JP6031665B2 - Synthetic resin mesh - Google Patents

Description

  The present invention relates to a synthetic resin net having at least a portion of a synthetic resin monofilament. More specifically, the present invention has a stable strength for long-term use and wear durability at the intersection of raw material monofilaments. The present invention relates to a synthetic resin network having excellent properties.

  Currently, aquaculture ginger (fishery material), gabion / futon fence (civil engineering material), rock fall prevention net (civil engineering material) used in the seawall construction method, intrusion prevention net (agricultural materials, building materials) for vehicles and animals, etc. Metal meshes are used in various fields such as grill nets (vehicle materials), but metal meshes are subject to oxidative corrosion over time, resulting in a decrease in durability. It has a number of problems such as exposed edges and heavy weight and poor handling. Especially when used as a cage for a ginger used in the sea, a rockfall protection net, etc. Due to the environment affected by calcium chloride for prevention, etc., the strength will be reduced in a short period due to the occurrence of rust, and frequent redrawing will be necessary. It is rare.

Among the conventional techniques, as a method for solving the above-mentioned problems, the ultimate viscosity is to improve the breaking strength, breaking elongation and durability of the turtle shell-type network made of synthetic resin monofilament. Is a polyester monofilament with a wire diameter of 1.5 or more, a wire diameter of 1.5 to 4.5 mm, a strength elongation product of 750 to 3000 kg / mm ² ·%, and a wear durability of 5000 times / mm ² or more. Synthetic resin nets having a hexagonal mesh (for example, see Patent Document 1) formed by weaving without joining or adhering to the mating portions have been proposed, and are also highly resistant to impacts from heavy objects such as falling rocks. The challenge is to provide a synthetic resin mesh that has strength and excellent impact durability, and is effective in rockfall protection. Be for rockfall protection synthetic resin mesh-like body having a mold mesh, rockfall protection synthetic resin mesh body tensile job polyester monofilament is 1000 kg / mm ² or more constituting the reticulated body (e.g., Patent Document 2 Have been proposed).
The above prior art discloses synthetic resin nets excellent in wear durability or impact resistance, but none of them is at a sufficient level for actual use, and synthetic resin nets are used in various fields. It was not satisfactory for wide deployment. That is, it was insufficient as a synthetic resin network that can be substituted for the metal network that the present invention has aimed for and achieved. The problems of the prior art are described below.

  That is, according to Patent Document 1, in the examples and comparative examples, the use of polyester monofilaments having a strength elongation product, intrinsic viscosity, wire diameter, and wear durability in a certain range is excellent as a habit for aquaculture. It has been shown that a synthetic resin network having fracture resistance can be obtained. Certainly, by using a synthetic resin mesh, there is no defect of reduced strength due to rust, and some improvement in durability can be seen, but this improvement improves the initial properties of the monofilaments that make up the mesh. It seems that the durability up to the broken net has been improved, but the durability against wind and rain and ultraviolet rays in a long-term use environment, and the durability after being scratched by flying objects, falling rocks, waves, etc. There is no disclosure or suggestion about improvement.

Further, according to Patent Document 2, in the example, the synthetic resin network using a polyester monofilament having a tensile break work of 1000 kg / mm ² ·% or more is a monofilament in a practical evaluation test in which a stone is actually dropped. It is described that there is no breakage and that the deformation of the mesh is small. From these results, it is considered that the net-like body described in Patent Document 2 can absorb impact energy without being greatly elongated even when subjected to impacts such as falling rocks immediately after making the net. However, since the net-like body of Patent Document 2 is difficult to stretch when subjected to an impact, it has a problem of being easily broken when stress is concentrated on a part of the monofilament. In addition, about the durability against wind and rain and ultraviolet rays in a long-term use environment where the mesh body is used for various purposes for a long time, and the durability improvement after being scratched by flying objects, falling rocks, waves, etc. No mention is made.

  On the other hand, as a method for improving the wear durability of the polyester monofilament, a polyester monofilament and an industrial fabric containing calcium carbonate, a monocarbodiimide compound, and a silicone compound (for example, see Patent Document 3) can improve weather resistance. Discloses a longline made of a synthetic resin monofilament to which carbon black is added (for example, see Patent Document 4). Although the above prior arts have improved the wear durability or weather resistance to some extent, they have not been able to satisfy the wear durability and weather resistance at the same time. In other words, it was different from a synthetic resin net that can be substituted for the metal net that the present invention has aimed for and achieved. The problems of the prior art are described below.

