1. Field of the Invention
The present invention relates generally to manually and/or treadle operated spinning wheels. More specifically, the invention relates to a flyer and spindle brake assembly for hand spinning wheels.
2. Description of the Related Art
Hand spinning wheels, i.e., yarn, thread, or other fiber spinning or twisting machines utilizing manual power for their operation, have a lengthy history. Historically, such wheels were used to produce the vast majority of spun fiber material (yarn, thread, and other fiber for cloth, etc.) until the development of large, powered industrial spinning machines. However, such manually powered spinning machines or spinning wheels are still popular today in many parts of the world where electricity or other power is generally not available, or where the use of such power is not desired for some reason. Also, manually powered spinning wheels are popular with a large number of hobbyists who enjoy using such older technology and working with their hands.
Generally speaking, manually operated spinning wheels are compound machines, in that they perform two functions. First, the machine twists the filaments together as they are fed into the machine to produce a twisted yarn, thread, string, cord, or the like. Secondly, as a length of twisted material is produced, the machine is used to take up the twisted yarn onto a spool or bobbin for storage. These two functions are accomplished by a relatively rapidly rotating “flyer” or bail, which at least generally surrounds the spool or bobbin. The flyer is rotated by a drive band extending from the large flywheel (probably the most readily recognizable feature of the classic spinning wheel) and around a smaller “whorl” or flyer drive pulley.
It will be understood that the takeup spool or bobbin is configured to rotate independently of the flyer, which rotates continuously so long as the large flywheel is being rotated (e.g., by a treadle mechanism, or by hand, etc.). When the yarn or cord is being twisted, it is not being taken up on the bobbin. During this portion of the operation, the flyer and bobbin rotate in unison with one another. Thus, even though the yarn or thread is being spun around the bobbin by the rotation of the flyer, it cannot be taken up on the bobbin, as the bobbin is rotating at the same rate. This operation results in a twist being produced in the filaments or fibers, thus producing a twisted yarn, cord, or the like.
When sufficient twist has been imparted to the filaments, they may be stored by winding them onto the bobbin or spool. This is accomplished by changing the rotary speed of the bobbin relative to the constantly rotating flyer, generally by braking the bobbin so that it is rotating more slowly than the flyer. This difference in rotational velocities between the two components, results in the flyer winding the twisted yarn onto the bobbin or spool for storage. When the twisted portion of the yarn has been wound onto the bobbin, the rotation of the bobbin is again matched with the rotation of the flyer, thereby resulting in the twisting of the filaments with no takeup onto the bobbin. The operation is repeated as desired to produce a relatively long length of twisted yarn, thread, cord, or the like.
Conventionally, most spinning wheels utilize an open-ended flyer, i.e., the two arms of the flyer are not connected to one another at their distal ends. This facilitates the removal and installation of the bobbin or spool onto the spindle, but a separate retaining component (e.g., threaded fastener, lateral pin, etc.) is still required to secure the bobbin on the spindle. Moreover, such an open-ended flyer structure is relatively weak in comparison to a closed flyer, which completely surrounds the bobbin. The reason that closed flyers have not proven popular is that up to the development of the present invention, such a mechanism has required additional fastening components, which must be removed in order to remove or replace the bobbin. This requires a fair amount of time for each bobbin removal and replacement, as well as increasing the cost of the mechanism and the chance of losing various small parts.
An example of such an open-ended flyer is found in German Patent No. 3,529,076, published on Sep. 10, 1987, describing an electrically powered tabletop fiber spinning appliance. It appears particularly from
Insofar as the spindle or bobbin brake mechanism is concerned, it is generally desirable to adjust the spindle, or the bobbin rotating on a stationary spindle, with a slight amount of drag or braking force. The tension applied to the yarn by the person spinning is sufficient to prevent takeup of the yarn onto the bobbin, thus resulting in a purely twisting force being applied to the yarn filaments. Relaxation of the tension on the spun yarn or thread allows the brake to slow or stop the bobbin or spindle rotation relative to the flyer, thereby allowing the yarn or thread to be wound upon the bobbin by the flyer for storage of the twisted yarn.
