CN110014235B

CN110014235B - Roller feeding frame with guide mechanism and pipe cutting machine using same

Info

Publication number: CN110014235B
Application number: CN201910319186.XA
Authority: CN
Inventors: 黄建滨
Original assignee: Guangdong Chittak Intelligent Equipment Co ltd
Current assignee: Guangdong Chittak Intelligent Equipment Co ltd
Priority date: 2019-04-19
Filing date: 2019-04-19
Publication date: 2024-05-31
Anticipated expiration: 2039-04-19
Also published as: CN110014235A

Abstract

Roller feeding frame with guiding mechanism and pipe cutting machine. The roller feeding frame with the guide mechanism comprises a supporting frame and a roller group rotatably arranged on the supporting frame, wherein the roller group comprises left row rollers and right row rollers which are arranged left and right, and a material space capable of allowing materials to pass through is arranged between the left row rollers and the right row rollers; the device is characterized in that the support frame comprises a left support frame and a right support frame which are arranged left and right separately, left row rollers in the roller group are respectively and rotatably arranged on the left support frame, and right row rollers are respectively and rotatably arranged on the right support frame; the guide rail is used for guiding the relative movement between the left support frame and the right support frame and enhancing the stability of the relative movement between the left support frame and the right support frame.

Description

Roller feeding frame with guide mechanism and pipe cutting machine using same

Technical Field

The invention relates to a feeding device for conveying materials, in particular to a roller feeding frame with a guiding mechanism. The invention also relates to a pipe cutting machine for conveying pipes by using the roller feeding frame.

Background

The tube stock just produced is often as long as 6m, 10m or even longer, so that a cutting process must be performed in advance to cut long tubes into short tubes of a specific length before being applied to a specific product. The traditional cutting method adopts manual cutting, which has low precision and low working efficiency. Cutting machines for automatically cutting pipes by using electric cutting knives have appeared in the market. However, with the rapid development of modern industrialization, the field of application to pipes is more and more, and the demand for pipes is also increasing. The manner of automatic cutting by means of an electric cutter has not completely met the increase in the high demands on the tubing. Pipe cutting machines with faster cutting speeds and greater precision are sought. The laser cutting machine is used for cutting the pipe by adopting the laser head, and the cutting efficiency and the cutting precision are higher than those of the automatic cutting knife by several times.

In order to adapt the efficient cutting efficiency of the laser cutting machine, a feeding device capable of feeding rapidly must be provided for the laser cutting machine. In chinese patent 201621414627.2, a laser cutting machine for pipes is disclosed, which uses a transfer mechanism for clamping and transferring pipes, the transfer mechanism including an upper transfer part, a lower transfer part, and a first motor for driving the upper transfer part to move. The upper transmission part and the lower transmission part are respectively arranged on the guide post in a sliding way. The upper transmission part comprises two driving wheels, the first motor is in transmission connection with a synchronous wheel and a belt, and the synchronous wheel is in transmission connection with each driving wheel through the belt. The lower transmission part comprises three driven wheels. The feeding device further comprises an adjusting part for adjusting the distance between the upper transmission part and the lower transmission part, the adjusting part comprises an adjusting hand wheel and a transmission part II, the transmission part II comprises a rotating shaft with left-handed threads and right-handed threads, a first threaded part in threaded connection with the left-handed threads and a second threaded part in threaded connection with the right-handed threads, and the upper transmission part and the lower transmission part are respectively connected with the first threaded part and the second threaded part. The upper transmission part and the lower transmission part are opened or closed when the rotating shaft is driven to rotate by the adjusting hand wheel, so that the effect of adjusting the distance between the driving wheel and the driven wheel is achieved.

Disclosure of Invention

The upper and lower transfer portions of 201621414627.2 are not stable when slipping, and no better solution is proposed in this patent. The invention provides a roller feeding frame with a guide mechanism, which comprises a supporting frame and a roller group rotatably arranged on the supporting frame, wherein the roller group comprises left row rollers and right row rollers which are arranged left and right, and a material space capable of allowing materials to pass through is arranged between the left row rollers and the right row rollers; the device is characterized in that the supporting frame comprises a left supporting frame and a right supporting frame which are arranged left and right separately, left row rollers in the roller group are respectively and rotatably arranged on the left supporting frame, and right row rollers are respectively and rotatably arranged on the right supporting frame; the left support frame and the right support frame are movably arranged on the sliding support rail; the left support frame and the right support frame can relatively and synchronously approach or fade away so that the material spacing is adjustable and the position of the center line between the left row of rollers and the right row of rollers is kept unchanged when the material spacing is adjusted; the sliding support rail is arranged in a staggered mode, the sliding support rail is connected with the left support frame and the right support frame, relative movement between the left support frame and the right support frame is not hindered, and the sliding support rail is used for guiding relative movement between the left support frame and the right support frame and enhancing stability of relative movement between the left support frame and the right support frame.