According to Patent Document 3, it is shown in the Examples and Comparative Examples that both excellent wear durability and hydrolysis resistance are provided, and the necessary and sufficient tensile strength is provided. Certainly, sufficient durability is obtained as an industrial monofilament, but the durability required for industrial fabrics is at most about half a year to a year and a half, and it is suitable for the wind, rain, ultraviolet rays, scratches, etc. required for synthetic resin nets. No mention is made of improving durability after receiving.
Patent Document 4 shows a graph showing the number of months of exposure and the residual strength retention for each addition amount when carbon black is added to polyester. Although it can be seen, the graph shows only the results of an exposure test for 9 months at the most, and a decrease in strength of about 10% is observed after 9 months, or is required for a synthetic resin network. The network was insufficient for improving durability after being subjected to wind and rain, ultraviolet rays, rubbing, etc. necessary for long-term use.

Japanese Patent Publication No. 7-30495 JP 2008-7986 A JP 2011-202298 A JP-A-7-75472

  An object of the present invention is to obtain a synthetic resin network having excellent durability even when used for a long period of time by using a monofilament excellent in weather resistance and wear durability as a constituent material. .

In order to achieve the above object, according to the present invention, there is provided a synthetic resin network having a hexagonal turtle shell-shaped mesh formed by knitting a synthetic resin monofilament as a constituent material, wherein the synthetic resin monofilament is a silicone compound. Is a monofilament having a diameter of 1.5 to 4.5 mm made of a polyester resin composition containing 0.1 to 10% by weight of carbon black and 0.05 to 5.0% by weight of carbon black. The strength retention after time irradiation is 70% or more, and the yarn-thread wear measured by the following evaluation method is 25000 times / mm ² or more , and the synthetic resin net is longitudinally irradiated for 1300 hours with a xenon weather meter. eye direction mesh strength 401N / mm ² or more, network strength of courses direction 258N / mm ² or more, Dearuko Synthetic resin mesh body is provided, wherein.
[Method for evaluating thread-thread wear]
(1) Prepare two monofilaments collected from the same sample with the same diameter, and fix one end to a slider connected to a motor via a cam, and make the monofilament horizontal and free to rotate freely A vertical load of 10 kg is fixed to the other end via a roller and suspended.
(2) The other monofilament is set by adjusting the height of the fixed part at one end and the free-rotating free roller so that it is orthogonal to the monofilament fixed at 5 mm above the monofilament fixed to the slider. A vertical load of 10 kg is fixed to the bottom and suspended.
(3) Remove the load of the first fixed monofilament once and hang down by fixing a vertical load of 10 kg to the other end through a free roller that can freely rotate through the upper side of the other monofilament set 5 mm above. This creates a state where the monofilaments are in contact with each other at a constant angular pressure.
(4) Actuate the motor, slide and wear it under the conditions of sliding length 30mm and sliding speed 120 times / minute, and measure the number of sliding times until one of the two monofilaments wears and cuts. The value divided by the cross-sectional area (mm ² ) is defined as the number of times of yarn-thread wear (times / mm ² ).

In the synthetic resin network of the present invention,
The synthetic resin monofilament tensile strength 200~350N / mm ^2, tensile elongation at break is given as the condition is preferably in the range of 30% to 100%.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the synthetic resin net-like body which maintains the durability excellent also for long-term use, and can reduce maintenance, such as a net reworking work.

Schematic showing mesh strength measurement in the longitudinal direction in synthetic resin mesh Schematic showing the mesh strength measurement in the transverse direction in the synthetic resin mesh Schematic showing dimensions of synthetic resin mesh

  The present invention is described in detail below.

The monofilament constituting the synthetic resin network having the turtle shell network of the present invention has a strength retention of 70% or more, preferably 80% or more after irradiation with a xenon weather meter for 1300 hours, according to the following evaluation method. It is important that the measured yarn-yarn wear is 25000 times / mm ² or more, preferably 30000 times / mm ² or more, and when this is satisfied, the synthetic resin net is used as a long-term farming ginger. When used as a gabion / futon fence, as a rock fall prevention net, etc. (hereinafter sometimes referred to as “when used for various purposes under harsh conditions for a long period of time”), waves, tidal currents, wind and rain Durability after being rubbed by ultraviolet rays, flying objects or falling rocks is improved.

