Pivoting magnet latches for improved weaving device

Textiles: weaving – Warp manipulation – Shedding

Reexamination Certificate

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Details

C139S059000, C139S085000

Reexamination Certificate

active

06216748

ABSTRACT:

TECHNICAL FIELD
The present invention relates to a weaving device and more specifically an improved latch for use with a Jacquard weaving device.
BACKGROUND OF THE INVENTION
Weaving devices, commonly called looms, are known in the art and have been in existence in one or another form for thousands of years. Weaving devices are generally used for producing woven fabric. Generally speaking, weaving devices consist of a frame, a generally horizontal array of eyelets movably supported by the frame between an upper position and a lower position, and a mechanism for moving the eyelets between the two positions.
To set up a typical weaving device for operation, a thread, or any type of weavable strand, is drawn off a spool and passed through an eyelet of the weaving device, then passed through a guide which is on the opposite side of the eyelet from the spool. The guide may be in the form of a long horizontal slot, or a gap between to horizontal, vertically opposed rollers. Each eyelet is threaded in this manner with an individual thread.
Selected eyelets are oriented the upper position and slightly above the guide, while the remaining eyelets are oriented in the lower position and slightly below the guide. This difference in the relative positions of the eyelets with respect to each other and to the guide, causes the threads to form an upper and lower row of parallel threads. The upper row passes from the upper eyelets to the guide, and the lower row passes from the lower eyelets to the guide. The two rows intersect, or meet, at the guide to form an acute interior corner. This formation of two rows of threads is generally called a shed. Thus, a shed can basically be described as two flat planes, each formed by a row of parallel threads, which meet to form a trough, or corner.
To begin the weaving process a cross-thread, called a weft thread, is placed into the corner of the shed where the threads meet at the guide, and perpendicular to the warp threads. After placement of the weft thread, the position of each eyelet is reversed—that is, the upper eyelets move to the lower position, and the lower eyelets move to the upper position. This change in position of the eyelets not only forms another shed, but also causes the warp threads to partially wrap around the weft thread. A second weft thread is then inserted into the corner of the new shed, and the position of each eyelet is again reversed. This process is continually repeated to form a fabric created from interlacing, or weaving, the warp and weft threads.
Basic woven fabric is produced on weaving devices which move the eyelets in a continuously repeating sequence of shed changes to produce a homogeneous fabric pattern. However, special type of weaving device, called a Jacquard device, may be used, among other purposes, to weave intricate or varying patterns into the fabric, or to perform seaming operations wherein two edges of fabric are woven together.
Jacquard devices are also well known in the art and have been in existence for hundreds of years. In a Jacquard device, each eyelet is individually selectively movable with each shed change. In other words, the sequence of movements of the eyelets is not merely repetitive, but may vary with each shed change.
Generally speaking, a Jacquard weaving device consists of an array of springs mounted on the top end of the frame of the weaving device. An eyelet is attached to each of the springs and hangs from the lower end of the spring. The springs bias the eyelets toward an upper position. A pulley block is attached to the lower side of each eyelet and hangs below the eyelet. A cord is strung through the pulley block, engaging the sheave, or pulley wheel, and both ends of the cord hang below the pulley block. The cord has two hooks attached to it, one on each end, which hang below the pulley block.
Attached to the frame, are two parallel horizontal bars, called griff bars, which reciprocally move up and down below the pulley block. The griff bars ire mechanically linked together so that, as one griff bar moves up, the other correspondingly moves down, and vice versa. An actuator is coupled to one of the griff bars to reciprocally move the griff bars at continuously repeating intervals.
The hooks are both engaged to guides mounted on the frame which restrict the path of movement of the hooks such that the path of movement of one of the hooks coincides with that of one of the griff bars, and the path of movement of the other hook coincides that of the other griff bar. Each hook has a slot or similar means which is open at the top, such that as the respective griff bar moves downward, it engages the slot, capturing the respective hook and pulling it downward. If the hook is held in its lowest position, the upward facing slot on the hook allows the griff bar to disengage the hook and move upward while leaving the hook in its lower position.
The cord which is connected between the hooks is of such a length that the respective spring, located above the eyelet, keeps the cord taught at all times. When both hooks are engaged to each respective griff bar, the hooks and cord travel in a reciprocal see-saw motion along with the griff bars, with the cord being pulled back and forth through the pulley block and rolling over the sheave. During this see-saw motion, the pulley block and eyelet remain stationary in the upper position, being held up by the tension of the respective spring.
The lower end of each hook is engageable with a pair of latches which are mounted on the frame and are located near the bottom of the path of travel of the respective hook. Each latch selectively captures and retains the respective hook in the lower position. As previously mentioned, if one of the hooks is held in its lower position by the respective latch, the respective griff bar disengages the hook as it travels upward, leaving the hook retained by the latch in the lower position. As the first griff bar moves upward, leaving one of the hooks retained by the first latch, the second hook is simultaneously pulled downward toward the second latch by the second griff bar as the first griff bar travels upward. Because the first hook is latched in the lower position, and is not allowed to raise up as the second hook is being pulled downward, the pulley block is pulled downward by the cord attached between the hooks, which pulls the eyelet downward against the force of the respective spring. This results in the eyelet reaching a lower position as both hooks are in their respective lower positions.
For the eyelet to remain in the lower position, both the first and second hooks must be retained in their respective lower positions by their respective latches. In this manner, the griff bars continue to reciprocally move in a see-saw motion above both hooks, but do not cause movement of the hooks, cord, pulley block, or eyelet.
Conversely, for the eyelet to raise to its upper position once again, one of the latches must disengage its respective hook as the respective griff bar is in the lower position and engaged to the respective latch. In this manner, one of the hooks is released by the latch and allowed to raise up with the griff bar to its upper position under the tension of the spring. This results in the respective pulley block and eyelet moving upward to their respective upper positions. For the eyelet to remain in the upper position, the other latch must also release its respective hook, allowing the see-saw motion of the hooks and cord to resume as initially described.
Many Jacquard weaving devices utilize electric solenoids to cause the selective retention of the hooks by the latches. In this type of design, an electric solenoid is mounted on the frame near each respective latch. Mounted on each latch is a material, such as iron, which is attracted by the magnetic field produced by the solenoid when the solenoid is energized with electrical current. Generally, each latch is biased in a latched position. As a hook is moved into engagement with the respective latch, the hook pushes the latch into its unlatched position a

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