CN111003579A - Steel wire drive type cable traction device - Google Patents

Abstract

The invention discloses a steel wire driving type cable traction device which comprises a main body shell. The invention can move on the guide steel wire rope, the movement can drive the cable rope, thereby realizing the installation of the cable wire, when driving, the maximum force during traction can be controlled, thereby preventing the damage of the overlarge traction force to the inner wire of the cable wire, and ensuring the performance of the cable wire, the device is provided with a gear meshing radius increasing type rotating strength effective degressive mechanism, which can effectively reduce the resistance during rotation, thereby effectively increasing the rotating strength of a driving motor, in addition, the device is provided with a spiral spring compression annular array type maximum rotating strength effective control mechanism, which can effectively control the strength during rotation, thereby preventing the cable wire from being damaged due to the overlarge traction force, the device is provided with a reverse thread structure rotating type longitudinal height effective adjusting mechanism, thereby controlling the biting force of a rotating wheel to the guide steel wire rope, and realizing driving.

Description

Steel wire drive type cable traction device

Technical Field

The invention relates to the technical field of traction devices, in particular to a steel wire driving type cable traction device.

Background

At present, when a cable is installed, particularly when the cable is installed in a mountain area or a long distance, a guide wire is needed to be used firstly, and then the cable is guided through the guide wire, but the conventional method has poor tension control capability when the cable is driven, so that the damage to the cable is large.

Disclosure of Invention

The invention aims to provide a steel wire driving type cable traction device to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a steel wire driving type cable traction device comprises a main body shell, wherein a driving motor installation shell is installed at the bottom of the main body shell through bolts, a driving motor is installed at one end inside the driving motor installation shell, a motor spindle in the driving motor is installed, a gear meshing radius increasing type rotating strength effective decreasing mechanism is installed at the end part of the motor spindle, a main rotating shaft is installed at the center of one end of the gear meshing radius increasing type rotating strength effective decreasing mechanism, a spiral spring compression annular array type maximum rotating strength effective control mechanism is installed at the end part of the main rotating shaft, the side surface of the spiral spring compression annular array type maximum rotating strength effective control mechanism is installed inside the driving motor installation shell through a main bearing, a secondary rotating shaft is installed at the center of one end of the spiral spring compression annular array type maximum rotating strength effective control mechanism, the main body shell is internally provided with a concave space, the auxiliary rotating shaft is provided with a main bevel gear at one end positioned in the concave space, the side surface of the main bevel gear is vertically meshed with two opposite auxiliary bevel gears, the center of the upper surface of the main body shell is provided with a main groove structure, two opposite rotating driving shafts are arranged in the main body shell, the two rotating driving shafts are respectively arranged at the centers of the sections of the two auxiliary bevel gears at the end parts facing to the outer side, a main rotating wheel is arranged at one end positioned in the main groove structure, the upper surface of the main body shell is provided with two opposite reverse thread structure rotating type longitudinal height effective adjusting mechanisms, the top ends of the two reverse thread structure rotating type longitudinal height effective adjusting mechanisms are provided with a fixed shaft, and the central part of the fixed shaft is provided with a rotating wheel through a pair of main bearings, the main rotating wheel and the auxiliary rotating wheel are arranged in an up-down symmetrical mode and are provided with annular groove structures at the circumference.

Furthermore, the gear meshing radius increasing type rotating strength effective decreasing mechanism comprises a hollow shell for the gear meshing radius increasing type rotating strength effective decreasing mechanism, a hollow structure for the gear meshing radius increasing type rotating strength effective decreasing mechanism, a first rotating shaft for the gear meshing radius increasing type rotating strength effective decreasing mechanism, a bearing for the gear meshing radius increasing type rotating strength effective decreasing mechanism and a second rotating shaft for the gear meshing radius increasing type rotating strength effective decreasing mechanism, a third rotating shaft for a gear meshing radius incremental type effective decreasing rotary strength mechanism, a first gear for the gear meshing radius incremental type effective decreasing rotary strength mechanism, a second gear for the gear meshing radius incremental type effective decreasing rotary strength mechanism, a third gear for the gear meshing radius incremental type effective decreasing rotary strength mechanism and a fourth gear for the gear meshing radius incremental type effective decreasing rotary strength mechanism; the hollow shell for the gear meshing radius increasing type effective decreasing rotary strength mechanism is internally provided with a hollow structure for the gear meshing radius increasing type effective decreasing rotary strength mechanism, the bottom center of the hollow shell for the gear meshing radius increasing type effective decreasing rotary strength mechanism is provided with a first rotating shaft for the gear meshing radius increasing type effective decreasing rotary strength mechanism through a bearing for the gear meshing radius increasing type effective decreasing rotary strength mechanism, the top center of the hollow shell for the gear meshing radius increasing type effective decreasing rotary strength mechanism is provided with a third rotating shaft for the gear meshing radius increasing type effective decreasing rotary strength mechanism through a bearing for the gear meshing radius increasing type effective decreasing rotary strength mechanism, the side surface of the hollow shell for the gear meshing radius increasing type effective decreasing rotary strength mechanism is provided with a gear meshing radius increasing type effective decreasing rotary strength mechanism through a bearing for the gear meshing radius increasing type effective decreasing rotary strength mechanism A second rotating shaft for the effective decreasing gear strength mechanism, a second gear for the increasing gear meshing radius type effective decreasing gear strength mechanism and a third gear for the increasing gear meshing radius type effective decreasing gear strength mechanism are mounted on a shaft body of the second rotating shaft for the increasing gear meshing radius type effective decreasing gear strength mechanism, a first gear for the increasing gear meshing radius type effective decreasing gear strength mechanism and a fourth gear for the increasing gear meshing radius type effective decreasing gear strength mechanism are respectively mounted on the top end of the first rotating shaft for the increasing gear meshing radius type effective decreasing gear strength mechanism and the bottom end of the third rotating shaft for the increasing gear meshing radius type effective decreasing gear strength mechanism, and the first gear for the increasing gear meshing radius type effective decreasing gear strength mechanism is meshed with a tooth structure between the second gear for the increasing gear meshing radius type effective decreasing gear strength mechanism, and the third gear for the gear meshing radius increasing type rotating strength effective decreasing mechanism is meshed with a tooth structure between the fourth gear for the gear meshing radius increasing type rotating strength effective decreasing mechanism.

