CN111365441A - Rotary centrifugal force type tension driving device - Google Patents

Abstract

The invention discloses a rotary centrifugal force type tension driving device which comprises a bottom mounting substrate. The invention utilizes the rapid rotation capability of the driving motor to drive a plurality of components to rotate to generate centrifugal force, a plurality of centrifugal forces are fed and connected in parallel, can provide combined type pulling force and controllable type pulling force, is rapid and effective, and has low requirement on the sealing performance of the components, therefore, the parts work conveniently, moreover, the device is provided with an annular array elastic contact type rotation resistance control mechanism, the phenomenon of breakage of the inner steel wire rope caused by overlarge resistance of rotation is prevented, in addition, the device has a supporting mechanism with a spiral spring elastically abutted against and installed to generate an upward thrust to stabilize the working state of the component, and in addition, the device has wire rope pulling force and connecting plate connection formula middle part dynamics conversion mechanism, can turn into the total pulling force at connecting plate position with a plurality of wire rope's pulling force.

Description

Rotary centrifugal force type tension driving device

Technical Field

The invention relates to the technical field of tension driving devices, in particular to a rotary centrifugal force type tension driving device.

Background

At present, a tension driving device is needed in some specific places, and the main functions of the tension driving device are as follows: the existing tension driving device is driven by gas or hydraulic pressure, and the mode has large limitation and low efficiency.

Disclosure of Invention

The present invention is directed to a rotary centrifugal force type tension driving device to solve the above problems.

In order to achieve the purpose, the invention provides the following technical scheme: a rotary centrifugal force type tension driving device comprises a bottom mounting base plate, wherein a main supporting rod and an auxiliary supporting rod are respectively mounted on two sides of the upper surface of the bottom mounting base plate, a main first shaft sleeve shell and a main second shaft sleeve shell are respectively mounted at the tops of the main supporting rod and the auxiliary supporting rod, a driving motor and a rotary hollow pipeline body are respectively mounted inside the main first shaft sleeve shell and the main second shaft sleeve shell, one side of the rotary hollow pipeline body is provided with a rotary circular body shell of an integrated structure, a main moving space and a plurality of auxiliary moving spaces arranged in an annular array are respectively arranged inside the rotary hollow pipeline body and the rotary circular body shell, a fillet structure is arranged at a communication and connection position of the main moving space and the plurality of auxiliary moving spaces arranged in the annular array, and a main moving cylinder is mounted inside each auxiliary moving space arranged in the annular array, a steel wire rope tension and connecting plate connection type middle force conversion mechanism is arranged in the main moving space, a main mosaic block is arranged at the center of each main moving cylinder facing the inner side through a main bearing, one end of a steel wire rope body is inlaid in the main mosaic block, the other end of the steel wire rope is arranged on one end face of the steel wire rope tension and connecting plate connection type middle force conversion mechanism, a main connecting rod is arranged on the other end face of the steel wire rope tension and connecting plate connection type middle force conversion mechanism through a plate body and bolts, a main mounting plate is arranged at the end part of the main connecting rod, an annular array elastic abutting type rotation resistance control mechanism is arranged at the end part of a motor main shaft in the driving motor, a main first rotating shaft is arranged at the center of one end of the annular array elastic abutting type rotation resistance control mechanism, and a shaft body of the main first rotating shaft is arranged in a main third shaft shell, the bottom of main third axle body shell is installed a helical spring elasticity and is contradicted installation formula supporting mechanism, the bolt mounting is passed through at bottom mounting substrate's upper surface in helical spring elasticity conflict installation formula supporting mechanism's bottom, the tip of main first rotation axis is passed through the auxiliary connection board and is installed at rotatory circular body shell terminal surface center.

