CN105173926A - Novel winding device and use method thereof - Google Patents

Abstract

The invention discloses a novel winding device and a use method for the novel winding device. The winding device comprises a winding mechanism, a wire arranging mechanism, a guiding part and a sliding part. The winding mechanism comprises a winding pipe. The winding pipe comprises a winding pipe body, a movable side plate and a fixed side plate, wherein the winding pipe body can be rotationally jointed between the movable side plate and the fixed side plate. The wire arranging mechanism comprises a wire arranging pipe. The wire arranging pipe is provided with a wire arranging pipe cavity and a guiding groove, and the guiding groove is communicated with the wire arranging pipe cavity and the outside and downwards faces the winding pipe body. The guiding part is horizontally installed in the wire arranging pipe cavity. The guiding part comprises a guiding shaft and a protruding ridge part which protrudes out of the guiding shaft and integrally extends in a ring shape. A preset route is formed between the protruding ridge part and the guiding groove. The sliding part is reversely arranged in the guiding groove and extends towards the winding pipe body from the guiding part so as to be used for conducting reciprocating wire arranging. The two sides of the sliding part are transversely internally tangent to the inner side and the outer side of the protruding ridge part respectively so that the sliding part can slide along the preset route to conduct reciprocating wire arranging relative to the rotation of the winding pipe.

Description

New wound-rotor device and using method thereof

Technical field

The present invention relates to a kind of Winder, specifically, is a kind of Portable novel Winder and using method thereof of cable being realized automatically to synchronizing wire winding and winding displacement.

Background technology

Along with the use of cable increases, collecting in time and being released into need the problem solved cable.Reeler is the drum being mainly used to be wound around cable, be very important drum in a kind of cable use procedure, be widely used in the power supply of all kinds of industrial and mining enterprises such as smelting iron and steel, electronics, petrochemical complex, mine, electric power, railway, building ground, mining plants, airport, drainage sunk well factory and port and pier, market, hotel as introducing equipment.

Existing wire spool passes through the mode of turnover by cable winds thereon, if there is no artificial assistance, cable excessively will be gathered in same position, manual operation causes the unbalance stress to cable, winding displacement entanglement, thus artificial wire spool mostly exist inefficiency, complex structure, can not be orderly cable is released and reclaims, even can tie a knot, misplace the situation such as to put, fault rate is high.Electronic wire spool often matches with bus cable device, carries out orderly winding displacement, wherein for cable in folding and unfolding process, wire spool all matches with motor mostly with bus cable device, complex structure, and cost is higher, be unfavorable for carrying wire spool, its application is also subject to great restriction.

Namely the patent of invention being CN104655227A in China Patent Publication No. discloses a kind of intelligent charge level detector, it comprises the weight be connected with steel rope, be provided with wire spool, wirerope-winding is on wire spool, be provided with wire spool actuating device, rotary encoder a is coaxially arranged with wire spool, flower wheel is provided with in the same way with wire spool, the turning cylinder of flower wheel is connected with rotary encoder b, steel rope passes through from flower wheel, steel rope connect weight after guide piece under enter space exploration, described rotary encoder a, the signal of rotary encoder b is connected to PLC.It realizes wire spool to the synchronizing wire winding of cable and winding displacement by coder, complex structure, and cost is higher, affects Portability.

Namely the patent of invention being CN104692188A in China Patent Publication No. discloses a kind of strand oscillator, described strand oscillator comprises the first supporting seat, be parallel to the second supporting seat of described first supporting seat, be arranged at slide mechanism between described first supporting seat and described second supporting seat, glass pulley, wire spool, servomotor, contact disk, rotating forward contact and the contact that reverses, described servomotor is electrically connected on described slide mechanism and slides to control described slide mechanism; The rotating forward of described servomotor is controlled when described rotating forward contact connects described contact disk; The reversion of described servomotor is controlled when described reversion contact connects described contact disk.Thus, existing bus cable device needs to be connected with motor just can carry out actv. crank motion, with being synchronized with the movement of wire spool, need accurately calculation procedure and calibration instrument, both just can be made to coordinate, need the position correction and the velocity calibration that carry out strand oscillator and wire spool before use at every turn, and the most schooling of the user of wire spool is lower, may operate miss be there is, limit use crowd.Thus, how fast, effective, easy to operately carry out synchronizing wire winding and winding displacement to cable is the problem that relevant builder is badly in need of solving.

