CN103609496A - Processing method for large netting gear clothes of double-layer structure - Google Patents
Processing method for large netting gear clothes of double-layer structure Download PDFInfo
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- CN103609496A CN103609496A CN201310608670.7A CN201310608670A CN103609496A CN 103609496 A CN103609496 A CN 103609496A CN 201310608670 A CN201310608670 A CN 201310608670A CN 103609496 A CN103609496 A CN 103609496A
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Abstract
A processing method for large netting gear clothes of a double-layer structure is characterized in that a small mesh ultra-high molecular weight polyethylene warp knitting net and a large mesh ultra-high molecular weight polyethylene warp knitting net are processed respectively; a head line is arranged on the upper edge in the length direction of the small mesh ultra-high molecular weight polyethylene warp knitting net which is 492m*11m and goes through anti-dirty treatment, and a foot line is arranged on the lower edge; a head line is arranged on the upper edge of the large mesh ultra-high molecular weight polyethylene warp knitting net which is 492m*11m and goes through anti-dirty treatment, and a foot line is arranged on the lower edge; the head line of the small mesh ultra-high molecular weight polyethylene warp knitting net which goes through the anti-dirty treatment and the head line of the large mesh ultra-high molecular weight polyethylene warp knitting net which goes through the anti-dirty treatment are bound into a head line of the large netting gear clothes of the double-layer structure; the foot line of the small mesh ultra-high molecular weight polyethylene warp knitting net which goes through the anti-dirty treatment and the foot line of the large mesh ultra-high molecular weight polyethylene warp knitting net which goes through the anti-dirty treatment are bound into a foot line of the large netting gear clothes of the double-layer structure.
Description
Technical field
The present invention relates to oceanic pasture dykes and dams or large-scale culturing net and enclose the large-scale netting gear processing method in field of engineering technology.
Background technology
Oceanic pasture dykes and dams or large-scale culturing net enclose concept and technology contents between netting gear in field of engineering technology and fishing gear, fish culture net cage and differ greatly, and fishing gear field etting processing method, fish culture net cage technical field casing etting processing method are not all suitable for oceanic pasture dykes and dams or large-scale culturing net encloses the double-deck large-scale netting gear etting processing method in field of engineering technology.Because aquaculture mode and stocked carp specification are different, etting size of mesh difference is larger; According to the size of size of mesh, the etting that people are not more than 50mm by size of mesh is called little mesh net or little mesh etting (if little mesh polyethylene is through netting), and the etting that size of mesh is not less than 200mm is called to large mesh net or large mesh etting (if large mesh polyethylene is through netting).According to the number of plies of etting in netting gear, people are called single layer fibre net or single layer fibre etting by single layer structure synthetic fibers etting, just double-decker synthetic fibers etting is called double-deck fleece or double-deck fiber etting, and three-decker synthetic fibers etting is called to three layers of fleece or three layers of fiber etting etc.The online marine biofouling of existing netting gear single layer fibre is serious, single layer fibre net is directly connected wearing and tearing with stanchion, under the bad weathers such as typhoon, hurricane tide, can there is the bad fish race accident of net in single layer fibre net, this brings loss not only to raiser or breeding enterprise, and the cultured fishes of escaping in a large number also can destroy local sea area biological chain sometimes, thereby bring heavy losses to whole industry and even marine ecology.In existing netting gear, put average weight in a suitable place to breed while being four double large yellow Crocker, people can adopt the single layer fibre net of size of mesh 65mm, once stocked carp difference in size is larger, small dimension fish in the stocked carp cultivation accident of escaping from single layer fibre net mesh will occur.Some technical barriers urgently to be resolved hurrily in netting gear evolution, have been exposed at present, marine biofouling problem as anti-in netting gear etting, between netting gear etting and stanchion (custom is referred to as between net stake) be directly connected contact wear problem, the not smooth problem of the inside and outside water body exchange of netting gear etting, the interior stocked carp escape problem of netting gear etting etc., the potential threat of the problems referred to above is large, had a strong impact on the culture benefit that oceanic pasture or large-scale culturing net enclose, therefore, it is the art unsolved technical barrier still for a long time that oceanic pasture dykes and dams or large-scale culturing net enclose double-deck large-scale netting gear etting processing method in field of engineering technology.The art is in the urgent need to a kind of double-deck large-scale netting gear etting processing method, to prevent stocked carp, escape, avoid directly connection contact wear between net stake, reduce draping number of times or labour intensity, raising cultivation comprehensive benefit, improve etting antifouling property and shock resistance, the Sustainable Healthy Development that boosting oceanic pasture or large-scale culturing net culture in enclosure are grown.
