CN116427123A - Production device for preparing filament spun-bonded geotextile based on recycled textile - Google Patents

Abstract

The invention relates to the technical field of textile processing, in particular to a production device for preparing filament spun-bonded geotextile based on recycled textiles. The utility model provides a production device based on retrieve fabrics preparation filament spun-bonded geotechnique cloth, including symmetrical distribution's conveying platform, there is the semicircle ring through supporting leg rigid coupling between the symmetrical distribution's conveying platform, semicircle ring rigid coupling has the disc of symmetrical distribution, a disc is provided with control terminal, the disc rotates and is connected with the rotation sleeve, the rotation sleeve rigid coupling that is close to control terminal has first gear, the disc rigid coupling that is close to control terminal has the gear motor who is connected with the control terminal electricity, gear motor's output shaft rigid coupling has the second gear with first gear engagement, symmetrical distribution's rotation sleeve has the heat conduction sleeve through backup pad rigid coupling. According to the invention, the geotextile is gradually thinned by extruding the geotextile through the electric rollers distributed at equal intervals, so that the phenomenon that the geotextile is wrinkled due to the fact that the geotextile is thinned rapidly is avoided.

Description

Production device for preparing filament spun-bonded geotextile based on recycled textile

Technical Field

The invention relates to the technical field of textile processing, in particular to a production device for preparing filament spun-bonded geotextile based on recycled textiles.

Background

The textile is a necessity in life, and when the textile is manufactured, part of enterprises producing the textile recycle the waste textile, so that the pollution to the environment is reduced, and the resource is saved.

In the prior art, for example, the patent with publication number CN115782009A discloses a production device for preparing geotechnical cloth from waste textiles and a production process thereof, the production device comprises a workbench, a rotating groove is formed in the workbench, the rotating groove is provided with an upper opening at the upper side and a side opening at the side surface, a heat conducting cylinder is rotationally arranged in the rotating groove, a heater is fixedly arranged on the side wall of the rotating groove far away from the side opening, the heater is arranged close to the inner top surface of the heat conducting cylinder, a driving mechanism for driving the heat conducting cylinder to rotate around the axis of the heat conducting cylinder is arranged on the workbench, and a fixing frame is arranged at one side of the upper end of the workbench, which is positioned at the upper opening.

The device has solved geotechnique cloth and can not be heated up in succession or the cooling, leads to the thin layer base to be heated unevenly to influence the problem of final yield, but the compression roller is when extrudeing geotechnique cloth, and the distance between compression roller and the geotechnique cloth does not change gradually, leads to compression roller extrusion geotechnique cloth to make geotechnique cloth appear the fold, and the device needs to guarantee that the distance between heat conduction section of thick bamboo and the heater changes gradually, and this just requires the heater to have the heat source of specific position, and the cost of manufacture of heater is high.

Disclosure of Invention

In order to solve the technical problems, the invention provides a production device for preparing filament spun-bonded geotextile based on recycled textiles, which is heated uniformly.

The technical proposal is as follows: the utility model provides a production device based on retrieve fabrics preparation filament spun-bonded geotechnique cloth, including symmetrical distribution's conveying platform, there is the semicircle ring through the supporting leg rigid coupling between the symmetrical distribution's conveying platform, semicircle ring rigid coupling has symmetrical distribution's disc, a disc is provided with control terminal, the disc rotates and is connected with the rotation sleeve, the rotation sleeve rigid coupling that is close to control terminal has first gear, the disc rigid coupling that is close to control terminal has the gear motor who is connected with control terminal electricity, gear motor's output shaft rigid coupling has the second gear with first gear engagement, symmetrical distribution's rotation sleeve has the heat-conducting sleeve through backup pad rigid coupling, symmetrical distribution's disc rigid coupling has the heat preservation cover, the heat preservation cover is provided with equidistant and symmetrical distribution's slide bar, be provided with the electric roller that is connected with control terminal electricity between the slide bar of symmetrical distribution, the heat-conducting sleeve is around being equipped with geotechnique cloth, equidistant electric roller and heat-conducting sleeve between the distance along geotechnique cloth direction of delivery taper, heat-conducting sleeve and equidistant electric roller synchronous rotation and conveying geotechnique cloth, geotechnique cloth receives equidistant electric roller extrusion taper, the disc is provided with the heating mechanism that is used for heating geotechnique cloth.

Preferably, the heating mechanism comprises a fixed shaft, the fixed shaft is fixedly connected with a symmetrically distributed disc through an L-shaped plate, a rotating sleeve is rotationally connected with the fixed shaft, the fixed shaft is fixedly connected with a fixed plate positioned in a heat conducting sleeve, the fixed plate is fixedly connected with a heat conducting shell through a supporting plate, the heat conducting sleeve is in sliding connection with the heat conducting shell, the fixed plate is fixedly connected with a water pump electrically connected with a control terminal through the supporting plate, the water pump is communicated with a heater electrically connected with the control terminal, the heater is communicated with the middle part of the heat conducting shell through a water pipe, an intercepting plate which is symmetrically distributed is in sliding connection with the heat conducting shell, the intercepting plate is gradually thickened from one side close to the heater to one side far away from the heater, the intercepting plate is provided with equally-spaced water inlets, the intercepting plate is fixedly connected with an arc-shaped pipe which is symmetrically distributed and is in sliding connection with the heat conducting shell, the arc-shaped pipe is communicated with the adjacent communication groove, the arc-shaped pipe is communicated with the water pump through a hose, and the heat conducting shell, the arc-shaped pipe and the hose are filled with water.

