the rock wool strips abut against the end parts of the rock wool strips which are cut short, so that the cross arrangement of the rock wool strips is realized; then, the pressing assembly 130 is reset, so that the rock wool strips which are arranged in a cross manner are driven by the material receiving and conveying mechanism 420 to be conveyed to the material discharging and conveying mechanism through the supporting assembly 440, meanwhile, the cutting assembly 450 is used for cutting the rock wool strips which are arranged in a cross manner according to the preset length, and in the cutting process, the rock wool strips are not stopped to be conveyed, namely, the rock wool strips are cut while being conveyed, and during cutting, the cutter 456 moves from one end of the straight cutting seam 443, which is relatively far away from the material receiving and conveying mechanism 420, to the other end, and therefore, the production efficiency is improved.

The continuous cotton feeding device 500 comprises a continuous cotton feeding rack 510 and a continuous cotton conveying mechanism 520 installed on the continuous cotton feeding rack 510, and the continuous cotton feeding device 500 can also be independently used in cooperation with a color steel composite board production line, so that the embodiment substantially provides a continuous cotton feeding device.

The continuous cotton conveying mechanism 520 is located right above the panel conveying device 120 and located on the same vertical plane with the panel conveying device 120, the input end of the continuous cotton conveying mechanism 520 is connected with the output end of the discharge conveying mechanism of the rock wool slitting and crossing device 400, the output end of the continuous cotton conveying mechanism 520 penetrates through the through hole in the platform 110 and is close to the conveying plane of the panel conveying device 120, and the gap between the two is slightly larger than the thickness of the color steel rock wool composite board to be produced. Specifically, the continuous cotton conveying mechanism 520 is a belt conveying mechanism, which includes a horizontal conveying section 521 and an inclined conveying section 522 connected to each other, wherein the inclined conveying section 522 may be composed of one conventional belt conveyor or a plurality of conventional belt conveyors connected to each other, and the inclined conveying section 522 is arranged obliquely with respect to the horizontal plane. It should be noted that the horizontal conveying section 521 and the discharging conveying mechanism may be two mechanisms that are independent from each other and are connected to each other, or the discharging conveying mechanism may be directly used as the horizontal conveying section 521, or the horizontal conveying section 521 is used as the discharging conveying mechanism, in this embodiment, the horizontal conveying section 521 is used as the discharging conveying mechanism for example, the continuous cotton support 510 and the slitting support 410 are fixedly connected to each other, and some parts (such as a support plate or a support rod) of the continuous cotton support 510 and the slitting support 410 may be integrally connected (i.e., share the same part).

At least one pressing assembly 130 is disposed at one end of the horizontal conveying section 521 relatively close to the inclined conveying section 522 and at one end of the inclined conveying section 522 relatively close to the horizontal conveying section 521, and at least one pressing assembly 130 is disposed at one end of the inclined conveying section 522 far away from the horizontal conveying section 521. Note that, in the present embodiment, "one end" does not only refer to the end portion, but also includes a position near the end portion. The pressing supports 313 of the pressing assemblies 130 in the continuous feeding mechanism 520 are all fixedly connected to the continuous feeding frame 510, and the pressing rollers 133 are arranged horizontally and vertically to the feeding direction of the continuous feeding mechanism 520. It should be noted that, although the structures of the pressing assemblies 130 in the continuous feeding and conveying mechanism 520 are the same as the structures of the pressing assemblies 130 at other positions, the usage manner is different, and the pressing assemblies 130 in the continuous feeding and conveying mechanism 520 do not block the conveying of the rock wool strips, but ensure that the rock wool strips are tightly attached to the conveying surface of the continuous feeding and conveying mechanism 520 to avoid the rock wool strips from tilting, specifically, when the rock wool strips are conveyed from the horizontal conveying section 521 to the inclined conveying section 522 or conveyed from the cleaning conveying section 522 to the panel conveying device 120, the rock wool strips are tightly pressed on the corresponding conveying surface by the corresponding pressing assemblies 130 to avoid the rock wool strips from tilting.

Preferably, the continuous cotton feeding frame 510 is rotatably connected with at least two unpowered conveying rollers 530 which are respectively arranged in parallel and in sequence with the pressure rollers 133 of the pressure components 130 in the continuous cotton feeding mechanism 520, each unpowered conveying roller 530 is arranged in sequence and jointly forms a transition conveying section connected with one end of the inclined conveying section 520 far away from the horizontal conveying section 510, and meanwhile, the continuous cotton feeding frame 510 is also provided with the pressure components 130 at the position corresponding to the transition conveying section, which is helpful for improving the smoothness when the rock wool strips are conveyed to the panel conveying device 120 from the inclined conveying section 520, ensuring that the rock wool strips are stably placed on the color steel plate on the panel conveying device 120, and improving the conveying stability and reliability.

Preferably, at least one pressing assembly 130 is further disposed on the continuous feeding frame 510 at a side of the transitional conveying section away from the continuous feeding conveying mechanism 520, the pressing brackets 313 of the pressing assemblies 130 are all fixedly connected to the frame of the panel conveying device 120, the pressing rollers 133 are horizontally disposed and perpendicular to the conveying direction of the panel conveying device 120, and when in use, the pressing rollers 133 ensure that the rock wool bars are tightly attached to the conveying surface of the panel conveying device 120, thereby further improving the conveying stability and reliability.