Summary of the invention
The invention provides a kind of double-deck large-scale netting gear etting processing method, object is to avoid stocked carp in netting gear to escape, reduce breeding facility draping number of times, avoid directly contact wear between net stake, promote the inside and outside water body exchange of netting gear etting and stocked carp grows, improves netting gear etting antifouling property and comprehensive benefit is grown in shock resistance, raising oceanic pasture or large-scale culturing net culture in enclosure, to promote oceanic pasture dykes and dams or large-scale culturing net encloses complete set equipment.
Technical scheme of the present invention adopts superhigh molecular weight polyethylene fibers, ultra-high molecular weight polyethylene braided wire and fishing net anti-fouling agent, it is the superhigh molecular weight polyethylene fibers yarn of 1610D that the superhigh molecular weight polyethylene fibers warping that to it is characterized in that line density be 1610D becomes line density, again according to the size of mesh of 44mm, the special braiding structure of " 4 lopping+12 inlaid thread " and longitudinally thermal finalization are processed 16 line densities, and to be 1610D superhigh molecular weight polyethylene fibers yarn be processed into little mesh ultra-high molecular weight polyethylene that specification is " UHMWPE-1610D * 24-44 " through netting with tricot machine, with fishing net anti-fouling agent, little mesh ultra-high molecular weight polyethylene is carried out to antifouling processing through netting, after drying, just obtain little mesh ultra-high molecular weight polyethylene after antifouling processing through netting, it is 1610D superhigh molecular weight polyethylene fibers yarn that the superhigh molecular weight polyethylene fibers warping that is 1610D by line density becomes line density, then according to the special braiding structure of the size of mesh of 453mm, " 8 lopping+21 inlaid thread " and longitudinally thermal finalization to process 29 line densities be that 1610D superhigh molecular weight polyethylene fibers yarn is processed into large mesh ultra-high molecular weight polyethylene that specification is " UHMWPE-1610D * 45-453 " through netting, with fishing net anti-fouling agent, large mesh ultra-high molecular weight polyethylene is carried out to antifouling processing through netting, after drying, just obtain large mesh ultra-high molecular weight polyethylene after antifouling processing through netting, it is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers rope yarn that is 6480D by 14 line densities according to the special torsade processes of S sth. made by twisting, the 31mm thigh lay pitch, the 34mm rope lay pitch, to become nominal diameter be that the S of 12mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades, it is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers rope yarn that is 6480D by 14 line densities according to the special torsade processes of Z sth. made by twisting, the 31mm thigh lay pitch, the 34mm rope lay pitch, to become nominal diameter be that the Z of 12mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades, it is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers rope yarn that is 6480D by 30 line densities according to the special torsade processes of Z sth. made by twisting, the 44mm thigh lay pitch, the 39mm rope lay pitch, to become nominal diameter be that the Z of 14mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades, it is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers that is 6480D by 30 line densities according to the special torsade processes of S sth. made by twisting, the 44mm thigh lay pitch, the 39mm rope lay pitch, to become nominal diameter be that the S of 14mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades, by 0.7068 horizontal hanging ratio, the little mesh ultra-high molecular weight polyethylene after the antifouling processing of width 492m length * 11m width is installed through the top edge of netting length direction S that a nominal diameter is 12mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades and using exaggerated through netting of this little mesh ultra-high molecular weight polyethylene after as antifouling processing, horizontal hanging ratio by 0.7068, little mesh ultra-high molecular weight polyethylene after the antifouling processing of above-mentioned 492m length * 11m width is installed through the lower limb of netting length direction the Z that a nominal diameter is 14mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades, usings the infraclass of this little mesh ultra-high molecular weight polyethylene after as antifouling processing through netting, by 0.7068 horizontal hanging ratio, the large mesh ultra-high molecular weight polyethylene after the antifouling processing of width 492m length * 11m width is installed through the top edge of netting length direction Z that a nominal diameter is 12mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades and using exaggerated through netting of this large mesh ultra-high molecular weight polyethylene after as antifouling processing, horizontal hanging ratio by 0.7068, large mesh ultra-high molecular weight polyethylene after the antifouling processing of above-mentioned 492m