Preferably, the adjusting part comprises a first electric push rod fixedly connected to the fixed plate, the first electric push rod is electrically connected with the control terminal, a U-shaped plate is fixedly connected to the telescopic end of the first electric push rod, a connecting plate is fixedly connected to the arc-shaped pipe close to the same interception plate, and symmetrically distributed connecting plates are matched with the U-shaped plate.

Preferably, the device further comprises an adjusting mechanism for adjusting the extrusion thickness of geotechnical cloth, the adjusting mechanism is arranged on the heat-insulating cover and comprises arc gear rings which are symmetrically distributed, the arc gear rings are provided with inclined sliding grooves which are distributed at equal intervals and are in sliding connection with adjacent sliding rods, the inclined sliding grooves of the arc gear rings deflect for a certain angle relative to the adjacent sliding rods, the sliding rods are in sliding connection with the heat-insulating cover, the heat-insulating cover is fixedly connected with a double-shaft motor which is electrically connected with a control terminal, and two output shafts of the double-shaft motor are fixedly connected with third gears which are meshed with the adjacent arc gear rings.

Preferably, the cleaning mechanism is arranged on the semicircular ring and used for cleaning impurities adhered to the heat conducting sleeve, the cleaning mechanism comprises a baffle plate fixedly connected to the semicircular ring, the semicircular ring is provided with a discharge hole matched with the baffle plate, the baffle plate is slidably connected with an arc-shaped rod fixedly connected with a first scraping plate matched with the heat conducting sleeve, and a stretching part used for reducing the adhesion amount of geotechnical cloth on the heat conducting sleeve is arranged on a conveying platform close to the discharge side of the geotechnical cloth.

Preferably, the stretching component comprises elastic plates which are symmetrically distributed, one ends of the elastic plates which are symmetrically distributed are fixedly connected to the heat insulation cover, rollers are arranged between the elastic plates which are symmetrically distributed, the conveying platform is fixedly connected with second electric push rods which are symmetrically distributed and electrically connected with the control terminal, the other ends of the elastic plates are fixedly connected with the telescopic ends of the adjacent second electric push rods, and the baffle is provided with a detection component for detecting residual geotechnical cloth on the heat conduction sleeve.

Preferably, the detection assembly comprises symmetrically distributed pressure sensors, the symmetrically distributed pressure sensors are fixedly connected to the baffle, the pressure sensors are in sliding connection with the adjacent arc rods, and springs are arranged between the pressure sensors and the first scraping plate.

Preferably, the dust removing device comprises a dust removing mechanism, wherein the dust removing mechanism is arranged on a conveying platform close to one side of the discharging of the geotechnical cloth, the dust removing mechanism is used for cleaning impurities on the geotechnical cloth, the dust removing mechanism comprises telescopic frames which are symmetrically distributed and electrically connected with a control terminal, the telescopic frames which are symmetrically distributed are arranged on the conveying platform on one side, guide plates are fixedly connected with the telescopic frames, dust suction boxes are fixedly connected with the guide plates which are symmetrically distributed, through holes are formed in one side, close to the geotechnical cloth, of the dust suction boxes, an exhaust fan is electrically connected with the control terminal, and the guide plates are provided with scraping components for scraping the impurities on the dust suction boxes.

Preferably, the scraping component comprises a servo motor, the servo motor is fixedly connected to a guide plate on one side, the servo motor is electrically connected with a control terminal, an output shaft of the servo motor is fixedly connected with a threaded rod, a rectangular frame is connected with the threaded rod in a threaded mode, the rectangular frame is connected with a U-shaped frame in a sliding mode, the U-shaped frame is in sliding fit with the guide plate and a dust box, symmetrically distributed tension springs are fixedly connected between the U-shaped frame and the rectangular frame, symmetrically distributed aggregate shells matched with the dust box are fixedly connected to the U-shaped frame, and an aggregate assembly used for cleaning impurities in the aggregate shells is arranged on the rectangular frame.

Preferably, the assembly gathers materials including the rack of symmetric distribution, the rack of symmetric distribution all rigid coupling in the rectangle frame, the deflector has through backup pad rigid coupling with adjacent shell complex that gathers materials receive the workbin, the deflector is connected with the bull stick through the backup pad rotation, the shell that gathers materials is provided with symmetric distribution and with adjacent bull stick complex recess, the bull stick rigid coupling has the second scraper blade of circumference equidistant distribution, the second scraper blade cooperates with adjacent shell that gathers materials, the bull stick rigid coupling has with adjacent rack complex fourth gear.

The beneficial effects of the invention are as follows: according to the invention, the geotextile is gradually thinned by extruding the geotextile through the electric rollers distributed at equal intervals, the geotextile is prevented from being quickly thinned to cause the geotextile to be wrinkled, the limit of the interception plate is used for dispersing water entering the heat conduction shell to two sides, the temperature of the heat conduction sleeve at the same position is gradually reduced from the middle part of the heat conduction shell to two sides, the geotextile outside the heat conduction sleeve is ensured to be heated and cooled firstly, the temperature change is more uniform, the distance between the interception plates is changed, the area of the geotextile heated by the heat conduction sleeve is adjusted, the different processing modes of the geotextile are adapted, the thickness of the geotextile is adjusted by changing the distance between the electric rollers and the heat conduction sleeve, the adhesion quantity of the geotextile on the heat conduction sleeve is reduced by enabling the geotextile to be slowly far away from the heat conduction sleeve, the integrality of the geotextile is improved, and the through holes on the lower surface of the dust absorption box are prevented from being plugged by fluff by periodically cleaning impurities adsorbed on the lower surface of the dust absorption box.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of a heat-conducting sleeve-heated geotextile according to the present invention.