According to the technical scheme, the invention has the beneficial technical effects that: due to the fact that the guide rail which is arranged in a staggered mode is additionally arranged on the basis of the sliding support rail, the left support frame and the right support frame can relatively and synchronously approach or fade away under the guidance of the sliding support rail and the guide rail, and therefore the material distance can be adjusted.

The guide rail with the connection structure between left support frame, the right support frame has multiple, for example:

The first connecting structure is characterized in that one end of the guide rail is fixedly connected with the left support frame or the right support frame, and the other end of the guide rail is connected with the other support frame in a sliding manner. When one end of the guide rail is fixedly connected to the left support frame, the other end of the guide rail is slidably connected to the right support frame, so that the guide rail is positioned by the left support frame, and meanwhile, the right support frame can slide relative to the left support frame under the guiding action of the guide rail. Conversely, when one end of the guide rail is fixedly connected to the right support frame, the other end of the guide rail is slidably connected to the left support frame.

The second connecting structure is characterized in that the guide rail is not fixedly connected to the support frame, and the guide rail is respectively and slidably connected to the left support frame and the right support frame. Thus, the left support frame and the right support frame can slide relative to the guide rail respectively.

The third connecting structure further comprises a peripheral coaming and a panel arranged in the horizontal direction, the panel is covered and pressed on the peripheral coaming, an opening is reserved on the panel, the peripheral coaming and the panel are combined to form an accommodating space, the supporting frame is accommodated in the accommodating space, and the roller set is exposed to the opening. Therefore, the peripheral coaming and the panel conceal the supporting frame, so that scrap iron and dust formed in the cutting process are prevented from adhering to the supporting frame in a large amount to influence the use. Further, at least one of the guide rails is fixedly connected to the peripheral coaming, and the middle parts of the guide rails are respectively and slidably connected to the left support frame and the right support frame. One of the left end or the right end of the guide rail can be fixedly connected to the peripheral enclosing plate, or both the left end and the right end can be fixedly connected to the peripheral enclosing plate.

The fourth connecting structure further comprises a pair of positioning columns, wherein the pair of positioning columns are fixedly connected to the front side and the rear side of the underframe respectively and positioned between the left support frame and the right support frame; a pair of synchronizing devices are further arranged between the left support frame and the right support frame, each synchronizing device comprises a first transmission arm and a second transmission arm, the first transmission arms and the second transmission arms are not only simultaneously associated with the positioning columns but also respectively associated with the left support frame or the right support frame, the positioning columns are matched with the synchronizing devices, the left support frame and the right support frame are not only used for guaranteeing that the left support frame and the right support frame are relatively and synchronously close to or gradually away from each other, but also used for determining that the positions of central lines between the left row of rollers and the right row of rollers are kept unchanged when the material spacing is adjusted. Further, the guide rail is fixedly connected to the positioning column, and two ends of the guide rail extending from two sides of the positioning column are respectively connected to the left support frame and the right support frame in a sliding mode.

The positioning columns are fixedly connected to the front side and the rear side of the underframe respectively and located between the left support frame and the right support frame, and firstly, the positioning columns can be directly or indirectly fixedly connected to the underframe so as to have fixed positions relative to the left support frame and the right support frame. And the positioning columns are arranged corresponding to the spacing spaces between the left support frame and the right support frame, and can be positioned in the spacing spaces between the left support frame and the right support frame or outside the spacing spaces between the left support frame and the right support frame.

The first and second driving arms are not only related to the positioning column, but also related to the left supporting frame or the right supporting frame respectively, the characteristic defines the connection structure between the first and second driving arms and the positioning column, the left supporting frame or the right supporting frame, the connection structure between the first and second driving arms and the positioning column is various, but no matter what structure is adopted, the first connection point between the first and second driving arms and the positioning column and the second connection point between the first and second driving arms and the left supporting frame or the right supporting frame are fixed points, and when the first connection point is a moving point, the second connection point is a fixed point, and vice versa. Therefore, through the cooperation of the positioning column and the synchronizing device, the left support frame and the right support frame synchronously approach or fade away under the condition that the position of the central line between the left row of rollers and the right row of rollers is unchanged, so that materials with different sizes can be adapted, the application range of the roller feeding frame is enlarged, and uniform and moderate clamping force can be respectively applied from the left side and the right side of the material feeding frame. In addition, because a pair of locating columns and a pair of synchronizing devices are arranged, the locating columns and the synchronizing devices can synchronously control the movement of the left support frame and the right support frame from front and back sides, the movement stability of the left support frame and the right support frame is improved, and the clamping force applied to materials by the idler wheels is further homogenized.