  Moreover, it is an important requirement for the synthetic resin network of the present invention to use a monofilament made of a polyester resin composition containing a silicone compound and carbon black at the same time as a constituent material.

  That is, when only the silicone compound is added to the polyester, the silicone compound improves the sliding of the yarn, so that the wear durability is improved to some extent, but the xenon weather meter is a model test that assumes long-term use. Wear resistance after irradiation for 1300 hours deteriorates. Conversely, when only carbon black is added, the strength retention after irradiation for 1300 hours of xenon weather meter is improved to some extent, but the wear durability is low. When used as a net made of a synthetic resin net having a mesh, it is not preferable because it is inferior in durability after being rubbed by waves, tidal currents, wind and rain, flying objects, falling rocks, etc. and breaks.

  Specific examples of the silicone compound used in the present invention are silicone compounds having fluidity at room temperature or high temperature, and known silicone compounds can be used. For example, dimethylsilicone oils having dimethylsiloxane as a repeating unit, methylphenylsilicone oils in which a part of dimethylsiloxane is substituted with phenyl groups, diols having both terminal diols in which methyl groups at both ends of dimethylsilicone oil are substituted with hydroxyl groups Straight silicone oils such as dimethyl silicone oils, methyl hydrogen silicone oils in which part of the methyl group of dimethylsiloxane is substituted with hydrogen atoms, and part of the methyl group in dimethyl silicone oil are replaced with long chain alkyl groups Alkyl-modified silicone oils, alkyl / aralkyl-modified silicone oils in which part of the methyl group of dimethyl silicone oil is substituted with a long-chain alkyl group or phenyl alkyl group, part of the methyl group of dimethyl silicone oil is hydrophilic Polyether-modified silicone oils substituted with polyoxyalkylene, higher fatty acid-modified silicone oils in which a part of methyl group of dimethyl silicone oil is substituted with higher fatty acid ester, part of methyl group in dimethyl silicone oil is polyfluoroalkyl group Fluorine-modified silicone oils substituted with amino acids, amino-modified silicone oils with a portion of methyl groups of dimethyl silicone oil substituted with aminoalkyl groups, and epoxies with a portion of methyl groups of dimethylsilicone oil substituted with alkyl groups containing epoxy groups Modified silicone oils, carboxyl-modified silicone oils in which part of the methyl group of dimethyl silicone oil is substituted with a carboxyl group-containing alkyl group, and part of the methyl group in dimethyl silicone oil is substituted with a hydroxyl group-containing alkyl group Alcohol-modified silicone oils, mercapto-modified silicone oils in which some methyl groups in dimethyl silicone oil are substituted with mercapto group-containing alkyl groups, and chloro-modified in which some methyl groups in dimethyl silicone oil are substituted with chlorine-containing alkyl groups Silicone oils, chloro-modified silicone oils in which part of the methyl group of dimethyl silicone oil is substituted with chlorine-containing alkyl groups, alkyl-aralkyl-polyether-modified silicones substituted with long-chain alkyl groups, phenylalkyl groups and polyoxyalkylenes Examples include oils. One or more of these can be contained in combination. Among these, the use of dimethyl silicone oils is particularly preferably used.

Further, as a specific example of the carbon black used in the present invention, known carbon black can be used. Examples thereof include furnace black, channel black, acetylene black, and thermal black. Among these, furnace black is preferably used from the viewpoint of availability and cost.
The addition amount of the silicone compound added to the polyester compound constituting the monofilament is 0.1 to 10% by weight, preferably 0.3 to 5.0% by weight, more preferably 0.3 to 1.0% by weight. It is important to be in range.

  That is, if the addition amount is less than 0.1% by weight, the effect of adding the silicone compound cannot be exerted, which is not preferable. If the addition amount exceeds 10% by weight, the spinnability when spinning the monofilament is deteriorated.

  The amount of carbon black added to the polyester compound constituting the monofilament is 0.05 to 5.0% by weight, preferably 0.1 to 3.0% by weight, more preferably 0.1 to 1. It is important to be in the range of 0% by weight. That is, if the addition amount is less than 0.05% by weight, even if carbon black is added, the effect of improving the strength retention after irradiation with a xenon weather meter is not seen. This is not preferable because not only the initial strength of the resin becomes low but also the spinnability deteriorates.

