CN114455402A - Containing and carding device for steel strands - Google Patents

Abstract

The invention discloses a steel strand accommodating and carding device which comprises a rotatable accommodating wire frame, wherein a plurality of annular partition plates are assembled on the outer ring of the accommodating wire frame at equal intervals along the axial direction, and an accommodating groove for accommodating a steel strand is formed between each annular partition plate and an adjacent annular partition plate; a give the mechanism for sending into steel strand wires holding tank one by one, just right the holding tank setting, send into the axial displacement of mechanism along accomodating the line frame in order to send into each holding tank with the steel strand wires, give the mechanism one by one and send into the holding tank in-process with the steel strand wires and accomodate line frame corotation: and the delivery mechanism is used for delivering the steel strand out, is arranged above the side of the accommodating coil holder far away from the delivery mechanism, and reversely rotates the accommodating coil holder to deliver the steel strand into the delivery mechanism and deliver the steel strand out by the delivery mechanism in the conveying direction. The automation effect of whole mechanism is higher, can realize that more unreel, fix with the automation of steel strand, export work.

Description

Containing and carding device for steel strands

Technical Field

The invention belongs to the field of steel strand processing equipment, and particularly relates to a containing and carding device with a steel strand.

Background

The steel strand has application in a plurality of industries, the steel strand in the prior art is coiled by a single wire, the steel strand needs to be cut in equal length and drawn in a shaping way when in use, each cutting or drawing wire needs to be matched with a special platform and a special cutting device, a plurality of drawing wires are arranged in parallel on a construction site, the occupied area is large, the energy consumption is high, the semi-automatic operation needs manpower to cut the steel strand and the steel strand is drawn and sent out by a tractor, the construction process wastes time and labor, and great manpower and material resources are wasted, the prior art does not have a process for arranging the steel strand, the steel strand cannot be arranged and combed into a row, the bearing effect of the steel strand in the prior art is limited, and the waste of steel quantity is caused,

and frock among the prior art, degree of automation is low to there is not the equipment that can realize many and send out after holding the fixed length with steel strand wires concurrent operation among the prior art, and the market vacancy is great.

Disclosure of Invention

The invention provides a steel strand accommodating and carding device for solving the problem that a plurality of steel strands cannot be automatically processed simultaneously in the existing product, and the device achieves the technical effects of dragging, accommodating, clamping and fixing the plurality of steel strands in fixed length, returning and outputting the steel strands simultaneously.

The technical scheme is as follows:

the accommodating and carding device for the steel strand comprises

The steel strand collecting device comprises a collecting wire frame capable of axially rotating, wherein a plurality of annular partition plates are assembled on the outer ring of the collecting wire frame at equal intervals along the axial direction, and a containing groove for containing a steel strand is formed between each annular partition plate and an adjacent annular partition plate;

the delivery mechanism is used for delivering the steel strands into the accommodating grooves and is arranged opposite to the accommodating grooves, the delivery mechanism moves along the axial direction of the accommodating wire frame to deliver the steel strands into each accommodating groove, and the accommodating wire frame rotates forwards when the delivery mechanism delivers the steel strands into the accommodating grooves;

a sending-out mechanism for sending out the steel strand, which is arranged on the oblique upper part of the side of the receiving wire frame far away from the delivering mechanism,

the storage wire frame reversely rotates to feed the steel strand into the feeding-out mechanism and the steel strand is fed out by the feeding-out mechanism like the conveying direction.

Furthermore, each accommodating groove is provided with a rotary self-locking piece for clamping the input end of the steel strand and a tail end locking unit for clamping the tail end of the steel strand;

the rotary self-locking piece is a component with two ends forming columnar parts and the columnar parts are connected through a bending rod,

the lower part of the rotary self-locking pieces is a clamping plate fixed on the inner side of the storage line frame, and the pivot of each rotary self-locking piece which is pivoted through the eccentric pin joint is matched on the frame body of the storage line frame in a rotating way.

Further, terminal locking unit set up in the outside of holding tank and with accomodate line frame fixed connection, terminal locking unit includes the end plate on the cyclic annular baffle of fixed, fixes the seat that compresses tightly on the end plate, has seted up the spout compressing tightly on the seat, is located the spout and slides and equips with compressing tightly the pole, compress tightly the slider and stretch out and along opening direction and sliding fit on the end plate in the opening seted up on the end plate, compressing tightly the wedge portion that the pole shaping has the wedge form to be used for compressing tightly the lift slider, the top of compressing tightly the pole be connected with the folding rod, the middle part pin joint of folding rod is on two adjacent end plates.

