CN113445518A - Application method of industrial solid waste landfill construction device - Google Patents

Abstract

The invention relates to the technical field of building construction, in particular to a using method of an industrial solid waste landfill construction device, which comprises the following steps: s1: the method comprises the steps of preparing an industrial solid waste landfill construction device, wherein the industrial solid waste landfill construction device comprises a bottom plate, a motor is fixedly connected to one side of the upper surface of the bottom plate, a driving shaft is fixedly connected to the output end of the motor in a coaxial mode, a connecting plate is fixedly connected to the end portion of the driving shaft, a sliding block is fixedly connected to the outer wall of the connecting plate, a guide groove is formed in the other side of the upper surface of the bottom plate, a guide block is slidably connected into the guide groove, a clip frame is fixedly connected to the top of the guide block, the sliding block is slidably connected into the clip frame, a feeding track is further fixedly connected to the upper surface of the bottom plate, and a mounting plate is horizontally and fixedly connected to one side of the feeding track.

Description

Application method of industrial solid waste landfill construction device

Technical Field

The invention relates to the technical field of building construction, in particular to a using method of an industrial solid waste landfill construction device.

Background

At present, sites for dangerous waste (industrial solid waste) and domestic garbage landfill sites are generally selected in remote mountainous areas. In order to reduce the engineering quantity of the landfill and save investment, most of the landfill is built in a deep ditch or depression with three sides surrounding mountains by utilizing valley fields. The sections are generally thick in vegetation, high in mountain and steep in slope and large in catchment area, so that surface water of a high mountain slope at the upstream of the landfill easily flows into the landfill, and side slope anchoring needs to be performed on a ring slope of the landfill to prevent the catchment from flowing through the slope to cause landslide.

The anchor cable is a reinforced support in slope anchoring, construction needs to be carried out according to specified procedures, the next procedure can be carried out after each procedure is finished and the inspection and acceptance are qualified, and the anchor cable construction procedures comprise hole forming, cable braiding, anchor cable installation, grouting, tensioning, anchor head reinforced concrete pouring and anchor sealing construction.

When the cable is braided, the anchor cable steel strand with the required length needs to be cut on the steel strand disc according to the drilling length, after the anchor cable steel strand is straightened and deoiled to remove embroidery, anchor cups are arranged at two ends of the anchor cable steel strand, and then the anchor is anchored by using an anchorage device.

Disclosure of Invention

The invention aims to solve the problem that hands of workers are easily scratched when an anchor cup is manually installed in the prior art, and provides a using method of an industrial solid waste landfill construction device.

In order to achieve the purpose, the invention adopts the following technical scheme:

the design is a construction device for industrial solid waste landfill, which comprises the following steps:

s1: preparing an industrial solid waste landfill construction device, wherein the industrial solid waste landfill construction device comprises a bottom plate, a motor is fixedly connected to one side of the upper surface of the bottom plate, a driving shaft is fixedly connected to the output end of the motor in a coaxial line manner, a connecting plate is fixedly connected to the end portion of the driving shaft, a sliding block is fixedly connected to the outer wall of the connecting plate, a guide groove is formed in the other side of the upper surface of the bottom plate, a guide block is slidably connected to the guide groove, a square frame is fixedly connected to the top of the guide block, the sliding block is slidably connected to the square frame, a feeding track is fixedly connected to the upper surface of the bottom plate, a mounting plate is horizontally and fixedly connected to one side of the feeding track, a short shaft is rotatably mounted at the end portion of the mounting plate, a reversing gear is fixedly connected to the short shaft, a connecting rod is fixedly connected to the top of the square frame, a first rack is fixedly connected to the top of the connecting rod, and the first rack is meshed to the bottom of the reversing gear, one end of the first rack is fixedly connected with a first partition plate, the first partition plate is connected in the feeding track in a sliding mode, the top of the mounting plate is fixedly connected with a sliding groove, a second partition plate is connected in the sliding groove in a sliding mode, one side of the second partition plate is horizontally and fixedly connected with a second rack, the second rack is meshed with the top of the reversing gear, one side of the feeding track is fixedly connected with a feeding groove, the interior of the feeding groove is semicircular, and the feeding groove is located right below a discharging port of the feeding track;

a vertical rod is fixedly connected to the bottom surface of the first rack in a vertical mode, a sliding pipe is fixedly connected to the bottom end of the vertical rod in a horizontal mode, a screw rod is inserted into the sliding pipe, the central axis of the screw rod and the central axis of the feeding trough are located on the same straight line, a top plate is fixedly connected to one end of the screw rod, an adjusting nut is screwed to the other end of the screw rod, and a compression spring is sleeved on the screw rod between the top plate and the sliding pipe;

the automatic feeding device is characterized by further comprising a bearing seat, a driven shaft is rotatably mounted in the bearing seat, a bevel gear is fixedly connected to one end of the driven shaft, an incomplete bevel gear is fixedly connected to the driving shaft, the incomplete bevel gear is meshed with the bevel gear, a balancing weight is fixedly connected to the other end of the driven shaft, a plurality of through holes are formed in the balancing weight at equal intervals, the central axes of the through holes are located on the same circumference, the through holes are slidably connected with an anchor cup, and the central axes of the through holes can coincide with the central axis of the feeding groove;