In order to drive the support frame to move, a further technical scheme can also be that the device further comprises a main driver and a torque transmission shaft which is in transmission connection with an output shaft of the main driver, wherein the torque transmission shaft extends to the position of the left support frame and also extends to the right support frame; at least one pair of rollers are driving rollers, and comprise a left driving roller and a right driving roller, wherein one left driving roller is in transmission connection with the moment transmission shaft through a left transmission device, and one right driving roller is in transmission connection with the moment transmission shaft through a right transmission device. Therefore, the left driving roller and the right driving roller can be driven to rotate actively under the drive of the moment transmission shaft, so that pushing force can be applied to materials from the left side and the right side respectively, and the conveying speed can be improved.

Besides, the invention also provides a pipe cutting machine applying the roller feeding frame, comprising the roller feeding frame and a laser cutting assembly, wherein the laser cutting assembly comprises a laser head for cutting, and the laser head is used for cutting materials conveyed by the roller feeding frame.

The further technical scheme may be that the pipe processing machine further comprises a clamping device, wherein the clamping device can rotate, the roller feeding frame is used for providing the received processed pipe to the clamping device and loosening the processed pipe when the clamping device rotates; the clamping device is used for clamping materials conveyed by the roller feeding frame and can drive the materials to rotate during cutting, and the laser head is also used for cutting the materials when the clamping device clamps the materials and rotates.

Because the invention has the characteristics and the advantages, the invention can be applied to the roller feeding frame and the pipe cutting machine.

Drawings

FIG. 1 is a schematic view of a front structure of a pipe cutting machine to which the technical scheme of the present invention is applied;

FIG. 2 is a schematic perspective view of the pipe cutting machine;

FIG. 3 is a schematic perspective view of another view of the pipe cutting machine;

fig. 4 is a schematic structural view of the roller carriage, wherein the peripheral enclosing plate 8 and the panel 81 are omitted;

FIG. 5 is a schematic perspective view of the positioning column;

FIG. 6 is a second association between the synchronization device and the positioning post, support frame;

FIG. 7 is a third correlation between the synchronization device and the positioning post, support frame;

FIG. 8 is a fourth relationship between the synchronization device and the positioning column and the supporting frame

FIG. 9 is a schematic cross-sectional view of a roller carriage;

FIG. 10 is a schematic view of the enlarged partial structure of the area A in FIG. 9;

FIG. 11 is a schematic diagram of the transmission between the rollers in the left row roller a;

fig. 12 is a schematic perspective view of the left auxiliary mounting 15.

Detailed Description

The roller feeding frame 100 and the pipe cutting machine using the technical scheme of the present invention will be further described with reference to the accompanying drawings.

As shown in fig. 1, 2 and 3, which are schematic structural views of a pipe cutting machine, the pipe cutting machine includes the roller feeding frame 100, a front feeding frame 500 positioned in front of the roller feeding frame 100, a laser cutting assembly 200 positioned at the rear of the roller feeding frame 100, and a clamping device 300 positioned between the laser cutting assembly 200 and the roller feeding frame 100. During cutting, the front feed carriage 500 provides the roller feed carriage 100 with processed tubing. The roller carriage 100 provides the received processed pipe to the clamping device 300. The clamping device 300 clamps the material delivered by the roller feeding frame 100 and can drive the material to rotate during cutting. When the clamping device 300 rotates, the roller feeding frame 100 releases the processed pipe. The laser cutting assembly 200 includes a cutting laser head 201, and the laser head 201 cuts the material clamped on the clamping device 300 when the clamping device 300 drives the material to rotate. The feeding and positioning device 600 is arranged above the roller feeding frame 100, and can be mounted on the roller feeding frame 100 or the front feeding frame 500. The loading positioning device 600 is used for positioning the material which is conveyed from the front material conveying frame 500 and reaches the roller material conveying frame 100 for the first time. A wire length metering device 400 is provided between the roller carriage 100 and the clamping device 300. Of course, in other embodiments, the wire length measuring device 400 may also be disposed on the roller feeding frame 100.