Fig. 3 is an exploded view of a three-dimensional structure of the present invention.

Fig. 4 is a schematic perspective view of a temperature raising mechanism according to the present invention.

Fig. 5 is a schematic perspective view of an adjusting member according to the present invention.

Fig. 6 is a schematic perspective view of the cooperation of the interception plate and the heat conducting shell.

Fig. 7 is a schematic perspective view of an adjusting mechanism according to the present invention.

Fig. 8 is a schematic perspective view of a tension member according to the present invention.

Fig. 9 is a schematic perspective view of a cleaning mechanism according to the present invention.

Fig. 10 is a schematic perspective view of the dust removing mechanism of the present invention.

Fig. 11 is a schematic perspective view of a scraping member of the present invention.

Fig. 12 is a schematic perspective view of an aggregate assembly according to the present invention.

Fig. 13 is a schematic perspective view of the engagement of the rack and the fourth gear of the present invention.

The reference symbols in the drawings: 1-conveying platform, 101-geotechnical cloth, 2-semicircular ring, 201-discharge hole, 3-disc, 4-rotary sleeve, 401-first gear, 402-gear motor, 403-second gear, 5-heat conducting sleeve, 6-heat insulation cover, 7-slide bar, 8-electric roller, 901-fixed shaft, 902-fixed plate, 903-heat conducting shell, 904-water pump, 905-heater, 906-interception plate, 9061-water inlet, 9062-communicating groove, 907-arc tube, 908-hose, 1001-first electric push rod, 1002-U-shaped plate, 1003-connecting plate, 1101-arc gear ring, 1102-double-shaft motors, 1103-third gears, 1201-baffles, 1202-arc rods, 1203-first scrapers, 1204-pressure sensors, 1205-springs, 1301-elastic plates, 1302-rollers, 1303-second electric push rods, 1401-telescopic frames, 1402-guide plates, 1403-dust boxes, 1404-exhaust fans, 1501-servo motors, 1502-threaded rods, 1503-rectangular frames, 1504-U-frames, 1505-tension springs, 1506-aggregate housings, 1601-racks, 1602-material receiving boxes, 1603-rotating rods, 1604-second scrapers, 1605-fourth gears.

Detailed Description

The invention will now be described in more detail with reference to the drawings and specific examples, which are not intended to limit the invention thereto.

Example 1: the utility model provides a production device based on retrieve fabrics preparation filament spun-bonded geotechnique cloth, as shown in fig. 1-3, including two conveying platform 1 of bilateral symmetry distribution, there is semicircle ring 2 through the supporting leg rigid coupling between two conveying platform 1, semicircle ring 2 rigid coupling has two discs 3 of front side, disc 3 is provided with control terminal, disc 3 rotates and is connected with rotary sleeve 4, rotary sleeve 4 rigid coupling of front side has first gear 401, disc 3 rigid coupling of front side has gear 402 with control terminal electricity connection, gear 402's output shaft rigid coupling has with first gear 401 meshing second gear 403, two rotary sleeve 4 have heat-conducting sleeve 5 through the backup pad rigid coupling, heat-conducting sleeve 5 is located semicircle ring 2, the central point of heat-conducting sleeve 5 and the coincidence of semicircle ring 2, the upper portion rigid coupling of two discs 3 has heat preservation cover 6, heat preservation cover 6 is provided with equidistant and front and back symmetric distribution's 7, be provided with the motorized roller 8 that is connected with control terminal electricity between the symmetric distribution 7, motorized roller 8 is in the face of electric roller 5 and is the electric roller 101 that is distributed at the control terminal electricity, the electric roller 5 is the electric roller 101 of the cloth that is equipped with the heat-conducting sleeve, the electric roller 101 of the equidistant cloth that is distributed from left side to the side and the heat-conducting sleeve is equipped with the heat-conducting sleeve, the electric roller 101 of the heat-conducting sleeve is used for the equidistant cloth that the heat-conducting sleeve 101 is gradually distributed to the heat-conducting sleeve 101, the equidistant between the cloth 101 of the equidistant roller 101 of the cloth that is used for the equidistant side 101 to the heat-up to the heat-conducting sleeve 101, the distance of the heat-proof roller 101 is gradually has the heat-proof sleeve 101, the vibration of the heat-proof sleeve 101, the vibration between the vibration of the vibration between the cloth is the heat between the heat-proof sleeve 101, and the vibration from the vibration to the vibration between the cloth.

As shown in fig. 2 and 4-6, the heating mechanism comprises a fixed shaft 901, the fixed shaft 901 is fixedly connected with symmetrically distributed discs 3 through an L-shaped plate, a rotating sleeve 4 is rotationally connected with the fixed shaft 901, the fixed shaft 901 is positioned in the rotating sleeve 4, the middle part of the fixed shaft 901 is fixedly connected with a fixed plate 902 positioned in a heat conducting sleeve 5, the fixed plate 902 is positioned between the two discs 3, the fixed plate 902 is fixedly connected with a heat conducting shell 903 through a supporting plate, the heat conducting shell 903 is arc-shaped, the heat conducting shell 903 is tightly attached to the upper side of the inner wall of the heat conducting sleeve 5, the heat conducting sleeve 5 is in sliding connection with the heat conducting shell 903, the middle part of the upper surface of the fixed plate 902 is fixedly connected with a water pump 904 electrically connected with a control terminal through the supporting plate, the upper part of the water pump 904 is communicated with a heater 905 electrically connected with the control terminal, the heater 905 is communicated with the middle part of the heat conducting shell 903 through a water pipe, the heat conduction casing 903 is connected with two interception plates 906 in a sliding mode, the two interception plates 906 are symmetrically distributed left and right, one side, close to the heater 905, of each interception plate 906 is gradually thickened from one side, close to the heater 905, of each heat conduction sleeve 5, heat absorbed by the middle portion of the heat conduction casing 903 towards two sides is gradually reduced, the interception plates 906 are provided with water inlets 9061 which are distributed at equal intervals in the front-back direction, the water inlets 9061 are located on the lower sides of the inner side faces of the adjacent interception plates 906, the interception plates 906 are provided with communication grooves 9062 communicated with the water inlets 9061, the lower sides of the interception plates 906 are fixedly connected with two arc-shaped pipes 907 which are symmetrically distributed in the front-back direction and are in sliding connection with the heat conduction casing 903, the arc-shaped pipes 907 are communicated with the adjacent communication grooves 9062, the arc-shaped pipes 907 are communicated with the water pump 904 through hoses 908, water is filled in the heat conduction casing 903, the arc-shaped pipes 907 and the hoses 908 are filled with water, and adjusting components used for adjusting the heated area of the heat conduction casing 903 are arranged on the fixing plates 902.

