Technical field
[0001] This invention relates to a knitting needle driving mechanism of a circular knitting
machine.
[0002] More specifically, this invention relates to the knitting needle driving mechanism
of a circular knitting machine capable of knitting a predetermined pattern by making
or removing engagement between raising cams for applying vertical movement to a plurality
of knitting needles on a circular cylinder of the circular knitting machine and cam
butts of jacks engaging with lower ends of the knitting needles on the basis of a
predetermined knitting plan.
Prior art
[0003] As illustrated in Fig. 8, a jacquard circular knitting machine is comprised of a
knitting cylinder 2 having a plurality of knitting needles 3, yarn feed devices 8,
and a knitting needle driving mechanism 1 for transmitting a patterning procedure
memorized in a patterning procedure memory 4 for vertical movement of the knitting
needles. The knitting cylinder 2 is rotated through a transmitting mechanism 7 by
a motor 6. The rotation of the knitting cylinder, more exactly, the rotational angle
of the knitting cylinder, is detected by a decoder 5 and transmitted to the patterning
procedure memory 4. A knitting procedure corresponding to the rotational angle of
the knitting cylinder 2 is transferred from the patterning procedure memory 4 to the
knitting needle driving mechanism 1. The patterning procedure memory 4 usually consists
of a pin drum or a computer memory. A plurality of yarn 9 is fed through the yarn
feed devices 8 to the knitting needles 3.
[0004] As a knitting needle driving mechanism now in wide use, there is known the knitting
needle driving mechanism as shown in Fig. 9, a main portion of which is comprised
of a plurality of plates 60 arranged slidably in parallel to each other. In this mechanism,
the plates 60 slide base on pins on the pin drum or signals emitted from the computer
memory. When a plate 60 moves toward a center of the knitting cylinder 62, a jack
61 engaging the lower end of the knitting needle moves toward the center of the knitting
cylinder, so that a cam butt provided on the lower portion of the jack 61 is disengaged
from a rising cam 64. Accordingly, by controlling the sliding movement of the plate
60 by the pins or signals emitted from the memory, the vertical movement of the corresponding
knitting is controlled and a knit cloth having the predetermined pattern can be made.
[0005] At the present, high speed drive of the jacquard circular knitting machine is desired.
It is necessary to speed up the response of the knitting needle driving mechanism
to achieve high speed drive of the circular knitting machine. However, there is a
limit to increasing the response speed or the sliding speed of the plates in a knitting
needle driving mechanism having the constitution where the plates are slid, such as
the known knitting needle driving mechanism. It is possible to obtain a high speed
circular knitting machine by increasing the number of plates slid at the ordinary
sliding speed, however, the knitting needle driving mechanism becomes too large due
to the increased number of plates, so that it becomes difficult to arrange the knitting
needle driving mechainsm in a narrow space outside the circular knitting machine.
Accordingly, a knitting needle driving mechanism having a small size and high response
speed is strongly desired to enable a high speed jacquard circular knitting machine.
[0006] To this aim the French Patent 1.564.603 describes a knitting needle driving mechanism
having a plurality of fingers arranged substantially superimposed at intervals along
the sliding direction of the knitting needles and capable of swinging in the sliding
direction of the knitting needles by being pivoted at points near their central portions,
and an electromagnetic finger operating device for selectively swinging the corresponding
fingers.
[0007] According to said French Patent No. 1.564.603, said electromagnetic finger operating
device comprises U-shaped polar expansions.
[0008] Further, at the end of the fingers, remote from the knitting cylinder, are provided
permanent magnets located between said U-shaped polar expansions of the electromagnetic
finger operating device.
[0009] According to the polarization sign of the electromagnetic finger operating device,
the permanent magnet abuts against one of the two polar expansions of said electromagnetic
finger operating device and said polar expansions operate as mechanical abutments
which stop the swinging movement of said swinging finger.
[0010] So that at each movement of the swinging finger there is a mechanical impact between
the end of the finger and said U-shaped polar expansion of the electromagnetic finger
operating device.