The specific structure of the roller feeding frame 100 having the synchronous moving structure will be described with emphasis. As shown in fig. 4 and 5, the roller feeding frame 100 includes a supporting frame (1, 1 a) and a roller set rotatably disposed on the supporting frame (1, 1 a), the roller set includes a left row of rollers a and a right row of rollers b disposed left and right, and a material space 12 capable of allowing materials to pass through is disposed between the left row of rollers a and the right row of rollers b. The outer circumferential surfaces of the rollers of the left row of rollers a and the right row of rollers b are respectively provided with a left groove 102 and a right groove 112 for clamping materials, and the left groove 102 and the right groove 112 are correspondingly matched left and right. Thus, the centers of the left groove 102 and the right groove 112 have the same height, and the clamping force of the left row of rollers a and the right row of rollers b can act on the same height position of the materials, so that the clamping stability is improved. The support frame includes left support frame 1, right support frame 1a that left and right are separately put, left side row gyro wheel a in the gyro wheel group rotates respectively and sets up on the left support frame 1, right side row gyro wheel b rotates respectively and sets up on the right support frame 1 a. The novel lifting device comprises a chassis 13, wherein the chassis 13 comprises a pair of sliding support rails (2, 2 a), and the left support frame 1 and the right support frame 1a are movably arranged on the pair of sliding support rails (2, 2 a). The device also comprises a pair of positioning columns (4, 4 a), wherein the pair of positioning columns (4, 4 a) are fixedly connected to the front side and the rear side of the underframe 13 and positioned between the left support frame 1 and the right support frame 1 a. The positioning column 4 and the positioning unit 4a have similar structures, and the positioning column 4 is described below as an example. The positioning column 4 comprises a column main body 40 and a mounting arm 41 extending from the column main body 40, wherein a chute 401 extending up and down along a center line O-O between the left row roller a and the right row roller b is arranged on the column main body 40. The positioning column 4 is located outside the space between the left support frame 1 and the right support frame 1a and is mounted on a peripheral coaming 8 which is suggested to be discussed below through the mounting arm 41 so as to be indirectly fixedly connected to the underframe 13, and thus has a fixed position relative to the left support frame 1 and the right support frame 1 a. Of course, in other embodiments, the positioning posts 4 may also be located in the space between the left support frame 1 and the right support frame 1a and directly fixed to the bottom frame 13.

As shown in fig. 4, a pair of synchronizing devices (3, 3 a) are further disposed between the left support frame 1 and the right support frame 1a, and the pair of synchronizing devices (3, 3 a) are disposed at the front and rear sides of the chassis. The synchronization device 3 and the synchronization device 3a have similar structures, and the association structure between the synchronization device 3 and the positioning column 4, the left support frame 1, the right support frame 1a, and the association structure between the synchronization device 3a and the positioning column 4a, the left support frame 1, and the right support frame 1a are similar, and the structure of the synchronization device 3 and the association structure between the synchronization device 3 and the positioning column 4, the left support frame 1, and the right support frame 1a are described below as examples. The synchronous device 3 is herringbone and comprises a first transmission arm (31) and a second transmission arm (32), the head ends (312, 322) of the first transmission arm (31) and the second transmission arm (32) are hinged together through a hinge shaft 33, the hinge shaft 33 is arranged in a sliding groove 401 of the positioning column 4 in a sliding manner and is kept on a central line O-O between the left row roller a and the right row roller b to move up and down, the tail end 311 of the first transmission arm 31 is rotatably arranged on the left support frame 1, and the tail end 321 of the second transmission arm 32 is rotatably arranged on the right support frame 1a. The first and second drive arms (31, 32) are thus associated not only with the positioning column 4 but also with the left support frame 1 or the right support frame 1a, respectively. The sliding device also comprises a moving driver 7 for driving the left support frame 1 and the right support frame 1a to relatively and synchronously approach or fade away, an output shaft of the moving driver 7 is connected to the right support frame 1a, when the moving driver 7 drives the right support frame 1a to move on the sliding support rails (2 and 2 a) and fade away from the left support frame 1, the second transmission arm 32 rotates around the tail end 321 and drives the hinge shaft 33 to slide in the sliding groove 401, and the hinge shaft 33 in sliding pulls the left support frame 1 to synchronously move on the sliding support rails (2 and 2 a) through the first transmission arm 31 and fade away from the right support frame 2. On the contrary, when the moving driver 7 drives the right support frame 1a to move on the sliding support rails (2, 2 a) to approach the left support frame 1, the left support frame 1 can be pulled to synchronously move by means of the positioning column 4 and the synchronizing device 3 to approach the right support frame 1a. Of course, in other embodiments, a correlation structure different from the above-mentioned one may be used between the synchronization device 3a and the positioning column 4a, the left support frame 1, and the right support frame 1a, for example, a second correlation structure to be discussed below may be used; or only one positioning column and one synchronizing device are arranged.

According to the technical scheme, the following steps are found: through the cooperation of reference column (4, 4 a) with synchronizer (3, 3 a), let left branch frame 1, right branch frame 1a are confirmed left side and are listed as under the circumstances that center line O-O's between gyro wheel a and the right side keeps unchanged the position of gyro wheel b synchronous and are close to or fade away to can adapt to the material of different size specifications, enlarge the application scope of gyro wheel pay-off frame, and can exert even, moderate clamping force from the left and right sides of material respectively, be favorable to improving push speed. In addition, since a pair of positioning columns (4, 4 a) and a pair of synchronizing devices (3, 3 a) are arranged, the pair of positioning columns (4, 4 a) and the pair of synchronizing devices (3, 3 a) can synchronously control the movement of the left support frame 1 and the right support frame 1a from front and back sides, the stability of the movement of the left support frame 1 and the right support frame 1a is improved, and the clamping force of the roller on the material can be further homogenized. The moving driver 7 not only can drive the right supporting frame 1a to move, but also can apply driving force to the left supporting frame 1 from front and rear sides simultaneously through the right supporting frame 1a and the pair of the synchronizing devices (3, 3 a) by means of the pair of the positioning columns (4, 4 a), and even clamping force can still be applied between the left row of rollers a and the right row of rollers b when the left supporting frame 1 and the right supporting frame 1a are loaded by a large number of rollers.

