Closed knotless net braiding-net collecting-forming integrated equipment
阅读说明:本技术 封闭无结网绞编-收网-成型一体化装备 (Closed knotless net braiding-net collecting-forming integrated equipment ) 是由 孟婥 杜诚杰 孙以泽 陈玉洁 于 2019-11-19 设计创作,主要内容包括:本发明涉及一种封闭无结网绞编-收网-成型一体化装备,由机头部件,机架和收网部件组成;机头部件包括机头固定组件和主传动部件;机头固定组件包括绞编底盘、锭子拆卸安装板、背板、嵌块;主传动部件包括拨盘驱动电机减速器、拨盘主动轴组件、拨盘过渡轴组件、拨盘从动轴组件、长锭子组件、嵌块驱动电机、嵌块主动轴组件、侧边嵌块主动轴组件、嵌块过渡轴组件、嵌块从动轴组件和侧边嵌块从动轴组件;机架包括承力台和绞编环安装架;收网部件包括左墙板、右墙板、罗拉驱动电机减速器和若干罗拉。本发明的一体化装备适合生产小网目多结节(可达400以上)的封闭无结绞编网,且装备安装方便、可靠性高。(The invention relates to a closed knotless net stranding-net collecting-forming integrated device, which consists of a machine head component, a machine frame and a net collecting component; the machine head part comprises a machine head fixing component and a main transmission part; the machine head fixing component comprises a braiding chassis, a spindle dismounting and mounting plate, a back plate and an embedding block; the main transmission part comprises a driving plate driving motor reducer, a driving plate driving shaft assembly, a driving plate transition shaft assembly, a driving plate driven shaft assembly, a long spindle subassembly, an embedded block driving motor, an embedded block driving shaft assembly, a side embedded block driving shaft assembly, an embedded block transition shaft assembly, an embedded block driven shaft assembly and a side embedded block driven shaft assembly; the frame comprises a bearing platform and a twisted ring mounting frame; the net collecting part comprises a left wall plate, a right wall plate, a roller driving motor reducer and a plurality of rollers. The integrated equipment is suitable for producing the small-mesh multi-knot (more than 400) closed knot-free twisted nets, and is convenient to install and high in reliability.)
1. The utility model provides a closed knotless net hank braids-receives net-shaping integration and equips, its characterized in that includes nose spare, frame and receives the net part, nose spare is located in the frame, and the frame includes the hank and braids the ring, nose spare and hank braids the ring coaxial arrangement, and the frame below is equipped with receives the net part, and closed knotless net that finishes by nose spare hank is propped out to be opened up the back and is stereotyped to receiving the net part through the hank braids ring on the frame, finishes receiving the net to closed knotless hank braids the net by receiving the net part, wherein:
the machine head part comprises an annular braiding chassis, a back plate, an embedded block driving mechanism and a driving plate driving mechanism, wherein n driving plates are arranged on the inner surface of the braiding chassis; groove-shaped fixed spindle rails which are distributed along the axial direction and the circumferential direction and correspond to the n drive plates are arranged on the inner surface of the twisting and weaving chassis for twisting, and the groove-shaped fixed spindle rails which are adjacent in the circumferential direction and the axial direction are intersected through an embedding block respectively; the surface of the insert is provided with a crossed spindle track and a non-crossed spindle track; when the embedded blocks are in a crossed state, the groove-shaped fixed spindle rails which are adjacent in the circumferential direction or the axial direction are crossed through the crossed spindle rails; when the embedded blocks are in a non-crossed state, the groove-shaped fixed spindle tracks which are adjacent in the circumferential direction or the axial direction are not crossed with each other at the embedded blocks; 2n long spindles with taper sleeves are correspondingly arranged in dial plate notches of n dial plates in a one-to-one manner according to a mode that 1 occupies 1 space, each dial plate is driven by a dial plate driving mechanism fixed on the outer ring surface of the braiding chassis to dial the long spindles to move along a closed snake-shaped spindle path formed by a groove type fixed spindle track and an insert block, and a yarn outlet of each long spindle is close to a braiding ring; the method comprises the following steps that each insert block which is located on the same vertical line in the axial direction and is not provided with a drive plate is defined as a row of insert blocks, K rows of insert blocks are shared, K is an even number, each insert block which is located on the same horizontal plane in the circumferential direction and is not provided with a drive plate is defined as a row of insert blocks, J rows are shared, and each row is provided with K insert blocks; the embedded blocks at the top end of the 2K-1 th row and each embedded block at the bottom end of the 2K-1 th row are driven by respective independent embedded block driving mechanisms fixed on the outer ring surface of the braiding chassis, so that the embedded blocks are switched between a non-crossed state and a crossed state, and K is more than or equal to 1 and less than or equal to K/2; each line of the J lines of the embedded blocks is controlled by K/4 embedded block driving mechanisms which are uniformly distributed in the circumferential direction, the lines of the J lines of the embedded blocks are not connected, and all the embedded blocks on each line of the embedded blocks are changed synchronously.
