CN211197580U - Conveying device for conveying EPS foam lines - Google Patents

Abstract

The utility model discloses a conveyor for EPS foam lines conveying, including the lines that adopt EPS foam material and the first conveyer belt that is used for conveying the lines, a plurality of screws are installed along its girth direction to first conveyer belt, and the screw includes screw cap and nail pole, and the screw is packed into and is followed the nail pole and upwards pierce through first conveyer belt from the inner wall of first conveyer belt, and nail pole part exposes at the outer wall of first conveyer belt, and the lines laminating is in the outer wall of first conveyer belt and expose the nail pole of first conveyer belt outer wall pricks the lines from the inner wall of lines. The utility model discloses do not influence the pleasing to the eye and the wholeness ability of lines, realize the reliable stable conveying of lines.

Description

Conveying device for conveying EPS foam lines

Technical Field

The utility model belongs to the technical field of conveyor technique and specifically relates to a conveyor that is used for EPS foam lines conveying is related to.

Background

The EPS decorative line can prevent fire and does not emit toxic substances, and is an environment-friendly high-quality decorative building material product. The novel outer wall decoration line and the novel outer wall decoration component are more suitable for installation, can embody European classical and elegant decoration styles on heat-insulating walls of outer walls EPS and XPS, and can ensure that the outer wall of a main building does not have cold and heat bridge effects. Has the advantages of convenient installation, economy, long durability and the like.

The bottom surface of current EPS foam lines is used for the installation, and the outer wall of EPS foam lines will cover a layer of net earlier, then scribbles the mortar in the outside of net, and the orbit that easily deviates in EPS foam lines at the transfer process needs to install specific guiding mechanism, because the specification of EPS foam lines is various, and the width is different, therefore guiding mechanism need adjustable talent go, and overall cost is great, and adaptability is relatively poor, remains to be improved.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome above-mentioned prior art not enough, provide a conveyor for EPS foam lines conveying, do not influence pleasing to the eye and the wholeness ability of lines, realize the reliable conveying of stabilizing of lines.

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

the utility model provides a conveyor for EPS foam lines conveying, includes the lines that adopt EPS foam material and the first conveyer belt that is used for conveying the lines, a plurality of screws are installed along its girth direction to first conveyer belt, the screw includes screw cap and nail pole, and the screw is packed into and is followed the nail pole and upwards pierce through first conveyer belt from the inner wall of first conveyer belt, nail pole part exposes the outer wall at first conveyer belt, the lines laminating is in the outer wall of first conveyer belt and expose in the nail pole of first conveyer belt outer wall pricks into the lines from the inner wall of lines.

The first conveyor belt is provided with a first conveyor belt counter bore, the first conveyor belt counter bore comprises a large-diameter hole penetrating through the inner wall of the first conveyor belt and a small-diameter hole penetrating through the outer wall of the first conveyor belt, the diameter of the large-diameter hole is larger than that of the small-diameter hole, the screw cap is located in the large-diameter hole, and the screw rod portion is located in the small-diameter hole.

The small-diameter hole is provided with an internal thread, and the nail rod is provided with an external thread matched with the internal thread.

The screws comprise a first screw and a second screw, the first screw and the second screw are distributed at equal intervals along the circumferential direction of the first conveyor belt, and the second screw is located on two sides of the first screw.

The first screws are located in the middle of the first conveyor belt in the width direction, the second screws are arranged in two rows, and the two rows of second screws are located on two sides of the first screws respectively.

The vertical distance from each row of second screws to the first screws is n, the distance between every two adjacent first screws is 2n, and the distance m between every two second screws opposite to each other in the width direction of the first conveyor belt is 4 cm.

The first conveyor belt is wrapped on the peripheries of the two conveyor belt wheels.

The top end of the lines is connected with a rotatable pinch roller in an abutting mode.

The utility model has the advantages that: the attractiveness and the overall performance of the line are not influenced; the lines are nailed through the screws, and the lines are reliably and stably conveyed on the premise of not needing a guide mechanism; the screw does not interfere with the transmission pulley.