Besides, the following association structures can be selected between the synchronization device and the positioning column, the left support frame 1, and the right support frame 1 a:

In a second related structure, as shown in fig. 6, the synchronization device 3 "is in a cross shape, the middle positions of the first and second transmission arms (31", 32 ") are hinged together by a hinge shaft 33", the hinge shaft 33 "is fixedly arranged on the positioning column 4" and positioned on a central line O-O between the left row roller a and the right row roller b, and the head ends (311 ", 321") of the first and second transmission arms (31 ", 32") are respectively and slidably arranged on the sliding groove 14 of the left support frame 1, and the tail ends (312 ", 322") of the first and second transmission arms (31 ", 32") are respectively and slidably arranged on the sliding groove 14a of the right support frame 1 a. So that when the left support frame 1 is driven to move on the sliding support rails (2, 2 a) so as to fade away from the right support frame 1a, the head ends (311 ', 321') of the first and second transmission arms respectively rotate around the hinge shaft 33 'and slide toward each other so that the first and second transmission arms are respectively moved toward each other the tail ends of the second transmission arms (31', 32 ') are simultaneously rotated around the hinge shafts 33' and are slid toward each other, thereby pulling the right support frame 1a to move synchronously on the sliding support rails (2, 2 a) and to fade away from the left support frame 1, and vice versa.

As shown in fig. 7, in the third related structure, the head end 312 'of the first driving arm 31' is rotatably disposed on the positioning post 4 'through the left rotating shaft 313', the tail end 311 'of the first driving arm 31 is slidably disposed on the chute 14 of the left support frame 1, the head end 322' of the second driving arm 32 is rotatably disposed on the positioning post 4 'through the right rotating shaft 323', the tail end 321 'of the second driving arm 32' is slidably disposed on the chute 14a of the right support frame 1a, and driving teeth are disposed between the head end 312 'of the first driving arm 31' and the head end 322 'of the second driving arm 32', and the left rotating shaft 313 'and the right rotating shaft 323' are symmetrically disposed on left and right sides of the center line O-O between the left row roller a and the right row roller b. Thus, when the left support frame 1 is driven to move on the sliding support rails (2, 2 a) so as to fade away from the right support frame 1a, the first transmission arm 31 'rotates around the left rotating shaft 313' and simultaneously the second transmission arm 32 'is driven to rotate around the right rotating shaft 323' through transmission teeth so as to pull the right support frame 1a to move on the sliding support rails (2, 2 a) so as to fade away from the left support frame 1, and vice versa.

A fourth association structure, which is relatively simple, can be understood with reference to fig. 4. The synchronous device 3 is herringbone, the head ends of the first and second transmission arms (31, 32) are hinged together through a hinge shaft 33, the hinge shaft 33 is fixedly arranged on the positioning column 4 and positioned on a central line O-O between the left row of rollers a and the right row of rollers b, the tail end of the first transmission arm 31 is slidably arranged on the left support frame 1, and the tail end of the second transmission arm 32 is slidably arranged on the right support frame 1 a. Thus, when the first and second transmission arms (31, 32) are synchronously driven to swing around the hinge shaft 33 by the moving driver, the left support frame 1 and the right support frame 1a can be pulled to relatively synchronously approach or fade away.

In a fifth related structure, as shown in fig. 8, the synchronizing device 3a is in a parallelogram shape, the first transmission arm comprises a pair of left transmission arms (31, 31 a), the second transmission arm comprises a pair of right transmission arms (32, 32 a), the left ends of the pair of left transmission arms (31, 31 a) are rotatably arranged on the left support frame 1, the right ends of the pair of right transmission arms (32, 32 a) are rotatably arranged on the right support frame 1a, the left transmission arm 31 and the right transmission arm 32 are hinged together through a hinge shaft 33, the left transmission arm 31a and the right transmission arm 32a are hinged together through a hinge shaft 33a, and the hinge shafts (33, 33 a) are respectively slidably arranged in a chute 401 of the positioning column 4 and kept on a center line O-O between the left row roller a and the right row roller b to move up and down.

As shown in fig. 2 and 9, the roller set further comprises a peripheral enclosing plate 8 and a panel 81, wherein the panel 81 is pressed on the peripheral enclosing plate 8, an opening 810 is reserved on the panel 81, an accommodating space 82 is formed by combining the peripheral enclosing plate 8 and the panel 81, the supporting frames (1, 1 a) are accommodated in the accommodating space 82, and the roller set is exposed to the opening 810. In this way, the peripheral coaming 8 and the panel 81 conceal the supporting frames (1, 1 a) to prevent iron filings and dust formed in the cutting process from adhering to the supporting frames (1, 1 a) in a large amount to influence the use.