2. The closed knotless braiding-net retracting-forming integrated equipment according to claim 1, wherein the drive plate driving mechanism comprises two rows of drive plate driving motor reducers arranged on the outer annular surface of the stranding back plate, a drive plate driving shaft assembly, a drive plate transition shaft assembly and a drive plate driven shaft assembly arranged on the outer annular surface of the braiding chassis; all the drive plate driving motor reducers of each row of drive plate driving motor reducers are uniformly distributed along the circumferential direction, and each drive plate driving motor reducer is connected with one drive plate driving shaft component; the driving plate driving shaft assembly comprises a driving plate driving shaft, a driving plate axial series gear and a driving plate side circumferential gear, wherein the driving plate driving shaft is sleeved with a driving plate bearing I; two rows of driving plate transition shaft assemblies are respectively arranged at the upper part and the lower part of the braiding chassis; the drive plate transition shaft assembly comprises a drive plate transition shaft sleeved with a drive plate bearing II, a drive plate axial series gear II and a drive plate side circumferential gear II, wherein the drive plate side circumferential gear II of the drive plate transition shaft assembly adjacent in the circumferential direction is meshed with the drive plate side circumferential gear I of the drive plate driving shaft assembly, so that the drive plate transition shaft and the adjacent drive plate driving shaft synchronously rotate, and the drive plate axial series gear II corresponding to the position of the drive plate transition shaft are driven to rotate; the circumferential gears on the sides of the drive plates of the two circumferentially adjacent drive plate transition shaft assemblies are meshed with each other, so that the two adjacent drive plate transition shafts synchronously rotate, and the drive plates corresponding to the positions of the two drive plate transition shafts and the drive plate axial serial gears are driven to rotate; the drive plate driving shaft component and the drive plate transition shaft component drive the drive plate driven shaft component which is adjacent to the drive plate driving shaft component in the axial direction to rotate; the driving plate driven shaft assembly comprises a driving plate driven shaft sleeved with a driving plate bearing III and a driving plate axial series gear III, the driving plate axial series gear III of the driving plate driven shaft assembly is meshed with a driving plate axial series gear I of a driving plate driving shaft assembly adjacent to the driving plate in the axial direction or a driving plate axial series gear II of a driving plate transition shaft assembly, so that the driving plate driven shaft and the adjacent driving plate driving shaft or the adjacent driving plate transition shaft synchronously rotate, and the driving plate axial series gear III corresponding to the driving plate driven shaft are driven to rotate; the driving plate axial serial gears of two driving plate driven shaft assemblies which are adjacent in the axial direction are in three-phase meshing, so that the two adjacent driving plate driven shafts synchronously rotate, and the driving plate corresponding to the two driving plate driven shafts and the driving plate axial serial gear II are driven to rotate.
