JPWO2005024110A1 - Rope heat treatment method, heat treatment equipment and rope - Google Patents

Abstract

The heating temperature can be dramatically increased, the strength of the obtained rope can be greatly improved, it can be applied not only to synthetic fiber ropes in general but also to composite ropes using different raw materials, and precise temperature control is possible. Provide rope heat treatment technology that can be incorporated into the rope. A steam supply unit B that generates and supplies high-temperature steam, a heat treatment chamber 1 that creates a high-temperature and high-humidity atmosphere around the rope R by the supplied water vapor, and a tension while sequentially feeding the rope R that is passed through the heat treatment chamber 1 And a rope processing unit 10 for applying. When tension is applied to the rope R in a high-temperature steam atmosphere, the strength and abrasion resistance of the rope R are improved. In particular, the effect is remarkable in ropes made of ultra high molecular weight polyethylene.

Description

  The present invention relates to a rope heat treatment method, a heat treatment facility, and a rope. More specifically, the present invention relates to a rope heat treatment method mainly composed of synthetic fibers used in various industrial fields, equipment used in the method, and a rope made by the method.

The process from the fiber yarn to the rope is mainly as follows.
(1) Twisted wire process for processing raw yarn into yarn, strand, rope (2) Resin processing and drying process for strand and twisted rope (3) Heat treatment process for preventing deformation of fiber rope (4) Inspection process of raw materials, processes, products, etc. Among the above, the performance of the fiber rope is almost dependent on the performance of the raw fiber, but the resin processing, drying process and heat treatment process are also (i) the diameter and length of the rope It is an important process for the purpose of (1) making the rope uniform, (2) increasing or decreasing the rope elongation to some extent, and (3) making the rope easy to use.
However, it is known that the heat treatment step described above may be necessary or unnecessary depending on the type of raw yarn.
That is, “Nylon rope and polyester rope return to their original state only by twisting them, so heat treatment is necessary to stabilize the rope twisting and prevent deformation, and polyethylene ropes and polypropylene ropes are not specially heat treated. "It's okay" is the current common sense of technology (see Non-Patent Document 1).
As for the above heat treatment method, conventionally, a dielectric heating method or a hot water immersion method has been used (see Non-Patent Document 2).
The dielectric heating method is a method in which rotational vibration is applied to molecules in a rope by the electric force of a high-frequency electromagnetic field, and heating is performed using heat generated by friction between adjacent molecules. The maximum temperature reaches 130 to 150 ° C., and even a thick rope can be heated uniformly both inside and outside. However, it can be applied to nylon and polyester, but cannot be applied to composite ropes using olefinic fibers such as polyethylene and polypropylene having no polarity in the molecule, steel wire, lead and the like.
In addition, on the equipment side of the heat treatment equipment, the matching between the oscillation part and the load (rope) influences the processing capacity, the electrode structure and capacity must be dedicated within the rope size range, and the heat treatment temperature cannot be measured. There are drawbacks such as inability to precisely control the temperature.
The hot water immersion method is a method in which a rope is immersed in a bath of high-temperature water obtained by heating with a heater or steam. However, the heating temperature of this system is only 100 ° C. or less at maximum, and only those having a low softening point such as polyethylene can be treated.
Moreover, in terms of the equipment of the heat treatment apparatus, there are disadvantages such that the time required for the heat treatment must be immersed (stretched), so that the apparatus becomes large and a drying process is necessary.
Heibonsha Encyclopedia, Volume 15, 1196, published on June 28, 1985, Heibonsha Rope knowledge August 28, 1993 Revised first edition issued Tokyo Maritime Co., Ltd.