[0011] These impacts require that the operating speed be reduced, otherwise the fingers
in question would only have a short life.
[0012] As an alternative, the fingers would have to be stronger, and therefore could no
longer be so small.
[0013] Also, if the size of the fingers were increased, the inertia forces concerned would
also increase.
[0014] Therefore in the device according to French Patent No. 1.564.603, the operating speed
may not exceed certain well-defined limits.
[0015] Also in the German Patent Application No. 2.106.839 the extreme positions of swinging
fingers are defined by means of mechanical stops and therefore the disadvantage of
the French Patent No. 1.564.603 are present.
Disclosure of the invention
[0016] The object of the present invention is to provide a knitting needle driving mechanism
having a small size and high response speed for a circular knitting machine.
[0017] In a knitting needle driving mechanism comprising a plurality of fingers arranged
substantially
[0018] In a knitting needle driving mechanism comprising a plurality of fingers arranged
substantially superimposed at intervals along the sliding direction of the knitting
needles and capable of swinging in the sliding direction of the knitting needles by
being pivoted at points near their central portions, and an electromagnetic finger
operating device for selectively swinging the corresponding fingers, according to
the invention, said electromagnetic finger operating device is arranged at a location
behind the fingers.
[0019] Permanent magnets are provided on ends of the fingers remote from the knitting cylinder
such that the lines connecting the two poles substantially correspond to the lengthwise
directions of the fingers. The ends of the fingers near to the knitting cylinder have
formed thereon pushing surfaces having a hill shape or a half hill shape in the horizontal
plane and a predetermined thickness in the vertical direction. The electromagnetic
finger operating device includes a plurality of electromagnets, the S-poles and N-poles
of which are attached on the housing. The S-poles and the N-poles of the electromagnets
are positioned at intervals in the vertical direction so as to substantially face
the end surfaces of the permanent magnets, of the fingers in the upper position and
lower position of the swinging movement of the fingers. The housing includes a plurality
of pivots supporting the fingers at the center portions thereof and a pair of finger
guides slidably guiding in the vertical direction the two side faces, in the horizontal
direction, of the plurality of fingers at the pushing side. The surfaces of the finger
guides facing the knitting cylinder are parallel to the lengthwise direction of the
knitting cylinder and extend in direction away from the fingers to form lead surfaces
for finger butts of jacks abutting the lower ends of the knitting needles. In the
knitting needle driving mechanism in accordance with the present invention, the electromagnets
of the electromagnetic finger operating device are supplied selectively with plus
or minus currents in accordance with a predetermined plan, whereby the fingers swing
and select the engagement between the pushing surfaces of the fingers and the finger
butts of the jacks. The engagement between a raising cams and cam butts of the jacks
is thereby selected and knitting of the predetermined pattern becomes possible.
[0020] Since the main portion of the knitting needle driving mechanism in accordance with
the present invention is comprised of a plurality of swingable fingers as described
hereinbefore and the swinging movement of the fingers is performed by an attractive
force and a repelling force of electromagnets against the permanent magnets arranged
on the ends of the fingers, the knitting needle driving mechanism can be operated
at a high response speed compared with the conventional known knitting needle driving
mechanism operated by the sliding movement of the fingers. Further, since the construction
of the device of the present invention is simple, the device can be manufactured at
low cost. Also, it is possible to save on electric power consumed in operating the
device.
[0021] Still more, the finger guides of the knitting needle driving mechanism according
to the present invention have formed thereon lead surfaces for the finger butts of
the jacks engaging the lower ends of the knitting needles so that any butt protruding
outward of the knitting cylinder for any reason is corrected in advance by the lead
surfaces. Consequently, there is no change that a finger butt of a jack will directly
abut a finger, thus minimizing the chance of damage to the fingers.