Furthermore, a compression telescopic cylinder is arranged right below each compression rod and pushes the compression rods to lock the steel strands.

Furthermore, the entrance of the sending-out mechanism is provided with a lifting plate capable of lifting along the vertical direction, the upper surface of the lifting plate is connected with the telescopic end of the vertically arranged telescopic cylinder, and the lifting plate lifts the extending end of the folding rod and can unlock the limit of the steel strand.

Further, the delivery mechanism comprises a delivery unit capable of moving in parallel along the axial direction of the receiving bobbin and a cutting unit capable of moving in parallel along the axial direction of the receiving bobbin, the delivery unit comprises a plurality of linkage rollers distributed in a folded line shape, a passing path for the steel strand to pass through is formed between the linkage rollers, and the cutting unit can cut off the delivered steel strand along the moving direction.

The storage rack is characterized by further comprising a supporting rack, the center of the storage rack is erected in the supporting rack through a rotating shaft, and one end of the rotating shaft is connected with the rotary motor.

Furthermore, the steel cables locked by the tail end locking unit are horizontally locked, and the steel cables are uniformly arranged in a straight line after being locked.

Furthermore, the delivery mechanism comprises a traction unit for drawing the steel rope and two delivery rollers arranged in parallel for delivering the steel rope, the traction unit is provided with a horizontal clamping opening, the steel rope is completely accommodated in the clamping opening and clamped after being unlocked, and the traction unit linearly draws the steel rope after clamping the steel rope and is delivered by the delivery rollers.

Furthermore, the delivery mechanism also comprises a cross rod which is used for lifting the inclined strut of the telescopic cylinder, the cross rod is positioned on one side of the traction unit and is positioned below the delivery roller, and the traction unit lifts the steel strand and delivers the steel strand to the delivery roller after clamping the steel strand, and the steel strand is delivered by the delivery roller.

It has the beneficial effect that for prior art:

1. the designed accommodating wire frame is provided with a plurality of accommodating grooves which are formed by dividing annular partition plates, the accommodating wire frame can be driven to rotate by a rotating motor, the designed rotating self-locking piece can lock the steel strand in the rotating process of the accommodating wire frame, and the steel strand is locked in the accommodating grooves by a tail end locking unit after the accommodating is finished.

2. The steel strand wires in every holding tank are delivered the mechanism realization through giving that can the sideslip change delivery station to give to the mechanism still has cutting ability to give to one's hand, after the steel strand wires delivered and get into the back holding tank, cut off the steel strand wires by oneself in order to realize the fixed length and many technological effects that hold.

3. The storage rack can be integrally turned over after the steel strands are stored, the tail ends of the horizontal postures of the steel strands are delivered to the position of the delivery mechanism, and the delivery mechanism can pull the integral output of the steel strands.

4. The self-locking piece rotates to self-lock the steel strand by utilizing the rotary force of the rotating wheel, the self-locking piece does not need an additional power source, the preset effect is realized by a simple structure, and the design is exquisite.

5. The tail end locking unit can follow and accomodate the synchronous gyration of line frame to tail end locking unit structure exquisiteness still has the release mechanism that can follow synchronous gyration, has realized through two locking units with the steel strand wires locking in order to guarantee subsequent synchronous output on accomodating the line frame.

6. The delivery mechanism is designed to align the steel strand with the respective receiving grooves in the transverse direction, i.e. the direction of the arrangement of the receiving grooves, and has a cutting unit for cutting to length after the end of the insertion of the steel strand.

7. The designed sending-out mechanism can integrally drag and drag the arranged steel strand and send out the steel strand under the action of the rubber covered roller.

8. The tail ends of the steel strands in the accommodating groove are arranged neatly, and the steel strands are conveniently and integrally conveyed out by the conveying mechanism due to the uniform distribution of the steel strands at equal intervals.

9. Can realize many steel strands to see off simultaneously because many steel strands that preorder scheme realized see off simultaneously and can form many steel strands and in bank output in subsequent handling, the effect of lapping simultaneously after the later stage ligature, after the lapping that a plurality of steel strands parallel, can standardize it, it is even to use its atress side by side, the anti-pulling limit obtains promoting, it is more reasonable to arrange, form new standardized many steel strands and roll up the product side by side according to length and radical preset promptly, this product has been in the transportation and has been in the use, the amount of labour of reduction job site that can be very big, the current has very big advantage to other products on the market.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention.