  As described above, in the present invention, by simultaneously containing the silicone compound and the carbon black, the weather resistance and the wear durability are further improved as compared with the case where each of them is used as a single substance, When used for a purpose, it exhibits durability over a long period of time, so that it is possible to extend the maintenance interval such as re-settlement of the net, and as a result, it is possible to reduce the maintenance cost.

  Further, the polyester monofilament constituting the synthetic resin network having the turtle shell network of the present invention is a composite monofilament such as a core-sheath type composite or a sea-island type composite as long as the effect of the present invention is satisfied, even if it has an irregular cross section. Furthermore, additives that are usually used for synthetic fibers, such as titanium oxide, flame retardants, heat-resistant agents, light-proofing agent end-capping agents, and the like can be contained.

  It is important that the diameter of the monofilament constituting the synthetic resin network having the turtle shell network of the present invention is in the range of 1.5 to 4.5 mm, preferably 2.0 to 4.0 mm.

  That is, if the diameter of the monofilament is smaller than 1.5 mm, the absolute mesh strength of the synthetic resin net is reduced, and when used for various purposes under severe conditions for a long time, If the weight is less than 4.5 mm, the yarn becomes too rigid and it becomes difficult to process the knitting mesh, which is not preferable.

The monofilament constituting the synthetic resin net having the turtle shell-shaped mesh of the present invention has a tensile strength to prevent deformation and breakage of the net when used as an aquaculture net or as a rockfall protection net. Is preferably 200 N / mm ² or more, and the elongation at break is preferably 100% or less. Considering the workability when the monofilament is knitted, the tensile strength is 350 N / mm ² or less and the elongation at break is 30% or more. It is preferable that

That is, when a monofilament having a tensile strength of less than 200 N / mm ² is used, it tends to break without being able to withstand the weight of fish, the weight of stone, and the weight of rock fall when used for various purposes under severe conditions for a long period of time. It is in. In addition, when a monofilament having a breaking elongation exceeding 100% is used, not only does the net tend to stretch and deform in the same manner, but cultured fish may escape from the stretched net.

On the other hand, in order to obtain a monofilament whose monofilament has a tensile strength exceeding 350 N / mm ² or a breaking elongation of less than 30%, it is necessary to draw all at a high magnification, thereby reducing the rigidity of the yarn. Since it becomes high, the knitting process becomes difficult, so the production capacity tends to drop extremely.

Furthermore, the synthetic resin mesh having a turtle shell-shaped mesh of the present invention has a mesh strength of 250 N / mm ² or more in the longitudinal direction shown in FIG. 1 after irradiation with a xenon weather meter for 1300 hours, and the transverse direction shown in FIG. It is preferable that the mesh strength of the resin is 150 N / mm ² or more. By clearing this condition, when the synthetic resin network is used for various purposes under severe conditions for a long time, waves, tidal currents, wind and rain Durability after being rubbed by ultraviolet rays, flying objects or falling rocks is improved.

  Although there is no particular limitation on the mesh size of the synthetic resin network having the turtle shell-shaped mesh of the present invention, generally, the mesh strength per unit area is increased if the mesh size is reduced, and there is no fear of breakage, When used as an aquaculture ginger, not only does the resistance of seawater increase, but the processing capability when creating a mesh body is low and the amount of raw yarn used increases, resulting in high costs. On the other hand, the processing cost can be reduced by increasing the mesh size, but not only the strength of the mesh per unit area is lowered, but also fish escape from the mesh when used for aquaculture ginger or used as gabion 3 is not practical because it is necessary to select and use large stones, and the appropriate mesh size is 20 to 80 mm for the mesh pitch a shown in FIG. 3 and 20 to 80 mm for the opposite side distance b, preferably the mesh. It can be arbitrarily designed according to the thickness of the monofilament used in the range where the pitch a is 30 to 70 mm and the opposite side distance b is 30 to 70 mm. The mesh shape does not necessarily need to be a regular hexagon, and can be arbitrarily designed depending on the application and usage, such as a vertically long shape having an opposite side distance b longer than the mesh pitch a and a horizontally long shape having an opposite side distance b shorter than the mesh pitch a. it can.

  Next, although an example of the manufacturing method of the synthetic resin network body of this invention and the monofilament which comprises this network body is shown, a manufacturing method is not restricted to this.