In view of the above circumstances, the present invention can dramatically increase the heating temperature, greatly improve the strength and wear resistance of the obtained rope, and can be applied not only to synthetic fiber ropes but also to composite ropes using different raw materials. An object of the present invention is to provide a rope heat treatment technique that enables precise temperature control and can be incorporated into a steelmaking machine.
The rope heat treatment method of the first invention is characterized in that tension is applied to the rope in a high-temperature steam atmosphere.
According to the heat treatment method of the first invention, water vapor can be heated to a high temperature of up to about 1000 ° C., so that the effect of aligning the rope elements is enhanced, and the rope strength and wear resistance are improved. It can be applied not only to synthetic fiber ropes but also to composite ropes using different raw materials. Furthermore, since the temperature of water vapor can be precisely controlled, the temperature can be selected according to the type of raw yarn. Moreover, since it becomes almost complete oxygen-free atmosphere, carbonization does not occur.
The rope heat treatment facility according to the second aspect of the invention includes a water vapor supply section that generates and supplies high-temperature water vapor, a heat treatment chamber that creates a high-temperature and high-humidity atmosphere around the rope by the supplied water vapor, and is passed through the heat treatment chamber. The heat treatment apparatus includes a rope processing unit that applies tension while sequentially feeding the rope.
According to the heat treatment equipment of the second invention, in addition to producing the effects of the first invention, the heat treatment part and the steam supply part can be separated and only the heat treatment part can be incorporated into the steelmaking machine. Processing facilities become possible, and space for manufacturing facilities can be saved.
The rope of the third invention is characterized in that a synthetic fiber rope obtained by a stranded wire process, or a rope obtained by mixing different raw materials with a synthetic fiber is heat-treated in a high-temperature steam atmosphere under tension. To do.
As a result of reflecting the effect of the first invention, the rope of the third invention has the advantage that the strength and the wear resistance are greatly improved.
The rope of the fourth invention is characterized in that, in the third invention, the rope is mainly composed of polyethylene.
According to the fourth invention, contrary to the technical common sense that heat treatment is not required, a polyethylene rope with improved tensile strength can be obtained by performing heat treatment.
The rope of the fifth invention is characterized in that, in the third invention, the rope is mainly composed of ultrahigh molecular weight polyethylene.
According to the fifth aspect of the invention, an ultrahigh molecular weight polyethylene rope having significantly improved tensile strength and wear resistance can be obtained by appropriately selecting the heat treatment temperature.

FIG. 1 is a principle diagram of a heat treatment method according to the present invention.
FIG. 2 is an explanatory diagram of the heat treatment apparatus A in the heat treatment facility of the present invention.
FIG. 3 is a circuit diagram of the heat treatment facility of the present invention.
FIG. 4 is an explanatory diagram of the wear test.

なお、上記表１において、Ｄは繊度の単位デニールを意味し、「打」はストランド数を示している。
（引張試験）
前記実施例１，２について３回の引張試験を行った（試験例１〜３）。各試験例１〜３の結果と平均値は下表２のとおりである。

