CN212158149U - Full-automatic feeding system is retrieved to metallic copper for power transmission - Google Patents

Abstract

The utility model discloses a full-automatic feeding system is retrieved to metallic copper for power transmission, including installing roll-over stand, the board that turns over and the telescopic link in fire door one side, a storage frame has been placed to one side that the fire door was kept away from to the roll-over stand, and this storage frame is used for stacking the copper, install grudging post, guide rail, clamping jaw and sucking disc between roll-over stand and the fire door, the guide rail is installed on the grudging post and is arranged along fire door, roll-over stand and storage frame direction, install a frame on the guide rail, an electric block is installed respectively at the frame both ends, clamping jaw and sucking disc are installed respectively on the lifting rope of these two electric blocks, just the sucking disc is connected with a vacuum tube through a vacuum tube, and the interval of these two electric blocks equals with the interval of storage fire door to roll-over stand to the interval of roll-over stand equals. The utility model discloses a full automatic feeding of copper has reduced staff's intensity of labour, has improved work efficiency.

Description

Full-automatic feeding system is retrieved to metallic copper for power transmission

Technical Field

The utility model relates to a full-automatic feeding system is retrieved to copper metal for power transmission belongs to cable processing technology field.

Background

The copper material smelting process in the power cable is indispensable, and the feeding of the smelting furnace is one of the key operations influencing the smelting process. At present, in the production process of a secondary copper smelting and processing enterprise, the feeding of metallurgical furnace materials is generally carried out in a manual or movable mechanical feeding mode. However, due to the characteristics of large volume of the smelting furnace, high working temperature, large feeding amount and the like, the traditional feeding has the problems of low production efficiency, high labor intensity, severe working environment, serious pollution and the like. Moreover, with the shortage of labor force and the increase of wage level, the labor cost is continuously increased, and the replacement of manual operation by mechanical automation is a problem to be solved urgently faced by domestic smelting plants.

Disclosure of Invention

The utility model aims at providing a full automatic feeding system is retrieved to metallic copper for power transmission, this full automatic feeding system is retrieved to metallic copper when not only having solved artifical input copper among the prior art, need repeated transport copper, the problem that intensity of labour is big has still solved staff's transport input inefficiency, problem that production efficiency is low.

In order to achieve the above purpose, the utility model adopts the technical scheme that: a full-automatic feeding system for recovering metal copper for power transmission comprises a turning frame, a turning plate and a telescopic rod, wherein the turning frame is installed on one side of a furnace opening, one end, close to the furnace opening, of the turning plate is hinged to the turning frame, the other end of the turning plate is hinged to one end of the telescopic rod, the other end of the telescopic rod is hinged to the bottom of the turning frame, a baffle is installed on the top surface of the turning plate and located on one side, close to the furnace opening, of the turning plate, a storage rack is placed on one side, far away from the furnace opening, of the turning frame, and;

the telescopic rod comprises a bottom rod and a worm inserted in the bottom rod, a telescopic motor is mounted on the bottom rod, a worm wheel is mounted on an output shaft of the telescopic motor, and a abdicating hole for meshing the worm wheel and the worm is formed in the bottom rod;

the furnace mouth, the turning frame and the storage rack are arranged in parallel, the guide rail is arranged on the vertical frame and is distributed along the direction of the furnace mouth, the turning frame and the storage rack, the guide rail is provided with a frame, two ends of the frame are respectively provided with an electric hoist, the clamping jaw and the suction disk are respectively arranged on lifting ropes of the two electric hoists, the suction disk is connected with a vacuum-pumping pump through a vacuum-pumping pipe, and the distance between the two electric hoists is equal to the distance between the furnace mouth and the turning frame and equal to the distance between the turning frame and the storage rack;

the bottom of the rack is provided with at least four sliding blocks, the bottom of each sliding block is rotatably provided with a walking wheel which is in contact with the guide rail, the rack is also provided with a walking motor, and an output shaft of the walking motor is inserted in the axis of the walking wheel;

the clamping jaw and the sucker are respectively arranged at the bottom ends of the first pull rod and the second pull rod;

the clamping jaw further comprises a clamping plate, a rotating plate and an air cylinder, the clamping plate is connected with the first pull rod, the rotating plate is hinged to the tail end of the clamping plate, a driving plate is further connected to the hinged end of the rotating plate, the air cylinder is hinged to the first pull rod, and a piston rod of the air cylinder is hinged to the driving plate.

