CN114351485A - Heavy double round traction device is used for wire rope transposition equipment - Google Patents

Abstract

The application discloses a heavy double-wheel traction device for steel wire rope stranding equipment, which relates to the technical field of steel wire rope stranding and comprises a forward traction wheel, an inclined traction wheel and a rotating driver, wherein an axis column of the forward traction wheel is connected with a forward transmission shaft for driving rotation, an axis column of the inclined traction wheel is connected with an inclined transmission shaft for driving rotation, and the forward transmission shaft and the inclined transmission shaft are both connected with the rotating driver; the length meter is arranged on the rotating driver and used for calculating the traction length of the steel wire rope according to the rotating linear speeds of the forward transmission shaft and the inclined transmission shaft; the diameters of the forward traction wheel and the inclined traction wheel are larger than or equal to 4500 mm. This application drives the rotation of drive main shaft and makes forward traction wheel and slope traction wheel rotate through rotating the driver to realize the length measurement to wire rope with hold-in range and length gauge cooperation, reach the purpose that the drive is stable, effectively pull and count major diameter wire rope.

Description

Heavy double round traction device is used for wire rope transposition equipment

Technical Field

The application relates to the technical field of steel wire rope stranding, in particular to a heavy double-wheel traction device applied to steel wire rope stranding equipment.

Background

The tubular stranding machine is a mechanical device widely applied to stranding of cables or steel wire ropes, and enables a plurality of single wires to be twisted into a stranded cable or steel wire rope, so that the technical requirements of wires are met. At present, a commonly used tubular wire twisting machine in China mainly comprises a transmission case, a wire arranging device and a wire twisting device, wherein a single wire on a wire releasing disc is twisted into a multi-strand twisted cable or a steel wire rope through the wire arranging device and the wire twisting device and then is directly taken up.

In order to draw the large-diameter steel wire rope to the tubular stranding machine, the requirement of required traction force cannot be met by adopting conventional double-wheel traction with the diameter within 4000, so that the traction and length measurement of the large-diameter steel wire rope are influenced, and improvement is needed.

Disclosure of Invention

In view of the above, the present application is directed to a heavy-duty double-wheel traction device for a steel wire rope stranding apparatus, so as to achieve the purpose of effectively drawing and counting large-diameter steel wire ropes. The specific scheme is as follows:

a heavy double-wheel traction device is applied to steel wire rope stranding equipment and comprises a forward traction wheel, an inclined traction wheel and a rotating driver, wherein an axis column of the forward traction wheel is connected with a forward transmission shaft for driving rotation, an axis column of the inclined traction wheel is connected with an inclined transmission shaft for driving rotation, and the forward transmission shaft and the inclined transmission shaft are both connected with the rotating driver;

the length meter is used for calculating the traction length of the steel wire rope according to the rotation linear speeds of the forward transmission shaft and the inclined transmission shaft;

the diameters of the forward traction wheel and the inclined traction wheel are larger than or equal to 4500 mm.

Preferably: the output shaft of the rotary driver is provided with a connecting shaft sleeve, the connecting shaft sleeve is fixedly connected with a driving main shaft, the driving main shaft is positioned between the forward traction wheel and the inclined traction wheel, and two ends of the driving main shaft are connected with the forward transmission shaft in matched connection with the forward traction wheel and the inclined transmission shaft in matched connection with the inclined traction wheel correspondingly.

Preferably: a main shaft seat bearing sleeve and a connecting bearing sleeve are respectively arranged at two ends of the driving main shaft, and one end of the corresponding forward transmission shaft and one end of the corresponding inclined transmission shaft are inserted into the main shaft seat bearing sleeve and are connected with the driving main shaft; one end of the corresponding positive transmission shaft and one end of the corresponding inclined transmission shaft are inserted into the connecting bearing sleeve and connected with the driving main shaft.