Summary of the invention

Main purpose of the present invention is to provide a kind of new wound-rotor device and using method thereof, it realizes synchronizing wire winding and winding displacement automatically to cable, do not need multiple motor to control winding mechanism and wire-arranging mechanism respectively, thus reduce operation easier and productive costs, expand market field of application.

Another object of the present invention is to provide a kind of new wound-rotor device and using method thereof, wherein, automatic synchronization coiling and winding displacement can be realized by artificial one-handed performance, timely to cable, orderly folding and unfolding, simple to operate, expand the crowd of being suitable for.

Another object of the present invention is to provide a kind of new wound-rotor device and using method thereof, it has simple integrative-structure, easy to carry, increases the portability that described Winder uses outside, do not need to increase intricately electrical equipment, reduce relevant manufacturing cost and use cost.

Another object of the present invention is to provide a kind of new wound-rotor device and using method thereof, wherein, convert rotational motion is linear reciprocal movement by wire-arranging mechanism, be achieved synchronizing wire winding and winding displacement, do not need to use coder to realize location, thus, be conducive to being widely used in collecting and discharging cable.

For reaching above object, the technical solution used in the present invention is: a kind of new wound-rotor device comprises a winding mechanism, described winding mechanism comprises a bobbin, described bobbin comprises a coiling body, a mobile side board and a fixed side, and described coiling body is engaged between described mobile side board and described fixed side rotationally; One wire-arranging mechanism, described wire-arranging mechanism comprises a winding displacement pipe, described winding displacement pipe is from the fixed side upwards horizontal-extending of described bobbin, towards described coiling body, wherein, described winding displacement pipe is provided with a winding displacement tube chamber and a guiding groove, winding displacement tube chamber and the external world described in described guiding groove UNICOM, downwards towards described coiling body; One guiding piece, described guiding piece level is installed in described winding displacement tube chamber, and wherein, described guiding piece comprises a leading axle and protrudes from a convex ridge portion of described leading axle one annular extension, forms a preset path between described convex ridge portion and described guiding groove; And a sliding component, described sliding component is inverted in described guiding groove, extend from described guiding piece to described coiling body, for reciprocal winding displacement, wherein, the both sides of described sliding component are laterally inscribed within the inside and outside both sides in described convex ridge portion respectively, be able to slide along described preset path, when described leading axle rotates, described convex ridge portion drives described sliding component to carry out traverse motion in described guiding groove, guides described sliding component to carry out reciprocal winding displacement relative to rotating of described bobbin; And a transmission component, described transmission component is installed in the tube chamber of described bobbin and described winding displacement pipe, connect described coiling body and described guiding piece step by step, wherein, described transmission component comprises multiple transmission shaft and engages multiple transmission gears of described transmission shaft and described guiding piece, for coiling body described in synchrodrive and described guiding piece.

According to one embodiment of the invention, transmission gear described in each has its pre-set dimension and shape respectively, and making has a relative rotation speed between described coiling body and described guiding piece, is applicable to the synchronizing wire winding to cable and winding displacement.

According to one embodiment of the invention, the sliding component of described wire-arranging mechanism comprises a winding displacement slide block, one auxiliary slider, a moving part and a winding displacement suspension hook, described winding displacement slide block and described auxiliary slider are by the connection of described moving part, be inscribed within the both sides cambered surface in described convex ridge portion respectively, slide along the preset path between described convex ridge portion and described guiding groove, wherein, described winding displacement suspension hook extends straight down from described winding displacement slide block, for the winding position keeping cable.

According to one embodiment of the invention, described guiding groove has a predetermined inner diameter, described predetermined inner diameter makes described winding displacement slide block and described auxiliary slider be suitable for wherein, linear slide is carried out towards described coiling body, wherein, the length stating guiding groove is consistent with the length in described convex ridge portion, is suitable for keeping described sliding component in described guiding groove and is tangential on described convex ridge portion carrying out motion of translation, meanwhile, the length of described guiding groove is not more than the length of described coiling body.