The further improved scheme in the technical scheme is as follows:

1. in the scheme, the guide rail is provided with a guide strip, and the peripheral wall of the travelling wheel is provided with an annular groove for embedding the guide strip.

2. In the above scheme, the number of the walking wheels is four, the number of the walking motors is two, and the two walking wheels are respectively positioned on the output shafts at two ends of one walking motor.

3. In the above scheme, two ends of the guide rail are provided with a limiting block corresponding to the sliding block.

4. In the above scheme, a silica gel pad is installed on one side of the limiting block, which is close to the sliding block.

5. In the above scheme, the silica gel pad is connected with the limiting block through a screw rod.

6. In the above scheme, the number of the first pull rods is 2, an installation plate is arranged between the two first pull rods, and the clamping jaw is arranged on the installation plate.

7. In the above scheme, the number of the second pull rods is 2, the bottom ends of the two second pull rods are connected with a carrier plate, and the suckers are installed on the bottom surface of the carrier plate.

8. In the above scheme, the number of the suckers is 4.

Because of above-mentioned technical scheme's application, compared with the prior art, the utility model have the following advantage:

1. the utility model discloses full-automatic feeding system is retrieved to metallic copper for power transmission, it is through the snatching of clamping jaw and sucking disc to the copper, the cooperation turns over the automatic upset function of board to the copper, makes the sucking disc constantly can transport the copper to turning over the board on, and the clamping jaw can transport the copper to fire door department to realize the full-automatic feeding of copper, not only can reduce staff's intensity of labour, can also improve the efficiency that the steel sheet was put in; simultaneously, clamping jaw and sucking disc are all installed in the frame, and the interval of control clamping jaw and sucking disc is the same with the spacing of fire door to roll-over stand, roll-over stand to storage frame, and synchronous motion's clamping jaw and frame can carry out getting of copper simultaneously and work of throwing of putting of copper is carried out simultaneously, further shortens the time of copper material loading.

2. The utility model discloses full-automatic feeding system of metal copper recovery for power transmission, it is through installing flexible motor and worm wheel on the sill bar, the worm that the cooperation was pegged graft in the sill bar drives the worm and reciprocates to slide in the cavity in the sill bar, has both realized the flexible function of telescopic link, and the supplementary board that turns over has accomplished the full-automatic upset of copper; the walking motor drives the walking wheel at the bottom of the rack to rotate, so that the rack is integrally arranged on the guide rail; it becomes ascending motion of vertical side through the setting of first sleeve, second sleeve and first pull rod, second pull rod, direction clamping jaw and sucking disc, stabilizes the effect of snatching of clamping jaw and sucking disc to the copper.

3. The utility model discloses full-automatic feeding system of metal copper recovery for power transmission, it is through the cooperation of annular groove on gib block and the walking wheel, the displacement of direction frame on the guide rail, avoid the frame to break away from the guide rail; the limit of displacement of the rack on the guide rail is limited by the arrangement of the limit block and the silica gel pad, so that the motion stability of the rack is further improved; the limit position of the silica gel pad on the frame is adjusted by installing the silica gel pad through the screw rod.

Drawings

FIG. 1 is a schematic view of the overall structure of the copper metal recovery full-automatic feeding system for power transmission of the present invention;

FIG. 2 is a schematic structural view of the turnover mechanism of the present invention;

FIG. 3 is a cross-sectional view of the telescoping rod portion of the present invention;

FIG. 4 is a schematic structural view of a guide rail portion;

figure 5 is a schematic view of the jaw portion.

In the following figures: 1. a furnace mouth; 21. a roll-over stand; 22. turning over a plate; 23. a telescopic rod; 24. a baffle plate; 25. a worm; 26. a telescopic motor; 27. a worm gear; 201. a bottom bar; 202. a hole of abdication; 3. a storage rack; 41. A guide rail; 42. a clamping jaw; 43. a suction cup; 44. an electric hoist; 45. a splint; 46. a rotating plate; 47. a cylinder; 48. a drive plate; 401. erecting a frame; 402. A vacuum pump is pumped; 403. a guide strip; 404. a limiting block; 405. a silica gel pad; 406. a screw; 5. a frame; 51. a first sleeve; 52. a second sleeve; 53. a first pull rod; 54. a second pull rod; 55. a slider; 56. a traveling wheel; 57. a traveling motor; 502. an annular groove; 503. mounting a plate; 504. and a carrier plate.

Detailed Description

In the description of this patent, it is noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention; the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; furthermore, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, as they may be fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The meaning of the above terms in this patent may be specifically understood by those of ordinary skill in the art.