Drawings

Fig. 1 is a perspective view of the line covering and coating integrated production line of the utility model;

FIG. 2 is an enlarged view taken at A in FIG. 1;

FIG. 3 is an enlarged view at B of FIG. 1;

FIG. 4 is an enlarged view at C of FIG. 1;

fig. 5 is a perspective view of the wire feeding device of the line-covering and coating integrated production line of the present invention;

fig. 6 is a perspective view of a template of the line-screening and coating integrated production line of the present invention;

fig. 7 is a perspective view of the curling device and the cutting device of the line-covering and coating integrated production line of the present invention;

fig. 8 is a schematic structural view of a curling device of the line-screening and coating integrated production line of the present invention;

fig. 9 is an exploded view of the coating mechanism of the line-screening and coating integrated production line of the present invention;

fig. 10 is a perspective view of a support of the line-screening and coating integrated production line of the present invention;

fig. 11 is a spliced three-dimensional view between the lines of the line-covering and coating integrated production line of the present invention;

fig. 12 is a schematic structural view of the present invention;

FIG. 13 is an enlarged view at D of FIG. 12;

fig. 14 is a schematic top view of the present invention.

In the figure: the template comprises a template 1, a template notch 11, a template internal scraping part 12, a template mounting hole 13, a template connecting strip 14, a template connecting strip through hole 15, a coating mechanism 2, a coating frame 21, a feed inlet 22, a coating plate 23, a coating plate notch 24, a coating plate internal scraping part 25, a coating bin mounting seat 26, a line 3, a net 31, a net edge folding part 32, a coating layer 33, a line spacer block 34, a line first outer wall 35, a line second outer wall 36, a net feeding device 4, a net releasing roller 41, a first net feeding roller 42, a second net feeding roller 43, a net feeding roller motor 44, a net feeding compression roller 45, a net feeding compression roller motor 46, a net feeding compression roller mounting rod 47, a sliding bearing 48, a net feeding compression roller motor lead screw 49, a cutting device 5, a walking motor 51, a walking lead screw 52, a walking seat 53, a cutting motor 54, a cutting motor lead screw 55, an electric saw 56, a cutting device sliding rail 57, a cutting device base 58, a protective cover 59, a protective, The device comprises a frame 6, a frame waist-shaped hole 61, an electric cabinet 62, a sensing device 63, a hemming front baffle mechanism 7, a hemming mechanism 71, a hemming front baffle shaft 72, a front baffle cylinder bearing 73, a hemming front baffle cylinder 74, a hemming cylinder shaft 75, a hemming cylinder bearing 76, a hemming cylinder 77, a hemming cylinder flanging 78, a support cross rod 8, a connecting block 81, a support vertical plate 82, a support vertical plate waist-shaped hole 83, a connecting block screw hole 84, a pressing wheel 85, a first conveyor belt motor 9, a first conveyor belt 91, a first conveyor belt front roller 92, a conveying guide strip 93, a second conveyor belt motor 94, a second conveyor belt 95, a third conveyor belt 96, a screw 97, a first conveyor belt counter bore 98, a screw cap 99, a screw rod 910, a conveyor belt wheel, a first screw 912 and a second screw 913.

Detailed Description

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

as shown in fig. 1 to 14, a conveyor for EPS foam strand transfer is mounted on a frame 6, and includes a strand 3 made of EPS foam and a first conveyor belt 91 for conveying the strand 3, wherein the strand 3 is formed by stretching a cross section in a direction perpendicular to the cross section, that is, the cross section at any position along the length direction of the strand 3 is the same.

The first conveyor belt 91 is driven by a first conveyor belt motor 9, and the first conveyor belt 91 is wrapped on the peripheries of the two conveyor belt wheels 911. Specifically, one of the two conveyor pulleys 911 is a driving wheel, and the other is a driven wheel, and the driving wheel is driven to rotate by the first conveyor motor 9.

First conveyer belt 91 is located on frame 6, a plurality of screws 97 are installed along its girth direction to first conveyer belt 91, screws 97 include screw cap 99 and nail pole 910, and screws 97 are packed into and nail pole 910 upwards pierces through first conveyer belt 91 from the inner wall of first conveyer belt 91, nail pole 910 part exposes in the outer wall of first conveyer belt 91, the interior wall of line 3 is pricked in line 3 from the inner wall of line 3 to line 3 is laminated to the nail pole 910 that just exposes at first conveyer belt 91 outer wall at the outer wall of line 3, and the inner wall (being the bottom surface) laminating of line 3 conveys on first conveyer belt 91. Because the inner wall of lines 3 is the one side of laminating wall when installing the wall, consequently even if the inner wall of lines 3 is pricked out hole by screw 97 and is not influenced pleasing to the eye, lines 3's thickness is great moreover, and the holistic performance of lines 3 can not be influenced by screw 97 pricks out hole by hole yet. The lines 3 are nailed by the screws 97, and reliable and stable transmission of the lines 3 is realized on the premise that a guide mechanism is not needed.

