EP0481378A1

EP0481378A1 - Process for producing high strength steel belt

Info

Publication number: EP0481378A1
Application number: EP91117409A
Authority: EP
Inventors: Takashi Igawa; Yoshihiro Uematsu; Toshihiko Takemoto
Original assignee: Nisshin Steel Co Ltd
Current assignee: Nippon Steel Nisshin Co Ltd
Priority date: 1990-10-16
Filing date: 1991-10-11
Publication date: 1992-04-22
Anticipated expiration: 2011-10-11
Also published as: ATE108711T1; JPH04154920A; DE69102969T2; EP0481378B1; DE69102969D1; JP3032273B2

Abstract

A high strength steel belt (1) having an excellent flatness and a duplex structure of austenite and martensite has been prepared by a process which comprises providing a cold rolled or cold rolled and annealed strip of a martensitic structure from low carbon martensitic stainless steel containing from 10 to 17 % by weight of Cr and having a carbon content of not exceeding 0.15 % by weight, connecting ends of the strip or ends of a plate cut from said strip to provide an endless belt, causing the endless belt to circularly move between rolls (2,3) under tension and to repeatedly pass through a heating furnace (4) where the belt is heated to a temperature within the range from (the As point of the steel + 30 °C.) to the Af point of the steel and not higher than 900 °C. so that a part of the martensitic phase may be changed to a reversed austenitic phase, and cooling the heated belt to ambient temperature.

Description

Field of the Invention

The invention relates to a process for the production of a high strength stainless steel belt having a fine duplex structure of martensite and austenite and an excellent flatness.

Background of the Invention

Stainless steel belts are widely used in various fields including, for example, continuous baking of cookies at high temperatures, freezing of foods at low temperatures, continuous pressing of ply wood and transportation of mechanical parts. Since high strength and excellent fatigue strength are required, steel species constituting such belts are generally selected from work hardened austenitic stainless steels, low carbon martensitic stainless steels and precipitation hardened stainless steels. Materials for such steel belts and processes for the production of such steel belts are disclosed in, for example, JP B 51-31085 and JP B 61-9903.
The known processes generally comprise preparing a flat stainless steel strip by a process including a rolling step for shape rectification, welding ends of the flat strip or ends of a plate cut from said strip to provide an endless belt, and again flattening the surface of the endless belt under tension.
Accordingly, to produce a stainless steel belt having a good shape, it has been necessary to prepare a flat stainless steel strip by a process including a rolling step for shape rectification. This step of rolling for shape rectification should be appropriately carried out, while carefully selecting conditions including, for example, rolling reduction, diameters of rolls and rate of rolling, depending upon the steel species, thickness of the strip and histories of the precedent production steps, or otherwise a flat stainless steel strip cannot be obtained or the production yield is reduced. Accordingly, it is eagerly desired to prepare a stainless steel strip excellent in flatness without the rolling step for shape rectification. Unfortunately, the desired technology is not yet established on the concerned steel species.
Even if a flat stainless steel strip has been prepared by rolling for shape rectification, when an endless belt is prepared from the flat strip by end welding, it is unavoidable that a strain due to expansion and contraction of the material is induced near the weld zone as a result of the welding. For this reason, the endless belt so prepared must be again flattened under tension.
Thus, in order to produce a high strength stainless steel belt in a high production yield, precise and complicated steps have been required. Particularly, when a wide steel belt is to be produced, two or more starting plates are longitudinally welded side by side to provide a wide welded plate, which is then made endless by end welding. In such a case, the flattening of the welded wide endless belt under tension is further complicated, time consuming and technically very difficult.

Object of the Invention

An object of the invention is to solve the above discussed problems associated with the prior art

Summary of the Invention

According to the invention, there is provided a process for the production of a high strength steel belt having a duplex structure of austenite and martensite which comprises providing a cold rolled or cold rolled and annealed strip of a martensitic structure from low carbon martensitic stainless steel containing from 10 to 17 % by weight of Cr and having a carbon content of not exceeding 0.15 % by weight, connecting ends of the strip or ends of a plate cut from said strip to provide an endless belt, causing the endless belt to circularly move between rolls under tension and to repeatedly pass through a heating furnace where the belt is heated to a temperature within the range from (the As point of the steel + 30 °C.) to the Af point of the steel and not higher than 900 °C. so that a part of the martensitic phase may be changed to a reversed austenitic phase, and cooling the heated belt to ambient temperature, wherein the As point of the steel is a temperature of the steel of which temperature is being raised at which the transformation of martensite to austenite begins and the Af point of the steel is a temperature of the steel of which temperature is being raised at which the transformation of martensite to austenite is finished.