According to one embodiment of the invention, described convex ridge portion has one to preset profilograph, the two ends of described default profilograph and described sliding component keep tangent, make described winding displacement slide block and described auxiliary slider relative bonding in described guiding groove, linearly reciprocatingly slide along with the rotation in described convex ridge portion.

According to one embodiment of the invention, described winding mechanism comprises an operating portion further, and described operating portion is for the described mobile side board of rotation, and wherein, described operating portion stretches out integratedly from described mobile side board, is applicable to the described mobile side board of singlehanded promotion.

According to one embodiment of the invention, described new wound-rotor device comprises a bracing frame further, support frame as described above from described winding mechanism to downward-extension, for support described winding mechanism, wherein, support frame as described above is engaged in the fixed dam of described winding mechanism separably.

A using method for new wound-rotor device, it comprises step:

A cable through wire-arranging mechanism is wound in coiling body by ();

B () rotates described coiling body, for winding cable;

C () synchronously drives the guiding piece of described wire-arranging mechanism to rotate; And

D () guides the sliding component axially reciprocating with cable by the rotation of described guiding piece, in the process of coiling, realize synchronous winding displacement, wherein, the convex ridge portion of described guiding piece promotes described sliding component, makes described sliding component traverse motion.

According to one embodiment of the invention, described step (b), step (c) and step (d) are carried out simultaneously, along with the rotation of described coiling body, with the described sliding component relative sliding gradually of cable, for the cable arrangement in winding process.

According to one embodiment of the invention, described step (d) comprises step further: form a preset path, described convex ridge portion is along with the rotation of described guiding piece, its lowest segment moves forward or backward towards described guiding groove, promote the sliding component being tangential on described convex ridge portion, in guiding groove, trend towards described convex ridge portion lowest segment slide, make described sliding component along described preset path, relatively described coiling body slides forward or backward, for cable of back and forth laterally arranging.

Accompanying drawing explanation

Fig. 1 is new wound-rotor apparatus structure schematic diagram according to a preferred embodiment of the present invention.

Fig. 2 is the new wound-rotor apparatus structure transparent view according to above preferred embodiment of the present invention.

Fig. 3 is the new wound-rotor device lateral plan according to above preferred embodiment of the present invention.

Fig. 4 is the guide formation schematic diagram according to above preferred embodiment of the present invention.

Fig. 5 is the wire-arranging mechanism partial schematic diagram according to above preferred embodiment of the present invention.

Fig. 6 A is the synchronizing wire winding diagram of work according to above preferred embodiment of the present invention.

Fig. 6 B is the synchronizing wire winding diagram of work according to above preferred embodiment of the present invention.

Fig. 6 C is the synchronizing wire winding diagram of work according to above preferred embodiment of the present invention.

Description of reference numerals

1, new wound-rotor device 10, winding mechanism 11, bobbin

110, coiling tube chamber 111, coiling body 112, mobile side board

113, fixed side 12, operating portion 20, wire-arranging mechanism

21, winding displacement pipe 210, winding displacement tube chamber 211, guiding groove

22, guiding piece 221, leading axle 222, convex ridge portion

23, sliding component 231, winding displacement slide block 232, auxiliary slider

233, moving part 234, winding displacement suspension hook 30, transmission component

31, imput shaft 32, first driven shaft 33, second driven shaft

34, transmission gear 40, bracing frame

Detailed description of the invention

Below describe and realize the present invention for disclosing the present invention to enable those skilled in the art.Preferred embodiment in below describing only as an example, it may occur to persons skilled in the art that other apparent modification.

