The present application relates to a technology for producing a spring. Particularly, the present application relates to a technology for reducing time required for a heat treatment for eliminating a machining strain generated in a spring steel material.
Plastic working (e.g., bending, twisting) on a spring steel material to form the spring steel material into a spring shape generates a machining strain in the spring steel material. Due to an adverse effect of the machining strain on spring characteristics (e.g., durability, setting resistance), a heat treatment (a so-called “low temperature annealing treatment”) for eliminating the machining strain of the spring steel material is executed after forming the spring steel material into a spring shape (Japan Society of Spring Engineers, “Spring,” 4th edition, P.463 to 466, Maruzen Co., Ltd.). This heat treatment normally uses a heating furnace such as a hot-blast stove or an infrared heating furnace. In a case where the heat treatment is executed using such heating furnace, the spring steel material formed into the spring shape is introduced into the heating furnace from its one end. The spring steel material introduced in the heating furnace is heated while being conveyed toward the other end of the heating furnace, and carried out from the other end of the heating furnace to the outside of the heating furnace. The spring steel material is subjected to the heat treatment in this manner, and consequently the machining strain is eliminated from the spring steel material. It should be noted in this heat treatment that the treatment temperature is generally set at 380 to 430° C. and the treatment time at 20 to 60 minutes.
When producing springs in a line production system (i.e., when mass-producing springs), a step of forming a spring steel material into a spring shape is executed, and then the formed spring steel material is conveyed to a heat treatment step where a heat treatment is executed. A problem of a conventional production method is that the heat treatment step requires longer time than the forming step. In other words, in the conventional production method, while the forming step requires 4 to 60 seconds, the heat treatment step requires 20 to 60 minutes. This means that a large number of workpiece materials are subjected to the heat treatment step simultaneously when the springs are produced in accordance with the time required in the forming step. For instance, when the forming step requires 30 seconds and the heat treatment step requires 30 minutes, one spring steel material is subjected to the heat treatment step every 30 seconds, generating 60 spring steel materials simultaneously in the heat treatment step. Therefore, a large heating furnace needs to be used for the heat treatment, lowering the heating efficiency. An object of the present application is to provide a technology capable of reducing the time required for the heat treatment step of eliminating the machining strain caused by the forming step.
The present specification discloses a method of producing a spring. This production method comprises a forming step of forming a spring steel material into a shape of a spring (a predetermined shape) and a heat treatment step of eliminating a machining strain generated in the spring steel material by the forming step. The heat treatment step is executed by electrically heating the spring steel material by applying a current thereto, and comprises a first step of heating the spring steel material to a predetermined set temperature, and a second step of keeping the spring steel material at the set temperature for a predetermined set time period subsequent to the first step. The set temperature is set to be higher than 430° C. but not higher than 500° C. The set temperature herein means a temperature of a surface of the spring steel material where the current flows.
This production method electrically heats the spring steel material and can therefore heat the spring steel material to the set temperature within a short period of time. Furthermore, the heat treatment temperature (set temperature) of the spring steel material is set to be higher than 430° C. but not higher than 500° C., which is higher than the conventional heat treatment temperature (380 to 430° C.). For these reasons, the machining strain that is generated in the spring steel material in the forming step can be eliminated within a short period of time, so that the heat treatment step can be executed within a short period of time.
The set temperature is set to be higher than 430° C. but not higher than 500° C. for the following reason. When the set temperature is 430° C. or lower, the time required in the heat treatment cannot be made short enough. On the other hand, the set temperature exceeding 500° C. transforms the structure of the spring steel material and changes its mechanical characteristics.
In the production method described above, it is preferred that the set temperature be set such that time required in the first and second steps is 1 minute or less and the set time period required in the second step is 5 seconds or more. This configuration can reduce the difference in required time between the forming step and the heat treatment step and efficiently produce the spring.
It is preferred that, in the heat treatment step, a temperature of the spring steel material is measured and an amount of the current applied to the spring steel material and time required for applying the current are controlled based on the measured temperature. Although a desired level of heat treatment can be performed within a short period of time by increasing the heat treatment temperature (the set temperature), the more the heat treatment temperature fluctuates, the more the level of heat treatment fluctuates. Therefore, an appropriate level of heat treatment can be performed on the spring steel material by controlling the amount of the current and the time required in the application of the current, based on the measured temperature of the spring steel material.
The present specification further discloses a device capable of suitably heating a coil spring electrically. This electrical heating device comprises a first clamping mechanism that comprises a first electrode capable of being connected electrically to one end of the coil spring and is capable of clamping the one end of the coil spring, a second clamping mechanism that comprises a second electrode capable of being connected electrically to the other end of the coil spring and is capable of clamping the other end of the coil spring, and a power unit that apples a voltage between the first electrode and the second electrode. At least one of the first clamping mechanism and the second clamping mechanism is capable of moving in an axial direction of the coil spring and rotating around an axis of the coil spring with respect to the other of the first clamping mechanism and the second clamping mechanism. In this device, even when the coil spring is thermally deformed due to the electric heat, one of the clamping mechanisms becomes displaced with respect to the other clamping mechanism, preventing an excessive stress acting on the coil spring.