Function

In the process according to the invention, an endless belt of a martensitic structure spanning rolls under an appropriate tension is caused to circularly move between the rolls, and during the circular movement the belt is caused to repeatedly pass through a heating furnace where it is heated to a temperature within the range from (the As point of the steel + 30 °C.) to the Af point of the steel and not higher than 900 °C. In the furnace a part of the martensite is reveresed to austenite while the belt is under a longitudinal tension. The belt is effectively flattened as the reversion proceeds, even in cases wherein the belt is made of a steel strip prepared by a process without a step of rolling for shape rectification and wherein a step of flattening the endless belt by tension has been eliminated after the welding step.
The reversed austenite grains are fine and so stable that they do not retransform to quenched martensite when cooled to ambient temperature. Thus, the steel belt produced by the process according to the invention has a fine duplex structure of martensite and reversed austenite. The fact that the reversed austenite does not retransform to quenched martensite upon cooling from the heating temperature leads to no strain due to quenching, indicating that the good flatness of the belt achieved in the heating furnace can be retained to ambient temperature.
Thus, a high strength steel belt having a good shape can be easily produced by the process according to the invention wherein an endless belt of a substantially martencitic structure is concurrently flattened and transformed to a duplex structure by the heat treatment prescribed herein. The endless belt may be made of a steel strip prepared by a process without a step of rolling for shape rectification, although it may be made of a shape-rectified steel strip.
For the function described above to proceed, it is sufficient that the steel prior to the heat treatment has a substantially martensitic structure. The presence of a small amount, for example, up to 20 % by volume of ferrite or austenite is permissible.
The basic concept of the invention is to produce a high strength steel belt excellent in flatness by forming a fine duplex structure of martensite and fine reversed austenite upon heating and maintaining the fine duplex structure to ambient temperature. In other words, the invention achieves a high strength by making the structure fine as known from the Hall-Petch'es formula, and realizes a tension annealed condition to ensure a good shape by causing the reversion to proceed while relaxing the flattening tension on the material passing through the heating furnace. Accordingly, it is essential to form a stable, fine duplex structure. If the heat treatment temperature is substantially lower than (the As point of the steel + 30 °C.), the amount of the reversed austenite is insufficient, and if the heat treatment temperature is higher than 900 °C.or the Af point of the steel, no martensite is retained or the amount of the retained martensite becomes too small, and thus, the desired stable and fine duplex structure is not obtained.

Brief Description of the Drawings

Fig. 1 is a schematic cross-sectional view of a heat treatment installation which can be used in the process according to the invention;
Fig. 2 is a perspective view of a strip for illustrating an LD shape value used herein; and
Fig. 3 a perspective view of a strip for illustrating a TD shape value used herein.