[0022] In the knitting needle driving mechanism in accordance with the present invention,
it is preferable that the relative position between the fingers and the finger guides
be determined such that, at the swinging position in which the pushing surfaces of
the fingers engage with the finger butts of the jacks abutting the lower ends of the
knitting needles, the two end edges of the pushing surfaces of the fingers, i.e.,
the hill shape portions, furthest from the knitting cylinder, or the end edge of half
hill shaped portions remote from the knitting cylinder, be positioned in the same
plane as the finger butt lead surfaces of the finger guides or move inward of the
finger guides than the lead surfaces. The knitting needle driving mechanism having
the aforesaid construction enables smooth contact of the finger butts positioned on
the lead surfaces with the fingers, so the risk of damage to the fingers can be reduced
and, as a result, the durability of the knitting needle driving mechanism can be significantly
increased.
[0023] If the pushing surfaces are formed in a hill shape, the knitting needle driving mechanism
in accordance with the present invention can be used when the circular knitting cylinder
is rotated in the normal direction and the reverse direction. Incidentally, when the
circular cylinder is rotated in one direction, pushing surfaces formed in a half hill
shape may be used.
Brief description of the drawings
[0024]
Figure 1 is a front elevation of a knitting needle driving mechanism illustrating
an embodiment according to the present invention;
Fig. 2 is a side view along the line II to II of Fig. 1;
Fig. 3 is a side view along the line III to III of Fig. 1;
Fig. 4 is an enlarged perspective view illustrating a relative relation among a finger,
an electromagnetic finger operating device and a housing in the knitting needle driving
mechanism illustrated in Fig. 1;
Figs. 5 and 6 are front elevations illustrating a model relationship between an operative
state of the knitting needle driving mechanism and a butt of a jack and a raising
cam, Fig. 5 showing the case where the butt does not abut the raising cam and Fig.
6 showing the case where the butt abuts the raising cam;
Fig. 7 is a plan view illustrating a shape of a pushing member and a relative position
between the pushing member and the housing;
Fig. 8 is a perspective view illustrating an example of a conventional known jacquard
circular knitting machine; and
Fig. 9 is a partial cross-sectional side view illustrating a conventional known knitting
needle driving mechanism.
Best mode for carrying out the invention
[0025] The present invention will be described hereinafter in connection with the accompanying
drawings showing an embodiment of the present invention.
[0026] As illustrated in Fig. 1, the knitting needle driving mechanism of the embodiment
is comprised of eight fingers 11, an electromagnetic finger operating device 30 arranged
behind the fingers 11, and a housing 20 supporting the eight fingers 11 and the electromagnetic
finger operating device 30. Though eight fingers are shown in the knitting needle
driving mechanism according to the present embodiment, the number of fingers is not
particularly limited. At least 16 fingers are used in conventional (sliding movement
type) knitting needle driving mechanisms. A knitting needle driving mechanism with
a small number of fingers is preferable, because it is possible to make the external
dimensions smaller. Since, in the embodiment according to the present invention, the
operation of the knitting needle driving mechanism can be made high speed, as described
hereinafter, it is possible to form the knitting needle driving mechanism with eight
fingers. Incidentally, the ideal number of fingers in a knitting needle driving mechanism
is just one.
[0027] As illustrated in the enlarged perspective view of Fig. 4, a finger 1 is comprised
of a finger central portion 19 supported rotatively by a pivot 16, a first arm 12
and a second arm 13 extending from the finger central portion 19 to the two sides,
a pushing member 14 attached to a top end of the first arm 12, and a permanent magnet
17 attached to a top end of the second arm 13. The top end of the pushing member 14
is substantially formed in a hill shape in the horizontal plane including the lengthwise
axis of the finger 11 and inclined surfaces thereof form pushing surfaces 15, 15'.
The permanent magnet 17 is formed such that the line connecting the two poles, i.e.,
S-pole and N-pole, corresponds to the lengthwise direction of the finger 11.
