CN109050780B - Transmission control structure based on big data management mode - Google Patents

Abstract

The invention discloses a transmission control device based on a big data management mode, which structurally comprises a locking nut, a waterproof shell, a transmission control device, a fixed head, a chain disc and a transmission seat board, wherein the transmission control device is integrally installed in the waterproof shell in an embedded mode The preparation method comprises the following steps of.

Description

Transmission control structure based on big data management mode

Technical Field

The invention relates to the field of transmissions, in particular to a transmission control structure based on a big data management mode.

Background

In general, a transmission is a standard equipment in a bicycle, and the use of the transmission increases the convenience of a user for riding the bicycle; in order to control the speed change of the bicycle derailleur, a pulling method of an actuating cable is usually adopted to adjust the position of a carriage of the bicycle derailleur, so as to switch the change of a bicycle chain between different gears.

Disclosure of Invention

Aiming at the defects of the prior art, the invention is realized by the following technical scheme: derailleur control structure based on big data management mode, its structure includes lock nut, waterproof case, derailleur controlling means, fixed head, chain dish, variable speed bedplate, the whole mode through the embedding of derailleur controlling means is installed inside waterproof case, waterproof case is close to fixed head one end and installs inside fixed head close waterproof case one end through the mode of embedding through derailleur controlling means, the variable speed bedplate is kept away from chain dish one end and is installed in waterproof case bottom through the mode of embedding, the chain dish is installed inside the variable speed bedplate and the chain dish axle center is fixed inside the variable speed bedplate through lock nut through the mode of embedding.

The transmission control device comprises a double-joint triggering mechanism, an outward-extending type positioning mechanism, a cooperative electricity control mechanism, a receiving and processing conductive mechanism, a main power output mechanism, an electricity storage mechanism and a power generation mechanism, wherein the power generation mechanism is fixedly arranged at the right end inside the waterproof shell, the electricity storage mechanism is arranged at the upper end and the lower end of the power generation mechanism and is fixedly arranged at the upper end and the lower end inside the waterproof shell in a welding manner, the main power output mechanism, the receiving and processing conductive mechanism, the cooperative electricity control mechanism, the outward-extending type positioning mechanism and the double-joint triggering mechanism are sequentially arranged at the right end and the left end of the power generation mechanism from right to left, the back of the main power output mechanism is fixedly connected to the inner surface of the waterproof shell in a manner of adopting an electric welding manner, the right end of the main power output mechanism is electrically connected with the receiving and processing conductive mechanism through a conducting wire, one end of the cooperative electricity control mechanism, which is, one end of the double-connection trigger mechanism, which is close to the receiving and processing conductive mechanism, is mechanically connected with one end of the extending type positioning mechanism.

As a further optimization of the technical scheme, the dual-connection trigger mechanism comprises an angle hook, a top rod, a spring positioning plate, a reset spring, a spring fixing plate, a first traction wire, a tension spring, a torsion spring wire wheel, a rotating rod and a second traction wire, wherein the inner surface of the angle hook is fixedly connected with the outer surface of one end, far away from the spring positioning plate, of the top rod in an adhesion mode, the inner annular surface of the spring positioning plate is fixedly connected with the outer surface of the middle position of the top rod in an electric welding mode, one end, close to the angle hook, of the reset spring is fixedly connected with one end, far away from the angle hook, of the spring positioning plate in an electric welding mode, one end, far away from the angle hook, of the top rod is fixedly connected with the spring fixing plate through the first traction wire, one end, far away from the tension spring, of the spring fixing plate is movably connected with, one end, close to the ejector rod, of the spring fixing plate is fixedly connected to one end, far away from the ejector rod, of the tension spring in an electric welding mode, and the other end of the rotating rod is fixedly connected with the outward-extending type positioning mechanism.

As a further optimization of the technical scheme, the outward-extending positioning mechanism comprises a sliding fixed groove rod, four sliding push rods, a positive end block, a two-stage magnetic disk, a fixed pulley, a magnetic disk attaching wheel, a conduction belt and a negative end block, wherein the four sliding push rods are divided into two groups, one ends of the four sliding push rods are movably connected with one ends of the sliding fixed groove rods, which are close to the two-stage magnetic disk, through pins, the other ends of the sliding push rods are respectively and fixedly connected with the two-stage magnetic disk and the negative end block in an adhesion mode, one ends of the two-stage magnetic disk, which are far away from the two-stage magnetic disk, are installed at the axle center of the magnetic disk attaching wheel in an embedding mode, the outer ring surface of the magnetic disk attaching wheel is movably connected with the.

