JP5270864B2 - Spring steel wire manufacturing method and manufacturing apparatus - Google Patents

Description

  The present invention relates to a method and an apparatus for manufacturing a spring steel wire that cools a wire after being heated by a heating coil.

In order to manufacture a spring steel wire, a wire rod rewinded from a rewind stand is quenched and tempered by using a heating device and a cooling device, and wound on a winding stand.
A coiling machine is used to form a quenched and tempered spring steel wire into a coil spring shape. In this coiling machine, the traveling direction of the spring steel wire is guided by a plurality of finger pins so as to be sequentially deflected and wound in a coil shape. However, a seizure phenomenon occurs between the steel wire and the finger pins. When the seizure phenomenon occurs, the winding speed becomes non-uniform so that the shape of the finished coil spring is not precisely determined, resulting in variations in product dimensions, and hence spring constants and spring characteristics. There's a problem.

In order to solve this problem, in the heat treatment process of the spring steel wire, the wire rod rewinded from the rewinding stand is subjected to quenching using heating / cooling means and tempering in order to wind up the wire to the winding stand. The wire that has passed through the heating means passes through the superheated steam atmosphere until it reaches the rapid cooling means, and the heated wire is an oxide film whose main component is Fe ₃ O ₄ with a uniform thickness around the entire surface. There is a conventional example in which (scale) is formed (Patent Document 1).

Japanese Patent Publication No. 6-2933

In the conventional example of Patent Document 1, a desired oxide film can be formed, but when the wire is wound around the winding stand in a coil shape, the wire is formed on the surface of the wire when bending stress is applied. The subject that an oxide film peels arises.
When the wire is wound into a coil shape, if the oxide film attached to the surface of the wire is peeled off, the base material is exposed, which causes a problem that the wire is burned with the coiling machine.

  The objective of this invention is providing the manufacturing method and manufacturing apparatus of a spring steel wire with few oxide films once formed peeling.

The spring steel wire manufacturing method of the present invention is a spring steel wire manufacturing method including a heating step using a heating coil and a cooling step performed after the heating step. After the heating step is performed, air is shut off. In addition, the wire is inserted into a shield pipe having an internal space into which water vapor of 62 liters / minute to 310 liters / minute and carbon dioxide of 10 liters / minute to 50 liters / minute are fed, and the wire is made of water vapor and carbon dioxide. an oxide film was formed by in-line approximately the wire material have location simultaneously in an atmosphere of, then and performing the cooling step.

A spring steel wire manufacturing apparatus according to the present invention is a spring steel wire manufacturing apparatus in which a heating device having a heating coil and a cooling device are arranged on an inline, and passes on the inline between the heating device and the cooling device. A gas supply device for supplying water vapor of 62 liters / minute to 310 liters / minute and carbon dioxide of 10 liters / minute to 50 liters / minute to form an oxide film on the wire to be supplied, and the gas supply device And a shield pipe in which the wire is placed in the atmosphere of steam and carbon dioxide almost simultaneously , and air is blocked.

  According to the invention of this configuration, after the heating process is performed on the wire using the heating coil, the wire is supplied to the wire heated in the heating process before the cooling process using the cooling device is performed. Then, water vapor and carbon dioxide are supplied to the sealing member, and the wire is placed in an atmosphere of water vapor and carbon dioxide inside the sealing member. By placing the wire in an atmosphere of water vapor, an oxide film is formed all around the surface of the wire, and by placing it in an atmosphere of carbon dioxide, this oxide film is surely adhered to the base material of the wire. Therefore, peeling of the oxide film from the base material of the wire is reduced.

In the invention of a method of manufacturing a spring steel wire, said heating step includes a first heating step of heating the wire, as obtain Preparations and a second heating step of heating the heated wire again configured in this first heating process Also good.
In the invention of apparatus for manufacturing a spring steel wire, said heating coil, a first heating coil for heating the wire, as Bei obtain configuration and a second heating coil for heating the heated wire again by the first heating coil Also good.

  In the invention of this configuration, the quenching temperature can be increased in a short time by heating the wire in two stages. Therefore, a sufficiently heated wire can be placed in an atmosphere of water vapor and carbon dioxide, so that an oxide film can be formed quickly.