As shown in fig. 4-6, the adjusting component includes a first electric push rod 1001, the first electric push rod 1001 is fixedly connected to the lower surface of the fixed plate 902, the first electric push rod 1001 is electrically connected to the control terminal, the telescopic end of the first electric push rod 1001 is fixedly connected with a U-shaped plate 1002, two arc tubes 907 close to the same interception plate 906 are fixedly connected with a connecting plate 1003, the two connecting plates 1003 are matched with the U-shaped plate 1002, and the U-shaped plate 1002 moves upwards to drive the two connecting plates 1003 to move upwards.

When needs use this apparatus for producing to heat geotechnique's cloth 101, operating personnel starts gear motor 402 through control terminal at first, gear motor 402's output shaft passes through second gear 403 and first gear 401 and drives the rotation sleeve 4 rotation of front side, the rotation sleeve 4 of front side drives heat conduction sleeve 5 through the backup pad and rotates clockwise, control terminal starts motorized roll 8 simultaneously, motorized roll 8 anticlockwise rotates, operating personnel puts geotechnique's cloth 101 on the left side conveying platform 1 between leftmost motorized roll 8 and heat conduction sleeve 5, motorized roll 8 and heat conduction sleeve 5 synchronous rotation carry geotechnique's cloth 101 to the right, when geotechnique's cloth 101 carries, heat geotechnique's cloth 101, specific operation is as follows: the control terminal starts the water pump 904, the water pump 904 pumps out the water in the heat conduction casing 903 through hose 908 and arc pipe 907, the water pump 904 carries water to the heater 905 in, control terminal starts the heater 905 and carries and get into the middle part in the heat conduction casing 903 through the water pipe upwards, the water after getting into heat conduction casing 903 disperses to both sides, because the spacing of interception board 906 for heat conduction sleeve 5 of heat conduction casing 903 homonymy reduces to both sides temperature by the middle part of heat conduction casing 903 gradually, guarantee the geotechnique 101 of heat conduction sleeve 5 outside heat-up earlier and then cooling down, and temperature variation is more even, water gets into intercommunication groove 9062 through inlet 9061 and discharges through arc pipe 907, and repeat the above-mentioned step and circulate, finally, geotechnique 101 shifts out from heat conduction sleeve 5 right side and carries platform 1 to the right side, in the course that geotechnique 101 is carried along heat conduction sleeve 5, because equidistant electric roller 8 and heat conduction sleeve 5 between the distance from left to right gradually reduce, make geotechnique 101 be pressed thin gradually, geotechnique 101 is avoided being pressed thin by the rapid, geotechnical cloth 101 is pressed to appear and the fold.

When the heated area of the geotechnical cloth 101 needs to be adjusted (when part of the geotechnical cloth 101 is at the highest temperature, the fibers on the geotechnical cloth 101 can be melted rapidly, the time for keeping the highest temperature can be reduced, and therefore the heated area of the geotechnical cloth 101 needs to be adjusted), the control terminal starts the first electric push rod 1001, the telescopic end of the first electric push rod 1001 drives the U-shaped plate 1002 to move upwards, the U-shaped plate 1002 drives the two connecting plates 1003 to move upwards, the connecting plates 1003 drive the adjacent arc-shaped pipes 907 to slide along the adjacent heat conducting shell 903, the arc-shaped pipes 907 drive the interception plates 906 to slide along the heat conducting shell 903, the distance between the two interception plates 906 is gradually shortened, the area of the geotechnical cloth 101 heated by the heat conducting sleeve 5 is reduced, the temperature reduction speed of the geotechnical cloth 101 (the temperature reduction speed of the geotechnical cloth 101 is determined by the bending degree of the interception plates 906), and different processing modes of the geotechnical cloth 101 are adapted.

Example 2: on the basis of embodiment 1, as shown in fig. 1 and 7, the device further comprises an adjusting mechanism for adjusting the extrusion thickness of geotechnical cloth 101, the adjusting mechanism is arranged on the heat insulation cover 6, the adjusting mechanism comprises two arc gear rings 1101 which are symmetrically distributed around, the arc gear rings 1101 are provided with inclined sliding grooves which are distributed at equal intervals and are in sliding connection with adjacent sliding rods 7, the inclined sliding grooves of the arc gear rings 1101 deflect for a certain angle relative to the adjacent sliding rods 7, the sliding rods 7 are in sliding connection with the heat insulation cover 6, the arc gear rings 1101 drive the sliding rods 7 to move through the inclined sliding grooves, the heat insulation cover 6 is fixedly connected with a double-shaft motor 1102 which is electrically connected with a control terminal, and two output shafts of the double-shaft motor 1102 are fixedly connected with a third gear 1103 which is meshed with the adjacent arc gear rings 1101.

