The present disclosure relates to a spring forming machine that brings a wire fed from a wire feeder into contact with a forming tool to form a coil spring surrounding a cored bar.
Conventionally, as this type of spring forming machine, there has been known a spring forming machine in which a lifting base that supports a cored bar is liftably attached to a fixing base to which a slide mechanism that supports a forming tool and a wire feeder are attached. In addition, in this spring forming machine, a pair of lifting mechanisms that support each of a cutting tool for separating the coil spring from the remaining wire and a pitch tool for expanding the space between coils of the coil spring in a liftable manner are also mounted on the lifting base (see JP 2812432 B2 (FIG. 5, paragraphs [0025] and [0053]), for example).
Incidentally, in a general spring forming machine, positions of movable parts such as a forming tool, a pitch tool, a cutting tool, and a cored bar may be individually adjusted by servo motors that are driving sources of the movable parts. However, in the above-described conventional spring forming machine, when the cored bar is moved by individual adjustment, the pitch tool is also moved accordingly, so that it takes time and effort to perform the individual adjustment. In view of the foregoing, the present disclosure provides a spring forming machine capable of easily performing individual adjustment compared to the conventional technology.
A spring forming machine according to one aspect made to solve the above problem is a spring forming machine in which a wire fed from a wire feeder along a horizontal wire feeding line is brought into contact with a forming tool so as to be formed into a coil spring surrounding a cored bar, a pitch tool for expanding a space between coils of the coil spring is inserted between the coils of the coil spring from one side in a vertical direction with respect to the coil spring, and a cutting tool for separating the coil spring from a remaining wire approaches and separates from the coil spring from an other side in the vertical direction with respect to the coil spring, the spring forming machine including: a forming tool slide mechanism including a slider to which the forming tool is fixed, the slider being supported to be linearly movable in a direction inclined with respect to the wire feeding line; a first lifting mechanism including a slider to which the pitch tool is fixed, the slider being supported to be liftable on one side in the vertical direction with respect to the cored bar; a second lifting mechanism including a slider to which the cutting tool is fixed, the slider being supported to be liftable on the other side in the vertical direction with respect to the cored bar; a fixing base to which the wire feeder and the forming tool slide mechanism are attached; a lifting base that is liftably supported by the fixing base, and to which the cored bar, the first lifting mechanism, and the second lifting mechanism are attached; a plurality of servo motors that are drive sources of the wire feeder, the forming tool slide mechanism, the first lifting mechanism, the second lifting mechanism, and the lifting base; a controller that controls the plurality of servo motors; an individual drive control unit that is provided in the controller and individually drives each of the servo motors corresponding to an operation of an operation unit; and an interlocking control unit that, when the servo motor of the lifting base is individually operated, interlocks the servo motors of the lifting base and the first lifting mechanism so that the slider of the first lifting mechanism is not lifted and lowered with respect to the fixing base by lifting and lowering of the lifting base with respect to the fixing base, and, when the servo motor of the first lifting mechanism is individually operated, does not interlock the servo motors of the lifting base and the first lifting mechanism.
Hereinafter, a spring forming machine 10 according to an embodiment of the present disclosure will be described with reference to
The spring forming machine 10 includes a wire feeder 12 on the left side at the substantially vertical center of the fixing base 11. The wire feeder 12 feeds a wire S (see
A guide member 14 is provided on the right of the pair of feeding rollers 13 on the downstream side in the feeding direction. As illustrated in
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One end parts of the base plates 50 on the side far from the wire feeder 12 protrude from the fixing base 11, and servo motors 93 and 94 are attached to the one end parts. A slider 53 that slides in the longitudinal direction is provided on a front surface of each base plate 50, and the forming tool 31 is fixed to each slider 53. The servo motors 93 and 94 and the slider 53 are connected through a crank mechanism, and each forming tool 31 is movable to an any desired position in the longitudinal direction of the base plate 50 (direction inclined with respect to wire feeding line L1) by position control by the servo motors 93 and 94.
In the present embodiment, the power transmission mechanism of the pair of forming tool slide mechanisms 40 to which the forming tools 31 are attached is the same as a first lifting mechanism 41 and a second lifting mechanism 42 to be described later. Hence, the same reference numerals are given except for the reference numerals of the servo motors as the drive sources thereof, and the power transmission mechanism will be described later only with respect to the first lifting mechanism 41. Note that the pair of forming tool slide mechanisms 40 and the later-described first lifting mechanism 41 and second lifting mechanism 42 may be different power transmission mechanisms.