However, in the past it has proven difficult to provide a bobbin or spindle brake that may be easily and precisely adjusted to produce exactly the desired braking force. While a relatively large amount of effort has gone into the development of spindle and/or bobbin brakes for large, automated industrial spinning and winding machines and looms, comparatively little development has occurred in spindle or bobbin brake systems in manually or treadle operated spinning wheels. Conventional bobbin or spindle brakes tend to be relatively primitive devices, and generally fail to provide the required degree of fine adjustment for accurate work.
Thus, a flyer and spindle brake assembly for hand spinning wheels solving the aforementioned problems is desired.
The flyer and spindle brake assembly for hand spinning wheels includes an adjustably rotating spindle upon which the yarn spool or bobbin is removably installed. The spindle is cantilevered from a single maiden post, with an adjustable spindle braking mechanism disposed in the upper end of the post through which the support end of the spindle passes. The flyer or bail extends around the spindle and any spool or bobbin installed thereon, with the flyer having a closed distal end selectively capturing the distal end of the spindle therein and including an axially disposed yarn orifice or guide beyond the spindle bearing. The attachment base end of the flyer is pivotally secured to a collar or sleeve, which is, in turn, rotationally affixed to the rotating whorl or flyer drive pulley, being driven by the drive belt from the larger diameter flywheel. A coil spring is installed on the spindle between the spool drive mandrel and the flyer attachment collar, the spring urging the collar (and therefore the flyer) toward the maiden post, thereby securing the spindle bearing of the distal end of the flyer about the distal end of the spindle during operation.
The device is used by initially drawing the flyer axially outwardly away from the maiden post by compressing the flyer retaining spring, thereby freeing the distal end of the spindle from the spindle bearing of the flyer. The flyer is then pivoted about its attachment points at the collar, thereby clearing the distal end of the spindle for the installation of a spool or bobbin thereon. The flyer is then repositioned to secure the distal end of the spindle in the spindle bearing of the distal end of the flyer in order to align the components axially with one another. The spindle brake may be adjusted as desired. Spinning operations may then commence, with the rotating flyer twisting the yarn, thread, etc. therearound so long as the bobbin or spool is allowed to rotate in unison with the flyer. When a length of spun yarn or cord has been produced, the tension on the spun material is relaxed, thereby allowing the brake to slow the rotational speed of the spindle and bobbin installed thereon. This results in the spun material being wound upon the relatively slowly spinning or stopped bobbin, as the flyer continues to rotate around the spindle and bobbin. Further tension on the fiber material overcomes the spindle brake, and causes the bobbin and spindle to rotate in unison with the flyer to twist another length of yarn, thread, or similar material. The process is repeated as desired, with the brake mechanism being adjusted as required for optimum operation.
These and other features of the present invention will become readily apparent upon further review of the following specification and drawings.
Similar reference characters denote corresponding features consistently throughout the attached drawings.
The present invention is related to the hand spinning wheel, in particular, a flyer or bail that obviates the need to remove components for access to the bobbin or spool, and a spindle brake device. The flyer and the brake assembly allow the person spinning yarn or thread to remove and replace the bobbin or spool much more rapidly than is the case with conventional systems, and further to more precisely adjust the spindle braking mechanism for more accurate control of the yarn or thread takeup.
The whorl 14 extends from the upper end of a single “maiden” or support post 18, which, in turn, extends upwardly from a generally horizontally disposed “mother” support bar 20. The mother bar 20 is adjustably positionable relative to the main wheel 12 in order to adjust the tension on the drive belt 16. Conventionally, the mother bar has two spaced-apart maiden posts extending upwardly therefrom, with the two opposite ends of the spindle being supported by the two opposed maiden posts. This necessitates the disassembly and removal of at least some components whenever the bobbin or spool must be replaced on the spindle. In contrast, the present mechanism utilizes only a single maiden post 18, with the spindle and associated components cantilevered from the single maiden 18.