Further, the circular array elastic abutting type rotation resistance control mechanism comprises a main hollow shell for the circular array elastic abutting type rotation resistance control mechanism, a main hollow interval for the circular array elastic abutting type rotation resistance control mechanism, a rotary column for the circular array elastic abutting type rotation resistance control mechanism, a semicircular groove structure for the circular array elastic abutting type rotation resistance control mechanism, an auxiliary hollow interval for the circular array elastic abutting type rotation resistance control mechanism, a movable plate for the circular array elastic abutting type rotation resistance control mechanism, a spiral spring for the circular array elastic abutting type rotation resistance control mechanism and a push rod for the circular array elastic abutting type rotation resistance control mechanism; the center of one end face of the main hollow shell for the annular array elastic abutting type rotation resistance control mechanism is fixedly connected with the end part of the motor spindle, the center of the inside of the main hollow shell for the annular array elastic abutting type rotation resistance control mechanism is a main hollow interval for the annular array elastic abutting type rotation resistance control mechanism, a rotary column for the annular array elastic abutting type rotation resistance control mechanism is sleeved inside the main hollow interval for the annular array elastic abutting type rotation resistance control mechanism by the main hollow shell for the annular array elastic abutting type rotation resistance control mechanism, an auxiliary hollow interval for the annular array elastic abutting type rotation resistance control mechanism is arranged inside the main hollow shell for the annular array elastic abutting type rotation resistance control mechanism, and the inside of the auxiliary hollow interval for the annular array elastic abutting type rotation resistance control mechanism is arranged inside the main hollow interval for the annular array elastic abutting type rotation resistance control mechanism One end face of the interval is provided with a movable plate for the annular array elastic abutting type rotation resistance control mechanism, a spiral spring for the annular array elastic abutting type rotation resistance control mechanism is fixed between one ends of the movable plates for the annular array elastic abutting type rotation resistance control mechanism in an auxiliary hollow interval, one end face of the movable plate for the annular array elastic abutting type rotation resistance control mechanism is provided with a push rod for the annular array elastic abutting type rotation resistance control mechanism in an integrated structure with the movable plate, the push rod for the annular array elastic abutting type rotation resistance control mechanism penetrates through a main hollow shell for the annular array elastic abutting type rotation resistance control mechanism and is located in the main hollow interval for the annular array elastic abutting type rotation resistance control mechanism, and the push rod for the annular array elastic abutting type rotation resistance control mechanism is located in the main hollow interval for the annular array elastic abutting type rotation resistance control mechanism One end of the main hollow interval for the contact type rotation resistance control mechanism is of a semicircular structure, a semicircular groove structure for the annular array elastic contact type rotation resistance control mechanism is arranged on the side face of the rotary column for the annular array elastic contact type rotation resistance control mechanism and used for placing the end part of the push rod for the annular array elastic contact type rotation resistance control mechanism, and one end of the rotary column for the annular array elastic contact type rotation resistance control mechanism is fixed with the end part of the main first rotary shaft.

Further, the initial length of the coil spring for the annular array elastic contact type rotation resistance control mechanism is greater than the length of the auxiliary hollow section for the annular array elastic contact type rotation resistance control mechanism.

Furthermore, the structural shape of the end part of the push rod for the annular array elastic abutting type rotation resistance control mechanism is consistent with the structural shape of the semicircular groove structure for the annular array elastic abutting type rotation resistance control mechanism.

Further, the spiral spring elastic abutting installation type supporting mechanism comprises a connecting plate for a spiral spring elastic abutting installation type supporting mechanism, a bolt hole for a spiral spring elastic abutting installation type supporting mechanism, a hollow shell for a spiral spring elastic abutting installation type supporting mechanism, a hollow structure for a spiral spring elastic abutting installation type supporting mechanism, a spiral spring for a spiral spring elastic abutting installation type supporting mechanism, a movable plate for a spiral spring elastic abutting installation type supporting mechanism, a push rod for a spiral spring elastic abutting installation type supporting mechanism and a connecting plate for a spiral spring elastic abutting installation type supporting mechanism, wherein a plurality of bolt holes for a spiral spring elastic abutting installation type supporting mechanism are arranged in the connecting plate for the spiral spring elastic abutting installation type supporting mechanism, the surface of the connecting plate for the spiral spring elastic abutting installation type supporting mechanism is provided with an integrated hollow shell for the spiral spring elastic abutting installation type supporting mechanism, the utility model provides a hollow shell for supporting mechanism, helical spring elasticity is contradicted installation formula hollow structure for supporting mechanism is provided with helical spring elasticity at the center in helical spring elasticity is contradicted installation formula hollow structure for supporting mechanism, helical spring elasticity is contradicted installation formula helical spring for supporting mechanism of a hollow structure's for the installation formula hollow structure's of spiral spring elasticity internally mounted compression state, a helical spring elasticity is contradicted installation formula for supporting mechanism and is installed a helical spring elasticity and contradict installation formula movable plate for supporting mechanism, a surface center installation helical spring elasticity is contradicted installation formula push rod for supporting mechanism on the movable plate for the installation formula supporting mechanism of helical spring elasticity, the body of rod of helical spring elasticity is contradicted installation formula for supporting mechanism push rod runs through helical spring elasticity and contradicts installation formula for supporting mechanism hollow shell top center, just helical spring elasticity is contradicted installation formula for installation formula supporting mechanism push rod top installation helical spring elasticity and is supported the machine A connecting plate is constructed.

Further, the connecting plate for the coil spring elastic abutting installation type supporting mechanism is installed on the upper surface of the bottom installation base plate through bolts inserted into the bolt holes for the coil spring elastic abutting installation type supporting mechanism.

Further, the spiral spring elastically supports against the mounting type supporting mechanism and is mounted at the bottom of the main third shaft sleeve shell through a connecting plate.

