Indian Patents. 195232:" A MEHOD OF MANUFACTURING HIGH-TOUGHNESS OIL-TEMPERED WIRE"

Title of Invention	" A MEHOD OF MANUFACTURING HIGH-TOUGHNESS OIL-TEMPERED WIRE"
Abstract	A method of manufacturing high-toughness oil-tempered wire wherein tempering in a quenching/tempering step is carried out at a heating rate of 150 °C/sec or more at a temperature of 450 °C to 600°C for 15 seconds or less from the start of heating to the start of a cooling step using a coolant such as water.

Full Text	The present invention relates to a method of manufacturing high-toughness oil-tempered wire The present invention relates to an oil- tempered wire, and more specifically an oil-tempered wire having sufficient toughness as a material for high-strength springs used valve springs for automotive engines. Valve springs for automtive engines are used in extremely harsh conditions 18 which they are subjected to high stress and high resp;ved speed In particular, value. serines used in recent car e;tes, which are small in size and consume less fuel, are used in still severer environments. It is therefor desirable to increase the strength of material for such valuve springs still further. valve springs are formed from an oil-tempered wire of chrome-vanadium steel for valve springs or an oil-tempered wire of silicon-chx-ome steel for valve springs. Efforts are being made to increase the strength of these wire materials . But a wire having increased strength tends to be low in toughness and ductility, so that it is liable to be broken while being formed into springs. In order to solve this problt-m. Examined Japanese Publication 3-6981 proposes to control the content of vanadium and the quenching conditions so that the crystal grain size will be 10 or more, thereby keeping high toughness of the wire. For the same purpose, Unexamined Japanese Patent Publication 3-162550 proposes an oil-tempered wire having a tempered martensite, that is, a matrix after tempering, in which is present a residual austenite phase by 5-20%. But in the former, it is impossible to markedly increase the strength and toughness if the crystal grain size is 10 or more. In the latter, if the residual austenite phase is present in a large amount, it may transform into a martensite phase while the wire is used as springs. If this happens, it may suffer a permanent set due to increased volume. That is, such a wire is less resistant to permanent setting. An object of the present invention is to provide an oil-tempered wire for springs which is less likely to suffer a permanent set and high in strength and toughness. As a result of our efforts, we have discovered that it is possible to increase toughness while keeping high resistance to permanent setting by finely dispersing a residual austenite phase in a tempered martensite at a volume rate of 1% to 5% and by controlling the density of unresolved carbides having particle diameters of 0.05µm or more to 5 pieces per wm or less as observed on a structure observation photograph, SUMMARY OF THE INVENTION According to this inventior., Therte is provided a high-toughness oi1-tempered wire for springs made of a steel containing in weight percer C.5-0.81; C, 1.2-2.5°, Si, ( .4-0.8°, Mn, 0.7-1.0% Cr, 0.005", or less Al and 0.0051 or less Ti, the steel containing, after quenching and tempering, 1°0 to 5% by volume of x-. invidul The steel may further contain 0.05-0.15% by weight of vanadiud mm, or further at least one of 0.05-0.5% by weight of Mo, 0.05-0.5% by weight of W and 0 . O5-0 . 15% by weight of !; In another arangement, the assembly of unresolved combodies having particle diameter. not less than 0.05 µm is gleaces per µm or less as observed on a structure observation photo , instead of resiting the content of residual In still another arrangement, both the density of carbides and the content of residual /"are restricted. The present invention also provides a method of nanufacturing oil-tempered wires as described above under specific quenching and tempering conditions. According to the present invention there is provided a method of manufacturing high-toughness oil-tempered wire wherein tempering in a quenching/tempering step is carried out at a heatmg rate of 150 °C/sec or more at a temperature of 450 °C to 600°C for 15 seconds or less from the start of heating to the start of a cooling step using a coolant such as water. Now we will explain wh y the steel composition has been restricted. 