The first conveyor belt 91 is provided with a first conveyor belt counterbore 98, the first conveyor belt counterbore 98 comprises a large-diameter hole penetrating through the inner wall of the first conveyor belt 91 and a small-diameter hole penetrating through the outer wall of the first conveyor belt 91, the diameter of the large-diameter hole is larger than that of the small-diameter hole, the screw cap 99 is positioned in the large-diameter hole, the screw rod 910 is partially positioned in the small-diameter hole, and the other part of the screw rod 910 is exposed out of the outer wall of the first conveyor belt 91. When the first belt 91 runs to the belt pulley 911, the screw 97 does not interfere with the belt pulley 911.

The small diameter hole is provided with an internal thread, and the nail shank 910 is provided with an external thread matched with the internal thread. Quick mounting of the screw 97 is achieved by a threaded fit.

The screws 97 include first screws 912 and second screws 913, the first screws 912 and the second screws 913 are equally spaced along the circumferential direction of the first belt 91, and the second screws 913 are located at two sides of the first screws 912. The reliability of the fixation of the line 3 is further improved by the arrangement of the rows of screws 97.

The first screws 912 are located in the middle of the first conveyor belt 91 in the width direction, the second screws 913 are provided in two rows, and the two rows of the second screws 913 are located on two sides of the first screws 912 respectively.

The vertical distance from each row of the second screws 913 to the first screws 912 is n, and the distance between two adjacent first screws 912 is 2n, that is, the second screws 913 and the first screws 912 are distributed in a staggered manner in the circumferential direction of the first conveyor belt 91.

A distance m between two second screws 913 facing in the width direction of the first conveyor belt 91 is 4 cm. The width of the line 3 currently used on the market is at least 5 cm, so that all screws 97 can fix the line 3. After the line 3 moves forwards to the position where the conveyer belt 911 is located, the screw 97 automatically withdraws from the line 3, at the moment, the screw 97 slowly transfers from the side surface of the first conveyer belt 91 to the lower part of the first conveyer belt 91, and the screw 97 at the side surface and the lower part of the first conveyer belt 91 does not play a role in fixing.

The top end of the line 3 is connected with a rotatable pinch roller 85 in an abutting mode. The frame 6 is provided with a support, and the lower part of the support is provided with a pressing wheel 85 for pressing the lines 3. The lines 3 can be firmly attached to the first conveyor belt 91 for conveying through the arrangement of the pinch roller 85.

The utility model also discloses a EPS foam lines covers a net application integration production line, including net 31, template 1, coating mechanism 2, be located sending net device 4 before template 1, be located the turn-up device after template 1, be located the cutting device 5 after the turn-up device, the integration production line still includes frame 6, and template 1, coating mechanism 2 send net device 4, turn-up device, cutting device 5 to all install in frame 6. According to the production process, the net feeding device 4, the template 1 net scraping 31, the curling device, the cutting device 5 and the coating mechanism 2 are sequentially and orderly produced.

The net 31 is a glued net 31, and the glue can be used to firmly adhere the net 31 to the outer wall of the line 3.

The cladding of net 31 is at the outer wall of lines 3, and lines 3 include inner wall and outer wall, and wherein the inner wall is used for laminating the wall to install, and the outer wall of lines 3 need cover the net and scribble the mortar.

The net feeding device 4 comprises a net discharging roller 41 for mounting the net 31 and a net feeding press roller 45 for pressing the net 31 on the upper end of the line 3, the coiled net 31 is sleeved on the net discharging roller 41, the net 31 is sequentially fed to the upper end of the line 3 along the net discharging roller 41, the first net feeding roller 42, the second net feeding roller 43 and the net feeding press roller 45, and the net discharging roller 41, the first net feeding roller 42, the second net feeding roller 43 and the net feeding press roller 45 are all mounted on the frame 6.