  First, for the production of the polyester monofilament that is a constituent material of the network of the present invention, it is not necessary to use any special production apparatus, for example, it can be produced by using a known melt spinning machine and a die, for example, The polyester resin composition containing a silicone compound and carbon black is supplied to an extruder type melt spinning machine, melted and kneaded at a temperature 20 to 50 ° C. higher than the melting point of the resin, and then the polyester resin composition is discharged from the die hole. Extrude the melt as yarn.

  At this time, the polyester resin composition to be used is a method in which a silicone compound and carbon black are weighed and directly blended with the polyester resin, and a master batch in which the silicone compound and carbon black are kneaded into the polyester resin in advance. Can be created by mixing, stirring and mixing just before spinning, but creating a master batch in advance and mixing just before spinning makes blending spots less likely to occur and easy adjustment of raw materials Therefore, it is preferably adopted.

  Next, the melted yarn of the extruded polyester resin composition is cooled and solidified in a cooling bath, and then at a relatively low magnification of 2.5 to 4.5 times under a temperature condition of 90 to 350 ° C. The film is heated and stretched, and further subjected to a heat relaxation treatment as necessary to be wound.

  The polyester monofilament thus obtained is then used for a knitted net. First, a plurality of the obtained polyester monofilaments are arranged, supplied to a known turtle shell network manufacturing apparatus, heated to a temperature not lower than the melting point and not higher than the melting point of the polyester monofilament, and then the polyester monofilaments cross each other. However, the polyester monofilament is continuously twisted so that the straight and twisted portions of the polyester monofilament are the sides of the hexagonal turtle shell mesh, and the knitted mesh is cooled to solidify the form. Can be manufactured.

  The synthetic resin net having the tortoiseshell type mesh thus obtained is used severely when used for a long time as an aquaculture ginger, when used for a long time as a gabion / futon cage, or when used as a rock fall prevention net for a long time. Even under conditions, the durability is improved after being rubbed by waves, tidal currents, wind and rain, ultraviolet rays, flying objects, falling rocks, etc., so that maintenance such as netting work can be reduced.

Hereinafter, embodiments of the present invention will be described in more detail by way of examples. In addition, the definition and the measuring method of the characteristic used for the specification text and the Example are as follows.
[diameter]
Using a coolant proof micrometer (measurement range 0 to 25 mm) manufactured by Mitutoyo Corporation, the major axis and minor axis at the same point were measured for five samples while rotating the monofilament, and the total average was taken as the diameter.
[Break strength, elongation at break]
Using a Tensilon UTM-4-100 type tensile tester manufactured by Orientec Co., Ltd., measurement was made at a constant speed tension type gripping interval of 25 cm in accordance with JIS L1013 8.5. It was.
[Weather resistance test]
Using a Super Xenon Weather Meter SX75 manufactured by Suga Test Instruments Co., Ltd., measuring the strength or elongation after processing for 1300 hours at an irradiation intensity of 180 W / m ² , a black panel temperature of 63 ° C., and a water spray time of 18 minutes / 120 minutes, It calculated | required according to the following formula. The average value of the three monofilaments was adopted as the value.

Strength retention = strength after weathering test / strength before weathering test x 100
[Spinnability]
Judged by spinnability during 24-hour continuous operation.

○: Spinning and drawing were possible without trouble such as yarn breakage,
X: Spinning was impossible due to discharge spots and frequent stretch breaks.
[Thread-thread wear test]
Prepare two monofilaments, fix one end to a slider connected to the motor via a cam, level the monofilament, and apply a 10 kg vertical load to the other end via a free-rotating free roller. Fix and hang down.

  The other monofilament is set by adjusting the height of the fixed part at one end and the free-rotating free roller so that it is orthogonal to the monofilament fixed at 5 mm above the monofilament fixed to the slider. Suspend with fixed vertical load.

  Next, the load of the first fixed monofilament is once removed, and a vertical load of 10 kg is fixed to the other end via a free roller that can freely rotate through the upper side of the other monofilament set 5 mm above and hangs down. This creates a state where the monofilaments are in contact with each other at a constant angular pressure.

After that, the motor is operated, and sliding wear is performed under the conditions of a sliding length of 30 mm and a sliding speed of 120 times / minute, and the number of sliding times until one of the two monofilaments is worn and cut is measured. The value divided by the cross-sectional area (mm ² ) was defined as thread-thread wear count (times / mm ² ). In this case, in principle, the two monofilaments are collected from the same sample having the same diameter.
[material]
Using a rotary vacuum dryer, a polyethylene terephthalate chip manufactured by Toray Industries, Inc. (titanium oxide content 0.1% by weight, intrinsic viscosity 1.15, glass transition temperature 69 ° C.) at a drying temperature of 110 ° C. and a moisture content of 60 ± Chips dried to 20 ppm were used as raw material A.