The material pressing assemblies 130 on one side, far away from the horizontal conveying section 521, of the inclined conveying section 522 are sequentially arranged to form a material pressing combination, in the material pressing combination, two material guiding cylinders 533 which are directly or indirectly fixedly connected to the continuous cotton frame 510 and are oppositely arranged are arranged between two adjacent material pressing assemblies 130, the two material guiding cylinders 533 which are oppositely arranged are respectively located on two sides of the width direction of the inclined conveying section 522, a material guiding frame 531 is fixedly connected to a piston rod of each material guiding cylinder 533, and at least one material guiding wheel 532 is rotatably connected to the material guiding frame 531, so that the corresponding material guiding wheels 532 can be driven to move by the telescopic action of the material guiding cylinders 533, and then the position of the rock wool strips output from the continuous cotton device 500 is finely adjusted, and the rock wool strips are ensured to accurately fall onto the color steel plate located on the panel conveying device 120.

In addition, two sides of the oblique conveying section 522 in the width direction are respectively provided with a limiting frame 523 slidably connected to the continuous cotton frame 510, one opposite side of the two limiting frames 523 is rotatably connected with a plurality of limiting wheels 524 sequentially arranged along the conveying direction of the oblique conveying section 522, and the continuous cotton frame 510 is further provided with a locking member (not shown in the figure) for relatively fixedly connecting the limiting frame 523 and the continuous cotton frame 510, in this embodiment, the locking member is a locking bolt. The rock wool strips can be guided by the limiting wheels 524, and the position of the limiting frame 523 can be adjusted by loosening the locking bolts.

During the use, the rock wool strip is carried continuous cotton conveying mechanism 520 from ejection of compact conveying mechanism, then carries on the various steel sheet that is located panel conveyor 120 through continuous cotton conveying mechanism 520 on, realizes the automatic feeding of rock wool strip.

The present invention has been described in detail with reference to the accompanying drawings, but the embodiments of the present invention are not limited to the above embodiments, and those skilled in the art can make various changes and applications to the present invention according to the prior art, which all belong to the protection scope of the present invention.

Claims (7)

1. A continuous cotton feeding device is characterized by comprising a continuous cotton frame and a continuous cotton conveying mechanism arranged on the continuous cotton frame, wherein the continuous cotton conveying mechanism comprises a horizontal conveying section and an inclined conveying section which are connected with each other, the inclined conveying section is arranged obliquely relative to a horizontal plane, and at least one material pressing component is arranged at one end of the horizontal conveying section, which is relatively close to the inclined conveying section, and at one end of the inclined conveying section, which is relatively close to the horizontal conveying section;

the pressing assembly comprises a pressing support fixedly connected to the continuous cotton feeding rack, two pressing cylinders fixedly connected to the pressing support respectively, and pressing rollers with two ends respectively rotatably connected to piston rods of the two pressing cylinders in a one-to-one manner, pistons of the pressing cylinders are arranged downwards, and the pressing rollers are horizontally arranged and are perpendicular to the conveying direction of the continuous cotton feeding mechanism.

2. The continuous web feeding device according to claim 1, wherein said continuous web conveying means is a belt conveying means.

3. The continuous web feeding device according to claim 1, wherein an end of the inclined conveying section away from the horizontal conveying section is also provided with at least one of the nip assemblies.

4. The continuous feeding device according to claim 3, wherein at least two unpowered conveying rollers are rotatably connected to the continuous feeding frame, the at least two unpowered conveying rollers are respectively arranged in parallel with the nip rollers and are sequentially arranged, each unpowered conveying roller jointly forms a transitional conveying section connected with one end of the inclined conveying section away from the horizontal conveying section, and the continuous feeding frame is also provided with the nip assembly at a position corresponding to the transitional conveying section.

5. The continuous feeding device of claim 4, wherein the continuous feeding frame is further provided with at least one pressing assembly at a side of the transitional conveying section away from the continuous feeding conveying mechanism.

6. The continuous feeding device according to claim 3, wherein the pressing assemblies located on one side of the inclined conveying section away from the horizontal conveying section are sequentially arranged to form a pressing combination, two material guiding cylinders which are directly or indirectly fixedly connected to the continuous feeding frame and are oppositely arranged are arranged between two adjacent pressing assemblies in the pressing combination, a material guiding frame is fixedly connected to a piston rod of each material guiding cylinder, and at least one material guiding wheel is rotatably connected to the material guiding frame.

7. The continuous cotton feeding device according to any one of claims 1 to 6, wherein two sides of the inclined conveying section in the width direction are respectively provided with a limiting frame slidably connected to the continuous cotton frame, one opposite side of the two limiting frames is rotatably connected with a plurality of limiting wheels which are sequentially arranged along the conveying direction of the inclined conveying section, and the continuous cotton frame is further provided with a locking member for relatively fixedly connecting the limiting frame and the continuous cotton frame.

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