CN220011574U - Geomembrane feeding mechanism with deviation correcting function - Google Patents

Abstract

The utility model discloses a geomembrane feeding mechanism with a deviation correcting function, which comprises: the upper end of the support frame is provided with a guide rail extending forwards and backwards; the top of the feeding frame is provided with two rollers extending back and forth at intervals left and right, and the bottom of the feeding frame is rotatably provided with rollers and is arranged on the guide rail through the rollers; and the driving assembly is in transmission connection with the roller and is used for driving the roller to rotate so as to walk along the extending direction of the guide rail. According to the utility model, the feeding frame is arranged, the rollers are arranged at the bottom of the feeding frame, the feeding frame is arranged on the supporting frame by utilizing the rollers, and the driving assembly is arranged to drive the rollers to rotate, so that the rollers can be driven to roll along the extending direction of the guide rail of the supporting frame, the feeding frame is driven to move back and forth, namely, the cylindrical geomembrane on the feeding frame is driven to move back and forth, so that the correction of the cylindrical geomembrane is realized, the cylindrical geomembrane does not need to be manually pushed to slide on the roller of the feeding frame for correction, time and labor are saved, and the operation is convenient.

Description

Geomembrane feeding mechanism with deviation correcting function

Technical Field

The utility model relates to the technical field of geotechnical material production and processing equipment, in particular to a geomembrane feeding mechanism with a deviation correcting function.

Background

After the geomembrane is initially produced, the geomembrane is rolled into a cylindrical shape for convenient transportation and storage, and is then unfolded and fed when other working procedures (such as roughening the surface of the geomembrane) are carried out, and the geomembrane rolled into the cylindrical shape is placed on two rollers and is then slowly pulled out, unfolded and fed for subsequent processing due to the fact that the geomembrane is rolled into the cylindrical shape and is usually provided with a feeding mechanism provided with rollers. The existing feeding mechanism has the following problems: when the cylindrical geomembrane is hung on two rollers of the feeding mechanism by using the hanging device, the geomembrane is not aligned with the processing area of the subsequent processing device (the two ends of the length direction of the cylindrical geomembrane are aligned with the processing area of the subsequent processing device), so that the cylindrical geomembrane is required to be manually pushed along the length direction of the rollers to rectify the deviation, but the geomembrane is generally longer and heavier after being rolled into a cylindrical shape, so that the geomembrane is more laborious to push, more difficult to push, time-consuming and laborious and low in efficiency.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the geomembrane feeding mechanism with the deviation correcting function is time-saving and labor-saving.

According to the embodiment of the utility model, the geomembrane feeding mechanism with the deviation correcting function comprises:

the upper end of the support frame is provided with a guide rail extending forwards and backwards;

the feeding frame is provided with two rollers extending forwards and backwards at left and right intervals at the top, and rollers are rotatably arranged at the bottom of the feeding frame and are arranged on the guide rail through the rollers;

and the driving assembly is in transmission connection with the roller and is used for driving the roller to rotate so as to walk along the extending direction of the guide rail.

The geomembrane feeding mechanism with the deviation correcting function provided by the embodiment of the utility model has at least the following beneficial effects:

through setting up the charging frame and setting up the gyro wheel at the charging frame bottom, utilize the gyro wheel to install the charging frame in the support frame, again through setting up drive assembly with the drive gyro wheel rotation, thereby can drive the gyro wheel and roll along the extending direction of the guide rail of support frame, drive the charging frame and reciprocate, drive the geomembrane of the tube-shape on the charging frame promptly and reciprocate, so as to realize rectifying of the geomembrane of tube-shape, need not the manual work to promote the geomembrane of tube-shape and make it slide in order to rectify on the cylinder of charging frame, labour saving and time saving, convenient operation.

According to some embodiments of the utility model, the supporting frame is provided with a limiting structure for preventing the roller from being separated from the guide rail along the extending direction of the guide rail.

According to some embodiments of the utility model, the driving assembly is provided with a hand-operated wheel, and the hand-operated wheel is rotatably arranged on the feeding frame and is in transmission connection with the roller, and the roller can be driven to rotate by rotating the hand-operated wheel.

According to some embodiments of the utility model, the driving assembly is provided with a transmission case, the transmission case is mounted at the front end of the feeding frame, the transmission case is provided with an input shaft extending back and forth and an output shaft extending left and right, the output shaft is driven to rotate by the rotation of the input shaft, the output shaft is in transmission connection with the roller, and the hand crank wheel is coaxially and fixedly arranged at the front end of the input shaft and is positioned outside the transmission case.