the upper surface of the sliding plate is horizontally and fixedly connected with a third rack, an incomplete gear is fixedly connected to a driving shaft and is meshed with the third rack, a punch is fixedly connected to the upper surface of the sliding plate, and the central axis of the through hole can coincide with the central axis of the punch;

s2: the motor is started, the motor drives the driving shaft to rotate, the driving shaft drives the connecting plate to rotate, the connecting plate can drive the sliding block to rotate when rotating, the sliding block is located inside the clip-shaped frame, and the clip-shaped frame can drive the guide block to slide back and forth in the guide groove when the sliding block rotates, so that the clip-shaped frame can reciprocate in the horizontal direction;

s3: the first rack is driven to synchronously move through the connecting rod when the square frame is driven to do reciprocating motion in the horizontal direction, the reversing gear is driven to rotate when the square frame drives the first rack to do reciprocating motion in the horizontal direction, the second rack is driven to move in the horizontal direction by the reversing gear, and the moving direction of the second rack is always opposite to that of the first rack;

the first rack can drive the first partition plate to periodically close the discharge hole of the feeding track when reciprocating in the horizontal direction; the second rack moves in the horizontal direction opposite to the moving direction of the first rack to drive the second partition plate to move synchronously, the second partition plate can periodically block a discharging path of the feeding rail, and the distance between the second partition plate and the first partition plate is the length of the outer diameter of the anchor cup;

s4: when the discharge port is closed by the first partition plate, the discharge path is not blocked by the second partition plate, and the anchor cup is positioned above the first partition plate;

the first partition plate is driven to gradually open the discharge port, the second partition plate can be gradually arranged in the feeding rail, the second partition plate can be inserted into a gap at the abutting part of the two anchor cups at the bottommost end in the process of being arranged in the feeding rail, the feeding path of the anchor cups above the second partition plate is blocked, and the anchor cups below the second partition plate have no influence;

after the discharge port of the first partition plate is opened, under the action of gravity, the anchor cup at the bottommost end falls into the feeding groove from the discharge port of the feeding rail, and the anchor cups except the feeding groove are blocked by the second partition plate;

along with the movement of the first rack, the first partition plate closes the discharge hole of the feeding track again, the second partition plate is separated from the feeding track, and the anchor cup abuts against the first partition plate again;

repeating the process to complete the step of periodically feeding the anchor cup in the feeding track to the feeding groove;

s5: when the first partition plate is driven to move in the horizontal direction, the vertical rod drives the sliding pipe to move synchronously, and when the sliding pipe moves, the top plate is driven to move synchronously;

s6: the top plate is driven to do reciprocating motion in the horizontal direction, so that the anchor cups in the feeding groove can be ejected out periodically, and the horizontal position of the top plate can be adjusted by rotating the adjusting nut, so that the anchor cups with different lengths can be ejected out;

s7: the driving shaft is made to rotate to drive the incomplete bevel gear to rotate, the incomplete bevel gear can drive the bevel gear to periodically rotate, the bevel gear can drive the driven shaft to rotate in the bearing seat when rotating, the driven shaft rotates to drive the balancing weight to rotate, and the rotation of the balancing weight can make the central axis of each through hole periodically coincide with the axis of the feeding trough;

when the axis of the through hole is coincident with the axis of the feeding groove, the top plate enables the anchor cup in the feeding groove to be placed in the through hole, the feeding operation of the feeding groove to the through hole is completed, and in order to reduce the influence of the anchor cup on the gravity center of the balancing weight, the quality of the balancing weight is required to be as large as possible;

s8: the driving shaft is enabled to rotate to drive the incomplete gear to rotate, the incomplete gear can be periodically meshed on the third rack, the third rack can be driven to horizontally move when the incomplete gear is meshed with the third rack, the sliding plate can be driven to horizontally slide on the upper surface of the bottom plate when the third rack horizontally moves, and the resetting spring can be compressed when the sliding plate horizontally slides; when the incomplete gear and the third rack are in a falling and meshing state, the sliding plate can be reset to an initial state under the elastic force action of the reset spring;

when the incomplete gear is meshed with the third rack, the incomplete gear drives the third rack to move left, the third rack drives the sliding plate to move left, the sliding plate can drive the punch to move synchronously when moving, the punch can push the anchor cup to move left in the through hole, the anchor cable to be processed is pre-installed at the right end of the through hole, and the anchor cup is installed at the end part of the anchor cable under the guiding action of the through hole.

Preferably, a feeding structure for the anchor cable is further arranged on the upper surface of the bottom plate, the feeding structure comprises a plurality of support plates, the support plates are vertically and fixedly connected to the upper surface of the bottom plate, two shaft pins are fixedly connected to each support plate at intervals, the central axes of the shaft pins on the same support plate are located on the same vertical surface, a feeding gear is sleeved on the end portion of each shaft pin, a sleeve is coaxially communicated with the end surface of each feeding gear, the sleeve is slidably connected to the shaft pins, the feeding gears on the same support plate are meshed together, the sleeves on the same central axis abut against each other, and a clamping spring is sleeved on the shaft pin between each feeding gear and the support plate;

the feeding device is characterized by further comprising a cross rod, wherein one end of the cross rod is fixedly connected to the sliding plate, the other end of the cross rod is fixedly connected with two fourth racks at intervals, and the fourth racks are meshed with the feeding gear;

the step S8 further includes the following steps:

s81: when the driving sliding plate moves leftwards, the transverse rod can be driven to move leftwards, the transverse rod drives the fourth rack to move leftwards, the fourth rack moves leftwards to drive the feeding gear which is in contact with the fourth rack to rotate anticlockwise, the anchor cable penetrates through the two feeding gears which are coaxial, two sides of the anchor cable abut against the end face of the feeding gear, and the end of the anchor cable can be conveyed into the through hole when the feeding gear rotates anticlockwise until the anchor cup is installed on the end of the anchor cable;

s82: when the slide moves to the right under reset spring's effect, the material loading gear clockwise rotation with fourth rack contact takes out the anchor rope that will process the completion from the through-hole, and the back is taken out completely in the through-hole to the anchor cup, and the material loading gear of two coaxial lines of sliding on the pivot makes it keep away from each other, and the material loading gear of two coaxial lines keeps away from each other and can make two sleeves that offset keep away from each other to open the breach, take out the anchor rope can.

The use method of the industrial solid waste landfill construction device provided by the invention has the beneficial effects that: in the installation process of the anchor cable and the anchor cup, the anchor cable is pulled by adopting the feeding structure, the anchor cable is pulled to be arranged in the through hole of the counterweight block, the end part of the anchor cable is arranged in the anchor cup through the guide of the through hole, the anchor cup is pressed by the punch to be fastened at the end part of the anchor cable, and the whole process adopts mechanical operation, so that the defect that the hand of a worker is easily scratched by a manual installation mode can be avoided, and the labor cost is saved.

Drawings

Fig. 1 is a schematic structural diagram of a use method of an industrial solid waste landfill site construction device provided by the invention.

Fig. 2 is a structural schematic diagram of a use method of the industrial solid waste landfill site construction device provided by the invention.

Fig. 3 is a structural schematic diagram three of a use method of the industrial solid waste landfill site construction device provided by the invention.

Fig. 4 is a first cross-sectional view of a method for using the industrial solid waste landfill site construction device according to the present invention.

Fig. 5 is an enlarged view of a portion a of the method for using the industrial solid waste landfill site construction device according to the present invention.

Fig. 6 is a structural schematic diagram of a fourth method for using the industrial solid waste landfill site construction device provided by the invention.

Fig. 7 is a second sectional view of the method for using the industrial solid waste landfill site construction device according to the present invention.

Fig. 8 is a schematic structural diagram of a fifth structural diagram of a using method of the industrial solid waste landfill site construction device provided by the invention.

Fig. 9 is a first structural schematic diagram of a feeding structure of a using method of the industrial solid waste landfill site construction device provided by the invention.

Fig. 10 is a structural schematic diagram of a feeding structure of a using method of the industrial solid waste landfill site construction device provided by the invention.

In the figure: the device comprises a bottom plate 1, a motor 2, a driving shaft 3, a guide groove 4, a guide block 5, a square frame 6, a connecting plate 7, a sliding block 8, a connecting rod 9, a feeding rail 10, a mounting plate 11, a sliding groove 12, a second partition plate 13, a second rack 14, a short shaft 15, a reversing gear 16, a first rack 17, a first partition plate 18, a bearing seat 19, a driven shaft 20, a bevel gear 21, an incomplete bevel gear 22, a balancing weight 23, a through hole 24, a vertical rod 25, a sliding pipe 26, a screw 27, a top plate 28, an adjusting nut 29, a compression spring 30, a feeding groove 31, an incomplete gear 32, a sliding plate 33, a limiting block 34, a return spring 35, a third rack 36, a return spring 37, a cross rod 38, a fourth rack 39, a support plate 40, a shaft pin 41, a clamping spring 42, a feeding gear 43, a sleeve 44, an anchor rope 45, an anchor cup 46 and a notch 47.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1 to 10, a method for using an industrial solid waste landfill site construction device, the industrial solid waste landfill site construction device comprising the steps of:

s1: preparing an industrial solid waste landfill construction device, wherein the industrial solid waste landfill construction device comprises a bottom plate 1, a motor 2 is fixedly connected to one side of the upper surface of the bottom plate 1, a driving shaft 3 is fixedly connected to the output end of the motor 2 coaxially, a connecting plate 7 is fixedly connected to the end portion of the driving shaft 3, a sliding block 8 is fixedly connected to the outer wall of the connecting plate 7, a guide groove 4 is formed in the other side of the upper surface of the bottom plate 1, a guide block 5 is slidably connected to the guide groove 4, a square frame 6 is fixedly connected to the top of the guide block 5, the sliding block 8 is slidably connected to the square frame 6, a feeding rail 10 is further fixedly connected to the upper surface of the bottom plate 1, a mounting plate 11 is horizontally and fixedly connected to one side of the feeding rail 10, a short shaft 15 is rotatably mounted at the end portion of the mounting plate 11, a reversing gear 16 is fixedly connected to the short shaft 15, a connecting rod 9 is fixedly connected to the top of the square frame 6, a first rack 17 is fixedly connected to the top of the connecting rod 9, and the first rack 17 is meshed to the bottom of the reversing gear 16, one end of the first rack 17 is fixedly connected with a first partition plate 18, the first partition plate 18 is connected in the feeding track 10 in a sliding manner, the top of the mounting plate 11 is fixedly connected with a sliding chute 12, a second partition plate 13 is connected in the sliding chute 12 in a sliding manner, one side of the second partition plate 13 is horizontally and fixedly connected with a second rack 14, the second rack 14 is meshed with the top of the reversing gear 16, one side of the feeding track 10 is fixedly connected with a feeding trough 31, the interior of the feeding trough 31 is semicircular, and the feeding trough 31 is positioned under a discharge port of the feeding track 10; starting the motor 2, driving the driving shaft 3 to rotate by the motor 2, driving the connecting plate 7 to rotate by the driving shaft 3, driving the sliding block 8 to rotate when the connecting plate 7 rotates, and enabling the sliding block 8 to be located inside the clip-shaped frame 6, wherein when the sliding block 8 rotates, the clip-shaped frame 6 can drive the guide block 5 to slide back and forth in the guide groove 4, so that the clip-shaped frame 6 can reciprocate in the horizontal direction;