3. The closed knotless net stranding-net collecting-forming integrated equipment according to claim 1, wherein the insert driving mechanism comprises an insert driving motor arranged on the outer ring surface of the back plate, an insert driving shaft assembly, an insert transition shaft assembly, an insert driven shaft assembly, a side insert driving shaft assembly and a side insert driven shaft assembly; each embedded block driving motor is connected with an embedded block driving shaft assembly or a side embedded block driving shaft assembly, a circle of embedded blocks which are positioned at the same axial position in the circumferential direction are defined as a row of embedded blocks, M embedded block driving motors are uniformly distributed in the circumferential direction outside a back plate where each row of embedded blocks are positioned, an embedded block transition shaft assembly is arranged at the central position of every two adjacent embedded blocks, four embedded block driven shaft assemblies, three embedded block transition shaft assemblies, an embedded block driving shaft assembly and an embedded block driving motor which drives the embedded block driving shaft assembly are defined as an embedded block driving unit, and each row of embedded blocks are driven by M embedded block driving units, the side embedded block driving units are distributed between adjacent driving plates in the uppermost row and between adjacent driving plates in the lowermost row in the axial direction; the embedded block driving shaft assembly comprises an embedded block driving shaft and an embedded block circumferential gear I, wherein the embedded block driving shaft is sleeved with an embedded block bearing I; the embedded block driven shaft assembly comprises an embedded block driven shaft and an embedded block circumferential gear II, wherein an embedded block bearing II is sleeved on the embedded block driven shaft, the embedded block driven shaft assembly is arranged at a position adjacent to the embedded block driving shaft assembly in the circumferential direction, and the embedded block circumferential gear II of the embedded block driven shaft assembly is meshed with the embedded block circumferential gear I of the embedded block driving shaft assembly, so that the embedded block driven shaft and the adjacent embedded block driving shaft synchronously rotate, and the embedded block corresponding to the embedded block driven shaft is driven to rotate; the embedded block transition shaft assembly comprises an embedded block transition shaft sleeved with an embedded block bearing III and an embedded block circumferential gear III, the embedded block transition shaft assembly is arranged at a position circumferentially adjacent to the embedded block driven shaft assembly, and the embedded block circumferential gear III of the embedded block transition shaft assembly is meshed with the embedded block circumferential gear II of the embedded block driven shaft assembly, so that the embedded block transition shaft and the adjacent embedded block driven shaft synchronously rotate; the side embedded block driving shaft assembly comprises a side embedded block driving shaft and an embedded block axial gear I, wherein the embedded block driving shaft is sleeved with an embedded block bearing IV; side abaculus driven shaft subassembly is including the side abaculus driven shaft and the abaculus axial gear two that the cover was equipped with the abaculus bearing five, and side abaculus driven shaft subassembly is installed at the axial adjacent position of side abaculus driving shaft subassembly, and the abaculus axial gear two of side abaculus driven shaft subassembly meshes with the abaculus axial gear of side abaculus driving shaft subassembly for side abaculus driven shaft rotates with adjacent side abaculus driving shaft is synchronous, thereby drives and rotates with the corresponding abaculus of side abaculus driven shaft position.
4. The closed knotless net braiding-net retracting-forming integrated equipment according to claim 1, wherein the frame comprises a bearing table and a braiding ring mounting frame, the bearing table is mounted on a foundation, the braiding ring mounting frame is fixedly connected to the bearing table, and the braiding ring is mounted on the braiding ring mounting frame.
5. The closed knotless net braiding, net collecting and forming integrated equipment as claimed in claim 4, wherein the net collecting component comprises an L-shaped left wall plate and an L-shaped right wall plate which are arranged in parallel, and the left wall plate and the right wall plate are installed on a foundation; a main net rolling roller, a main net rolling pressing roller and a net rolling reversing roller which are matched with the main net rolling pressing roller are arranged between one ends of the horizontal sections of the left wall plate and the right wall plate and are driven to rotate by a roller driving motor reducer, and a net feeding reversing roller is arranged between the other ends of the horizontal sections of the left wall plate and the right wall plate; a main net feeding roller driven by a roller driving motor reducer II to rotate and a main net feeding pressing roller matched with the main net feeding roller are arranged between the vertical sections of the left wall plate and the right wall plate; the closed knotless twisted net separated from the twisted ring is sent to a net-feeding reversing roller through a main net-rolling roller and a main net-rolling roller, then is sent to a main net-feeding roller through the net-feeding reversing roller, and the main net-feeding roller realizes discharging.
Technical Field
The invention belongs to the technical field of high-end textile equipment, and relates to equipment integrating closed knotless net stranding, net collecting and forming.
Background
The knotless net is a net piece formed by interweaving the folded yarns of two yarns into knots, has the advantages of high knot strength and attractive appearance compared with the knotted net, and is widely applied to the fields of fishery, sports goods and the like.
