1. Field of the Invention
This invention relates to stitching systems utilizing a bobbin case assembly from which a stored supply of thread is drawn and, more particularly, to a bobbin case assembly having an associated thread tensioning assembly which produces a controlled resistance to payout of thread from a supply thereof.
2. Background Art
In sewing/stitching operations, and particularly in embroidery operations, the tension of two source components forming the lockstitch needle thread and bobbin thread must balance to achieve a high quality stitch. If the tension in the needle thread is significantly greater than the bobbin thread tension, the bobbin thread can be pulled through from the underside of the fabric and show at the top side of the fabric being sewn. This condition can cause puckering of the fabric or disfigured sewing to occur. If the needle thread tension is significantly less than the bobbin thread tension, loops can form on either side of the fabric and the stitching formation can appear loose or distortedly large.
A primary job of a sewing equipment operator is to keep bobbin and needle thread tensions as close as possible to balanced. This method of balancing thread tension has historically been carried out by having the sewing equipment operator observe the pattern after stitches are laid down. Good sewing equipment operators constantly adjust the tension of both needle and bobbin threads to maintain a proper balance. Less skilled operators may not consistently maintain this balance as a result of which poor quality stitching formation may result.
In
The bobbin case 40 and bobbin basket assembly 16 cooperatively define a wall structure 42 that captively maintains the bobbin 24 in an operative position relative to the support 14. Through this arrangement, the bobbin 24 is allowed to rotate relative to the wall structure 42 and support 14 around the axis 28.
The thread 34 is directed through the wall structure 42 to be engaged by a thread drawing mechanism 44. The drawn thread is manipulated by one or more stitching components 46 through which the thread 34 is sewn or stitched in any conventional manner with which those skilled in the art are familiar.
The bobbin case 40 has a peripheral wall 47 which surrounds the peripheral wall 20 on the bobbin basket assembly 16. The thread 34 may extend from the supply through one or both of the peripheral walls 20, 47 to be engaged by the thread drawing mechanism 44. In this embodiment, the peripheral wall 47 has a thread receiving opening 50 formed therethrough. A slot 52 extends through the peripheral wall 47 from one axial end thereof in an L shape up to the thread receiving opening 50.
A thread tensioning assembly at 54 is provided on the peripheral wall 47 and is in the form of a spring element 60 that is curved to nominally match the curvature of the outside surface 62 of the peripheral wall 47. The spring element 50 is maintained on the peripheral wall 47 by a screw fastener 64. The curved spring element 60 overlies all, or part, of the thread receiving opening 50, and a portion of the slot 52. The spring element 60 has an elongate body 66 with a mounting portion 68 that is fixed to the peripheral wall 47 through the screw fastener 64. The free end 70 of the body 66, remote from the mounting portion 68, has an offset finger 72 which projects into an opening 74, and interacts with an edge 78, bounding the opening 74, in such a manner that the free end 70 is confined against axial shifting relative to the peripheral wall 47. A second offset finger 80 on the spring element 60 projects into a slot 82 in the peripheral wall 47, likewise to consistently locate the spring element 60 by preventing axial shifting thereof relative to the peripheral wall 47.
Thread 34 departing from the supply on the bobbin 24 and projecting through the thread receiving opening 50, resides between the spring element 60 and the outside surface 62 of the peripheral wall 47. A captive frictional force can be generated on the thread 34 between the radial inwardly facing surface 84 on the spring element 60 and the outside surface 62 of the peripheral wall 47. The captive pressure applied on the thread 34 can be varied by repositioning a flexing portion 86 of the body 66 relative to the mounting portion 68 of the body 66 through an adjustment screw 88. The user sets the adjustment screw 88 to select a desired frictional resistance force between the thread 34 and surfaces 62, 84 to set a “draw tension” for the bobbin case assembly 12.