A method for producing a spring according to an embodiment will be described. In the present embodiment, the method for producing an automotive suspension coil spring (referred to as “suspension coil spring,” hereinafter), which is a type of spring, will be described as an example. The suspension coil spring is to be disposed between a vehicle body and a wheel and generates force for pressing the wheel against a road surface. The suspension coil spring is produced by forming a spring steel material into a spiral shape. A spring wire rod that has a constant sectional area of its cross section perpendicular to an axial direction can be used as the spring steel material. Examples of the spring wire rod include an oil tempered wire having a wire diameter of Φ3 to 20 mm (SUP12 (JIS G 4801), SWOSC-B (JIS G 3560), etc.).
In order to produce the suspension coil spring, first, the spring steel material is subjected to cold or warm bending and then formed into a spiral shape, as shown in
Subsequently, a heat treatment (a low temperature annealing treatment) is executed on the spring steel material formed in the spiral shape (S12). This heat treatment is performed by electric heat. The electric heat applies a current to the spring steel material to be treated, thereby heating the spring steel material. The use of electric heat can heat the spring steel material to a desired temperature within a short period of time. The use of the spring wire rod with the constant cross-sectional area as the spring steel material of the suspension coil spring can evenly heat the entire spring steel material, and therefore the heat treatment can be performed evenly on the entire spring steel material.
The heat treatment of step S12 has a first step (0 to t1) of heating the spring steel material to a predetermined set temperature T1 and a second step (t1 to t2) of keeping the spring steel material having been heated to the set temperature T1 at the set temperature T1 for a predetermined set time period. When the second step is ended (i.e., when the heat treatment of step S12 is ended), the current flowing through the spring steel material is shut off, and accordingly the spring steel material is cooled naturally (from t2 and thereon).
The set temperature T1 described above is set to be higher than 430° C. but not higher than 500° C. Setting the set temperature higher than 430° C. can heat the spring steel material to a temperature higher than the conventional heat treatment temperature (380 to 430° C.) and end the heat treatment within a short period of time. On the other hand, setting the set temperature at 500° C. or lower can prevent the structure of the spring steel material from being transformed and the mechanical characteristics of the spring steel material from being changed by the heat treatment.
Furthermore, the set temperature T1is set in accordance with the time period (0to t2) in which the heat treatment of step S12 is executed.
For example, the heat treatment time period can be set in step S12 and the set temperature T1 can be set in accordance with this set time period, such that the time period required in the first and second steps (0 to t2) is 1 minute or less and the time period required in the second step (t1 to t2) is 5 seconds or more. Setting the time period required in the first and second steps to be 1 minute or less can make the time period required in the forming process of step S10 be equal to the time period required in the heat treatment of step S12 or reduce the difference therebetween. As a result, the number of heat treatment devices disposed in a production line for mass-producing suspension coil springs can be reduced. A specific example will now be described. Suppose that a forming device produces one coil spring every 30 seconds. In this case when it takes 5 minutes for a heat treatment device to thermally treat one coil spring, ten heat treatment devices are required per forming device. On the other hand, when it takes 1 minute for the heat treatment device to thermally treat one coil spring, only two heat treatment devices may be required per forming device, achieving a reduction in the number of heat treatment devices required.
An example of an electrical heating device used in the heat treatment of step S12 will now be described. As shown in
The clamping mechanism (24a, 26a) has clamping members 24a, 26a. As shown in
The clamping members 24a, 26a are moved by an actuator, not shown, between a position where these clamping members are close to each other (a clamping position) and a position where these clamping members are separated from each other (an open position). When the clamping members 24a, 26a are moved to the clamping position, the upper end 22a of the spring steel material 22 is clamped by the electrodes 25a, 23a. As a result, the spring steel material 22 is electrically connected to the electrodes 25a, 23a. When, on the other hand, the clamping members 24a, 26a are moved to the open position, the upper end 22a of the spring steel material 22 and the electrodes 25a, 23a enter a non-contact state. Note that the clamping mechanism (24a, 26a) is capable of rotating around an axis of winding of the spring steel material 22 (i.e., an axis of the suspension coil spring). Therefore, even when the spring steel material 22 is deformed as a result of the electrical heating, the clamping mechanism can deal with such deformation.