As a further optimization of this technical scheme, the accuse electric mechanism of cooperateing is including releasing spring, the fixed lantern ring, passive branch, pin rod, long connecting strut, branch sleeve, second connecting strut, it adopts the mode fixed connection that the electric welding was kept away from long connecting strut one end in the fixed lantern ring to release the spring and be close to long connecting strut one end, fixed lantern ring inner ring and passive branch surface interference fit, passive branch is close to fixed lantern ring one end and is close to fixed lantern ring one end swing joint together through the pin with long connecting strut, the pin rod is installed at long connecting strut intermediate position through the mode of embedding, long connecting strut keeps away from passive branch one end and is connected branch one end swing joint together through the pin with the second, the second connecting strut surface is nested with branch sleeve internal surface mutually.

As a further optimization of this technical scheme, receive and handle electrically conductive mechanism and include information processing board, controllable conducting block, location foot piece, output terminal, the location foot piece is equipped with four altogether and divide into two a set of modes that adopt the electric welding respectively fixed connection in both ends about the information processing board, controllable conducting block back adopts the mode fixed connection of electric welding in the positive terminal surface intermediate position of information processing board, output terminal back adopts the mode fixed connection of electric welding to keep away from controllable conducting block one end in the positive terminal surface of information processing board, output terminal keeps away from controllable conducting block one end and is in the same place with main power output mechanism fixed connection.

As a further optimization of the technical scheme, the main power output mechanism comprises a second power line, a micro motor, a jacket and a motor fixing sleeve, the micro motor is integrally installed inside the positive end face of the motor fixing sleeve in an embedded mode, the inner surface of the jacket is fixedly connected to the outer surface of the upper end and the lower end of the motor fixing sleeve in an electric welding mode, one end of the second power line, which is far away from the output terminal, is installed at the back of the motor fixing sleeve, which is close to one end of the output terminal and is fixedly connected to the back of the micro motor in an electric welding mode, and one end of the second power line, which is far away from the micro.

As a further optimization of the technical scheme, the electricity storage mechanism comprises a storage battery, a fixed strip, a movable pin, a conductive rod, an input terminal and a first power line, the storage battery, the fixed strip, the movable pin, the conducting rod, the input terminal and the first power line are respectively provided with two and are respectively fixedly connected with the upper surface and the lower surface inside the waterproof shell by the fixed strip in an electric welding way, one end of the storage battery, which is far away from the conducting rod, is arranged in the fixed strip in an embedding mode, one end of the conducting rod, which is close to the storage battery, is mechanically connected with the storage battery through a movable pin, one end of the input terminal far away from the first power line is fixedly connected with one end of the storage battery close to the first power line in an electric welding mode, the first power line is close to one end of the storage battery, is fixedly connected to the input terminal in an electric welding mode and is far away from one end of the storage battery, and the bottom end of the first power line is fixedly connected with the top end of the power type power generation mechanism.

As a further optimization of the technical scheme, the power generation mechanism comprises a magnet ring, a coil, a shaft rod, a fixing frame, a power transmission plate and a metal shell, wherein the outer annular surface of the magnet ring is adsorbed on the inner surface of the metal shell through magnetic force, the back of the metal shell is installed on the front end surface of the power transmission plate in an embedded mode, the shaft rod is installed at the axis position of the coil in an embedded mode and is in the same axis with the metal shell, the back of the shaft rod penetrates through the middle position of the front end surface of the power transmission plate, the outer surface of the power transmission plate is installed on the inner surface of the fixing frame in an embedded mode, the outer surface of the fixing frame is fixedly connected to one side, away from the double-connection trigger mechanism, of the waterproof shell in an electric welding mode, the first.