Typically, the spring element body 66 is made from a thin piece of spring metal which has a uniform thickness. By turning the adjustment screw 88, the inwardly facing surface 84 on the spring element 60 is selectively moved towards the outside surface 62 of the peripheral wall 47 and allowed to move away therefrom, whereby the frictional resistance force on the thread 34 is varied. The amount of friction, and thus the resulting draw tension, is generally determined on a trial-and-error basis. That is, the user roughly sets the adjustment screw 88 to set a thread draw tension, estimated to be at least within a reasonable range of a desired thread draw tension, and then pulls on the thread 34 while holding the bobbin case assembly 12, or thrusts the bobbin case assembly 12 while holding the thread 34. By these procedures, the user can roughly ascertain whether the desired draw tension has been set to within that reasonable range of the desired thread draw tension. Appropriate fine adjustment can thereafter be attempted through manipulation of the adjustment screw 88, with a repetition of the same trial-and-error procedure.
Given the nature of the spring element 60, and its uniform thickness, the bending characteristics of the flexing portion 86 are substantially the same over the entire length of the flexing portion 86. The nature of the spring element 60 and the adjusting structure, i.e. the adjustment screw 88, are such that generally only a relatively gross adjustment in draw tension can be set by the system operator. The spring element 60 has been conventionally made with a construction that is sufficiently stiff that it does not lend itself to fine adjustments that would allow selection of very specific draw tensions that may be desirable for a balanced system capable of producing high quality stitching.
Regardless of skill level, a system operator will generally be incapable of initially setting a desired draw tension or tensions with any predictability. The system operator, by turning the adjustment screw 88, is capable of changing the state of the spring element 60 from one wherein virtually no frictional force is generated upon the departing thread 34, and one wherein the thread 34 becomes locked between the surfaces 62, 84. All settings in between, made through trial and error, may be difficult to select given that a relatively small change in position of the adjustment screw 88 may produce a relatively large change in the thread draw tension. As such, the system operator is relegated to using potentially time consuming and frustrating trial-and-error techniques in attempting to set all draw tensions within the permitted range.
The assignee herein devised an alternative tensioning system, which is the subject of U.S. Pat. No. 6,152,057, which is incorporated herein by reference. In U.S. Pat. No. 6,152,057, an elongate tensioning element is incorporated and has a cylindrical surface against which thread bears to produce a frictional force. By varying the contact area between the thread and tensioning element, different draw tensions can be set for the system. The system lends itself to wrapping of the thread around the tensioning element, with the degree of wrapping dictating the frictional resistance force between the thread and tensioning element. The structure disclosed in U.S. Pat. No. 6,152,057 does offer significant advantages compared to the prior art system described above with respect to
In high volume sewing operations, there may be a large number of bobbin case assemblies which require setup on a one-by-one basis and periodic adjustments as these systems are operated. Thus, minimizing adjusting time and simplifying adjustment procedures are key to economical operation of such sewing operations. The industry continues to seek out ways to predictably select draw tensions, at or close to desired values, without complicated setup procedures or excessive adjustment as the system is monitored both at startup and during use.
In one form, the invention is directed to a bobbin case assembly having a wall structure mountable operably upon a support and defining a first receptacle within which a supply of thread is stored, and a tensioning assembly for exerting a frictional force on the thread extending away from the receptacle to thereby resist drawing of the thread out of the receptacle. The tensioning assembly has a first surface that bears against the thread extending away from the receptacle. At least one of the wall structure and tensioning assembly has a second surface. The thread extending away from the receptacle resides between the first and second surfaces so that the frictional force on the thread is generated between the first and second surfaces. At least one of the first and second surfaces is defined by a body that is bendable to thereby allow one of the first and second surfaces to be moved selectively towards and away from the other of the first and second surfaces. The body has a mounting portion and a flexing portion which projects away from the mounting portion. The flexing portion is bendable relative to the mounting portion and has a first flexing region and a second flexing region. The second flexing region is more flexible in bending relative to the first flexing region than the first flexing region is flexible in bending relative to the mounting portion. The first surface is defined on the second flexing region.
In one form, the first and second flexing regions are connected by a hinge portion.
In one form, the body has a length and the first and second flexing regions are spaced from each other lengthwise of the body.
The body has a cross-sectional area as viewed in a plane extending transversely to the length of the body. The cross-sectional area of the hinge portion may be locally reduced.