Wherein the height of the first net feeding roller 42 is lower than that of the net releasing roller 41 and the second net feeding roller 43, the height of the net feeding press roller 45 is lower than that of the first net feeding roller 42, the second net feeding roller 43 is driven to rotate by a net feeding roller motor 44, the first net feeding roller 42 is a tension roller, and tension sensors are arranged at two ends of the first net feeding roller 42 and used for monitoring the tension of the net 31, so that the speed of the net feeding 31 can be kept synchronous with the advancing speed of the lines 3, and the tension of the net 31 can be adjusted. The net 31 is initially manually adhered to the outer wall of the line 3 for a length while ensuring that the center of the net 31 is aligned with the middle of the outer wall of the line 3, so that the width of the net 31 finally adhered to both sides of the inner wall of the line 3 is maintained to be equal, and the middle of the outer wall of the line 3, i.e., the center of the length of the entire outer wall of the line 3 after spreading.

The net feeding press roller 45 is driven by a power device to be capable of lifting up and down. The power device in the utility model is a net feeding compression roller motor 46, a frame waist-shaped hole 61 is arranged on a frame 6, both ends of a net feeding compression roller 45 form a net feeding compression roller mounting rod 47, the output of the net feeding compression roller motor 46 is connected with a net feeding compression roller motor screw rod 49, the net feeding compression roller motor screw rod 49 is in threaded connection with the net feeding compression roller mounting rod 47 at one end, thus the net feeding compression roller motor 46 can drive the net feeding compression roller 45 to move up and down, the net feeding compression roller mounting rod 47 passes through the frame waist-shaped hole 61, the outer wall of the net feeding compression roller mounting rod 47 is provided with a sliding bearing 48, the net feeding compression roller 45 moves up and down along the frame waist-shaped hole 61 through the sliding bearing 48, the friction resistance is small, the movement is smooth, the line 3 initially enters the net feeding compression roller 45, after the center of the net 31 and the middle of the outer wall of the line 3 are, thereby ensuring that the web 31 conforms horizontally to the lines 3 before entering the formwork 1.

The web 31 and the threads 3 pass successively through the die plate 1 and the coating means 2, the frame 6 is provided with a second conveyor 95 located behind the first conveyor 91, the strands 3 are conveyed by the first conveyor belt 91 and pass through the die plate 1, a plurality of first conveyor front rollers 92 are further mounted on the frame 6, the plurality of first conveyor front rollers 92 are positioned in front of the first conveyor belt 91, thus, the thread 3 firstly passes through a plurality of first conveyor belt front rollers 92 and then enters the first conveyor belt 91, two conveying guide strips 93 are also arranged on the frame 6, the thread 3 enters the first conveyor belt front rollers 92 and the first conveyor belt 91 along the two conveying guide strips 93, after the center of the net 31 and the middle of the outer wall of the line 3 are adjusted and aligned manually, the two conveying guide bars 93 are immediately moved and respectively attached to the two sides of the line 3 to be fixed, the positioning and guiding effects are achieved, and therefore each subsequent line is attached to two conveying guide bars 93 and then enters the space.

The support includes support horizontal pole 8, link up piece 81 and support riser 82, the both ends of support horizontal pole 8 are connected in frame 6, 8 outer wall covers of support horizontal pole are equipped with links up piece 81, thereby link up piece 81 can slide along support horizontal pole 8 and can the adjusting position, link up piece 81 both ends are equipped with links up piece screw 84, twist the jackscrew in one of them links up piece screw 84 and will link up piece 81 and fix at 8 outer walls of support horizontal pole, the other end linking bridge riser 82 of linking up piece 81, support riser 82 is equipped with support riser waist shape hole 83 along its length direction extension, pass support riser waist shape hole 83 through the screw and twist in another linking piece screw 84 and realize the fixed of support riser 82, pinch roller 85 is installed in the bottom of support riser 82, support riser 82 can reciprocate the regulation and make the reliable butt upper end of lines 3 of pinch roller 85. The utility model discloses a support has a plurality of, when line 3 had just entered, template 1 covered net 31 time, the crimping device during operation all through the upper end of pinch roller 85 butt lines 3 to line 3.

The template 1 comprises a template notch 11 matched with the cross section of the line 3, specifically, the template notch 11 is equal to the cross section of the line 3, the line 3 is made of EPS foam material and has certain elasticity, the net 31 is thin, the net 31 and the line 3 can penetrate through the template notch 11 together, and if the template notch 11 is used for covering a net and a film by other materials, the template notch 11 needs to be adjusted according to actual conditions.