Advantageous effects

The invention relates to a transmission control structure based on a big data management mode, wherein a fixed head is fixed at the side end of a rear wheel of a bicycle, a waterproof shell and a transmission control device are inserted into one end of the fixed head, the waterproof shell and the transmission control device are fixed and limit a top rod after being inserted into the fixed head, the top rod stretches a reset spring and pulls a first traction line to be pulled rightwards under the limiting action of a spring fixing plate when being stressed to move leftwards, so that a magnetic disk sticking wheel drives a two-stage magnetic disk to rotate so as to exchange the positions of a positive pole and a negative pole of the magnetic disk, when the magnetic pole ends of the magnetic disk are exchanged, the repulsion force generated by the top rod pushes a positive pole end block and a negative pole end block to drive a sliding push rod to push a sliding fixing groove rod to extend outwards and is embedded into the two ends in the fixed head to effectively movably fix a waterproof shell, and when the waterproof shell is, the replacement amount of parts is reduced, the driven support rod is synchronously braked while the ejector rod is pushed, the second connecting support rod performs retraction motion under the pulling of the long connecting support rod, the conducting rod rotates clockwise half-plane around the movable pin by gravity and contacts with the power-on end of the information processing board, the waste of a power supply stored by a storage battery is avoided, the bicycle is connected with a shaft rod through one side of the shaft end of the bicycle in the running process and drives the mechanical energy of the shaft rod to rotate at high speed, micro current generated by magnetic induction phenomenon is transmitted to an input terminal through the shaft rod, the continuous electric energy generation is realized and is circularly supplied to a receiving processing conducting mechanism and a main power output mechanism, when a speed change signal is received through a waterproof shell, the power supply of a micro motor is connected through a controllable conducting block through the controllable conducting block, the electric energy is converted into mechanical energy again to generate power supply for the movement of a speed change seat, the shift chain is moved in each of the shift gears by the movement of the shift base plate via the traction of the chain disk.

Based on the prior art, the invention mainly utilizes the double-connection triggering mechanism, the abduction type positioning mechanism, the cooperative electricity control mechanism, the receiving processing conductive mechanism, the main power output mechanism, the electricity storage mechanism and the power generation mechanism, the transmission is integrally fixed in a split way by mutually matching the double-connection triggering mechanism, the abduction type positioning mechanism and the cooperative electricity control mechanism, when the internal parts are damaged, the whole can be dismantled and repaired only by operating the double-connection triggering mechanism, the repair cost is greatly reduced, the energy conversion and storage are carried out by the electricity storage mechanism and the power generation mechanism, and the power supply of automatic speed change is realized under the mutual matching of the receiving processing conductive mechanism and the main power output mechanism.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic diagram of a transmission control architecture based on big data management mode according to the present invention.

FIG. 2 is a schematic diagram of the internal structure of the big data management mode based transmission control architecture of the present invention.

FIG. 3 is a schematic diagram of the internal details of the big data management mode based transmission control architecture of the present invention.

FIG. 4 is a detailed internal structural diagram of a double-connection triggering mechanism of the transmission control structure based on the big data management mode.

FIG. 5 is a schematic diagram of the internal detailed structure of the motion state of the double-connection trigger mechanism of the transmission control structure based on the big data management mode.

FIG. 6 is a schematic diagram of the internal details of the abduction positioning mechanism of the big data management mode based transmission control architecture of the present invention.

FIG. 7 is a schematic diagram of the kinematic internal detailed structure of the abduction positioning mechanism of the transmission control structure based on big data management mode according to the present invention.

FIG. 8 is a detailed structural diagram of the internal structure of the cooperative electric control mechanism of the transmission control structure based on big data management mode.

FIG. 9 is a schematic diagram of the internal detailed structure of the motion state of the cooperative electric control mechanism of the transmission control structure based on big data management mode.

In the figure: a locking nut-1, a waterproof shell-2, a transmission control device-3, a fixed head-4, a chain disc-5, a transmission seat plate-6, a double-connection trigger mechanism-31, an outward-extending positioning mechanism-32, a cooperative electric control mechanism-33, a receiving and processing conductive mechanism-34, a main power output mechanism-35, an electric storage mechanism-36, a power generation mechanism-37, an angle hook-311, a push rod-312, a spring positioning plate-313, a reset spring-314, a spring fixing plate-315, a first traction wire-316, a tension spring-317, a torsion spring reel-318, a rotating rod-319, a second traction wire-3110, a sliding fixing groove rod-321, a sliding push rod-322, an anode end block-323, a double-stage disc-324, a double-4, Fixed pulley-325, disk attaching wheel-326, conducting belt-327, negative terminal block-328, push-out spring-331, fixed collar-332, passive support rod-333, pin rod-334, long connecting support rod-335, support rod sleeve-336, second connecting support rod-337, information processing board-341, controllable conducting block-342, positioning pin-343, output terminal-344, second power supply wire-351, micro motor-352, jacket-353, motor fixing sleeve-354, storage battery-361, fixing strip-362, movable pin-363, conducting rod-364, input terminal-365, first power supply wire-366, magnet ring-371, coil-372, shaft rod-373, fixing frame-374, power transmission plate-375, Metal shell-376.