Furthermore, in the invention of the method for producing a spring steel wire, the first heating step is to heat the wire at a temperature of 900 ° C. or higher, and the second heating step is a heating temperature of the first heating step. The structure which heats the said wire at the temperature higher 50 to 100 degreeC is preferable.
In the invention of this configuration, the amount of oxide film generated is larger than when heating at a low temperature, for example, 700 ° C.

Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing an outline of a spring steel wire manufacturing apparatus according to the present embodiment.
In FIG. 1, a spring steel wire manufacturing apparatus includes a rewind stand 2 on which a wire 1 to be processed is previously wound, and a cleaning device (not shown) for cleaning the wire 1 unwound from the rewind stand 2. ), A heating device 3 for heating the wire 1 cleaned by the cleaning device, a cooling device 4 for cooling the wire 1 heated by the heating device 3, and a wire 1 cooled by the cooling device 4 A tempering coil 5 to be returned, a cooling jacket 6 for cooling the wire 1 tempered by the tempering coil 5, a winding stand 7 for winding the wire 1 cooled by the cooling jacket 6, a heating device 3 and a cooling device 4 And a gas supply device 8 for supplying gas to the wire 1 passing between the two.
The wire 1 is formed from a material suitable for a spring steel wire, such as carbon steel or alloy steel. The spring steel wire manufacturing apparatus is provided with a feed mechanism (not shown) for feeding the wire 1, and the wire 1 is moved at a predetermined speed, for example, 70 mm / sec to 350 mm / sec by this feed mechanism.
The unwinding stand 2 and the winding stand 7 have the same structure as before.

The heating device 3 heats the wire 1 for quenching, and includes a first heating coil 31 and a second heating coil 32 that heats the wire 1 heated by the first heating coil 31 again. . The first heating coil 31 and the second heating coil 32 are connected to a power source (not shown). This power source is connected to a control device (not shown), and the heating temperature is adjusted by controlling the voltage applied to the first heating coil 31 and the second heating coil 32 by the control device.
A feed roll 10 is disposed between the first heating coil 31 and the second heating coil 32. A shield pipe 11 is disposed between the roll 10 and the first heating coil 31, and a shield pipe 12 is disposed between the roll 10 and the second heating coil 32. Air is blocked inside these shield pipes 11 and 12, and the wire 1 is inserted. Steam or the like is introduced into the shield pipes 11 and 12 as necessary.

The cooling device 4 has the same structure as the conventional one, and the wire 1 heated by the heating device 3 is cooled when the wire 1 passes through the cooling device 4.
The tempering coil 5 heats the wire 1 to temper and is connected to a power source (not shown). This power source is connected to a control device (not shown), and the voltage applied to the tempering coil 5 is controlled by this control device.
The cooling jacket 6 cools the wire 1 heated by the tempering coil 5 again, and the wire 1 is cooled when the wire 1 passes through the inside thereof.

A shield pipe 13 as a sealing member is disposed between the cooling device 4 and the second heating coil 32. The shield pipe 13 is air-blocked in its internal space, and the wire 1 is inserted therethrough.
A shield pipe 14 is arranged between the tempering coil 5 and the cooling jacket 6. The shield pipe 14 is air-blocked in its internal space, and the wire 1 is inserted therethrough.
The gas supply device 8 includes a water vapor supply line 81 that supplies water vapor into the shield pipe 13 and a carbon dioxide supply line 82 that supplies carbon dioxide.

The steam supply line 81 includes a steam generator 810, a steam supply pipe 811 having one end connected to the steam generator 810 and the other end opened to the shield pipe 13, and the flow rate of water vapor flowing through the steam supply pipe 811. A flow rate adjustment valve 812 to be adjusted, a branch pipe 813 branched from the water vapor supply pipe 811 and having a tip opened to the shield pipe 14, and a flow rate adjustment valve 814 for adjusting the flow rate of the water vapor flowing through the branch pipe 813 are provided. .
Steam generator 810 are those water is boiled to generate steam in a boiler or the like, the steam generated in the steam generator 810, a predetermined flow rate, for example 62 l / min to 310 l / min (water terms At 50 cc / min to 250 cc / min) through the steam supply pipe 811 and the branch pipe 813 to the shield pipe 13 and the shield pipe 14.
In the present embodiment, the steam generator 810 supplies water to the shield pipe 13 and the shield pipe 14 through the steam supply pipe 811 and the branch pipe 813, and supplies water to the wire 1 passing through the shield pipe 13 and the shield pipe 14. The water may vaporize at the temperature of the wire 1 to generate water vapor.