なお、上記表２において、ＫＮとは引張力の単位キロニュートンである。
上記の結果から、以下のことが分かる。
（１）実施例１，２に共通するが、無処理ロープに対して熱処理されたロープは、どの加熱温度の場合も、引張強度が向上している。これは加熱延伸されることにより撚り糸の引き揃え効果が高くなったことによると考えられる。
（２）実施例１のポリプロピレン製ロープは、無処理に対し熱処理した場合の引張強度向上は認められるが、処理温度相互間の引張強度の相違は認められない。
（３）実施例２の超高分子量ポリエチレン製ロープは、無処理に対し熱処理した場合の引張強度向上が認められる点は実施例１と同様であるが、これに加え、熱処理温度間の相違が認められる。すなわち、熱処理温度１１５℃に比較し１４０℃処理ではさらに１０％強の引張強度の向上が認められる。
（磨耗試験）
磨耗試験は、図４に示す摩耗試験機を用いて行った。ロープＲの途中を、３９０ｍｍの間隔をあけて配置した２個のガイドローラ３１，３２に渡し掛け、ロープＲの一端を直径５５０ｍｍの円板３３に取付け、ロープの他端に１０ｋｇの重鍾３４を取付けた。２個のガイドローラ３１，３２の間に摩擦面を設置し、前記円板３１をモータで回転させ、ロープＲに５００ｍｍのストロークで往復させた。
摩擦面は、４ｍｍ×５０ｍｍの２本のアングル材３５，３６を並べて、一方のアングル材３６の上面には、サンドペーパー３７（８０番）を置き、ロープＲをアングル材３５のエッジとサンドペーパーで摩擦するようにしたものである。
試験要領は、つぎのとおりである。
ストロークが５００ｍｍで、１分間に８往復させ、ロープＲが１往復する毎に新しい面が接するようにサンドペーパー３７を移動させ、各２５０回往復させた。
なお、ロープＲより発生する摩擦熱を冷却させる目的で工業用扇風機で常時冷却し、湿度による接触面の乾燥の均一を図る目的で工業用ドライヤー工業用扇風機を使用した。試験機の構造上ロープＲの接触面は同一面上を接触させた。
上記磨耗試験を５回行い（試験例１〜５）、試験後の引張強度（以下、残存強度という）を各試験例１〜５について計測した。それぞれの結果と平均値は、下表３のとおりである。

