CN111498588A

CN111498588A - Automatic winding table for cable storage and transportation

Info

Publication number: CN111498588A
Application number: CN202010317576.6A
Authority: CN
Inventors: 冯显安; 周光玉; 吴红伟; 翟斌
Original assignee: Anhui Huajin Cable Group Co ltd
Current assignee: Anhui Huajin Cable Group Co ltd
Priority date: 2020-04-21
Filing date: 2020-04-21
Publication date: 2020-08-07
Anticipated expiration: 2040-04-21
Also published as: CN111498588B

Abstract

The invention relates to an automatic winding table for cable storage and transportation, which comprises a table body, wherein winding drums are symmetrically distributed on the table body in the left-right direction; and cable body guide members are arranged between the bobbins distributed on the left and right sides, rotate in situ to guide the bobbins distributed on the left and right sides alternately, and driving members are arranged at the bottom of the table body. Compared with the prior art, the cable winding device has the advantages that the two winding drums, the cable head clamping piece rotating in situ, the driving component, the power on-off mechanism and the rotating motor are arranged, so that cables are wound on the winding drums in order, and the phenomena of mutual winding and connection correction are avoided; and the two bobbins are wound alternately under the condition of no shutdown as much as possible through one driving source, so that the winding efficiency is improved, and the energy consumption is reduced.

Description

Automatic winding table for cable storage and transportation

Technical Field

The invention relates to the technical field of cable production and processing, in particular to an automatic winding table for cable storage and transportation.

Background

A cable is a conductor made up of one or more conductors insulated from each other and an outer insulating jacket, which carries power or information from one location to another.

After the cable is produced and processed, the cable needs to be wound on a wire spool for storage and transportation. The existing manual winding and mechanical winding modes are mainly adopted, wherein the manual winding is low in efficiency, the labor intensity is high, the mechanical winding is inconvenient to operate, manual auxiliary operation is needed, the winding process is easy to realize mutual winding and link correction, in addition, only one winding drum works on a common winding machine, the winding efficiency is low, and the winding time is long.

Disclosure of Invention

In order to solve the technical problem, the invention provides an automatic winding table for cable storage and transportation.

The technical problem to be solved by the invention is realized by adopting the following technical scheme:

an automatic winding table for cable storage and transportation comprises a table body, wherein bobbins which rotate around respective central axes and alternately wind are symmetrically distributed on the table body from left to right;

and a cable body guide member used for lifting the cable by a diameter height every time the winding drums rotate for a circle so as to enable the cable to be orderly wound on the winding drums is arranged between the winding drums distributed on the left and the right, the cable body guide member rotates in situ so as to alternately guide the winding drums distributed on the left and the right, and a driving member for driving the winding drums to rotate and the cable body guide member to intermittently lift the lead is arranged at the bottom of the table body.

Furthermore, a rotating seat for driving the winding reel to rotate is arranged in the table body, and the rotating seat is coaxially connected with the driving component.

Furthermore, cable head clamping pieces are arranged on the winding drums distributed on the left and right sides and comprise cable head clamping plates and clamping grooves, the cable head clamping plates are used for clamping and fixing the cable heads on the side walls of the winding drums, the clamping grooves are formed in the side edges of the bottoms of the winding drums, and the cable head clamping plates are installed in the clamping grooves through adjusting clamping rods.

Furthermore, the cable body guiding member comprises a lifting screw rod and a guide rod which are arranged on the table body through a rotating plate, and a bent cable body lifting plate which is arranged on the lifting screw rod and the guide rod and has an adjustable horizontal position, and the lifting screw rod is connected with the driving member.

Furthermore, a rotating motor which is connected with the rotating plate and is coaxial with the guide rod is arranged at the bottom of the table body.

Furthermore, the end part of the bent cable body lifting plate is provided with an adjusting screw, and the bent cable body lifting plate is arranged on the lifting screw rod and the guide rod through a lifting plate matched with the adjusting screw.

Further, the driving member includes a rotating motor, a first driving assembly connecting the rotating motor with the bobbins distributed left and right, and a second driving assembly connecting the rotating motor with the cable body guide member.