According to some embodiments of the utility model, a worm and a worm wheel are meshed with each other, the worm is coaxially arranged on the input shaft, and the worm wheel is coaxially arranged on the output shaft.

According to some embodiments of the utility model, at least two groups of rollers are arranged at intervals in front and back, one group of rollers comprises at least two rollers which are symmetrically arranged left and right, the rollers in the same group are fixedly connected through a connecting shaft, the connecting shaft is rotationally arranged at the bottom of the feeding frame, a first chain wheel is fixedly arranged on the connecting shaft positioned at the front end of the feeding frame, a second chain wheel is fixedly arranged on the output shaft, and the second chain wheel is in transmission connection with the first chain wheel through a chain.

According to some embodiments of the utility model, the lifting frame is arranged on the feeding frame, the lifting frame can vertically adjust the position relative to the feeding frame, and the lifting frame and the roller wheel are alternately abutted against the upper surface of the supporting frame.

According to some embodiments of the utility model, the lifting frame comprises a supporting base and an adjusting rod, the supporting base is used for propping against the upper surface of the supporting frame, the adjusting rod vertically slides through the feeding frame, and the adjusting rod is in threaded connection with adjusting nuts on the upper side and the lower side of the feeding frame.

According to some embodiments of the utility model, an embedding groove is formed at the upper end of the supporting frame, and the embedding groove is used for embedding the lifting frame so as to limit the lifting frame forwards and backwards.

According to some embodiments of the utility model, two limiting plates are arranged at left and right intervals at the bottom of the lifting frame and are used for being matched with the supporting frame to limit the lifting frame left and right when the lifting frame is embedded into the caulking groove.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The utility model is further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a schematic view of a mounting structure of an embodiment of the present utility model;

FIG. 2 is an exploded view of an installation state of an embodiment of the present utility model;

FIG. 3 is a schematic view of a loading rack and a driving assembly according to an embodiment of the present utility model;

fig. 4 is a schematic diagram of the transmission of the roller according to the embodiment of the utility model.

Reference numerals:

the device comprises a supporting frame 100, a caulking groove 101, a guide rail 110, a limiting block 120 and a bump 130;

the feeding frame 200, the supporting rod 201, the mounting seat 202, the roller 210, the roller 220, the connecting shaft 230 and the first sprocket 240;

the driving assembly 300, the hand-operated wheel 310, the transmission box 320, the input shaft 330, the output shaft 340, the worm 350, the worm wheel 360, the second sprocket 370 and the chain 380;

the lifting frame 400, the limiting plate 401, the supporting base 410, the adjusting rod 420 and the adjusting nut 430.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

In the description of the present utility model, it should be understood that the direction or positional relationship indicated with respect to the description of the orientation, such as up, down, etc., is based on the direction or positional relationship shown in the drawings, is merely for convenience of describing the present utility model and simplifying the description, and does not indicate or imply that the apparatus or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, plural means two or more. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present utility model, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present utility model can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.

Referring to fig. 1 and 2, a geomembrane feeding mechanism with deviation correcting function according to an embodiment of the present utility model includes: the device comprises a supporting frame 100, a feeding frame 200 and a driving assembly 300.

The upper end of the support 100 is provided with a guide rail 110 extending back and forth.

The top of the feeding frame 200 is provided with two rollers 210 extending back and forth at intervals left and right for placing cylindrical geomembranes, the two rollers 210 can be rotatably mounted on the feeding frame 200 around the axis of the rollers, so that friction force is reduced when the geomembranes are pulled and unfolded, and the bottom of the feeding frame 200 is rotatably provided with rollers 220 and mounted on the guide rail 110 through the rollers 220. Specifically, the peripheral wall of the roller 220 is recessed inward for the insertion of the guide rail 110.

The driving assembly 300 is in transmission connection with the roller 220, and is used for driving the roller 220 to rotate so as to walk along the extending direction of the guide rail 110, specifically, the peripheral wall of the roller 220 abuts against the upper surface of the guide rail 110, when the driving assembly 300 drives the roller 220 to rotate, the roller 220 can walk along the extending direction of the guide rail 110 by virtue of friction force, so that the feeding frame 200 is driven to move back and forth, and the cylindrical geomembrane placed on the feeding frame 200 is aligned with the processing area of subsequent processing equipment, so that correction is realized.