when the square frame 6 reciprocates in the horizontal direction, the connecting rod 9 drives the first rack 17 to synchronously move, when the square frame 6 drives the first rack 17 to reciprocate in the horizontal direction, the reversing gear 16 is driven to rotate, the reversing gear 16 drives the second rack 14 to move in the horizontal direction, and the moving direction of the second rack 14 is always opposite to that of the first rack 17;

the first rack 17 drives the first partition plate 18 to periodically close the discharge hole of the feeding rail 10 when reciprocating in the horizontal direction; the second rack 14 moves in the horizontal direction opposite to the moving direction of the first rack 17 to drive the second partition plate 13 to move synchronously, the second partition plate 13 periodically blocks the discharging path of the feeding rail 10, and the distance between the second partition plate 13 and the first partition plate 18 is the length of the outer diameter of the anchor cup 46;

as can be seen from the above, for the loading rail 10:

when the first partition plate 18 closes the discharge hole, the second partition plate 13 does not block the discharge path, and the anchor cup 46 is positioned above the first partition plate 18;

the discharge port is gradually opened by the first partition plate 18, the second partition plate 13 is gradually arranged in the feeding rail 10, the second partition plate 13 is inserted into a gap at the abutting part of the two anchor cups 46 at the bottommost end in the process of being arranged in the feeding rail 10, the feeding path of the anchor cup 46 above the second partition plate 13 is blocked, and the anchor cup 46 below the second partition plate 13 has no influence;

after the discharge hole is opened by the first partition plate 18, under the action of gravity, the bottommost anchor cup 46 falls into the feeding groove 31 from the discharge hole of the feeding rail 10, and the other anchor cups 46 are blocked by the second partition plate 13;

along with the movement of the first rack 17, the first partition plate 18 closes the discharge hole of the feeding rail 10 again, the second partition plate 13 is separated from the feeding rail 10, and the anchor cup 46 abuts against the first partition plate 18 again;

the above process is repeated, so that the steps of periodically feeding the upper trough 31 by the anchor cups 46 in the feeding rail 10 can be completed.

An upright rod 25 is fixedly connected to the bottom surface of the first rack 17 vertically, a sliding pipe 26 is fixedly connected to the bottom end of the upright rod 25 horizontally, a screw rod 27 is inserted into the sliding pipe 26, the central axis of the screw rod 27 and the central axis of the feeding chute 31 are positioned on the same straight line, a top plate 28 is fixedly connected to one end of the screw rod 27, an adjusting nut 29 is screwed to the other end of the screw rod 27, and a compression spring 30 is sleeved on the screw rod 27 between the top plate 28 and the sliding pipe 26; when the first partition 18 is driven to move in the horizontal direction, the vertical rod 25 drives the slide tube 26 to move synchronously, and when the slide tube 26 moves, the top plate 28 is driven to move synchronously.

The anchor cups 46 in the feeding trough 31 can be ejected out periodically by driving the top plate 28 to reciprocate in the horizontal direction, and the horizontal position of the top plate 28 can be adjusted by rotating the adjusting nut 29, so that the anchor cups 46 with different lengths can be ejected out.

The automatic feeding device is characterized by further comprising a bearing seat 19, a driven shaft 20 is rotatably mounted in the bearing seat 19, one end of the driven shaft 20 is fixedly connected with a bevel gear 21, the driving shaft 3 is fixedly connected with an incomplete bevel gear 22, the incomplete bevel gear 22 is meshed with the bevel gear 21, the other end of the driven shaft 20 is fixedly connected with a balancing weight 23, the balancing weight 23 is provided with a plurality of through holes 24 at equal intervals, the central axes of the through holes 24 are positioned on the same circumference, the through holes 24 are slidably connected with an anchor cup 46, and the central axes of the through holes 24 can coincide with the central axis of the feeding trough 31; the drive driving shaft 3 rotates to drive the incomplete bevel gear 22 to rotate, the incomplete bevel gear 22 rotates to drive the bevel gear 21 to periodically rotate, the bevel gear 21 rotates to drive the driven shaft 20 to rotate in the bearing seat 19, the driven shaft 20 rotates to drive the balancing weight 23 to rotate, and the rotation of the balancing weight 23 enables the central axis of each through hole 24 to periodically coincide with the axis of the upper trough 31.

When the axis of the through hole 24 coincides with the axis of the loading chute 31, the top plate 28 allows the anchor cup 46 in the loading chute 31 to be loaded into the through hole 24, and the loading operation of the loading chute 31 to the through hole 24 is completed. To reduce the effect of the anchor cup 46 on the center of gravity of the counterweight 23, the mass of the counterweight 23 should be as large as possible.