[0028] In the electromagnetic finger operating device, a pair of electromagnets is arranged
for each finger 11. The pair of the electromagnets includes two electromagnetic coils
33 and 34 and electromagnet ends 31 and 35 provided on each electromagnetic coil 33
and 34 to form a U-shape electromagnetic coil, as illustrated in Fig. 4. Incidentally,
though Fig. 4 shows that the two electromagnet ends 31 and 35 connected with the electromagnetic
coils 33 and 34 by leading wires, this is for convenience in explanation. In actuality,
as illustrated in Fig. 1, the electromagnet ends are the ends of the core of the electromagnetic
coil. The electromagnet ends 31 and 35 are arranged in a rear vertical plate 22 of
the housing 20, as illustrated in Fig. 3. Namely, the electromagnet ends 31a and 35a
in Fig. 3 are ends of the core of the pair of electromagnetic coil 33a and 34a. When
current flows to each electromagnetic coil to energize them, it is possible to reverse
the states, e.g., change a plus state of the electromagnet end 35a and a minus state
of the electromagnet end 31a a to a minus state of the electromagnet end 35a and a
plus state of the electromagnet end 31 a, by changing the direction of the electric
current. The change of the direction of the electric current is usually performed
by means of transistors, so that the change between the plus state and the minus state
of the electromagnet surface can be performed at an extreme high speed.
[0029] As described hereinbefore, eight fingers are arranged in the present embodiment.
With regard to an arrangement of the fingers, the pushing surfaces 15 and 15' (for
simplification, Fig. 2, the reference numerals are given only to the pushing surfaces
15a, 15b... and 15h on one side) are arranged at intervals in the vertical direction
in Fig. 2 (which coincides with the sliding direction of the knitting needles). However,
in the present embodiment, four fingers of the eight fingers are pivotably supported
at a front side and the other four fingers (not shown in Fig. 1) at the back side
by forming the pushing member 14 of the rear portion of the pushing surface 15 in
a sickle-like shape as illustrated in Fig. 4. Therefore, the electromagnet surfaces
corresponding to the permanent magnets 17 on the ends of the eight fingers are arranged
such that four pairs are at the left and four pairs are at the right. By arranging
the eight fingers are described hereinbefore, the eight finger central portions 19
are separated into two groups; a left 19a, 19b, 19c, and 19d and a right 19e, 19f,
19g and 19h in Fig. 2. Consequently, the finger central portions 19 and the pivots
16 can be designed to dimensions sufficient to withstand the high speed sliding of
the fingers 11 and, as a result the durability of the knitting needle driving mechanism
according to the present invention can be increased. On the other hand, it is possible
to make a knitting needle driving mechanism having the same strength with a smaller
overall size.
[0030] Further, it is preferable that the space between the permanent magnets 17 and the
electromagnetic ends 31 and 35 of the electromagnetic finger drawing mechanism 30
be such that the two approach each other without actual contact.
[0031] Next, the relationship between the housing 20 and the fingers 11 will be described.
The housing 20 includes a pivot support member (not shown) extending in the vertical
direction in the roughly central portion of the housing 20. The pivot support member
supports four pivots 16 on both sides thereof. On the other hand, the housing includes
a front vertical plate, i.e., a finger guide 21. The finger guide 21 is provided with
an opening 23 having a substantially rectangular shape. The pushing surfaces 15 and
15' of the fingers 11 protrude into the opening 23. The opening 23 may be formed as
a slit extending from a top end to a lower end of the housing 20. The relative position
between the finger guide 21 and the pivots 16 supporting the fingers 11 is determined
such that the space between the side walls 25 and 25' of the opening 23 (see Fig.
2 and 4) is set slightly larger than the distance between the side walls 55 and 55'
of the pushing member 14 and such that at least one portion of the pushing surface
15 protrudes from the lead surface 24 of the finger guide 21.
[0032] An operation of the fingers 11 of the knitting needle driving device according to
the present embodiment and the moving state of a cam butt (leveling butt) of the jack
caused by the operation will be now described in connection with Figs. 5 and 6. In
Figs. 5 and 6, 40 is a jack. The jack 40 is provided with a finger butt 41 and a cam
butt 42. In Fig. 5, the S-pole at the end of the permanent magnet 17 of the finger
11 faces an electromagnet end 31, the end face of which is an N-pole, so that the
finger 11 is kept in the horizontal plane in Fig. 5. Consequently, the finger butt
42 of the jack 40 on the knitting cylinder (not shown) abuts the pushing surface 15
of the finger 11, so that the jack 40 is turned in the counterclockwise direction.