上記の結果から、以下のことが分かる。
（１）実施例１のポリプロピレン製ロープでは、熱処理の有無によって残存強度の違いはほとんど認められず、残存率（試験前の引張強度に対する試験後の引張強度の割合）も４７〜５３％で有意差は認められないものである。
（２）実施例２の超高分子量ポリエチレン製ロープは、無処理に対し熱処理温度１１５℃のロープで１．１〜１．２倍に強度向上が認められるが、注目すべきは、熱処理温度１４０℃の場合で、実に１．５倍以上に残存強度が向上していることである。このように、とくに超高分子量ポリエチレン製のロープでは、本発明の熱処理による耐摩耗性の向上が顕著に認められるのである。
この根拠としては、ロープ原料の融点以上に高温にできることから、ロープの表面（樹脂も含む）が溶け、その後冷却することにより、ロープ表面が硬化することによるものと考えられる。
すなわち、実施例２のロープは、撚り線工程においても、ストランドの状態とロープの状態のときにポリウレタンなどの樹脂を含浸させている。ロープの摩擦による切断は、繊維間の摩擦として発現して切れにつながるのであるが、含浸させた樹脂が融点を異にしていることにより、繊維の摩擦により生じた熱の移動が生じて冷却作用が生じることから、耐摩性が向上しているのである。これに加え、本発明の熱処理を行うと、上記の理由で耐摩耗性がさらに向上するものと考えられる。Next, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a principle diagram of a heat treatment method according to the present invention.
Reference numeral 1 denotes a heat treatment chamber, which is a cylindrical member having an opening through which a rope passes at both ends. In the heat treatment chamber 1, superheated water vapor is injected at normal pressure. The temperature of the water vapor is up to about 1000 ° C., but is usually used up to about 500 ° C.
When the rope R is passed through the superheated steam atmosphere in the heat treatment chamber 1 while applying tension, heat treatment can be performed.
The ropes to which the heat treatment method of the present invention can be applied are synthetic ropes in general. It can also be applied to composite ropes in which different raw materials are combined with synthetic fibers.
Synthetic fiber rope materials include nylon, polyester, acrylic, vinylon, polyvinyl chloride, vinylidene, polyurethane, polyclar, benzoate, polyethylene, and polypropylene.
Examples of the different raw materials to be combined with the synthetic fiber raw material include metal, lead, and various other materials.
In particular, for polyethylene ropes and polypropylene ropes, it has been conventionally recognized that there is no need for heat treatment, but with knowledge that overturns the conventional common knowledge of the present invention, by appropriately selecting the heat treatment temperature, the tensile strength and The remarkable effect that the friction resistance is obtained is obtained.
Water vapor can be heated to a high temperature of about 1000 ° C. at normal pressure, and can be reasonably heated up to about 500 ° C. In this way, the higher the temperature is heated, the more external force applied to the rope acts on each part in the rope, so that the effect of aligning the rope elements increases and the rope strength improves. In particular, for polyethylene ropes and polypropylene ropes, heat treatment itself was conventionally not necessary as described above. However, as will be described in detail later in the examples, an effect of improving tensile strength was recognized, and the ultra high molecular weight was further increased. For polyethylene ropes, improved wear resistance is also observed.
Moreover, since heating with water vapor is not limited by materials, it can be applied not only to synthetic fiber ropes but also to composite ropes in which different raw materials are combined.
Furthermore, since the temperature of water vapor can be precisely controlled, an optimum heating temperature can be selected according to the type of raw yarn. In addition, since the atmosphere is almost completely oxygen-free, there is no accident of carbonization of the rope.
FIG. 2 is an explanatory view of the heat treatment apparatus A in the heat treatment facility of the present invention.
A main component of the heat treatment apparatus A is a heat treatment chamber 1, and this heat treatment chamber 1 includes a cylindrical chamber 1a and seal fittings 1b attached to both ends thereof. The seal fitting 1b is used to pass the rope R and to seal the inside of the chamber 1a as much as possible. The rope R is put into the chamber 1a through the seal fitting 1b.
A steam supply pipe 2 is connected to the heat treatment chamber 1, and an opening / closing valve 3 is interposed in the steam supply pipe 2. This on-off valve 3 is a manual type and is used to control the on / off of water vapor at the beginning and end of the heat treatment operation.
Reference numeral 4 denotes a coupler for connecting to a steam supply unit B side described later.
An open / close valve 5 for introducing compressed air is attached to the chamber 1a. This on-off valve 5 is for forced cooling of the heat treatment chamber 1 and is used, for example, to lower the chamber temperature when the heat treatment operation is stopped.
Reference numeral 6 denotes a suction pipe connected to the two seal fittings 1b. The suction pipe 10 is provided for recovering the treated water vapor and returning it to the raw water. Reference numeral 10 denotes a rope processing unit, which is configured as follows.
An entrance capstan roll 11 is installed near the entrance of the heat treatment chamber 1. The capstan roll 11 is a set of two sheaves 12 and 13, and is provided with a resistance to tension by winding the rope R several times. An exit capstan roll 14 is installed near the outlet of the heat treatment chamber 1. The capstan roll 14 is a set of two sheaves 15 and 16, and is provided with resistance against tension by winding the rope R several times.