The carbon dioxide supply line 82 circulates through a cylinder 820 filled with carbon dioxide, a carbon dioxide supply pipe 821 having one end connected to the cylinder 820 and the other end opened to the shield pipe 13, and the carbon dioxide supply pipe 821. And a flow rate adjusting valve 822 for adjusting the flow rate of carbon dioxide.
The cylinder 820 supplies carbon dioxide into the shield pipe 13 at a predetermined flow rate, for example, 10 liters / minute to 50 liters / minute.
As shown in an enlarged view in FIG. 2, the openings of the water vapor supply pipe 811 and the carbon dioxide supply pipe 821 to the shield pipe 13 are arranged close to each other. The inside of the shield pipe 13 is sealed with water vapor and carbon dioxide for a predetermined time, for example, 60 seconds or less.

Next, the manufacturing method of the spring steel wire concerning this embodiment is demonstrated.
First, the wire 1 is unwound from the rewind stand 2, washed with a washing device, and then sent to the heating device 3. A heating process is performed by the heating device 3.
In the heating process, first, the wire 1 is heated by the first heating coil 31 to perform the first heating process, and then the second heating coil 32 is heated again at a temperature higher than the heating temperature in the first heating coil 31. The second heating step is performed. Here, a 1st heating process heats the wire 1 at the temperature of 900 degreeC or more, and a 2nd heating process heats the wire 1 at the temperature 50-100 degreeC higher than the heating temperature of a 1st heating process. The wire 1 that has passed through the first heating coil 31 is sent to the second heating coil 32 by the feed roll 10, and the wire 1 is heated again by the second heating coil 32.

The wire 1 sent from the second heating coil 32 is sent to the inside of the shield pipe 13 disposed between the second heating coil 32 and the cooling device 4. Here, since the gas supply device 8 is operated, water vapor and carbon dioxide are introduced into the shield pipe 13 substantially simultaneously. Thereby, while the wire 1 is located inside the shield pipe 13, the wire 1 is in an atmosphere of water vapor and carbon dioxide.
On the surface of the wire 1 sent from the shield pipe 13, an oxide film mainly composed of Fe ₃ O ₄ having a uniform predetermined thickness is formed.
Thereafter, the heated wire 1 is cooled by the cooling device 4 and then tempered by the tempering coil 5.
The tempered wire 1 is sent to the cooling jacket 6 after passing through the shield pipe 14 under a steam atmosphere, and is further wound up by the winding stand 7.

Next, examples will be described.
The chemical composition of the wire 1 used in Examples and Comparative Examples is shown in Table 1, and the configuration of the wire 1 is shown in Table 2.

Moreover, the wire 1 is sent at 190 mm / sec as the heat treatment condition.
[Example 1]
Under the above conditions, in Example 1, water vapor and carbon dioxide were simultaneously introduced into the shield pipe 13 disposed between the second heating coil 32 and the cooling device 4. The heating temperature of the wire 1 in the first heating coil 31 is 700 ° C., and the heating temperature of the wire 1 in the second heating coil 32 is 950 ° C. Water vapor was introduced into the shield pipe 14 disposed between the tempering coil 5 and the cooling jacket 6. The wire 1 cooled by the cooling jacket 6 was cut over a predetermined length to obtain a test piece.
[Example 2]
Example 2 is the same as Example 1 except that the temperature of the second heating step is different from Example 1. That is, in Example 2, the heating temperature of the wire 1 in the first heating coil 31 is 700 ° C., and the heating temperature of the wire 1 in the second heating coil 32 is 1000 ° C.