The geomembrane feeding mechanism with deviation correcting function of this embodiment is through setting up the material loading frame 200 and setting up gyro wheel 220 in material loading frame 200 bottom, utilize gyro wheel 220 to install material loading frame 200 in support frame 100, again through setting up drive assembly 300 in order to drive gyro wheel 220 rotation, thereby can drive gyro wheel 220 along the extending direction of the guide rail 110 of support frame 100 and roll, drive material loading frame 200 back-and-forth movement, drive the tubular geomembrane on the material loading frame 200 and reciprocate, in order to realize the deviation correcting of tubular geomembrane, need not the manual work to promote tubular geomembrane and make it slide on the cylinder 210 of material loading frame 200 in order to rectify, labour saving and time saving, convenient operation.

In some specific embodiments, in order to prevent the rolled diameter of the cylindrical geomembrane from being reduced during the feeding process, a supporting rod 201 extending back and forth is further provided on the supporting frame 100 between the two corresponding rollers 210, so as to support the cylindrical geomembrane after the rolled diameter of the cylindrical geomembrane is reduced.

Referring to fig. 1 and 2, it can be understood that the supporting frame 100 is provided with a limiting structure for preventing the roller 220 from being separated from the guide rail 110 along the extending direction of the guide rail 110, i.e. limiting the forward and backward rolling travel of the roller 220, so that the safety of the feeding frame 200 during forward and backward movement adjustment can be improved. In this embodiment, the limiting structure is provided with two sets of limiting blocks 120, wherein one set of limiting blocks 120 is used for abutting against the roller 220 to limit the forward rolling travel of the roller 220, and the other set of limiting blocks 120 is used for abutting against the roller 220 to limit the backward rolling travel of the roller 220.

Referring to fig. 1 and 3, it can be understood that the driving assembly 300 is provided with a hand wheel 310, the hand wheel 310 is rotatably arranged on the feeding frame 200 and is in transmission connection with the roller 220, the roller 220 can be driven to rotate by rotating the hand wheel 310, in particular, a hand handle is arranged on the hand wheel 310 to provide a better force application position for an operator, and through the arrangement, the manual driving roller 220 can be rotated, so that the cost is lower and faults are not easy to occur relative to electric driving.

Referring to fig. 1 and 3, it can be understood that the driving assembly 300 is provided with a transmission case 320, the transmission case 320 is mounted at the front end of the feeding frame 200, the transmission case 320 is provided with an input shaft 330 extending back and forth and an output shaft 340 extending left and right, the input shaft 330 is matched with the output shaft 340, the output shaft 340 is driven to rotate by rotating the input shaft 330, the output shaft 340 is in transmission connection with the roller 220, the rotation of the output shaft 340 can drive the roller 220 to rotate, the hand wheel 310 is coaxially fixed at the front end of the input shaft 330 and is positioned at the outer side of the transmission case 320, the rotation of the output shaft 330 can be driven by driving the roller 220 to rotate, in this embodiment, the transmission case 320 is arranged at the front end of the feeding frame 200, and the hand wheel 310 is arranged at the front end of the input shaft 330 by arranging the transmission case 320, so that when an operator rotates the hand wheel 310 to drive the roller 220 to roll forward, the operator can operate at the front end of the feeding frame 200, and does not need to walk forward along with the feeding frame 200, the operation is convenient, and the whole structure is quite reasonable.

Referring to fig. 3 and 4, it can be understood that the worm 350 and the worm wheel 360 meshed with each other are disposed in the transmission case 320, the worm 350 is coaxially disposed on the input shaft 330, the worm wheel 360 is coaxially disposed on the output shaft 340, and the matching of the input shaft 330 and the output shaft 340 is realized by the matching of the worm wheel 360 and the worm 350, and the embodiment has the advantage that, compared with the bevel gear matching, the matching of the worm wheel 360 and the worm 350 has a self-locking function, and when the hand wheel 310 is not operated, even if the feeding frame 200 is subjected to other external forces, the roller 220 will not rotate at will. In addition, the worm wheel 360 and the worm 350 are matched, so that the speed reduction function is realized, and the adjustment is more accurate.