The rope R wound around the capstan roll 11 on the inlet side is guided by the guide sheave 17, passed through the heat treatment chamber 1, and the rope R that has come out is wound up by the capstan roll 14 on the outlet side. If the winding amount of the roller 14 is made larger than that of the capstan roll 11 on the entry side, the rope R tension can be applied continuously.
Since this device is a compact device composed of a chamber and a capstan roll as described above, it can be installed on the exit side of the steelmaking machine S, and is incorporated on the same line to increase production efficiency. Can do.
Note that the heat-treated rope R wound around the outlet capstan roll 14 may be wound around a winding drum 18 installed at an appropriate place, and then sent to the inspection process.
FIG. 3 is a circuit diagram of the heat treatment facility according to the present invention, which is mainly composed of a heat treatment apparatus A and a steam supply unit B.
The mechanical configuration of the heat treatment apparatus A is as described above, and the circuit configuration is supplemented as follows.
A suction fan 7 is connected to the suction pipe 6 connected to the heat treatment chamber 1, and the treated water vapor in the heat treatment chamber 1 is sucked by the suction fan 7. The sucked water vapor may be released as it is, or may be reused as cooling water or boiler feed water.
The heat treatment chamber 1 is provided with a heater 8 using a heating wire. The heater 8 is heated when the heat treatment chamber 1 is started up and is kept warm so that the water vapor temperature of the supplied water does not decrease. Reference numeral 9 denotes a thermostat interposed in the power supply path of the heater 8.
Next, the steam supply unit B will be described.
A boiler 21 heats the supplied water to generate water vapor. The water vapor is reduced in pressure from about 0.4 MPa to about 0.05 MPa by the pressure reducing valve 22 and supplied to the header 23. The electromagnetic valve 24 controls the supply / cutoff of water vapor to the heater 25. A high frequency oscillator 26 is attached to the heater 25, and the water vapor is directly heated by electromagnetic induction heating to make the temperature higher. As a result, superheated steam is obtained. The temperature of the superheated steam is about 1000 ° C. at maximum, but it is usually operated at about 500 ° C. This temperature control can be executed precisely by adjusting the output of the high-frequency oscillator 26 or the like.
A cooling pipe 27 for passing cooling water is attached to the heater 25. The amount of water in the cooling pipe 27 prevents the heater 25 from rising above the limit. A steam line 29 for sending superheated steam from the heater 25 to the heat treatment chamber 1 is composed of a pipe or a hose and is connected to the steam supply pipe 2 via the coupler 4.
A cooling water pump 28 supplies water to the cooling pipe 27 and the boiler 21. The cooling water is taken from a water supply tank (not shown), and the water that has cooled the heater 25 is returned to the water supply tank.
Since the steam supply unit B of the present embodiment has the above-described configuration, heated steam in a wide temperature range can be created by adjusting the steam supply amount from the boiler 21 and the heating amount of the heater 25. . For example, although the maximum is up to 1000 ° C., the temperature can be as high as 500 ° C. even under normal operating conditions. Therefore, the ropes of various materials can be heat-treated by applying an optimum temperature range.
Further, since the opening degree of the electromagnetic valve 24 and the heating temperature of the heater 25 can be finely adjusted, it is possible to precisely control the water vapor temperature supplied to the heat treatment chamber 1. Therefore, the quality control of the rope can be performed at a high level.
Furthermore, since the steam supply part B can be connected to the heat treatment apparatus A by the coupler 4, the steam supply part B may be located at any position away from the heat treatment apparatus A, so that the degree of freedom in equipment layout is improved. . For this reason, as described above, the heat treatment apparatus A can be installed on the exit side of the steelmaking machine.
Next, as a performance test of the rope obtained by the present invention, a test of tensile strength and wear resistance was performed, and the results will be described next.
The ropes subjected to the performance test are a polypropylene rope (Example 1) and an ultra high molecular weight polyethylene rope (Example 2), and the specifications are as shown in Table 1 below.
Ultra high molecular weight polyethylene is a kind of polyethylene, and its chemical structure is represented by (—CH ₂ —CH ₂ —) _n [molecular weight: about 4 million, —CH ₂ is about 300,000 units linked], and the density is 0.97 g / cm ² . For example, there is a trade name “Dyneema” manufactured by Toyobo Co., Ltd.