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Note that an entire left side part of the lifting base 15 except for both end parts in the vertical direction is removed in order to avoid interference with the feeding roller 13 and the guide member 14, for example. As illustrated in
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On the upper side of the support sleeve 64 in the lifting base 15, a second lifting mechanism 42 having the same structure as the first lifting mechanism 41 is provided, for example, symmetrically with the first lifting mechanism 41. The pitch tool 33 is fixed to an upper end part of the slider 53 of the first lifting mechanism 41 and protrudes upward, and the cutting tool 34 is fixed to a lower end part of the slider 53 of the second lifting mechanism 42 and protrudes downward. The pitch tool 33 is movable to an any desired position in the vertical direction by the servo motor 91 which is a drive source of the first lifting mechanism 41, and the cutting tool 34 is movable to an any desired position in the vertical direction by a servo motor 92 which is a drive source of the second lifting mechanism 42.
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The pitch tool 33 has, for example, a structure in which a tip end part of a prism having a rectangular cross section is cut so as to be inclined with respect to the vertical direction, and an edge part along the cut oblique side is cut even further so as to have a wedge-like cross section. In the present embodiment, the pitch tool 33 is disposed, for example, such that its cut inclined surface faces away from the quill 14A. The pitch tool 33 expands the pitch between the coils in the coil spring W1. The pitch is changed according to the amount by which the pitch tool 33 is inserted between the coils of the coil spring W1.
Specifically, each operation program includes, for example, a plurality of pieces of target position data for the servo motors 90 to 96, and the servo motors 90 to 96 are driven so that the positions of the feeding roller 13, the lifting base 15, the forming tool 31, the cored bar 32, the pitch tool 33, and the cutting tool 34 (hereinafter collectively referred to as “forming movable part”) change to positions specified by the target position data. The controller 70 is switchable between a continuous operation mode and a manual operation mode, for example. A plurality of coil springs W1 are continuously formed by repeatedly executing an operation program by the microcomputer 71A in the continuous operation mode. The controller 70 can also be set to the manual operation mode to cause the microcomputer 71A to execute an operation program to stop the coil spring W1 in an any desired state while forming.
In the manual operation mode, for example, each servo motor 90 to 96 can be individually operated by the console 72 to create target position data by teaching. That is, when the feeding roller 13, the forming tool 31, the cored bar 32, the pitch tool 33, and the cutting tool 34 are moved to any desired positions and stopped by the individual operation of the servo motors 90 to 96, the storage button of the console 72 is turned on. With this, the detected positions of rotation position sensors of the plurality of servo motors 90 to 96 at the stopped positions can be stored (taught) as a plurality of pieces of target position data constituting a target position data set. Then, an operation program can be created by setting the speed and acceleration for moving to the teaching point specified by the target position data set by program editing using the console 72.
After the operation program is created, the operation program is actually executed in the manual operation mode to form the coil spring W1. The program is edited so that the difference between the coil spring W1 and the specification falls within an allowable value. Specifically, for example, a desired target position data set is selected by the operation program, and desired target position data of the target position data set is changed by inputting a specific numerical value using the console 72. Then, program editing is performed such that the difference between the actually formed coil spring W1 and the specification falls within the allowable value. Additionally, another operation program for forming a coil spring W1 with a different coil diameter can be created by copying an existing operation program and then changing desired target position data to obtain a new target position data set, for example.
Here, as described above, when the servo motor 90 to 96 is individually operated, the controller 70 functions as an individual drive control unit 70A illustrated in the block diagram of
As illustrated in
On the other hand, for example, when the servo motor 95 of the lifting base 15 is individually operated to change the vertical position of the cored bar 32, the operation itself of the servo motor 95 of the lifting base 15 is controlled in the same manner as when the servo motor 91 of the pitch tool 33 is individually operated. In addition, in order to prevent the pitch tool 33 from moving with respect to the fixing base 11 together with the lifting base 15, an interlocking control unit 70B included in the individual drive control unit 70A interlocks the servo motor 91 serving as the drive source of the pitch tool 33, with the servo motor 95 serving as the drive source of the lifting base 15. As a result, the pitch tool 33 moves with respect to the lifting base 15 at a predetermined speed in the direction opposite to the upward or downward movement of the lifting base 15.
That is, the interlocking control unit 70B of the present embodiment is configured to interlock the servo motors 91 and 95, so that the slider 53 of the first lifting mechanism 41 is not lifted and lowered with respect to the fixing base 11 along with lifting and lowering of the lifting base 15 with respect to the fixing base 11 when the servo motor 95 of the lifting base 15 is individually operated, and not to interlock the servo motors 91 and 95 when the servo motor 91 of the first lifting mechanism 41 is individually operated. Since the interlocking control unit 70B is provided, the spring forming machine 10 of the present embodiment can easily perform individual adjustment of the forming movable parts by the plurality of servo motors 90 to 96.