Still include a slide 33, slide 33 is placed at 1 upper surface of bottom plate, notch 47 has been seted up on slide 33, slidable is connected with stopper 34 in the notch 47, stopper 34 bottom rigid coupling is at 1 upper surface of bottom plate, notch 47 is equipped with a reset spring 35, reset spring 37 one end is supported and is leaned on stopper 34, the reset spring 37 other end is supported and is leaned on notch 47 inner wall, slide 33 upper surface level rigid coupling has third rack 36, it has incomplete gear 32 still to have the rigid coupling on drive shaft 3, incomplete gear 32 meshing is on third rack 36, slide 33 upper surface still rigid coupling has drift 37, the axis of through-hole 24 all can coincide with the axis of drift 37. When the driving shaft 3 rotates, the incomplete gear 32 can be driven to rotate, the incomplete gear 32 can be periodically meshed with the third rack 36, when the incomplete gear 32 is meshed with the third rack 36, the third rack 36 can be driven to horizontally move, when the third rack 36 horizontally moves, the sliding plate 33 can be driven to horizontally slide on the upper surface of the bottom plate 1, and when the sliding plate 33 horizontally slides, the return spring 35 can be compressed; in the state where the incomplete gear 32 is out of engagement with the third rack 36, the slide plate 33 is returned to the initial state by the elastic force of the return spring 35.

When the incomplete gear 32 is meshed with the third rack 36, as shown in fig. 3, the incomplete gear 32 drives the third rack 36 to move to the left, the third rack 36 drives the sliding plate 33 to move to the left, the sliding plate 33 drives the punch 37 to move synchronously, the punch 37 moves to the left and pushes the anchor cup 46 to move to the left in the through hole 24, the anchor wire 45 to be processed is pre-installed at the right end of the through hole 24, and the anchor cup 46 is installed at the end of the anchor wire 45 under the guiding action of the through hole 24.

The upper surface of the bottom plate 1 is also provided with a feeding structure for an anchor cable 45, the feeding structure comprises a plurality of support plates 40, the support plates 40 are vertically and fixedly connected to the upper surface of the bottom plate 1, two shaft pins 41 are fixedly connected to each support plate 40 at intervals, the central axes of the shaft pins 41 on the same support plate 40 are positioned on the same vertical surface, a feeding gear 43 is sleeved on the end part of each shaft pin 41, a sleeve 44 is coaxially communicated with the end surface of each feeding gear 43, the sleeve 44 is slidably connected to the shaft pin 41, the feeding gears 43 on the same support plate 40 are meshed together, the sleeves 44 on the same central axis abut against each other, and a clamping spring 42 is sleeved on the shaft pin 41 between the feeding gear 43 and the support plate 40; the feeding device further comprises a cross rod 38, one end of the cross rod 38 is fixedly connected to the sliding plate 33, two fourth racks 39 are fixedly connected to the other end of the cross rod 38 at intervals, and the fourth racks 39 are meshed with the feeding gear 43. As shown in fig. 8, when the sliding plate 33 moves to the left, the cross bar 38 is driven to move to the left, the cross bar 38 drives the fourth rack 39 to move to the left, the fourth rack 39 moves to the left to drive the feeding gear 43 in contact with the fourth rack 39 to rotate counterclockwise, the anchor cable 45 passes through between the two feeding gears 43 on the same axis, two sides of the anchor cable 45 abut against the end surface of the feeding gear 43, and the counterclockwise rotation of the feeding gear 43 can convey the end of the anchor cable 45 into the through hole 24 until the anchor cup 46 is mounted on the end of the anchor cable 45; when the sliding plate 33 moves to the right under the action of the return spring 35, the feeding gear 43 in contact with the fourth rack 39 rotates clockwise, the processed anchor cable 45 is pulled out from the through hole 24, after the anchor cup 46 is completely pulled out from the through hole 24, the two coaxial feeding gears 43 slide on the shaft pin 41 to be away from each other, and the two coaxial feeding gears 43 are away from each other to make the two offset sleeves 44 be away from each other, so that the gap is opened, and the anchor cable 45 is taken out.

S2: starting the motor 2, driving the driving shaft 3 to rotate by the motor 2, driving the connecting plate 7 to rotate by the driving shaft 3, driving the sliding block 8 to rotate when the connecting plate 7 rotates, and enabling the sliding block 8 to be located inside the clip-shaped frame 6, wherein when the sliding block 8 rotates, the clip-shaped frame 6 can drive the guide block 5 to slide back and forth in the guide groove 4, so that the clip-shaped frame 6 can reciprocate in the horizontal direction;

s3: when the clip frame 6 is driven to do reciprocating motion in the horizontal direction, the first rack 17 is driven to synchronously move through the connecting rod 9, when the clip frame 6 drives the first rack 17 to do reciprocating motion in the horizontal direction, the reversing gear 16 is driven to rotate, the reversing gear 16 drives the second rack 14 to move in the horizontal direction, and the moving direction of the second rack 14 is always opposite to that of the first rack 17;

the first rack 17 drives the first partition plate 18 to periodically close the discharge hole of the feeding rail 10 when reciprocating in the horizontal direction; the second rack 14 moves in the horizontal direction opposite to the moving direction of the first rack 17 to drive the second partition plate 13 to move synchronously, the second partition plate 13 periodically blocks the discharging path of the feeding rail 10, and the distance between the second partition plate 13 and the first partition plate 18 is the length of the outer diameter of the anchor cup 46;