Fig. 1 is a side view of a carding unit for accommodating steel strands.

Fig. 2 is a perspective view of the carding unit for accommodating the steel strand.

Fig. 3 is an axial view of the storage bobbin.

FIG. 4 is a top view of the wire rack.

FIG. 5 is a perspective view of the storage rack.

Fig. 6 is a structural view of the tip lock unit.

Fig. 7 is a side view structural view of the tip lock unit.

Fig. 8 is a sectional structural view of the tip lock unit.

Fig. 9 is a side view structural view of the delivery mechanism.

Fig. 10 is an internal structural view of the delivery unit.

Fig. 11 is an axial view of the feeding mechanism.

Fig. 12 is a side view structural view of the feeding mechanism.

Detailed Description

In order to make the technical solutions of the present invention better understood, 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.

The invention is further explained below according to the attached drawings 1-12, and provides a steel strand accommodating and carding device, which comprises a supporting rack 5, wherein the supporting rack 5 is a latticed steel framework, a storage wire rack 1 is rotatably assembled at the middle shaft of the supporting rack 5 through a rotating shaft, the storage wire rack 1 is a columnar rotating rack body, the middle shaft of the storage wire rack 1 is connected with a rotating motor, and the rotating motor is fixed on the supporting rack 5.

The containing line frame 1 can rotate axially, a plurality of annular partition plates 1a are assembled on the outer ring of the containing line frame 1 at equal intervals along the axial direction, a containing groove 1d for containing steel strands is formed between each annular partition plate 1a and the adjacent annular partition plate 1a, and the containing groove 1d is an annular groove body

As shown in fig. 1 and 2, the wire-stranding machine further comprises a delivering mechanism 2 for delivering the steel strands into the accommodating grooves 1d, wherein the delivering mechanism 2 is arranged opposite to the accommodating grooves 1d, the delivering mechanism moves along the axial direction of the accommodating wire frame 1 to deliver the steel strands into each accommodating groove 1d, and the accommodating wire frame 1 rotates forwards when the delivering mechanism 2 delivers the steel strands into the accommodating grooves 1 d; and a feeding mechanism 4 for feeding out the steel strand, which is arranged obliquely above the side of the storage coil holder 1 far away from the feeding mechanism 2, wherein the storage coil holder 1 is reversed to feed the steel strand into the feeding mechanism 4 and the steel strand is fed out by the feeding mechanism 4 in the conveying direction.

As another embodiment provided by the present invention, as shown in fig. 3, a rotary self-locking member 1b and a terminal locking unit 3 for locking both ends of a steel strand are added.

Specifically, be located and all be furnished with the rotation from locking part 1b that is used for pressing from both sides tight steel strand wires input in every holding tank 1d, rotation from locking part 1b for both ends become the component that links to each other through the pole of bending between column portion and the column portion, rotate from locking part 1 b's below for fixing the pinch-off blades 1c of accomodating line frame 1 inboard, rotate from locking part 1b and set up side by side on pinch-off blades 1c, each rotates from locking part 1 b's the department of bending through a public sharing axle with the normal running fit on the frame of accomodating line frame 1, sharing axle be eccentric pin joint on rotating from locking part 1 b.

As shown in fig. 5 to 8, as still another embodiment provided by the present invention, there is disclosed a terminal locking unit 3 for clamping the end of a steel strand;

specifically, the tail end locking unit 3 is arranged at the outer side of the accommodating groove 1d and fixedly connected with the accommodating wire frame 1, the tail end locking unit 3 is opposite to the delivery mechanism 2, but the tail end locking unit 3 can rotate along with the accommodating wire frame 1, the tail end locking unit 3 comprises an end plate 3a fixed on each annular partition plate 1a and a pressing seat 3f fixed on the end plate 3a, one side of the pressing seat 3f is provided with a linear sliding groove, a pressing rod 3d is arranged in the sliding groove in a sliding manner, a pressing slide block 3b extends out from an opening formed in the end plate 3a and is in sliding fit with the end plate 3a along the opening direction, two sides of the linear sliding groove are respectively provided with a guide post extending out perpendicular to the pressing seat 3f, two sides of the pressing slide block 3b extend out of a side plate and are in transition fit with the guide posts to realize linear sliding, the pressing rod 3d is formed with a wedge-shaped wedge part for pressing the lifting slide block, the top of the pressing rod 3d is hinged with a folding rod 3c, the middle of the folding rod 3c is pivoted on the two adjacent end plates 3a, a pressing telescopic cylinder is arranged right below each pressing rod 3d, and the pressing telescopic cylinders push the pressing rods 3d to lock the steel strand.