The clamping mechanism (24b, 26b) for clamping the lower end of the spring steel material 22 has substantially the same configuration as the clamping mechanism (24a, 26a) described above. However, unlike the clamping mechanism (24a, 26a), the clamping mechanism (24b, 26b) is driven in a vertical direction of
As shown in
Note that the spring steel material 22 can be electrically heated by the above-described electrical heating device in the following procedure. First, the clamping mechanism (24b, 26b) and the jig 28 are retracted downward. Next, the spring steel material 22 is installed to the jig 42 by using a robot hand that is not shown. In other words, the robot hand is driven until the upper end 22a of the spring steel material 22 comes into abutment with the jig 42, and accordingly the spring steel material 22 is positioned with respect to the jig 42. At the same time, the clamping mechanism (24a, 26a) clamps the upper end 22a of the spring steel material 22. Subsequently, the jig 28 and the clamping mechanism (24b, 26b) are moved upward, and thereafter the clamping mechanism (24b, 26b) clamps the lower end 22b of the spring steel material 22. Once the upper end 22a and the lower end 22b of the spring steel material 22 are clamped, the power unit 50 applies a voltage between the upper end and the lower end of the spring steel material 22 to supply power to the spring steel material 22. As a result, the spring steel material 22 is heated. When this electrical heating of the spring steel material 22 is ended, the clamping mechanism (24b, 26b) releases the lower end 22b of the spring steel material 22, and thereafter the jig 28 and the clamping mechanism (24b, 26b) are retracted downward. Then, while the robot hand, not shown, grabs the spring steel material 22, the clamping mechanism (24a, 26a) releases the upper end 22a of the spring steel material 22, and thereafter the robot hand conveys the spring steel material 22 to the outside of the device.
Note that the heat caused by electrically heating the spring steel material 22 deforms the spring steel material 22. In the present embodiment, while the clamping mechanism (24b, 26b) moves in the vertical direction, the clamping mechanisms (24a, 26a), (24b, 26b) rotate around the axis of winding of the spring steel material 22, in response to the deformation of the spring steel material 22. Consequently, the thermal deformation of the spring steel material 22 is absorbed.
Subsequent to the execution of the above-described heat treatment, a surface of the spring steel material is subjected to shot peening (S14 shown in
Next, the spring steel material is heated after the shot peening (S16). This improves the setting resistance of the suspension coil spring. In this heating treatment, the surface of the spring steel material is heated to a predetermined set temperature (e.g., 190 to 300° C.). Note that various heating methods can be employed in this heating treatment, examples of which include high-speed hot-air heating (wind speed: 10 m/s or higher), induction heating, infrared heating, and electrical heating.
After heating the spring steel material in step S16, the spring steel material is cooled naturally, and a coating is sprayed onto the surface of the spring steel material (S18). When spraying the coating onto the surface of the spring steel material, for example, spray coating can be employed where the coating is atomized and then sprayed with high-pressure air. Alternatively, the coating can be sprayed electrostatically onto the surface of the spring steel material.
After the end of the spray coating on the surface of the spring steel material, the spring steel material is heated to bake the coating, which is sprayed onto the surface of the spring steel material, onto the surface of the spring steel material (S20). A heating furnace, a heat gun, or the like can be used for heating the spring steel material.
In the method of producing a suspension coil spring according to the present embodiment described above, electrical heating is performed in step S12 to heat the spring steel material at a temperature higher than that of the conventional technology, thereby achieving a reduction in the time required in the heat treatment of step S12. Therefore, the difference between the time required in the forming step of step S10 and the time required in the heat treatment step of step S12 can be reduced. As a result, the number of heat treatment facilities disposed in a production line can be reduced, and suspension coil springs can be produced efficiently.
While specific examples of the present application have been described above in detail, these examples are merely illustrative and place no limitation on the scope of the patent claims. The technology described in the patent claims also encompasses various changes and modifications to the specific examples described above.
For example, the embodiment above has described the example of producing a suspension coil spring; however, the technology according to the present application can be applied to an example of producing a spring other than the suspension coil spring. For example, the technology according to the present application can be used for producing a stabilizer bar, a torsion bar spring, and the like.
In addition, in order to appropriately execute the heat treatment of step S12, the temperature of the surface of the spring steel material may be measured using a non-contact thermometer (e.g., a radiation thermometer, a thermograph), and then the amount of the current applied to the spring steel material and the time for applying the current may be controlled based on the measured surface temperature. In this manner, the temperature of the spring steel material is controlled accurately, and an appropriate amount of heat treatment can be executed on the spring steel material.
Moreover, the embodiment above has described the example in which the electrical heating method of the present application is applied to the heat treatment (low temperature annealing treatment) for removing a machining strain that is generated as a result of forming the spring steel material into a spring shape by cold or warm working. However, the technology disclosed in the present specification is not limited to this example. For instance, the electrical heating method disclosed in the present specification can be applied to a heat treatment step (tempering treatment) that is performed after forming the spring steel material into a spring shape by the hot working and then quenching the formed spring steel material.
The technical elements explained in the present description or drawings provide technical utility either independently or through various combinations. The present invention is not limited to the combinations described at the time the claims are filed. Further, the purpose of the examples illustrated by the present description or drawings is to satisfy multiple objectives simultaneously, and satisfying any one of those objectives gives technical utility to the present invention.
Number | Date | Country | Kind |
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2010-166806 | Jul 2010 | JP | national |
PCT/JP2011/065886 | Jul 2011 | JP | national |
This application is a divisional of U.S. patent application Ser. No. 13/812,138, which is a 371 of PCT/JP2011/065866 filed Jul. 12, 2011, and claims priority to JP 2010-166806 filed Jul. 26, 2010, which are all incorporated herein by reference.
Number | Date | Country | |
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Parent | 13812138 | Jan 2013 | US |
Child | 15448969 | US |