s4: when the first partition plate 18 closes the discharge hole, the second partition plate 13 does not block the discharge path, and the anchor cup 46 is positioned above the first partition plate 18;

the first partition plate 18 is driven to gradually open the discharge hole, the second partition plate 13 can be gradually arranged in the feeding rail 10, the second partition plate 13 can be inserted into a gap at the abutting part of the two anchor cups 46 at the bottommost end in the process of being arranged in the feeding rail 10, the feeding path of the anchor cups 46 above the second partition plate 13 is blocked, and the anchor cups 46 below the second partition plate 13 have no influence;

after the discharge hole is opened by the first partition plate 18, under the action of gravity, the bottommost anchor cup 46 falls into the feeding groove 31 from the discharge hole of the feeding rail 10, and the other anchor cups 46 are blocked by the second partition plate 13;

along with the movement of the first rack 17, the first partition plate 18 closes the discharge hole of the feeding rail 10 again, the second partition plate 13 is separated from the feeding rail 10, and the anchor cup 46 abuts against the first partition plate 18 again;

repeating the above process to complete the step of periodically feeding the anchor cup 46 in the feeding rail 10 to the feeding groove 31;

s5: when the first partition 18 is driven to move in the horizontal direction, the vertical rod 25 drives the slide tube 26 to move synchronously, and when the slide tube 26 moves, the top plate 28 is driven to move synchronously.

S6: the top plate 28 is driven to reciprocate in the horizontal direction, so that the anchor cups 46 in the feeding groove 31 can be ejected out periodically, and the horizontal position of the top plate 28 can be adjusted by rotating the adjusting nut 29, so that the anchor cups 46 with different lengths can be ejected out;

s7: the driving shaft 3 is made to rotate to drive the incomplete bevel gear 22 to rotate, the incomplete bevel gear 22 is made to rotate to drive the bevel gear 21 to periodically rotate, the bevel gear 21 drives the driven shaft 20 to rotate in the bearing seat 19 when rotating, the driven shaft 20 rotates to drive the balancing weight 23 to rotate, and the balancing weight 23 rotates to enable the central axis of each through hole 24 to periodically coincide with the axis of the upper trough 31.

When the axis of the through hole 24 coincides with the axis of the loading chute 31, the top plate 28 allows the anchor cup 46 in the loading chute 31 to be loaded into the through hole 24, and the loading operation of the loading chute 31 to the through hole 24 is completed. In order to reduce the influence of the anchor cup 46 on the gravity center of the balancing weight 23, the mass of the balancing weight 23 should be as large as possible;

s8: the driving shaft 3 is enabled to rotate and also can drive the incomplete gear 32 to rotate, the incomplete gear 32 can be periodically meshed with the third rack 36 in a rotating mode, the third rack 36 can be driven to horizontally move when the incomplete gear 32 is meshed with the third rack 36, the sliding plate 33 can be driven to horizontally slide on the upper surface of the bottom plate 1 when the third rack 36 horizontally moves, and the sliding plate 33 can compress the return spring 35 when the sliding plate 33 horizontally slides; in the state where the incomplete gear 32 is out of engagement with the third rack 36, the slide plate 33 is returned to the initial state by the elastic force of the return spring 35.

When the incomplete gear 32 is meshed with the third rack 36, the incomplete gear 32 drives the third rack 36 to move left, the third rack 36 drives the sliding plate 33 to move left, the sliding plate 33 drives the punch 37 to move synchronously, the punch 37 moves left to push the anchor cup 46 to move left in the through hole 24, the anchor cable 45 to be processed is pre-installed at the right end of the through hole 24, and the anchor cup 46 is installed at the end of the anchor cable 45 under the guiding action of the through hole 24.

S81: when the driving sliding plate 33 moves leftwards, the cross rod 38 is driven to move leftwards, the cross rod 38 drives the fourth rack 39 to move leftwards, the fourth rack 39 moves leftwards to drive the feeding gear 43 which is in contact with the fourth rack 39 to rotate anticlockwise, the anchor cable 45 penetrates through the two coaxial feeding gears 43, two sides of the anchor cable 45 abut against the end face of the feeding gear 43, the feeding gear 43 rotates anticlockwise to convey the end part of the anchor cable 45 into the through hole 24 until the anchor cup 46 is installed on the end part of the anchor cable 45;

s82: when the sliding plate 33 moves to the right under the action of the return spring 35, the feeding gear 43 in contact with the fourth rack 39 rotates clockwise, the processed anchor cable 45 is pulled out from the through hole 24, after the anchor cup 46 is completely pulled out from the through hole 24, the two coaxial feeding gears 43 slide on the shaft pin 41 to be away from each other, and the two coaxial feeding gears 43 are away from each other to make the two offset sleeves 44 be away from each other, so that the gap is opened, and the anchor cable 45 is taken out.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (2)