Preferred Embodiments of the Invention

Fig. 1 shows an example of a heat treatment installation which can be used in carrying out the process according to the invention. An endless belt 1 which is made from a martensitic stainless steel and spans rolls 2 and 3 is caused to circularly move between the rolls by driving one of them. A heat treating furnace 4 is provided so that the circularly moving endless belt 1 may repeatedly pass through the furnace 4. The furnace 4 may be provided on its belt exit side with an air jet nozzle 5 which may serves to cool the heat treated belt when desired. While the furnace 4 is conveniently heated electrically, it may be heated by fuel combustion as well. The atmosphere of the furnace may be air, but if oxidation of the belt should be avoided, reducing or inert gas may be used.
The endless belt 1 may be prepared by cutting out a starting material plate having a required length from a martensitic steel strip, and welding ends of the plate. In some cases ends of the plate may connected by rivetting. When a wide belt is desired, it may be prepared by longitudinally welding two or more starting plates side by side and welding ends of the so welded wide plate to make it endless. The martensitic steel strip from which the endless belt 1 is prepared may be one that has not been subjected to a rolling step for shape rectification. Furthermore, the endless belt 1 need not be mechanically shape rectified prior to the heat treatment according to the invention. The endless belt can be flattened by the heat treatment according to the invention.
The endless belt 1 is hung between rolls 2 and 3 under an appropriate tension and caused to circularly move between the rolls. A suitable tension is 0.5 kgf/mm² or higher when the heat treatment temperature used is relatively low (near the As point + 30 °C.). Whereas when the heat treatment temperature used is near the Af point a relatively low tension below 0.5 kgf/mm² is preferred. The lower the heat treatment temperature the longer the heat treatment time, and the higher the heat treatment temperature the shorter the heat treatment time. While the optimum tension and heat treatment time depend upon the particular composition of the steel and the particular heat treatment temperature, they should be selected so that a part of the martensite may be reversed to austenite to provide a fine duplex structure and the belt may be flattened during the heat treatment. These conditions can be determined by carrying out several experiments on the particular steel.
By the heat treatment of the endless belt under tension according to the invention a desirably fine duplex structure is realized and by maintaining the fine duplex structure there can be produced a high strength steel belt excellent in shape, in which the weld zone and mother metal have substantially the same structure and flatness. Accordingly, upon the heat treatment it is essential to form a desirably stable and fine duplex structure. If the heat treatment temperature is substantially lower than (the As point of the steel + 30 °C.), the amount of the reversed austenite is insufficient, and the heat treatment temperature is higher than 900 °C.or the Af point of the steel, a large amount of austenite is formed, retaining no or an insufficient amount of martensite, and thus, the desired stable and fine duplex structure is not obtained. Accordingly, the heat treatment should be carried out at a temperature within the range from (the As point of the steel + 30 °C.) to the Af point of the steel and not higher than 900 °C.
The steel used herein is substantially martensitic in the annealed condition. The structure of the endless belt prior to the heat treatment should be substantially martencitic. The endless belt can be prepared from an annealed steel strip which has been made martensitic in the final annealing step, a cold rolled steel strip prepared by finish cold rolling the above mentioned annealed steel strip, or a cold rolled strip in which strain induced martensite has been formed by cold rolling. The structure of the belt prior to the heat treatment need not be 100 % martencitic. The presence of a minor amount, for example, up to 20 % by volume, of ferrite or austenite is permissible. In any event, it is intended that the belt should have a tensile strength as high as the order of 100 kgf/mm² or higher in the heat treated condition.
As to the chemical composition, the steel used herein is a low carbon martensitic stainless steel containing from 10 to 17 % by weight of Cr and having a carbon content of not exceeding 0.15 % by weight. Ni can also be a principal alloying element. Furthermore, the steel may contain other alloying elements normally contained in low carbon martensitic stainless steel.
Typical alloying elements and contents thereof by weight are as follows:

C: : 0.15 % or less (exclusive 0),
Si: : 6.0 % or less (exclusive 0),
Mn: : 10.0 % or less (exclusive 0),
Ni: : 8.0 % or less (exclusive 0),
Cr: : 10.0 to 17.0 %,
N: : 0.3 % or less (exclusive 0),
Mo: : 4.0 % or less (inclusive 0),
Cu: : 4.0 % or less (inclusive 0),
Co: : 4.0 % or less (inclusive 0).

In addition, the steel used herein may contain Ti, Al, Nb, V, Zr, B and rare earth elements in an amount of 1.0 % or less in total, and unavoidable impurities.
Furthermore, amounts of the alloying elements are mutually controlled so that the nickel equivalent, Ni_eq, of the steel may fall within the range between 8.0 and 17.5. The nickel equivalent, Ni_eq, of the steel is defined as follows.

${Ni}_{eq} = Ni + Mn + Cu + Mo + 0.2Co + 0.5Cr + 0.3Si + 20(C + N)$
,

in the case wherein the steel contains none of Ti, Al, Nb, V, Zr, B and rare earth elements, whereas