Preferably: one ends of the two forward transmission shafts, which are far away from the driving main shaft, are respectively provided with a primary bearing sleeve and a secondary bearing sleeve, and the axial center columns of the forward traction wheels are respectively inserted into the corresponding primary bearing sleeve and the corresponding secondary bearing sleeve and are connected with the corresponding forward transmission shafts; and one ends of the two inclined transmission shafts, which are far away from the driving main shaft, are respectively provided with a third-stage bearing sleeve and a fourth-stage bearing sleeve, and the axis columns of the inclined traction wheels are respectively inserted in the corresponding third-stage bearing sleeve and the fourth-stage bearing sleeve and are connected with the corresponding inclined transmission shafts.

Preferably: the length direction of the driving main shaft is parallel to the axis of the axis column of the forward traction wheel, the length direction of the forward transmission shaft is perpendicular to the axis of the axis column of the forward traction wheel, and the length direction of the inclined transmission shaft is perpendicular to the axis of the axis column of the inclined traction wheel.

Preferably: the upper end of one-level bearing housing is provided with the forward lantern ring that is the semicircle form, the forward traction wheel orientation one side of the forward lantern ring is provided with the forward go-between, the forward go-between be provided with the inboard spacing forward contact of the forward lantern ring, the cross-section of forward contact be L form and be provided with the fixed forward fixed connection portion is connected to the forward go-between.

Preferably: the upper end of tertiary bearing housing is provided with the slope lantern ring that is the semicircle form, the slope traction wheel orientation one side of the slope lantern ring is provided with the slope go-between, the slope go-between be provided with the inboard spacing oblique contact body of contact of the slope lantern ring, the cross-section of oblique contact body be the L form and be provided with the slope go-between is connected fixed slope fixed connection portion.

Preferably: one end, far away from the rotation driving body, of the driving main shaft is provided with a synchronous belt, and the synchronous belt is connected with the length gauge.

Preferably: an included angle which is larger than 0 degree and smaller than or equal to 30 degrees is formed between the axis of the axis column of the inclined traction wheel and the horizontal plane.

Preferably: the device is characterized by also comprising a foundation pit body, wherein an installation pit is arranged in the foundation pit body, and the forward traction wheel and the inclined traction wheel are both arranged in the installation pit; the device is characterized in that a walking ladder is arranged in the mounting pit, a tensioning device is arranged on the foundation pit body, and the tensioning device is connected with the inclined traction wheel in a matched mode.

According to the scheme, the application provides a heavy double-wheel traction device for steel wire rope stranding equipment, and the heavy double-wheel traction device for the steel wire rope stranding equipment has the following beneficial effects:

1. the synchronous belt is in transmission connection with the driving main shaft, so that the traction length of the steel wire rope is effectively calculated when the rotation linear speed of the driving main shaft is collected;

2. the effect of further reducing the use difficulty of the length meter is realized by matching with the foundation pit body to install the forward traction wheel and the inclined traction wheel, so that the effect of effectively calculating the length is achieved;

3. the forward traction wheel and the inclined traction wheel with the diameter of 4500mm are adopted to carry out traction on the large-diameter steel wire rope with the diameter of more than or equal to 200mm, and the effect of 60 tons of traction force is achieved;

4. the effective traction of the large-diameter steel wire rope is realized through the traction of the forward traction wheel and the repeated traction of the inclined traction wheel;

5. the transmission driver drives the driving main shaft to rotate, so that the driving main shaft is matched with the synchronous belt and the length gauge to realize the length measurement of the steel wire rope when the driving main shaft effectively drives the forward transmission shaft and the inclined transmission shaft to respectively drive the forward traction wheel and the inclined traction wheel to rotate, and the purposes of driving stably, effectively drawing and counting large-diameter steel wire ropes are achieved.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, it is obvious that the drawings in the following description are only embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

FIG. 1 is a schematic structural view of a schematic structural view disclosed herein;

FIG. 2 is a schematic structural view of a mounting structure of the present disclosure;

FIG. 3 is an enlarged schematic view of portion A of FIG. 2;

FIG. 4 is an enlarged schematic view of portion B of FIG. 2;

fig. 5 is an enlarged schematic view of a portion C in fig. 2.