Referring to fig. 1 and 3, it can be understood that, in order to make the feeding frame 200 have a stable supporting structure, at least two sets of rollers 220 are disposed at intervals in front and back, and one set of rollers 220 includes at least two rollers 220 symmetrically disposed in left and right directions; the same group of rollers 220 are fixedly connected through the connecting shaft 230, the connecting shaft 230 is rotationally arranged at the bottom of the feeding frame 200 through a bearing, the connecting shaft 230 at the front end of the feeding frame 200 is fixedly provided with the first sprocket 240, the output shaft 340 is fixedly provided with the second sprocket 370, the second sprocket 370 is in transmission connection with the first sprocket 240 through the chain 380, the transmission is stable and reliable, and the slipping phenomenon can not occur.

In some specific embodiments, considering that the adjustment stroke is generally not too large when feeding and correcting, in order to save materials, the guide rails 110 are arranged in sections in this embodiment, and each roller 220 is correspondingly provided with a section of guide rail 110.

Referring to fig. 1 to 3, it can be understood that the geomembrane feeding mechanism with deviation correcting function according to the embodiment of the present utility model further includes a lifting frame 400 disposed on the feeding frame 200, where the lifting frame 400 can vertically adjust a position relative to the feeding frame 200, and make the lifting frame 400 and the roller 220 alternately contact with the upper surface of the support frame 100, and it should be noted that the contact between the roller 220 and the upper surface of the support frame 100 refers to the contact between the roller 220 and the upper surface of the guide rail 110; specifically, by adjusting the lifting frame 400 downward relative to the feeding frame 200, the lifting frame 400 can be supported against the upper surface of the supporting frame 100, the feeding frame 200 can be lifted up when the lifting frame is adjusted downward, the rollers 220 are separated from the guide rail 110, and then the feeding frame 200 can be dropped down again by adjusting the lifting frame 400 in the opposite direction, so that the rollers 220 are supported on the guide rail 110.

Specifically, in this embodiment, at least four lifting frames 400 are provided, and at least one lifting frame 400 is provided at each of four corners of the feeding frame 200.

Referring to fig. 1 to 3, it can be understood that the lifting frame 400 includes a supporting base 410 and an adjusting rod 420, the adjusting rod 420 is fixed at the upper end of the supporting base 410, the supporting base 410 is used for propping against the upper surface of the supporting frame 100, the adjusting rod 420 vertically slides through the upper and lower sides of the upper material frame 200, the adjusting rod 420 is connected with adjusting nuts 430 in a threaded manner, specifically, in this embodiment, the mounting base 202 is provided on the side wall of the upper material frame 200 corresponding to the adjusting rod 420, the adjusting rod 420 vertically slides through the mounting base 202, the adjusting rod 420 is connected with adjusting nuts 430 in a threaded manner on the upper and lower sides of the mounting base 202, respectively, and by screwing the adjusting nuts 430 on the upper and lower sides of the mounting base, the vertical position of the lifting frame 400 relative to the upper material frame 200 can be adjusted, and compared with the adjustment in an electric drive or hydraulic drive manner, the cost of this embodiment is lower.

Referring to fig. 1 to 3, it can be understood that the upper end of the supporting frame 100 is provided with a caulking groove 101 for embedding the supporting base 410 of the lifting frame 400, so as to limit the lifting frame 400 in front and back, thereby preventing the feeding frame 200 from shaking in front and back when the feeding frame 200 is lifted by the lifting frame 400, and reducing the potential safety hazard.

In this embodiment, two protrusions 130 are disposed on the upper surface of the support frame 100 at intervals to form the caulking groove 101, which is convenient for processing and does not reduce the structural strength of the support frame 100. In addition, during loading, in order to avoid interference between the supporting frame 100 and the bump 130, the lifting frame 400 needs to be adjusted to a position where the bump 130 avoids the forward and backward movement path of the lifting frame 400.

Referring to fig. 1 to 3, it can be understood that two limiting plates 401 are disposed at left and right intervals at the bottom of the lifting frame 400, and are used to limit the lifting frame 400 left and right in cooperation with the supporting frame 100 when the supporting base 410 of the lifting frame 400 is embedded in the caulking groove 101, so that when the lifting frame 400 is used to lift the feeding frame 200, the feeding frame 200 can be prevented from shaking left and right, and potential safety hazards are reduced. It can be understood that the supporting frame 100 is formed by welding a plurality of rod members, and the two limiting plates 401 are used for being matched with the rod members on the upper side of the supporting frame 100 to limit the lifting frame 400 left and right, that is, the rod members on the upper side of the supporting frame 100 can be embedded between the two limiting plates 401 to limit the lifting frame 400 left and right.