[Example 3]
Example 3 is the same as Example 1 except that the temperature of the first heating step is different from Example 1.
That is, in Example 3, the heating temperature of the wire 1 in the first heating coil 31 is 900 ° C., and the heating temperature of the wire 1 in the second heating coil 32 is 950 ° C.
[Example 4]
Example 4 is the same as Example 1 except that the temperatures of the first heating step and the second heating step are different from Example 1.
That is, in Example 4, the heating temperature of the wire 1 in the first heating coil 31 is 900 ° C., and the heating temperature of the wire 1 in the second heating coil 32 is 1000 ° C.

[Comparative Example 1]
Comparative Example 1 is an example in which nitrogen is sealed in shield pipes 11, 12, and 13, respectively. The other conditions are the same as in Example 1.
[Comparative Example 2]
Comparative Example 2 is an example in which nitrogen is sealed in the shield pipe 11 and water vapor is sealed in the shield pipes 12 and 13 respectively. The other conditions are the same as in Example 1.
[Comparative Example 3]
Comparative Example 3 is an example in which nitrogen and graphite powder are sealed in the shield pipes 11 and 12, respectively, and nitrogen is sealed in the shield pipe 13. The other conditions are the same as in Example 1.
[Comparative Example 4]
Comparative Example 4 is an example in which nitrogen and graphite powder are sealed in the shield pipes 11 and 12, respectively, and water vapor is sealed in the shield pipe 13. The other conditions are the same as in Example 1.
[Comparative Example 5]
In Comparative Example 5, carbon dioxide and graphite powder were simultaneously introduced into the shield pipe 13. The rest is the same as in Example 1.
Table 3 shows the conditions of Examples 1 to 4 and Comparative Examples 1 to 5 described above.

[Experimental result]
The thickness of the oxide film (scale) attached to the test piece was measured with an optical microscope. Table 4 shows the thicknesses of the oxide films measured in Examples 1 to 4 and Comparative Examples 1 to 5.
The test piece was bent at a right angle, and the adhesion of the oxide film was visually evaluated.
In Comparative Examples 1 and 2, many peelings of the oxide film were observed around the bent portion of the test piece. In Comparative Example 4, peeling of the oxide film was also observed. Although Comparative Example 3 was less than Comparative Examples 1, 2, and 4, peeling of the oxide film was observed. In Comparative Example 5 as well, many peelings of the oxide film were observed around the bent portion of the test piece (indicated by “x” in Table 4).
On the other hand, in all of Examples 1 to 4, peeling of the oxide film is extremely small as compared with Comparative Examples 1 to 4. In particular, the color change of the oxide film formed on the bent portion of the test piece is very small.
In Examples 1 and 2, although the color tone of the oxide film formed on the linear portion of the test piece slightly changes with slight peeling, the influence is small (indicated by “◯” in Table 4). , 4 has little change in the color tone of the straight line portion as indicated by “◎” in Table 4.

Moreover, in order to confirm the peeling condition of an oxide film, inner diameter 2D winding experiment was implemented. In this experiment, the test piece itself is wound around an axis that is twice the diameter of the test piece, and it is confirmed whether or not peeling of the oxide film is acceptable. A plurality of these experiments are performed, and the probability that the peel amount is large and out of the allowable range among the plurality of experiments is an evaluation criterion.
In the experimental example in which water vapor and carbon dioxide were simultaneously added to the shield pipe 13, the peeling rate was 20 to 50%. On the other hand, in the comparative example in which water vapor was introduced into the shield pipe 13, the peeling rate was 60 to 90%.

According to the above examples, the following effects can be achieved in the present embodiment.
(1) After the heating process is performed on the wire 1 using the second heating coil 32, before the cooling process using the cooling device 4 is performed on the wire 1, gas is supplied to the wire 1 heated in the heating process. Steam and carbon dioxide were supplied from the apparatus 8 to the shield pipe 13, and the wire 1 was placed in the atmosphere of steam and carbon dioxide inside the shield pipe 13. Therefore, an oxide film is formed on the entire circumference of the surface layer of the wire 1, and the oxide film adheres securely to the base material of the wire 1 when placed in an atmosphere of carbon dioxide. Peeling from the material can be reduced.