Template 1 adopts the metal material to make, and template 1 scrapes portion 12 in the template of the outer edge formation that lies in template breach 11 in the template, scrapes the outer wall profile of portion 12 corresponding lines 3 in the template.

The net 31 and the lines 3 penetrate through the template 1 along the template notch 11 and the net 31 is scraped on the outer wall of the lines 3 through the template inner scraping part 12, the template inner scraping part 12 is inclined at 5-85 degrees with the horizontal plane, the inclined direction of the template inner scraping part 12 is opposite to the moving direction of the lines 3, namely the template inner scraping part 12 inclines backwards when the lines 3 move forwards. The template internal scraping part 12 comprises an abutting part which can be at least partially abutted against the outer wall of the cross section of the line 3, the abutting part can cover the circumference range of the outer wall of the whole line 3, more specifically, the abutting part and the horizontal plane are inclined by 5-85 degrees, and the inclined direction of the abutting part is opposite to the moving direction of the line 3.

The template 1 is also installed on the frame 6 through the support, this support is including support horizontal pole 8 equally, link up piece 81 and support riser 82, the difference lies in not having pinch roller 85, but connect template connecting strip 14 in the bottom of support riser 82, be equipped with template connecting strip perforation 15 on the template connecting strip 14, be equipped with the template mounting hole 13 with template connecting strip perforation 15 one-to-one correspondence on the template 1, pass template connecting strip perforation 15 through the screw and twist template mounting hole 13 and realize the installation of template 1, template mounting hole 13 is the screw hole. The formwork connecting strips 14 are attached to the formwork 1, i.e. they are inclined at the same angle. Meanwhile, in order to facilitate the installation of the template 1, the support cross rod 8 at the position is also installed in a horizontal inclined mode, and the inclined angle of the support cross rod is matched with the inclined angle of the template 1. The movement direction of slope setting and incline direction and lines 3 through between template 1 and the horizontal plane is opposite, can play the effect of scraping to net 31, can not take net 31 up, covers to net effectual.

The connecting line of the two end points at the bottom of the template internal scraping part 12 and the plane of the cross section of the line 3 are inclined by 5-85 degrees, and more specifically, the connecting line of the two end points at the bottom of the abutting part of the external wall of the cross section of the line 3 and the plane of the cross section of the line 3 can be pressed by the template internal scraping part 12 and inclined by 5-85 degrees. Make net 31 and 3 outer walls of lines gradually in proper order get into in the template scrape portion 12 like this, all points on the same cross section of net 31 and lines 3 get into in the template time of scraping portion 12 different promptly to give net 31 abundant deformation time, promoted greatly and covered the net effect, it is good to cover the net reliability.

The outer walls of the lines 3 comprise a first line outer wall 35 and a second line outer wall 36, and the part of the template inner scraping part 12 corresponding to the second line outer wall 36 is positioned in front of the part of the template inner scraping part 12 corresponding to the first line outer wall 35. The front of the position is based on the moving direction of the line 3, and one end of the first covered net is the front. The utility model discloses the relative first outer wall 35 of lines of structure of well lines second outer wall 36 is more complicated, covers the net 31 to the first outer wall 35 of lines that the structure is simple relatively earlier promptly during actual operation like this, covers net 31 to the relative complicated lines second outer wall 36 of structure again, and the net 31 that covers of here successively uses the same cross section of lines 3 as the benchmark, and the first outer wall 35 of lines of same cross section covers net 31 earlier promptly. This design can achieve a better net 31 coverage effect (easy before difficult).

It is also possible that the portion of the template inner scratch 12 corresponding to the line second outer wall 36 is located behind the portion of the template inner scratch 12 corresponding to the line first outer wall 35.

The hemming device comprises a hemming mechanism 71, the hemming device further comprises a hemming front blocking mechanism 7 located in front of the hemming mechanism 71, the hemming front blocking mechanism 7 comprises a hemming front blocking shaft 72, a front blocking cylinder bearing 73 and a hemming front blocking cylinder 74, the number of the hemming front blocking shafts 72 is two and the two blocking cylinders are distributed at intervals, the hemming front blocking shaft 72 is fixedly connected to the frame 6 through screws, the front blocking cylinder bearing 73 is installed at the upper end and the lower end of the hemming front blocking shaft 72, the hemming front blocking cylinder 74 is concentrically sleeved on the outer wall of the hemming front blocking shaft 72, the inner wall of the hemming front blocking cylinder 74 is in interference fit with the outer walls of the upper front blocking cylinder bearing 73 and the lower front blocking cylinder bearing 73, and therefore the two hemming front blocking cylinders 74 can rotate.