The non-knotted net knitted by a ① warp knitting machine has defects, and strands far away from the knots do not participate in 'knitting', so that the strands of two yarns are not completely interwoven, the knot strength is low, and the application is narrow, ② the non-knotted net knitted by a common knitting machine meets the requirements on the strength, but cannot produce meshes with small mesh specifications at present, and the knitting number is small because common non-knotted net knitting equipment adopts short spindles, and a twisting and knitting chassis is in a plane type, so that the distance between a yarn outlet point of each spindle and a knitting ring is different, the yarns are converged in advance before the knitting ring, mesh feet of the meshes are increased, on the other hand, the dial and the number of the spindles of the plane type twisting and knitting chassis are small, 4 strands are required to be knitted into 1 strand, 2 strands of yarns are required to be knitted into the knots, namely 8 spindles are required to be knitted into 1 knot, and the number and the width of the meshes are limited.
Disclosure of Invention
The technical problem to be solved by the invention is as follows: the prior art winching equipment cannot produce small-mesh multi-knot closed knotless nets.
In order to solve the technical problem, the technical scheme of the invention provides a closed knotless net stranding-net collecting-forming integrated device, which is characterized by comprising a machine head component, a rack and a net collecting component, wherein the machine head component is arranged on the rack, the rack comprises a stranding ring, the machine head component and the stranding ring are coaxially arranged, the net collecting component is arranged below the rack, a closed knotless net stranded by the machine head component is stretched and shaped by the stranding ring on the rack and then is separated to the net collecting component, and the net collecting component finishes net collecting of the closed knotless stranding net, wherein:
the machine head part comprises an annular braiding chassis, a back plate, an embedded block driving mechanism and a driving plate driving mechanism, wherein n driving plates are arranged on the inner surface of the braiding chassis; groove-shaped fixed spindle rails which are distributed along the axial direction and the circumferential direction and correspond to the n drive plates are arranged on the inner surface of the twisting and weaving chassis, and the groove-shaped fixed spindle rails which are adjacent in the circumferential direction and the axial direction are intersected through an embedding block respectively; the surface of the insert is provided with a crossed spindle track and a non-crossed spindle track; when the embedded blocks are in a crossed state, the groove-shaped fixed spindle rails which are adjacent in the circumferential direction or the axial direction are crossed through the crossed spindle rails; when the embedded blocks are in a non-crossed state, the groove-shaped fixed spindle tracks which are adjacent in the circumferential direction or the axial direction are not crossed with each other at the embedded blocks; 2n long spindles with taper sleeves are correspondingly arranged in dial plate notches of n dial plates in a one-to-one manner according to a mode that 1 occupies 1 space, each dial plate is driven by a dial plate driving mechanism fixed on the outer ring surface of the braiding chassis to dial the long spindles to move along a closed snake-shaped spindle path formed by a groove type fixed spindle track and an insert block, and a yarn outlet of each long spindle is close to a braiding ring; the method comprises the following steps of defining all the embedded blocks which are positioned on the same vertical line in the axial direction and are not provided with driving plates to be a row of embedded blocks, wherein K is an even number, and defining all the embedded blocks which are positioned on the same horizontal plane in the circumferential direction and are not provided with driving plates to be a row of embedded blocks, wherein J rows are provided, and each row is provided with K embedded blocks; the embedded blocks at the top end of the 2K-1 th row and each embedded block at the bottom end of the 2K-1 th row are driven by respective independent embedded block driving mechanisms fixed on the outer ring surface of the braiding chassis, so that the embedded blocks are switched between a non-crossed state and a crossed state, and K is more than or equal to 1 and less than or equal to K/2; each line of the J lines of the embedded blocks is controlled by K/4 embedded block driving mechanisms which are uniformly distributed in the circumferential direction, the lines of the J lines of the embedded blocks are not connected, and all the embedded blocks on each line of the embedded blocks are changed synchronously.