As shown in fig. 3, as a further embodiment provided by the present invention, a mechanism for unlocking a steel hoist rope is disclosed.

Specifically, the inlet of the sending-out mechanism 4 is provided with a lifting plate 6a capable of lifting along the vertical direction, the upper surface of the lifting plate is connected with a telescopic end of a vertically arranged telescopic cylinder 6b, and the lifting plate lifts the extending end of the folding rod 3c and can unlock the limit of the steel strand.

As a further embodiment provided by the present invention, as shown in fig. 9-10, a delivery mechanism 2 for delivering a steel hoist is disclosed,

specifically, the delivering mechanism 2 comprises a delivering unit which can move in parallel along the axial direction of the receiving coil holder 1, the delivering unit is integrally assembled on a first slide rail module 2b, and a cutting unit 2d which can move in parallel along the axial direction of the receiving coil holder 1, the cutting unit 2d is integrally assembled on a second slide rail module 2c, the delivering unit comprises a plurality of linkage rollers, the linkage rollers 2e are pivoted in a delivering unit casing, a passing path for passing a steel strand is formed between the linkage rollers 2e, the linkage rollers are meshed through a gear 2f to synchronously rotate, the first slide rail module 2b and the second slide rail module 2c are arranged in parallel, the cutting unit can cut off the delivered steel strand along the moving direction, a delivering motor 2a is arranged above the delivering unit casing, the delivering motor 2a is in power connection with the pivot of one linkage roller 2e, the cutting unit is a grinding wheel cutting machine.

In order to ensure that the whole traction can be carried out in the subsequent traction process, the steel cables locked by the tail end locking unit 3 are horizontally locked, and the steel cables are uniformly distributed in a straight line after being locked.

As a further embodiment provided by the present invention, as shown in fig. 11-12, a feed-out mechanism 4 for delivering a steel hoist rope is disclosed,

specifically, the sending-out mechanism 4 comprises a sending-out machine shell, a traction unit used for traction of the steel rope, two sending-out rollers 4c and a sending-out motor 4a which are arranged in parallel and used for sending the steel rope, the sending-out rollers 4c are in power connection with the sending-out motor 4a, the traction unit is provided with a horizontal clamping opening capable of being opened and closed, the whole traction unit is in linear sliding fit in the sending-out machine shell, a traction cylinder 4b used for driving the traction unit to move linearly is connected to the back of the traction unit, one end of the traction cylinder 4b is connected with the sending-out machine shell, and the sending-out end of the traction cylinder 4b is connected with the traction unit.

The traction unit comprises a traction shell which is in sliding fit in the sending-out machine shell, a traction roller 4h and a clamping rod parallel to the traction roller 4h are arranged on a rotating frame in the traction shell, transition pieces connected with two ends of the clamping rod are in rotating fit to the traction roller 4h, a clamping cylinder 4f is arranged on one side of each transition piece, one end of each clamping cylinder 4f is hinged with the traction shell, the other end of each clamping cylinder is hinged with the transition piece, all steel strands are contained in a clamping opening and clamped after the locking of the steel strands is released, and the steel strands are linearly dragged and conveyed by a sending-out roller 4c after the steel strands are clamped by the traction unit. The delivery mechanism 4 further comprises a cross rod which is obliquely supported by a lifting telescopic cylinder 4e, two ends of the cross rod are hinged to the lower portion of the traction shell through a swing arm 4d, the cross rod is located on one side of the traction unit and located below the delivery roller 4c, the steel strand is lifted and delivered to the lower portion of the delivery roller 4c under continuous action of the delivery roller 4c after the steel strand is clamped by the traction unit, the steel strand is delivered to a slope-shaped plate located on the downstream of the steel strand conveying direction by the delivery roller 4c, a plurality of vertical plates are vertically arranged on the upper surface of the slope-shaped plate, and the number of channels formed between the vertical plates is the same as the number of the pulled steel strands.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (10)