length * 11m width is installed through the lower limb of netting length direction the S that a nominal diameter is 14mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades, usings the infraclass of this large mesh ultra-high molecular weight polyethylene after as antifouling processing through netting, large mesh ultra-high molecular weight polyethylene by the little mesh ultra-high molecular weight polyethylene after antifouling processing after the exaggerated and antifouling processing of netting is tied up into the exaggerated of double-deck large-scale netting gear etting through the exaggerated ultra-high molecular weight polyethylene braided wire bundle that is 3.3mm with diameter of netting, little mesh ultra-high molecular weight polyethylene after the antifouling processing ultra-high molecular weight polyethylene braided wire that the large mesh ultra-high molecular weight polyethylene after antifouling processing is 3.3mm through the infraclass of netting with diameter through the infraclass of netting is pricked to the infraclass of tiing up into double-deck large-scale netting gear etting, and this has just obtained double-deck large-scale netting gear etting.Large mesh ultra-high molecular weight polyethylene after exaggerated, the infraclass of double-deck large-scale netting gear etting and antifouling processing is enclosed to stanchion through netting and oceanic pasture dykes and dams or large-scale culturing net and directly prick to tie up and be connected, can guarantee that double-deck large-scale netting gear etting can tightly be fixed on oceanic pasture dykes and dams or large-scale culturing net encloses on stanchion.
Outstanding feature of the present invention is on the basis of a large amount of unconventional tests, and the size of mesh of having determined double-deck large-scale netting gear etting is 44mm, has effectively prevented that small dimension fish from outwards escaping from large-scale netting gear etting mesh, the present invention adopts the special braiding structure of " 4 lopping+12 inlaid thread ", and etting is carried out createing after longitudinal thermal finalization processing 24 strands little mesh ultra-high molecular weight polyethylenes that specification is " UHMWPE-1610D * 24-44 " through netting, 24 strands of common braiding structure ultra-high molecular weight polyethylenes that the equal nominal number of share of stock (24 strands) that it can more existing same material be made, braiding structure are " 5 lopping+9 inlaid thread " obviously improve through netting is powerful, and this has improved service life and the equipment of double-deck large-scale netting gear etting greatly, the present invention adopts the special braiding structure of " 8 lopping+21 inlaid thread ", and etting is carried out createing after longitudinal thermal finalization processing 45 strands of large mesh ultra-high molecular weight polyethylenes that specification is " UHMWPE-1610D * 45-453 " through netting, 45 strands of common braiding structure ultra-high molecular weight polyethylenes that the equal nominal number of share of stock (45 strands) that it can more existing same material be made, braiding structure are " 9 lopping+18 inlaid thread " obviously improve through netting is powerful, and this has improved service life and the equipment of large-scale netting gear etting greatly, the present invention carries out antifouling processing through netting with fishing net anti-fouling agent to large and small mesh ultra-high molecular weight polyethylene, to obtain large and small mesh ultra-high molecular weight polyethylene after antifouling processing through netting, greatly improved the antifouling property of large-scale netting gear etting, greatly reduced large-scale netting gear etting draping number of times and reduced labour intensity, having promoted the inside and outside water body flow of large-scale netting gear etting and stocked carp to grow, the present invention encloses with creative use double-decker etting first on large-scale netting gear etting at oceanic pasture dykes and dams or large-scale culturing net, large mesh ultra-high molecular weight polyethylene in double-decker etting is through netting bearing part stanchion tractive force and outside high current billow impulsive force, the impact through netting to the medium and small mesh ultra-high molecular weight polyethylene of large-scale netting gear of buffering high current billow, improved little mesh ultra-high molecular weight polyethylene in double-decker etting through the anti-impact force of netting, service life and equipment, greatly improving oceanic pasture dykes and dams or large-scale culturing net encloses by large-scale netting gear etting shock resistance, the present invention encloses stanchion by the large mesh ultra-high molecular weight polyethylene in large-scale netting gear etting through netting and oceanic pasture dykes and dams or large-scale culturing net and directly contacts and prick to tie up and be connected, and little mesh ultra-high molecular weight polyethylene in netting gear etting does not directly contact with stanchion through netting, avoided the direct contact wear of little mesh ultra-high molecular weight polyethylene between netting and stanchion, this has greatly improved oceanic pasture