Preferably, the drive plate driving mechanism comprises two rows of drive plate driving motor reducers arranged on the outer annular surface of the twisting back plate, a drive plate driving shaft assembly, a drive plate transition shaft assembly and a drive plate driven shaft assembly on the outer annular surface of the twisting chassis; all the drive plate driving motor reducers of each row of drive plate driving motor reducers are uniformly distributed along the circumferential direction, and each drive plate driving motor reducer is connected with one drive plate driving shaft component; the driving plate driving shaft assembly comprises a driving plate driving shaft, a driving plate axial series gear and a driving plate side circumferential gear, wherein the driving plate driving shaft is sleeved with a driving plate bearing I; two rows of driving plate transition shaft assemblies are respectively arranged at the upper part and the lower part of the braiding chassis; the drive plate transition shaft assembly comprises a drive plate transition shaft sleeved with a drive plate bearing II, a drive plate axial series gear II and a drive plate side circumferential gear II, wherein the drive plate side circumferential gear II of the drive plate transition shaft assembly adjacent in the circumferential direction is meshed with the drive plate side circumferential gear I of the drive plate driving shaft assembly, so that the drive plate transition shaft and the adjacent drive plate driving shaft synchronously rotate, and the drive plate axial series gear II corresponding to the position of the drive plate transition shaft are driven to rotate; the circumferential gears on the sides of the drive plates of the two circumferentially adjacent drive plate transition shaft assemblies are meshed with each other, so that the two adjacent drive plate transition shafts synchronously rotate, and the drive plates corresponding to the positions of the two drive plate transition shafts and the drive plate axial serial gears are driven to rotate; the drive plate driving shaft component and the drive plate transition shaft component drive the drive plate driven shaft component which is adjacent to the drive plate driving shaft component in the axial direction to rotate; the driving plate driven shaft assembly comprises a driving plate driven shaft sleeved with a driving plate bearing III and a driving plate axial series gear III, the driving plate axial series gear III of the driving plate driven shaft assembly is meshed with a driving plate axial series gear I of a driving plate driving shaft assembly adjacent to the driving plate in the axial direction or a driving plate axial series gear II of a driving plate transition shaft assembly, so that the driving plate driven shaft and the adjacent driving plate driving shaft or the adjacent driving plate transition shaft synchronously rotate, and the driving plate axial series gear III corresponding to the driving plate driven shaft are driven to rotate; the driving plate axial serial gears of two driving plate driven shaft assemblies which are adjacent in the axial direction are in three-phase meshing, so that the two adjacent driving plate driven shafts synchronously rotate, and the driving plate corresponding to the two driving plate driven shafts and the driving plate axial serial gear II are driven to rotate.
Preferably, the insert driving mechanism comprises an insert driving motor arranged on the outer ring surface of the back plate, an insert driving shaft assembly, an insert transition shaft assembly, an insert driven shaft assembly, a side insert driving shaft assembly and a side insert driven shaft assembly, wherein the insert driving shaft assembly, the insert transition shaft assembly, the insert driven shaft assembly, the side insert driving shaft assembly and the side insert driven shaft assembly are arranged on the outer ring surface of the braiding chassis; each embedded block driving motor is connected with an embedded block driving shaft assembly or a side embedded block driving shaft assembly, a circle of embedded blocks which are positioned at the same axial position in the circumferential direction are defined as a row of embedded blocks, M embedded block driving motors are uniformly distributed in the circumferential direction outside a back plate where each row of embedded blocks are positioned, an embedded block transition shaft assembly is arranged at the central position of every two adjacent embedded blocks in the circumferential direction, four embedded block driven shaft assemblies, three embedded block transition shaft assemblies, an embedded block driving shaft assembly and an embedded block driving motor for driving the embedded block driving shaft assembly are defined as an embedded block driving unit, each row of embedded blocks are driven by M embedded block driving units, the embedded block driving units are mutually connected end to end in the circumferential direction, a side embedded block driven shaft assembly, a side embedded block driving shaft assembly and an embedded block driving motor for driving the side embedded block driving shaft assembly are defined as a side embedded block