Detailed Description

In order to make the technical means, the original characteristics, the achieved purposes and the effects of the invention easy to understand, the following description and the accompanying drawings further illustrate the preferred embodiments of the invention.

Examples

Referring to fig. 1 to 9, the present invention provides a transmission control structure based on a big data management mode, which includes a lock nut 1, a waterproof case 2, a transmission control device 3, a fixing head 4, a chain disc 5, and a transmission seat plate 6, wherein the transmission control device 3 is integrally installed inside the waterproof case 2 in an embedded manner, one end of the waterproof case 2 close to the fixing head 4 is installed inside one end of the fixing head 4 close to the waterproof case 2 in an embedded manner through the transmission control device 3, one end of the transmission seat plate 6 far from the chain disc 5 is installed at the bottom end of the waterproof case 2 in an embedded manner, the chain disc 5 is installed inside the transmission seat plate 6 in an embedded manner, and the axis of the chain disc 5 is fixed inside the transmission seat plate 6 through the lock nut 1.

The transmission control device 3 comprises a double-connection trigger mechanism 31, an outward-extending type positioning mechanism 32, a cooperative power control mechanism 33, a receiving processing conductive mechanism 34, a main power output mechanism 35, a power storage mechanism 36 and a power generation mechanism 37, wherein the power generation mechanism 37 is fixedly installed at the right end inside the waterproof shell 2, the power storage mechanism 36 is arranged at the upper end and the lower end of the power generation mechanism 37 and is fixed at the upper end and the lower end inside the waterproof shell 2 in a welding manner, the main power output mechanism 35, the receiving processing conductive mechanism 34, the cooperative power control mechanism 33, the outward-extending type positioning mechanism 32 and the double-connection trigger mechanism 31 are sequentially installed on the power generation mechanism 37 from right to left, the back of the main power output mechanism 35 is fixedly connected to the inner surface of the waterproof shell 2 in an electric welding manner, and the right end of the main power output mechanism 35 is electrically connected with the receiving processing conductive mechanism 34 through a lead, one end of the cooperative electric control mechanism 33, which is far away from the receiving processing conductive mechanism 34, is mechanically connected with one end of the double-connection trigger mechanism 31, which is close to the receiving processing conductive mechanism 34, and one end of the double-connection trigger mechanism 31, which is close to the receiving processing conductive mechanism 34, is mechanically connected with one end of the abduction type positioning mechanism 32.

The double-connection trigger mechanism 31 comprises an angle hook 311, a top rod 312, a spring positioning plate 313, a reset spring 314, a spring fixing plate 315, a first pull wire 316, a tension spring 317, a torsion spring reel 318, a rotating rod 319 and a second pull wire 3110, wherein the inner surface of the angle hook 311 is fixedly connected with the outer surface of one end of the top rod 312 far away from the spring positioning plate 313 in an adhesion mode, the inner annular surface of the spring positioning plate 313 is fixedly connected with the outer surface of the middle position of the top rod 312 in an electric welding mode, one end of the reset spring 314 close to the angle hook 311 is fixedly connected with one end of the spring positioning plate 313 far away from the angle hook 311 in an electric welding mode, one end of the top rod 312 far away from the angle hook 311 is fixedly connected with the spring fixing plate 315 through the first pull wire 316, one end of the spring fixing plate 315 far away from the tension spring, the rotating rod 319 is close to one end of the spring fixing plate 315 and is installed at the axis position of the torsion spring reel 318 in an embedded mode, one end of the spring fixing plate 315 close to the top rod 312 is fixedly connected to one end, far away from the top rod 312, of the tension spring 317 in an electric welding mode, and the other end of the rotating rod 319 is fixedly connected to the abduction type positioning mechanism 32.

The extended positioning mechanism 32 includes a sliding fixed slot rod 321, a sliding push rod 322, a positive terminal block 323, a dual-stage disk 324, a fixed pulley 325, a disk attaching wheel 326, a conductive belt 327, and a negative terminal block 328, the sliding push rod 322 is divided into two groups, one end of the sliding push rod is movably connected with one end of the sliding fixed slot rod 321 close to the dual-stage disk 324 through a pin, the other end of the sliding push rod 322 is respectively fixedly connected with the dual-stage disk 324 and the negative terminal block 328 through an adhesion mode, one end of the dual-stage disk 324 far from the dual-stage disk 324 is installed at the axial position of the disk attaching wheel 326 through an embedding mode, the outer ring surface of the disk attaching wheel 326 is movably connected with the fixed pulley 325 through the conductive belt 327, and the fixed pulley 325 is in clearance fit with the outer surface of.