As shown in fig. 3, the device further comprises a pair of guide rails (9, 9 a), wherein the pair of guide rails (9, 9 a) are respectively arranged at the front side and the rear side of the support frame (1, 1 a). The guide rails (9, 9 a) and the sliding support rails (2, 2 a) are arranged in a staggered manner and connected to the left support frame 1 and the right support frame 1a but do not interfere with the relative movement between the left support frame 1 and the right support frame 1a, and the guide rails (9, 9 a) are used for guiding the relative movement between the left support frame 1 and the right support frame 1a and enhancing the stability of the relative movement between the left support frame 1 and the right support frame 1 a; . In this way, the sliding support rails (2, 2 a) and the guide rails (9, 9 a) are in a staggered layout relationship, and can provide sliding guide for the left support frame 1 and the right support frame 1a from different positions, so that the left support frame 1 and the right support frame 1a can be cooperatively guided to move relatively and the stability of the relative movement between the left support frame 1 and the right support frame 1a is enhanced.

As for the connection structure between the guide rails (9, 9 a) and the left and right support frames 1, 1a, there are various kinds such as:

First kind of connection structure, guide rail (9, 9 a) one end links firmly on the left branch frame 1, the other end sliding connection of guide rail (9, 9 a) is in on the right branch frame 1a, so guide rail (9, 9 a) relies on left branch frame 1 obtains the location, can also let simultaneously right branch frame 1a is in the direction effect of guide rail (9, 9 a) is relative left branch frame 1 slides. Of course, one end of the guide rail (9, 9 a) may be fixedly connected to the right support frame 1a, and the other end of the guide rail (9, 9 a) is slidably connected to the left support frame 1.

In the second connecting structure, the guide rails (9, 9 a) are not fixedly connected to the support frames (1, 1 a), and the guide rails (9, 9 a) are respectively and slidably connected to the left support frame 1 and the right support frame 1 a. In this way, the left support frame 1 and the right support frame 1a can slide relative to the guide rails (9, 9 a), respectively.

In the third connecting structure, at least one of the guide rails (9, 9 a) is fixedly connected to the peripheral coaming 8, and the middle parts of the guide rails (9, 9 a) are respectively and slidably connected to the left support frame 1 and the right support frame 1 a. One of the left end or the right end of the guide rail can be fixedly connected with the peripheral coaming, and the left end and the right end can also be fixedly connected with the peripheral coaming.

And in a fourth connecting structure, the guide rail 9 is fixedly connected to the positioning column 4, and two ends of the guide rail 9, which extend from two sides of the positioning column 4, are respectively and slidably connected to the left support frame 1 and the right support frame 1 a. The guide rail 9a is fixedly connected to the positioning column 4a, and two ends of the guide rail 9a extending from two sides of the positioning column 4a are respectively and slidably connected to the left support frame 1 and the right support frame 1 a.

As shown in fig. 4, 9 and 12, the roller feeding frame 100 further includes a main driver 5 and a torque transmission shaft 50 drivingly connected to an output shaft of the main driver 5, and the torque transmission shaft 50 extends not only to the position of the left support frame 1 but also to the right support frame 1a. Wherein, the left driving roller 10 in the left row roller a is in transmission connection with the moment transmission shaft 50 through a left transmission device. The left transmission device comprises a first left gear 6 arranged on the left driving roller rotating shaft 101 and a first transmission gear 61 which is arranged on the moment transmission shaft 50 and can be meshed with the first left gear 6 for transmission. A left auxiliary mounting rack 15 is arranged on the left support frame 1, and the left auxiliary mounting rack 15 is locked on the left support frame 1 through a screw 16. A first left mounting hole 151 and a second left mounting hole 152 are provided on the left auxiliary mounting bracket 15, and hole axes of the first left mounting hole 151 and the second left mounting hole 152 are perpendicular to each other. The first left gear 6 is rotatably disposed in the first control hole 151 through a bearing, and the first transmission gear 61 is rotatably disposed in the second control hole 152 through a bearing, so that the first transmission gear 61 is indirectly disposed on the left support frame 1. Wherein, the right driving roller 11 in the right row roller b is in transmission connection with the moment transmission shaft 50 through a right transmission device. The right transmission device comprises a first right gear 6a arranged on the right driving roller rotating shaft 101a and a second transmission gear 61a which is arranged on the moment transmission shaft 50 and can be meshed with the first right gear 6a for transmission. A right auxiliary mounting rack 15a is arranged on the right support frame 1a, and the right auxiliary mounting rack 15a is locked on the right support frame 1 through a screw 16 a. The right auxiliary mounting frame 15a has the same structure as the left auxiliary mounting frame 15, a first right mounting hole and a second right mounting hole with hole axes perpendicular to each other are also formed, the first right gear 6a is rotatably arranged in the first right control hole through a bearing, and the second transmission gear 61a is rotatably arranged in the second right control hole through a bearing, so that the second transmission gear 61a is indirectly arranged on the right support frame 1a. The torque of the torque transmission shaft 50 can be basically and synchronously transmitted to the left driving roller 10 and the right driving roller 11 through the meshing transmission between the first left gear 6 and the first transmission gear 61 and the meshing transmission between the second left gear 6a and the second transmission gear 61a, and the left driving roller 10 and the right driving roller 11 have consistent rotation linear speeds and can synchronously give pushing force to materials from the left side and the right side, so that the transmission speed and the accuracy are greatly improved. On this basis, the length of the material conveyed forward under the pushing of the left driving roller 10 and the right driving roller 11 can be calculated by arranging an encoder for measuring the angular displacement of the moment transmission shaft 50, the left driving roller 10 or the right driving roller 11.