Furthermore, the first driving assembly comprises two first belt wheels correspondingly connected with the winding drums distributed on the left and right sides and a first driving belt connecting the two first belt wheels, any one of the two first belt wheels is connected with the rotating motor, and a power dividing and combining mechanism is arranged between each first belt wheel and the corresponding winding drum.

Furthermore, the power on-off mechanism comprises a friction rotating disc coaxially connected with the first belt pulley, a transmission sleeve coaxially connected with the winding drum, and a transmission shaft which is slidably arranged in the transmission sleeve and is circumferentially limited and clamped with the transmission sleeve, a friction abutting plate in friction fit with the friction rotating disc is arranged at the end part of the transmission shaft, and an on-off screw rod which drives the transmission shaft to slide along the transmission sleeve so as to enable the friction abutting plate to be in on-off connection with the friction rotating disc is arranged on the side edge of the bearing sleeve.

Furthermore, the second driving assembly comprises an intermittent gear coaxially connected with the rotating motor, a transmission gear intermittently meshed with the intermittent gear, two second belt wheels coaxially connected with the transmission gear and the lifting screw rod, and a tension wheel arranged at the bottom of the table body in a sliding manner, wherein the two second belt wheels and the tension wheel are connected through a second driving belt.

The invention has the beneficial effects that:

compared with the prior art, the cable winding device has the advantages that the two winding drums, the cable head clamping piece rotating in situ, the driving component, the power on-off mechanism and the rotating motor are arranged, so that cables are wound on the winding drums in order, and the phenomena of mutual winding and connection correction are avoided; and the two bobbins are wound alternately under the condition of no shutdown as much as possible through one driving source, so that the winding efficiency is improved, and the energy consumption is reduced.

Drawings

The invention is further illustrated with reference to the following figures and examples:

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic sectional view A-A of FIG. 1;

FIG. 3 is a schematic sectional view of the structure of B-B in FIG. 1;

fig. 4 is a schematic top view of the present invention.

Detailed Description

In order to make the technical means, the creation features, the achievement purposes and the effects of the invention easy to understand, the invention is further explained in the following with the accompanying drawings and the embodiments.

As shown in fig. 1 to 4, an automatic winding table for cable storage and transportation comprises a table body 1, wherein bobbins 2 which rotate around respective central axes and alternately wind are symmetrically distributed on the table body 1 from left to right;

and a cable body guide member used for lifting the cable by a diameter height every time the winding reel 2 rotates for a circle so as to enable the cable to be wound on the winding reel 2 neatly is arranged between the winding reels 2 distributed on the left and right, the cable body guide member is driven to rotate in situ so as to guide the winding reels 2 distributed on the left and right alternately, and a driving member used for driving the winding reel 2 to rotate and intermittently lifting the lead wire by the cable body guide member is arranged at the bottom of the table body 1.

As a further improvement of the invention, two bobbins 2 are symmetrically distributed on the left and right sides, two rotating seats 3 matched with the two bobbins 2 are arranged inside the left and right sides of the table body 1, and after the bobbins 2 are placed in the rotating seats 3, the bobbins can synchronously rotate along with the rotating seats 3, so that the winding work is realized. Both rotary seats 3 are coaxially connected with the drive member.

The cable body guide member is distributed in the middle of the two bobbins 2, and is initially matched with any one of the bobbins 2, and after the current bobbin 2 is wound, the cable body guide member rotates 180 degrees in situ and is matched with the other bobbin 2, so that the two bobbins 2 which are symmetrically distributed at left and right can be wound alternately, and the winding efficiency is improved.

Through the cable body guide member rotating 180 degrees in situ, the two bobbins 2 are wound alternately, and compared with the conventional single bobbin winding, the winding efficiency is greatly improved.

As a further improvement of the invention, cable head clamping pieces are arranged on the bobbins 2 which are distributed on the left and the right, the cable head clamping pieces comprise cable head clamping plates 4 used for clamping and fixing cable heads on the side walls of the bobbins 2 and clamping grooves 6 arranged at the side edges of the bottoms of the bobbins 2, and the cable head clamping plates 4 are installed in the clamping grooves 6 through adjusting clamping rods 5.