dykes and dams or large-scale culturing net encloses service life and the equipment with large-scale netting gear etting, the present invention encloses manufacture with large-scale netting gear etting through netting material for oceanic pasture dykes and dams or large-scale culturing net by ultra-high molecular weight polyethylene, keeping under equal powerful prerequisite, large-scale netting gear reduces greatly with the more existing common synthetic fibers etting of ultra-high molecular weight polyethylene etting specification, greatly reduced the raw materials consumption of large-scale netting gear etting, develop low-carbon (LC) cultivation, promoted breeding facility equipment, exaggerated or infraclass in the large-scale netting gear etting of the present invention is processed into torsade (comprising that " Z " is to torsade and " S " to torsade) by two phase reverse lays, in effectively having avoided using two with twisting with the fingers to the work accidents such as mutual winding between rope.Result of the test shows, this method is enclosed anti-pollution function and shock resistance with large-scale netting gear etting, prevented that small dimension fish from escaping, reduce large-scale netting gear draping number of times, promoting inside and outside large-scale netting gear etting water body to exchange and stocked carp grows, avoids the aspect technique effects such as direct contact wear between large-scale netting gear etting and stanchion very obvious improving existing oceanic pasture dykes and dams or large-scale culturing net; Compare with the large-scale netting gear etting technology of the existing single layer structure with the manufacture of common synthetic fibers etting, the present invention has outstanding substantive distinguishing features and significant progressive, has greatly promoted China's oceanic pasture dykes and dams or large-scale culturing net and has enclosed complete set equipment.
Accompanying drawing explanation
Fig. 1 is that little mesh ultra-high molecular weight polyethylene after antifouling processing is through netting structure chart.
Fig. 2 is that large mesh ultra-high molecular weight polyethylene after antifouling processing is through netting structure chart.
Fig. 3 is that oceanic pasture dykes and dams or large-scale culturing net enclose with large-scale netting gear etting structure chart.
Embodiment
Below in conjunction with accompanying drawing explanation, implement best way of the present invention:
The present invention adopts superhigh molecular weight polyethylene fibers, ultra-high molecular weight polyethylene braided wire and fishing net anti-fouling agent, it is the superhigh molecular weight polyethylene fibers yarn of 1610D that the superhigh molecular weight polyethylene fibers warping that to it is characterized in that line density be 1610D becomes line density, again according to the size of mesh of 44mm, the special braiding structure of " 4 lopping+12 inlaid thread " and longitudinally thermal finalization are processed 16 line densities, and to be 1610D superhigh molecular weight polyethylene fibers yarn be processed into little mesh ultra-high molecular weight polyethylene that specification is " UHMWPE-1610D * 24-44 " through netting with tricot machine, with fishing net anti-fouling agent, little mesh ultra-high molecular weight polyethylene is carried out to antifouling processing through netting, after drying, just obtain little mesh ultra-high molecular weight polyethylene after antifouling processing through netting (5 in Fig. 1),
It is 1610D superhigh molecular weight polyethylene fibers yarn that the superhigh molecular weight polyethylene fibers warping that is 1610D by line density becomes line density, then according to the special braiding structure of the size of mesh of 453mm, " 8 lopping+21 inlaid thread " and longitudinally thermal finalization to process 29 line densities be that 1610D superhigh molecular weight polyethylene fibers yarn is processed into large mesh ultra-high molecular weight polyethylene that specification is " UHMWPE-1610D * 45-453 " through netting; With fishing net anti-fouling agent, large mesh ultra-high molecular weight polyethylene is carried out to antifouling processing through netting, after drying, just obtain large mesh ultra-high molecular weight polyethylene after antifouling processing through netting (6 in Fig. 2);
It is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers rope yarn that is 6480D by 14 line densities according to the special torsade processes of S sth. made by twisting, the 31mm thigh lay pitch, the 34mm rope lay pitch, to become nominal diameter be that the S of 12mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades;
It is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers rope yarn that is 6480D by 14 line densities according to the special torsade processes of Z sth. made by twisting, the 31mm thigh lay pitch, the 34mm rope lay pitch, to become nominal diameter be that the Z of 12mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades;
It is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers rope yarn that is 6480D by 30 line densities according to the special torsade processes of Z sth. made by twisting, the 44mm thigh lay pitch, the 39mm rope lay pitch, to become nominal diameter be that the Z of 14mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades;