driving unit, the driving plates are distributed between adjacent driving plates in the uppermost row and between adjacent driving plates in the lowermost row in the axial direction; the embedded block driving shaft assembly comprises an embedded block driving shaft and an embedded block circumferential gear I, wherein the embedded block driving shaft is sleeved with an embedded block bearing I; the embedded block driven shaft assembly comprises an embedded block driven shaft and an embedded block circumferential gear II, wherein an embedded block bearing II is sleeved on the embedded block driven shaft, the embedded block driven shaft assembly is arranged at a position adjacent to the embedded block driving shaft assembly in the circumferential direction, and the embedded block circumferential gear II of the embedded block driven shaft assembly is meshed with the embedded block circumferential gear I of the embedded block driving shaft assembly, so that the embedded block driven shaft and the adjacent embedded block driving shaft synchronously rotate, and the embedded block corresponding to the embedded block driven shaft is driven to rotate; the embedded block transition shaft assembly comprises an embedded block transition shaft sleeved with an embedded block bearing III and an embedded block circumferential gear III, the embedded block transition shaft assembly is arranged at a position circumferentially adjacent to the embedded block driven shaft assembly, and the embedded block circumferential gear III of the embedded block transition shaft assembly is meshed with the embedded block circumferential gear II of the embedded block driven shaft assembly, so that the embedded block transition shaft and the adjacent embedded block driven shaft synchronously rotate; the side embedded block driving shaft assembly comprises a side embedded block driving shaft and an embedded block axial gear I, wherein the embedded block driving shaft is sleeved with an embedded block bearing IV; side abaculus driven shaft subassembly is including the side abaculus driven shaft and the abaculus axial gear two that the cover was equipped with the abaculus bearing five, and side abaculus driven shaft subassembly is installed at the axial adjacent position of side abaculus driving shaft subassembly, and the abaculus axial gear two of side abaculus driven shaft subassembly meshes with the abaculus axial gear of side abaculus driving shaft subassembly for side abaculus driven shaft rotates with adjacent side abaculus driving shaft is synchronous, thereby drives and rotates with the corresponding abaculus of side abaculus driven shaft position.
Preferably, the rack comprises a bearing platform and a twisted ring mounting frame, the bearing platform is mounted on the foundation, the twisted ring mounting frame is fixedly connected to the bearing platform, and the twisted ring is mounted on the twisted ring mounting frame.
Preferably, the net collecting part comprises an L-shaped left wall plate and an L-shaped right wall plate which are arranged in parallel, and the left wall plate and the right wall plate are installed on the foundation; a main net rolling roller, a main net rolling pressing roller and a net rolling reversing roller which are matched with the main net rolling pressing roller are arranged between one ends of the horizontal sections of the left wall plate and the right wall plate and are driven to rotate by a roller driving motor reducer, and a net feeding reversing roller is arranged between the other ends of the horizontal sections of the left wall plate and the right wall plate; a main net feeding roller driven by a roller driving motor reducer II to rotate and a main net feeding pressing roller matched with the main net feeding roller are arranged between the vertical sections of the left wall plate and the right wall plate; the closed knotless twisted net separated from the twisted ring is sent to a net-feeding reversing roller through a main net-rolling roller and a main net-rolling roller, then is sent to a main net-feeding roller through the net-feeding reversing roller, and the main net-feeding roller realizes discharging.
The invention provides a closed knotless net-winding-net-collecting-forming integrated device which is composed of a long conical spindle and can produce a small-net-number multi-knot (more than 400), and the device has the following beneficial effects:
(1) according to the closed knotless net twisting, winding and forming integrated equipment, in the process of the long spindle subassembly staggering motion, most yarn staggering points are protected by the spindle taper sleeves, so that the contact time and the friction and the wear of yarns are small, 2 folded yarns are twisted into 1 yarn, 4 folded yarns are twisted into knots, the strength of a net piece is high, and the quality is good;
(2) the closed knotless net braiding-net collecting-forming integrated equipment has the advantages that the braiding base plate is cylindrical, the number of the driving plates is increased by fully utilizing the axial size, the occupied area is small, and the knotless net which can be braided is large in number of nodes, small in mesh and large in width.
