1. Field of the Invention
The systems and methods described herein relate to coil spring manufacture.
2. Description of the Related Art
Today, mattresses are typically made of an inner spring core that is covered with a layer of padding and upholstery. The quality of the mattress depends, at least in part, on the quality of the inner spring core. The inner spring core is typically a plurality of springs each of which is made of steel and each of which has enough resiliency so that the inner spring core collectively can support a number of users that are resting comfortably on the mattress. The quality of the inner spring can vary according to a number of factors including, the design of the inner spring core, such as open coil or Marshall coil, the number of coils employed within the inner spring core, the quality of springs used in the inner spring core, and a number of other factors.
As the quality of the mattress depends in part on the quality of the springs used in the core, engineers have worked to develop improved springs that are more capable of providing support and comfort. Engineers have recently developed an inner spring core that comprises a plurality of multi-strand coils which are fashioned together to provide an inner spring core.
These new inner spring cores promise to provide more comfortable and durable mattresses. However, conventional coiler machines cannot be used to manufacture these coils. Accordingly, new systems are needed for manufacturing multi-strand coils that may be employed within the inner spring cores of mattresses.
The systems and methods described herein include systems for manufacturing coils, and techniques for manufacturing such coils.
More particularly, the systems and methods described herein include machines that feed multi-strand wire to a coil winder, to manufacture one or more coil springs. In one embodiment, these systems include a coil-spring winder that forms the wire into a coil spring. The coil spring typically has a plurality of coils, and is resilient. The wire is typically steel, but may be any other suitable material, or a combination of materials. The coil-spring winder receives wire from a wire holder, and forms the wire into a coil spring. The wire holder may include a spool or reel, about which the supply of wire is held.
Typically, but not always, the coil-spring winder cuts the coil spring to a desired length, and thereby takes wire off a spool to form a plurality of coil springs of the type that can be employed in a mattress, furniture, car seat, industrial machine, or for any other suitable application. To feed the coil-spring winder, the systems and methods described herein include a wire holder that supplies the wire to the coil-spring winder along a feed direction. The wire holder is supported for rotation about an axis that is typically aligned with the feed direction. In this case, the rotation of the wire holder may be synchronous with the formation of the coils of the coil spring.
Thus, in one embodiment, the spool of wire is mounted onto a wire holder that can rotate about an axis that is essentially aligned with the feed direction of the wire being fed into the coil-spring winder. Thus, as the spool of wire revolves around the central spool axis, the spool also revolves around a second axis, which typically is orthogonal to the spool axis. In this way, it is understood that the coil-spring winder can pull wire off the spool without it causing twisting in the wire to unravel or snap the multi-strand wire.
As described below, the systems and methods described herein include systems for manufacturing coil springs from multi-strand wire, wherein the strands may be overlaid, braided, or helically twisted along a common axis. The strands may have a cross-sectional shape that is round, elliptical, square, rectangular, flat or any other suitable shape.
In optional, alternate embodiments, the systems may have a motor for rotating the wire holder. Such alternate embodiments may also include a torque sensor for measuring torque imparted to the wire, and a motor controller responsive to the torque, for controlling the wire holder's speed or direction.
Optionally, the systems may have a magnetic-particle clutch to controllably transfer torque from a motor to the wire holder. In yet other embodiments, a magnetic-particle brake may be used to reduce the speed of, or completely stop, a rotation of the wire holder. Sensors and controllers may optionally be used to control the operation of a magnetic-particle brake or clutch.
In some embodiments, the systems may include retainers for discouraging the departure of the wire from the supply of the wire at undesirable locations, and possibly getting entangled. Such retainers are useful when the inertia of the wire holder leads to the wire holder continuing a rotational motion even after solicitation of wire from the wire holder has ceased.
Other aspects of the invention, include methods for manufacturing a coil spring from a multi-strand wire. In one practice, such methods include the steps of dispensing wire, from a wire holder, along a feed direction to a coil-spring winder, and causing the coil-spring winder to form the wire into a coil spring having a plurality of coils. The method includes rotating the wire holder about a holding axis, wherein the rotating of the wire holder prevents or reduces torque imparted to the wire. Optionally, the holding axis may be essentially aligned with the feed direction. Rotating of the wire may be substantially synchronous with the formation of coils by the coil-spring winder. The method may further include providing a motor to rotate the wire holder about the holding axis. Optionally, the method may include providing a feedback mechanism by which a motor controller controls the speed and/or direction of rotation of the motor rotating the wire holder. The feedback mechanism may measure the torque acting on the wire. Optionally, the method may provide a brake to modify the speed of rotation of the motor rotating the wire holder. The method may further include providing a clutch for regulating transferring power from the motor to the wire holder.
