CN221070515U - Automatic coiling and uncoiling device of bored concrete pile detector - Google Patents

Abstract

The utility model provides an automatic winding and unwinding device of a bored pile detector, which comprises a supporting unit, a wire feeding unit and a winding and unwinding unit, wherein a wire passes through the supporting unit, the wire feeding unit and the winding and unwinding unit in sequence, the wire feeding unit comprises a rotary table unit and a reciprocating wiring unit which are connected, and the reciprocating wiring unit drives the rotary table unit to reciprocate in the horizontal direction vertical to the wire through a reciprocating mechanism. The device is convenient for operators to take up and pay off wires, so that the labor cost is effectively saved, and the working efficiency is improved; the wire feeding unit moves left and right, wires are uniformly wound on the rotating wire frame, the wires are prevented from being knotted and wound, and the winding length of the wires is increased; the device orderly regulates the site construction environment and has attractive appearance.

Description

Automatic coiling and uncoiling device of bored concrete pile detector

Technical Field

The utility model belongs to the technical field of instrument coiling and uncoiling, and particularly relates to an automatic coiling and uncoiling device of a bored pile detector.

Background

The bored concrete pile is a hole in place, and the pile is made by pouring concrete or reinforced concrete, and the drilling depth is 8 m-12 m, so that the bored concrete pile detector also needs a longer line to support the condition that the detector detects the bottom of the hole, and the coiling and uncoiling device of the current bored concrete pile detector mostly needs manual coiling and uncoiling, and has the following defects:

1. The bored concrete pile detector has longer lines in construction, is messy in site, wastes labor in each time of winding and unwinding, takes more time, can be completed by at least 2 workers, and has high labor cost;

2. During operation, the operator is required to walk to the end part of the cable, pick up the cable, collect the cable along the extending direction of the cable, then throw the cable beside the coil in a piling mode, the length of the cable is longer, knotting is very easy to occur in the whole operation process, and winding is irregular and attractive due to manual winding.

Therefore, how to effectively solve the technical problems that the operation of winding and unwinding the filling pile detector is inconvenient, time-consuming and labor-consuming is a technical problem to be solved urgently.

Disclosure of utility model

Aiming at the defects in the background technology, the utility model provides an automatic winding and unwinding device for a bored pile detector, which solves the problems of inconvenient winding and unwinding operation and time and labor waste of the bored pile detector.

The technical scheme of the application is as follows:

The utility model provides an automatic coiling and uncoiling device of bored concrete pile detector, includes the supporting element that supplies the wire to pass through in proper order, send line unit, receive and uncoil line unit, send line unit including continuous carousel unit and reciprocal wiring unit, reciprocating motion mechanism drives reciprocal wiring unit carousel unit reciprocating motion in with wire vertically horizontal direction. The device is convenient for operators to take up and pay off wires, so that the labor cost is effectively saved, and the working efficiency is improved; the wire feeding unit moves left and right, wires are uniformly wound on the rotating wire frame, the wires are prevented from being knotted and wound, and the winding length of the wires is increased; the device orderly regulates the site construction environment and has attractive appearance.

Further, the turntable unit comprises rolling wheels, at least two rolling wheels are arranged in parallel up and down, the rolling wheels are arranged at intervals, and the rolling wheels are connected with a first motor.

Further, the thread rolling wheel is arranged on the movable base, a pulley which is in sliding fit with the sliding rail is arranged on the lower surface of the movable base, and the reciprocating mechanism drives the movable base to reciprocate on the sliding rail.

Further, the reciprocating wiring unit comprises a second bracket, a movable vertical rod connected with the movable base is sleeved on the second bracket, a sleeve for a wire to pass through is connected to the upper end of the movable vertical rod, and the height of the sleeve is the same as the height of the interval between the rolling wheels.

Further, the movable vertical rod is connected with a reciprocating mechanism, and the reciprocating mechanism drives the sleeve and the movable base to reciprocate left and right through a motor II.

Further, the reciprocating mechanism comprises a first connecting rod, a second connecting rod and a third connecting rod which are hinged in sequence, a first hole for a third bracket to pass through is formed in the third connecting rod, the other end of the first connecting rod is connected with a second motor through a first connecting piece and hinged with the third bracket respectively, and the first connecting piece is used as a first rotating shaft.

Further, the reciprocating mechanism comprises a connecting rod IV, a connecting rod V and a connecting rod VI which are sequentially hinged, the other end of the connecting rod IV is connected with a motor IV through a connecting piece II, the other end of the connecting rod VI is connected with a connecting rod seven, the connecting piece II is hinged with a bracket IV, a hole II for the bracket IV to pass through is formed in the connecting rod seven, and the reciprocating mechanism takes the connecting piece II as a second rotating shaft.