Further, the structure radius of the first gear reference circle for the gear engagement radius incremental rotary strength effective decreasing mechanism is smaller than the structure radius of the second gear reference circle for the gear engagement radius incremental rotary strength effective decreasing mechanism, the structure radius of the second gear reference circle for the gear engagement radius incremental rotary strength effective decreasing mechanism is larger than the structure radius of the third gear reference circle for the gear engagement radius incremental rotary strength effective decreasing mechanism, and the structure radius of the third gear for the gear engagement radius incremental rotary strength effective decreasing mechanism is smaller than the structure radius of the fourth gear reference circle for the gear engagement radius incremental rotary strength effective decreasing mechanism.

Furthermore, the end part of the first rotating shaft for the gear meshing radius increasing type rotating strength effective decreasing mechanism and the end part of the third rotating shaft for the gear meshing radius increasing type rotating strength effective decreasing mechanism are respectively and fixedly connected with the end parts of the motor spindle and the main rotating shaft.

Further, the helical spring compression annular array type maximum rotation strength effective control mechanism comprises a main hollow shell for the helical spring compression annular array type maximum rotation strength effective control mechanism, a main hollow section for the helical spring compression annular array type maximum rotation strength effective control mechanism, a rotating column for the helical spring compression annular array type maximum rotation strength effective control mechanism, a semicircular groove structure for the helical spring compression annular array type maximum rotation strength effective control mechanism, the spiral spring compression annular array type maximum rotation intensity effective control mechanism comprises an auxiliary hollow section for the spiral spring compression annular array type maximum rotation intensity effective control mechanism, a movable plate for the spiral spring compression annular array type maximum rotation intensity effective control mechanism, a spiral spring for the spiral spring compression annular array type maximum rotation intensity effective control mechanism and a push rod for the spiral spring compression annular array type maximum rotation intensity effective control mechanism; the center of one end face of the main hollow shell for the helical spring compression annular array type maximum rotation strength effective control mechanism is fixedly connected with the end part of a main rotating shaft, the center of the inside of the main hollow shell for the helical spring compression annular array type maximum rotation strength effective control mechanism is a main hollow interval for the helical spring compression annular array type maximum rotation strength effective control mechanism, a rotating column for the helical spring compression annular array type maximum rotation strength effective control mechanism is sleeved in the main hollow interval for the helical spring compression annular array type maximum rotation strength effective control mechanism, the inside of the main hollow shell for the helical spring compression annular array type maximum rotation strength effective control mechanism is an auxiliary hollow interval for the helical spring compression annular array type maximum rotation strength effective control mechanism, a movable plate for the helical spring compression annular array type maximum rotation strength effective control mechanism is placed in one end face of the secondary hollow section for the helical spring compression annular array type maximum rotation strength effective control mechanism, the helical spring compression annular array type maximum rotation strength effective control mechanism fixes a helical spring for the helical spring compression annular array type maximum rotation strength effective control mechanism between one ends of the movable plates for the helical spring compression annular array type maximum rotation strength effective control mechanism, one end face of the movable plate for the helical spring compression annular array type maximum rotation strength effective control mechanism is provided with a push rod for the helical spring compression annular array type maximum rotation strength effective control mechanism which is of an integral structure with the movable plate, and the push rod for the helical spring compression annular array type maximum rotation strength effective control mechanism penetrates through the main hollow shell for the helical spring compression annular array type maximum rotation strength effective control mechanism and is positioned in the main hollow section for the helical spring compression annular array type maximum rotation strength effective control mechanism, one end of the push rod for the helical spring compression annular array type maximum rotation strength effective control mechanism positioned in the main hollow section for the helical spring compression annular array type maximum rotation strength effective control mechanism is in a semicircular structure, a semicircular groove structure for the helical spring compression annular array type maximum rotation strength effective control mechanism used for placing the end part of the push rod for the helical spring compression annular array type maximum rotation strength effective control mechanism is arranged on the side surface of the rotating column for the helical spring compression annular array type maximum rotation strength effective control mechanism, one end of the rotary column for the spiral spring compression annular array type maximum rotation strength effective control mechanism is fixed with the end part of the auxiliary rotating shaft.

Further, the initial length of the spiral spring for the spiral spring compression annular array type maximum rotation strength effective control mechanism is larger than the length of the auxiliary hollow section for the spiral spring compression annular array type maximum rotation strength effective control mechanism.

Furthermore, the structural shape of the end part of the push rod for the helical spring compression annular array type maximum rotation strength effective control mechanism is consistent with the structural shape of the semicircular groove structure for the helical spring compression annular array type maximum rotation strength effective control mechanism.

Further, the reverse thread structure rotary type vertical height effective adjusting mechanism comprises a thread sleeve for a reverse thread structure rotary type vertical height effective adjusting mechanism, a thread section for a reverse thread structure rotary type vertical height effective adjusting mechanism, a thread structure for a reverse thread structure rotary type vertical height effective adjusting mechanism, a bottom threaded rod for a reverse thread structure rotary type vertical height effective adjusting mechanism, a top threaded rod for a reverse thread structure rotary type vertical height effective adjusting mechanism, a spacing hole for a reverse thread structure rotary type vertical height effective adjusting mechanism, a spacing rod for a reverse thread structure rotary type vertical height effective adjusting mechanism, a first connecting plate for a reverse thread structure rotary type vertical height effective adjusting mechanism, a shaft body mounting column for a reverse thread structure rotary type vertical height effective adjusting mechanism, a first bolt hole for a reverse thread structure rotary type vertical height effective adjusting mechanism and a reverse thread structure rotary type A shaft body mounting hole for the longitudinal height effective adjusting mechanism; the inside center of the threaded sleeve for the reverse threaded structure rotary type vertical height effective adjusting mechanism is provided with a threaded interval for the reverse threaded structure rotary type vertical height effective adjusting mechanism, which is communicated with two end faces of the threaded sleeve for the reverse threaded structure rotary type vertical height effective adjusting mechanism, the threaded sleeve for the reverse threaded structure rotary type vertical height effective adjusting mechanism is located on the inner wall of the threaded interval for the reverse threaded structure rotary type vertical height effective adjusting mechanism, the threaded structure for the reverse threaded structure rotary type vertical height effective adjusting mechanism is provided with a threaded structure for the reverse threaded structure rotary type vertical height effective adjusting mechanism, the bottom and the top of the threaded interval for the reverse threaded structure rotary type vertical height effective adjusting mechanism are respectively connected with a bottom threaded rod for the reverse threaded structure rotary type vertical height effective adjusting mechanism and a top threaded rod for the reverse threaded structure rotary type vertical height effective adjusting mechanism through a threaded structure The reverse thread structure rotary type vertical height effective adjusting mechanism uses a bottom threaded rod and a reverse thread structure rotary type vertical height effective adjusting mechanism uses a top threaded rod, the opposite ends are internally provided with limiting holes for the reverse thread structure rotary type vertical height effective adjusting mechanism, the limiting holes for the reverse thread structure rotary type vertical height effective adjusting mechanism are inserted into a limiting rod for the reverse thread structure rotary type vertical height effective adjusting mechanism, the other two ends of the reverse thread structure rotary type vertical height effective adjusting mechanism use the bottom threaded rod and the reverse thread structure rotary type vertical height effective adjusting mechanism use the top threaded rod are respectively provided with a first connecting plate for the reverse thread structure rotary type vertical height effective adjusting mechanism and a shaft body mounting column for the reverse thread structure rotary type vertical height effective adjusting mechanism, the first connecting plate for the reverse thread structure rotary type vertical height effective adjusting mechanism and the shaft body mounting column for the reverse thread structure rotary type vertical height effective adjusting mechanism are internally provided with a first bolt hole for the reverse thread structure rotary type vertical height effective adjusting mechanism and a shaft body mounting hole for the reverse thread structure rotary type vertical height effective adjusting mechanism.