1) C: 0.5-0.8 wt.% C is essential to increase the strength of the steel wire. If its content is less than 0.5%, the strength of the wire will be insufficient. On the other hand, a steel wire containing more than 0.8% carbon is low in toughness. Such a wire is not reliable enough because it is more liable to get marred. 2) Si: 1.2-2.5 wt.% Si helps increase the strength of ferrite and thus improve the resistance to permanent set. If its content is less than 1.2%, this effect cannot be achieved sufficiently. If over 2.5%, hot and cold machinability will drop. Also, such a largt; amount will promote decarbonization during heat treatment, 3) Mn: 0.4-0.8 wt.% Mn improves the hardening properties of the steel and prevents any harmful effect caused by suffer in the steel by fixing it. If its content is less than 0.4%, this effect cannot be achieved sufficiently. If over 0.8%, the toughness will drop. 4) Cr: 0.7-1.0 wt.% Like Mn, Cr improves the hardening properties of the steel. It also serves to increase the toughness of the wire by patenting after hot rolling and to increase the resistance to softening during tempering after quenching and thus the strength of the wire. If its content is less than 0.7%, this effect cannot be achieved sufficiently. If over 1.0%, Cr will hinder carbides from turning into solid solution, thus lowering the strength of the wire. Also, such a large amount will cause excessive tempering action, leading to reduced toughness. 5) V: 0.05-0.15 wt.% Vanadium helps the formation of carbides during tempering, thus increasing the resistance to softening of the wire. If its content is less than 0.05%, this effect will be insufficient. If over 0.15%, a large amount of carbides will be formed during heating for quenching, which will lower the toughness of the wire. 6) Mo: 0.05-0.15 wt.% Mo helps the formation of carbides during tempering, thus increasing the resistance to softening of the wire. If its content is less than 0.05%, this effect will be insufficient. If over 0.5%, wire drawing will become difficult. 7) W: 0.05-0.15 wt.% Tungsten helps the formation of carbides during tempering, thus increasing the resistance to softening of the wire. If its content is less than 0.05%, this effect will be insufficient. If over 0.15%, too large an amount of carbides will be formed during heating for quenching so that the toughness of the wire will drop. 8) Mb: 0.05-0.15 wt.% Nb helps the formation of carbides during tempering, thus increasing the resistance to softening of the wire. If its content is less than 0.05%, this effect will be insufficient. If over 0.15%, too large an amount of carbides will be formed during heating for quenching, so that the toughness of the wire will drop. 9) Al, Ti: 0.005 wt.% or less They form AL2O3 and TiO which are high-melting point, non-metallic inclusions. These inclusions are hard and can markedly lower the fatigue strength if present near the steel wire surface. Thus, though they are unavoidable impurities, their contents have to be 0.005 wt.% or less. For this purpose, a raw material containing lesser impurities should be selected. 10) Reason why the content of residual  is restricted to 1-5% by volume A residual  phase present in the tempered martensite improves the toughness of the steel wire. If its content is less than 1%, the effect will be insufficient. But if its content is more than 5%, the resistance to permanent set will decrease due to marten.sitic transformation while the wire is used a spring. 