In Table 1, D means unit denier of fineness, and “striking” indicates the number of strands.
(Tensile test)
Three tensile tests were performed on Examples 1 and 2 (Test Examples 1 to 3). The results and average values of Test Examples 1 to 3 are as shown in Table 2 below.

In Table 2, KN is a unit of tensile force in kilonewtons.
From the above results, the following can be understood.
(1) Although common to Examples 1 and 2, the tensile strength of the rope heat-treated with respect to the untreated rope is improved at any heating temperature. This is considered to be due to the fact that the effect of aligning the twisted yarns is enhanced by heating and stretching.
(2) The polypropylene rope of Example 1 shows an improvement in tensile strength when heat-treated without treatment, but no difference in tensile strength between treatment temperatures.
(3) The ultra-high molecular weight polyethylene rope of Example 2 is the same as Example 1 in that an improvement in tensile strength is observed when heat-treated without treatment, but in addition, there is a difference between the heat treatment temperatures. Is recognized. That is, an improvement in the tensile strength of more than 10% is recognized in the 140 ° C. treatment as compared with the heat treatment temperature of 115 ° C.
(Abrasion test)
The wear test was performed using a wear tester shown in FIG. The middle of the rope R is passed over two guide rollers 31 and 32 arranged at an interval of 390 mm, one end of the rope R is attached to a circular plate 33 having a diameter of 550 mm, and a 10 kg weight 34 is attached to the other end of the rope. Installed. A friction surface was installed between the two guide rollers 31 and 32, the disk 31 was rotated by a motor, and reciprocated on the rope R with a stroke of 500 mm.
The friction surface is composed of two 4 mm × 50 mm angle members 35, 36. Sandpaper 37 (No. 80) is placed on the upper surface of one angle member 36, and the rope R is attached to the edge of the angle material 35 and the sandpaper. It is made to rub with.
The test procedure is as follows.
The stroke was 500 mm, and reciprocated 8 times per minute. Each time the rope R reciprocated, the sandpaper 37 was moved so that a new surface contacted, and reciprocated 250 times.
In addition, it was always cooled with an industrial fan for the purpose of cooling the frictional heat generated from the rope R, and an industrial dryer industrial fan was used for the purpose of achieving uniform drying of the contact surface due to humidity. Due to the structure of the testing machine, the contact surface of the rope R was brought into contact with the same surface.
The above wear test was performed 5 times (Test Examples 1 to 5), and the tensile strength after the test (hereinafter referred to as residual strength) was measured for each of Test Examples 1 to 5. The respective results and average values are as shown in Table 3 below.

From the above results, the following can be understood.
(1) In the polypropylene rope of Example 1, there is almost no difference in residual strength depending on the presence or absence of heat treatment, and the residual rate (ratio of tensile strength after test to tensile strength before test) is also significant at 47 to 53%. There is no difference.
(2) The ultrahigh molecular weight polyethylene rope of Example 2 is 1.1 to 1.2 times stronger than the untreated rope at a heat treatment temperature of 115 ° C., but it should be noted that the heat treatment temperature is 140. In the case of ° C., the residual strength is actually improved 1.5 times or more. Thus, particularly in the rope made of ultra high molecular weight polyethylene, the improvement in wear resistance by the heat treatment of the present invention is remarkably recognized.
The reason for this is considered to be that the surface of the rope (including the resin) is melted and then cooled, and then the rope surface is hardened by cooling since the temperature can be higher than the melting point of the rope raw material.
That is, the rope of Example 2 is impregnated with a resin such as polyurethane in the strand state and the rope state even in the stranded wire process. Cutting by rope friction is manifested as friction between fibers, leading to breakage, but because the impregnated resin has a different melting point, heat transfer caused by fiber friction occurs and cooling action occurs. Therefore, the wear resistance is improved. In addition to this, it is considered that when the heat treatment of the present invention is performed, the wear resistance is further improved for the above-mentioned reason.

  The present invention can be used for ropes in all industrial fields such as land use and marine use.

Claims (5)

A rope heat treatment method characterized by applying tension to a rope in a high-temperature steam atmosphere. A steam supply section that generates and supplies high-temperature steam, a heat treatment chamber that creates a high-temperature and high-humidity atmosphere around the rope by the supplied steam, and a rope treatment that applies tension while sequentially feeding the rope passed through the heat treatment chamber Heat treatment equipment for a rope, comprising a heat treatment device having a section. A rope obtained by heat-treating a rope made of synthetic fiber obtained by a stranded wire process, or a rope obtained by mixing different raw materials with synthetic fiber in a high-temperature steam atmosphere. The rope according to claim 3, wherein the rope is made mainly of polyethylene. The rope according to claim 3, wherein the rope is mainly composed of ultra high molecular weight polyethylene.

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