Further, the length of the sliding rail is longer than the length of the motion track of the reciprocating mechanism.

Further, the supporting unit comprises a first bracket for supporting the wire, and two ends of the first bracket are provided with a first baffle for preventing the wire from sliding off.

Further, the winding and unwinding unit comprises a rotating lead frame connected with the motor III, and two ends of the rotating lead frame are provided with a baffle II for preventing the lead from sliding down due to accumulation.

The utility model has the following specific beneficial effects:

1. the wire winding and unwinding of operators are facilitated, the labor cost is effectively saved, and the working efficiency is improved;

2. The wire feeding unit moves left and right, wires are uniformly wound on the rotating wire frame, the wires are prevented from being knotted and wound, and the winding length of the wires is increased;

3. Orderly and orderly regulating the site construction environment and having beautiful appearance.

Drawings

In order to more clearly illustrate the embodiments of the present utility model, the drawings that are required for the description of the embodiments will be briefly described below, it being apparent that the drawings in the following description are only some embodiments of the present utility model and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.

FIG. 1 is a plan view of an automatic take-up and pay-off device of a bored pile detector;

FIG. 2 is a perspective view of an automatic take-up and pay-off device of the bored pile detector;

FIG. 3 is a schematic view of a turntable unit;

fig. 4 is a schematic diagram of embodiment 1 of a reciprocation wiring unit;

fig. 5 is a schematic diagram of embodiment 2 of the reciprocation wiring unit.

Reference numerals illustrate:

1. a supporting unit; 2. a wire feeding unit; 3. a wire winding and unwinding unit;

4. a turntable unit; 5. a reciprocating wiring unit; 6. a reciprocating mechanism;

11. A first bracket; 12. a baffle;

31. A third motor; 32. rotating the lead frame;

41. A thread rolling wheel; 42. a first motor; 43. a movable base; 44. a pulley; 45. a slide rail;

51. a second bracket; 52. moving the vertical rod; 53. a sleeve;

61. A first connecting rod; 62. a second connecting rod; 63. a connecting rod III; 64. a third bracket;

65. A second motor; 66. a first connecting piece;

71. a connecting rod IV; 72. a connecting rod V; 73. a connecting rod six; 74. a connecting rod seven; 75. a bracket IV;

76. A second connecting piece; 77. and a fourth motor.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without any inventive effort, are intended to be within the scope of the utility model.

The utility model provides an automatic coiling and uncoiling device of bored concrete pile detector, is shown as fig. 1, fig. 2, including support element 1, send line unit 2, coiling and uncoiling unit 3 that supply the wire to pass through in proper order, send line unit 2 includes the carousel unit 4 that links to each other and reciprocal wiring unit 5, and reciprocating motion mechanism 6 drives reciprocal wiring unit 5 carousel unit 4 reciprocates in the horizontal direction with the wire vertically. The device is convenient for operators to take up and pay off wires, so that the labor cost is effectively saved, and the working efficiency is improved; the wire feeding unit moves left and right, wires are uniformly wound on the rotating wire frame, the wires are prevented from being knotted and wound, and the winding length of the wires is increased; the device orderly regulates the site construction environment and has attractive appearance.

Embodiment 1, as a preferred embodiment of an automatic winding and unwinding device of a bored pile detector, comprises a supporting unit 1, a wire feeding unit 2 and a winding and unwinding unit 3, wherein a wire is sequentially passed through the supporting unit 1, the wire feeding unit 2 comprises a rotary table unit 4 and a reciprocating wiring unit 5 which are connected, and the reciprocating wiring unit 5 drives the rotary table unit 4 to reciprocate in a horizontal direction perpendicular to the wire through a reciprocating mechanism 6.

Specifically, as shown in fig. 3, the turntable unit 4 includes at least two rollers 41, the rollers 41 are disposed up and down, the rollers are disposed at intervals, and the rollers 41 are connected to a first motor 42.

Preferably, four wire rolling wheels 41 are provided, two are located above and two are located below, the wire passes through the interval between the upper wire rolling wheel and the lower wire rolling wheel, the motor one 42 drives the wire rolling wheel to rotate, and the wire moves forwards or backwards under the rotation of the wire rolling wheel to take up or pay off.

