DE102010017947A1 - Plate for knitting needle of flat knitting machine, has functional element base formed in two different heights for functional element, where lowering of drive base into functional element bed is controlled - Google Patents

Abstract

The plate (11) has a drive base (16) lifted over a functional element bed (100) i.e. needle bed, by pivoting the plate around axles by a lifting linkage. A functional element base (115) is formed in two different heights for a functional element (10). The functional element and the plate are pivotably arranged in a common functional element channel (110) of the functional element bed. Lowering of the drive base into the bed is controlled. The drive base is lifted against spring force. The plate is backwardly movable in an inactive starting position over a positioning base (12).

Description

The invention relates to a circuit board for a functional element of a knitting machine, wherein with the board a lowered in a functional element bed drive foot of the functional element via the functional element bed can be raised.

Such boards for functional elements in the form of knitting needles of knitting machines, in particular of flat knitting machines, are already known. For example, describes the DE 687608 a board with which a sunk into the functional element bed drive foot of a knitting needle can be raised via the functional element bed, so that the drive foot of a lock curve of a knitting system can be detected. The path taken by the drive foot through the knitting cam determines what function the knitting needle performs, that is, whether it forms stitches, takes a catch or remains in an inactive position.

The known boards are complex in construction. In addition, there is no way to prevent the unintentional lowering of the drive feet of the needles when the knitting needles are heavily loaded in the axial direction.

With certain types of knits or knit patterns, it is advantageous to knit different stitches in a knit row differently. This can be realized by the fact that the drive foot of the needle protrudes differently far from the functional element bed and thereby receives engagement in different cam curves, see, for example. DE 38 36 806 A1 ,

In the illustrated solution, the board (lifting board) must be guided through the knitting lock at a defined distance from the needle. There are two successive drive feet of the needle required.

The present invention has for its object to provide a circuit board, which allows both a reliable lifting of a drive foot of a functional element and can reliably prevent unintentional lowering of the drive foot in the functional element bed. In addition, if necessary, the functional element to be driven with reduced foot engagement in the lock plate.

The object is achieved by a board for a functional element of a knitting machine, wherein the board a lowered in a functional element bed drive foot of the functional element via the functional element bed can be raised, which is characterized in that with the board a functional element base for the functional element in at least two different heights is formed, with the lowering of the drive foot of the functional element can be prevented in the functional element bed.

The board according to the invention is thus able to form a functional element base over which the functional element can slide, in particular during its return movement in the functional element channel and which prevents the drive foot from lowering when the functional element is loaded axially. At the same time, the board ensures a reliable lifting of the drive foot of the functional element, so that it can be reliably detected by lock parts of a knitting system and can perform the desired functions such as stitching, catching, holding in inactive position (mesh take-up) or mesh transfer. The functional element may preferably have only one drive foot.

As a functional element is, for example, a knitting needle, a selection element or another element of a knitting machine in question. The board may be a lifting board or a selection board, which serves as a support depending on their way in the direction of activation of a drive foot in variable height. This makes it possible to bring the drive foot in different heights with different lock tracks in engagement. A 3-way Tehcnik (not knit - stitch - catch or handover - takeover - no action) is made possible. On a printer technology can be omitted. The board can be realized with a small length and simple structure, which saves manufacturing costs. The functional element bed can be for example a needle bed.

Further advantages result if the drive foot can be raised against the spring force acting on it by the circuit board. The provision of the drive foot in his lowered into the functional element bed position then does not have to be done by the board or another element. The provision is rather passively by the spring force, which is preferably generated by the functional element itself.

For the design of the board various possibilities are conceivable.

One possibility is to arrange the board linearly displaceable in the functional element channel. By moving the blank onto the functional element, the drive foot can be raised by means of a sinker section and the functional element bottom can be formed in at least one height, in particular at a first height. As long as the board remains in its advanced position, it thus forms the needle bottom, the unwanted lowering of the drive foot of the Function element prevented. With a single movement of the board thus both functions, the lifting of the drive foot and the formation of the functional element reason can be realized. It is further advantageous if the board can be moved back to its inactive starting position via a positioning foot. This retraction movement can be carried out at the end of a lock passage of the associated functional element. The drive foot of the functional element can thereby be recessed into the functional element bed. By different positions of the board in the axial direction of a functional element ground can be realized in different heights.