Therefore, the cam butt 42 of the lower end of the jack 40 does not abut a raising
cam 43 arranged on a machine frame of the circular knitting machine, so that the jack
40 and the knitting needle (not shown) engaging the jack 40 do not receive a raising
movement caused by the raising cam 43.
[0033] Reversal of the direction of the electric current of the electromagnetic coil by
the electromagnet ends 31 and 35 as shown in Fig. 6 results in the S-pole of the permanent
magnet being attracted, from the position of Fig. 5, by the N-pole appearing at the
electromagnet end 35 and repelled by the S-pole appearing at the electromagnet end
31, whereby the pushing surface of the end of the figure 11 is moved down. When the
knitting cylinder rotates in this state, the finger butt 41 of the jack 40 on the
knitting cylinder does not abut the pushing surface 15 and the jack 40 is maintained
in roughly the vertical position in Fig. 6. The cam butt 42 of the jack 40 maintaining
its vertical position and rotating with the knitting cylinder abuts the raising cam
43 and guide by the triangle shape side edge to rise so that the knitting needle engaging
with the top end of the jack is raised.
[0034] Incidentally, the relative position between the pushing surface 15 of the finger
11 and the finger butt 41 of the jack 40 may be constituted, conversely to Fig. 6,
so that engagement between the finger butt 41 and the pushing surface 15 is released
by upward movement of the pushing surface 15.
[0035] As described hereinbefore, the swinging movement of the finger 11 is performed by
changing the direction of the electric current toward the electromagnetic coils 33
and 34. Since the change of the direction of the electric current is performed by
a usual transistor, it can be effected at a high speed. Since the finger can change
in position by a swinging movement about the pivot 16, the finger rapidly responds
to the attraction between different poles of the electromagnets and the repulsion
between the same poles of the electromagnets to change in position. Consequently,
the pushing surface of the finger can be inserted to or removed from a position engaging
with the finger butt of the jack at a higher speed compared with any conventional
known knitting needle driving mechanism.
[0036] The shape of the pushing member 14 and the relative position between the finger guide
21 and the pushing member 14 in the housing 20 are now described in connection with
Fig. 7.
[0037] The pushing member 14 may be formed in a hill shape having inclined pushing surfaces
15 and 15' on its two sides, as illustrated in Fig. 7(a) (b), (c), (d) and (e), or
in a half hill shape having an inclined pushing surface 15' on only one side, as illustrated
in Fig. 7(f). In the former case, when the knitting cylinder can rotate in two directions,
i.e., the normal direction and the reverse direction, rotation in the two directions
of the knitting cylinder can be handled by a single knitting needle driving mechanism.
The latter pushing member can be used only for rotation in one direction of the knitting
cylinder.
[0038] The relative position between the finger guide 21 and the pushing member 14 may be
determined such that the pushing surfaces 15 and 15' of the pushing member 14 are
completely exposed from the lead surface 24 and 24' and further portions of side walls
55 and 55' of the pushing member 14 are exposed from the lead surface 24 and 24' as
illustrated in Fig. (e). However, it is preferable that the relative position between
the finger guide 21 and the pushing member 14 be determined such that points 56 and
56', at which the pushing surfaces 15 and 15' meet the side walls 55 and 55', are
arranged within the lead surfaces 24 and 24' as illustrated in Fig. 7(a); or the points
56 and 56' coincide with the lead surfaces 24 and 24', as illustrated in Fig. 7(b).
When the relative position between them is determined as illustrated in Fig. 7(a)
or Fig. 7(b), the jack butt 41 advancing toward the pushing surfaces 15 and 15' under
the guide of the lead surface 24 or 24' can ride on the pushing surface 15 or 15'
without receiving any resistance and can move by being pushed by the pushing surface
15 or 15', more concretely, by the jack butt being pushed toward an axis of the knitting
cylinder.