Description of reference numerals: 1. a forward traction wheel; 11. a first-stage bearing sleeve; 12. a secondary bearing sleeve; 13. a forward collar; 14. a positive contact; 141. a forward fixing portion; 15. a forward connecting ring; 2. inclining the traction wheel; 21. a third-stage bearing sleeve; 22. a four-stage bearing sleeve; 23. an inclined collar; 24. a sloping contact body; 241. an inclined fixed connection part; 25. inclining the connecting ring; 3. driving the main shaft; 4. a length gauge; 41. a synchronous belt; 5. a rotation driver; 51. connecting the shaft sleeve; 52. a main shaft seat bearing sleeve; 521. a forward drive shaft; 53. connecting a bearing sleeve; 531. inclining the transmission shaft; 6. a tensioning device; 7. a foundation pit body; 71. installing a pit; 72. a walking ladder.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, 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 application.

As shown in fig. 1, a heavy type double-wheel traction device is applied to a wire rope stranding apparatus, and includes a forward traction wheel 1, a tilting traction wheel 2, and a rotation driver 5. The axial center column of the forward traction wheel 1 is connected with a forward transmission shaft 521 for driving rotation, the axial center column of the inclined traction wheel 2 is connected with an inclined transmission shaft 531 for driving rotation, and the forward transmission shaft 521 and the inclined transmission shaft 531 are both connected with the rotation driver 5. Therefore, when the rotation driver 5 operates, the forward transmission shaft 521 and the inclined transmission shaft 531 are directly driven to operate simultaneously, and then the forward transmission shaft 521 drives the connected forward traction wheel 1 to rotate and the inclined transmission shaft 531 drives the connected inclined traction wheel 2 to rotate.

Wherein, the rotation driver 5 is provided with a length meter 4, and the length meter 4 calculates the wire rope traction length according to the rotation linear speed of the forward transmission shaft 521 and the inclined transmission shaft 531. Because the rotating linear speed of the rotating driver 5 is in a fixed proportion to the forward traction wheel 1 and the inclined traction wheel 2, the traction length of the steel wire rope can be effectively measured when the corresponding rotating linear speed of the driving driver is obtained. In addition, in order to effectively pull a large-diameter wire rope having a diameter of more than 200m, the diameters of the forward traction sheave 1 and the inclined traction sheave 2 are both 4500mm or more. And the forward traction wheel 1 and the inclined traction wheel 2 are formed by welding steel plates, and wheel grooves subjected to quenching treatment are formed on the peripheral surfaces of the forward traction wheel and the inclined traction wheel, so that the wheel grooves are matched with the steel wire rope, and the steel wire rope is stably pulled.

As shown in fig. 1 and 2, a timing belt 41 is provided at one end of the drive spindle 3 remote from the rotary drive body. The synchronous belt 41 is connected with the length gauge 4, so that the synchronous belt 41 can effectively draw and measure the rotation linear velocity, and the measurement of the drawing length of the steel wire rope is realized. In order to realize effective traction of the steel wire rope, an included angle which is larger than 0 degree and smaller than or equal to 30 degrees is formed between the axis of the axis column of the inclined traction wheel 2 and the horizontal plane. Meanwhile, in order to reduce the use difficulty of the heavy double-wheel traction device on steel wire rope stranding equipment, a foundation pit body 7 is further arranged. An installation pit 71 is arranged in the foundation pit body 7, and the forward traction wheel 1 and the inclined traction wheel 2 are both arranged in the installation pit 71. Wherein, a walking ladder 72 is arranged in the mounting pit 71, and a tensioning device 6 is arranged on the foundation pit body 7. The tensioning device 6 is connected with the inclined traction wheel 2 in a matching way.