However, the board can also be arranged pivotably in the functional element channel. In this case, the drive foot of the functional element by a pivoting movement of the board can be raised and at the same time the functional element reason be formed. In particular, by pivoting the board about its axis by means of a lifting rocker the drive foot can be raised and the functional element ground can be formed in at least one height. A linear movement is not required here if the board already engages under the functional element in the region of the drive foot even in its inactive starting position. Then a pivoting of the board is sufficient to raise both the drive foot and to form the functional element base, which prevents unintentional lowering of the drive foot. By different pivot positions of the board, a functional element ground can be realized in different heights.

In this embodiment, the board can be moved back into its inactive starting position by the drive foot or a force acting on it. The board must then be actively driven only to lift the drive foot.

However, it is also possible to make the board pivotable in one direction against a spring force or adjustable in height. Even then, an active drive only in a pivoting direction or against the spring force for the board is necessary. The provision of the board in its inactive starting position can be done in this embodiment by the spring force, ie passive.

The board can be guided along a guide. In particular, it may have a control cam, with a guide, for. B. a guide wire cooperates.

The circuit board and the functional element may be arranged in a common channel of a functional element bed or arranged in different beds.

The scope of the invention also includes a knitting machine having a functional element bed, a functional element arranged in a functional element channel of the functional element bed, and a circuit board according to the invention.

Hereinafter, preferred embodiments of the invention boards are explained in detail with reference to the drawings.

Showing:

1a to 1f a section through a functional element channel of a functional element bed with a first board and a first functional element;

2 one of the 1 corresponding sectional view with the board off 1 and a second functional element;

3a to 3e a section through a functional element channel of a functional element bed with a second board and a third functional element;

4 one of the 3 corresponding sectional view with the board off 3 and the functional element 2 ;

5a to 5f one of the 3 corresponding sectional view with a third board and the functional element 3 ;

6 one of the 5 corresponding sectional view with the board off 5 and the functional element 2 ;

7a to 7f a section through a functional element channel of a functional element bed with a fourth board and the functional element 1 ;

8th one of the 7 corresponding sectional view with the functional element 2 ,

1a to 1f each show sections through a functional element bed 100 in the area of a functional element channel 110 in which a trained as a knitting needle functional element 10 as well as a circuit board 11 are arranged. The functional element 10 becomes together with its neighboring functional elements by a cover rail 120 and the board 11 together with their neighboring boards by a cover rail 130 against being lifted out of the needle channel 110 secured. The functional element channel has a recess 19 in the functional element reason 115 on. The board 11 is supported by a spring element 11.1 on the cover rail 130 from.

In 1a are both the functional element 10 as well as the board 11 in their inactive starting position. The board 11 is using a positioning foot 12 has been moved backwards. The needle hook 13 of the functional element 10 is in the same position. In its rear area, the functional element 10 a resilient section 14 on the functional element body 15 on, at the rear end of a drive foot 16 for the functional element 10 is arranged. The springy section 14 pushes the drive foot 16 down, so this on a slope 17 or a surface 17 ' or 17 '' in the recess 19 the functional element reason 115 of the functional element bed 100 rests.

Now on the positioning foot 12 the board 11 a force in the direction of the arrow 18 exercised, as in 1b is shown, so pushes the board 11 the functional element 10 at her drive foot 16 forward. The drive foot slides 16 on the slope 17 upwards and is thus a bit far from the functional element bed 100 raised. He can now from over the functional element bed 100 moved, not shown here lock parts are detected. The board 11 lies in the in 1b shown position in front of a slope 17.1 , In a further shift of the board 11 in the direction of the arrow 18 she glides along the slope at the same time 17.1 upwards and thereby lifts the drive foot 16 until its full foot engagement from the functional element bed ( 1c ). Using the lock parts, the functional element 10 for example, in the 1d shown expelled position. During these functional element movements, the circuit board remains 11 in their driven position, in which they have a section 11a forms a functional element ground at a first height, the recess 19 closes and in the functional element reason 115 in the front area of the functional element bed 100 passes almost completely. This can be during the withdrawal of the functional element 10 , as in 1e is shown, the drive foot 16 of the functional element 10 over the through the section 11a slide away formed functional element base, without being accidentally recessed into the functional element bed. Only by actively moving the board back 11 at her positioning foot 12 in the in 1a shown starting position, the drive foot 16 through the resilient section 14 of the functional element 10 back into the functional element bed 100 be lowered. Due to the design of the board 11 So it can not be an unintentional lowering of the drive foot here 16 for example, by an axial load of the functional element 10 come.