11) Reason why the number of unresolved carbides (0.05 µm or more in particle diameter) is restricted to 5 pieces per µm as observed on a structure observation photo. Unresolved carbides having particle diameters of 0.05 µm or more can be starting points of destruction while forming springs. Thus, if the number of such carbides exceeds 5 pieces per µm2 as observed on a structure observation photo, the toughness of the wire will drop markedly. The content of residual  and the density of carbides can be adjusted to the abovomentioned values by subjecting the wire to the following heat treatment. The heating time for quenching in the quenching/tempering step before the cooling step is started, should be within 15 seconds. Otherwise, crystal grains will grow too large, lowering the toughness of the wire. If the heating rate IS 150°C/sec or lower, it is impossible to resolve carbides sufficiently within the 15-second interval before the cooling step begins. If the heating temperature is 1100 °C or higher, crystal grains will grow too large, thus lowering the toughness or causing decarbonization. If T E °C) is equal to 500 + 750C + 500-V or less (wherein C is the content of carbon in weight % and V is the content of vanadium in weight %), carbides will not be resolved sufficiently. Tempering during the quenching/tempering step has to be finished within 15 seconds before the cooling step is started, while keeping the heating rate at 150 sC/sec or higher. Otherwise, the residual austenite phase will decrease to less than 1% by volume. DETAILED DESCRIPTION OF THE EXAMPLES 4.O-mm-diameter wires were formed by melting, rolling, heat-treating and drawing specimens having the chemical compositions shown in Table 1. After quenching and tempering these wires under predetermined conditions, the amount of residual phase was measured using X-rays, and the amount of carbides was measured by observing the wire structure. Also, they were subjected to a tensile test to measure the toughness in terms of reduction of area. (Example 1) After quenching and tempering Specimens A-I under the conditions shown in Table 2, measurement of residual and a tensile test were carried out. The results for Specimens A, B, C and I are shown in Table 3. The amounts of residual in the specimens manufactured by the method of the present invention were 1-5 vol.%. It is thus apparent that their toughness is sufficiently high. (Example 2) After quenching and tempering Specimens A-I under the conditions shown in Table 4, the amount of carbides (0.05 urn or more) in each specimen was measured, and then the specimens were subjected to a tensile test. The results for Specimens A, Br D and H are shown in Table 5. From Table 5 , it is apparent that the specimens according to Example 2, having 5 or less carbides per square micrometer, are sufficiently tough. As described above, the oil-tempered wire for springs according to the present invention is highly resistant to permanent set and highly strong and tough. TABLE 1 2 (Table Removed) Heating time is the time frets start of heati.-g to start of coiling. TABLE 3 (Table Removed) Residual 7 content and reduction of area TABLE 4 (Table Removed) * Heating time is the time from start of heating to start of cooling. TABLE 5 (Table Removed) (Density of carbides 3rd reduction of area We Claim: - 1. A method of manufacturing high-toughness oil-tempered wire wherein tempering in a quenching/tempering step is carried out at a heating rate of 150 °C/sec or more at a temperature of 450 °C to 600°C for 15 seconds or less from the start of heating to the start of a cooling step using a coolant such as water. 2. A method of manufacturing the high-toughness oil- tempered wire wherein quenching during a quenching/tempering step is carried out by heating to a temperature not higher than 1100°C and not less than a temperature determined by T (°C) = 500 + 750°C + 500°V at a heating rate of 150°C/sec. or more for 15 seconds or less from the start of heating to the start of cooling with water or oil. 3. A method of manufacturing the high-toughness oil- tempered wire wherein quenching during a quenching/tempering step is carried out by heating to a temperature not higher than 1100°C and not less than a temperature determined by T (°C) = 500 + 750°C + 500°V at a heating rate of 150°C/sec. or more for 15 seconds or less from the start of heating to the start of cooling with water or oil and wherein tempering in the quenching/tempering step is carried out at a heating rate of 150°C/sec or more to a temperature of 450°C to 600°C for 15 seconds or less from the start of heating to the start of cooling using a coolant such as water. 4. A method of manufacturing the high-toughness oil-tempered wire substantially as herein described with reference to the foregoing examples.