As described above, in the spring forming machine 10 of the present embodiment, the positions of the movable parts such as the forming tool 31 and the pitch tool 33 can be individually adjusted by the individual operation of the plurality of servo motors 90 to 95 which are drive sources thereof. Here, in the spring forming machine 10 of the present embodiment, the first lifting mechanism 41 that supports the pitch tool 33 is attached to the lifting base 15 that supports the cored bar 32. However, when the servo motor 95 of the lifting base 15 is individually operated, the servo motors 91 and 95 of the lifting base 15 and the first lifting mechanism 41 are interlocked, so that the slider 53 of the first lifting mechanism 15 is not lifted and lowered with respect to the fixing base 11 along with lifting and lowering of the lifting base 15 with respect to the fixing base 11. Hence, the conventional problem does not occur. Furthermore, when the servo motor 91 of the first lifting mechanism 41 is individually operated, the servo motors 91 and 95 of the lifting base 15 and the first lifting mechanism 41 are not interlocked. Hence, the problem that the position of the cored bar 32 is changed along with the change in the position of the pitch tool 33 does not occur. As a result, the spring forming machine 10 of the present embodiment can perform individual adjustment of the position of the movable parts by the plurality of servo motors 90 to 96 easily, compared to the conventional technology.
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Here, when the target position data of the servo motors 90, 91, 92, 93, 94, and 96 of forming movable parts other than the servo motor 95 of the lifting base 15 is selected and changed, only the selected target position data is changed. On the other hand, when the target position data of the servo motor 95 of the lifting base 15 is selected and changed in order to change the vertical position of the cored bar 32, in addition to the change of the target position data of the servo motor 95, the change of the position of the lifting base 15 with respect to the fixing base 11 due to the change of the target position data of the servo motor 95 will change the position of the pitch tool 33 mounted on the lifting base 15 with respect to the fixing base 11. To avoid such a change in the position of the pitch tool 33, an interlocking change unit 70F changes the target position data of the servo motor 91 of the first lifting mechanism 41 in conjunction with the target position data of the servo motor 95 of the lifting base 15. Since the interlocking change unit 70F is provided, the spring forming machine 10 of the present embodiment facilitates editing work of the operation program.
Note that in the spring forming machine 10 of the present embodiment, the winding direction of the coil spring W1 can be reversed by disposing the forming tool 31 and the cored bar 32 below the wire feeding line L1, attaching the cutting tool 34 to the first lifting mechanism 41, and attaching the pitch tool 33 to the second lifting mechanism 42. This increases variations in the type of the coil spring W1 that can be formed. In a case where the cutting tool 34 is attached to the first lifting mechanism 41 and the pitch tool 33 is attached to the second lifting mechanism 42, the above-described control is performed with the lifting mechanism of reference numeral 42 to which the pitch tool 33 is attached serving as the “first lifting mechanism” and the lifting mechanism of reference numeral 41 to which the cutting tool 34 is attached serving as the “second lifting mechanism”.
In a spring forming machine 10 of the present embodiment, in an operation program, origin position data is set for each forming movable part, and target position data of each forming movable part is specified by a displacement amount based on the origin position data. As a result, by changing any desired origin position data in a program editing unit 70E, the positions specified by all the target position data in the operation program based on the origin position data are changed at once. When the origin position data for a cored bar 32, which is the reference of the target position data of a servo motor 95 of a lifting base 15, is changed in order to change the vertical position of the cored bar 32, an interlocking change unit 70F changes the position data of the origin position for a pitch tool 33, so that the position of the pitch tool 33 with respect to a fixing base 11 does not change together with a slider 53 of a first lifting mechanism 41 due to the change in the position of the lifting base 15 with respect to the fixing base 11. As described above, in the spring forming machine 10 of the present embodiment, data processing of canceling the lifting and lowering of the slider 53 of the first lifting mechanism 41 due to the change of the target position data of the servo motor 95 of the lifting base 15 becomes easy.
(1) While the spring forming machine 10 of the first embodiment includes the pair of forming tool slide mechanisms 40 for using the pair of forming tools 31, it is also conceivable to use only one forming tool 31 with only one forming tool slide mechanism 40.
(2) The mechanism for converting the rotational output of the servo motor into linear motion described in the first embodiment is not limited to the crank mechanism and the ball screw mechanism described above, and may be appropriately changed to a cam mechanism, a rack-and-pinion mechanism, or the like.
Note that, while specific examples of the technology included in the claims are disclosed in the present specification and drawings, the technology described in the claims is not limited to these specific examples, and includes those obtained by variously modifying and changing the specific examples, and also includes those obtained by singly extracting a part from the specific examples.
Number | Date | Country | Kind |
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2021-056575 | Mar 2021 | JP | national |