As shown in fig. 1, 3 and 4, the output shaft of the rotary actuator 5 is provided with a coupling boss 51. The connecting sleeve 51 is fixedly connected with the drive spindle 3. The driving main shaft 3 is positioned between the forward traction wheel 1 and the inclined traction wheel 2, and both ends of the driving main shaft are connected with a forward transmission shaft 521 which is correspondingly matched and connected with the forward traction wheel 1 and an inclined transmission shaft 531 which is correspondingly matched and connected with the inclined traction wheel 2.

It should be mentioned that a spindle base bearing bush 52 and a connecting bearing bush 53 are respectively provided at both ends of the drive spindle 3. One end of the corresponding positive transmission shaft 521 and one end of the corresponding inclined transmission shaft 531 are inserted into the main shaft base bearing sleeve 52 and connected with the driving main shaft 3; one end of the corresponding forward transmission shaft 521 and the inclined transmission shaft 531 is inserted into the connecting bearing housing 53 and connected to the drive spindle 3. Meanwhile, the length direction of the driving spindle 3 is parallel to the axis of the axis column of the forward traction wheel 1, the length direction of the forward transmission shaft 521 is perpendicular to the axis of the axis column of the forward traction wheel 1, and the length direction of the inclined transmission shaft 531 is perpendicular to the axis of the axis column of the inclined traction wheel 2, so that the driving spindle 3 is driven to rotate when the rotary driver 5 operates, and the driving spindle 3 effectively drives the rotation of the forward transmission shaft 521 and the forward traction wheel 1 and the rotation of the inclined transmission shaft 531 and the inclined traction wheel 2.

As shown in fig. 1, 3 and 5, one ends of the two forward transmission shafts 521, which are far away from the driving spindle 3, are respectively provided with a primary bearing bush 11 and a secondary bearing bush 12. The axial center column of the forward traction wheel 1 is respectively inserted into the corresponding primary bearing sleeve 11 and the corresponding secondary bearing sleeve 12 and is connected with the corresponding forward transmission shaft 521. Wherein, the upper end of the first-stage bearing sleeve 11 is provided with a semicircular forward lantern ring 13. The side of the forward traction wheel 1 facing the forward collar 13 is provided with a forward coupling ring 15. The forward connecting ring 15 is provided with a forward contact body 14 which is in contact with the inner side of the forward collar 13 for limiting, and the cross section of the forward contact body 14 is L-shaped and is provided with a forward fixing part 141 which is fixedly connected with the forward connecting ring 15.

As shown in fig. 1, 4 and 5, one ends of the two inclined transmission shafts 531 away from the driving spindle 3 are respectively provided with a third-stage bearing bush 21 and a fourth-stage bearing bush 22. The axial center columns of the inclined traction wheels 2 are respectively inserted into the corresponding third-stage bearing sleeve 21 and the fourth-stage bearing sleeve 22 and connected with the corresponding inclined transmission shafts 531. Wherein, the upper end of the third-stage bearing sleeve 21 is provided with a semicircular inclined lantern ring 23. The side of the tilting traction wheel 2 facing the tilting collar 23 is provided with a tilting attachment ring 25. The tilt coupling ring 25 is provided with a tilt contact body 24 that is in contact with the inner side of the tilt collar 23 to be restrained, and the tilt contact body 24 has an L-shaped cross section and is provided with a tilt fixing portion 241 that is connected and fixed to the tilt coupling ring 25.

It should be noted that the inclined collar 23 and the inclined contact body 24 are matched to the inclined traction wheel 2 and both form a matched angle with the horizontal plane, so as to achieve the effect of significantly improving the stability of the inclined traction wheel 2.