In the 1f is the board 11 in one of the 1b corresponding position shown in the direction of the arrow 18 is advanced, but still on the surface 17 ' rests. This means that the top of the section 11a compared to 1e has a lower height. The drive foot 16 therefore protrudes less far above the functional element bed 100 out. The section 11a however, again forms a functional element ground, this time at a second height. This can be during the withdrawal of the functional element 10 , like in the 1f shown, the drive foot 16 of the functional element 10 over the through the section 11a slide away formed functional element ground, without him unintentionally back into the functional element bed 100 sunk. Only by actively moving the board back 11 at her positioning foot 12 in the in the 1a shown starting position, the drive foot 16 through the resilient section 14 of the functional element 10 back into the functional element bed 100 be lowered.

Through the resilient section 11.1 will ensure that the board 11 always pressed down into the functional element bed.

The 2 essentially corresponds to the 1f , In this case, however, is the functional element 20 constructed in two parts. The drive foot 26 This functional element is on a pivoting element 25 arranged, the hinged to the functional element shaft 21 connected is. The functional element shaft 21 has at its rear end a resilient portion 24 on, its free end in the drive foot 26 intervenes. The springy section 24 ensures that the drive foot 26 of the functional element 20 in the inactive starting position of the functional element 20 in the functional element bed 100 sunk.

The 3a to 3f show a section through a functional element bed 100 ' in the region of a functional element channel, wherein in the functional element channel a second embodiment of a circuit board 30 and a one-piece functional element 40 are arranged. The functional element 40 again has a resilient section 44 on, at the rear end of a drive foot 46 is stored. The board 30 is about an axis 31 pivotally mounted in the functional element channel. It also has a lift arm 32 on that the drive foot 46 of the functional element 40 engages below. Next she is with an actuating rocker 33 provided, with the help of which they can be placed in a pivoting movement. In the inactive starting position of the board 30 is the lifting arm 32 at the bottom of a recess 19 ' in the functional element bed 100 ' on or the actuating rocker 33 is supported by the cover rail 130 from. The drive foot 46 the likewise inactive functional element 40 is through the resilient section 44 pressed down and is thus in the functional element bed 100 ' sunk.

By pressure in the direction of the arrow 34 on the swingarm 33 pivots the board 30 , as 3b shows, and lifts with her lifting arm 32 the drive foot 46 of the functional element 40 via the functional element bed, so that it can be detected by lock parts of a knitting system. Subsequently, the functional element 40 driven out, for example, for stitch formation, which is in 3c is shown. During this propulsion movement, the force in the direction of arrow 34 on the swingarm 33 Stay that way, so that the lift arm 33 the recess 19 ' in the functional element bed 100 ' closes and a functional element reason 115 '' forms.

During the advancing movement of the needle 40 is the formation of a functional element ground by the lifting arm 32 but not required because the drive foot 46 of the functional element 40 yourself here on the functional element reason 115 ' in the front area of the functional element bed 100 ' supported and therefore can not be inadvertently sunk into the functional element bed. It is therefore also possible during the propulsion movement, the force on the drive rocker 33 to finish, so the lift arm 33 can swing down again.

During the retraction movement of the needle becomes the lifting arm 32 however again raised what was in 3d is shown.

Because the resilient section 44 of the drive foot 46 pushes down, must during the return movement of the functional element 40 the lifting arm 32 the board 30 by applying force to the actuating rocker 33 be raised when the drive foot 46 should remain in the raised state.