The cooperative electric control mechanism 33 comprises a push-out spring 331, a fixed collar 332, a passive support rod 333, a pin 334, a long connecting support rod 335, a support rod sleeve 336 and a second connecting support rod 337, the end of the push-out spring 331 close to the long connecting rod 335 is fixedly connected to the end of the fixing collar 332 far from the long connecting rod 335 by means of electric welding, the inner ring surface of the fixed lantern ring 332 is in interference fit with the outer surface of the passive strut 333, one end of the passive strut 333 close to the fixed lantern ring 332 is movably connected with one end of the long connecting strut 335 close to the fixed lantern ring 332 through a pin, the pin rod 334 is installed at the middle position of the long connecting support rod 335 in an embedded mode, one end of the long connecting support rod 335 far away from the passive support rod 333 is movably connected with one end of a second connecting support rod 337 through a pin, and the outer surface of the second connecting support rod 337 is nested with the inner surface of the support rod sleeve 336.

The receiving processing conductive mechanism 34 includes an information processing board 341, a controllable conductive block 342, a positioning pin block 343, and an output terminal 344, the positioning pin block 343 is provided with four and is divided into two groups and fixedly connected to the upper and lower ends of the information processing board 341 respectively in a manner of electric welding, the back of the controllable conductive block 342 is fixedly connected to the middle position of the positive end surface of the information processing board 341 in a manner of electric welding, the back of the output terminal 344 is fixedly connected to the positive end surface of the information processing board 341 in a manner of electric welding and is far away from one end of the controllable conductive block 342, and one end of the output terminal 344, which is far away from the controllable conductive block 342, is fixedly connected to the main power output mechanism.

The main power output mechanism 35 includes a second power line 351, a micro motor 352, a jacket 353 and a motor fixing sleeve 354, the whole micro motor 352 is installed inside the front end face of the motor fixing sleeve 354 in an embedding manner, the inner surface of the jacket 353 is fixedly connected to the outer surfaces of the upper end and the lower end of the motor fixing sleeve 354 in an electric welding manner, one end of the second power line 351, far away from the output terminal 344, is installed at one end of the motor fixing sleeve 354, close to the output terminal 344, in an embedding manner and is fixedly connected to the back of the micro motor 352 in an electric welding manner, and one end of the second power line 351, far away from the micro motor 352, is fixedly connected.

The electricity storage mechanism 36 comprises a storage battery 361, a fixed strip 362, a movable pin 363, a conductive rod 364, an input terminal 365 and a first power line 366, wherein the storage battery 361, the fixed strip 362, the movable pin 363, the conductive rod 364, the input terminal 365 and the first power line 366 are respectively provided with two parts and fixedly connected to the upper surface and the lower surface of the interior of the waterproof housing 2 through the fixed strip 362 in an electric welding manner, one end of the storage battery 361 far away from the conductive rod 364 is installed in the fixed strip 362 in an embedding manner, one end of the conductive rod 364 close to the storage battery 361 is mechanically connected with the storage battery 361 through the movable pin 363, one end of the input terminal 365 far away from the first power line 366 is fixedly connected to one end of the storage battery 361 close to the first power line 366 in an electric welding manner, one end of the first power line 366 close to the storage battery 361 is fixedly, the bottom end of the first power line 366 is fixedly connected with the top end of the power generation mechanism 37.

The dynamic power generation mechanism 37 comprises a magnet ring 371, a coil 372, a shaft 373, a fixed frame 374, a power transmission plate 375 and a metal shell 376, the outer circumferential surface of the magnet ring 371 is attached to the inner surface of the metal housing 376 by magnetic force, the back of the metal housing 376 is mounted on the front end surface of the power transmission plate 375 by embedding, the shaft 373 is embedded in the coil 372 and is coaxial with the metal housing 376, the shaft 373 is penetrated through the middle position of the front end face of the power transmission plate 375 from the back, the outer surface of the power transmission plate 375 is mounted on the inner surface of the fixing frame 374 in an embedded manner, the outer surface of the fixing frame 374 is fixedly connected to the side far away from the dual-connection triggering mechanism 31 inside the waterproof shell 2 by electric welding, the first power line 366 is provided with two power lines, and the bottom ends of the two power lines are respectively and fixedly connected to the upper end and the lower end of the power transmission plate 375 in an electric welding manner. .