On the basis of the above embodiment, the thread rolling wheel 41 is disposed on the movable base 43, a pulley 44 slidably engaged with the slide rail 45 is disposed on the lower surface of the movable base 43, and the reciprocating mechanism 6 drives the movable base 43 to reciprocate on the slide rail 45.

Specifically, the lower surface of the movable base 43 is provided with 4 pulleys, two slide rails 45 are provided, the slide rails are arranged in parallel, and the slide rails are arranged in parallel with the bracket 11, the reciprocating wiring unit 5 and the wire winding and unwinding unit 3.

On the basis of the above embodiment, the reciprocating wiring unit 5 includes a second bracket 51, a movable vertical rod 52 connected with the movable base 43 is sleeved on the second bracket 51, a sleeve 53 through which a wire passes is connected to the upper end of the movable vertical rod 52, and the second bracket 51 is in a C shape.

On the basis of the above embodiment, the height of the sleeve 53 is the same as the height of the interval between the thread rolling wheels 41, so that the wire passes through the sleeve 53 again after passing through the thread rolling wheels 41.

On the basis of the above embodiment, the movable vertical rod 52 is connected with the reciprocating mechanism 6, and the reciprocating mechanism 6 drives the sleeve 53 and the movable base 43 to reciprocate through the second motor 65.

Preferably, the two reciprocating mechanisms 6 are symmetrically arranged relative to the second bracket 51, the reciprocating mechanisms 6 are connected to the movable vertical rod 52, when the second motor 65 is started, the second motor 65 drives the reciprocating mechanisms 6 to reciprocate, the reciprocating mechanisms 6 drive the movable vertical rod 52 and the sleeve 53 to reciprocate, and meanwhile, the movable vertical rod 52 drives the movable base 43 to reciprocate under the limitation of the sliding rail 45, so that the wire feeding effect is achieved.

On the basis of the above embodiment, as shown in fig. 4, the reciprocating mechanism 6 includes a first connecting rod 61, a second connecting rod 62, and a third connecting rod 63 that are hinged in sequence, a first hole through which the third bracket 64 passes is provided on the third connecting rod 63, the other end of the first connecting rod 61 is connected with the second motor 65 through a first connecting piece 66 and hinged with the third bracket 64, and the reciprocating mechanism 6 uses the first connecting piece 66 as a first rotation axis.

Specifically, the end of the first connecting rod 61 is aligned with the end of the third bracket 64, the first connecting member 66 sequentially passes through the end of the first connecting rod 61 and the end of the third bracket 64, the first connecting member 66 is fixedly connected with the first connecting rod 61, the first connecting member is hinged with the third bracket 64, the second motor 65 is fixedly connected with the first connecting member, the second motor 65 drives the first connecting rod 61 to rotate around the first rotating shaft, the first connecting rod 61 drives the second connecting rod 62 and the third connecting rod 63 to reciprocate back and forth, the third connecting rod 63, the movable vertical rod 52 and the movable base 43 are sequentially connected, the movable base 43 is driven by the reciprocating mechanism 6 to reciprocate back and forth along a sliding rail, and the movable base 43 is consistent with the motion track of the reciprocating mechanism 6.

On the basis of the above embodiment, the length of the sliding rail 45 is longer than the length of the motion track of the reciprocating mechanism 6.

On the basis of the above embodiment, the supporting unit 1 includes a first bracket 11 for supporting the wires, two ends of the first bracket 11 are provided with a first baffle 12 for preventing the wires from sliding off, the first bracket 11 is at a certain height from the ground, the wires are placed on the first bracket 11, so that the wires are conveniently sent to the wire feeding unit 2, the first baffle 12 prevents the wires from sliding off from two ends of the first bracket 11, and the first bracket 11 is in a C shape.

On the basis of the above embodiment, the pay-off and take-up unit 3 includes a rotating lead frame 32 connected to a third motor 31, and two ends of the rotating lead frame 32 are provided with a second baffle plate for preventing the lead from sliding down due to accumulation.

The device is convenient for operators to take up and pay off wires, so that the labor cost is effectively saved, and the working efficiency is improved; the wire feeding unit moves left and right, wires are uniformly wound on the rotating wire frame, the wires are prevented from being knotted and wound, and the winding length of the wires is increased; the device orderly regulates the site construction environment and has attractive appearance.

Embodiment 2, which is a preferred embodiment of an automatic wire winding and unwinding device of a bored pile detector, is different from embodiment 1 in that the automatic wire winding and unwinding device comprises a supporting unit 1, a wire feeding unit 2 and a wire winding and unwinding unit 3, wherein a wire feeding unit 2 comprises a rotary table unit 4 and a reciprocating wiring unit 5 which are connected, and the reciprocating wiring unit 5 drives the rotary table unit 4 to reciprocate in a horizontal direction perpendicular to a wire through a reciprocating mechanism 6.