Full Text

The present invention relates to a method of manufacturing high-toughness oil-tempered wire
The present invention relates to an oil- tempered wire, and more specifically an oil-tempered wire having sufficient toughness as a material for high-strength springs used valve springs for automotive engines.
Valve springs for automtive engines are used in extremely harsh conditions 18 which they are subjected to high stress and high resp;ved speed In particular, value. serines used in recent car e;tes, which are small in size and consume less fuel, are used in still severer environments. It is therefor desirable to increase the strength of material for such valuve springs still further. valve springs are formed from an oil-tempered wire of chrome-vanadium steel for valve springs or an oil-tempered wire of silicon-chx-ome steel for valve springs. Efforts are being made to increase the strength of these wire materials .
But a wire having increased strength tends to be low in toughness and ductility, so that it is liable to be broken while being formed into springs.
In order to solve this problt-m. Examined Japanese Publication 3-6981 proposes to control the content of
vanadium and the quenching conditions so that the crystal grain size will be 10 or more, thereby keeping high toughness of the wire. For the same purpose, Unexamined Japanese Patent Publication 3-162550 proposes an oil-tempered wire having a tempered martensite, that is, a matrix after tempering, in which is present a residual austenite phase by 5-20%.
But in the former, it is impossible to markedly increase the strength and toughness if the crystal grain size is 10 or more. In the latter, if the residual austenite phase is present in a large amount, it may transform into a martensite phase while the wire is used as springs. If this happens, it may suffer a permanent set due to increased volume. That is, such a wire is less resistant to permanent setting.
An object of the present invention is to provide an oil-tempered wire for springs which is less likely to suffer a permanent set and high in strength and toughness.
As a result of our efforts, we have discovered that it is possible to increase toughness while keeping high resistance to permanent setting by finely dispersing a residual austenite phase in a tempered martensite at a volume rate of 1% to 5% and by controlling the density of unresolved carbides having particle diameters of 0.05µm or more to 5 pieces per wm or less as observed on a structure
observation photograph,
SUMMARY OF THE INVENTION
According to this inventior., Therte is provided a high-toughness oi1-tempered wire for springs made of a steel containing in weight percer C.5-0.81; C, 1.2-2.5°, Si, ( .4-0.8°, Mn, 0.7-1.0% Cr, 0.005", or less Al and 0.0051 or less Ti, the steel containing, after quenching and tempering, 1°0 to 5% by volume of x-. invidul
The steel may further contain 0.05-0.15% by weight of vanadiud mm, or further at least one of 0.05-0.5% by weight of Mo, 0.05-0.5% by weight of W and 0 . O5-0 . 15% by weight of
!;
In another arangement, the assembly of unresolved combodies having particle diameter. not less than 0.05 µm is gleaces per µm or less as observed on a structure observation photo , instead of resiting the content of residual
In still another arrangement, both the density of carbides and the content of residual /"are restricted.
The present invention also provides a method of nanufacturing oil-tempered wires as described above under specific quenching and tempering conditions.
According to the present invention there is provided a method of manufacturing high-toughness oil-tempered wire wherein tempering in a quenching/tempering step is carried out at a heatmg rate of 150 °C/sec or more at a temperature of 450 °C to 600°C for 15 seconds or less from the start of heating to the start of a cooling step using a coolant such as water.
Now we will explain wh y the steel composition has
been restricted.
1) C: 0.5-0.8 wt.%
C is essential to increase the strength of the steel wire. If its content is less than 0.5%, the strength of the wire will be insufficient. On the other hand, a steel wire containing more than 0.8% carbon is low in toughness. Such a wire is not reliable enough because it is more liable to get marred.
2) Si: 1.2-2.5 wt.%
Si helps increase the strength of ferrite and thus improve the resistance to permanent set. If its content is less than 1.2%, this effect cannot be achieved sufficiently. If over 2.5%, hot and cold machinability will drop. Also, such a largt; amount will promote decarbonization during heat treatment,
3) Mn: 0.4-0.8 wt.%
Mn improves the hardening properties of the steel and prevents any harmful effect caused by suffer in the steel by fixing it. If its content is less than 0.4%, this effect cannot be achieved sufficiently. If over 0.8%, the toughness will drop.
4) Cr: 0.7-1.0 wt.%
Like Mn, Cr improves the hardening properties of the steel. It also serves to increase the toughness of the wire by patenting after hot rolling and to increase the
resistance to softening during tempering after quenching and thus the strength of the wire. If its content is less than 0.7%, this effect cannot be achieved sufficiently. If over 1.0%, Cr will hinder carbides from turning into solid solution, thus lowering the strength of the wire. Also, such a large amount will cause excessive tempering action, leading to reduced toughness.