Further, the steel wire rope tension and connecting plate connection type middle force conversion mechanism comprises a cylindrical block for the steel wire rope tension and connecting plate connection type middle force conversion mechanism, a conical guide structure for the steel wire rope tension and connecting plate connection type middle force conversion mechanism, a bolt mounting hole for the steel wire rope tension and connecting plate connection type middle force conversion mechanism, a part mounting groove structure for the steel wire rope tension and connecting plate connection type middle force conversion mechanism, a bearing for the steel wire rope tension and connecting plate connection type middle force conversion mechanism, an inlay block for the steel wire rope tension and connecting plate connection type middle force conversion mechanism and a steel wire rope inlay groove structure for the steel wire rope tension and connecting plate connection type middle force conversion mechanism; the two ends of the cylindrical block for the steel wire rope tension and connecting plate connection type middle force conversion mechanism are respectively provided with a steel wire rope tension and connecting plate connection type middle force conversion mechanism conical guide structure, the two ends of the steel wire rope tension and connecting plate connection type middle force conversion mechanism cylindrical block are respectively provided with a steel wire rope tension and connecting plate connection type middle force conversion mechanism bolt mounting hole and a steel wire rope tension and connecting plate connection type middle force conversion mechanism component mounting groove structure, a steel wire rope tension and connecting plate connection type middle force conversion mechanism bearing is mounted in the steel wire rope tension and connecting plate connection type middle force conversion mechanism component mounting groove structure, a steel wire rope tension and connecting plate connection type middle force conversion mechanism mosaic block is mounted in an inner ring of the steel wire rope tension and connecting plate connection type middle force conversion mechanism bearing, the center of the mosaic block for the steel wire rope tension and connecting plate connection type middle part force conversion mechanism is provided with a steel wire rope mosaic groove structure for the steel wire rope tension and connecting plate connection type middle part force conversion mechanism.

Furthermore, the steel wire rope tension and connecting plate connection type middle part force conversion mechanism is arranged in the main part moving space through a cylindrical block.

Further, the bolt mounting hole for the steel wire rope tension and connecting plate connection type middle part force conversion mechanism is fixedly connected with the end part of the main connecting rod through a bolt and a plate body, and one end rope body of the steel wire rope is embedded in the steel wire rope embedding groove structure for the steel wire rope tension and connecting plate connection type middle part force conversion mechanism.

Compared with the prior art, the invention has the beneficial effects that: the invention utilizes the rapid rotation capability of the driving motor to drive a plurality of components to rotate to generate centrifugal force, a plurality of centrifugal forces are fed and connected in parallel, can provide combined type pulling force and controllable type pulling force, is rapid and effective, and has low requirement on the sealing performance of the components, therefore, the parts work conveniently, moreover, the device is provided with an annular array elastic contact type rotation resistance control mechanism, the phenomenon of breakage of the inner steel wire rope caused by overlarge resistance of rotation is prevented, in addition, the device has a supporting mechanism with a spiral spring elastically abutted against and installed to generate an upward thrust to stabilize the working state of the component, and in addition, the device has wire rope pulling force and connecting plate connection formula middle part dynamics conversion mechanism, can turn into the total pulling force at connecting plate position with a plurality of wire rope's pulling force.

Drawings

FIG. 1 is a schematic diagram of a full-sectional structure of a rotational centrifugal force type tension driving device according to the present invention;

FIG. 2 is a schematic structural diagram of a circular array elastic contact type rotation resistance control mechanism in a rotation centrifugal force type tension driving device according to the present invention;

FIG. 3 is a schematic structural view of a supporting mechanism installed in an elastic abutting manner of a coil spring in a rotational centrifugal force type tension driving device according to the present invention;

fig. 4 is a schematic structural view of a middle force conversion mechanism of a rotary centrifugal force type tension driving device, in which a tension of a steel wire rope and a connecting plate are connected;

in the figure: 1, a bottom mounting base plate, 2, a main support bar, 3, an auxiliary support bar, 4, a main first sleeve housing, 5, a main second sleeve housing, 6, a driving motor, 7, a motor main shaft, 8, a circular array elastic contact type rotation resistance control mechanism, 81, a circular array elastic contact type rotation resistance control mechanism main hollow housing, 82, a circular array elastic contact type rotation resistance control mechanism main hollow section, 83, a circular array elastic contact type rotation resistance control mechanism rotation column, 84, a circular array elastic contact type rotation resistance control mechanism semicircular groove structure, 85, a circular array elastic contact type rotation resistance control mechanism auxiliary hollow section, 86, a circular array elastic contact type rotation resistance control mechanism movable plate, 87, a circular array elastic contact type rotation resistance control mechanism spiral spring, 88, annular array elastic contact type push rod for rotation resistance control mechanism, 9, main first rotation axis, 10, main third shaft housing, 11, coil spring elastic contact mounting type supporting mechanism, 111, connecting plate for coil spring elastic contact mounting type supporting mechanism, 112, bolt hole for coil spring elastic contact mounting type supporting mechanism, 113, hollow housing for coil spring elastic contact mounting type supporting mechanism, 114, hollow structure for coil spring elastic contact mounting type supporting mechanism, 115, coil spring for coil spring elastic contact mounting type supporting mechanism, 116, movable plate for coil spring elastic contact mounting type supporting mechanism, 117, push rod for coil spring elastic contact mounting type supporting mechanism, 118, connecting plate for coil spring elastic contact mounting type supporting mechanism, 12, auxiliary connecting plate, 13, rotating hollow pipe body, 14, rotating circular housing, 15, a main moving space, 16, an auxiliary moving space, 17, a steel wire rope tension and connecting plate connection type middle force conversion mechanism, 171, a cylindrical block for the steel wire rope tension and connecting plate connection type middle force conversion mechanism, 172, a tapered guide structure for the steel wire rope tension and connecting plate connection type middle force conversion mechanism, 173, a bolt mounting hole for the steel wire rope tension and connecting plate connection type middle force conversion mechanism, 174, a part mounting groove structure for the steel wire rope tension and connecting plate connection type middle force conversion mechanism, 175, a bearing for the steel wire rope tension and connecting plate connection type middle force conversion mechanism, 176, an inlay block for the steel wire rope tension and connecting plate connection type middle force conversion mechanism, 177, a steel wire rope tension and connecting plate connection type middle force conversion mechanism steel wire rope inlay groove structure, 18, a main moving cylinder, 19, a main inlay block, 20, a steel wire rope and 21, a rounding structure and 22, a main connecting rod and 23 and a main mounting plate.