Further, the thread structure for the vertical highly effective adjustment mechanism of reverse thread structure rotation type is including setting up the internal thread structure at the vertical highly effective adjustment mechanism of reverse thread structure rotation type with the threaded sleeve inner wall with set up the external thread structure on the vertical highly effective adjustment mechanism of reverse thread structure rotation type with the vertical highly effective adjustment mechanism of bottom threaded rod and the vertical highly effective adjustment mechanism of reverse thread structure rotation type with the top threaded rod body of rod, and is located the thread opposite direction of the thread structure on the vertical highly effective adjustment mechanism of reverse thread structure rotation type with the vertical highly effective adjustment mechanism of bottom threaded rod and the vertical highly effective adjustment mechanism of reverse thread structure rotation type with the top threaded rod body of rod.

Furthermore, the structural appearance of the cross section of the limiting hole for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure and the structural appearance of the cross section of the limiting rod for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure are both triangular structures, and the first bolt hole for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure and the end part of the shaft body mounting hole for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure are respectively mounted on the upper surface of the main body shell and the shaft body of the fixed shaft.

Compared with the prior art, the invention has the beneficial effects that: the invention can move on the guide steel wire rope, the movement can drive the cable rope, thereby realizing the installation of the cable, when driving, the maximum force during traction can be controlled, thereby preventing the damage of the overlarge traction force to the inner lead of the cable, and ensuring the performance of the cable, moreover, the device is provided with a gear engagement radius increasing type rotating strength effective degressive mechanism, which can effectively reduce the resistance during rotation, thereby effectively increasing the rotating strength of the driving motor, in addition, the device is provided with a spiral spring compression annular array type maximum rotating strength effective control mechanism, which can effectively control the rotating strength, thereby preventing the cable from being damaged due to the overlarge traction force, in addition, the device is provided with a reverse thread structure rotating type longitudinal height effective adjusting mechanism, which can adjust the distance, thereby controlling the occluding force of the rotating wheel pair to guide the steel rope and realizing the driving.

Drawings

FIG. 1 is a schematic view of a full-section structure of a steel wire driven cable traction device according to the present invention;

FIG. 2 is a schematic structural view of a mechanism for increasing the gear engagement radius of a rotating strength effectively decreasing mechanism in a steel wire driven cable traction device according to the present invention;

FIG. 3 is a schematic structural diagram of a maximum rotation strength effective control mechanism of a coil spring compression ring array type in a steel wire driven cable traction device according to the present invention;

FIG. 4 is a schematic structural view of a rotary type longitudinal height effective adjusting mechanism with a reverse thread structure in the steel wire driven cable traction device of the present invention;