Other embodiments shall be apparent from the following description of certain illustrated embodiments.
The foregoing and other objects and advantages of the invention will be appreciated more fully from the following further description thereof, with reference to the accompanying drawings, wherein;
Definitions:
For convenience, certain terms employed in the specification, including examples and appended claims, are collected here. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the systems and methods described herein pertain.
The article “a” and “an” are used herein to refer to one, or to more than one (i.e., to at least one) of the grammatical object of the article, unless context clearly indicates otherwise. By way of example, “an element” means one element or more than one element.
The term “including” is used herein to mean, and is used interchangeably with, the phrase “including, but not limited to.”
The term “or” is used herein to mean, and is used interchangeably with, the term “and/or,” unless context clearly indicates otherwise.
The term “coil-spring winder” is used herein to mean, and is used interchangeably with, the term “spring coiler.”
The term “reel” is used herein to mean, and is used interchangeably with, the term “spool.” The term “reel axis” is used herein to mean, and is used interchangeably with, the term “spool axis.”
The term “cross section” (or its equivalent term “cross-section”) is used herein to mean a section or slice formed by a plane cutting through an object, at a non-zero angle to an axis, wherein the angle may or may not be a 90-degree angle. For example, a cross section of a wire is a section or slice formed when an imaginary or real plane cuts through the wire at a non-zero angle to the longitudinal axis of a segment of the wire neighboring the intersection of the plane and the wire.
To provide an overall understanding of the invention, certain illustrative practices and embodiments will now be described, including a machine and method for manufacturing a coil spring made of multi-strand wire. However, it will be understood by one of ordinary skill in the art that the systems and methods described herein can be adapted and modified and applied in other applications and that such other additions, modifications and uses will not depart from the scope hereof.
The systems and methods described herein provide, among other things, a coil winder capable of manufacturing coil springs from multi-strand wire. To this end, the systems include a device for releasing the rotational torque that builds on a multi-strand twisted-wire or braided cable during a coil-winding process. In one embodiment, the feeder spool assembly that provides the cable to the coiler is modified so as to allow for an additional degree of rotational freedom. This additional degree of freedom allows the wire to rotate in response to the rotational torque being applied to the multi-strand wire. This prevents or reduces damage to the wire.
Turning to
In the systems and methods described herein, the wire on the spool 111 is a multi-strand wire. Typically, this wire comprises a plurality of twisted or braided steel strands. In either case, the exterior surface of the multi-strand wire is knurled. Consequently, as the coil spring-winder 112 pulls the multi-strand wire off 113 the spool 111, the knurled exterior surface of the wire has a tendency to turn or torque the wire 113 as it spools into the coil-spring winder 112. This imparts a torsional torque on the wire. In time, the torque may accumulate and, depending on the direction of the torque and/or the type of multi-strand wire, cause the wire to fray or fracture.
To accommodate the torsional torque build-up in a multi-strand twisted-wire cable, the systems and methods described herein include a feeder spool 211 having a second degree of rotational freedom. Typically, this second axis of rotation 219 is substantially orthogonal, or perpendicular, to the axis 216 about which the spool 211 rotates. This is shown schematically by arrows 222 in
As shown in
In one embodiment, the coupling device 220 includes a ball-bearing interface between the mounting brace 217 and the reference fixture 215. This is akin to the mounting apparatus of a front wheel of a supermarket cart, for example, where the wheels have two degrees of rotational freedom, one by which the cart is propelled and another which allows for the cart to turn.
Specifically,
In one embodiment, the coupling device 220 comprises a ball bearing connector that mechanically attaches the mounting brace 217 to the reference fixture 215, and accommodates rotation about the axis 219. One such example of a ball bearing coupling device suitable for use with the system 200 is a pillow-block anti-friction bearing of the type sold by the Torrington Company, of Torrington, Conn. Other suitable bearing systems are known in the art. In operation, as wire 213 is fed into the coiler 212, a torsional torque may arise that acts on a plane orthogonal to the wire at any cross section of the wire 213, the torque being about an axis defined by the local longitudinal axis of the wire 213. As the torque increases, the force of the torque may cause the wire spool 211 and mounting brace 217 to rotate about the axis 219. As the ball bearing coupling device 220 will not support a torque, the spool 211 and mounting brace 217 will continue to rotate, possibly even substantially synchronously with the formation of coils. In this embodiment the coupling 220 serves as a passive device that allows the torque generated by the coiler 212 to cause the wire holder to rotate.
In alternate embodiments, other types of coupling mechanisms may be employed. For example, the coupling 220 may comprise an axle, bushings, a gear assembly, motors, or any other suitable device. In any case, the coupling mechanism 220 will be adapted to allow the spool 211 to rotate in a manner that prevents torsional force from building up and causing the multi-strand wire or cable 213 to fracture or to unravel.