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 bottom mounting base plate 1, a main support rod 2 and an auxiliary support rod 3 are respectively installed on two sides of the upper surface of the bottom mounting base plate 1, a main first shaft sleeve shell 4 and a main second shaft sleeve shell 5 are respectively installed on the tops of the main support rod 2 and the auxiliary support rod 3, a driving motor 6 and a rotary hollow pipeline body 13 are respectively installed inside the main first shaft sleeve shell 4 and the main second shaft sleeve shell 5, one side of the rotary hollow pipeline body 13 is provided with a rotary circular body shell 14 of an integrated structure, a main moving space 15 and auxiliary moving spaces 16 arranged by a plurality of annular arrays are respectively arranged inside the rotary hollow pipeline body 13 and the rotary circular body shell 14, a fillet structure 21 is arranged at a communication and handover position of the main moving space 15 and the auxiliary moving spaces 16 arranged by the plurality of annular arrays, and a main moving cylinder 18 is installed inside each auxiliary moving space 16 arranged by the annular arrays, a steel wire rope tension and connecting plate connection type middle force conversion mechanism 17 is installed inside the main moving space 15, a main mosaic block 19 is installed on the center of each main moving cylinder 18 facing the inner side through a main bearing, one end of a steel wire rope 20 is embedded inside the main mosaic block 19, the other end of the steel wire rope 20 is installed on one end face of the steel wire rope tension and connecting plate connection type middle force conversion mechanism 17, a main connecting rod 22 is installed on the other end face of the steel wire rope tension and connecting plate connection type middle force conversion mechanism 17 through a plate body and a bolt, a main installation plate 23 is installed on the end portion of the main connecting rod 22, a circular array elastic abutting type rotation resistance control mechanism 8 is installed on the end portion of a motor main shaft 7 in the driving motor 6, a main first rotating shaft 9 is installed at the center of one end of the circular array elastic abutting type rotation resistance control mechanism 8, the axis body of main first rotation axis 9 is installed in the inside of a main third axle body shell 10, a helical spring elasticity installation formula supporting mechanism 11 of contradicting is installed to the bottom of main third axle body shell 10, the bolt is passed through at the upper surface of bottom mounting substrate 1 in the bottom of helical spring elasticity conflict installation formula supporting mechanism 11's bottom, the tip of main first rotation axis 9 is installed at rotatory circular body shell 14 terminal surface center through auxiliary connecting plate 12.