At the in 3e , f situation shown is the circuit board 30 shown in a pivoting position extending between the pivoting position according to 3a and the pivot position according to 3b located. Through the lifting arm 32 becomes a functional element reason 115 ''' which is slightly below the functional element reason 115 ' is arranged. This is the drive foot 46 at a different working height, in particular protrudes less far above the functional element bed 100 ' out than in the 3c . 3d ,

One of the 3f appropriate situation is with the board 30 and the functional element 20 according to 2 in 4 shown. In the functional element 20 is the drive foot 26 on a pivoting element 25 arranged. The pivoting element 25 is articulated on the functional element shaft 21 arranged and is by a resilient section 24 of the functional element shaft 21 in the relaxed state of the resilient section 24 pressed down. The drive foot 26 is located above the functional element bed and can thus be grasped by a lock. However, the drive foot is 26 not so far beyond the functional element bed as in the example in the in 3d shown situation. This is because the board 30 occupies an intermediate position and thus the Hebeschwinge 32 forms a functional element ground at a lower level.

The 3e 3f you can see that the rotatable board 30 is rotated during the Kuliervorgang depending on the depth of the chuck to keep the engagement height of the functional element constant.

The 5a to 5f show a further embodiment of a circuit board 60 , again around an axis 61 rotatable in the functional element channel of a functional element bed 100 ' is arranged. She works here with the needle 40 out 3 together. Unlike the board 30 Show her next to a lifting jib 62 and an actuating rocker 63 a spring element 64 on, that's the hilt 62 in the in 5a shown downwardly pivoted position forces. This must be the resilient element 44 of the functional element 40 only his drive foot 46 in the functional element bed 100 ' Lower. Should the drive foot 46 be raised, so is in the direction of arrow 66 a force on the actuating rocker 63 exercised, like 5b shows. Therefore, only one force must be exerted on the board to lift a lifting arm. From the comparison of 5b to 5d with the 5f it turns out that the lift arm 62 can form a functional element ground at different heights.

One of the 5f appropriate situation with the board 60 and the two-part functional element 20 according to 2 is in the 6 shown.

In the 7a are both the functional element 10 as well as the board 70 in their inactive starting position. The board 70 is using a positioning foot 71 have been moved to a rear end position. The height fixation of the board 70 via guidewires 72 . 73 , which by trained as cams guides 74 . 75 the board 70 protrude and fixed in the functional element bed. The guides 74 . 75 own sections 76 . 77 as well as sections 78 . 79 which is deeper in the board 70 are introduced as the sections 76 . 77 , With a linear movement of the board 70 so different height levels can be taken from this. The needle hook 13 of the functional element 10 is in the same position. In its rear area, the functional element 10 a resilient section 14 on the functional element shaft 15 on, at its rear end a drive foot 16 for the functional element 10 is arranged. The springy section 14 pushes the drive foot 16 down, so this on a slope 17 or a surface 17 ' in the recess 19 the functional element reason 115 of the functional element bed 100 ' rests.

Now on the positioning foot 71 the board 70 a force in the direction of the arrow 18 exercised, as in the 7b is shown, so pushes the board 70 the functional element 10 at his drive foot 16 forward. The drive foot slides 16 on the slope 17 upwards and is characterized by the functional element bed 100 ' raised. He can now from over the functional element bed 100 ' moved, not shown here lock parts are detected. In the in 7b position shown was the board 70 so far in the direction of the arrow 18 that shifted their guides 74 . 75 still at the height level of the sections 76 . 77 the guides 74 . 75 are located. In a further shift of the board 70 in the direction of the arrow 18 pass the sections 78 . 79 the guide wires 72 . 73 , causing the board 70 and thus the drive foot 16 to be raised slightly. This will get the drive foot 16 in a higher working height.

Using the lock parts, the functional element 10 for example, in the in the 7d shown expelled position. During these functional element movements, the circuit board remains 70 in their driven and raised position, in which they have a section 70a forms a functional element ground at a first height, the recess 19 closes and in the functional element reason 115a in the front area of the functional element bed 100 ' passes almost completely. This can be during the withdrawal of the functional element 10 , like in the 7e is shown, the drive foot 16 of the functional element 10 over the through the section 70a slide away formed functional element base, without being accidentally recessed into the functional element bed. Only by actively moving the board back 70 at her positioning foot 71 in the in the 7a shown starting position, the drive foot 16 through the resilient section 14 of the functional element 10 be lowered back into the functional element bed. Due to the design of the board 70 So it can not be an unintentional lowering of the drive foot here 16 , For example, by an axial load of the functional element 10 , come.