Example 1: a full-automatic feeding system for recovering metal copper for power transmission refers to the attached figures 1-5 and comprises a turning frame 21, a turning plate 22 and a telescopic rod 23, wherein the turning frame 21 is installed on one side of a furnace opening, one end, close to the furnace opening 1, of the turning plate 22 is hinged to the turning frame 21, the other end of the turning plate 22 is hinged to one end of the telescopic rod 23, the other end of the telescopic rod 23 is hinged to the bottom of the turning frame 21, a baffle plate 24 is installed on the top surface of the turning plate 22, the baffle plate 24 is located on one side, close to the furnace opening 1, of the turning frame 21, a storage frame 3 is placed on one side, far away from the furnace opening;

the telescopic rod 23 comprises a bottom rod 201 and a worm 25 inserted in the bottom rod 201, a telescopic motor 26 is mounted on the bottom rod 201, a worm wheel 27 is mounted on an output shaft of the telescopic motor 26, and a yielding hole 202 for meshing the worm wheel 27 and the worm 25 is formed in the bottom rod 201;

a vertical frame 401, a guide rail 41, a clamping jaw 42 and a sucking disc 43 are arranged between the turning frame 21 and the furnace mouth 1, the guide rail 41 is arranged on the vertical frame 401 and is distributed along the directions of the furnace mouth 1, the turning frame 21 and the storage rack 3, a frame 5 is arranged on the guide rail 41, two ends of the frame 5 are respectively provided with an electric hoist 44, the clamping jaw 42 and the sucking disc 43 are respectively arranged on lifting ropes of the two electric hoists 44, the sucking disc 43 is connected with a vacuum-pumping pump 402 through a vacuum-pumping pipe, and the distance between the two electric hoists 44 is equal to the distance between the furnace mouth 1 and the turning frame 21 and equal to the distance between the turning frame 21 and the storage rack 3;

at least four sliding blocks 55 are arranged at the bottom of the rack 5, a walking wheel 56 in contact with the guide rail 41 is rotatably arranged at the bottom of each sliding block 55, a walking motor 57 is further arranged on the rack 5, and an output shaft of the walking motor 57 is inserted in the shaft center of the walking wheel 56;

a first sleeve 51 and a second sleeve 52 are mounted on the frame 5, a first pull rod 53 and a second pull rod 54 are respectively inserted into the bottom ends of the first sleeve 51 and the second sleeve 52, and the clamping jaw 42 and the suction cup 43 are respectively mounted at the bottom ends of the first pull rod 53 and the second pull rod 54;

the clamping jaw 42 further comprises a clamping plate 45, a rotating plate 46 and an air cylinder 47, wherein the clamping plate 45 is connected with a first pull rod 53, the rotating plate 46 is hinged at the tail end of the clamping plate 45, a driving plate 48 is further connected to the hinged end of the rotating plate 46, the air cylinder 47 is hinged on the first pull rod 53, and a piston rod of the air cylinder 47 is hinged with the driving plate 48.

Example 2: a full-automatic feeding system for recovering metal copper for power transmission refers to the attached figures 1-5 and comprises a turning frame 21, a turning plate 22 and a telescopic rod 23, wherein the turning frame 21 is installed on one side of a furnace opening, one end, close to the furnace opening 1, of the turning plate 22 is hinged to the turning frame 21, the other end of the turning plate 22 is hinged to one end of the telescopic rod 23, the other end of the telescopic rod 23 is hinged to the bottom of the turning frame 21, a baffle plate 24 is installed on the top surface of the turning plate 22, the baffle plate 24 is located on one side, close to the furnace opening 1, of the turning frame 21, a storage frame 3 is placed on one side, far away from the furnace opening;

the telescopic rod 23 comprises a bottom rod 201 and a worm 25 inserted in the bottom rod 201, a telescopic motor 26 is mounted on the bottom rod 201, a worm wheel 27 is mounted on an output shaft of the telescopic motor 26, and a yielding hole 202 for meshing the worm wheel 27 and the worm 25 is formed in the bottom rod 201;

a vertical frame 401, a guide rail 41, a clamping jaw 42 and a sucking disc 43 are arranged between the turning frame 21 and the furnace mouth 1, the guide rail 41 is arranged on the vertical frame 401 and is distributed along the directions of the furnace mouth 1, the turning frame 21 and the storage rack 3, a frame 5 is arranged on the guide rail 41, two ends of the frame 5 are respectively provided with an electric hoist 44, the clamping jaw 42 and the sucking disc 43 are respectively arranged on lifting ropes of the two electric hoists 44, the sucking disc 43 is connected with a vacuum-pumping pump 402 through a vacuum-pumping pipe, and the distance between the two electric hoists 44 is equal to the distance between the furnace mouth 1 and the turning frame 21 and equal to the distance between the turning frame 21 and the storage rack 3;