Referring to fig. 2, the circular array elastic contact type rotation resistance control mechanism 8 includes a main hollow housing 81 for the circular array elastic contact type rotation resistance control mechanism, a main hollow section 82 for the circular array elastic contact type rotation resistance control mechanism, a rotation column 83 for the circular array elastic contact type rotation resistance control mechanism, a semicircular groove structure 84 for the circular array elastic contact type rotation resistance control mechanism, a sub hollow section 85 for the circular array elastic contact type rotation resistance control mechanism, a movable plate 86 for the circular array elastic contact type rotation resistance control mechanism, a spiral spring 87 for the circular array elastic contact type rotation resistance control mechanism, and a push rod 88 for the circular array elastic contact type rotation resistance control mechanism; the center of one end face of the main hollow housing 81 for the annular array elastic contact type rotation resistance control mechanism is fixedly connected with the end part of the motor spindle 7, the center of the inside of the main hollow housing 81 for the annular array elastic contact type rotation resistance control mechanism is a main hollow section 82 for the annular array elastic contact type rotation resistance control mechanism, the inside of the main hollow housing 81 for the annular array elastic contact type rotation resistance control mechanism positioned in the main hollow section 82 for the annular array elastic contact type rotation resistance control mechanism is sleeved with a rotation column 83 for the annular array elastic contact type rotation resistance control mechanism, the inside of the main hollow housing 81 for the annular array elastic contact type rotation resistance control mechanism is an auxiliary hollow section 85 for the annular array elastic contact type rotation resistance control mechanism, and the inside of the auxiliary hollow section 85 for the annular array elastic contact type rotation resistance control mechanism positioned in the auxiliary hollow section 85 A movable plate 86 for annular array elastic contact type rotation resistance control mechanism is disposed on one end face of the main hollow section 82 for resistance control mechanism, a coil spring 87 for annular array elastic contact type rotation resistance control mechanism is fixed between one ends of the movable plates 86 for annular array elastic contact type rotation resistance control mechanism at the auxiliary hollow section 85 for annular array elastic contact type rotation resistance control mechanism, a push rod 88 for annular array elastic contact type rotation resistance control mechanism of an integrated structure with the movable plate 86 for annular array elastic contact type rotation resistance control mechanism is disposed on one end face of the movable plate 86 for annular array elastic contact type rotation resistance control mechanism, and the push rod 88 for annular array elastic contact type rotation resistance control mechanism penetrates through the main hollow housing 81 for annular array elastic contact type rotation resistance control mechanism and is disposed inside the main hollow section 82 for annular array elastic contact type rotation resistance control mechanism, the push rod 88 for the annular array elastic abutting type rotation resistance control mechanism is of a semicircular structure at one end of the main hollow section 82 for the annular array elastic abutting type rotation resistance control mechanism, a semicircular groove structure 84 for the annular array elastic abutting type rotation resistance control mechanism is arranged on the side surface of the rotary column 83 for the annular array elastic abutting type rotation resistance control mechanism and used for placing the end part of the push rod 88 for the annular array elastic abutting type rotation resistance control mechanism, and one end of the rotary column 83 for the annular array elastic abutting type rotation resistance control mechanism is fixed with the end part of the main first rotary shaft 9; the initial length of the coil spring 87 for the annular array elastic contact type rotation resistance control mechanism is longer than the length of the auxiliary hollow section 85 for the annular array elastic contact type rotation resistance control mechanism; the structural shape of the end of the push rod 88 for the annular array elastic contact type rotation resistance control mechanism is consistent with the structural shape of the semicircular groove structure 84 for the annular array elastic contact type rotation resistance control mechanism, and the structure mainly has the following functions: when the driving resistance is too large and the resistance is larger than the elasticity of the coil spring 87 for the annular array elastic contact type rotation resistance control mechanism, the coil spring 87 for the annular array elastic contact type rotation resistance control mechanism is compressed, and the two rotation shafts rotate relatively under the causal action to play a protection role, so that the elasticity of the coil spring 87 for the annular array elastic contact type rotation resistance control mechanism is smaller than the maximum traction force of the steel wire rope 20.

Referring to fig. 3, the supporting mechanism 11 includes a connecting plate 111 for supporting mechanism, a bolt hole 112 for supporting mechanism, a hollow shell 113 for supporting mechanism, a hollow structure 114 for supporting mechanism, a coil spring 115 for supporting mechanism, a moving plate 116 for supporting mechanism, a push rod 117 for supporting mechanism, and a connecting plate 118 for supporting mechanism, wherein the connecting plate 111 has a plurality of bolt holes 112, and the connecting plate 111 has a surface provided with a plurality of bolt holes 112 A hollow shell 113 for a supporting mechanism, a hollow structure 114 for a supporting mechanism of a spiral spring elastic abutting installation type is arranged at the center inside the hollow shell 113 for the supporting mechanism of the spiral spring elastic abutting installation type, a spiral spring 115 for the supporting mechanism of the spiral spring elastic abutting installation type in a compression state is arranged inside the hollow structure 114 for the supporting mechanism of the spiral spring elastic abutting installation type, a movable plate 116 for the supporting mechanism of the spiral spring elastic abutting installation type is arranged at the top of the spiral spring 115 for the supporting mechanism of the spiral spring elastic abutting installation type, a push rod 117 for the supporting mechanism of the spiral spring elastic abutting installation type is arranged at the center of the upper surface of the movable plate 116 for the supporting mechanism of the spiral spring elastic abutting installation type, and the rod body of the push rod 117 for the supporting mechanism of the spiral spring elastic abutting installation type penetrates through the center of the top of the hollow shell 113 for the supporting mechanism of, a connecting plate 118 for the spiral spring elastic abutting mounting type supporting mechanism is mounted at the top end of the push rod 117 for the spiral spring elastic abutting mounting type supporting mechanism; the connecting plate 111 for the coil spring elastic abutting mounting type supporting mechanism is mounted on the upper surface of the bottom mounting substrate 1 through bolts inserted into the bolt holes 112 for the coil spring elastic abutting mounting type supporting mechanism; the connecting plate 118 for the mounting type supporting mechanism is elastically abutted by the spiral spring and is mounted at the bottom of the main third shaft sleeve shell 10, and the main functions of the connecting plate are as follows: and the function of elastic support is achieved.