The curling mechanism 71 comprises two curling barrel shafts 75 and a curling barrel 77 which is positioned at the periphery of the curling barrel shafts 75 and can rotate along the axis of the curling barrel shafts 75, the upper end and the lower end of each curling barrel shaft 75 are provided with curling barrel bearings 76, and the inner wall of the curling barrel 77 is in interference fit with the outer walls of the upper curling barrel bearing 76 and the lower curling barrel bearing 76.

The curling barrel 77 includes a curling barrel flange 78 extending horizontally outward, and the lower end of the curling front stop 74 is lower than the curling barrel flange 78. After the wire 31 passes through the template 1, the wire 31 has redundant parts which are not covered, the parts are symmetrically distributed on two sides of the outer wall of the wire 3, the parts which are not covered are straightened at the two pre-crimping baffles 74, namely the redundant wires 31 on two sides vertically sag, the distance between the two pre-crimping baffles 74 is equivalent to the distance between two sides of the outer wall of the wire 3, and thus the two pre-crimping baffles 74 are driven to rotate by friction when the wire 3 passes through the wire 31, and the redundant wires 31 on two sides vertically sag.

The net 31 is scraped on the outer wall of the line 3 to form a net folding edge part 32 exceeding the outer wall of the line 3, and the redundant nets 31 on the two sides are the net folding edge parts 32.

The net flange part 32 is attached to pass through the upper ends of the two hemming barrel flanges 78, and the hemming barrel flanges 78 scrape the net flange part 32 on two sides of the bottom surface of the wire 3. Namely, the bottom surface of the line 3 and the upper end of the hemming tube hem 78 are at the same height, the two hemming tube hems 78 are driven to rotate by friction force when the two sides of the outer wall of the line 3 pass through the two hemming tube hems 78, and meanwhile, the net covering 31 of the bottom surface of the line 3 is realized.

The cutting device 5 comprises an electric saw 56, a walking power source for driving the electric saw 56 to move back and forth, and a cutting power source for driving the electric saw 56 to move the dividing line 3 left and right. The utility model provides a walking power supply still can be for cylinder, pneumatic cylinder etc. for walking motor 51, the utility model provides a cut off the power supply and for cutting off motor 54, still can be for cylinder, pneumatic cylinder etc..

The walking motor 51 is installed on the cutting device base 58, the cutting device base 58 can be connected with the rack 6 in a welding mode, the output end of the walking motor 51 is connected with the walking motor screw rod 52, the cutting device base 58 is provided with a cutting device sliding rail 57, the walking seat 53 is arranged on the cutting device sliding rail 57 in a sliding mode, the walking motor screw rod 52 penetrates through the walking seat 53 in a threaded connection mode, and therefore the walking motor 51 can drive the walking seat 53 to move back and forth. One end of the walking seat 53 is provided with a cutting motor 54, the output end of the cutting motor 54 is connected with a cutting motor screw 55, and the cutting motor screw 55 is in threaded connection with and penetrates through an electric saw 56.

A line spacer block 34 is attached between the two adjacent lines 3. The line spacer 34 is manually installed to separate a section of the line 3. The thread spacer 34 connects the lower end faces of the two threads 3.

Lie in induction system 63 that is equipped with behind the hemming device in frame 6, induction system 63 can be infrared ray induction system, and induction system 63 highly is less than the highest point of lines 3, when complete lines 3 passes through, blocks the infrared ray, when lines spacer block 34 passes through, because lines spacer block 34's position is lower, the infrared ray permeable, induction system 63 triggers cutting device 5 work, specifically is: the walking motor 51 starts firstly to enable the electric saw 56 to move forwards at the same speed as the advancing speed of the line 3, so that the electric saw 56 and the line 3 advance synchronously, meanwhile, the cut-off motor 54 starts to drive the electric saw 56 to move left and right to separate the two lines 3, and after the separation is finished, the electric saw 56 returns to the original position to wait for the next cutting operation, the cutting part of the electric saw 56 is actually the line spacer block 34 between the next line 3, and the line spacer block 34 is arranged at the tail end of the previous line 3 after the separation, so that the subsequent coating of the previous line 3 cannot be influenced. The cutting device 5 can reduce the labor and has high efficiency. A protective cover 59 is arranged on the frame 6, and the protective cover 59 is used for covering the cutting device 5 and preventing the electric saw 56 from accidentally injuring people during operation.