[0039] Since the lead surfaces 24 and 24' serve to push the jack to a suitable level when
the jack jumps out in the radial direction of the knitting cylinder by centrifugal
force itself or damage itself, the lead surface can prevent the finger butt from damaging
the finger of the knitting needle driving mechanism. Further, the angle of inclination
of the lead surfaces 24 and 24' may be such that the lead surfaces 24 and 24' are
in the horizontal plane in Fig. 7, as illustrated in Fig. 7(a) and Fig. 7(b) are inclined
outward as illustrated in Fig. 7(c), or inclined inward as illustrated in Fig. 7(d).
The position of Fig. 7(c) helps to slowly push in a protruding jack, and the position
of Fig. (d) helps to push in an abnormally protruding jack.
[0040] Though the leads surfaces 24 and 24' of the finger guide 21 are formed as flat planes,
the shape of the lead surfaces is not limited to a flat plane and may be formed as
an arc-like shape.
Capability of exploitation in industry
[0041] Since the knitting needle driving device according to the present invention is constituted
as described hereinbefore, the movement of the pushing surface of a finger for selecting
a needle is very speedy. Therefore, it is possible to make the knitting needle driving
mechanism small by decreasing the number of fingers compared with the conventional
knitting needle driving mechanism. Further since the construction of the device is
simple, the device according to the present invention has advantages of low cost manufacture
of the device and significant savings in power consumption.
[0042] Further, when the two edges of the pushing surface of the pushing member are arranged
within the lead surface of the housing, as indicated in the preferred embodiment of
the present invention, it is possible to prevent fingers in the knitting needle driving
mechanism from being damaged by the butt on the rotating knitting cylinder.
1. A knitting needle driving mechanism of a circular knitting machine able to knit
a predetermined pattern by making or removing engagement between raising cams (43)
for applying vertical movement to a plurality of knitting needles (3), on a circular
cylinder (2), of the circular knitting machine and cam butts (42) of jacks (40) engaging
with lower ends of the knitting needles (3) on the basis of a predetermined knitting
plan; wherein said knitting needle driving mechanism is comprised of a plurality of
fingers (11) arranged substantially superimposed at intervals along a sliding direction
of the knitting needles and capable of swinging in the sliding direction of the knitting
needles (3) by being pivoted at points (16) near their central portions (19), an electromagnetic
finger operating device (30) for selectively swinging the corresponding fingers, and
a housing (20) for supporting the plurality of fingers (11) and the electromagnetic
finger operating device (30); permanent magnets (17) being provided on ends of the
fingers; the ends (12) near to the knitting cylinder fingers having formed thereon
pushing surfaces (15,15') having a hill shape or a half hill shape in the horizontal
plane and a predetermined thickness in the vertical direction; said electromagnetic
finger operating device (30) including a plurality of electromagnets (31, 35), S-poles
and N-poles of which are attached on the housing; said housing (20) including a plurality
of pivots (16) supporting the fingers (11) at the center portions (19) thereof characterized
in that said electromagnetic finger operating device (30) is arranged at location
behind the fingers (11), that said permanent magnets (17) are provided on ends of
the fingers remote from the knitting cylinder (2) in such a position that the lines
connecting the two poles substantially corresponds to the lengthwise directions of
the fingers; that said electromagnetic finger operating device (30) includes a plurality
of electromagnets (31, 35), the S-poles and the N-poles of which being positioned
at intervals in the vertical direction so as to substantially face the end surface
of the permanent magnets (17) of the fingers (11) in the upper position and lower
position of the swinging movement of the fingers; that a pair of finger guides (25,
25') slidably guides the fingers (11) on the pushing side in the vertical direction;
that the surfaces (24) of the finger guides (25, 25') facing the knitting cylinder
(2) are parallel to the lengthwise direction of the knitting cylinder and extending
in direction away from the fingers (11) to form lead surfaces for finger butts (41)
of jack (40) abutting the lower ends of the knitting needles (11); and that the electromagnet
(31, 35) of the electromagnetic finger operating device (30) is supplied selectively
with plus or minus currents in accordance with a predetermined plan, whereby the fingers
(11) swing and select the engagement between the pushing surfaces (15, 15') of the
fingers (11) and the finger butts (41) of the jack (40) so that the engagement between
raising cams (43) and the cam butts (42) of the jacks is thereby selected and knitting
of the predetermined pattern becomes possible.