Referring to fig. 4, the steel wire rope tension and connecting plate connection type middle force conversion mechanism 17 includes a steel wire rope tension and connecting plate connection type middle force conversion mechanism cylindrical block 171, a steel wire rope tension and connecting plate connection type middle force conversion mechanism conical guide structure 172, a steel wire rope tension and connecting plate connection type middle force conversion mechanism bolt mounting hole 173, a steel wire rope tension and connecting plate connection type middle force conversion mechanism part mounting groove structure 174, a steel wire rope tension and connecting plate connection type middle force conversion mechanism bearing 175, a steel wire rope tension and connecting plate connection type middle force conversion mechanism mosaic block 176 and a steel wire rope tension and connecting plate connection type middle force conversion mechanism steel wire rope mosaic groove structure 177; the two ends of the cylindrical block 171 for the steel wire rope tension and connecting plate connecting type middle force conversion mechanism are provided with a steel wire rope tension and connecting plate connecting type middle force conversion mechanism conical guide structure 172, the two ends of the cylindrical block 171 for the steel wire rope tension and connecting plate connecting type middle force conversion mechanism are provided with a steel wire rope tension and connecting plate connecting type middle force conversion mechanism bolt mounting hole 173 and a steel wire rope tension and connecting plate connecting type middle force conversion mechanism component mounting groove structure 174 respectively, the inside of the steel wire rope tension and connecting plate connecting type middle force conversion mechanism component mounting groove structure 174 is provided with a steel wire rope tension and connecting plate connecting type middle force conversion mechanism bearing 175, the inner ring of the steel wire rope tension and connecting plate connecting type middle force conversion mechanism bearing 175 is provided with a steel wire rope tension and connecting plate connecting type middle force conversion mechanism insert 176, the center of the steel wire rope tension and connecting plate connection type middle force conversion mechanism inlaying block 176 is provided with a steel wire rope tension and connecting plate connection type middle force conversion mechanism steel wire rope inlaying groove structure 177; the steel wire rope tension and connecting plate connection type middle force conversion mechanism is arranged in the main part moving space 15 through a cylindrical block 171; the bolt mounting hole 173 is passed through bolt and plate body fixed connection with the tip of main connecting rod 22 with the bolt for connecting plate connection formula middle part dynamics conversion mechanism to wire rope pulling force, the inside of wire rope for connecting plate connection formula middle part dynamics conversion mechanism inlay groove structure 177 is inlayed and is had the one end rope body of wire rope 20, and its main action is: can realize the comprehensive action of force.

The specific use mode is as follows: in the working process of the invention, the main mounting plate 23 and the connecting part needing tension are mounted, then the driving motor 6 is started, the rotating circular body shell 14 and the rotating hollow pipeline body 13 rotate rapidly under the linkage action of the components, in the rotating process, the main moving column body 18 can generate a driving type moving to the periphery under the action of centrifugal force, the trend acts on the middle force conversion mechanism 17 of the connection type of the tension of the steel wire rope and the connecting plate through the steel wire rope 20, and the action of the middle force conversion mechanism 17 of the connection type of the tension of the steel wire rope and the connecting plate produces the needed tension.

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. A rotary centrifugal force type tension driving device comprises a bottom mounting substrate (1), and is characterized in that: the bottom mounting base plate (1) is characterized in that a main supporting rod (2) and an auxiliary supporting rod (3) are respectively mounted on two sides of the upper surface of the bottom mounting base plate (1), a main first shaft sleeve shell (4) and a main second shaft sleeve shell (5) are respectively mounted at the tops of the main supporting rod (2) and the auxiliary supporting rod (3), a driving motor (6) and a rotary hollow pipeline body (13) are respectively mounted inside the main first shaft sleeve shell (4) and the main second shaft sleeve shell (5), one side of the rotary hollow pipeline body (13) is provided with a rotary circular body shell (14) of an integrated structure, a main moving space (15) and auxiliary moving spaces (16) arranged by a plurality of annular arrays are respectively arranged inside the rotary hollow pipeline body (13) and the rotary circular body shell (14), and fillet structures (21) are arranged at communicated joint positions of the main moving space (15) and the auxiliary moving spaces (16) arranged by the plurality of annular arrays, every a main movable cylinder (18) is all installed to the inside in vice shift space (16) that the annular array set up, a main movable cylinder (18) is all installed through a main bearing installation main mosaic piece (19) at the center towards the inboard in a internally mounted wire rope pulling force and connecting plate connection formula middle part dynamics shifter (17), the inside of main mosaic piece (19) is inlayed and is had the one end of wire rope (20) rope body, the terminal surface at wire rope pulling force and connecting plate connection formula middle part dynamics (17) is installed to the other end of wire rope (20), another terminal surface of wire rope pulling force and connecting plate connection formula middle part dynamics shifter (17) passes through a plate body and a main connecting rod of bolt installation (22), a main mounting board (23) is installed to the tip of main connecting rod (22), an annular array elasticity of the tip installation of motor main shaft (7) in driving motor (6) is supported and is touched formula and is revolved soon Rotating resistance control mechanism (8), annular array elasticity is supported and is touched the first rotation axis of owner (9) of rotatory resistance control mechanism (8) one end center installation, the axis body of the first rotation axis of owner (9) is installed in the inside of a main third shaft body shell (10), a coil spring elasticity of bottom installation of main third shaft body shell (10) is contradicted installation formula supporting mechanism (11), the upper surface at bottom mounting substrate (1) is passed through the bolt in the bottom of coil spring elasticity conflict installation formula supporting mechanism (11), the tip of the first rotation axis of owner (9) is installed at rotatory circular body shell (14) terminal surface center through vice connecting plate (12).