The strands 3 are conveyed by the second conveyor 95 and through the coating mechanism 2, at which point the strands 3 have been coated. The second conveyor belt 95 is driven by a second conveyor belt motor 94.

The coating mechanism 2 is provided with a coating plate notch 24 matched with the cross section of the line 3, the coating mechanism 2 comprises a feed port 22 and a coating frame 21 penetrating through the feed port from front to back, coating plates 23 are mounted at the front end and the back end of the coating frame 21, and the coating plate notch 24 is arranged on the coating plate 23. The coating plate notch 24 of the front-end coating plate 23 (the coating plate 23 which is contacted with the coating mechanism 2 firstly when the line 3 enters) is equal to the cross section of the line 3, the line 3 is made of EPS foam material and has certain elasticity, and the net 31 is thin, so that the line 3 which is coated with the net can pass through, the coating plate notch 24 of the rear-end coating plate 23 is equidistantly enlarged by 3-5mm from the cross section of the line 3, and 3-5mm mortar is coated outside the line 3, so that the line 3 can smoothly come out of the rear-end coating plate 23 after being coated with the mortar.

The feed opening 22 is provided at the top of the coating frame 21. The feed opening 22 is used for adding mortar during the production process. The bottom of the coating frame 21 is provided with a coating bin mounting seat 26, and the coating bin mounting seat 26 is fixedly connected with the frame 6.

The coating mechanism 2 forms a coating plate inner scraping part 25 at the outer edge of the coating plate notch 24, the coating plate inner scraping part 25 corresponds to the outer wall profile of the line 3, a coating material, namely mortar, is arranged in the coating mechanism 2, the line 3 and the net 31 penetrate through the coating mechanism 2 along the coating plate notch 24, the coating material is coated on the outer wall of the net 31 through the coating plate inner scraping part 25 to form a coating layer 33, the coating plate inner scraping part 25 is inclined at 5-85 degrees with the horizontal plane, and the inclined direction of the coating plate inner scraping part 25 is opposite to the moving direction of the line 3. That is, the scraping part 25 in the coating plate inclines backwards when the line 3 moves forwards, so that the net 31 cannot be lifted, mortar is pressed on the outer walls of the line 3 and the net 31, the mortar coating effect can be improved, and the coating plate is more uniform and compact. The coating plate internal scraping portion 25 at least partially presses the net 31, and the portion capable of pressing the net 31 can cover the whole circumference range of the outer wall of the line 3.

Meanwhile, a connecting line of two end points at the bottom of the inner scraping part 25 of the coating plate and a plane where the cross section of the line 3 is located are inclined by 5-85 degrees, and the distance is opened back and forth through the coating part, so that the outer wall of the line 3 is sequentially coated step by step, and the uniform effect of mortar coating is further improved. The portion of the coating plate inner scraping portion 25 corresponding to the line second outer wall 36 is located forward of the portion of the coating plate inner scraping portion 25 corresponding to the line first outer wall 35. The front of the position is based on the moving direction of the line 3, and the end coated first is the front. The utility model discloses the relative first outer wall 35 of lines of structure of well lines second outer wall 36 is more complicated, carries out the application to the first outer wall 35 of lines that the structure is simple relatively earlier promptly during actual operation like this, carries out the application to the relative complicated lines second outer wall 36 of structure again, and the application of here successively uses the same cross section of lines 3 as the benchmark, the first outer wall 35 of lines of same cross section is the application earlier promptly. The design can realize better coating effect (easy first and difficult last), and the mortar is more uniform and compact in coating. The part of the coating plate inner scraping part 25 corresponding to the line second outer wall 36 can be positioned behind the part of the coating plate inner scraping part 25 corresponding to the line first outer wall 35.

A third conveyor belt 96 is also arranged on the machine frame 6 behind the coating device 2, and the third conveyor belt 96 conveys away the coated threads 3.

The electric cabinet 62 is installed on the frame 6, and each process flow of the whole production can be controlled through the electric cabinet 62, and the electric cabinet 62 is not described in detail herein.