in the figure: 1, a main body shell, 2, a driving motor mounting shell, 3, a driving motor, 4, a motor spindle, 5, a gear meshing radius increasing type effective decreasing rotary strength mechanism, 51, a hollow shell for the gear meshing radius increasing type effective decreasing rotary strength mechanism, 52, a hollow structure for the gear meshing radius increasing type effective decreasing rotary strength mechanism, 53, a first rotating shaft for the gear meshing radius increasing type effective decreasing rotary strength mechanism, 54, a bearing for the gear meshing radius increasing type effective decreasing rotary strength mechanism, 55, a second rotating shaft for the gear meshing radius increasing type effective decreasing rotary strength mechanism, 56, a third rotating shaft for the gear meshing radius increasing type effective decreasing rotary strength mechanism, 57, a first gear for the gear meshing radius increasing type effective decreasing rotary strength mechanism, 58, a second gear for the gear meshing radius increasing type effective decreasing rotary strength mechanism, 59, a third gear 510 for a gear-meshing radius increasing type rotation strength effective decreasing mechanism, a fourth gear 6 for a wheel-meshing radius increasing type rotation strength effective decreasing mechanism, a main rotating shaft 7, a coil spring compression ring array type maximum rotation strength effective control mechanism 71, a main hollow housing 72 for a coil spring compression ring array type maximum rotation strength effective control mechanism, a main hollow section 73 for a coil spring compression ring array type maximum rotation strength effective control mechanism, a rotating column 74 for a coil spring compression ring array type maximum rotation strength effective control mechanism, a semicircular groove structure 75 for a coil spring compression ring array type maximum rotation strength effective control mechanism, an auxiliary hollow section 76 for a coil spring compression ring array type maximum rotation strength effective control mechanism, a movable plate 76 for a coil spring compression ring array type maximum rotation strength effective control mechanism, 77, helical springs for a helical spring compression ring array type maximum rotation strength effective control mechanism, 78, a push rod for a helical spring compression ring array type maximum rotation strength effective control mechanism, 8, an auxiliary rotating shaft, 9, a concave space, 10, a main bevel gear, 11, a main groove structure, 12, a rotation driving shaft, 13, an auxiliary bevel gear, 14, a main rotating wheel, 15, a reverse thread structure rotary type longitudinal height effective adjustment mechanism, 151, a reverse thread structure rotary type threaded sleeve for a longitudinal height effective adjustment mechanism, 152, a reverse thread structure rotary type threaded section for a longitudinal height effective adjustment mechanism, 153, a reverse thread structure rotary type longitudinal height effective adjustment mechanism threaded structure, 154, a reverse thread structure rotary type longitudinal height effective adjustment mechanism bottom threaded rod, 155, a reverse thread structure rotary type top threaded rod for a longitudinal height effective adjustment mechanism, 156, the vertical highly effective adjustment mechanism of reverse screw-thread structure rotation type is with spacing hole, 157, the vertical highly effective adjustment mechanism of reverse screw-thread structure rotation type is with gag lever post, 158, the vertical highly effective adjustment mechanism of reverse screw-thread structure rotation type is with first connecting plate, 159, the vertical highly effective adjustment mechanism of reverse screw-thread structure rotation type is with axis body erection column, 1510, the vertical highly effective adjustment mechanism of reverse screw-thread structure rotation type is with first bolt hole, 1511, the vertical highly effective adjustment mechanism of reverse screw-thread structure rotation type is with axis body erection hole, 16, the fixed axle, 17, vice swiveling wheel.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, an embodiment of the present invention: the device comprises a main body shell 1, wherein a driving motor installation shell 2 is installed at the bottom of the main body shell 1 through bolts, a driving motor 3 is installed at one end inside the driving motor installation shell 2, a motor spindle 4 in the driving motor 3 is arranged, a gear meshing radius increasing type rotating strength effective decreasing mechanism 5 is installed at the end part of the motor spindle 4, a main rotating shaft 6 is installed at the center of one end of the gear meshing radius increasing type rotating strength effective decreasing mechanism 5, a spiral spring compression annular array type maximum rotating strength effective control mechanism 7 is installed at the end part of the main rotating shaft 6, the side surface of the spiral spring compression annular array type maximum rotating strength effective control mechanism 7 is installed inside the driving motor installation shell 2 through a main bearing, and a pair of rotating shafts 8 is installed at the center of one end of the spiral spring compression annular array type maximum rotating strength effective control mechanism 7, the inside of main part casing 1 is provided with character cut in bas-relief space 9, a main bevel gear 10 is installed at the one end that lies in character cut in bas-relief space 9 to vice rotation axis 8, the side of main bevel gear 10 meshes two opposite vice bevel gears 13 at perpendicular angle, the center of main part casing 1 upper surface is provided with main groove structure 11, the internally mounted of main part casing 1 has two opposite rotation drive shafts 12, two rotation drive shafts 12 install respectively in the center of a section of two vice bevel gears 13 at the tip towards the outside, two rotation drive shafts 12 are in the one end installation main swiveling wheel 14 that lies in main groove structure 11 is inside, the upper surface mounting of main part casing 1 two opposite reverse screw thread structure rotation type vertical highly effective adjustment mechanism 15, two a fixed axle 16 is installed on the top of reverse screw structure rotation type vertical highly effective adjustment mechanism 15, the central part of the fixed shaft 16 is provided with a pair of rotating wheels 17 through a main bearing, the main rotating wheel 14 and the pair of rotating wheels 17 are symmetrically arranged up and down, and the two rotating wheels are provided with annular groove structures at the circumference.

Referring to fig. 2, the gear-meshing-radius-increasing-type effective decreasing mechanism 5 for rotational strength includes a hollow housing 51 for a gear-meshing-radius-increasing-type effective decreasing mechanism for rotational strength, a hollow structure 52 for a gear-meshing-radius-increasing-type effective decreasing mechanism for rotational strength, a first rotating shaft 53 for a gear-meshing-radius-increasing-type effective decreasing mechanism for rotational strength, a bearing 54 for a gear-meshing-radius-increasing-type effective decreasing mechanism for rotational strength, a second rotating shaft 55 for a gear-meshing-radius-increasing-type effective decreasing mechanism for rotational strength, a third rotating shaft 57 for a gear-meshing-radius-increasing-type effective decreasing mechanism for rotational strength, a first gear 58 for a gear-meshing-radius-increasing-type effective decreasing mechanism for rotational strength, a second gear 59 for a gear-meshing-radius-increasing-type effective decreasing mechanism for rotational strength, a third gear 510 for a gear-meshing-radius-increasing-type effective decreasing mechanism for rotational strength 511; a hollow structure 52 for the gear engagement radius increasing type effective decreasing rotary strength mechanism is arranged in the hollow shell 51 for the gear engagement radius increasing type effective decreasing rotary strength mechanism, a first rotating shaft 53 for the gear engagement radius increasing type effective decreasing rotary strength mechanism is arranged at the bottom center of the hollow shell 51 for the gear engagement radius increasing type effective decreasing rotary strength mechanism through a bearing 54 for the gear engagement radius increasing type effective decreasing rotary strength mechanism, a third rotating shaft 57 for the gear engagement radius increasing type effective decreasing rotary strength mechanism is arranged at the top center of the hollow shell 51 for the gear engagement radius increasing type effective decreasing rotary strength mechanism through the bearing 54 for the gear engagement radius increasing type effective decreasing rotary strength mechanism, and a side surface of the hollow shell 51 for the gear engagement radius increasing type effective decreasing rotary strength mechanism is provided with a third rotating shaft 57 for the gear engagement radius increasing type effective decreasing rotary strength mechanism through the bearing 54 for the gear engagement radius increasing type effective decreasing rotary strength mechanism A second rotating shaft 55 for a gear-meshing-radius-increasing type effective decreasing rotary strength mechanism, wherein a second gear 59 for a gear-meshing-radius-increasing type effective decreasing rotary strength mechanism and a third gear 510 for a gear-meshing-radius-increasing type effective decreasing rotary strength mechanism are mounted on a shaft body of the second rotating shaft 55 for a gear-meshing-radius-increasing type effective decreasing rotary strength mechanism, a first gear 58 for a gear-meshing-radius-increasing type effective decreasing rotary strength mechanism and a fourth gear 511 for a gear-meshing-radius-increasing type effective decreasing rotary strength mechanism are mounted on a top end of the first rotating shaft 53 for a gear-meshing-radius-increasing type effective decreasing rotary strength mechanism and a bottom end of the third rotating shaft 57 for a gear-meshing-radius-increasing type effective decreasing rotary strength mechanism, respectively, and the first gear 58 for a gear-meshing-radius-increasing type effective decreasing rotary strength mechanism and the second gear 59 for a gear-meshing-radius-increasing type effective decreasing rotary strength mechanism The tooth structure of the gear engagement radius increasing type rotating strength effective decreasing mechanism is engaged with the tooth structure between the third gear 510 and the fourth gear 511; the structure radius of the reference circle of the first gear 58 for the gear engagement radius incremental rotary strength effective decreasing mechanism is smaller than the structure radius of the reference circle of the second gear 59 for the gear engagement radius incremental rotary strength effective decreasing mechanism, the structure radius of the reference circle of the second gear 59 for the gear engagement radius incremental rotary strength effective decreasing mechanism is larger than the structure radius of the reference circle of the third gear 510 for the gear engagement radius incremental rotary strength effective decreasing mechanism, and the structure radius of the third gear 510 for the gear engagement radius incremental rotary strength effective decreasing mechanism is smaller than the structure radius of the reference circle of the fourth gear 511 for the gear engagement radius incremental rotary strength effective decreasing mechanism; the end part of the first rotating shaft 53 for the gear meshing radius increasing type rotating strength effective decreasing mechanism and the end part of the third rotating shaft 57 for the gear meshing radius increasing type rotating strength effective decreasing mechanism are respectively and fixedly connected with the end parts of the motor spindle 4 and the main rotating shaft 6, and the main functions of the mechanism are as follows: the reduction of the rotation force can be realized by utilizing the gear meshing principle.

