This application claims the benefit of Swiss Patent Application No. 00146/12, filed Feb. 2, 2012, which is incorporated herein by reference as if fully set forth.
The subject matter of the present invention is a hook system for a sewing machine.
Hook systems are known. The hook system of the sewing machine guides the upper thread around the lower thread so that a knot can be formed.
The present hook system is a hook system that makes possible a CB-hook-type knot formation. In such hook systems, the upper thread loop, which is guided around the lower thread, is not rotated or twisted; rather, the upper thread runs around the lower thread in a U shape and consequently pulls the lower thread untwisted into the sewed material at the underside. In order to be able to do this, the loop of the upper thread must be guided around the hook body, with the bobbin and the bobbin case situated therein, by the hook tip. This means that the hook body, or hook for short, is not connected to the hook driver via a shaft, but rather is freely mounted in a hook race, and can be set into rotation by the hook driver using suitable means. The further problem occurs here that the upper thread and also the lower thread are braked in irregular fashion by the elements of the hook system, so that changes in thread tension caused by this are detectable later in the stitch pattern.
In such hooks mounted freely in a hook race, there is also the problem that the upper thread, or the upper thread loop, can become clamped between the hook and the hook race during the guiding through. In order to make it possible to release the clamped thread, currently the hook has to be removed from the hook race. This is laborious for the operator, and requires a certain degree of dexterity.
In the known hook systems, there is the further problem that the lower thread, which is pulled into the sewed material by the upper thread, briefly accelerates the lower thread bobbin, so that an overrun of the lower thread cannot be avoided. This causes changes in the thread tension that can again result in a non-optimal stitch pattern.
Therefore, an object of the present invention is to create a hook system that enables the upper thread loop to be pulled off, or pulled into the material being sewed, with as little friction as possible, or with as constant a level of friction as possible.
A further object of the present invention is to increase the sewing speed, i.e. the number of stitches per time unit, and to minimize the production of noise despite the higher stitch count.
A further object of the present invention is to counteract the clamping of the upper thread in the hook race, and, should a thread nonetheless become clamped, to make it easily releasable from the hook race.
A further object of the present invention is to compensate, to the greatest degree possible, the changes in thread tension caused by the necessarily jerky pulling on the lower thread.
These objects are achieved by hook systems according to the features of the invention.
According to the present invention, the upper thread loop can successfully be guided untwisted around the hook, and thus also around the bobbin case and the bobbin mounted therein, in circulating fashion, i.e. circulating in only one direction of rotation. Through the alternating and, between the alternations, simultaneous engagement of at least two drive cams in the back of the hook body, this body is on the one hand driven continuously while on the other hand space is always created for the frictionless passage of the upper thread loop between the hook and the bobbin case.
The conical design of the hook race for the hook, in combination with an elastically acting axial guiding of the hook in the hook race, makes it possible to release a clamped upper thread without disassembling the hook.
Using a spring that is situated between the bobbin on the bobbin case and is pivotable along the circumference of the bobbin case, changes in the take-off speed of the thread and tension peaks on the lower thread are compensated.
Using a lubricating element, the drive cams can be permanently lubricated, thus preventing wear thereof and increased noise caused thereby.
The present invention is explained in more detail on the basis of illustrated exemplary embodiments.
a shows a perspective view of a hook driver and, in diagonal section, a hook, with drive cams situated vertically one over the other,
b shows the same view as
a shows an enlargement of segment A in
a shows an enlargement of segment B in
For clarity, the representation of the sewing machine has been omitted in the Figures. Likewise, the drive means for the hook driver, e.g. the main shaft in the lower arm of the sewing machine, are not shown. These have long been known from the prior art.
Specifically shown are, in the foreground of
Drive cams 17 are situated on a cam support 19 that is displaceably guided in a guide bearing 21, which is e.g. disk-shaped. Guide bearing 21 is situated so as to be capable of rotation and capable of being driven on a shaft 35 that is placed in rotationally fixed fashion in the lower arm of the sewing machine. In the depicted example, in the guide bearing 21 there are fashioned two diagonally situated slots 23 in which the two drive cams 17 are guided so as to be essentially radially displaceable.