at least four sliding blocks 55 are arranged at the bottom of the rack 5, a walking wheel 56 in contact with the guide rail 41 is rotatably arranged at the bottom of each sliding block 55, a walking motor 57 is further arranged on the rack 5, and an output shaft of the walking motor 57 is inserted in the shaft center of the walking wheel 56;

a first sleeve 51 and a second sleeve 52 are mounted on the frame 5, a first pull rod 53 and a second pull rod 54 are respectively inserted into the bottom ends of the first sleeve 51 and the second sleeve 52, and the clamping jaw 42 and the suction cup 43 are respectively mounted at the bottom ends of the first pull rod 53 and the second pull rod 54;

the clamping jaw 42 further comprises a clamping plate 45, a rotating plate 46 and an air cylinder 47, wherein the clamping plate 45 is connected with a first pull rod 53, the rotating plate 46 is hinged at the tail end of the clamping plate 45, a driving plate 48 is further connected to the hinged end of the rotating plate 46, the air cylinder 47 is hinged on the first pull rod 53, and a piston rod of the air cylinder 47 is hinged with the driving plate 48.

The guide rail 41 is provided with a guide bar 403, and the peripheral wall of the travelling wheel 56 is provided with an annular groove 502 for the guide bar 403 to be embedded; the number of the walking wheels 56 is four, the number of the walking motors 57 is two, and the two walking wheels 56 are respectively positioned on output shafts at two ends of one walking motor 57; two ends of the guide rail 41 are provided with a limiting block 404 corresponding to the slide block 55; a silica gel pad 405 is arranged on one side of the limiting block 404 close to the sliding block 55; the silicone pad 405 is connected to the stopper 404 via a screw 406.

The number of the first pull rods 53 is 2, a mounting plate 503 is arranged between the two first pull rods 53, and the clamping jaw 42 is positioned on the mounting plate 503; the number of the second pull rods 54 is 2, the bottom ends of the two second pull rods 54 are connected with a carrier plate 504, and the suction cups 43 are mounted on the bottom surface of the carrier plate 504; the number of the suction cups 43 is 4.

When the metal copper recovery full-automatic feeding system for power transmission is adopted, the copper plate is grabbed by the clamping jaws and the suckers, and the automatic overturning function of the overturning plate on the copper plate is matched, so that the copper plate can be continuously conveyed to the overturning plate by the suckers, and the copper plate can be conveyed to a furnace mouth by the clamping jaws, so that full-automatic feeding of the copper plate is realized, the labor intensity of workers can be reduced, and the steel plate feeding efficiency can be improved; simultaneously, clamping jaw and sucking disc are all installed in the frame, and the interval of control clamping jaw and sucking disc is the same with the spacing of fire door to roll-over stand, roll-over stand to storage frame, and synchronous motion's clamping jaw and frame can carry out getting of copper simultaneously and work of throwing of putting of copper is carried out simultaneously, further shortens the time of copper material loading.

In addition, the worm inserted in the bottom rod is matched to drive the worm to slide in a reciprocating manner in the cavity in the bottom rod, so that the telescopic function of the telescopic rod is realized, and the turning plate is assisted to complete full-automatic turning of the copper plate; the walking motor drives the walking wheel at the bottom of the rack to rotate, so that the rack is integrally arranged on the guide rail; it becomes ascending motion of vertical side through the setting of first sleeve, second sleeve and first pull rod, second pull rod, direction clamping jaw and sucking disc, stabilizes the effect of snatching of clamping jaw and sucking disc to the copper.

In addition, the guide strip is matched with the annular groove on the travelling wheel to guide the displacement of the rack on the guide rail, so that the rack is prevented from being separated from the guide rail; the limit of displacement of the rack on the guide rail is limited by the arrangement of the limit block and the silica gel pad, so that the motion stability of the rack is further improved; the limit position of the silica gel pad on the frame is adjusted by installing the silica gel pad through the screw rod.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims (9)