Drawings
FIG. 1 is a general isometric view of the apparatus;
FIG. 2 is an isometric view of a nose piece;
FIG. 3 is an isometric view of a handpiece stationary assembly;
FIG. 4 is a partial view of the main drive components;
FIG. 5 is a partial view of an insert drive unit and a side insert drive unit; FIG. 6 is an isometric view of the frame;
FIG. 7 is an isometric view of a net retrieving member;
FIG. 8 is a schematic view of a closed knotless braiding process;
wherein, 1-machine head part, 2-machine frame, 3-net collecting part, 4-machine head fixing component, 5-main transmission part, 6-twisting chassis, 7-spindle dismounting mounting plate, 8-back plate, 9-embedded block, 10-driving plate motor reducer, 11-embedded block driving motor, 12-driving plate driving shaft component, 13-driving plate transition shaft component, 14-embedded block driving shaft component, 15-embedded block driven shaft component, 16-side embedded block driven shaft component, 17-side embedded block driving shaft component, 18-embedded block sub component transition shaft component, 19-long spindle, 20-driving plate driven shaft component, 21-bearing platform, 22-twisting ring mounting rack, 23-main winding net driving motor reducer, 24-main winding net roller, 25-main net rolling compaction roller, 26-net rolling reversing roller, 27-main net rolling coupler, 28-left wall plate, 29-roller bearing seat assembly, 30-right wall plate, 31-main net feeding roller driving motor reducer, 32-main net feeding coupler, 33-net feeding reversing roller, 34-main net feeding roller and 35-main net feeding compaction roller.
Detailed Description
The invention will be further illustrated with reference to the following specific examples. It should be understood that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention. Further, it should be understood that various changes or modifications of the present invention may be made by those skilled in the art after reading the teaching of the present invention, and such equivalents may fall within the scope of the present invention as defined in the appended claims.
The invention discloses a closed knotless net stranding-net collecting-forming integrated device, which consists of a machine head part 1, a
The nose part 1 comprises a nose fixing assembly 4 and a main transmission part 5.
The machine head fixing component 4 comprises a
The primary drive component 5 includes a dial
The drive plate driving mechanism comprises two rows of drive plate
The method comprises the following steps of defining all the embedded blocks which are positioned on the same vertical line in the axial direction and are not provided with driving plates to be a row of embedded blocks, wherein K is an even number, and defining all the embedded blocks which are positioned on the same horizontal plane in the circumferential direction and are not provided with driving plates to be a row of embedded blocks, wherein J rows are provided, and each row is provided with K embedded blocks; the embedded blocks at the top end of the 2K-1 th row and each embedded block at the bottom end of the 2K-1 th row are driven by respective independent embedded block driving mechanisms fixed on the outer ring surface of the braiding chassis, so that the embedded blocks are switched between a non-crossed state and a crossed state, and K is more than or equal to 1 and less than or equal to K/2; each line of J lines of the embedded blocks is respectively controlled by K/4 embedded block driving mechanisms which are uniformly distributed in the circumferential direction, the lines are not connected, and all the embedded blocks on each line are changed synchronously. That is, in the present invention, the state of all the blocks will not change, some blocks are fixed on the braiding chassis, and only the non-crossed spindle rail is processed on the blocks, which is equivalent to the shape of a part of the rail is well defined. The insert blocks which can change state are all integrated with the insert block driven shaft and the side insert block driven shaft discussed below, and cross spindle tracks and non-cross spindle tracks are arranged on the insert blocks.
The insert driving mechanism comprises an
The power transmission of the main transmission is divided into drive plate power and slug power, the drive plate power sequence is 4, which are ① drive plate drive motor reducer 10-main shaft coupling-drive plate driving shaft assembly 12-
The
The net collecting component comprises a
The following describes how to adopt the closed knotless net braiding-net collecting-forming integrated equipment to braid a small-mesh multinode closed knotless net by combining with a specific case.
By adopting the braiding knot 400, the mesh foot is 10mm, the closed knotless net is arranged, 100 rows in the circumferential direction and 8 rows in the axial direction are arranged on the
The closed knotless net specifically comprises the following steps:
(1) all the
(2) the dial
(3) All the embedded
(4) the
(5) All blocks drive electric, 11 stops, BjWhen the number is 0, the main
(6) the dial
(7) All the embedded
(8) the
(9) And (3) repeating the steps (1) to (8) all the time, so that the yarn is switched between the states of knitting yarn, knitting yarn and knitting yarn.
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