5) V: 0.05-0.15 wt.%
Vanadium helps the formation of carbides during tempering, thus increasing the resistance to softening of the wire. If its content is less than 0.05%, this effect will be insufficient. If over 0.15%, a large amount of carbides will be formed during heating for quenching, which will lower the toughness of the wire.
6) Mo: 0.05-0.15 wt.%
Mo helps the formation of carbides during tempering, thus increasing the resistance to softening of the wire. If its content is less than 0.05%, this effect will be insufficient. If over 0.5%, wire drawing will become difficult.
7) W: 0.05-0.15 wt.%
Tungsten helps the formation of carbides during tempering, thus increasing the resistance to softening of the wire. If its content is less than 0.05%, this effect will be insufficient. If over 0.15%, too large an amount
of carbides will be formed during heating for quenching so that the toughness of the wire will drop.
8) Mb: 0.05-0.15 wt.%
Nb helps the formation of carbides during tempering, thus increasing the resistance to softening of the wire. If its content is less than 0.05%, this effect will be insufficient. If over 0.15%, too large an amount of carbides will be formed during heating for quenching, so that the toughness of the wire will drop.
9) Al, Ti: 0.005 wt.% or less
They form AL2O3 and TiO which are high-melting point, non-metallic inclusions. These inclusions are hard and can markedly lower the fatigue strength if present near the steel wire surface. Thus, though they are unavoidable impurities, their contents have to be 0.005 wt.% or less. For this purpose, a raw material containing lesser impurities should be selected.
10) Reason why the content of residual  is restricted to
1-5% by volume
A residual  phase present in the tempered martensite improves the toughness of the steel wire. If its content is less than 1%, the effect will be insufficient. But if its content is more than 5%, the resistance to permanent set will decrease due to marten.sitic transformation while the wire is used a spring.
11) Reason why the number of unresolved carbides (0.05 µm or more in particle diameter) is restricted to 5 pieces per µm as observed on a structure observation photo.
Unresolved carbides having particle diameters of 0.05 µm or more can be starting points of destruction while
forming springs. Thus, if the number of such carbides
exceeds 5 pieces per µm2 as observed on a structure
observation photo, the toughness of the wire will drop markedly.
The content of residual  and the density of carbides can be adjusted to the abovomentioned values by subjecting the wire to the following heat treatment.
The heating time for quenching in the quenching/tempering step before the cooling step is started, should be within 15 seconds. Otherwise, crystal grains will grow too large, lowering the toughness of the wire. If the heating rate IS 150°C/sec or lower, it is impossible to resolve carbides sufficiently within the 15-second interval before the cooling step begins. If the heating temperature is 1100 °C or higher, crystal grains will grow too large, thus lowering the toughness or causing decarbonization. If T E °C) is equal to 500 + 750*C + 500-V or less (wherein C is the content of carbon in weight % and V is the content of vanadium in weight %), carbides will not be resolved sufficiently.
Tempering during the quenching/tempering step has to be finished within 15 seconds before the cooling step is started, while keeping the heating rate at 150 sC/sec or higher. Otherwise, the residual austenite phase will decrease to less than 1% by volume.
DETAILED DESCRIPTION OF THE EXAMPLES
4.O-mm-diameter wires were formed by melting, rolling, heat-treating and drawing specimens having the chemical compositions shown in Table 1. After quenching and tempering these wires under predetermined conditions, the amount of residual phase was measured using X-rays, and the amount of carbides was measured by observing the wire structure. Also, they were subjected to a tensile test to measure the toughness in terms of reduction of area.
(Example 1)
After quenching and tempering Specimens A-I under the conditions shown in Table 2, measurement of residual and a tensile test were carried out. The results for Specimens A, B, C and I are shown in Table 3.
The amounts of residual in the specimens manufactured by the method of the present invention were
1-5 vol.%. It is thus apparent that their toughness is sufficiently high.
(Example 2)
After quenching and tempering Specimens A-I under the conditions shown in Table 4, the amount of carbides (0.05 urn or more) in each specimen was measured, and then the specimens were subjected to a tensile test. The results for Specimens A, Br D and H are shown in Table 5.
From Table 5 , it is apparent that the specimens according to Example 2, having 5 or less carbides per square micrometer, are sufficiently tough.
As described above, the oil-tempered wire for springs according to the present invention is highly resistant to permanent set and highly strong and tough.
TABLE 1 2 (Table Removed)
* Heating time is the time frets start of heati.-g to start of coiling.
TABLE 3 (Table Removed)
Residual 7 content and reduction of area
TABLE 4 (Table Removed)
* Heating time is the time from start of heating to start of cooling.
TABLE 5 (Table Removed)