The principle of the invention is as follows: because the fixed head 4 is fixed at the side end of the rear wheel of the bicycle, the waterproof casing 2 and the transmission control device 3 are inserted into one end of the fixed head 4, 311 is inserted into the fixed head 4 and fixed and limits the ejector rod 312, when the ejector rod 312 moves leftwards under stress, the reset spring 314 is stretched and the first traction wire 316 is pulled rightwards under the limiting action of the spring fixing plate 315, so that the disk sticking wheel 326 drives the two-stage disk 324 to rotate by mechanical energy, and the positions of the positive and negative poles of the two-stage disk are exchanged, when the magnetic poles of the ejector rod are exchanged, the repulsion force generated by the ejector rod pushes the positive pole end block 323 and the negative pole end block 328 to drive the sliding push rod 322 to push the sliding fixing groove rod 321 to extend outwards and embed into the two ends in the fixed head 4, the waterproof casing 2 is effectively fixed movably, when the waterproof casing 2 is damaged, the waterproof casing can be dismounted without damage by the double-connection, the replacement amount of parts is reduced, the driven support rod 333 is synchronously braked while the push rod 312 is pushed, the second connecting support rod 337 retracts under the pulling of the long connecting support rod 335, and the conductive rod 364 rotates clockwise half-way around the movable pin 363 through gravity to contact with the power-on end of the information processing board 341, so that the waste of the power stored in the storage battery 361 is avoided, while the bicycle is connected with the shaft rod 373 through one side of the shaft end and drives the shaft rod 373 to rotate at high speed through the mechanical energy of the shaft rod 373, micro-current generated through the magnetic induction phenomenon is transmitted to the input terminal 365 through the shaft rod 366, the continuous generated electric energy of the electric power is realized and is circularly supplied to the receiving processing conductive mechanism 34 and the main power output mechanism 35, and the power transmission of the micro-motor 352 is switched on through the second power line 351 through the controllable conductive block 342 when the speed change signal is received by the waterproof shell 2, the electric energy is converted into mechanical energy again to generate power supply for the movement of the speed changing seat plate 6, and the speed changing chain is moved at each speed changing gear through the traction of the chain disc 5 by the movement of the speed changing seat plate 6.

Coil 372 of the present invention is generally referred to as a wire winding in the form of a loop, with the most common coil applications being: the coil in the circuit refers to an inductor, namely, the wires are wound one by one and are insulated from each other, the insulating tube can be hollow, and can also comprise an iron core or a magnetic powder core, the inductor is called as an inductor for short, the inductor can be divided into a fixed inductor and a variable inductor, the fixed inductor coil is called as an inductor or a coil for short, the tension spring 317 is a mechanical part which works by utilizing elasticity, the part made of elastic materials deforms under the action of external force, and recovers the original shape after the external force is removed, and is also used as a 'spring', and the tension spring is generally made of spring steel.

The invention solves the problem that the manual brake is usually needed to replace the auxiliary gear of the speed changer and the speed changer is integrally fixed with the machine body, so that the integral replacement is needed when the internal parts are damaged, and the maintenance cost is increased The preparation method comprises the following steps of.

While there have been shown and described what are at present considered the fundamental principles of the invention, the essential features and advantages thereof, it will be understood by those skilled in the art that the present invention is not limited by the embodiments described above, which are merely illustrative of the principles of the invention, but rather, is capable of numerous changes and modifications in various forms without departing from the spirit or essential characteristics thereof, and it is intended that the invention be limited not by the foregoing descriptions, but rather by the appended claims and their equivalents.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (8)

1. Transmission control structure based on big data management mode characterized in that: the structure of the anti-theft device comprises a locking nut (1), a waterproof shell (2), a transmission control device (3), a fixing head (4), a chain disc (5) and a speed change seat plate (6), wherein the transmission control device (3) is integrally installed inside the waterproof shell (2) in an embedded mode, one end, close to the fixing head (4), of the waterproof shell (2) is installed inside one end, close to the waterproof shell (2), of the fixing head (4) in an embedded mode through the transmission control device (3), one end, far away from the chain disc (5), of the speed change seat plate (6) is installed at the bottom end of the waterproof shell (2) in an embedded mode, the chain disc (5) is installed inside the speed change seat plate (6) in an embedded mode, and the chain disc (5) is fixed inside the speed change seat plate (6) through an axis locking nut;