When the thickness of the geotechnical cloth 101 after the machining is required to be adjusted, taking increasing the final thickness of the geotechnical cloth 101 as an example, the control terminal starts the double-shaft motor 1102, two output shafts of the double-shaft motor 1102 drive two third gears 1103 to rotate, the third gears 1103 drive adjacent arc gear rings 1101 to rotate, the arc gear rings 1101 drive the sliding bars 7 to move through limiting grooves on the arc gear rings 1101, the two sliding bars 7 which are symmetrical front and back drive the electric roller 8 to be away from the heat conducting sleeve 5, the distance between the electric roller 8 and the heat conducting sleeve 5 is increased, and the thickness of the geotechnical cloth 101 is increased.

Example 3: on the basis of embodiment 1, as shown in fig. 2, 8 and 9, the device further comprises a cleaning mechanism, the cleaning mechanism is arranged on the semicircular ring 2, the cleaning mechanism is used for cleaning impurities adhered on the heat conducting sleeve 5, the cleaning mechanism comprises a baffle 1201, the baffle 1201 is fixedly connected to the semicircular ring 2, the baffle 1201 is located on the lower side of the right part of the inner side surface of the semicircular ring 2, the semicircular ring 2 is provided with a discharge hole 201 matched with the baffle 1201, the baffle 1201 guides the residual geotechnical cloth 101 to the discharge hole 201 and discharges the residual geotechnical cloth, the baffle 1201 is connected with an arc rod 1202 in a sliding mode, a first scraping plate 1203 matched with the heat conducting sleeve 5 is fixedly connected to the upper end of the arc rod 1202, and a stretching part for reducing the adhesion amount of the geotechnical cloth 101 on the heat conducting sleeve 5 is arranged on the right side of the conveying platform 1.

As shown in fig. 2 and 8, the stretching component includes two elastic plates 1301 symmetrically distributed around, the upper ends of the two elastic plates 1301 are fixedly connected to a heat insulation cover 6, a roller 1302 equally spaced is arranged between the two elastic plates 1301, two second electric push rods 1303 symmetrically distributed around and electrically connected to the control terminal are fixedly connected to the conveying platform 1, the lower ends of the elastic plates 1301 are fixedly connected to the telescopic ends of the adjacent second electric push rods 1303, and a baffle 1201 is provided with a detection assembly for detecting residual geotechnical cloth 101 on the heat conduction sleeve 5.

As shown in fig. 8 and 9, the detecting assembly includes symmetrically distributed pressure sensors 1204, the symmetrically distributed pressure sensors 1204 are all fixedly connected to the baffle 1201, the pressure sensors 1204 are annular, the pressure sensors 1204 are slidably connected with adjacent arc rods 1202, springs 1205 are disposed between the pressure sensors 1204 and the first scraping plates 1203, and when the geotechnical cloth 101 stacked on the heat conducting sleeve 5 increases, the resistance of the first scraping plates 1203 increases.

In the process that the geotechnical cloth 101 is transferred onto the right conveying platform 1 from the outer side surface of the heat conducting sleeve 5, in order to avoid directly pulling the geotechnical cloth 101 onto the right conveying platform 1, tearing occurs after the geotechnical cloth 101 is directly pulled, and the geotechnical cloth 101 is enabled to be adhered on the outer side of the heat conducting sleeve 5 in a large area, so that the integrity of the geotechnical cloth 101 is damaged, the following operation is performed: when the geotechnical cloth 101 moves out of the heat conducting sleeve 5, the upper side surface of the geotechnical cloth 101 clings to the left side surface of the roller 1302, and the distance from the roller 1302 distributed from top to bottom to the heat conducting sleeve 5 is gradually increased, so that the geotechnical cloth 101 is slowly far away from the heat conducting sleeve 5, the adhesion of the geotechnical cloth 101 on the heat conducting sleeve 5 is reduced, and the integrity of the geotechnical cloth 101 is improved.

When it is necessary to scrape off the residual geotextile 101 adhered to the outside of the heat conductive sleeve 5, the following operations are performed: as the heat conducting sleeve 5 continuously rotates, since the first scraper 1203 is tightly attached to the outer side surface of the heat conducting sleeve 5, when the residual geotechnical cloth 101 adhered to the outer side of the heat conducting sleeve 5 contacts with the first scraper 1203, the residual geotechnical cloth 101 adhered to the outer side of the heat conducting sleeve 5 is scraped by the first scraper 1203, so that the geotechnical cloth 101 is convenient to be continuously conveyed subsequently, the scraped residual geotechnical cloth 101 is guided by the baffle 1201 to be discharged through the discharge port 201, and an operator collects the discharged residual geotechnical cloth 101.

When the amount of the residual geotextile 101 attached to the outer side surface of the heat-conducting sleeve 5 changes, the position of the drum 1302 needs to be adjusted, taking the example that the amount of the residual geotextile 101 attached to the outer side surface of the heat-conducting sleeve 5 increases, the following operations are specifically performed: when geotechnical cloth 101 adhered to the outer side surface of heat conducting sleeve 5 increases, the resistance born by first scraping plate 1203 increases synchronously, first scraping plate 1203 drives two arc rods 1202 to slide, two springs 1205 are compressed, pressure detected by pressure sensor 1204 increases, pressure sensor 1204 sends detected values to a control terminal, the control terminal starts two second electric push rods 1303, two second electric push rods 1303 drive telescopic ends to drive the lower ends of two elastic plates 1301 to move leftwards, the inclination angle of elastic plates 1301 is gradually reduced, and two elastic plates 1301 reduce the included angle between geotechnical cloth 101 and heat conducting sleeve 5 through roller 1302, so that the adhesion quantity of geotechnical cloth 101 on heat conducting sleeve 5 is reduced.