In the cam support 19, a centrally situated opening 25 is further fashioned in two guide surfaces 27 that run parallel to one another. Between the guide surfaces 27, a sliding block 29 is placed in the opening 25 that can be moved back and forth between the two guide surfaces 27, guided with a small amount of play. The sliding block 29 is supported in its center by a bolt 31. The bolt 31 is connected to the front end of the shaft 35. The bolt 31 is fastened on the end face of shaft 35, eccentrically to axis of rotation X (see
The guide bearing 21 is seated so as to be capable of rotation and capable of being driven on non-rotatable shaft 35. The drive of the guide bearing 21 is explained below. The rotation of guide bearing 21 on shaft 35 causes cam support 19 to move back and forth. The sliding block 29, mounted rotatably on bolt 31, causes cam support 19 to move drive cams 17 in alternating fashion radially into and out of openings 15 on the back 14 of hook 1. In the intermediate positions between the upper and lower end positions of bolt 31, situated eccentrically to axis X of shaft 35, the two drive cams 17 are simultaneously engaged with both slots 15. This means that, independent of the angle of rotation of guide bearing 21, hook 1 is uninterruptedly in positive connection with drive cams 17, and is therefore continuously driven.
In order to enable the hook 1 to be driven with the drive cams 17, or to bring it into driven connection, the guide bearing 21 is for example set into rotation via a gear 37 that is mounted so as to be freely rotatable on stationary shaft 35, and is fixedly connected on the back of the guide bearing 21. The gear 37 is preferably driven by the main shaft.
During operation, in a known manner catch tip 39 on hook 1 forms an upper thread loop and guides it around the hook 1. The eccentric drive for the hook 1 is set such that the drive cam 17 in the region of the upper end position of the hook 1 is lowered in the moment of the passing through of the thread loop; i.e., it moves out of engagement with the hook 1. The upper thread loop can in this way slide through between a conical guide race 41 in which the hook 1 is rotatably mounted. In the angular region in which the one drive cam 17 is out of engagement with hook 1, the other drive cam 17, situated approximately opposite, moves into the other slot 15 and during this time solely takes over the positive transmission of the rotational movement to hook 1.
As soon as the upper thread loop has left the hook 1, the drive cam 17, which previously was still not engaged, again travels into the slot 15. Both of the drive cams 17 are now temporarily engaged on the hook 1.
In order on the one hand to guarantee operation with as little wear as possible, and on the other hand to make operation as low-noise as possible, on the inner side between the guide bearing 21 and the hook 1 there is situated a lubricating element 63 that lubricates the parts of the drive cams 17 that come into contact with the walls or side surfaces in the openings 15. The lubricating element 63 can for example be placed on or in a carrier disc 65, in such a way that some lubricant is dispensed onto the drive cams 17 during each advance and retreat of the drive cams 17. The carrier disc 65 can be fashioned as an exchangeable wearing part that can be exchanged after a specifiable time of use of the sewing machine. The lubricating element 63 is for example a felt panel placed into the support disc 65 or fastened thereon. Preferably, the felt panel is accessible from the hook side, and oil can be dripped onto it.
The hook or guide race 41 expands conically towards the open side, and is made in hook race carrier 7. Likewise, the edge 3 of hook 1 extends conically and is fashioned with the same cone angle. In order to prevent hook 1 from falling out of hook race 41, a magnet system, in the form of one or more magnets 43, can be placed in the guide bearing 21 or in the back of the hook 1 (
The hook race cover 45 is mounted so as to be elastically flexible axially, e.g. due to a spring mounting using a spring 47. This makes it possible to easily release a thread 49 clamped between the hook 1 and the hook race 41, by lifting the hook 1 away somewhat from the hook race 41 at the location of the clamping by pulling on the thread 49, so that the clamped thread can be released. Due to this measure, a cutting device on the hook 1 can be omitted, and the handling of a clamped thread 49 is significantly simplified. In other words, the previously required axial pulling out of the hook 1 from the hook race 41 can be avoided simply by pulling on the thread 49. For this purpose, the forces of the magnets 43 and of the spring 47 are matched to the machine drive.
Due to the conical construction of the hook race 41, the placing of the hook 1 into the guide race 41 is also significantly simpler than is the case given a cylindrical hook race. The hook 1 cannot become tilted, and therefore cannot become stuck, in the hook race 5.
At least two ramps 61 are fashioned on an annular surface 59 that is situated perpendicular to the axis of rotation of the hook 1, connected to the hook race 41. These ramps extend over an angular range on annular surface 59. The ramps 61 are situated over the slots 23 through which the drive cams 17 engage in the hook back 14.
The ramps 61 prevent the hook 1 from pivoting out of its situation coaxial to the hook race carrier 7 when the drive cams 17 move into the openings 15; such pivoting could cause the hook to wobble at higher sewing speeds. The ramps 61 deflect the needle 67 minimally from its axis.
As shown in
In the hook race carrier 7, an oil reservoir 57 can be fashioned from which oil can exit onto the hook race 5 in a specifiable quantity in order to bring about a maximally friction-free gliding of the hook 1 on the hook race 5. This additionally reduces the production of noise.
Number | Date | Country | Kind |
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00146/12 | Feb 2012 | CH | national |