It is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers rope yarn that is 6480D by 30 line densities according to the special torsade processes of S sth. made by twisting, the 44mm thigh lay pitch, the 39mm rope lay pitch, to become nominal diameter be that the S of 14mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades;
By 0.7068 horizontal hanging ratio, the little mesh ultra-high molecular weight polyethylene after the antifouling processing of width 492m length * 11m width is installed through the top edge of netting length direction S that a nominal diameter is 12mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades and using this little mesh ultra-high molecular weight polyethylene after as antifouling processing exaggerated (1 in Fig. 1) through netting;
Horizontal hanging ratio by 0.7068, little mesh ultra-high molecular weight polyethylene after the antifouling processing of described 492m length * 11m width is installed through the lower limb of netting length direction the Z that a nominal diameter is 14mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades, usings the infraclass (in Fig. 1 2) of this little mesh ultra-high molecular weight polyethylene after as antifouling processing through netting;
By 0.7068 horizontal hanging ratio, the large mesh ultra-high molecular weight polyethylene after the antifouling processing of width 492m length * 11m width is installed through the top edge of netting length direction Z that a nominal diameter is 12mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades and using this large mesh ultra-high molecular weight polyethylene after as antifouling processing exaggerated (3 in Fig. 2) through netting;
Horizontal hanging ratio by 0.7068, large mesh ultra-high molecular weight polyethylene after the antifouling processing of described 492m length * 11m width is installed through the lower limb of netting length direction the S that a nominal diameter is 14mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades, usings the infraclass (in Fig. 2 4) of this large mesh ultra-high molecular weight polyethylene after as antifouling processing through netting;
Large mesh ultra-high molecular weight polyethylene by the little mesh ultra-high molecular weight polyethylene after antifouling processing after the exaggerated and antifouling processing of netting pricks through the exaggerated ultra-high molecular weight polyethylene braided wire that is 3.3mm with diameter of netting exaggerated (7 in the Fig. 3) that ties up into double-deck large-scale netting gear etting; Little mesh ultra-high molecular weight polyethylene after the antifouling processing ultra-high molecular weight polyethylene braided wire that the large mesh ultra-high molecular weight polyethylene after antifouling processing is 3.3mm through the infraclass of netting with diameter through the infraclass of netting is pricked to the infraclass (8 in Fig. 3) of tiing up into double-deck large-scale netting gear etting, and this has just obtained double-deck large-scale netting gear etting (9 in Fig. 3);
Large mesh ultra-high molecular weight polyethylene after exaggerated, the infraclass of double-deck large-scale netting gear etting and antifouling processing is enclosed to stanchion through netting and oceanic pasture dykes and dams or large-scale culturing net and directly contact and prick to tie up and be connected, guarantee that oceanic pasture dykes and dams or large-scale culturing net enclose with double-deck large-scale netting gear etting to be tightly fixed on oceanic pasture dykes and dams or large-scale culturing net encloses on stanchion.
Claims (2)
1. double-deck large-scale netting gear etting processing method, it is the superhigh molecular weight polyethylene fibers yarn of 1610D that the superhigh molecular weight polyethylene fibers warping that to it is characterized in that line density be 1610D becomes line density, then according to the special braiding structure of the size of mesh of 44mm, " 4 lopping+12 inlaid thread " and longitudinally thermal finalization to process 16 line densities be 1610D superhigh molecular weight polyethylene fibers yarn with tricot machine, is processed into little mesh ultra-high molecular weight polyethylene that specification is " UHMWPE-1610D * 24-44 " through netting; With fishing net anti-fouling agent, little mesh ultra-high molecular weight polyethylene is carried out to antifouling processing through netting, after drying, just obtain little mesh ultra-high molecular weight polyethylene after antifouling processing through netting; It is 1610D superhigh molecular weight polyethylene fibers yarn that the superhigh molecular weight polyethylene fibers warping that is 1610D by line density becomes line density, then according to the special braiding structure of the size of mesh of 453mm, " 8 lopping+21 inlaid thread " and longitudinally thermal finalization to process 29 line densities be that 1610D superhigh molecular weight polyethylene fibers yarn is processed into large mesh ultra-high molecular weight polyethylene that specification is " UHMWPE-1610D * 45-453 " through netting; With fishing net anti-fouling agent, large mesh ultra-high molecular weight polyethylene is carried out to antifouling processing through