Is a kind of new wound-rotor device 1 as shown in Fig. 1 to Fig. 3, described new wound-rotor device 1 comprises a winding mechanism 10, described winding mechanism 10 comprises a bobbin 11, described bobbin 11 comprises coiling body 111, mobile side board 112 and a fixed side 113, and described coiling body 111 is engaged between described mobile side board 112 and described fixed side 113 rotationally; One wire-arranging mechanism 20, described wire-arranging mechanism 20 comprises a winding displacement pipe 21, described winding displacement pipe 21 is from the fixed side 113 upwards horizontal-extending of described bobbin 11, towards described coiling body 111, wherein, described winding displacement pipe 21 is provided with winding displacement tube chamber 210 and a guiding groove 211, and winding displacement tube chamber 210 and the external world described in described guiding groove 211 UNICOM, downwards towards described coiling body 111; One guiding piece 22, described guiding piece 22 level is installed in described winding displacement tube chamber 210, wherein, described guiding piece 22 comprises a leading axle 221 and protrudes from a convex ridge portion 222 of described leading axle 221 one annular extension, forms a preset path between described convex ridge portion 222 and described guiding groove 211; And a sliding component 23, described sliding component 23 is inverted in described guiding groove 211, extend from described guiding piece 22 to described coiling body 111, for reciprocal winding displacement, wherein, the both sides of described sliding component 23 are laterally inscribed within the inside and outside both sides in described convex ridge portion 222 respectively, be able to slide along described preset path, when described leading axle 221 rotates, described convex ridge portion 222 drives described sliding component 23 to carry out traverse motion in described guiding groove 211, guides described sliding component 23 to carry out reciprocal winding displacement relative to rotating of described bobbin 11; And a transmission component 30, described transmission component 30 is installed on described bobbin 11 with in the tube chamber of described winding displacement pipe 21, connect described coiling body 111 and described guiding piece 22 step by step, wherein, described transmission component 30 comprises multiple transmission shaft and engages multiple transmission gears 34 of described transmission shaft and described guiding piece 22, for coiling body 111 described in synchrodrive and described guiding piece 22.Thus, synchronizing wire winding and winding displacement are realized automatically to cable, does not need multiple motor to control winding mechanism 10 and wire-arranging mechanism 20 respectively, reduce operation easier and productive costs, expand market field of application.

Wherein, described mobile side board 112 extends from one end radial direction of described coiling body 111, described coiling body 111 rotates along with the rotation of described mobile side board 112, described fixed side 113 extends from the other end radial direction of described coiling body 111, described coiling body 111 is engaged in described fixed side 113 in relative rotation, wherein, described fixed side 113 keeps motionless, is connected between described coiling body 111 with described fixed side 113 by bearing.

Wherein, described coiling body 111 has a coiling tube chamber 110, the transmission shaft of described transmission component 30 comprises imput shaft 31,1 first driven shaft 32 and one second driven shaft 33, engaged by described transmission gear 34 between described imput shaft 31 with described first driven shaft 32, engaged by described transmission gear 34 between described first driven shaft 32 with described second driven shaft 33, described second driven shaft 33 is engaged by described transmission gear 34 with between described guiding piece 22, is able to synchronous transmitting torque step by step.

Wherein, described imput shaft 31 is arranged in described coiling tube chamber 110 with described first driven shaft 32, described imput shaft 31 is connected between described mobile side board 112 and described fixed side 113 rotationally, when described mobile side board 112 rotates, drive described imput shaft 31 coaxial rotating, thus described imput shaft 31 drives described first driven shaft 32 synchronous axial system.Wherein, described second driven shaft 33 is arranged at the vertical side of described winding displacement tube chamber 210, and described first driven shaft 32 drives described second driven shaft 33 synchronous axial system.Wherein, described guiding piece 22 is arranged at the horizontal side of institute's winding displacement tube chamber 210, and described second driven shaft 33 drives described guiding piece 22 synchronous axial system, thus, when described mobile side board 112 rotates, described guiding piece 22 relatively described coiling body 111 synchronous axial system.

Wherein, described in each, transmission gear 34 has its pre-set dimension and shape respectively, be applicable to there is a relative rotation speed between described coiling body 111 and described guiding piece 22, make the rotating speed relative engagement of the sliding velocity of described sliding component 23 and described coiling body 111, in other words, by the different designs to transmission gear 34, described coiling body 111 is different from the rotating speed of described guiding piece 22, make described sliding component 23 have one to preset sliding velocity, described default sliding velocity is applicable to synchronizing wire winding to cable and winding displacement.Such as, when described coiling body 111 coiling one is enclosed, described sliding component 23 is slided gradually by the guiding of described guiding piece 22 the cable width of a unit, the like, made cable synchronizing wire winding and winding displacement.