The embodiments of the present utility model have been described in detail with reference to the accompanying drawings, but the present utility model is not limited to the above embodiments, and various changes can be made within the knowledge of one of ordinary skill in the art without departing from the spirit of the present utility model.

Claims (10)

1. Geomembrane feed mechanism with function of rectifying, its characterized in that includes:

the upper end of the support frame (100) is provided with a guide rail (110) extending forwards and backwards;

the feeding frame (200) is provided with two rollers (210) extending forwards and backwards at intervals on the left and right of the top, and rollers (220) are rotatably arranged at the bottom of the feeding frame (200) and are arranged on the guide rail (110) through the rollers (220);

and the driving assembly (300) is in transmission connection with the roller (220) and is used for driving the roller (220) to rotate so as to walk along the extending direction of the guide rail (110).

2. The geomembrane feeding mechanism with deviation correcting function according to claim 1, wherein: the support frame (100) is provided with a limiting structure for preventing the roller (220) from being separated from the guide rail (110) along the extending direction of the guide rail (110).

3. The geomembrane feeding mechanism with deviation correcting function according to claim 1, wherein: the driving assembly (300) is provided with a hand-operated wheel (310), the hand-operated wheel (310) is rotationally arranged on the feeding frame (200) and is in transmission connection with the roller (220), and the roller (220) can be driven to rotate by rotating the hand-operated wheel (310).

4. A geomembrane feeding mechanism with deviation correcting function according to claim 3, characterized in that: the driving assembly (300) is provided with a transmission box (320), the transmission box (320) is installed at the front end of the feeding frame (200), the transmission box (320) is provided with an input shaft (330) extending front and back and an output shaft (340) extending left and right, the output shaft (340) is driven to rotate by the rotation of the input shaft (330), the output shaft (340) is in transmission connection with the roller (220), and the hand-operated wheel (310) is coaxially fixed at the front end of the input shaft (330) and is positioned at the outer side of the transmission box (320).

5. The geomembrane feeding mechanism with deviation correcting function according to claim 4, wherein: the transmission case (320) is internally provided with a worm (350) and a worm wheel (360) which are meshed, the worm (350) is coaxially arranged on the input shaft (330), and the worm wheel (360) is coaxially arranged on the output shaft (340).

6. The geomembrane feeding mechanism with deviation correcting function according to claim 4, wherein: the novel automatic feeding device is characterized in that at least two groups of rollers (220) are arranged at intervals in front and back, one group of rollers (220) comprises at least two rollers (220) which are symmetrically arranged left and right, the rollers (220) are fixedly connected with one another through a connecting shaft (230), the connecting shaft (230) is rotationally arranged at the bottom of the feeding frame (200), a first chain wheel (240) is fixedly arranged on the connecting shaft (230) at the front end of the feeding frame (200), a second chain wheel (370) is fixedly arranged on the output shaft (340), and the second chain wheel (370) is in transmission connection with the first chain wheel (240) through a chain (380).

7. The geomembrane feeding mechanism with deviation correcting function according to claim 1, wherein: the lifting frame (400) is arranged on the feeding frame (200), the lifting frame (400) can vertically adjust the position relative to the feeding frame (200), and the lifting frame (400) and the roller (220) are alternately abutted against the upper surface of the supporting frame (100).

8. The geomembrane feeding mechanism with deviation correcting function according to claim 7, wherein: the lifting frame (400) comprises a supporting base (410) and an adjusting rod (420), the supporting base (410) is used for being in contact with the upper surface of the supporting frame (100) in a propping mode, the adjusting rod (420) vertically slides to penetrate through the feeding frame (200), and the adjusting rod (420) is in threaded connection with adjusting nuts (430) on the upper side and the lower side of the feeding frame (200).

9. The geomembrane feeding mechanism with deviation correcting function according to claim 7, wherein: the upper end of the supporting frame (100) is provided with an embedding groove (101) for embedding the lifting frame (400) so as to limit the lifting frame (400) forwards and backwards.

10. The geomembrane feeding mechanism with deviation correcting function according to claim 9, wherein: the lifting frame (400) is characterized in that two limiting plates (401) are arranged at left and right sides of the bottom of the lifting frame (400) at intervals and are used for being matched with the supporting frame (100) to limit the lifting frame (400) left and right when the lifting frame (400) is embedded into the caulking groove (101).