The upper end of the cable head clamping plate 4 is provided with an inward bent arc state for better clamping and fixing the cable body. The adjusting clamping rod 5 is a threaded rod, the clamping groove 6 is a threaded groove, and the clamping of the cable head is realized by the screwing and matching of threads between the adjusting clamping rod 5 and the clamping groove 6.

As a further improvement of the present invention, the cable body guiding member comprises a lifting screw 7 and a guide rod 8 which are arranged on the table body 1 through a rotating plate 71, and a bent cable body lifting plate 9 which is arranged on the lifting screw 7 and the guide rod 8 and has an adjustable horizontal position, the bottom of the table body 1 is provided with a rotating motor 10 which is coaxial with the rotating plate 71 and the guide rod 8, and the lower end of the lifting screw 7 extends to the bottom of the table body 1 and is connected with the driving member. The table body 1 is provided with a semicircular guide groove 72 taking the axis of the guide rod 8 as the center of a circle, and when the rotary motor 10 drives the rotary plate 71 to rotate, the semicircular guide groove 72 provides guidance for the lifting screw rod 7.

The lifting screw rod 7 is driven to rotate intermittently by the driving component, so that the bent cable body lifting plate 9 is lifted intermittently, and the intermittent time of lifting the bent cable body lifting plate 9 each time is exactly the time for winding a circle on the winding drum 2. By means of the arrangement, after the winding action of the winding drum 2 is combined with the intermittent lifting action of the bent cable body lifting plate 9, the cable is wound according to the winding motion in the spiral direction.

As a further improvement of the invention, an adjusting screw 91 is arranged at the end of the bent cable body lifting plate 9, a lifting plate 92 is arranged on the lifting screw rod 7 and the guide rod 8, and the adjusting screw 91 is horizontally arranged on the lifting plate 92.

The adjusting screw 91 is used for changing the horizontal position of the bent cable body lifting plate 9, so that the distance between the bent cable body lifting plate 9 and the side wall of the winding drum 2 is changed. Thereby enabling the bobbin 2 to be wound in multiple layers.

As a further improvement of the present invention, the driving means includes a rotary motor 11, a first driving assembly connecting the rotary motor 11 with the bobbins 2 distributed left and right, and a second driving assembly connecting the rotary motor 11 with the cable body guide means. The rotating motor 11 is fixed at the right side of the bottom of the table body 1 through a mounting frame 111, and the first driving assembly is connected with the rotating seats 3 corresponding to the bobbins 2 distributed at the left and right.

The winding action of the winding reel 2 and the intermittent lifting action of the cable body guide member are realized by one driving source, so that the structure of the invention is more compact, and the working efficiency is improved.

As a further improvement of the present invention, the first driving assembly includes two first pulleys 12 correspondingly connected to the rotary base 3, and a first driving belt 13 connecting the two first pulleys 12, the right first pulley 12 of the two first pulleys 12 is connected to the rotary motor 11, and a power dividing and combining mechanism is provided between each first pulley 12 and the correspondingly connected rotary base 3.

As a further improvement of the invention, the power dividing and combining mechanism comprises a friction turntable 19 coaxially connected with the first pulley 12, a transmission sleeve 20 coaxially connected with the bobbin 2, and a transmission shaft 21 slidably mounted in the transmission sleeve 20 and circumferentially and limitedly clamped with the transmission sleeve, a clamping groove is arranged in the transmission sleeve 20, a clamping strip is arranged on the transmission shaft 21, the transmission shaft 21 and the transmission sleeve 20 can synchronously and axially rotate through the matching of the clamping groove and the clamping strip, the transmission shaft 21 can axially slide along the transmission sleeve 20, a friction resisting plate 22 in friction fit with the friction turntable 19 is arranged at the end of the transmission shaft 21, the transmission shaft 21 can synchronously rotate along with the friction turntable 19 through the friction transmission between the friction resisting plate 22 and the friction turntable 19, a dividing and combining screw 23 for driving the transmission shaft 21 to slide along the transmission sleeve 20 so as to enable the friction resisting plate 22 to be combined with the friction turntable 19 is arranged at the side edge of the transmission shaft 21, the split-combination screw 23 is connected with the transmission shaft 21 through a connecting rod 211 with one end provided with a bearing sleeve. The switching screw 23 in the left power switching mechanism is positioned on the left side of the transmission shaft 21, and the switching screw 23 in the right power switching mechanism is positioned on the right side of the transmission shaft 21.