(2) A first heating step in which the heating step is performed by the first heating coil 31, and a second heating step in which the wire heated in the first heating step is heated again by the second heating coil 32 at a higher temperature. Between the second heating step and the cooling step, water vapor and carbon dioxide were introduced into the wire 1 almost simultaneously. Therefore, by heating the wire 1 in two stages, the quenching temperature can be quickly increased to a high temperature in a short time (for example, 60 seconds or less) compared to the case where the heating process is performed in one stage. The oxide film can be formed quickly.

(3) The first heating step heats the wire 1 at a temperature of 900 ° C., and the second heating step heats the wire 1 at 950 ° C. to 1000 ° C., so that the first heating step of the wire 1 is performed at 700 ° C. Compared with the case, the production amount of the oxide film can be increased.

[Modification]
It should be noted that the present invention is not limited to the above-described embodiments, and modifications, improvements, and the like within the scope that can achieve the object of the present invention are included in the present invention.
For example, in the above embodiment, the heating process for quenching is composed of two stages of the first heating process and the second heating process, but in the present invention, it may be composed of three stages or four or more stages.

Furthermore, although the sealing member is composed of the shield pipe 13, it may be composed of another member, for example, a hollow sphere.
Moreover, in the said embodiment, although carbon dioxide was supplied from the upstream of the wire rod 1 sent, and water vapor | steam was injected from the downstream, in this invention, if these carbon dioxide and water vapor | steam are thrown in substantially simultaneously. Regardless of before and after the charging, for example, water vapor may be input from the upstream side of the wire 1 to be fed and carbon dioxide may be input from the downstream side. Furthermore, the charging ratio of both gases is set as appropriate.

  The present invention can be used for manufacturing a spring steel wire.

The schematic block diagram of the manufacturing apparatus of the spring steel wire which concerns on one Embodiment of this invention. Schematic which shows the principal part of the said embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Wire rod, 2 ... Rewind stand, 3 ... Heating device, 4 ... Cooling device, 7 ... Winding stand, 8 ... Gas supply device, 31 ... 1st heating coil, 32 ... 2nd heating coil, 13 ... Shield pipe (Sealing member), 11, 12, 14 ... shield pipe, 81 ... water vapor supply line, 82 ... carbonic acid supply line

Claims (5)

In the manufacturing method of the spring steel wire provided with the heating process by a heating coil and the cooling process implemented after this heating process,
After carrying out the heating step, a shield pipe having an internal space in which air is shut off and water vapor of 62 liters / minute to 310 liters / minute and carbon dioxide of 10 liters / minute to 50 liters / minute are sent. the inserted through the wire the wire material have substantially simultaneously location in an atmosphere of water vapor and carbon dioxide to form in-line oxidation film on the wire,
Then, the said cooling process is performed , The manufacturing method of the spring steel wire characterized by the above-mentioned . In the manufacturing method of the spring steel wire described in Claim 1,
It said heating step includes a first heating step of heating the wire, a manufacturing method of a spring steel wire characterized by a kite and a second heating step of heating the heated wire again in the first heating step. In the manufacturing method of the spring steel wire described in Claim 2,
The first heating step heats the wire at a temperature of 900 ° C. or higher, and the second heating step heats the wire at a temperature higher by 50 ° C. to 100 ° C. than the heating temperature of the first heating step. A method for producing a spring steel wire, characterized by heating. In a spring steel wire manufacturing apparatus in which a heating device having a heating coil and a cooling device are arranged on an in-line,
62 liters / minute to 310 liters / minute of water vapor and 10 liters / minute to 50 liters / minute of carbon dioxide to form an oxide film on the wire passing over the in-line between the heating device and the cooling device. A gas supply device for supplying
An apparatus for producing a spring steel wire, comprising: a shield pipe in which the wire is placed almost simultaneously in an atmosphere of water vapor and carbon dioxide supplied by the gas supply device and air is blocked. In the manufacturing apparatus of the spring steel wire described in Claim 4,
The heating coil has a first heating coil for heating the wire manufacturing apparatus of a spring steel wire, characterized in that to obtain Bei and a second heating coil for heating the heated wire again in the first heating coil.

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