1. The construction device for the industrial solid waste landfill site is characterized by comprising the following steps:

s1: prepare an industry solid waste landfill construction device, industry solid waste landfill construction device includes bottom plate (1), bottom plate (1) upper surface one side rigid coupling has motor (2), coaxial line rigid coupling has drive shaft (3) on the output of motor (2), the rigid coupling has even board (7) on the drive shaft (3) tip, the rigid coupling has slider (8) on even board (7) outer wall, guide way (4) have been seted up to bottom plate (1) upper surface opposite side, slidable connection guide block (5) in guide way (4), guide block (5) top rigid coupling has back shape frame (6), slider (8) slidable connection is in back shape frame (6), bottom plate (1) upper surface still rigid coupling has material loading track (10), horizontal rigid coupling in material loading track (10) one side has mounting panel (11), the rotatable minor axis (15) of installing of mounting panel (11) tip, the rigid coupling has reversing gear (16) on minor axis (15), it has connecting rod (9) to go back shape frame (6) top rigid coupling, connecting rod (9) top rigid coupling has first rack (17), first rack (17) meshing is in reversing gear (16) bottom, first rack (17) one end rigid coupling has first baffle (18), first baffle (18) slidable connection in material loading track (10), mounting panel (11) top rigid coupling has spout (12), slidable connection has second baffle (13) in spout (12), the horizontal rigid coupling in second baffle (13) one side has second rack (14), second rack (14) meshing is in reversing gear (16) top, material loading track (10) one side rigid coupling has material loading groove (31), material loading groove (31) inside is semi-circular, the feeding groove (31) is positioned right below a discharge hole of the feeding rail (10);

a vertical rod (25) is fixedly connected to the bottom surface of the first rack (17) vertically, a sliding pipe (26) is fixedly connected to the bottom end of the vertical rod (25) horizontally, a screw rod (27) is inserted into the sliding pipe (26), the central axis of the screw rod (27) and the central axis of the feeding trough (31) are positioned on the same straight line, a top plate (28) is fixedly connected to one end of the screw rod (27), an adjusting nut (29) is screwed to the other end of the screw rod (27), and a compression spring (30) is sleeved on the screw rod (27) between the top plate (28) and the sliding pipe (26);

the automatic feeding device is characterized by further comprising a bearing seat (19), a driven shaft (20) is rotatably mounted in the bearing seat (19), a bevel gear (21) is fixedly connected to one end of the driven shaft (20), an incomplete bevel gear (22) is fixedly connected to the driving shaft (3), the incomplete bevel gear (22) is meshed with the bevel gear (21), a balancing weight (23) is fixedly connected to the other end of the driven shaft (20), a plurality of through holes (24) are formed in the balancing weight (23) at equal intervals, the central axes of the through holes (24) are located on the same circumference, the through holes (24) are connected with an anchor cup (46) in a sliding mode, and the central axes of the through holes (24) can coincide with the central axis of the feeding trough (31);

further comprises a sliding plate (33), the sliding plate (33) is placed on the upper surface of the bottom plate (1), a notch (47) is formed in the sliding plate (33), a limit block (34) is connected in the notch (47) in a sliding manner, the bottom of the limiting block (34) is fixedly connected with the upper surface of the bottom plate (1), the notch (47) is provided with a return spring (35), one end of the return spring (37) is abutted against the limiting block (34), the other end of the return spring (37) is abutted against the inner wall of the notch (47), a third rack (36) is horizontally and fixedly connected on the upper surface of the sliding plate (33), an incomplete gear (32) is also fixedly connected on the driving shaft (3), the incomplete gear (32) is meshed with the third rack (36), a punch (37) is fixedly connected to the upper surface of the sliding plate (33), the central axis of the through hole (24) can be coincided with the central axis of the punch (37);

s2: the motor (2) is started, the motor (2) drives the driving shaft (3) to rotate, the driving shaft (3) drives the connecting plate (7) to rotate, the connecting plate (7) can drive the sliding block (8) to rotate when rotating, the sliding block (8) is positioned inside the clip-shaped frame (6), and when the sliding block (8) rotates, the clip-shaped frame (6) can drive the guide block (5) to slide back and forth in the guide groove (4), so that the clip-shaped frame (6) can reciprocate in the horizontal direction;

s3: when the clip frame (6) is driven to do reciprocating motion in the horizontal direction, the first rack (17) is driven to synchronously move through the connecting rod (9), the clip frame (6) drives the first rack (17) to do reciprocating motion in the horizontal direction, the reversing gear (16) is driven to rotate, the reversing gear (16) drives the second rack (14) to move in the horizontal direction, and the moving direction of the second rack (14) is always opposite to that of the first rack (17);

when the first rack (17) reciprocates in the horizontal direction, the first partition plate (18) is driven to periodically close the discharge hole of the feeding rail (10); the second rack (14) moves in the horizontal direction in the direction opposite to the moving direction of the first rack (17) to drive the second partition plate (13) to move synchronously, the second partition plate (13) can periodically block a discharging path of the feeding rail (10), and the distance between the second partition plate (13) and the first partition plate (18) is the outer diameter length of the anchor cup (46);

s4: when the first partition plate (18) closes the discharge hole, the second partition plate (13) does not block the discharge path, and the anchor cup (46) is positioned above the first partition plate (18);

the first partition plate (18) is driven to gradually open the discharge hole, the second partition plate (13) can be gradually arranged in the feeding track (10), the second partition plate (13) can be inserted into a gap at the abutting position of two anchor cups (46) at the bottommost end in the process of being arranged in the feeding track (10), the feeding path of the anchor cups (46) above the second partition plate (13) is blocked, and the anchor cups (46) below the second partition plate (13) have no influence;

after the discharge hole is opened by the first partition plate (18), under the action of gravity, the bottommost anchor cup (46) falls into the feeding groove (31) from the discharge hole of the feeding rail (10), and the other anchor cups (46) are blocked by the second partition plate (13);