The rotation of the opening and closing screw 23 enables the transmission shaft 21 to slide up and down, thereby opening and closing the friction resisting plate 22 and the friction turntable 19.

Through power deciliter mechanism for 2 of the bobbin that distribute about rotate with stop between switch wantonly, hot-blast first drive assembly, power deciliter mechanism for a driving source is under the circumstances of not shutting down as far as, order about 2 of the bobbin that distribute in turn wire winding in turn about ordering, have not only improved wire winding efficiency, have reduceed energy consumption moreover.

The power on-off mechanism in the invention has a similar principle with the clutch, but the difference is that in order to adapt to the use of the invention, the power on-off mechanism in the invention has self-locking performance through the arranged on-off screw 23, after the friction resisting plate 22 is separated from the friction turntable 19, the drive to the transmission shaft 21 is removed, and the friction resisting plate 22 cannot reset and the friction turntable 19 is engaged with the friction for synchronous rotation again.

Through the arrangement, after the bobbin 2 is switched between rotation and stop, driving acting force does not need to be continuously applied, and the use is convenient.

As a further improvement of the invention, the second driving component comprises an intermittent gear 14 coaxially connected with the rotating motor 11, a transmission gear 15 intermittently meshed with the intermittent gear 14, two second belt wheels 16 coaxially connected with the transmission gear 15 and the lifting screw rod 7, and a tension pulley 17 slidably mounted at the bottom of the table body 1, wherein the two second belt wheels 16 and the tension pulley 17 are connected through a second driving belt 18. A tension spring 151 is also arranged in the sliding groove of the tension wheel 15. The tension pulley 15 is used for ensuring that the second driving belt 18 is always in a tight state before and after the second belt pulley 16 which is coaxially connected with the lifting screw rod 7 rotates by 180 degrees.

The intermittent gear 12 is an eighth toothed gear, that is, the central angle of the toothed part of the intermittent gear 12 is 45 °.

The use process comprises the following steps:

when in use, the two empty bobbins 2 are correspondingly placed on the two rotating seats 3 on the table body 1; initially, the friction turntable 19 and the friction resisting plate 22 in the two power on-off mechanisms are both in a closed state, and initially, the bent cable body lifting plate 9 in the cable body guide member corresponds to the right winding reel 2, and at this time, the friction turntable 19 and the friction resisting plate 22 in the left power on-off mechanism are separated.

Then, the cable head is fixed on the right winding drum 2 through the cable head clamping piece, then, the rotating motor 11 is started, the right winding drum 2 performs winding work, when the winding drum 2 winds a circle, the bent cable body lifting plate 9 is lifted upwards by a cable diameter height through the driving assembly, and when the winding drum 2 winds a layer, the bent cable body lifting plate 9 is adjusted to move to the left side by an interval of the cable diameter so as to perform winding work of a second layer.

After the winding of the winding reel 2 on the right side is finished, the rotating motor 10 is started to enable the cable body guide member to rotate 180 degrees around the axis of the guide rod 8, so that the bent cable body lifting plate 9 in the cable body guide member corresponds to the winding reel 2 on the left side, the friction turntable 19 and the friction resisting plate 22 in the left power on-off mechanism are closed, and the friction turntable 19 and the friction resisting plate 22 in the right power on-off mechanism are separated.

Then, before the cable head is fixed on the left winding drum 2, the motor 11 is rotated reversely, so that the bent cable body lifting plate 9 on the lifting screw rod 7 is reset, and after the bent cable body lifting plate 9 is reset to the initial position, the cable head is fixed on the left winding drum 2.