${Ni}_{eq} = Ni + Mn + Cu + Mo + 0.2Co + 0.5Cr + 0.3 Si$

in the case wherein the steel contains any one of Ti, Al, Nb, V, Zr, B and rare earth elements.
The reasons for such numerical restriction are as noted below.
C is an austenite forming element and serves not only to effectively stabilize the reversed austenitic phase formed during the heat treatment according to the invention at a temperature within the range from (the As point of the steel + 30 °C.) to the Af point of the steel but also to effectively strengthen the martensite and reversed austenite phases. However, the presence of an excessive amount of C results in the formation of Cr carbide during the heat treatment step which Cr carbide may impair the corrosion resistance of the steel. Accordingly, the upper limit of C is set herein as 0.15 %.
Cr is a basic alloying element of stainless steels, and at least 10.0 % of Cr is required to achieve a satisfactory corrosion resistance. However, since Cr is a ferrite forming element, the presence of an excessive amount of Cr results in the formation of a quantity of δ ferrite, and therefore, in the production of the starting strip, it is difficult to achieve a substantially martensitic phase after annealing and cooling to ambient temperature. Accordingly, the upper limit of Cr is set herein as 17.0 %.
Ni is an austenite forming element and serves to effectively stabilize the reversed austenitic phase formed during the heat treatment according to the invention at a temperature within the range from (the As point of the steel + 30 °C.) to the Af point of the steel. However, if the Ni content is unduly high, in the production of the starting strip, it is difficult to achieve a substantially martensitic phase after annealing and cooling to ambient temperature. Accordingly, the content of Ni is preferably 8.0 % or less.
Si acts to broaden the temperature range between the As and Af points. This is advantageous in obtaining a stable duplex structure of austenite and martensite. Si further serves to effectively strengthen the martensitic and reversed austenitic phases formed in the heat treatment according to the invention. However, the production of a steel strip having an unduly high Si content is not easy. Accordingly, the content of Si is preferably 6.0 % or less.
Mn is an austenite forming element and serves to effectively stabilize the reversed austenitic phase formed during the heat treatment according to the invention at a temperature within the range from (the As point of the steel + 30 °C.) to the Af point of the steel. However, if the Mn content is unduly high, there happens such a trouble that Mn fume is formed in the production of such a high Mn steel by melting. Accordingly, the content of Mn is preferably 10.0 % or less.
N is an austenite forming element as C is and serves not only to effectively stabilize the reversed austenitic phase formed during the heat treatment according to the invention at a temperature within the range from (the As point of the steel + 30 °C.) to the Af point of the steel but also to effectively strengthen the martensitic and reversed austenitic phases. However, the presence of an excessive amount of N results in the formation of blow holes in the production of such a high N steel by melting, and thus does not provide a sound ingot. Accordingly, the content of N is preferably 0.30 % or less.
Mo serves not only to enhance the corrosion resistance of the steel but also to effectively strengthen the martensitic and reversed austenitic phases formed in the heat treatment according to the invention. However, since Mo is a ferrite forming element, the presence of an excessive amount of Mo results in the formation of a quantity of δ ferrite, and therefore, in the production of the strip, it is difficult to achieve a substantially martensitic phase after annealing and cooling to ambient temperature. Accordingly, the content of Mo is preferably 4.0 % or less.
Cu is an austenite forming element as Ni is and effective in the formation of austenite during the heat treatment according to the invention. However, the presence of an excessive amount of Cu adversely affects the hot workability of the steel. Accordingly, the content of Cu is preferably 4.0 % or less.
Co is an austenite forming element as Ni is and effective in the formation of austenite during the heat treatment according to the invention. However, since Co is expensive, the content of Co is preferably 4.0 % or less.
Ti, Al, Nb, V and Zr are effective not only in maintaining the stable, fine and uniform duplex structure of martensite and reversed austenite but also in suppressing the formation of Cr carbide to maintain the corrosion resistance. However, since the presence of unduly high amounts of these elements adversely affects the easiness of the production of the steel strip, the amounts of these elements are preferably 1.0 % or less in total.
As already discussed, in the process according to the invention, a high strength steel belt having excellent fatigue properties can be produced by reversing a part of martencite to fine austenite to form a fine duplex structure and maintaining the fine duplex structure. Accordingly, it is essential to form a stable fine duplex structure. If the nickel equivalent, Ni_eq, of the steel is substantially below 8.0, the amount of austenite reversed during the heat treatment at a relatively low temperature within the range of between (the As point + 30 °C.) and the Af point is insufficient, and if Ni_eq is substantially higher than 17.5, the amount of inverse formed austenite becomes excessively large, and thus, it becomes difficult to realize the desirably stable and fine duplex structure. Accordingly, amounts of alloying elements of the steel are preferably adjusted so that the nickel equivalent, Ni_eq, of the steel may fall within the range between 8.0 and 17.5.