derailleur controlling means (3) including two trigger mechanism (31), abduction formula positioning mechanism (32), cooperation accuse electric mechanism (33), receive and handle electric mechanism (34), main power output mechanism (35), accumulate mechanism (36), dynamic power mechanism (37), waterproof shell (2) inside right-hand member fixed mounting has dynamic power mechanism (37), accumulate mechanism (36) are located dynamic power mechanism (37) and are gone up the lower extreme and fix in waterproof shell (2) inside upper and lower extreme through the welded mode, install in proper order from right to left in the inside of derailleur controlling means (3) dynamic power mechanism (37), main power output mechanism (35), receive and handle electric mechanism (34), cooperation accuse electric mechanism (33), abduction formula positioning mechanism (32), two trigger mechanism (31), main power output mechanism (35) back adopts the mode fixed connection of electric welding to be in waterproof shell (2) The partial surface, main power output mechanism (35) left end is connected through the wire electricity with receiving and handling electrically conductive mechanism (34), the cooperation accuse electric mechanism (33) is kept away from and is received and handle electrically conductive mechanism (34) one end and connect trigger mechanism (31) to be close to receiving and handle electrically conductive mechanism (34) one end mechanical connection together, connect trigger mechanism (31) to be close to receiving and handle electrically conductive mechanism (34) one end and abduction formula positioning mechanism (32) one end mechanical connection together.

2. The big data management mode-based transmission control structure according to claim 1, wherein: the double-connection trigger mechanism (31) comprises an angle hook (311), a push rod (312), a spring positioning plate (313), a reset spring (314), a spring fixing plate (315), a first traction wire (316), a tension spring (317), a torsion spring wire wheel (318), a rotating rod (319) and a second traction wire (3110), wherein the inner surface of the angle hook (311) is fixedly connected with the outer surface of one end, far away from the spring positioning plate (313), of the push rod (312) in an adhesion mode, the inner annular surface of the spring positioning plate (313) is fixedly connected with the outer surface of the middle position of the push rod (312) in an electric welding mode, one end, close to the angle hook (311), of the reset spring (314) is fixedly connected with one end, far away from the angle hook (311), of the push rod (312), far away from the angle hook (311), is fixedly connected with the spring fixing plate (315) through the first traction wire (316), one end, far away from the tension spring (317), of the spring fixing plate (315) is movably connected with the outer annular surface of the torsion spring wire wheel (318) through a second traction wire (3110), one end, close to the spring fixing plate (315), of the rotating rod (319) is installed at the axis position of the torsion spring wire wheel (318) in an embedded mode, one end, close to the ejector rod (312), of the spring fixing plate (315) is fixedly connected to one end, far away from one end of the ejector rod (312), of the tension spring (317) in an electric welding mode, and the other end of the rotating rod (319) is fixedly connected with the outward-extending type positioning mechanism (32).

3. The big data management mode-based transmission control structure according to claim 1 or 2, wherein: the outward-extending type positioning mechanism (32) comprises sliding fixed groove rods (321), sliding push rods (322), a positive end block (323), two-stage magnetic disks (324), a fixed pulley (325), a magnetic disk sticking wheel (326), a conduction belt (327) and a negative end block (328), the sliding push rods (322) are divided into two groups, one end of each sliding push rod (322) is movably connected with one end, close to the two-stage magnetic disks (324), of each sliding fixed groove rod (321) through a pin, and the other end of one sliding push rod (322) in each group of sliding push rods (322) is fixedly connected with the two-stage magnetic disks (324) in an adhesion mode; the other end of the other sliding push rod (322) in each group of sliding push rods (322) is fixedly connected with the negative pole end block (328) in an adhesion mode; one end of the double-stage magnetic disc (324), which is far away from the sliding fixed grooved rod (321), is arranged at the axle center of the magnetic disc sticking wheel (326) in an embedding mode, the outer ring surface of the magnetic disc sticking wheel (326) is movably connected with the fixed pulley (325) through the transmission belt (327), and the axle hole of the fixed pulley (325) is in clearance fit with the outer surface of one end of the rotating rod (319).