1. The accommodating and carding device for the steel strand is characterized by comprising

The rotary storage coil holder is characterized in that a plurality of annular partition plates are assembled on the outer ring of the storage coil holder at equal intervals along the axial direction, and a containing groove for containing steel strands is formed between each annular partition plate and the adjacent annular partition plate;

the delivery mechanism is used for delivering the steel strands into the accommodating grooves and is arranged opposite to the accommodating grooves, the delivery mechanism moves along the axial direction of the accommodating wire frame to deliver the steel strands into each accommodating groove, and the accommodating wire frame rotates forwards when the delivery mechanism delivers the steel strands into the accommodating grooves;

a sending-out mechanism for sending out the steel strand, which is arranged on the oblique upper part of the side of the receiving wire frame far away from the delivering mechanism,

the storage wire frame reversely rotates to feed the steel strand into the feeding-out mechanism and the steel strand is fed out by the feeding-out mechanism like the conveying direction.

2. The steel strand accommodating and carding device as claimed in claim 1, wherein each accommodating groove is provided with a rotary self-locking piece for clamping the input end of the steel strand and a terminal locking unit for clamping the terminal end of the steel strand;

the rotary self-locking piece is a component with two ends forming columnar parts and the columnar parts are connected through a bending rod,

the lower part of the rotary self-locking pieces is a clamping plate fixed on the inner side of the storage line frame, and the pivot of each rotary self-locking piece which is pivoted through the eccentric pin joint is matched on the frame body of the storage line frame in a rotating way.

3. The accommodating and carding device for the steel strand according to claim 2, wherein the terminal locking unit is disposed outside the accommodating groove and fixedly connected to the accommodating wire holder, the terminal locking unit comprises an end plate fixed to the annular partition plate, and a pressing seat fixed to the end plate, a sliding groove is formed in the pressing seat, a pressing rod is slidably fitted in the sliding groove, the pressing slider protrudes from an opening formed in the end plate and slidably fits the end plate along the opening direction, a wedge-shaped portion for pressing the lifting slider is formed in the pressing rod, a folding rod is connected to the top of the pressing rod, and the middle of the folding rod is pivotally connected to two adjacent end plates.

4. The accommodating and carding device for the steel strands as claimed in claim 3, wherein a compression telescopic cylinder is arranged right below each compression rod, and the compression telescopic cylinder pushes the compression rods to lock the steel strands.

5. The accommodating and carding device for the steel strands as claimed in claim 3, wherein a lifting plate capable of lifting in a vertical direction is arranged at an inlet of the sending-out mechanism, an upper surface of the lifting plate is connected with a telescopic end of a vertically arranged telescopic cylinder, and the lifting plate lifts an extending end of the folding rod to unlock the limit of the steel strands.

6. The apparatus of claim 1, wherein the delivery mechanism includes a delivery unit movable in parallel along the axial direction of the take-up reel and a cutting unit movable in parallel along the axial direction of the take-up reel, the delivery unit includes a plurality of linkage rollers arranged in a zigzag shape, a passing path for the steel strand to pass through is formed between the linkage rollers, and the cutting unit is capable of cutting off the delivered steel strand in the moving direction.

7. The device for containing and carding the steel strands as claimed in claim 1, further comprising a support frame, wherein the center of the storage coil holder is erected in the support frame through a rotating shaft, and one end of the rotating shaft is connected with a rotary motor.

8. The device for accommodating and carding steel strands as claimed in claim 3, wherein the steel strands locked by the end locking unit are horizontally locked, and the steel strands are uniformly arranged in a straight line after being locked.

9. The device for accommodating and carding steel strands as claimed in claim 8, wherein the feed-out mechanism comprises a pulling unit for pulling the steel strand, two feed-out rollers arranged in parallel for feeding the steel strand, the pulling unit has a horizontal nip, the steel strand is completely accommodated in the nip and clamped after being unlocked, and the pulling unit linearly drags and is conveyed by the feed-out rollers after clamping the steel strand.

10. The device for containing and carding steel strands as claimed in claim 9, wherein the delivery mechanism further comprises a cross bar which is inclined by a lifting telescopic cylinder, the cross bar is located on one side of the pulling unit and below the delivery roller, and the lifting bar lifts and delivers the steel strand to the delivery roller after the pulling unit clamps the steel strand and the steel strand is delivered out by the delivery roller.

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