Specifically, as shown in fig. 3, the turntable unit 4 includes at least two rollers 41, the rollers 41 are disposed up and down, the rollers are disposed at intervals, and the rollers 41 are connected to a first motor 42.

Preferably, four wire rolling wheels 41 are provided, two are located above and two are located below, the wire passes through the interval between the upper wire rolling wheel and the lower wire rolling wheel, the motor one 42 drives the wire rolling wheel to rotate, and the wire moves forwards or backwards under the rotation of the wire rolling wheel to take up or pay off.

On the basis of the above embodiment, the thread rolling wheel 41 is disposed on the movable base 43, a pulley 44 slidably engaged with the slide rail 45 is disposed on the lower surface of the movable base 43, and the reciprocating wiring unit 5 drives the movable base 43 to reciprocate on the slide rail 45.

Specifically, the lower surface of the movable base 43 is provided with 4 pulleys, two slide rails 45 are provided, the slide rails are arranged in parallel, and the slide rails are arranged in parallel with the bracket 11, the reciprocating wiring unit 5 and the wire winding and unwinding unit 3.

On the basis of the above embodiment, the reciprocating wiring unit 5 includes a second bracket 51, a movable vertical rod 52 connected with the movable base 43 is sleeved on the second bracket 51, a sleeve 53 through which a wire passes is connected to the upper end of the movable vertical rod 52, and the second bracket 51 is in a C shape.

On the basis of the above embodiment, the height of the sleeve 53 is the same as the height of the interval between the thread rolling wheels 41, so that the wire passes through the sleeve 53 again after passing through the thread rolling wheels 41.

On the basis of the above embodiment, the movable vertical rod 52 is connected with the reciprocating mechanism 6, and the reciprocating mechanism 6 drives the sleeve 53 and the movable base 43 to reciprocate through the second motor 65.

Preferably, the two reciprocating mechanisms 6 are symmetrically arranged relative to the second bracket 51, the reciprocating mechanisms 6 are connected to the movable vertical rod 52, when the second motor 65 is started, the second motor 65 drives the reciprocating mechanisms 6 to reciprocate, the reciprocating mechanisms 6 drive the movable vertical rod 52 and the sleeve 53 to reciprocate, and meanwhile, the movable vertical rod 52 drives the movable base 43 to reciprocate under the limitation of the sliding rail 45, so that the wire feeding effect is achieved.

On the basis of the above embodiment, as shown in fig. 5, the reciprocating mechanism 6 includes a fourth link 71, a fifth link 72, and a sixth link 73 that are sequentially hinged, the other end of the fourth link 71 is connected to a fourth motor 77 through a second connector 76, the second connector 76 is hinged to a fourth bracket 75, the other end of the sixth link 73 is connected to a seventh link 74, a second hole through which the fourth bracket 75 passes is provided in the seventh link 74, and the reciprocating mechanism 6 uses the second connector 76 as a second rotation axis.

Specifically, the end of the fourth link 71 is aligned with the end of the fourth bracket 75, the second connecting member 76 sequentially passes through the end of the fourth link 71 and the end of the fourth bracket 75, the second connecting member 76 is fixedly connected with the fourth link 71, the second connecting member 76 is hinged with the fourth bracket 75, the fourth motor 77 is fixedly connected with the second connecting member 76, the fourth motor 77 drives the fourth link 71 to rotate around the second rotation axis, the fourth link 71 performs circular motion, the fourth link 71 drives the fifth link 72 to perform swinging motion, the fifth link 72 drives the sixth link 73 and the seventh link 74 to perform back-and-forth reciprocating motion, the seventh link 74, the movable vertical rod 52 and the movable base 43 are sequentially connected, the movable base 43 is driven by the reciprocating mechanism 6 to perform back-and-forth reciprocating motion along a sliding rail, and the movable base 43 is consistent with the motion track of the reciprocating mechanism 6.

On the basis of the above embodiment, the length of the sliding rail 45 is longer than the length of the motion track of the reciprocating mechanism 6.

On the basis of the above embodiment, the supporting unit 1 includes a first bracket 11 for supporting the wires, two ends of the first bracket 11 are provided with a first baffle 12 for preventing the wires from sliding off, the first bracket 11 is at a certain height from the ground, the wires are placed on the first bracket 11, so that the wires are conveniently sent to the wire feeding unit 2, the first baffle 12 prevents the wires from sliding off from two ends of the first bracket 11, and the first bracket 11 is in a C shape.