The production method of the EPS foam line lapping and coating integrated production line comprises the following steps:

a. the wire 3 is conveyed on the first conveyor belt 91, the net 31 is conveyed by the net conveying device 4 and synchronously advances the net 31 and the wire 3, the net 31 covers the outer wall of the wire 3 and passes through the template 1 together, the template 1 comprises a template notch 11 matched with the cross section of the wire 3, the template 1 forms a template inner scraping part 12 at the outer edge of the template notch 11, the net 31 and the wire 3 pass through the template 1 along the template notch 11 and scrape the net 31 on the outer wall of the wire 3 through the template inner scraping part 12, and the net 31 scrapes on the outer wall of the wire 3 to form a net folding part 32 exceeding the outer wall of the wire 3;

b. the line 3 with the outer wall covered with the net 31 passes through a curling device, and the curling device scrapes and covers the net folding edge parts 32 on two sides of the bottom surface of the line 3;

c. the finished wire 3 covered with the net 31 passes through a cutting device 5, and the cutting device 5 cuts the wire 3;

d. the divided lines 3 pass through a coating mechanism 2, the coating mechanism 2 is provided with a coating plate notch 24 matched with the cross section of the lines 3, the coating mechanism 2 forms a coating plate inner scraping part 25 at the outer edge of the coating plate notch 24, a coating material is arranged in the coating mechanism 2, the lines 3 and a net 31 pass through the coating mechanism 2 along the coating plate notch 24, and the coating material is coated on the outer wall of the net 31 through the coating plate inner scraping part 25 to form a coating layer 33;

e. the coated strands 3 are transported away by a third conveyor 96.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included within the protection scope of the present invention.

Claims (8)

1. A conveyor for EPS foam lines conveying, characterized in that: including line (3) that adopt EPS foam material and first conveyer belt (91) that are used for conveying line (3), a plurality of screws (97) are installed along its girth direction in first conveyer belt (91), screw (97) are including screw cap (99) and nail pole (910), and screw (97) are packed into and are followed nail pole (910) and upwards pierce through first conveyer belt (91) from the inner wall of first conveyer belt (91), nail pole (910) part exposes at the outer wall of first conveyer belt (91), line (3) laminating is in line (3) are pricked into from the inner wall of line (3) at the outer wall of first conveyer belt (91) and nail pole (910) that expose at first conveyer belt (91) outer wall.

2. A conveying device for EPS foam strand transfer as set forth in claim 1, wherein: the first conveyor belt (91) is provided with a first conveyor belt counter bore (98), the first conveyor belt counter bore (98) comprises a large-diameter hole penetrating through the inner wall of the first conveyor belt (91) and a small-diameter hole penetrating through the outer wall of the first conveyor belt (91), the diameter of the large-diameter hole is larger than that of the small-diameter hole, the screw cap (99) is located in the large-diameter hole, and the screw rod (910) is partially located in the small-diameter hole.

3. A conveying device for EPS foam strand transfer as set forth in claim 2, wherein: the small-diameter hole is provided with internal threads, and the nail rod (910) is provided with external threads matched with the internal threads.

4. A conveying device for EPS foam strand transfer as set forth in claim 1, wherein: the screws (97) comprise first screws (912) and second screws (913), the first screws (912) and the second screws (913) are distributed at equal intervals along the circumferential direction of the first conveyor belt (91), and the second screws (913) are located on two sides of the first screws (912).

5. A conveying device for EPS foam strand transfer as set forth in claim 4, wherein: the first screws (912) are located in the middle of the first conveyor belt (91) in the width direction, the second screws (913) are arranged in two rows, and the two rows of the second screws (913) are located on two sides of the first screws (912) respectively.

6. A conveying device for EPS foam strand transfer as set forth in claim 5, wherein: the vertical distance from each row of the second screws (913) to the first screws (912) is n, the distance between every two adjacent first screws (912) is 2n, and the distance m between every two second screws (913) opposite to each other in the width direction of the first conveyor belt (91) is 4 cm.

7. A conveying device for EPS foam strand transfer as set forth in claim 1, wherein: the first conveyor belt (91) is wrapped on the periphery of the two conveyor belt wheels (911).

8. A conveying device for EPS foam strand transfer as set forth in claim 1, wherein: the top end of the line (3) is connected with a rotatable pinch roller (85) in an abutting mode.

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