Referring to fig. 3, the helical spring compression ring array type maximum rotation strength effective control mechanism 7 includes a main hollow housing 71 for the helical spring compression ring array type maximum rotation strength effective control mechanism, a main hollow section 72 for the helical spring compression ring array type maximum rotation strength effective control mechanism, a rotary column 73 for the helical spring compression ring array type maximum rotation strength effective control mechanism, a semicircular groove structure 74 for the helical spring compression ring array type maximum rotation strength effective control mechanism, a pair of hollow sections 75 for the helical spring compression annular array type maximum rotation intensity effective control mechanism, a movable plate 76 for the helical spring compression annular array type maximum rotation intensity effective control mechanism, a helical spring 77 for the helical spring compression annular array type maximum rotation intensity effective control mechanism, and a push rod 78 for the helical spring compression annular array type maximum rotation intensity effective control mechanism; the center of one end face of the main hollow shell 71 for the helical spring compression annular array type maximum rotation strength effective control mechanism is fixedly connected with the end part of a main rotating shaft 6, the center of the inside of the main hollow shell 71 for the helical spring compression annular array type maximum rotation strength effective control mechanism is a main hollow section 72 for the helical spring compression annular array type maximum rotation strength effective control mechanism, the main hollow shell 71 for the helical spring compression annular array type maximum rotation strength effective control mechanism is sleeved with a rotating column 73 for the helical spring compression annular array type maximum rotation strength effective control mechanism in the main hollow section 72 for the helical spring compression annular array type maximum rotation strength effective control mechanism, and the inside of the main hollow shell 71 for the helical spring compression annular array type maximum rotation strength effective control mechanism is an auxiliary hollow section for the helical spring compression annular array type maximum rotation strength effective control mechanism A section 75 in which a coil spring compression ring array type maximum rotation strength effective control mechanism movable plate 76 is disposed inside the coil spring compression ring array type maximum rotation strength effective control mechanism auxiliary hollow section 75 on one end surface of the coil spring compression ring array type maximum rotation strength effective control mechanism main hollow section 72, a coil spring compression ring array type maximum rotation strength effective control mechanism coil spring 77 is fixed between one ends of the coil spring compression ring array type maximum rotation strength effective control mechanism movable plates 76, one end surface of the coil spring compression ring array type maximum rotation strength effective control mechanism movable plate 76 is provided with a coil spring compression ring array type maximum rotation strength effective control mechanism push rod 78 integrally structured therewith, and the helical spring compression ring array type maximum rotation strength effective control mechanism push rod 78 penetrates the helical spring compression ring array type maximum rotation strength effective control mechanism main hollow housing 71 and is positioned inside the helical spring compression ring array type maximum rotation strength effective control mechanism main hollow section 72, the helical spring compression ring array type maximum rotation strength effective control mechanism push rod 78 is in a semicircular structure at one end of the helical spring compression ring array type maximum rotation strength effective control mechanism main hollow section 72, a helical spring compression ring array type maximum rotation strength effective control mechanism rotary column 73 side surface is provided with a helical spring compression ring array type maximum rotation strength effective control mechanism semicircular groove structure 74 for placing the end of the helical spring compression ring array type maximum rotation strength effective control mechanism push rod 78, one end of the spiral spring compression annular array type maximum rotation strength effective control mechanism is fixed with the end part of the auxiliary rotating shaft 8 by one end of a rotating column 73; the initial length of the coil spring 77 for the helical spring compression annular array type maximum rotation intensity effective control mechanism is greater than the length of the auxiliary hollow section 75 for the helical spring compression annular array type maximum rotation intensity effective control mechanism; the structural shape of the end of the push rod 78 for the helical spring compression annular array type maximum rotation strength effective control mechanism is consistent with the structural shape of the semicircular groove structure 74 for the helical spring compression annular array type maximum rotation strength effective control mechanism, and the main functions are as follows: when the driving resistance is too large, the resistance is larger than the elasticity of the helical spring 77 for the helical spring compression annular array type maximum rotation strength effective control mechanism, the helical spring 77 for the helical spring compression annular array type maximum rotation strength effective control mechanism is compressed, and under the causal action, the relative rotation between the two rotating shafts is realized, so that the protection effect is achieved, and the elasticity of the helical spring 77 for the helical spring compression annular array type maximum rotation strength effective control mechanism is smaller than the strength of the maximum deformation tension value of the cable when the cable is installed.