Wherein, described winding mechanism 10 comprises an operating portion 12 further, described operating portion 12 is for the described mobile side board 112 of rotation, described mobile side board 112 is able to be rotated by electronic or manual mode, when described mobile side board 112 is electrically controlled, described operating portion 12 is an Electronic control equipment, when described mobile side board 112 Non-follow control, described operation can be leader, operating personal can rotate described mobile side board 112 by one hand, to realize synchronous winding displacement to cable and coiling.Preferably, in order to increase the portability of described new wound-rotor device 1, described operating portion 12 stretches out integratedly from described mobile side board 112, promotes described mobile side board 112 for one hand.Thus, automatic synchronization coiling and winding displacement can be realized by artificial one-handed performance, timely to cable, orderly folding and unfolding, simple to operate, expand the crowd of being suitable for.

Shown in Fig. 4 and Fig. 5 is described wire-arranging mechanism 20, the sliding component 23 of described wire-arranging mechanism 20 comprises a winding displacement slide block 231, one auxiliary slider 232, one moving part 233 and a winding displacement suspension hook 234, described winding displacement slide block 231 and the connection of described auxiliary slider 232 by described moving part 233, the both sides cambered surface in described convex ridge portion 222 is inscribed within respectively, slide along the preset path between described convex ridge portion 222 and described guiding groove 211, wherein, described winding displacement suspension hook 234 extends straight down from described winding displacement slide block 231, for the winding position keeping cable, made cable pass described winding displacement suspension hook 234 to extend to described coiling body 111, uniform winding is carried out by the mode of synchronous winding displacement.In other words, cable is placed in the winding displacement suspension hook 234 of described winding displacement slide block 231, cable extends to described coiling body 111 through described winding displacement suspension hook 234, when described winding displacement slide block 231 relatively described coiling body 111 synchronous slide, described winding displacement suspension hook 234 drives cable to discharge in order.

Wherein, described guiding groove 211 internal diameter is consistent with the diameter of described winding displacement slide block 231 and described auxiliary slider 232, described guiding groove 211 is made substantially to keep the position of described winding displacement slide block 231 and described auxiliary slider 232, prevent its any sideway movement, be applicable to described sliding component 23 to be engaged in slidably in described guiding groove 211, make described sliding component 23 along described guiding groove 211 linear reciprocating motion.Wherein, described winding displacement slide block 231 is engaged in described guiding groove 211 with described auxiliary slider 232 by the mode that bearing is connected, described winding displacement slide block 231 and the bearing portion of described auxiliary slider 232 are external in the cell wall of described guiding groove 211, that is, described winding displacement slide block 231 and described auxiliary slider 232 one end respectively before and after inside and outside ground and the convex ridge portion 222 of described guiding piece 22 both sides tangent, extend from described convex ridge portion 222 to described guiding groove 211, the other end of described slide block is limited in described guiding groove 211 by the mode that bearing engages, be able to carry out linear reciprocating motion along described guiding groove 211, and, the sliding resistance suffered by described slide block is reduced by the mode of bearing.

In other words, described guiding groove 211 has a predetermined inner diameter, and described predetermined inner diameter makes described winding displacement slide block 231 be suitable for wherein with described auxiliary slider 232, carries out linear slide towards described coiling body 111.

The leading axle 221 of described guiding piece 22 is engaged in described second driven shaft 33 rotationally by transmission gear 34, made described guiding piece 22 and described coiling body 111 synchronous axial system, wherein, described guiding piece 22 is inconsistent with the speed of described coiling body 111.

Wherein, be the axial linear motion of described sliding component 23 by the convert rotational motion of described leading axle 221 by described convex ridge portion 222, that is, described convex ridge portion 222 has one to preset profilograph, the two ends of described default profilograph and described sliding component 23 keep tangent, make described winding displacement slide block 231 and the relative bonding of described auxiliary slider 232 in described guiding groove 211, linearly reciprocatingly slide along with the rotation in described convex ridge portion 222.Wherein, described default profilograph is complicated space curved surface, the spatial coordinates of described profilograph is calculated and designs according to the preset path of described sliding component 23 and the characteristics of motion, make described guiding piece 22 volume little, compact conformation, transmitting torque is large, thus, described guiding piece 22 makes gyroscopic movement, guides described sliding component 23 to complete predetermined moving along the preset path of design.