On the basis of the above embodiment, the pay-off and take-up unit 3 includes a rotating lead frame 32 connected to a third motor 31, and two ends of the rotating lead frame 32 are provided with a second baffle plate for preventing the lead from sliding down due to accumulation.

The utility model is convenient for operators to take up and pay off, effectively saves labor cost and improves working efficiency; the wire feeding unit moves left and right, wires are uniformly wound on the rotating wire frame, the wires are prevented from being knotted and wound, and the winding length of the wires is increased; the utility model orderly regulates the site construction environment and has beautiful appearance.

The present utility model is not limited to the conventional technical means known to those skilled in the art.

The foregoing has shown and described the basic principles, main features and advantages of the present utility model. The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (10)

1. Automatic coiling and uncoiling device of bored concrete pile detector, its characterized in that: the wire feeding device comprises a supporting unit (1), a wire feeding unit (2) and a wire winding and unwinding unit (3), wherein a wire feeding unit (2) comprises a rotary table unit (4) and a reciprocating wiring unit (5) which are connected, and a reciprocating mechanism (6) drives the reciprocating wiring unit (5) to reciprocate in the horizontal direction perpendicular to the wire.

2. An automatic winding and unwinding device for a bored pile detector according to claim 1, wherein: the turntable unit (4) comprises rolling wheels (41), wherein the rolling wheels (41) are arranged at least two and are arranged in parallel up and down, the rolling wheels (41) are arranged at intervals, and the rolling wheels (41) are connected with a first motor (42).

3. An automatic take-up and pay-off device for a bored pile detector according to claim 2, wherein: the rolling wheel (41) is arranged on the movable base (43), a pulley (44) which is in sliding fit with the sliding rail (45) is arranged on the lower surface of the movable base (43), and the reciprocating mechanism (6) drives the movable base (43) to reciprocate on the sliding rail (45).

4. An automatic take-up and pay-off device for a bored pile detector according to claim 2, wherein: the reciprocating wiring unit (5) comprises a second bracket (51), a movable vertical rod (52) connected with the movable base (43) is sleeved on the second bracket (51), a sleeve (53) for a wire to pass through is connected to the upper end of the movable vertical rod (52), and the height of the sleeve (53) is the same as the interval height between the rolling wheels (41).

5. An automatic take-up and pay-off device for a bored pile detector according to claim 4, wherein: the movable vertical rod (52) is connected with the reciprocating mechanism (6), and the reciprocating mechanism (6) drives the sleeve (53) and the movable base (43) to reciprocate through a motor II (65).

6. An automatic take-up and pay-off device for a bored pile detector according to claim 5, wherein: the reciprocating mechanism (6) comprises a first connecting rod (61), a second connecting rod (62) and a third connecting rod (63) which are sequentially hinged, a first hole for a third bracket (64) to pass through is formed in the third connecting rod (63), the other end of the first connecting rod (61) is respectively connected with a second motor (65) through a first connecting piece (66) and hinged with the third bracket (64), and the reciprocating mechanism (6) takes the first connecting piece (66) as a first rotating shaft.

7. An automatic take-up and pay-off device for a bored pile detector according to claim 5, wherein: the reciprocating mechanism (6) comprises a connecting rod IV (71), a connecting rod V (72) and a connecting rod VI (73) which are sequentially hinged, the other end of the connecting rod IV (71) is connected with a motor IV (77) through a connecting piece II (76), the connecting piece II (76) is hinged with a bracket IV (75), the other end of the connecting rod VI (73) is connected with a connecting rod V (74), a hole II for the bracket IV (75) to pass through is formed in the connecting rod V (74), and the reciprocating mechanism (6) takes the connecting piece II (76) as a second rotating shaft.

8. A bored pile detector automatic take-up and pay-off device according to claim 3, wherein: the length of the sliding rail (45) is longer than the length of the motion track of the reciprocating mechanism (6).

9. An automatic winding and unwinding device for a bored pile detector according to claim 1, wherein: the support unit (1) comprises a first support (11) for supporting the wires, and baffle plates (12) for preventing the wires from sliding off are arranged at two ends of the first support (11).

10. An automatic winding and unwinding device for a bored pile detector according to claim 1, wherein: the winding and unwinding unit (3) comprises a rotating lead frame (32) connected with a motor III (31), and two ends of the rotating lead frame (32) are provided with a baffle II for preventing the lead from sliding down due to accumulation.