Example 4: on the basis of embodiment 1, as shown in fig. 10-12, the dust removing device is further arranged on the conveying platform 1 on the right side, the dust removing device is used for cleaning impurities on geotechnical cloth 101 and comprises two telescopic frames 1401 which are symmetrically distributed around and are electrically connected with a control terminal, the two telescopic frames 1401 are arranged on the conveying platform 1 on the right side, a guide plate 1402 is fixedly connected to the upper side of the telescopic frames 1401, a dust suction box 1403 is fixedly connected between the two guide plates 1402, a through hole is formed in the lower side face of the dust suction box 1403, an exhaust fan 1404 electrically connected with the control terminal is arranged on the dust suction box 1403, and a scraping component for scraping the impurities on the dust suction box 1403 is arranged on the guide plate 1402.

As shown in fig. 10-12, the scraping component includes a servomotor 1501, the servomotor 1501 is fixedly connected to the upper surface of a front side guide plate 1402, the servomotor 1501 is electrically connected with a control terminal, an output shaft of the servomotor 1501 is fixedly connected with a threaded rod 1502, the threaded rod 1502 is in threaded connection with a rectangular frame 1503, a round rod is arranged at the lower part of the rectangular frame 1503, a U-shaped frame 1504 is slidingly connected with the lower part of the rectangular frame 1503, the U-shaped frame 1504 is slidingly matched with the guide plate 1402 and the dust box 1403, two tension springs 1505 which are symmetrically distributed around are fixedly connected between the U-shaped frame 1504 and the rectangular frame 1503, two aggregate shells 1506 which are symmetrically distributed around and are matched with the dust box 1403 are fixedly connected at the lower side of the U-shaped frame 1504, the U-shaped frame 1504 drives the two aggregate shells 1506 to move to scrape impurities on the lower surface of the dust box 1403, and the rectangular frame 1503 is provided with an aggregate component for cleaning impurities in the aggregate shells 1506.

As shown in fig. 11-13, the aggregate assembly includes symmetrically distributed racks 1601, the symmetrically distributed racks 1601 are fixedly connected to the rectangular frame 1503, the symmetrically distributed racks 1601 are respectively located at left and right sides of the rectangular frame 1503, a material receiving box 1602 matched with an adjacent aggregate housing 1506 is fixedly connected to the lower side of a guide plate 1402 through a support plate, the guide plate 1402 is rotatably connected with a rotating rod 1603 through the support plate, the aggregate housing 1506 is provided with two grooves which are symmetrically distributed left and right and are matched with the adjacent rotating rod 1603, the rotating rod 1603 is fixedly connected with three second scraping plates 1604 which are circumferentially and equidistantly distributed, the second scraping plates 1604 are matched with the adjacent aggregate housing 1506, the second scraping plates 1604 discharge impurities in the aggregate housing 1506, and a fourth gear 1605 matched with the adjacent racks 1601 is fixedly connected to the rotating rod 1603.

After the geotextile 101 is heated, a part of the fluff impurities will remain on the geotextile 101, so the residual fluff impurities on the geotextile 101 need to be removed, and the specific operation is as follows: in an initial state, the lower surface of the dust collection box 1403 is tightly attached to the geotechnical cloth 101, the control terminal starts the exhaust fan 1404, the exhaust fan 1404 generates suction force, dust impurities on the geotechnical cloth 101 are adsorbed on the lower surface of the dust collection box 1403 when the geotechnical cloth 101 passes through the lower side of the dust collection box 1403, dust and fluff impurities on the geotechnical cloth 101 are removed, subsequent treatment is facilitated, the fluff is adsorbed by the dust collection box 1403 for a long time, a through hole on the lower surface of the dust collection box 1403 is blocked by the fluff, suction force of the dust collection box 1403 is reduced, therefore, the impurities adsorbed on the lower surface of the dust collection box 1403 need to be cleaned regularly, and in the initial state, the U-shaped frame 1504 is positioned on the guide plate 1402 on the front side or the rear side, and the work of the dust collection box 1403 is not influenced, and the following operations are carried out: the control terminal starts two expansion brackets 1401, two expansion brackets 1401 drive deflector 1402 and suction box 1403 upwards move, after the suction box 1403 drives the part on it upwards move a section distance, control terminal stops expansion bracket 1401, suction box 1403 no longer upwards moves, control terminal starts servo motor 1501, servo motor 1501's output shaft drives threaded rod 1502 and rotates, threaded rod 1502 drives rectangular frame 1503 and removes, rectangular frame 1503 drives U-shaped frame 1504 and two casings that gathers materials 1506 through extension spring 1505 to the middle part of suction box 1403, rectangular frame 1503 drives two racks 1601 to the middle part of suction box 1403 simultaneously and removes.