along with the movement of the first rack (17), the first partition plate (18) closes the discharge hole of the feeding track (10) again, the second partition plate (13) is separated from the feeding track (10), and the anchor cup (46) abuts against the first partition plate (18) again;

the process is repeated, so that the step of periodically feeding the upper material groove (31) by the anchor cup (46) in the feeding track (10) can be completed;

s5: when the first partition plate (18) is driven to move in the horizontal direction, the vertical rod (25) drives the sliding pipe (26) to move synchronously, and when the sliding pipe (26) moves, the top plate (28) is driven to move synchronously;

s6: the top plate (28) is driven to do reciprocating motion in the horizontal direction, so that the anchor cups (46) in the feeding groove (31) can be ejected out periodically, and the horizontal position of the top plate (28) can be adjusted by rotating the adjusting nut (29), so that the anchor cups (46) with different lengths can be ejected out;

s7: the driving shaft (3) is made to rotate and also can drive the incomplete bevel gear (22) to rotate, the incomplete bevel gear (22) can drive the bevel gear (21) to periodically rotate, the bevel gear (21) can drive the driven shaft (20) to rotate in the bearing seat (19) when rotating, the driven shaft (20) rotates and drives the balancing weight (23) to rotate, and the balancing weight (23) rotates and enables the central axis of each through hole (24) to periodically coincide with the axis of the feeding trough (31);

when the axis of the through hole (24) is coincident with the axis of the feeding groove (31), the top plate (28) enables the anchor cup (46) in the feeding groove (31) to be arranged in the through hole (24), the feeding operation of the feeding groove (31) to the through hole (24) is completed, and in order to reduce the influence of the anchor cup (46) on the gravity center of the balancing weight (23), the quality of the balancing weight (23) is required to be as large as possible;

s8: the driving shaft (3) is enabled to rotate and also can drive the incomplete gear (32) to rotate, the incomplete gear (32) can be periodically meshed on the third rack (36), the third rack (36) can be driven to horizontally move when the incomplete gear (32) is meshed with the third rack (36), the sliding plate (33) can be driven to horizontally slide on the upper surface of the bottom plate (1) when the third rack (36) horizontally moves, and the sliding plate (33) can compress the return spring (35) when the sliding plate (33) horizontally slides; when the incomplete gear (32) and the third rack (36) are in a falling engagement state, the sliding plate (33) can be reset to an initial state under the action of the elastic force of the reset spring (35);

when the incomplete gear (32) is meshed with the third rack (36), the incomplete gear (32) drives the third rack (36) to move leftwards, the third rack (36) drives the sliding plate (33) to move leftwards, the sliding plate (33) can drive the punch head (37) to move synchronously when moving, the punch head (37) moves leftwards to push the anchor cup (46) to move leftwards in the through hole (24), the anchor cable (45) to be processed is pre-installed at the right end of the through hole (24), and the anchor cup (46) is installed at the end part of the anchor cable (45) under the guiding action of the through hole (24).

2. The use method of the industrial waste-fixing landfill site construction device according to claim 1, characterized in that a feeding structure for anchor cables (45) is further arranged on the upper surface of the bottom plate (1), the feeding structure comprises a plurality of support plates (40), the support plates (40) are vertically and fixedly connected on the upper surface of the bottom plate (1), two shaft pins (41) are fixedly connected on each support plate (40) at intervals, the central axes of the shaft pins (41) on the same support plate (40) are on the same vertical plane, a feeding gear (43) is sleeved on the end of each shaft pin (41), a sleeve (44) is coaxially communicated on the end surface of each feeding gear (43), the sleeve (44) is slidably connected on the shaft pins (41), the feeding gears (43) on the same support plate (40) are meshed together, and the sleeves (44) on the same central axis abut against each other, a clamping spring (42) is sleeved on the shaft pin (41) between the feeding gear (43) and the support plate (40);

the feeding device is characterized by further comprising a cross rod (38), wherein one end of the cross rod (38) is fixedly connected to the sliding plate (33), the other end of the cross rod (38) is fixedly connected with two fourth racks (39) at intervals, and the fourth racks (39) are meshed with the feeding gear (43);

the step S8 further includes the following steps:

s81: when the driving sliding plate (33) moves leftwards, the cross rod (38) can be driven to move leftwards, the cross rod (38) drives the fourth rack (39) to move leftwards, the fourth rack (39) moves leftwards to drive the feeding gear (43) in contact with the fourth rack (39) to rotate anticlockwise, the anchor cable (45) penetrates through the two feeding gears (43) on the same axis, two sides of the anchor cable (45) abut against the end face of the feeding gear (43), and the feeding gear (43) rotates anticlockwise to convey the end part of the anchor cable (45) into the through hole (24) until the anchor cup (46) is installed on the end part of the anchor cable (45);

s82: when the sliding plate (33) moves rightwards under the action of the return spring (35), the feeding gear (43) in contact with the fourth rack (39) rotates clockwise, the processed anchor cable (45) is drawn out from the through hole (24), the anchor cup (46) is completely drawn out from the through hole (24), the two feeding gears (43) with the same axis slide on the shaft pin (41) to be away from each other, the two feeding gears (43) with the same axis are away from each other to enable the two butted sleeves (44) to be away from each other, so that a gap is opened, and the anchor cable (45) can be taken out.

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