In summary, the present application provides a heavy-duty double-wheel traction device for a steel wire rope stranding apparatus, which is used for the transmission connection of the steel wire rope stranding apparatus with a driving main shaft 3 through a synchronous belt 41, so as to effectively calculate the steel wire rope traction length when acquiring the rotation linear speed of the driving main shaft 3; and the forward traction wheel 1 and the inclined traction wheel 2 are arranged by matching with the foundation pit body 7, so that the effect of further reducing the use difficulty of the length meter 4 is realized, and the effect of effectively calculating the length is achieved. Meanwhile, the forward traction wheel 1 and the inclined traction wheel 2 with the diameters of 4500mm are adopted to pull the large-diameter steel wire rope with the diameters larger than or equal to 200mm, the effect of 60-ton traction force is achieved, and then the forward traction wheel 1 and the inclined traction wheel 2 are pulled again, so that the large-diameter steel wire rope is effectively pulled. Therefore, this application drives the rotation of drive spindle 3 through the transmission driver for drive spindle 3 when effective drive forward transmission shaft 521 and inclined transmission shaft 531 rotate with driving forward traction wheel 1 and inclined traction wheel 2 respectively, realize the length measurement to wire rope with hold-in range 41 and length counter 4 cooperation, reach the purpose that the drive is stable, effectively pull and count major diameter wire rope.

References in this application to "first," "second," "third," "fourth," etc., if any, are intended to distinguish between similar elements and not necessarily to describe a particular order or sequence. It will be appreciated that the data so used may be interchanged under appropriate circumstances such that the embodiments described herein may be practiced otherwise than as specifically illustrated or described herein. Furthermore, the terms "comprises" and "comprising," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, or apparatus.

It should be noted that the descriptions in this application referring to "first", "second", etc. are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present application.

The principle and the implementation of the present application are explained herein by applying specific examples, and the above description of the embodiments is only used to help understand the method and the core idea of the present application; meanwhile, for a person skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (10)

1. The utility model provides a heavy double round pulls device uses in wire rope transposition equipment which characterized in that: the device comprises a forward traction wheel (1), an inclined traction wheel (2) and a rotary driver (5), wherein an axis post of the forward traction wheel (1) is connected with a forward transmission shaft (521) for driving rotation, an axis post of the inclined traction wheel (2) is connected with an inclined transmission shaft (531) for driving rotation, and the forward transmission shaft (521) and the inclined transmission shaft (531) are both connected with the rotary driver (5);

the length meter (4) is arranged on the rotating driver (5), and the length meter (4) calculates the traction length of the steel wire rope according to the rotating linear speeds of the forward transmission shaft (521) and the inclined transmission shaft (531);

the diameters of the forward traction wheel (1) and the inclined traction wheel (2) are larger than or equal to 4500 mm.

2. The heavy duty double-wheel traction device as claimed in claim 1, wherein the heavy duty double-wheel traction device is used in a steel wire rope stranding apparatus, and the heavy duty double-wheel traction device is characterized in that: the output shaft of rotation driver (5) is provided with coupling sleeve (51), coupling sleeve (51) fixedly connected with drive spindle (3), drive spindle (3) are located forward traction wheel (1) with between slope traction wheel (2), and both ends all with corresponding forward transmission shaft (521) of forward traction wheel (1) accordant connection and with corresponding slope traction wheel (2) accordant connection slope transmission shaft (531) are connected.

3. The heavy duty double-wheel traction device as claimed in claim 2, wherein the heavy duty double-wheel traction device is used in a steel wire rope stranding apparatus, and the heavy duty double-wheel traction device is characterized in that: a main shaft seat bearing sleeve (52) and a connecting bearing sleeve (53) are respectively arranged at two ends of the driving main shaft (3), and one end of the corresponding forward transmission shaft (521) and one end of the corresponding inclined transmission shaft (531) are inserted into the main shaft seat bearing sleeve (52) and connected with the driving main shaft (3); one end of the corresponding positive transmission shaft (521) and one end of the corresponding inclined transmission shaft (531) are inserted into the connecting bearing sleeve (53) and connected with the driving main shaft (3).