4. The big data management mode-based transmission control structure according to claim 1, wherein: the cooperative electricity control mechanism (33) comprises a push-out spring (331), a fixed lantern ring (332), a driven supporting rod (333), a pin rod (334), a long connecting supporting rod (335), a supporting rod sleeve (336) and a second connecting supporting rod (337), wherein one end, close to the long connecting supporting rod (335), of the push-out spring (331) is fixedly connected to one end, far away from the long connecting supporting rod (335), of the fixed lantern ring (332) in an electric welding mode, the inner ring surface of the fixed lantern ring (332) is movably matched with the outer surface of the driven supporting rod (333), one end, close to the fixed lantern ring (332), of the driven supporting rod (333) is movably connected with one end, close to the fixed lantern ring (332), of the long connecting supporting rod (335) through a pin, the pin rod (334) is installed at the middle position of the long connecting supporting rod (335) in an embedding mode, one end, far away from the driven supporting rod (333), of the, the outer surface of the second connecting strut (337) nests with the inner surface of the strut sleeve (336).

5. The big data management mode-based transmission control structure according to claim 1, wherein: the receiving and processing conductive mechanism (34) comprises an information processing board (341), a controllable conductive block (342), a positioning pin block (343) and an output terminal (344), wherein the positioning pin block (343) is provided with four parts and is divided into two groups to adopt the electric welding mode to be respectively fixedly connected to the upper end and the lower end of the information processing board (341), the back of the controllable conductive block (342) adopts the electric welding mode to be fixedly connected to the middle position of the positive end face of the information processing board (341), the back of the output terminal (344) adopts the electric welding mode to be fixedly connected to the positive end face of the information processing board (341) to be far away from one end of the controllable conductive block (342), and the output terminal (344) is far away from one end of the controllable conductive block (342) and is fixedly connected with a main power output mechanism (35.

6. The big data management mode-based transmission control structure according to claim 5, wherein: the main power output mechanism (35) comprises a second power line (351), a micro motor (352), a jacket (353) and a motor fixing sleeve (354), the micro motor (352) is integrally installed inside the front end face of the motor fixing sleeve (354) in an embedded mode, the inner surface of the jacket (353) is fixedly connected to the outer surfaces of the upper end and the lower end of the motor fixing sleeve (354) in an electric welding mode, one end, far away from an output terminal (344), of the second power line (351) is electrically connected with the input end of the micro motor (352), and one end, far away from the micro motor (352), of the second power line (351) is electrically connected with one end of the output terminal (344).

7. The big data management mode-based transmission control structure according to claim 1, wherein: the power storage mechanism (36) comprises a storage battery (361), a fixed strip (362), a movable pin (363), a conductive rod (364), an input terminal (365) and a first power line (366), wherein two storage batteries (361), two fixed strips (362), two movable pins (363), two conductive rods (364), two input terminals (365) and two first power lines (366) are arranged respectively; fixed strip (362) adopt the mode of electric welding respectively fixed connection in waterproof housing (2) inside upper and lower surface, battery (361) are kept away from conducting rod (364) one end and are installed inside fixed strip (362) through the mode of embedding, conducting rod (364) are close to battery (361) one end and are passed through activity round pin (363) and battery (361) mechanical connection together, input terminal (365) are kept away from first power cord (366) one end and are adopted the mode fixed connection of electric welding to be close to first power cord (366) one end in battery (361), first power cord (366) are close to battery (361) one end and are kept away from battery (361) one end electricity with input terminal (365) and are connected, battery (361) one end electricity is connected together in first power cord (366) bottom and powered electricity generation mechanism (37) top fixed connection.

8. The big data management mode-based transmission control structure according to claim 7, wherein: the power type power generation mechanism (37) comprises a magnet ring (371), a coil (372), a shaft rod (373), a fixing frame (374), a power transmission plate (375) and a metal shell (376), wherein the outer annular surface of the magnet ring (371) is adsorbed on the inner surface of the metal shell (376) through magnetic force, the back of the metal shell (376) is installed on the positive end surface of the power transmission plate (375) in an embedding mode, the shaft rod (373) is installed at the axial center position of the coil (372) in an embedding mode and is the same with the metal shell (376), the back of the shaft rod (373) penetrates through the middle position of the positive end surface of the power transmission plate (375), the outer surface of the power transmission plate (375) is installed on the inner surface of the fixing frame (374) in an embedding mode, the outer surface of the fixing frame (374) is fixedly connected to one side, far away from the dual trigger mechanism, the first power lines (366) are provided with two power lines, and the bottom ends of the two power lines are respectively and fixedly connected to the upper end and the lower end of the power transmission plate (375) in an electric welding mode.

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