2. A rotary centrifugal force type tension driving apparatus as claimed in claim 1, wherein: the annular array elastic abutting type rotation resistance control mechanism (8) comprises a main hollow shell (81) for the annular array elastic abutting type rotation resistance control mechanism, a main hollow interval (82) for the annular array elastic abutting type rotation resistance control mechanism, a rotary column (83) for the annular array elastic abutting type rotation resistance control mechanism, a semicircular groove structure (84) for the annular array elastic abutting type rotation resistance control mechanism, an auxiliary hollow interval (85) for the annular array elastic abutting type rotation resistance control mechanism, a movable plate (86) for the annular array elastic abutting type rotation resistance control mechanism, a spiral spring (87) for the annular array elastic abutting type rotation resistance control mechanism and a push rod (88) for the annular array elastic abutting type rotation resistance control mechanism; the center of one end face of a main hollow shell (81) for the annular array elastic abutting type rotation resistance control mechanism is fixedly connected with the end part of a motor spindle (7), the center of the inner part of the main hollow shell (81) for the annular array elastic abutting type rotation resistance control mechanism is a main hollow section (82) for the annular array elastic abutting type rotation resistance control mechanism, a rotary column (83) for the annular array elastic abutting type rotation resistance control mechanism is sleeved in the main hollow shell (81) for the annular array elastic abutting type rotation resistance control mechanism, a secondary hollow section (85) for the annular array elastic abutting type rotation resistance control mechanism is arranged in the main hollow section (82) for the annular array elastic abutting type rotation resistance control mechanism, a movable plate (86) for the annular array elastic abutting type rotation resistance control mechanism is arranged in an auxiliary hollow area (85) for the annular array elastic abutting type rotation resistance control mechanism at one end face of a main hollow area (82) for the annular array elastic abutting type rotation resistance control mechanism, a spiral spring (87) for the annular array elastic abutting type rotation resistance control mechanism is fixed between the auxiliary hollow area (85) for the annular array elastic abutting type rotation resistance control mechanism and one end of the movable plate (86) for the annular array elastic abutting type rotation resistance control mechanism, a push rod (88) for the annular array elastic abutting type rotation resistance control mechanism is arranged at one end face of the movable plate (86) for the annular array elastic abutting type rotation resistance control mechanism and is of an integral structure with the movable plate, and the push rod (88) for the annular array elastic abutting type rotation resistance control mechanism penetrates through the annular array elastic abutting type rotation resistance control mechanism A main hollow housing (81) for the rotation resistance control mechanism, which is located inside the annular array elastic contact type main hollow section (82) for the rotation resistance control mechanism, one end of the push rod (88) for the annular array elastic contact type rotation resistance control mechanism, which is positioned in the main hollow area (82) for the annular array elastic contact type rotation resistance control mechanism, is of a semicircular structure, a semicircular groove structure (84) for the annular array elastic contact type rotation resistance control mechanism is arranged on the side surface of the rotation column (83) for the annular array elastic contact type rotation resistance control mechanism and used for placing the end part of a push rod (88) for the annular array elastic contact type rotation resistance control mechanism, one end of the rotary column (83) for the annular array elastic contact type rotary resistance control mechanism is fixed with the end part of the main first rotary shaft (9).

3. A rotary centrifugal force type tension driving apparatus according to claim 2, wherein: the initial length of the spiral spring (87) for the annular array elastic contact type rotation resistance control mechanism is larger than the length of the auxiliary hollow section (85) for the annular array elastic contact type rotation resistance control mechanism.

4. A rotary centrifugal force type tension driving apparatus according to claim 2, wherein: the structural shape of the end part of the push rod (88) for the annular array elastic abutting type rotation resistance control mechanism is consistent with the structural shape of the semicircular groove structure (84) for the annular array elastic abutting type rotation resistance control mechanism.