2. A knitting needle driving mechanism according to claim 1, characterized in that
relative positions between said fingers (11) and said finger guides (25, 25') are
determined such that, in the swinging position in which the pushing surfaces (15,
15') of the fingers engage with the finger butts (41) of the jacks (40) engaging the
lower ends of the knitting needles, both edges of the hill shape portions remote from
the knitting cylinder or an edge of the half hill shape portions, forming the pushing
surfaces of the fingers, remote from the knitting cylinder are positioned in the same
plane as the finger butt lead surfaces of the finger guides or an inward position
of the finger guides compared with said finger butt lead surfaces.
3. A knitting needle driving mechanism according to claim 1, or claim 2, characterized
in that said ends (14) of the fingers (11) near to the knitting cylinder are formed
in a hill shape in the horizontal plane to constitute said pushing surfaces (15, 15').
4. A knitting needle driving mechanism according to claim 1 or claim 2, characterized
in that said ends (14) of the fingers (11) near to the knitting cylinder (2) are formed
in a half hill shape in the horizontal plane to constitute said pushing surfaces (15,
15').
1. Nadelauswahlvorrichtung für Rundstrickmaschinen, die imstande ist, gemäß einem
vorbestimmten Muster zu stricken, indem sie zwischen den Nadelhebern (43), die bei
einer Vielzahl von Nadeln (3) auf einem Rundzylinder (2) einer Rundstrickmaschine
eine senkrechte Bewegung erzeugen, und den Nockenanschlägen (42) der Hebevorrichtungen
(40), die ihrerseits mit den unteren Enden der Nadeln (3) verbunden sind, gemäß einem
vorbestimmten Strickmuster ein Einrasten und Ausrasten bewirkt, wobei die genannte
Nadelauswahlvorrichtung eine Vielzahl von Fingern (11) aufweist, die im wesentlichen
in Zwischenräumen entlang der Gleitlinie der Nadeln übereinandergelagert und imstande
sind, in der Gleitrichtung der Nadeln (3) zu schwingen, da sie mit Drehzapfen in Punkten
(16), die ihrem Zentralbereich (19) naheliegen, mit einer elektromagnetischen Vorrichtung
(30) zur Orientierung der Finger aufgrund der wahlweisen Schwingung der entsprechenden
Finger und mit einem Gehäuse (20), das die Vielzahl der Finger (11) und die elektromagnetische
Vorrichtung (30) zur Orientierung der Finger aufnimmt, versehen sind; wobei Dauermagnete
(17) an den Enden der Finger angebracht sind; wobei die Enden (12) der dem Strickzylinder
am nahesten gelegenen Finger eine Schuboberfläche (15, 15') in der Form eines Hügels
oder Halbhügels auf waagerechter Ebene und eine vorbestimmte Dicke in senkrechter
Richtung aufweisen; wobei die genannten elektromagnetische Vorrichtung (30) zur Orientierung
der Finger eine Vielzahl von Elektromagneten (31, 35), deren S- und N-Pole am Gehäuse
befestigt sind, aufweist; wobei das genannte Gehäuse (20) eine Vielzahl von Drehzapfen
(16) aufweist, die die Finger (11) in ihren Zentralbereichen (19) halten; dadurch
gekennzeichnet, daß die genannte elektromagnetische Vorrichtung (30) zur Orientierung
der Finger hinter den Fingern (11) angebracht ist; daß die genannten Dauermagnete
(17) an den Enden der vom Zylinder (2) der Strickmaschine entfernten Finger in einer
derartigen Position angebracht sind, daß die Linien, die die beiden Pole verbinden,