Referring to fig. 4, the reverse-threaded-structure rotary type effective longitudinal height adjustment mechanism 15 includes a reverse-threaded-structure rotary type effective longitudinal height adjustment mechanism threaded sleeve 151, a reverse-threaded-structure rotary type effective longitudinal height adjustment mechanism threaded section 152, a reverse-threaded-structure rotary type effective longitudinal height adjustment mechanism threaded structure 153, a reverse-threaded-structure rotary type effective longitudinal height adjustment mechanism bottom threaded rod 154, a reverse-threaded-structure rotary type effective longitudinal height adjustment mechanism top threaded rod 155, a reverse-threaded-structure rotary type effective longitudinal height adjustment mechanism limiting hole 156, a reverse-threaded-structure rotary type effective longitudinal height adjustment mechanism limiting rod 157, a reverse-threaded-structure rotary type effective longitudinal height adjustment mechanism first connecting plate 158, a reverse-threaded-structure rotary type effective longitudinal height adjustment mechanism mounting post 159, a reverse, A first bolt hole 1510 for a rotary type longitudinal height effective adjustment mechanism of a reverse thread structure and a shaft body mounting hole 1511 for a rotary type longitudinal height effective adjustment mechanism of a reverse thread structure; the center inside the threaded sleeve 151 for the reverse thread structure rotary type vertical height effective adjusting mechanism is provided with a threaded interval 152 for the reverse thread structure rotary type vertical height effective adjusting mechanism communicating with two end faces of the threaded sleeve 151 for the reverse thread structure rotary type vertical height effective adjusting mechanism, the threaded sleeve 151 for the reverse thread structure rotary type vertical height effective adjusting mechanism is positioned at the inner wall of the threaded interval 152 for the reverse thread structure rotary type vertical height effective adjusting mechanism is provided with a threaded structure 153 for the reverse thread structure rotary type vertical height effective adjusting mechanism, the bottom and the top of the threaded interval 152 for the reverse thread structure rotary type vertical height effective adjusting mechanism are respectively connected with a bottom threaded rod 154 for the reverse thread structure rotary type vertical height effective adjusting mechanism and a vertical height effective adjusting mechanism for the reverse thread structure rotary type vertical height effective adjusting mechanism through the threaded structure 153 for the reverse thread structure rotary type vertical height effective adjusting mechanism A top threaded rod 155 for a joint mechanism, a bottom threaded rod 154 for a rotary type longitudinal height effective adjusting mechanism of a reverse thread structure and a top threaded rod 155 for a rotary type longitudinal height effective adjusting mechanism of a reverse thread structure are respectively provided with a limiting hole 156 for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure inside the opposite end, a limiting rod 157 for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure is inserted inside the limiting hole 156 for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure, the other two ends of the bottom threaded rod 154 for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure and the top threaded rod 155 for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure are respectively provided with a first connecting plate 158 for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure and a mounting post 159 for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure, a first bolt hole 1510 for the rotary type longitudinal height effective adjustment mechanism of the reverse thread structure and a shaft body mounting hole 1511 for the rotary type longitudinal height effective adjustment mechanism of the reverse thread structure are arranged inside the first connecting plate 158 for the rotary type longitudinal height effective adjustment mechanism of the reverse thread structure and the shaft body mounting column 159 for the rotary type longitudinal height effective adjustment mechanism of the reverse thread structure; the thread structure 153 for the reverse thread structure rotary type longitudinal height effective adjusting mechanism comprises an internal thread structure arranged on the inner wall of a thread sleeve 151 for the reverse thread structure rotary type longitudinal height effective adjusting mechanism and external thread structures arranged on a bottom threaded rod 154 for the reverse thread structure rotary type longitudinal height effective adjusting mechanism and a top threaded rod 155 for the reverse thread structure rotary type longitudinal height effective adjusting mechanism, and the thread directions of the thread structures on the rod bodies of the bottom threaded rod 154 for the reverse thread structure rotary type longitudinal height effective adjusting mechanism and the top threaded rod 155 for the reverse thread structure rotary type longitudinal height effective adjusting mechanism are opposite; the structural appearance of the cross section of the limiting hole 156 for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure and the structural appearance of the cross section of the limiting rod 157 for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure are both triangular structures, the end parts of the first bolt hole 1510 for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure and the shaft body mounting hole 1511 for the rotary type longitudinal height effective adjusting mechanism of the reverse thread structure are respectively mounted on the upper surface of the main body shell 1 and the shaft body of the fixed shaft 16, and the main functions are as follows: when the rotation is performed, the distance adjustment function can be performed, so that the occlusal force can be adjusted.

The specific use mode is as follows: in the work of the invention, a guide steel wire rope passes through the annular groove structures in the main rotating wheel 14 and the auxiliary rotating wheel 17, then the rotary type longitudinal height effective adjusting mechanism 15 with an adjusting reverse thread structure is adopted, so that the main rotating wheel 14 and the auxiliary rotating wheel 17 are meshed with the guide steel wire rope, then a cable is fixed on the back of the main body shell 1 through a fixing device in the prior art, then a mobile power supply is carried, an electric power plug of the driving motor 3 is inserted into the mobile power supply, under the linkage action of the components, the main rotating wheel 14 is driven to rotate, further the driving is realized, when the driving motor 3 rotates but the main rotating wheel 14 does not rotate, the surface tension resistance is overlarge, the continuous traction is stopped, and the corresponding arrangement is carried out.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (10)

1. The utility model provides a steel wire drive formula cable conductor draw gear, includes main part casing (1), its characterized in that: the bottom of main part casing (1) is through a bolt installation driving motor installation shell (2), a driving motor (3) is installed to the inside one end of driving motor installation shell (2), motor spindle (4) in driving motor (3), the effective degressive mechanism of gear engagement radius incremental type rotation intensity (5) is installed to the tip of motor spindle (4), a main rotation axle (6) is installed at gear engagement radius incremental type rotation intensity effective degressive mechanism (5) one end center, the tip installation of main rotation axle (6) is the effective control mechanism of the maximum rotation intensity of coil spring compression annular array (7), the side of the effective control mechanism of the maximum rotation intensity of coil spring compression annular array (7) is installed inside driving motor installation shell (2) through the base bearing, the effective control mechanism of the maximum rotation intensity of coil spring compression annular array (7) one end center installation pair rotation The shaft (8), the inside of main part casing (1) is provided with character cut in bas-relief space (9), vice rotation axis (8) is in the one end installation a main bevel gear (10) that is located character cut in bas-relief space (9) inside, the side of main bevel gear (10) is at two opposite vice bevel gear (13) of perpendicular angle meshing, the center of main part casing (1) upper surface is provided with main groove structure (11), the internally mounted of main part casing (1) has two opposite rotation drive axle (12), two rotation drive axle (12) are installed respectively at the center of a section of two vice bevel gear (13) at the tip towards the outside, two rotation drive axle (12) are in the one end of being located main groove structure (11) inside installs a main swiveling wheel (14), the upper surface installation two opposite reverse screw thread structure rotation type vertical height of main part effective adjustment mechanism (15), two a fixed axle (16) is installed on the top end of the vertical highly effective adjustment mechanism of reverse thread structure rotation type (15), a pair of swiveling wheel (17) is installed through the main bearing at the central point of fixed axle (16), main swiveling wheel (14) and vice swiveling wheel (17) are set up in the longitudinal symmetry, and both are provided with annular groove structure in circumference department.