(Density of carbides 3rd reduction of area

We Claim: -
1. A method of manufacturing high-toughness oil-tempered wire wherein
tempering in a quenching/tempering step is carried out at a heating rate of 150
°C/sec or more at a temperature of 450 °C to 600°C for 15 seconds or less from
the start of heating to the start of a cooling step using a coolant such as
water.
2. A method of manufacturing the high-toughness oil- tempered wire wherein quenching during a quenching/tempering step is carried out by heating to a temperature not higher than 1100°C and not less than a temperature determined by T (°C) = 500 + 750°C + 500°V at a heating rate of 150°C/sec. or more for 15 seconds or less from the start of heating to the start of cooling with water or oil.
3. A method of manufacturing the high-toughness oil- tempered wire wherein quenching during a quenching/tempering step is carried out by heating to a temperature not higher than 1100°C and not less than a temperature determined by T (°C) = 500 + 750°C + 500°V at a heating rate of 150°C/sec. or more for 15 seconds or less from the start of heating to the start of cooling with water or oil and wherein tempering in the quenching/tempering step is carried out at a heating rate of 150°C/sec or more to a temperature of 450°C to 600°C for 15 seconds or less from the start of heating to the start of cooling using a coolant such as water.
4. A method of manufacturing the high-toughness oil-tempered wire substantially as herein described with reference to the foregoing examples.

Documents:

1403-del-1996-abstract.pdf

1403-del-1996-claims.pdf

1403-del-1996-correspondence-others.pdf

1403-del-1996-correspondence-po.pdf

1403-del-1996-description (complete).pdf

1403-del-1996-form-1.pdf

1403-del-1996-form-13.pdf

1403-del-1996-form-2.pdf

1403-del-1996-form-3.pdf

1403-del-1996-form-4.pdf

1403-del-1996-form-6.pdf

1403-del-1996-gpa.pdf

1403-del-1996-petition-137.pdf

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Patent Number

195232

Indian Patent Application Number

1403/DEL/1996

PG Journal Number

31/2009

Publication Date

31-Jul-2009

Grant Date

Date of Filing

25-Jun-1996

Name of Patentee

SUMITOMO ELECTRIC INDUSTRIES,LTD.,

Applicant Address

5-33, KITAHAMA 4-CHOME, CHUO-KU, OSAKA, JAPAN

Inventors:

#	Inventor's Name	Inventor's Address
1	SADAMU MITASUMOTO	C/O ITAMI WORKS OF SUMMITOMO ELECTRIC INDUSTRIES LTD., 1-1 KOYAKITA 1-CHOME,ITAMI-SHI,HYOGO,JAPAN
2	TAKASHI YOSHIOKA	C/O ITAMI WORKS OF SUMMITOMO ELECTRIC INDUSTRIES LTD., 1-1 KOYAKITA 1-CHOME,ITAMI-SHI,HYOGO,JAPAN
3	TERUTUKI MURAI	C/O ITAMI WORKS OF SUMMITOMO ELECTRIC INDUSTRIES LTD., 1-1 KOYAKITA 1-CHOME,ITAMI-SHI,HYOGO,JAPAN

PCT International Classification Number

B21F 21/00

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	7-248412	1995-09-01	Japan