The multi-strand wire 113 pulled from the spool 111 may be fed into a coiler, such as the coiler 112 of the prior arts system of
One example of a spring made from a multi-strand wire 332 and formed into a coil by the systems and methods described herein, is depicted in
In the embodiment depicted in
Turning to
The embodiments described above are merely representative of the systems and methods according to the invention. Many alternative embodiments may be achieved and the embodiment selected will depend, at least in part, on the application. For example, in some alternate embodiments, a feeder spool 511 may be employed that comprises a large spool of wire that lacks a central axis. In this embodiment, the spool 511 may be mounted to a brace 517 so that wire 513 may be taken sideways off the spool 511.
Specifically,
An embodiment may further include a first clutch 640 that engages to transmit torque from the first motor 630 to the spool axle 650. Optionally, the first clutch 640 may be a magnetic-particle clutch. Magnetic particle clutches, as is known in the art, are well suited for jerk-free start-stop motion control (typical in coil-winding processes wherein the wire holder must supply wire intermittently to the coil winder), for tension control along the longitudinal axis of the wire, and generally for a user-controlled engagement suitable for the application of interest.
For example, because the magnetic particles in a magnetic-particle clutch 640 respond essentially instantaneously to an electromagnetic field that may be applied to them, very quick response times can be achieved to control the motion of the spool (not shown in
In a further alternative embodiment, the systems and methods described herein may include a first brake 641 for adjusting the speed of rotation of the spool axle 650, and in turn adjusting the speed of rotation of the spool (not shown in
A magnetic-particle brake is useful in applications wherein the combination of the spool 211 and the supply of wire 213 that the spool holds, has large inertia. This is the case, for example, in mattress coil manufacturing, wherein a spool 211 holding a spring wire 213 is large and heavy. Due to the stop-and-pull motion that a spool 211 undergoes (a phenomenon having to do with methods for manufacturing mattress springs, known in the art), fast, yet smooth, braking of the spool 211 is desirable. For such applications, therefore, a magnetic-particle brake (such as 641, shown in
In a further embodiment, the systems and methods described herein may include a second motor (not shown in
In a further embodiment, the second motor may engage the mounting assembly 617 via a magnetic particle clutch not unlike 640, the second clutch intended to controllably transfer torque from the second motor to the mounting assembly 617 to rotate the mounting assembly 617 in, say, direction 622. In yet a further embodiment, the systems and methods described herein may include a second magnetic-particle brake (not shown in
In an embodiment, any subset of the first motor 630, the first magnetic-particle clutch 640, and the first magnetic-particle brake 641 may be controlled by a feedback control mechanism similar to that shown in
Similarly, in an embodiment including any subset of the second motor, the second magnetic-particle clutch, and the second magnetic-particle brake, a feedback control mechanism may be used analogous to that described for
Examples of control devices analogous to 442 are the TCS-200-1 Manual/Analog Adjustable Torque controller, the MCS2000 Digital Web Tensioning controller, and MCS-203, MCS-204, and MCS-166 dancer control, all manufactured by Warner Electric.
Basic information about magnetic-particle clutches, magnetic-particle brakes, and their electronic controllers is contained in a brochure published by Warner Electric-DANA, located in South Beloit, Ill.; the brochure is titled “WARNER Magnetic Particle Clutches and Brakes.”
Turning now to
In a further embodiment, a retainer 639 may have an adaptively varying position, wherein the position depends on the supply of wire remaining on the spool. For example, a retainer may be spring-loaded to press against the supply of wire. As the wire is pulled off the spool, the retainer maintains a pressed position against the remaining supply of wire. As the wire supply diminishes, the retainer approaches the core axis of the spool. This embodiment may further include a sensor to measure the supply of wire remaining on the spool, using the adaptively-varying position of the retainer and at least one physical property of the wire (such as its thickness). In one embodiment, information about the remaining supply of the wire on the reel may be further used to influence the operation of any motor, magnetic-particle brake, or magnetic-particle clutch that the embodiment entails.
Those skilled in the art will know or be able to ascertain using no more than routine experimentation, many equivalents to the embodiments and practices described herein. For example, the illustrative embodiments rotate the spool of wire for the purpose of reducing torque. Optionally however, the feeder which pull wire into the winder may rotate, thereby preventing torque from being transferred to the spool. In either case, the systems and methods described herein include mechanisms for reducing torque building on a wire, as that wire is fed into a winder. Accordingly, it will be understood that the invention is not to be limited to the embodiments disclosed herein, but is to be understood from the following claims, which are to be interpreted as broadly as allowed under the law.
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Number | Date | Country | |
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20050056066 A1 | Mar 2005 | US |