4. The heavy duty double wheel traction device as claimed in claim 3, wherein the heavy duty double wheel traction device is used in a steel wire rope stranding apparatus, and the heavy duty double wheel traction device is characterized in that: one ends, far away from the driving main shaft (3), of the two forward transmission shafts (521) are respectively provided with a primary bearing sleeve (11) and a secondary bearing sleeve (12), and the axis columns of the forward traction wheels (1) are respectively inserted into the corresponding primary bearing sleeve (11) and the corresponding secondary bearing sleeve (12) and connected with the corresponding forward transmission shaft (521); and one ends of the two inclined transmission shafts (531), which are far away from the driving main shaft (3), are respectively provided with a third-stage bearing sleeve (21) and a fourth-stage bearing sleeve (22), and the axis columns of the inclined traction wheels (2) are respectively inserted into the corresponding third-stage bearing sleeve (21) and the fourth-stage bearing sleeve (22) and are connected with the corresponding inclined transmission shafts (531).

5. The heavy duty double wheel traction device as claimed in claim 4, wherein the heavy duty double wheel traction device is used in a steel wire rope stranding apparatus, and the heavy duty double wheel traction device is characterized in that: the length direction of the driving spindle (3) is parallel to the axis of the axis column of the forward traction wheel (1), the length direction of the forward transmission shaft (521) is perpendicular to the axis of the axis column of the forward traction wheel (1), and the length direction of the inclined transmission shaft (531) is perpendicular to the axis of the axis column of the inclined traction wheel (2).

6. The heavy duty double wheel traction device as claimed in claim 4, wherein the heavy duty double wheel traction device is used in a steel wire rope stranding apparatus, and the heavy duty double wheel traction device is characterized in that: the upper end of one-level bearing housing (11) is provided with forward lantern ring (13) that is the semicircle form, forward traction wheel (1) orientation one side of forward lantern ring (13) is provided with forward go-between (15), forward go-between (15) be provided with the inboard spacing forward contact (14) of contact of forward lantern ring (13), the cross-section of forward contact (14) be L form and be provided with fixed forward fixed connection portion (141) are connected to forward go-between (15).

7. The heavy duty double wheel traction device as claimed in claim 4, wherein the heavy duty double wheel traction device is used in a steel wire rope stranding apparatus, and the heavy duty double wheel traction device is characterized in that: the upper end of tertiary bearing housing (21) is provided with the slope lantern ring (23) that is the semicircle form, slope traction wheel (2) orientation one side of the slope lantern ring (23) is provided with slope go-between (25), slope go-between (25) be provided with the inboard spacing oblique contact body (24) of the contact of the slope lantern ring (23), the cross-section of oblique contact body (24) be L form and be provided with fixed slope fixed connection portion (241) are connected to slope go-between (25).

8. The heavy duty double-wheel traction device as claimed in claim 2, wherein the heavy duty double-wheel traction device is used in a steel wire rope stranding apparatus, and the heavy duty double-wheel traction device is characterized in that: one end, far away from the rotary driving body, of the driving main shaft (3) is provided with a synchronous belt (41), and the synchronous belt (41) is connected with the length meter (4).

9. The heavy duty double-wheel traction device as claimed in claim 1, wherein the heavy duty double-wheel traction device is used in a steel wire rope stranding apparatus, and the heavy duty double-wheel traction device is characterized in that: an included angle which is larger than 0 degree and smaller than or equal to 30 degrees is formed between the axis of the axis column of the inclined traction wheel (2) and the horizontal plane.

10. The heavy duty double-wheel traction device as claimed in claim 1, wherein the heavy duty double-wheel traction device is used in a steel wire rope stranding apparatus, and the heavy duty double-wheel traction device is characterized in that: the traction mechanism is characterized by further comprising a foundation pit body (7), wherein an installation pit (71) is arranged in the foundation pit body (7), and the forward traction wheel (1) and the inclined traction wheel (2) are both arranged in the installation pit (71); a walking ladder (72) is arranged in the mounting pit (71), a tensioning device (6) is arranged on the foundation pit body (7), and the tensioning device (6) is connected with the inclined traction wheel (2) in a matched mode.

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