In one form, the first and second flexing regions are spaced from each other lengthwise of the body. The cross-sectional area of at least a part of the second flexing region is less than the cross-sectional area of at least a part of the first flexing region to allow a two-stage flexing of the body as the first surface bears against the thread.
The tensioning element may be selectively adjustable to set and maintain a plurality of different magnitudes of frictional force on the thread extending away from the receptacle.
The tensioning assembly may be selectively adjustable through a threaded fastener.
In one form, the wall structure has a peripheral wall which defines the second surface.
The thread may project from the receptacle through the peripheral wall.
In one form, the body has a flat surface with oppositely facing surfaces and one of the oppositely facing surfaces defines the first surface.
In one form, the wall structure has a peripheral wall with a curved shape and the body is shaped to at least nominally match the curved shape of the peripheral wall.
The bobbin case assembly may be provided in combination with a thread drawing mechanism for engaging and drawing the thread from the receptacle.
The combination may further include at least one component for generating stitching using thread drawn from the receptacle by the thread drawing mechanism.
The invention is further directed to the combination of a bobbin case assembly and first and second tensioning assemblies. The bobbin case assembly has a wall structure mountable operably upon a support and defining a receptacle within which a supply of thread is stored. The first thread tensioning assembly has a first body for exerting a two-stage frictional force on the thread extending away from the receptacle to thereby resist drawing of the thread out of the receptacle. The second tensioning assembly has a second body for exerting a two-stage frictional force on thread extending away from the receptacle to thereby resist drawing of the thread out of the receptacle. The first and second tensioning assemblies have different frictional force generating characteristics. The first and second tensioning assemblies are interchangeably operatively mountable on the wall structure to allow selection of desired force generating characteristics.
In one form, the first body is made from a first material and the second body is made from a second material, with the difference in the first and second materials accounting for different frictional force generating characteristics with the first and second tensioning assemblies operatively mounted on the wall structure.
In one form, the first and second bodies have different dimensions that account for different frictional force generating characteristics with the first and second tensioning assemblies operatively mounted on the wall structure.
In another form, the first and second bodies have different configurations that account for different frictional force generating characteristics with the first and second tensioning assemblies operatively mounted on the wall structure.
In one form, the first body has a first mounting portion and a first flexing portion which projects away from the first mounting portion. The first flexing portion is bendable relative to the first mounting portion and has a first flexing region and a second flexing region. The second flexing region is more flexible in bending relative to the first flexing region than the first flexing region is flexible in bending relative to the first mounting portion.
The first and second flexing regions may be connected by a hinge portion.
In one form, the first body has a length and the first and second flexing regions are spaced from each other lengthwise of the body.
The combination may further include a support to which the wall structure is operably mounted.
The combination may still further include a thread drawing mechanism for engaging and drawing the thread out of the receptacle.
The combination may further include at least one component for generating stitching using the thread drawn from the receptacle by the thread drawing mechanism.
The invention is further directed to the combination of a wall structure, a body mounted operatively on the wall structure, and first and second adjusting elements. The wall structure is mountable operably upon a support and defines a first receptacle within which a supply of thread is stored. The body has a surface for generating a frictional resistance force on thread projecting from the supply in the receptacle. The first adjusting element is operable to reposition at least a part of the body relative to the wall to thereby vary a frictional resistance force generated by the body on the thread and has a first adjusting capability. The second adjusting element is operable to reposition at least a part of the body relative to the wall to thereby vary a frictional resistance force generated by the body on the thread and has a second adjusting capability that is different than the first adjusting capability. The first and second adjusting elements are selectively interchangeably useable to thereby allow a user to select a desired adjusting capability with respect to a frictional resistance force generated by the body on the thread.
In one form, the first and second adjusting elements are first and second threaded adjustment screws, respectively. Each adjustment screw has a thread length. The thread length of the first adjustment screw is different than the thread length of the second adjustment screw to account for the different adjusting capabilities of the first and second adjusting elements.