The reverse side one of described convex ridge portion 222 from one end of described leading axle 221 to its other end extends, rotation direction reversed bending, ringwise streamlined structure, remain that described slide block is tangent with the internal and external cambered surface in described convex ridge portion 222 respectively by described moving part 233, the profilograph in described convex ridge portion 222 and thickness are suitable for the tangent state keeping described sliding component 23, promote described sliding component 23 for curve, make described sliding component 23 linear reciprocal movement.

The preset path of described sliding component 23 is formed at the joining coordinate of described convex ridge portion 222 and described guiding groove 211, when described convex ridge portion 222 rotates, axially there is a lowest segment in described convex ridge portion 222 all the time, described lowest segment is near described guiding groove 211, described sliding component 23 is inscribed within described lowest segment both sides, thus, described sliding component 23 trends towards the lowest segment motion in described convex ridge portion 222, and the lowest segment in described convex ridge portion 222 remains in described guiding groove 211, realize the crank motion of described sliding component 23.In other words, described convex ridge portion 222 forms described preset path with a series of intersect coordinates of described guiding groove 211, described sliding component 23 is reciprocatingly slided in described guiding groove 211 along described preset path, and do not need extra operation, sliding component 23 commutates and slides as will be described, structure is simple, easy to operate.

Wherein, the length of described guiding groove 211 is consistent with the length in described convex ridge portion 222, is suitable for keeping described sliding component 23 in described guiding groove 211 and is tangential on described convex ridge portion 222 carrying out motion of translation.Meanwhile, the length of described guiding groove 211 is not more than the length of described coiling body 111, in case cable is extraneous around arriving.

Described moving part 233 axially connects described winding displacement slide block 231 and described auxiliary slider 232, intersect at the lowest segment in described convex ridge portion 222, when described guiding piece 22 rotates, the lowest segment in described convex ridge portion 222 moves forward or backward gradually along guiding groove 211, because described convex ridge portion 222 is tangent with two slide blocks of described sliding component 23, and described slide block is engaged in described guiding groove 211 slidably, described convex ridge portion 222 is subject to the resistance of one of them slide block in rotation process, and provide the propelling thrust of horizontal direction in described slide block, described slide block is made to drive described moving part 233 and another slide block.That is, torque axis is changed to axial force by the convex ridge portion 222 of described guiding piece 22, acts on described sliding component 23.

Such as, described winding displacement slide block 231 is tangential on backward the inside face in described convex ridge portion 222, described auxiliary slider 232 is tangential on forward the outside face in described convex ridge portion 222, when namely the lowest segment in described convex ridge portion 222 moves to described auxiliary slider 232 to described front movement, described auxiliary slider 232 produces resistance to described convex ridge portion 222, described convex ridge portion 222 provides a thrust to described auxiliary slider 232, due to the restriction of described guiding groove 211, described convex ridge portion 222 along described guiding groove 211 direction driven forward described in auxiliary slider 232, thus, described auxiliary slider 232 drives described moving part 233 and described winding displacement slide block 231, move forward to oneself's adjustment, in like manner, when namely to described winding displacement slide block 231 move backward by movement for the lowest segment in described convex ridge portion 222, described winding displacement slide block 231 produces resistance to described convex ridge portion 222, described convex ridge portion 222 provides a thrust to described winding displacement slide block 231, equally due to the restriction of described guiding groove 211, described convex ridge portion 222 promotes described winding displacement slide block 231 backward along the direction of described guiding groove 211, thus, described winding displacement slide block 231 drives described moving part 233 and described auxiliary slider 232, and oneself moves to adjustment backward.Thus convert rotational motion is linear reciprocal movement by described wire-arranging mechanism 20, is achieved synchronizing wire winding and winding displacement, does not need to use coder to realize location, be conducive to being widely used in collecting and discharging cable.

Wherein, described new wound-rotor device 1 comprises a bracing frame 40 further, support frame as described above 40 is from described winding mechanism 10 to downward-extension, for the described winding mechanism 10 of support, wherein, support frame as described above 40 is engaged in the fixed dam of described winding mechanism 10 separably, is convenient to carrying of described new wound-rotor device 1, and reduces transport space.