In the illustration according to 7f is the board 70 opposite the representation of the 7e lowered again. This means that the sections 76 . 77 the guides 74 . 75 the guide wires 72 . 73 have passed, so the guidewires 72 . 73 in the sections 76 . 77 the guides 74 . 75 are located. The drive foot 16 lies on the board section 70a through which a functional element ground is now formed at a lower level. This means that the drive foot 16 less far up beyond the functional element bed and under certain circumstances can now be detected by other lock parts.

The 8th shows a representation analogous to 7f with the difference that here again the two-part functional element 20 according to 2 is shown.

In the functional element 20 is the drive foot 26 on a pivoting element 25 arranged. The pivoting element 25 is articulated on the functional element shaft 21 arranged and is by a resilient section 24 of the functional element shaft 21 in the relaxed state of the resilient section 24 pressed down. The drive foot 26 is located above the functional element bed and can thus be grasped by a lock. However, the drive foot is 26 not so far beyond the functional element bed as in the example in the in 7d shown situation. This is because the board 70 occupies a lower position and thus forms a functional element ground at a lower level.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 687608 [0002]
• DE 3836806 A1 [0004]

Claims (13)

Board for a functional element ( 10 . 20 . 40 ) of a knitting machine, wherein with the board ( 11 . 30 . 60 . 70 ) into a functional element bed ( 100 . 100 ' . 100 ' ) lowered drive foot ( 16 . 26 . 46 . 56 . 76 ) of the functional element ( 10 . 20 . 40 ) via the functional element bed ( 100 . 100 ' . 100 ' ) is liftable, characterized in that with the board ( 11 . 30 . 60 . 70 ) a functional element reason ( 115 . 115 ' . 115 '' . 115 ''' ) for the functional element ( 10 . 20 . 40 ) is formed in at least two different heights, with a lowering of the drive foot ( 16 . 26 . 46 . 56 . 76 ) of the functional element ( 10 . 20 . 40 ) in the functional element bed ( 100 . 100 ' . 100 ' ) is preventable. Board according to claim 1, characterized in that the drive foot ( 16 . 26 . 46 ) is liftable against a spring force acting on it. Board according to claim 1 or 2, characterized in that it is linear in the functional element channel ( 110 ) is arranged displaceably. Board according to claim 3, characterized in that by moving the board ( 11 ) on the functional element ( 10 . 20 ) by means of a board section ( 11a ) the drive foot ( 16 . 26 ) and the functional element reason ( 115 ) is formed in at least one height. Board according to claim 3 or 4, characterized in that it has a positioning foot ( 12 ) is moved back into its inactive starting position. Board according to claim 1 or 2, characterized in that it is pivotable in the functional element channel ( 110 ) is arranged. Board according to claim 6, characterized in that by pivoting the board ( 30 . 60 ) about its axis ( 31 . 61 ) by means of a lifting arm ( 32 . 62 ) the drive foot ( 26 . 46 ) and the functional element reason ( 115 '' . 115 , '') can be formed in at least one height. Board according to claim 6 or 7, characterized in that it is driven by the drive foot ( 26 . 46 ) of the knitting needle ( 10 . 20 . 40 ) is moved back into its inactive starting position. Board according to one of the preceding claims, characterized in that it is pivotable in a direction counter to a spring force or adjustable in height. Board according to claim 9, characterized in that it is pivotable back or adjustable by the spring force in its inactive starting position. Board according to one of the preceding claims, characterized in that it is guided along a guide. Board according to one of the preceding claims, characterized in that the board ( 11 . 30 . 60 . 70 ) and the functional element ( 10 . 20 . 40 ) in a common functional element channel ( 110 ) of a functional element bed ( 100 . 100 ' . 100 ' . 100 ' ) are arranged or the functional element and the board are arranged in different beds. Knitting machine with a functional element bed ( 100 . 100 ' . 100 ' ), one in a functional element channel of the functional element bed ( 100 . 100 ' . 100 ' ) arranged functional element ( 10 . 20 . 40 ) and a board ( 11 . 30 . 60 . 70 ) according to any one of the preceding claims.

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