5. A rotary centrifugal force type tension driving apparatus as claimed in claim 1, wherein: the spiral spring elastic conflict installation type supporting mechanism (11) comprises a connecting plate (111) for a spiral spring elastic conflict installation type supporting mechanism, a bolt hole (112) for a spiral spring elastic conflict installation type supporting mechanism, a hollow shell (113) for a spiral spring elastic conflict installation type supporting mechanism, a hollow structure (114) for a spiral spring elastic conflict installation type supporting mechanism, a spiral spring (115) for a spiral spring elastic conflict installation type supporting mechanism, a movable plate (116) for a spiral spring elastic conflict installation type supporting mechanism, a push rod (117) for a spiral spring elastic conflict installation type supporting mechanism and a connecting plate (118) for a spiral spring elastic conflict installation type supporting mechanism, wherein a plurality of bolt holes (112) for a spiral spring elastic conflict installation type supporting mechanism are arranged inside the connecting plate (111) for the spiral spring elastic conflict installation type supporting mechanism, the surface of the connecting plate (111) for the spiral spring elastic conflict mounting type supporting mechanism is provided with an integrated hollow shell (113) for the spiral spring elastic conflict mounting type supporting mechanism, the inner center of the hollow shell (113) for the spiral spring elastic conflict mounting type supporting mechanism is provided with a hollow structure (114) for the spiral spring elastic conflict mounting type supporting mechanism, the inner part of the hollow structure (114) for the spiral spring elastic conflict mounting type supporting mechanism is provided with a spiral spring (115) in a compression state, the top of the spiral spring (115) for the spiral spring elastic conflict mounting type supporting mechanism is provided with a movable plate (116) for the spiral spring elastic conflict mounting type supporting mechanism, the upper surface center of the movable plate (116) for the spiral spring elastic conflict mounting type supporting mechanism is provided with a push rod (117) for the spiral spring elastic conflict mounting type supporting mechanism, the body of rod of helical spring elasticity conflict installation formula push rod (117) for supporting mechanism runs through hollow shell (113) top center for the installation formula supporting mechanism of helical spring elasticity conflict, just helical spring elasticity conflicts an installation formula connecting plate (118) for supporting mechanism of helical spring elasticity conflict installation formula for supporting mechanism on push rod (117) top for the installation formula supporting mechanism of helical spring elasticity.

6. A rotary centrifugal force type tension driving apparatus according to claim 5, wherein: the connecting plate (111) for the spiral spring elastic abutting installation type supporting mechanism is installed on the upper surface of the bottom installation base plate (1) through bolts inserted into bolt holes (112) for the spiral spring elastic abutting installation type supporting mechanism.

7. A rotary centrifugal force type tension driving apparatus according to claim 5, wherein: the spiral spring elastically supports against the mounting type supporting mechanism and is mounted at the bottom of the main third shaft sleeve shell (10) through a connecting plate (118).

8. A rotary centrifugal force type tension driving apparatus as claimed in claim 1, wherein: the steel wire rope tension and connecting plate connection type middle force conversion mechanism (17) comprises a steel wire rope tension and connecting plate connection type middle force conversion mechanism cylindrical block (171), a steel wire rope tension and connecting plate connection type middle force conversion mechanism conical guide structure (172), a steel wire rope tension and connecting plate connection type middle force conversion mechanism bolt mounting hole (173), a steel wire rope tension and connecting plate connection type middle force conversion mechanism part mounting groove structure (174), a steel wire rope tension and connecting plate connection type middle force conversion mechanism bearing (175), a steel wire rope tension and connecting plate connection type middle force conversion mechanism embedded block (176) and a steel wire rope tension and connecting plate connection type middle force conversion mechanism steel wire rope embedded groove structure (177); the steel wire rope tension and connecting plate connection type middle force conversion mechanism comprises a cylindrical block (171) and is characterized in that two ends of the cylindrical block (172) are provided with a steel wire rope tension and connecting plate connection type middle force conversion mechanism conical guide structure (172), two ends of the cylindrical block (171) are provided with a steel wire rope tension and connecting plate connection type middle force conversion mechanism bolt installation hole (173) and a steel wire rope tension and connecting plate connection type middle force conversion mechanism part installation groove structure (174), a steel wire rope tension and connecting plate connection type middle force conversion mechanism bearing (175) is installed inside the steel wire rope tension and connecting plate connection type middle force conversion mechanism part installation groove structure (174), and a steel wire rope tension and connecting plate connection type middle force conversion mechanism is installed in an inner ring of the steel wire rope tension and connecting plate connection type middle force conversion mechanism bearing (175) With inlay block (176), the wire rope pulling force is provided with wire rope mosaic groove structure (177) for the connecting plate connected middle part dynamics shifter with the center of inlay block (176) for the connecting plate connected middle part dynamics shifter.

9. A rotary centrifugal force type tension driving device according to claim 8, wherein: the steel wire rope tension and connecting plate connection type middle force conversion mechanism is arranged in the main part moving space (15) through a cylindrical block (171).

10. A rotary centrifugal force type tension driving device according to claim 8, wherein: the bolt mounting hole (173) for the steel wire rope tension and connecting plate connection type middle force conversion mechanism is fixedly connected with the end part of the main connecting rod (22) through a bolt and a plate body, and a steel wire rope body of one end of a steel wire rope (20) is embedded inside the steel wire rope embedding groove structure (177) for the steel wire rope tension and connecting plate connection type middle force conversion mechanism.

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