Wherein, described winding displacement pipe 21 from described bobbin 11 straight up, horizontal-extending, described second driven shaft 33 is arranged in the vertical side of described winding displacement pipe 21, described guiding piece 22 is arranged in the horizontal side of described winding displacement pipe 21, described winding displacement pipe 21 is grip structure at right angles, be convenient to the carrying of described novel wire arranging device with carry, increase its portability, be conducive to outdoor operations.

Shown in Fig. 6 A to Fig. 6 C is synchronizing wire winding and the winding displacement process of described new wound-rotor device 1, the winding displacement suspension hook 234 that described wire-arranging mechanism 20 is passed in one end of cable is fixed on described coiling body 111, rotate described coiling body 111 and carry out winding operation, synchronously, described sliding component 23 is travelled forward gradually by the rotation of described guiding piece 22, when described coiling body 111 winds a circle cable, described sliding component 23 slides certain distance, described distance can be the width of cable, thus carry out automatically in winding process to cable, winding displacement in an orderly manner, be able to uniform coiling on coiling body 111.Along with synchronizing wire winding and winding displacement continue carry out, when cable from one end of described cable body when to the other end of described cable body, as from mobile side board 112 end when to fixed side 113 end, described sliding component 23 slides into the end of described guiding groove 211, the lowest segment in described convex ridge portion 222 starts reverse movement, due to the change of thrust direction, described sliding component 23 moves backward from moving forward to become, guide carrying out in order of winding displacement, cable is from rotating to the initial end of described coiling body 111 again, as cable moves from fixed side 113 end to mobile side board 112 sections of coilings.Thus described new wound-rotor device 1 has simple integrative-structure, easy to carry, increases the portability that described Winder uses outside, do not need to increase intricately electrical equipment, reduce relevant manufacturing cost and use cost.

A using method for new wound-rotor device 1, it comprises step:

A cable through wire-arranging mechanism 20 is wound in coiling body 111 by ();

B () rotates described coiling body 111, for winding cable;

C () synchronously drives the guiding piece 22 of described wire-arranging mechanism 20 to rotate; And

D () guides sliding component 23 axially reciprocating with cable by the rotation of described guiding piece 22, synchronous winding displacement is realized in the process of coiling, wherein, the convex ridge portion 222 of described guiding piece 22 promotes described sliding component 23, makes described sliding component 23 traverse motion.

Wherein, described step (b), step (c) and step (d) are carried out simultaneously, along with the rotation of described coiling body 111, with described sliding component 23 relative sliding gradually of cable, for the cable arrangement in winding process.

Wherein, described step (d) comprises step further: form a preset path, described convex ridge portion 222 is along with the rotation of described guiding piece 22, its lowest segment moves forward or backward towards described guiding groove 211, promote the sliding component 23 being tangential on described convex ridge portion 222, in guiding groove 211, trend towards described convex ridge portion 222 lowest segment slide, make described sliding component 23 along described preset path, relatively described coiling body 111 slides forward or backward, for cable of back and forth laterally arranging.

More than show and describe groundwork of the present invention, principal character and advantage of the present invention.The technical personnel of the industry should be understood; the present invention is not restricted to the described embodiments; the just principle of the present invention described in above-described embodiment and specification sheets; the present invention also has various changes and modifications without departing from the spirit and scope of the present invention, and these changes and improvements all fall in claimed scope of the present invention.The protection domain of application claims is defined by appending claims and equivalent thereof.

Claims (10)

1. a new wound-rotor device, is characterized in that, comprising:

One winding mechanism, described winding mechanism comprises a bobbin, and described bobbin comprises a coiling body, a mobile side board and a fixed side, and described coiling body is engaged between described mobile side board and described fixed side rotationally;

One wire-arranging mechanism, described wire-arranging mechanism comprises:

One winding displacement pipe, described winding displacement pipe from the fixed side upwards horizontal-extending of described bobbin, towards described coiling body, wherein, described winding displacement pipe is provided with a winding displacement tube chamber and a guiding groove, winding displacement tube chamber and the external world described in described guiding groove UNICOM, downwards towards described coiling body;

One guiding piece, described guiding piece level is installed in described winding displacement tube chamber, and wherein, described guiding piece comprises a leading axle and protrudes from a convex ridge portion of described leading axle one annular extension, forms a preset path between described convex ridge portion and described guiding groove; And