As shown in fig. 11, adjacent rollers (10, 10a, 10 b) in the left row roller a on the left are connected in synchronous transmission. Specifically, the rotating shafts of the rollers (10 a, 10 b) are respectively provided with a transmission gear (6 a, 6 b), the rotating shaft 101 of the roller (10) is also provided with a transmission gear (6 e), and the transmission gear (6 e) is positioned above the first left gear (6). Intermediate transmission gears (6 c, 6 d) are respectively arranged between the transmission gears (6 a, 6 b) and the transmission gear (6 e), and the gears (6 a, 6b, 6c, 6d, 6 e) are in synchronous meshing transmission connection. The adjacent rollers in the right row roller b on the right are connected through a gear synchronous transmission, and the specific structure is the same as that shown in fig. 11, and the discussion is not repeated here. Therefore, all rollers in the left row of rollers a and all rollers in the right row of rollers b are active rollers, pushing force can be applied to materials, the total pushing resultant force born by the materials is increased, and the conveying speed is further improved. In addition, the conveying precision of the left row roller a and the right row roller b can be further improved by the fact that all rollers in the left row roller a have uniform rotation linear speeds and all rollers in the right row roller b have uniform rotation linear speeds. Of course, in other embodiments, only one pair of rollers may be provided as active rollers.

In order to be able to maintain the torque transmission shaft 50 in a driving relationship with the left and right driving rollers 10, 11 when the left and right support frames 1, 1a are relatively moved, the main drive 5 is arranged outside the left and right support frames 1, 1a, as further shown in fig. 9 and 10, in this embodiment the main drive 5 is arranged on the peripheral coaming 8. The first transmission gear 61 is slid on the torque transmission shaft 50 through a sliding shaft hole thereon, and the second transmission gear 61a is slid on the torque transmission shaft 50 through a sliding shaft hole thereon. The transmission structure between the first transmission gear 61, the second transmission gear 61a and the torque transmission shaft 50 is similar, and a transmission structure between the first transmission gear 61 and the torque transmission shaft 50 is explained as an example. The torque transmission shaft 50 is provided with an axially extending groove 501, the axial extension length of the groove 501 is not smaller than the axial sliding distance of the first transmission gear 61, the hole wall of the sliding shaft hole of the first transmission gear 61 is provided with a convex strip 611 capable of extending into the groove 501, and the first transmission gear 61 can axially slide on the torque transmission shaft 50 and synchronously transmit the torque of the torque transmission shaft 50 to the first left gear 6 by virtue of the cooperation between the convex strip 611 and the groove 501. Of course, in other embodiments, a flat key structure may be provided between the shaft hole of the first transmission gear 61 and the torque transmission shaft 50. In this way, when the left support frame 1 and the right support frame 1a are relatively moved, the first transmission gear 61 and the second transmission gear 61a can respectively axially slide on the torque transmission shaft 50 and can respectively synchronously transmit the torque of the torque transmission shaft 50 to the left driving roller 10 and the right driving roller 11.

In addition, the following transmission scheme can be adopted:

The first transmission scheme is as follows: the main driver 5 is arranged on the left support frame 1, the second transmission gear 61a is sleeved on the moment transmission shaft 50 in a sliding shaft hole in the second transmission gear, and when the left support frame 1 and the right support frame 1a relatively move, the second transmission gear 61a can axially slide on the moment transmission shaft 50 and can synchronously transmit the moment of the moment transmission shaft 50 to the right driving roller 11. The transmission structure between the second transmission gear 61a and the torque transmission shaft 50 may be the structure shown in fig. 9, and the description thereof will not be repeated. In this way, the second transmission gear 61a is able to synchronously transmit the torque of the torque transmission shaft 50 to the right driving roller 11 through the meshing transmission with the first right gear 6a while moving together with the right support frame 1 a.