Examples

Each steel having a composition indicated in Table 1 was prepared by melting, forged, hot rolled to a thickness of 6 mm, solution treated, pickled, cold rolled, annealed, and finish cold rolled to a thickness of 1 mm. For a purpose of confirming a beneficial effect of shape rectification during the heat treatment according to the invention, cold rolling conditions used were willfully selected so that a cold rolled material having a bad shape might be obtained. Some of the finish cold rolled strips were annealed at a temperature of 1030 °C. and pickled. A starting material plate was cut from each strip so prepared, and ends of the plate were welded together by TIG welding to provide an endless belt having a width of 300 mm and a length of 5 m, which was subjected to the heat treatment according to the invention as described below. Table 1 indicates the As and Af transformation points of the steels tested as well. These transformation points were determined from inflection points of a temperature-electrical resistance curve obtained on each steel the temperature of which was being raised at a rate of 1 °C./min. in an electrical resistance measuring device.
Each belt was heat treated in a heat treatment installation as shown in Fig. 1 under conditions indicated in Table 2. The heat treatment time shown in Table 2 is the total of the time for which the belt travelled through the heating furnace.

$Heat treatment time = Time of circular movement of belt$
$× Effective length of furnace/Length of belt (5 m)$
After the heat treatment a specimen was taken from the heat treated belt and tested for the proof strength and tensile strength. Furthermore, the shape of the belt was examined before and after the heat treatment. Results are shown in Table 2, wherein the LD shape value is a height of an undulation h (mm) divided by a length 1 (mm) in the rolling direction, as shown in Fig. 2, while the TD shape value is a height of an undulation h (mm) divided by a width 1 (300 mm) of the belt, as shown in Fig. 3.
From the results shown in Table 2, it is understood that all belts prepared by the process according to the invention have a high strength represented by the proof strength as high as at least 80 kgf/mm² and an excellent shape represented by an LD shape value of not in excess of 2.5/1000 and a TD shape value of not in excess of 1/300. In contrast, belts prepared in control Runs Nos. 2, 6, 9 and 14 outside the scope of the invention are unsuitable as a high strength steel belt because of their bad shape or low strength.

Effect of the Invention

By the process according to the invention both the properties, flatness and high strength essential in a stainless steel belt, can be concurrently achieved in the step of heat treatment after welding. This means that a steel strip prepared by a process without a step of rolling for shape rectification or a plate cut from such a strip may be used as a starting material for the production of the steel belt, and that steps of flattening by tension before and after the welding step may be eliminated. Accordingly, the invention greatly contributes to saving process steps and enhancing production yields. Furthermore, the production of a wide steel belt including a step of longitudinally welding two or more starting material plates side by side can also be easily carried out by the process according to the invention.

Claims

A process for the production of a high strength steel belt having a duplex structure of austenite and martensite which comprises providing a cold rolled or cold rolled and annealed strip of a martensitic structure from low carbon martensitic stainless steel containing from 10 to 17 % by weight of Cr and having a carbon content of not exceeding 0.15 % by weight, connecting ends of the strip or ends of a plate cut from said strip to provide an endless belt, causing the endless belt to circularly move between rolls under tension and to repeatedly pass through a heating furnace where the belt is heated to a temperature within the range from (the As point of the steel + 30 °C.) to the Af point of the steel and not higher than 900 °C. so that a part of the martencitic phase may be changed to a reversed austenitic phase, and cooling the heated belt to ambient temperature, wherein the As point of the steel is a temperature of the steel of which temperature is being raised at which the transformation of martensite to austenite begins and the Af point of the steel is a temperature of the steel of which temperature is being raised at which the transformation of martensite to austenite is finished.
The process according to claim 1 wherein the endless belt contains up to 20 % by volume of a ferritic or austenitic phase before it is caused pass through the heating furnace.
The process according to claim 1 or 2 wherein the stainless steel contains, in addition to Cr and C, up to 8.0 % by weight of Ni, up to 6.0 % by weight of Si, up to 10.0 % by weight of Mn and up to 0.3 % by weight of N.