The wall structure has an outside wall surface. In one form, the first and second adjusting elements each have a fully tightened state. The surface of the body is spaced further from the outside wall surface with the first adjusting element in its fully tightened state than with the second adjusting element in its fully tightened state to thereby account for the different adjusting capabilities of the first and second adjusting elements.
The present invention is directed to an improvement in the thread tensioning assembly 54, previously described with respect to
In
In
According to the invention, the flexing portion 106 has first and second flexing regions 110, 112. The second flexing region 112 is more flexible in bending relative to the first flexing region 110 than the first flexing region 110 is flexible in bending relative to the mounting portion 104. In this particular embodiment, the different flexing characteristics at the first and second flexing regions 110, 112 are attributable to different thicknesses T, T1 for the first and second flexing regions 110, 112, respectively.
With this arrangement, as the adjustment screw 114, corresponding to the adjustment screw 88, previously described, is tightened, the free end 116 of the body 102 is urged towards the peripheral wall 47, in the direction of the arrow 118 in
Accordingly, as the body 102 is loaded against the thread 34 and peripheral wall 47, as the adjustment screw 114 is progressively tightened, the magnitude of the frictional resistance force between the thread 34 and body 102 is significantly affected by reactive bending of the body 102. A force produced on the thread 34, by urging the body 102 towards the peripheral wall 47, is diminished by reason of the combined effect of the first flexing region 110 deforming/flexing in a first manner and the second flexing region 112 deforming/flexing in a second manner. With this two-stage arrangement, the force that would be imparted to the thread 34, by urging the first flexing region 110 towards the peripheral wall 47 by tightening the adjustment screw 114, may be significantly reduced or tempered by the flexing of the second flexing region 112 relative to the first flexing region 110. Thus, relatively fine adjustments of draw tension are made possible by tightening the adjustment screw 114 in an otherwise conventional arrangement of elements.
The invention contemplates various different structures for allowing the two-stage flexing. In
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In
The invention also contemplates that an additional “stage” of flexing can be incorporated by changing the bending characteristics over the second flexing region. As shown in
The same capability can be incorporated by progressively varying a width W for a body 102′″″, shown in a further modified form of tensioning element 100′″″ in
A still further variation of the inventive concept is shown in
The two-stage flexing characteristics can also be incorporated by building a hinge portion into the tensioning element. As shown in
A like functioning hinge portion can be defined by other means which locally reduces the corresponding cross-sectional area thereat. As shown for example in
While the tensioning elements 100, 100′, 100″, 100′″, 100″″, 100′″″, 1006×′, 1007×′, 1008×′ have been shown to have bodies 102, 102′, 102″, 102′″, 102″″, 102′″″, 1026×′, 1027×′′, and 1028×′ that are made from a flat sheet stock material, this configuration is not critical. As just one other example, as shown in
It is also not necessary that the tensioning element be conventionally mounted through a cantilevered arrangement. As shown in
Still other configurations for the tensioning element 100, and manners of mounting the same to the peripheral wall 47, are contemplated by the invention. A broad range of modifications, contemplated by the present invention, are depicted generically in the schematic drawing in
Another aspect of the invention can be seen in
The configuration in
In one form of the invention, the tensioning elements on each of the first and second tensioning assemblies 154, 154′ are set or settable to generate one or more predetermined frictional resistance forces resulting in predeterminable draw tensions. A system operator may be made aware of what tensioning assembly 154, 154′ is to be selected and installed to produce the desired draw tension or range of draw tensions.
The tensioning assemblies 154, 154′ may include the tensioning elements, previously described, to cooperate with the surface 62 of the peripheral wall 20, or alternatively may be self-contained to have two cooperating surfaces between which the thread 34 is captively located. These different structural options are shown in
In
In
The invention also contemplates selling a kit, as shown at 170 in
A still further form of kit, according to the present invention, as shown in
Other variations are contemplated by the invention. As just one example, coatings may be provided on surfaces against which the thread 34 bears, to thereby alter the frictional resistance force thereon.
The foregoing disclosure of specific embodiments is intended to be illustrative of the broad concepts comprehended by the invention.