The second transmission scheme is as follows: the main driver 5 is arranged on the left support frame 1 or outside the left support frame 1 and the right support frame 1a, the torque transmission shaft 50 comprises a left torque transmission shaft and a right torque transmission shaft, the left torque transmission shaft is in transmission connection with the main driver 5, the right torque transmission shaft is sleeved on the left torque transmission shaft in a sliding manner and can synchronously transmit the rotation torque of the left torque transmission shaft, the first transmission gear 61 is in transmission connection with the left torque transmission shaft, and the second transmission gear 61a is in transmission connection with the right torque transmission shaft; when the left support frame 1 and the right support frame 1a relatively move, the left moment transmission shaft and the right moment transmission shaft can relatively axially slide and can synchronously transmit the moment of the main driver 5 to the left driving roller 10 and the right driving roller 11 respectively. The left torque transmission shaft and the right torque transmission shaft are shaft bodies capable of transmitting a rotational torque and axially sliding relatively, and a transmission structure between the left torque transmission shaft and the right torque transmission shaft can adopt a transmission structure between the first transmission gear 61 and the torque transmission shaft 50 in the above transmission scheme, and a detailed description thereof is omitted.

Claims

1. The roller feeding frame with the guide mechanism comprises a supporting frame and a roller group rotatably arranged on the supporting frame, wherein the roller group comprises left row rollers and right row rollers which are arranged left and right, and a material distance capable of allowing materials to pass through is arranged between the left row rollers and the right row rollers; the device is characterized in that the supporting frame comprises a left supporting frame and a right supporting frame which are arranged left and right separately, left row rollers in the roller group are respectively and rotatably arranged on the left supporting frame, and right row rollers are respectively and rotatably arranged on the right supporting frame; the left support frame and the right support frame are movably arranged on the sliding support rail; the left support frame and the right support frame can relatively and synchronously approach or fade away so that the material spacing is adjustable and the position of the center line between the left row of rollers and the right row of rollers is kept unchanged when the material spacing is adjusted; the guide rail is arranged in a staggered manner with the sliding support rail and is connected with the left support frame and the right support frame but does not hinder the relative movement between the left support frame and the right support frame, and the guide rail is used for guiding the relative movement between the left support frame and the right support frame and enhancing the stability of the relative movement between the left support frame and the right support frame;

The rolling wheel set comprises a rolling wheel set, a supporting frame, a panel, a peripheral coaming and a panel, wherein the rolling wheel set is arranged in the horizontal direction;

The positioning columns are fixedly connected to the front side and the rear side of the underframe respectively and positioned between the left support frame and the right support frame; a pair of synchronizing devices are further arranged between the left support frame and the right support frame, each synchronizing device comprises a first transmission arm and a second transmission arm, the first transmission arms and the second transmission arms are simultaneously related to the positioning columns and are also related to the left support frame and the right support frame respectively, the positioning columns are matched with the synchronizing devices, the positioning columns are used for ensuring that the left support frame and the right support frame relatively synchronously approach or fade away, and the positions of central lines between the left row of rollers and the right row of rollers are kept unchanged when the material spacing is adjusted;

The device also comprises a main driver and a torque transmission shaft which is in transmission connection with the output shaft of the main driver, wherein the torque transmission shaft extends to the position of the left support frame and also extends to the right support frame; at least one pair of rollers are driving rollers, and comprise a left driving roller and a right driving roller, wherein one left driving roller is in transmission connection with the moment transmission shaft through a left transmission device, and one right driving roller is in transmission connection with the moment transmission shaft through a right transmission device.

2. The roller carriage of claim 1 wherein one end of the rail is fixedly attached to the left support frame or the right support frame and the other end is slidably attached to the other support frame.

3. The roller carriage of claim 1 wherein the guide rail is not fixedly attached to the support frame and the guide rail is slidably attached to the left support frame and the right support frame, respectively.

4. The roller feeding frame according to claim 1, wherein at least one of the guide rails is fixedly connected to the peripheral coaming, and the middle portions of the guide rails are respectively slidably connected to the left support frame and the right support frame.

5. The roller feeding frame according to claim 1, wherein the guide rail is fixedly connected to the positioning column, and two ends of the guide rail extending from two sides of the positioning column are respectively slidably connected to the left support frame and the right support frame.

6. A pipe cutting machine employing the roller carriage of any one of claims 1 to 5, comprising the roller carriage and further comprising a laser cutting assembly comprising a cutting laser head for cutting material conveyed by the roller carriage.

7. The pipe cutting machine of claim 6, further comprising a clamping device, the clamping device being rotatable, the roller carriage for providing the received processed pipe to the clamping device and for releasing the processed pipe when the clamping device is rotated; the clamping device is used for clamping materials conveyed by the roller feeding frame and can drive the materials to rotate during cutting, and the laser head is also used for cutting the materials when the clamping device clamps the materials and rotates.