Taking the case of the rearward movement of the aggregate housing 1506 as an example, when the aggregate housing 1506 contacts the lower surface of the dust box 1403, the aggregate housing 1506 scrapes off the impurities adsorbed on the lower surface of the dust box 1403, and the impurities fall into the rear aggregate housing 1506, when the two aggregate housings 1506 are located in the middle of the dust box 1403, the state is as shown in fig. 10 and 11, as the aggregate housing 1506 continues to move rearward, when the U-shaped frame 1504 moves above the rear guide plate 1402, the state is as shown in fig. 12, as the aggregate housing 1506 continues to move rearward, when the aggregate housing 1506 contacts the rear collecting box 1602, the aggregate housing 1506 is limited by the rear collecting box 1602 and cannot continue to move rearward, so that the U-shaped frame 1504 cannot continue to move rearward, at this time, the state is as shown in fig. 13, the rotating rod 1603 is caught in the two grooves of the aggregate housing 1506, the rack 1601 is meshed with the fourth gear 1605, as the rectangular frame 1503 continues to move backwards, the tension spring 1505 at the rear side is stretched, the tension spring 1505 at the front side is compressed, the rectangular frame 1503 drives the rack 1601 to move backwards, the rack 1601 drives the fourth gear 1605 to rotate, the fourth gear 1605 drives the second scraper 1604 to rotate through the rotating rod 1603 so as to push impurities accumulated in the aggregate shell 1506 into the receiving box 1602 at the rear side, when the rectangular frame 1503 moves to the rear end of the threaded rod 1502, the control terminal stops the servo motor 1501, the rectangular frame 1503 does not move any more, then the control terminal starts the telescopic frame 1401 to reduce the height of the dust box 1403, the dust box 1403 continues to adsorb impurities on the geotechnical cloth 101, and after a period of time, the steps are repeated continuously, so that the threaded rod 1502 reversely rotates to drive the rectangular frame 1503 to move forwards, and an operator periodically processes the impurities in the receiving box 1602.

The foregoing is merely illustrative of the present invention, and the present invention is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. The production device for preparing filament spun-bonded geotechnical cloth based on recycled textiles is characterized by comprising symmetrically distributed conveying platforms (1), wherein semicircular rings (2) are fixedly connected between the symmetrically distributed conveying platforms (1) through supporting legs, symmetrically distributed discs (3) are fixedly connected with the semicircular rings (2), one disc (3) is provided with a control terminal, the discs (3) are rotationally connected with rotating sleeves (4), the rotating sleeves (4) close to the control terminal are fixedly connected with first gears (401), the discs (3) close to the control terminal are fixedly connected with reducing motors (402) electrically connected with the control terminal, the output shafts of the reducing motors (402) are fixedly connected with second gears (403) meshed with the first gears (401), the symmetrically distributed rotating sleeves (4) are fixedly connected with heat conducting sleeves (5) through supporting plates, the symmetrically distributed discs (3) are fixedly connected with heat insulating covers (6), the heat insulating covers (6) are provided with equidistant and symmetrically distributed sliding rods (7), electric rollers (8) electrically connected with the control terminal are arranged between the symmetrically distributed sliding rods (7), the heat conducting sleeves (5) are wound with the heat conducting sleeves (101) and gradually reduce the distance between the heat conducting sleeves (101) and the heat conducting sleeves (101) along the direction of the heat conducting sleeves, the heat conducting sleeve (5) and the equidistant electric rollers (8) synchronously rotate and convey the geotechnical cloth (101), the geotechnical cloth (101) is extruded by the equidistant electric rollers (8) and gradually thinned, and the disc (3) is provided with a heating mechanism for heating the geotechnical cloth (101).

2. The production device for preparing filament spun-bonded geotextile based on recycled textiles according to claim 1, wherein the heating mechanism comprises a fixed shaft (901), the fixed shaft (901) is fixedly connected with a symmetrically distributed disc (3) through an L-shaped plate, a rotating sleeve (4) is rotationally connected with the fixed shaft (901), the fixed shaft (901) is fixedly connected with a fixed plate (902) positioned in a heat conducting sleeve (5), the fixed plate (902) is fixedly connected with a heat conducting shell (903) through a supporting plate, the heat conducting sleeve (5) is in sliding connection with the heat conducting shell (903), the fixed plate (902) is fixedly connected with a water pump (904) electrically connected with a control terminal through the supporting plate, the water pump (904) is communicated with a heater (905) electrically connected with the control terminal, the heater (905) is communicated with the middle part of the heat conducting shell (903) through a water pipe, a blocking plate (906) which is symmetrically distributed is slidingly connected with the heat conducting shell (903), the blocking plate (906) is gradually thickened from one side close to the heat conducting shell (905) to the side of the heat conducting sleeve (905), the blocking plate (906) is provided with uniformly distributed water inlet holes (61), the blocking plate (903) is fixedly connected with the heat conducting plate (906) through a water pipe, the water inlet (907) is communicated with the heat conducting pipe (906) and is communicated with the heat conducting shell (906), the arc-shaped pipe (907) is communicated with the adjacent communication groove (9062), the arc-shaped pipe (907) is communicated with the water pump (904) through the hose (908), water is filled in the heat conduction shell (903), the arc-shaped pipe (907) and the hose (908), and the fixing plate (902) is provided with an adjusting part for adjusting the heated area of the heat conduction shell (903).

3. The production device for preparing filament spun-bonded geotechnical cloth based on recycled textiles according to claim 2, wherein the adjusting component comprises a first electric push rod (1001), the first electric push rod (1001) is fixedly connected to a fixing plate (902), the first electric push rod (1001) is electrically connected with a control terminal, a U-shaped plate (1002) is fixedly connected to a telescopic end of the first electric push rod (1001), a connecting plate (1003) is fixedly connected to an arc-shaped pipe (907) close to the same interception plate (906), and symmetrically distributed connecting plates (1003) are matched with the U-shaped plate (1002).