The maiden post 18 has an upper end 22, which includes a laterally disposed spindle passage 24 and an axial spindle brake passage 26 normal to the spindle passage 24. These passages 24 and 26 are shown most clearly in
The whorl pulley 14 is, in turn, installed concentrically upon the spindle 28 adjacent to the maiden post 18, and is free to rotate and slide axially upon the spindle 28. Although the whorl 14 illustrated in
A pair of diametrically opposed arms 46 extend from the collar attachment pins 44 of the flyer 40 to a point adjacent the distal end 32 of the spindle 28. The arms 46 preferably each include at least one, and preferably a series of, level winding hooks 48 disposed therealong. A crossmember 50 extends between the distal portions of the two flyer arms 46, with the crossmember 50 having a spindle end bearing 52 disposed centrally therein. The two flyer arms 46 terminate at their distal ends in a yarn orifice 54, with the orifice 54 having an axis A concentric with the spindle end bearing 52. Thus, the orifice 54 is aligned with the axis of the spindle 28 when the spindle end bearing 52 of the flyer 40 is engaged with the distal end of the spindle 28, as shown in
A yarn collection bobbin or spool 56 is removably installed upon the spindle 28, and rotates in unison with the spindle by means of a bobbin drive mandrel 58 immovably and affixed to the spindle 28 for rotation with the spindle 28. A compression spring 60 is disposed upon the spindle 28 between the flyer attachment collar 36 and the bobbin drive mandrel 58. The spring 60 serves to prevent the flyer attachment collar 36, and thus the flyer 40, from sliding axially along the spindle 28 and releasing the spindle end bearing 52 of the flyer 40 from its seated position upon the distal end 32 of the spindle 28. However, the spring 60 is normally not in compression and does not normally bear upon the collar 36 or mandrel 58 until the flyer attachment collar 36 (and its attached whorl 14 and flyer 40) are urged toward the distal end 32 of the spindle 28. This allows the spindle end bearing 52 of the flyer 40 to release from the distal end 32 of the spindle 28, thereby allowing the flyer 40 to pivot radially relative to the spindle 28 rotation of the flyer attachment pins 44 in passages 38, generally as shown in
The flyer 40 rotates in unison with the flyer attachment collar 36 and whorl pulley 14, as described further above, when driven by the flywheel 12 and drive belt 16. The rotation of the flyer attachment collar 36 and whorl 14 result in some frictional drag upon the spindle 28, thus urging the spindle and its bobbin 56 captured thereon to rotate in unison with the flyer 40 during the spinning operation. This results in a pure spinning of the yarn or other fiber material, since the rotation of the spindle 28 and bobbin 56 in unison with the flyer 40 cannot wind the yarn onto the bobbin, as there is no relative rotary motion between the bobbin 56 and flyer 40. However, if the rotation of the spindle 28 and its bobbin 56 are slowed or braked relative the rotation of the flyer 40, the difference in relative rotational speeds between the flyer 40 and bobbin 56 will result in the previously twisted yarn or thread being wound upon the bobbin for storage thereon. Accordingly, the winding operation may be controlled by regulating the rotational speed of the spindle 28 and its bobbin 56 relative to the flyer 40.
This may be accomplished by a brake mechanism, e.g., 34a of
The brake assembly 34b of
In conclusion, the flyer and spindle brake assembly for hand spinning wheels greatly facilitates the spinning operation for persons using such devices. The ease of removal and replacement of bobbins by means of the flyer and spindle mechanism of the present invention greatly speeds the operation and reduces the down time when the wheel is not rotating and no spinning is being performed. The spindle brake allows the spinning person to adjust the spindle drag quite accurately, thereby enabling the spinner to achieve precisely the twist desired when spinning yarns and threads of various materials and textures. Accordingly, spinning wheels incorporating the flyer and brake spindle assembly will be much appreciated by those involved in the spinning craft.
It is to be understood that the present invention is not limited to the embodiments described above, but encompasses any and all embodiments within the scope of the following claims.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 60/872,476, filed Dec. 4, 2006.
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Number | Date | Country | |
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20080127624 A1 | Jun 2008 | US |
Number | Date | Country | |
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60872476 | Dec 2006 | US |