1. The utility model provides a full automatic feeding system is retrieved to metallic copper for power transmission which characterized in that: the furnace mouth turnover device comprises a turnover frame (21), a turnover plate (22) and a telescopic rod (23) which are arranged on one side of a furnace mouth, wherein one end, close to the furnace mouth (1), of the turnover plate (22) is hinged to the turnover frame (21), the other end of the turnover plate (22) is hinged to one end of the telescopic rod (23), the other end of the telescopic rod (23) is hinged to the bottom of the turnover frame (21), a baffle (24) is arranged on the top surface of the turnover plate (22), the baffle (24) is located on one side, close to the furnace mouth (1), of the turnover plate (22), a storage frame (3) is placed on one side, far away from the furnace mouth (1), of the turnover frame (21), and the;

the telescopic rod (23) comprises a bottom rod (201) and a worm (25) inserted in the bottom rod (201), a telescopic motor (26) is mounted on the bottom rod (201), a worm wheel (27) is mounted on an output shaft of the telescopic motor (26), and a abdicating hole (202) for meshing the worm wheel (27) and the worm (25) is formed in the bottom rod (201);

a vertical frame (401), a guide rail (41), a clamping jaw (42) and a sucking disc (43) are arranged between the turnover frame (21) and the furnace mouth (1), the guide rail (41) is arranged on the vertical frame (401) and is distributed along the directions of the furnace mouth (1), the turnover frame (21) and the storage frame (3), a rack (5) is arranged on the guide rail (41), two ends of the rack (5) are respectively provided with an electric hoist (44), the clamping jaw (42) and the sucking disc (43) are respectively arranged on lifting ropes of the two electric hoists (44), the sucking disc (43) is connected with a vacuum pump (402) through a vacuum pumping pipe, and the distance between the two electric hoists (44) is equal to the distance between the furnace mouth (1) and the turnover frame (21) and equal to the distance between the turnover frame (21) and the storage frame (3);

at least four sliding blocks (55) are installed at the bottom of the rack (5), a traveling wheel (56) which is in contact with the guide rail (41) is rotatably installed at the bottom of each sliding block (55), a traveling motor (57) is further installed on the rack (5), and an output shaft of the traveling motor (57) is inserted into an axis of the traveling wheel (56);

a first sleeve (51) and a second sleeve (52) are mounted on the rack (5), a first pull rod (53) and a second pull rod (54) are respectively inserted into the bottom ends of the first sleeve (51) and the second sleeve (52), and the clamping jaw (42) and the suction cup (43) are respectively mounted at the bottom ends of the first pull rod (53) and the second pull rod (54);

the clamping jaw (42) further comprises a clamping plate (45), a rotating plate (46) and a cylinder (47), the clamping plate (45) is connected with a first pull rod (53), the rotating plate (46) is hinged to the tail end of the clamping plate (45), a driving plate (48) is further connected to the hinged end of the rotating plate (46), the cylinder (47) is hinged to the first pull rod (53), and a piston rod of the cylinder (47) is hinged to the driving plate (48).

2. The full-automatic feeding system for recovering metal copper for power transmission according to claim 1, characterized in that: the guide rail (41) is provided with a guide strip (403), and the peripheral wall of the travelling wheel (56) is provided with an annular groove (502) for embedding the guide strip (403).

3. The full-automatic feeding system for recovering metal copper for power transmission according to claim 1, characterized in that: the number of the walking wheels (56) is four, the number of the walking motors (57) is two, and the two walking wheels (56) are respectively positioned on output shafts at two ends of one walking motor (57).

4. The full-automatic feeding system for recovering metal copper for power transmission according to claim 1, characterized in that: and two ends of the guide rail (41) are provided with a limiting block (404) corresponding to the sliding block (55).

5. The full-automatic feeding system for recovering metal copper for power transmission of claim 4, characterized in that: and a silica gel pad (405) is arranged on one side of the limiting block (404) close to the sliding block (55).

6. The full-automatic feeding system for recovering metal copper for power transmission of claim 5, characterized in that: the silica gel pad (405) is connected with the limiting block (404) through a screw (406).

7. The full-automatic feeding system for recovering metal copper for power transmission according to claim 1, characterized in that: the number of the first pull rods (53) is 2, a mounting plate (503) is arranged between the two first pull rods (53), and the clamping jaw (42) is located on the mounting plate (503).

8. The full-automatic feeding system for recovering metal copper for power transmission according to claim 1, characterized in that: the number of the second pull rods (54) is 2, the bottom ends of the two second pull rods (54) are connected with a carrier plate (504), and the suction cups (43) are arranged on the bottom surface of the carrier plate (504).

9. The full-automatic feeding system for recovering metal copper for power transmission according to claim 1, characterized in that: the number of the suckers (43) is 4.

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