4. The production device for preparing filament spun-bonded geotechnical cloth based on recycled textiles according to claim 1, further comprising an adjusting mechanism for adjusting extrusion thickness of geotechnical cloth (101), wherein the adjusting mechanism is arranged on the heat insulation cover (6), the adjusting mechanism comprises arc gear rings (1101) which are symmetrically distributed, the arc gear rings (1101) are provided with inclined sliding grooves which are distributed at equal intervals and are in sliding connection with adjacent sliding rods (7), the inclined sliding grooves of the arc gear rings (1101) deflect for a certain angle relative to the adjacent sliding rods (7), the sliding rods (7) are in sliding connection with the heat insulation cover (6), a double-shaft motor (1102) which is electrically connected with a control terminal is fixedly connected with the heat insulation cover (6), and two output shafts of the double-shaft motor (1102) are fixedly connected with third gears (1103) which are meshed with the adjacent arc gear rings (1101).

5. The production device for preparing filament spun-bonded geotechnical cloth based on recycled textiles according to claim 1, further comprising a cleaning mechanism, wherein the cleaning mechanism is arranged on the semicircular ring (2) and used for cleaning impurities adhered to the heat conducting sleeve (5), the cleaning mechanism comprises a baffle (1201), the baffle (1201) is fixedly connected to the semicircular ring (2), the semicircular ring (2) is provided with a discharge hole (201) matched with the baffle (1201), the baffle (1201) is slidably connected with an arc-shaped rod (1202), the arc-shaped rod (1202) is fixedly connected with a first scraping plate (1203) matched with the heat conducting sleeve (5), and a conveying platform (1) close to the discharge side of the geotechnical cloth (101) is provided with a stretching component used for reducing the adhesion amount of the geotechnical cloth (101) on the heat conducting sleeve (5).

6. The production device for preparing filament spun-bonded geotextile based on recycled textiles according to claim 5, wherein the stretching component comprises symmetrically-distributed elastic plates (1301), one ends of the symmetrically-distributed elastic plates (1301) are fixedly connected to the heat insulation cover (6), rollers (1302) are arranged between the symmetrically-distributed elastic plates (1301), the conveying platform (1) is fixedly connected with second electric pushing rods (1303) which are symmetrically distributed and are electrically connected with the control terminal, the other ends of the elastic plates (1301) are fixedly connected with telescopic ends of adjacent second electric pushing rods (1303), and the baffle (1201) is provided with a detection component for detecting residual geotextile (101) on the heat conduction sleeve (5).

7. The production device for preparing filament spun-bonded geotextile based on recycled textiles according to claim 6, wherein the detection assembly comprises symmetrically-distributed pressure sensors (1204), the symmetrically-distributed pressure sensors (1204) are fixedly connected to the baffle plate (1201), the pressure sensors (1204) are slidably connected with adjacent arc rods (1202), and a spring (1205) is arranged between the pressure sensors (1204) and the first scraping plate (1203).

8. The production device for preparing filament spun-bonded geotechnical cloth based on recycled textiles according to claim 1, further comprising a dust removing mechanism, wherein the dust removing mechanism is arranged on a conveying platform (1) close to the discharging side of the geotechnical cloth (101), the dust removing mechanism is used for cleaning impurities on the geotechnical cloth (101), the dust removing mechanism comprises telescopic frames (1401) which are symmetrically distributed and are electrically connected with a control terminal, the telescopic frames (1401) which are symmetrically distributed are arranged on the conveying platform (1) on one side, the telescopic frames (1401) are fixedly connected with guide plates (1402), the symmetrically distributed guide plates (1402) are fixedly connected with dust suction boxes (1403), through holes are formed in the side, close to the geotechnical cloth (101), of the dust suction boxes (1403), exhaust fans (1404) which are electrically connected with the control terminal are arranged on the guide plates (1402), and scraping components used for scraping the impurities on the dust suction boxes (1403).

9. The production device for preparing filament spun-bonded geotechnical cloth based on recycled textiles according to claim 8, wherein the scraping component comprises a servo motor (1501), the servo motor (1501) is fixedly connected to a guide plate (1402) on one side, the servo motor (1501) is electrically connected with a control terminal, an output shaft of the servo motor (1501) is fixedly connected with a threaded rod (1502), the threaded rod (1502) is in threaded connection with a rectangular frame (1503), the rectangular frame (1503) is in sliding connection with a U-shaped frame (1504), the U-shaped frame (1504) is in sliding fit with the guide plate (1402) and the dust box (1403), symmetrically distributed tension springs (1505) are fixedly connected between the U-shaped frame (1504) and the rectangular frame (1503), the U-shaped frame (1504) is fixedly connected with a symmetrically distributed aggregate shell (1506) matched with the dust box (1403), and the rectangular frame (1503) is provided with an aggregate assembly for cleaning impurities in the aggregate shell (1506).

10. The production device for preparing filament spun-bonded geotechnical cloth based on recycled textiles according to claim 9, wherein the aggregate component comprises symmetrically-distributed racks (1601), the symmetrically-distributed racks (1601) are fixedly connected to a rectangular frame (1503), a receiving box (1602) matched with an adjacent aggregate shell (1506) is fixedly connected to a guide plate (1402) through a supporting plate, a rotating rod (1603) is rotatably connected to the guide plate (1402) through the supporting plate, the aggregate shell (1506) is provided with grooves symmetrically-distributed and matched with the adjacent rotating rod (1603), second scrapers (1604) distributed at equal intervals in the circumferential direction are fixedly connected to the rotating rod (1603), the second scrapers (1604) are matched with the adjacent aggregate shell (1506), and a fourth gear (1605) matched with the adjacent racks (1601) is fixedly connected to the rotating rod (1603).

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