And then, repeating the winding process of the winding bobbin 2 on the right, and in the winding process of the winding bobbin 2 on the left, detaching the winding bobbin 2 with the winding completed on the right and replacing with a new winding bobbin 2.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides an automatic wire winding platform of cable storage transportation usefulness which characterized in that: comprises a table body (1), wherein bobbins (2) which rotate around respective central axes and alternately wind are symmetrically distributed on the table body (1) from left to right;

a cable body guide member used for lifting the cable by a diameter height every time the winding reel (2) rotates for a circle so as to enable the cable to be wound on the winding reel (2) in order is arranged between the winding reels (2) distributed on the left and right, the cable body guide member rotates in situ so as to guide the winding reels (2) distributed on the left and right in an alternating mode, and a driving member driving the winding reel (2) to rotate and intermittently lift the lead wire by the cable body guide member is arranged at the bottom of the table body (1).

2. The automatic winding station for cable storage and transportation according to claim 1, wherein: the table body (1) is internally provided with a rotating seat (3) for driving the winding reel (2) to rotate, and the rotating seat (3) is coaxially connected with the driving component.

3. The automatic winding station for cable storage and transportation according to claim 1, wherein: all be equipped with the cable head folder on controlling distributed bobbin (2), the cable head folder is including being used for the cable head to press from both sides tight cable head splint (4) of fixing on bobbin (2) lateral wall, set up and press from both sides tight groove (6) in bobbin (2) bottom side department, cable head splint (4) are installed in pressing from both sides tight groove (6) through adjusting clamping rod (5).

4. The automatic winding station for cable storage and transportation according to claim 1, wherein: the cable body guiding component comprises a lifting screw rod (7) and a guide rod (8) which are arranged on the table body (1) through a rotating plate (71), and a bent cable body lifting plate (9) which is arranged on the lifting screw rod (7) and the guide rod (8) and has an adjustable horizontal position, wherein the lifting screw rod (7) is connected with a driving component.

5. The automatic winding station for cable storage and transportation according to claim 4, wherein: the bottom of the table body (1) is provided with a rotary motor (10) which is connected with the rotary plate (71) and is coaxial with the guide rod (8).

6. The automatic winding station for cable storage and transportation according to claim 4, wherein: the end part of the bent cable body lifting plate (9) is provided with an adjusting screw rod (91), and the bent cable body lifting plate (9) is arranged on the lifting screw rod (7) and the guide rod (8) through a lifting plate (92) matched with the adjusting screw rod (91).

7. The automatic winding station for cable storage and transportation according to claim 1, wherein: the driving component comprises a rotating motor (11), a first driving component for connecting the rotating motor (11) with the winding drums (2) distributed at the left and right, and a second driving component for connecting the rotating motor (11) with the cable body guiding component.

8. The automatic winding station for cable storage and transportation according to claim 7, wherein: the first driving assembly comprises two first belt wheels (12) correspondingly connected with the winding drums (2) distributed on the left and right sides and a first driving belt (13) connecting the two first belt wheels (12), any one of the two first belt wheels (13) is connected with the rotating motor (11), and a power dividing and combining mechanism is arranged between each first belt wheel (12) and the corresponding winding drum (2).

9. The automatic winding station for cable storage and transportation according to claim 8, wherein: the power dividing and combining mechanism comprises a friction turntable (19) coaxially connected with the first belt pulley (12), a transmission sleeve (20) coaxially connected with the winding drum (2), and a transmission shaft (21) which is slidably arranged in the transmission sleeve (20) and is clamped with the transmission sleeve in a circumferential limiting manner, wherein a friction abutting plate (22) in friction fit with the friction turntable (19) is arranged at the end part of the transmission shaft (21), and a dividing and combining screw (23) which is connected with the transmission shaft (21) through a bearing sleeve and drives the transmission sleeve (20) to slide so that the friction abutting plate (22) and the friction turntable (19) are divided and combined is driven to be combined and combined.

10. The automatic winding station for cable storage and transportation according to claim 7, wherein: the second driving assembly comprises an intermittent gear (14) coaxially connected with the rotating motor (11), a transmission gear (15) intermittently meshed with the intermittent gear (14), two second belt wheels (16) coaxially connected with the transmission gear (15) and the lifting screw rod (7), and a tension wheel (17) arranged at the bottom of the table body (1) in a sliding mode, wherein the two second belt wheels (16) and the tension wheel (17) are connected through a second driving belt (18).