  Using a rotary vacuum dryer, a polyethylene terephthalate chip manufactured by Toray Industries, Inc. (containing no titanium oxide, intrinsic viscosity 1.21, glass transition temperature 69 ° C.) was dried at a drying temperature of 110 ° C. until the moisture content reached 60 ± 20 ppm. The chip was used as raw material B.

  Chip obtained by adding 20% by weight of carbon black RCF # 45L manufactured by Mitsubishi Chemical Corporation to raw material A using a twin screw extruder with a processing temperature of 285 ° C. until the moisture content reaches 60 ± 20 ppm at a drying temperature of 110 ° C. The dried chip was used as raw material C.

A chip obtained by adding 10% by weight of dimethylpolysiloxane (silicone oil KF96 manufactured by Shin-Etsu Chemical Co., Ltd.) to the raw material A using a twin screw extruder at a processing temperature of 275 ° C. was dried at 110 ° C. The chip dried to a moisture content of 60 ± 20 ppm was used as the raw material D.
[Examples 1 to 3]
A mixed raw material obtained by blending raw material A, raw material B, raw material C, and raw material D so as to have the blend ratio shown in Table 1 is supplied to a melt spinning apparatus having a uniaxial extruder of φ 60 mm (L / D = 25). Melting was performed at a spinning temperature of 285 ° C. The molten resin was weighed by a gear pump so that the diameter after stretching was as described in Table 1, and then filtered through a # 200 filter in a spinning pack, and spun from a die hole having a hole diameter of 15 mm and a hole length of 10 mm. The spun yarn was cooled and solidified in a cooling bath filled with 70 ° C. warm water, and then taken up by the first roll. The drawn unstretched monofilament is continuously wound without being wound once, and is stretched one step at a magnification of 3.8 between the first roll and the second roll, and the relaxation treatment is performed 1 time between the second roll and the third roll. After applying, it was wound on a winder. A hot water bath having a length of 1500 mm and a temperature of 95 ° C. was installed as a stretching heat source between the first roll and the second roll. Subsequently, the obtained monofilament was formed into a knotless net having a hexagonal turtle shell network structure by the method described in Example of Patent Document 1. Table 1 shows the characteristics of the monofilament and the synthetic resin network thus obtained.
[Examples 4 to 7]
The same procedure as in Example 1 was performed except that the raw material A, the raw material B, the raw material C, and the raw material D were blended at the blend ratio shown in Table 1 and the diameter of the monofilament was changed by changing the discharge amount.

As is clear from Table 1, the monofilament used in the synthetic resin network of the present invention and the synthetic resin network are excellent in weather resistance and wear durability. When used in applications, maintenance such as re-straining of the net can be reduced by improving durability after being rubbed by waves, tidal currents, wind and rain, ultraviolet rays, flying objects and falling rocks.
[Comparative Examples 1 to 7]
A mixed raw material obtained by blending raw materials A, C, and D so as to have a blend ratio shown in Table 2 is supplied to a melt spinning apparatus having a uniaxial extruder of φ60 mm (L / D = 25), and a spinning temperature of 285 ° C. And melted. The molten resin was weighed with a gear pump so that the diameter after stretching was as described in Table 2, and then filtered through a # 200 filter in a spinning pack, and spun from a die hole having a hole diameter of 15 mm and a hole length of 10 mm. The spun strand was cooled and solidified in a cooling bath filled with 70 ° C. warm water, and then taken up by the first roll. The unstretched monofilament that has been taken up is continuously stretched at a magnification of 3.8 between the first roll and the second roll without being wound once, and a relaxation treatment of 1 time is performed between the second roll and the third roll. And then wound up on a winder. A hot water bath having a length of 1500 mm and a temperature of 95 ° C. was installed as a stretching heat source between the first roll and the second roll. Subsequently, the obtained monofilament was formed into a knotless net having a hexagonal turtle shell network structure by the method described in Example of Patent Document 1. Table 2 shows the characteristics of the monofilament and the synthetic resin network thus obtained.
[Comparative Examples 8 and 9]
The same operation as in Example 1 was performed except that the diameter of the monofilament was changed by changing the discharge amount.