2. The steel wire driven cable traction device as claimed in claim 1, wherein: the gear meshing radius increasing type rotating strength effective decreasing mechanism (5) comprises a hollow shell (51) for a gear meshing radius increasing type rotating strength effective decreasing mechanism, a hollow structure (52) for the gear meshing radius increasing type rotating strength effective decreasing mechanism, a first rotating shaft (53) for the gear meshing radius increasing type rotating strength effective decreasing mechanism, a bearing (54) for the gear meshing radius increasing type rotating strength effective decreasing mechanism, a second rotating shaft (55) for the gear meshing radius increasing type rotating strength effective decreasing mechanism, a third rotating shaft (57) for the gear meshing radius increasing type rotating strength effective decreasing mechanism, a first gear (58) for the gear meshing radius increasing type rotating strength effective decreasing mechanism, a second gear (59) for the gear meshing radius increasing type rotating strength effective decreasing mechanism, a third gear (510) for the gear meshing radius increasing type rotating strength effective decreasing mechanism and a gear meshing radius increasing type rotating strength rotating rotation A fourth gear (511) for a rotation intensity effective decreasing mechanism; a hollow structure (52) for the gear meshing radius increasing type rotary strength effective decreasing mechanism is arranged in the hollow shell (51) for the gear meshing radius increasing type rotary strength effective decreasing mechanism, a first rotating shaft (53) for the gear meshing radius increasing type rotary strength effective decreasing mechanism is arranged at the bottom center of the hollow shell (51) for the gear meshing radius increasing type rotary strength effective decreasing mechanism through a bearing (54) for the gear meshing radius increasing type rotary strength effective decreasing mechanism, a third rotating shaft (57) for the gear meshing radius increasing type rotary strength effective decreasing mechanism is arranged at the top center of the hollow shell (51) for the gear meshing radius increasing type rotary strength effective decreasing mechanism through the bearing (54) for the gear meshing radius increasing type rotary strength effective decreasing mechanism, and the side surface of the hollow shell (51) for the gear meshing radius increasing type rotary strength effective decreasing mechanism is increased through the gear meshing radius increasing type rotary strength effective decreasing mechanism A second rotating shaft (55) for a gear mesh radius increasing type rotating strength effective decreasing mechanism is arranged on a bearing (54) for the gear mesh radius increasing type rotating strength effective decreasing mechanism, a second gear (59) for the gear mesh radius increasing type rotating strength effective decreasing mechanism and a third gear (510) for the gear mesh radius increasing type rotating strength effective decreasing mechanism are arranged on a shaft body of the second rotating shaft (55) for the gear mesh radius increasing type rotating strength effective decreasing mechanism, a first gear (58) for the gear mesh radius increasing type rotating strength effective decreasing mechanism and a fourth gear (511) for the gear mesh radius increasing type rotating strength effective decreasing mechanism are respectively arranged at the top end of a first rotating shaft (53) for the gear mesh radius increasing type rotating strength effective decreasing mechanism and the bottom end of a third rotating shaft (57) for the gear mesh radius increasing type rotating strength effective decreasing mechanism, and the tooth structure between the first gear (58) and the second gear (59) is meshed, and the third gear (510) and the fourth gear (511) are meshed.

3. The steel wire driven cable traction device as claimed in claim 2, wherein: the structure radius of the reference circle of the first gear (58) for the gear engagement radius increasing type effective decreasing mechanism of the rotary strength is smaller than the structure radius of the reference circle of the second gear (59) for the gear engagement radius increasing type effective decreasing mechanism of the rotary strength, the structure radius of the reference circle of the second gear (59) for the gear engagement radius increasing type effective decreasing mechanism of the rotary strength is larger than the structure radius of the reference circle of the third gear (510) for the gear engagement radius increasing type effective decreasing mechanism of the rotary strength, and the structure radius of the third gear (510) for the gear engagement radius increasing type effective decreasing mechanism of the rotary strength is smaller than the structure radius of the reference circle of the fourth gear (511) for the gear engagement radius increasing type effective decreasing mechanism of the rotary strength.

4. The steel wire driven cable traction device as claimed in claim 2, wherein: the end part of the first rotating shaft (53) for the gear meshing radius increasing type rotating strength effective decreasing mechanism and the end part of the third rotating shaft (57) for the gear meshing radius increasing type rotating strength effective decreasing mechanism are respectively and fixedly connected with the end parts of the motor spindle (4) and the main rotating shaft (6).

5. The steel wire driven cable traction device as claimed in claim 1, wherein: the helical spring compression annular array type maximum rotation strength effective control mechanism (7) comprises a main hollow shell (71) for the helical spring compression annular array type maximum rotation strength effective control mechanism, a main hollow interval (72) for the helical spring compression annular array type maximum rotation strength effective control mechanism, a rotating column (73) for the helical spring compression annular array type maximum rotation strength effective control mechanism and a semicircular groove structure (74) for the helical spring compression annular array type maximum rotation strength effective control mechanism, the device comprises auxiliary hollow sections (75) for the helical spring compression annular array type maximum rotation strength effective control mechanism, a movable plate (76) for the helical spring compression annular array type maximum rotation strength effective control mechanism, helical springs (77) for the helical spring compression annular array type maximum rotation strength effective control mechanism and push rods (78) for the helical spring compression annular array type maximum rotation strength effective control mechanism; the center of an end face of a main hollow shell (71) for the effective control mechanism of the annular array of the compression spiral type maximum rotation intensity of the spiral spring and the end part of a main rotating shaft (6) are fixedly connected, the center of the inside of the main hollow shell (71) for the effective control mechanism of the annular array of the compression spiral type maximum rotation intensity of the spiral spring is the main hollow interval (72) for the effective control mechanism of the annular array of the compression spiral type maximum rotation intensity of the spiral spring, the main hollow shell (71) for the effective control mechanism of the annular array of the compression spiral type maximum rotation intensity is located inside the main hollow interval (72) for the effective control mechanism of the annular array of the compression spiral spring, a rotating column (73) for the effective control mechanism of the annular array of the compression spiral type maximum rotation intensity is sleeved inside the main hollow shell (71) for the effective control mechanism of the annular array of the compression spiral spring, and the inside of The inside of the auxiliary hollow interval (75) for the effective control mechanism of the maximum rotation intensity of the helical spring compression annular array type is located at one end face of the main hollow interval (72) for the effective control mechanism of the maximum rotation intensity of the helical spring compression annular array type, a movable plate (76) for the effective control mechanism of the maximum rotation intensity of the helical spring compression annular array type is placed at one end face of the main hollow interval (72) for the effective control mechanism of the maximum rotation intensity of the helical spring compression annular array type, the auxiliary hollow interval (75) for the effective control mechanism of the maximum rotation intensity of the helical spring compression annular array type is located between one ends of the movable plates (76) for the effective control mechanism of the maximum rotation intensity of the helical spring compression annular array type, a helical spring (77) for the effective control mechanism of the maximum rotation intensity of the helical spring compression annular array type is arranged at one end face of the movable plate (76) for The push rod (78) for the spiral spring compression annular array type maximum rotation strength effective control mechanism is arranged on the side surface of the rotary column (73) for the spiral spring compression annular array type maximum rotation strength effective control mechanism, the push rod (78) for the spiral spring compression annular array type maximum rotation strength effective control mechanism penetrates through the main hollow shell (71) for the spiral spring compression annular array type maximum rotation strength effective control mechanism and is located in the main hollow interval (72) for the spiral spring compression annular array type maximum rotation strength effective control mechanism, the push rod (78) for the spiral spring compression annular array type maximum rotation strength effective control mechanism is located at one end of the main hollow interval (72) for the spiral spring compression annular array type maximum rotation strength effective control mechanism and is of a semicircular structure, and the side surface of the rotary column (73) for the spiral spring compression annular array type maximum rotation strength effective control mechanism is provided with a push rod (78) for placing the spiral spring compression (78) The spiral spring at the end part compresses the semicircular groove structure (74) for the annular array type maximum rotation intensity effective control mechanism, and one end of the rotary column (73) for the annular array type maximum rotation intensity effective control mechanism is fixed with the end part of the auxiliary rotating shaft (8).