netting, after drying, just obtain large mesh ultra-high molecular weight polyethylene after antifouling processing through netting; It is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers rope yarn that is 6480D by 14 line densities according to the special torsade processes of S sth. made by twisting, the 31mm thigh lay pitch, the 34mm rope lay pitch, to become nominal diameter be that the S of 12mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades; It is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers rope yarn that is 6480D by 14 line densities according to the special torsade processes of Z sth. made by twisting, the 31mm thigh lay pitch, the 34mm rope lay pitch, to become nominal diameter be that the Z of 12mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades; It is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers rope yarn that is 6480D by 30 line densities according to the special torsade processes of Z sth. made by twisting, the 44mm thigh lay pitch, the 39mm rope lay pitch, to become nominal diameter be that the Z of 14mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades; It is the superhigh molecular weight polyethylene fibers rope yarn of 6480D that the superhigh molecular weight polyethylene fibers doubling that is 1620D by line density becomes line density, then the superhigh molecular weight polyethylene fibers that is 6480D by 30 line densities according to the special torsade processes of S sth. made by twisting, the 44mm thigh lay pitch, the 39mm rope lay pitch, to become nominal diameter be that the S of 14mm twists with the fingers three bursts of ultra-high molecular weight polyethylene torsades; By 0.7068 horizontal hanging ratio, the little mesh ultra-high molecular weight polyethylene after the antifouling processing of width 492m length * 11m width is installed through the top edge of netting length direction S that a nominal diameter is 12mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades and using exaggerated through netting of this little mesh ultra-high molecular weight polyethylene after as antifouling processing; Horizontal hanging ratio by 0.7068, little mesh ultra-high molecular weight polyethylene after the antifouling processing of above-mentioned 492m length * 11m width is installed through the lower limb of netting length direction the Z that a nominal diameter is 14mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades, usings the infraclass of this little mesh ultra-high molecular weight polyethylene after as antifouling processing through netting; By 0.7068 horizontal hanging ratio, the large mesh ultra-high molecular weight polyethylene after the antifouling processing of width 492m length * 11m width is installed through the top edge of netting length direction Z that a nominal diameter is 12mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades and using exaggerated through netting of this large mesh ultra-high molecular weight polyethylene after as antifouling processing; Horizontal hanging ratio by 0.7068, large mesh ultra-high molecular weight polyethylene after the antifouling processing of above-mentioned 492m length * 11m width is installed through the lower limb of netting length direction the S that a nominal diameter is 14mm and is twisted with the fingers three bursts of ultra-high molecular weight polyethylene torsades, usings the infraclass of this large mesh ultra-high molecular weight polyethylene after as antifouling processing through netting; Large mesh ultra-high molecular weight polyethylene by the little mesh ultra-high molecular weight polyethylene after antifouling processing after the exaggerated and antifouling processing of netting is tied up into the exaggerated of double-deck large-scale netting gear etting through the exaggerated ultra-high molecular weight polyethylene braided wire bundle that is 3.3mm with diameter of netting; Little mesh ultra-high molecular weight polyethylene after the antifouling processing ultra-high molecular weight polyethylene braided wire that the large mesh ultra-high molecular weight polyethylene after antifouling processing is 3.3mm through the infraclass of netting with diameter through the infraclass of netting is pricked to the infraclass of tiing up into double-deck large-scale netting gear etting, and this has just obtained double-deck large-scale netting gear etting.
2. double-deck large-scale netting gear etting processing method according to claim 1, is characterized in that the large mesh ultra-high molecular weight polyethylene after exaggerated, the infraclass of double-deck large-scale netting gear etting and antifouling processing is enclosed to stanchion through netting and oceanic pasture dykes and dams or large-scale culturing net directly to be pricked to tie up and be connected.
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| CN106350938A (en) * | 2016-11-08 | 2017-01-25 | 山东好运通网具科技股份有限公司 | Large meshed net manual weaving auxiliary device and mesh weaving method applying auxiliary device |
| CN110409373A (en) * | 2019-08-12 | 2019-11-05 | 鲁普耐特集团有限公司 | A kind of flood-fighting net device and its application and application method |
| CN111387096A (en) * | 2020-04-30 | 2020-07-10 | 浙江东一海洋集团有限公司 | Be applied to large-scale rail facility in marine ranch |
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