  As is clear from Table 2, Comparative Examples 1 to 7 in which the blend ratio of the polyester resin composition is outside the scope of the present invention not only decreases the monofilament strength retention after 1300 hours of xenon weather meter irradiation, Since the thread-thread wear frequency will be low, it will be in a synthetic resin network state that is inferior in weather resistance and wear durability, so when using it for various purposes under severe conditions for a long time, In addition, the durability after rubbing due to wind and rain, ultraviolet rays, flying objects, falling rocks, etc. is lowered, so that it cannot be used for a long period of time.

  Further, Comparative Example 6 in which the silicone compound was blended beyond the scope of the present invention and Comparative Example 7 in which the carbon black was blended beyond the scope of the present invention were both monofilaments due to poor spinning properties such as ejection spots and frequent stretch breaks. Could not get.

  Next, in Comparative Example 8 in which the diameter of the monofilament is too narrow than the range of the present invention, the absolute strength of the monofilament is lowered due to the fineness of the diameter of the yarn, weather resistance by the xenon weather meter, and yarn-thread wear. Since it was inferior in wear durability, it was not applicable when used for various purposes under severe conditions for a long period of time.

  On the other hand, Comparative Example 9 in which the diameter of the monofilament is too thick in the range of the present invention was satisfactory in the characteristics of the monofilament, but the rigidity of the yarn coming from the thickness of the monofilament was high, and the knitting net was hung on a knitting machine. I tried, but the mesh could not be fixed well and the knitted mesh could not be made.

  The synthetic resin net-like body of the present invention is lighter than conventional metal net-like bodies, so that it is easy to handle, and there is no strength reduction due to rust caused by seawater, sodium chloride, etc. , Aquaculture ginger (aquatic materials), gabion used in revetment method / futon wall / revetment net (civil engineering materials), rock fall prevention net (civil engineering materials), invasion prevention nets for vehicles and animals (agricultural materials, building materials) When applied to various fields such as automobile grill nets (vehicle materials), it is excellent in weather resistance and wear durability under severe usage conditions, so the maintenance interval can be extended, and it is long at low cost. Can be used stably over a period of time.

a. Mesh pitch b. Opposite distance

Claims (2)

A synthetic resin net having a hexagonal turtle shell mesh formed by knitting a synthetic resin monofilament as a constituent material, wherein the synthetic resin monofilament contains 0.1 to 10% by weight of a silicone compound and 0% of carbon black. A monofilament having a diameter of 1.5 to 4.5 mm comprising a polyester resin composition containing 0.05 to 5.0% by weight, and the strength retention after irradiation of the monofilament with a xenon weather meter for 1300 hours is 70% or more, and The yarn-yarn wear measured by the following evaluation method is 25000 times / mm ² or more , and the longitudinal mesh strength after irradiation of a synthetic resin mesh with a xenon weather meter for 1300 hours is 401 N / mm ² or more, the transverse direction. The mesh strength of the synthetic resin is 258 N / mm ² or more .
[Method for evaluating thread-thread wear]
(1) Prepare two monofilaments collected from the same sample with the same diameter, and fix one end to a slider connected to a motor via a cam, and make the monofilament horizontal and free to rotate freely A vertical load of 10 kg is fixed to the other end via a roller and suspended.
(2) The other monofilament is set by adjusting the height of the fixed part at one end and the free-rotating free roller so that it is orthogonal to the monofilament fixed at 5 mm above the monofilament fixed to the slider. A vertical load of 10 kg is fixed to the bottom and suspended.
(3) Remove the load of the first fixed monofilament once and hang down by fixing a vertical load of 10 kg to the other end through a free roller that can freely rotate through the upper side of the other monofilament set 5 mm above. This creates a state where the monofilaments are in contact with each other at a constant angular pressure.
(4) Actuate the motor, slide and wear it under the conditions of sliding length 30mm and sliding speed 120 times / minute, and measure the number of sliding times until one of the two monofilaments wears and cuts. The value divided by the cross-sectional area (mm ² ) is defined as the number of times of yarn-thread wear (times / mm ² ). ^2. The synthetic resin net-like body according to claim 1, wherein the synthetic resin monofilament has a tensile strength of 200 to 350 N / mm ² and a tensile elongation at break of 30 to 100%.

Images