6. The steel wire driven cable traction device according to claim 5, wherein: the initial length of the spiral spring (77) for the spiral spring compression annular array type maximum rotation intensity effective control mechanism is larger than the length of the auxiliary hollow section (75) for the spiral spring compression annular array type maximum rotation intensity effective control mechanism.

7. The steel wire driven cable traction device according to claim 5, wherein: the structural shape of the end part of the push rod (78) for the helical spring compression annular array type maximum rotation intensity effective control mechanism is consistent with the structural shape of the semicircular groove structure (74) for the helical spring compression annular array type maximum rotation intensity effective control mechanism.

8. The steel wire driven cable traction device as claimed in claim 1, wherein: the reverse thread structure rotary type longitudinal height effective adjusting mechanism (15) comprises a thread sleeve (151) for a reverse thread structure rotary type longitudinal height effective adjusting mechanism, a thread section (152) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism, a thread structure (153) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism, a bottom threaded rod (154) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism, a top threaded rod (155) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism, a limiting hole (156) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism, a limiting rod (157) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism, a first connecting plate (158) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism, a shaft body mounting column (159) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism, A first bolt hole (1510) for a rotary type longitudinal height effective adjustment mechanism with a reverse thread structure and a shaft body mounting hole (1511) for a rotary type longitudinal height effective adjustment mechanism with a reverse thread structure; the inside center of the threaded sleeve (151) for the vertical highly effective adjustment mechanism of reverse thread structure rotation type is provided with the threaded interval (152) for the vertical highly effective adjustment mechanism of reverse thread structure rotation type of the threaded sleeve (151) for the vertical highly effective adjustment mechanism of reverse thread structure rotation type both ends face, the threaded sleeve (151) for the vertical highly effective adjustment mechanism of reverse thread structure rotation type is located the inner wall of the threaded interval (152) for the vertical highly effective adjustment mechanism of reverse thread structure rotation type is provided with the threaded structure (153) for the vertical highly effective adjustment mechanism of reverse thread structure rotation type, the bottom and the top of the threaded interval (152) for the vertical highly effective adjustment mechanism of reverse thread structure rotation type are connected with the bottom threaded rod (154) for the vertical highly effective adjustment mechanism of reverse thread structure rotation type through the threaded structure (153) for the vertical highly effective adjustment mechanism of reverse thread structure rotation type respectively ) And the vertical effective adjustment mechanism of high height of reverse thread structure rotation type is with top threaded rod (155), the vertical effective adjustment mechanism of high height of reverse thread structure rotation type is with bottom threaded rod (154) and the vertical effective adjustment mechanism of high height of reverse thread structure rotation type is with top threaded rod (155) all be provided with the vertical effective adjustment mechanism of high height of reverse thread structure rotation type in opposite end inside spacing hole (156), two the inside of the vertical effective adjustment mechanism of high height of reverse thread structure rotation type is with spacing rod (157) for the vertical effective adjustment mechanism of high height of reverse thread structure rotation type, the vertical effective adjustment mechanism of high height of reverse thread structure rotation type is with bottom threaded rod (154) and the vertical effective adjustment mechanism of high height of reverse thread structure rotation type is with first connecting plate (158) and the vertical effective adjustment mechanism of reverse thread structure rotation type for top threaded rod (155) are installed respectively at other both ends And a first bolt hole (1510) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism and a shaft body mounting hole (1511) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism are arranged inside the first connecting plate (158) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism and the shaft body mounting column (159) for the reverse thread structure rotary type longitudinal height effective adjusting mechanism.

9. The steel wire driven cable traction device according to claim 8, wherein: the thread structure (153) for the vertical highly effective adjustment mechanism of reverse thread structure rotation type is including setting up the internal thread structure at the vertical highly effective adjustment mechanism of reverse thread structure rotation type with thread sleeve (151) inner wall and setting up the external thread structure on the vertical highly effective adjustment mechanism of reverse thread structure rotation type is with bottom threaded rod (154) and the vertical highly effective adjustment mechanism of reverse thread structure rotation type with top threaded rod (155) body of rod, and is located the vertical highly effective adjustment mechanism of reverse thread structure rotation type is with bottom threaded rod (154) and the vertical highly effective adjustment mechanism of reverse thread structure rotation type is with the thread direction of the thread structure on the body of rod of top threaded rod (155) body of rod.

10. The steel wire driven cable traction device according to claim 8, wherein: the cross section structure appearance of the limiting hole (156) for the rotary type vertical height effective adjusting mechanism of the reverse thread structure and the cross section structure appearance of the limiting rod (157) for the rotary type vertical height effective adjusting mechanism of the reverse thread structure are both triangular structures, and the end parts of the first bolt hole (1510) for the rotary type vertical height effective adjusting mechanism of the reverse thread structure and the shaft body mounting hole (1511) for the rotary type vertical height effective adjusting mechanism of the reverse thread structure are respectively mounted on the upper surface of the main body shell (1) and the shaft body of the fixed shaft (16).

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