One sliding component, described sliding component is inverted in described guiding groove, extend from described guiding piece to described coiling body, for reciprocal winding displacement, wherein, the both sides of described sliding component are laterally inscribed within the inside and outside both sides in described convex ridge portion respectively, be able to slide along described preset path, when described leading axle rotates, described convex ridge portion drives described sliding component to carry out traverse motion in described guiding groove, guides described sliding component to carry out reciprocal winding displacement relative to rotating of described bobbin; And

One transmission component, described transmission component is installed in the tube chamber of described bobbin and described winding displacement pipe, connect described coiling body and described guiding piece step by step, wherein, described transmission component comprises multiple transmission shaft and engages multiple transmission gears of described transmission shaft and described guiding piece, for coiling body described in synchrodrive and described guiding piece.

2. new wound-rotor device according to claim 1, is characterized in that, transmission gear described in each has its pre-set dimension and shape respectively, and making has a relative rotation speed between described coiling body and described guiding piece, is applicable to the synchronizing wire winding to cable and winding displacement.

3. new wound-rotor device according to claim 1 and 2, it is characterized in that, the sliding component of described wire-arranging mechanism comprises a winding displacement slide block, one auxiliary slider, a moving part and a winding displacement suspension hook, described winding displacement slide block and described auxiliary slider are by the connection of described moving part, the both sides cambered surface in described convex ridge portion is inscribed within respectively, slide along the preset path between described convex ridge portion and described guiding groove, wherein, described winding displacement suspension hook extends straight down from described winding displacement slide block, for the winding position keeping cable.

4. new wound-rotor device according to claim 3, it is characterized in that, described guiding groove has a predetermined inner diameter, described predetermined inner diameter makes described winding displacement slide block and described auxiliary slider be suitable for wherein, linear slide is carried out towards described coiling body, wherein, the length stating guiding groove is consistent with the length in described convex ridge portion, be suitable for keeping described sliding component in described guiding groove and be tangential on described convex ridge portion carrying out motion of translation, meanwhile, the length of described guiding groove is not more than the length of described coiling body.

5. new wound-rotor device according to claim 4, it is characterized in that, described convex ridge portion has one to preset profilograph, the two ends of described default profilograph and described sliding component keep tangent, make described winding displacement slide block and described auxiliary slider relative bonding in described guiding groove, linearly reciprocatingly slide along with the rotation in described convex ridge portion.

6. new wound-rotor device according to claim 5, it is characterized in that, described winding mechanism comprises an operating portion further, described operating portion is for the described mobile side board of rotation, wherein, described operating portion stretches out integratedly from described mobile side board, is applicable to the described mobile side board of singlehanded promotion.

7. new wound-rotor device according to claim 6, it is characterized in that, described new wound-rotor device comprises a bracing frame further, support frame as described above is from described winding mechanism to downward-extension, for the described winding mechanism of support, wherein, support frame as described above is engaged in the fixed dam of described winding mechanism separably.

8. a using method for new wound-rotor device, is characterized in that, comprises step:

A cable through wire-arranging mechanism is wound in coiling body by ();

B () rotates described coiling body, for winding cable;

C () synchronously drives the guiding piece of described wire-arranging mechanism to rotate; And

D () guides the sliding component axially reciprocating with cable by the rotation of described guiding piece, in the process of coiling, realize synchronous winding displacement, wherein, the convex ridge portion of described guiding piece promotes described sliding component, makes described sliding component traverse motion.

9. the using method of new wound-rotor device according to claim 8, it is characterized in that, described step (b), step (c) and step (d) are carried out simultaneously, along with the rotation of described coiling body, with the described sliding component relative sliding gradually of cable, for the cable arrangement in winding process.

10. the using method of new wound-rotor device according to claim 9, it is characterized in that, described step (d) comprises step further: form a preset path, described convex ridge portion is along with the rotation of described guiding piece, its lowest segment moves forward or backward towards described guiding groove, promote the sliding component being tangential on described convex ridge portion, in guiding groove, trend towards described convex ridge portion lowest segment slide, make described sliding component along described preset path, relatively described coiling body slides forward or backward, for cable of back and forth laterally arranging.