im wesentlichen der Längsrichtung der Finger entsprechen; daß die genannte elektromagnetische
Vorrichtung (30) zur Orientierung der Finger eine Vielzahl von Elektromagneten (31,
35) aufweist, deren S- und N-Pole in Zwischenräumen in senkrechter Richtung angebracht
sind, damit sie im wesentlichen zur Oberfläche der Enden der Dauermagnete (17) der
Finger (11) gewandt sind, wenn sich diese in der oberen und unteren Position der Schwingbewegung
der Finger befinden; daß zwei Fingergleitschienen (25, 25' die Finger (11) auf der
Schubseite in senkrechter Richtung führen; daß die Oberflächen (24) der Fingergleitschienen
(25, 25'), die zum Zylinder (2) der Strickmaschine gewandt sind, parallel zur Längsrichtung
des Maschinenzylinders ver laufen und sich in eine Richtung erstrecken, die sich von
den Fingern (11) entfernt, um Führungsoberflächen für die Fingeranschläge (41) der
Hebevorrichtung (40) zu bilden, die auf die unteren Enden der Nadeln (11) der Maschine
auftreffen; und daß die Elektromagneten (31, 35) der elektromagnetischen Vorrichtung
(30) zur Orientierung der Finger gemäß einem vorbestimmten Plan wahlweise mit positivem
oder negativem Strom gespeist werden, wodurch die Finger (11) schwingen und den Kontakt
zwischen den Schuboberflächen (15, 15') der Finger (11) und den Fingeranschlägen (41)
der Hebevorrichtungen (40) wählen, sodaß dadurch das Einrasten der Nadelheber (43)
und der Nockenanschläge (42) der Hebevorrichtungen gewählt ist und der Strickvorgang
des vorbestimmten Musters ermöglicht wird.
2. Nadelauswahlvorrichtung für Rundstrickmaschinen gemäß Anspruch 1, dadurch gekennzeichnet,
daß die jeweiligen Positionen zwischen den genannten Fingern (11) und den genannten
Fingerschienen (25,25') derart festgelegt werden, daß in der Schwingposition, in der
die Schuboberflächen (15, 15') der Finger die Fingeranschläge (41) der Hebevorrichtungen
(40) berühren, die ihrerseits mit den unteren Enden der Nadeln der Strickmaschine
verbunden sind, beide Seiten der hügelförmigen, vom Zylinder am weitesten entfernten
Teile oder eine Seite der halbhügelförmigen, vom Zylinder der Strickmaschine am weitesten
entfernten Teile, die die Schuboberflächen der Finger bilden, auf derselben Ebene
der Führungsoberflächen des Anschlags auf den Fingerschienen oder in einer Position
auf den Schienen angebracht sind, die gegenüber den genannten Führungsoberflächen
für den Fingeranschlag weiter innen liegt.
3. Nadelauswahlvorrichtung für Rundstrickmaschinen gemäß Anspruch 1 oder 2, dadurch
gekennzeichnet, daß die genannten Enden (14) der Finger (11), die nahe beim Zylinder
der Strickmaschine liegen, auf waagerechter Ebene eine Hügelform aufweisen, die die
genannten Schuboberflächen (15, 15') bildet.
4. Nadelauswahlvorrichtung für Rundstrickmaschinen gemäß Anspruch 1 oder 2, dadurch
gekennzeichnet, daß die genannten Enden (14) der Finger (11), die nahe beim Zylinder
(2) der Strickmaschine liegen, auf waagerechter Ebene eine Halbhügelform aufweisen,
die die genannten Schuboberflächen (15, 15') bildet.
1. Un mécanisme d'actionnement des aiguilles pour machines à tricoter circulaires
en mesure de tricoter selon un schéma prédéterminé, en engagement ou en libérant les
cames (43) de levage qui impriment un mouvement vertical à une pluralité d'aiguilles
(3) à tricoter sur un cylindre circulaire (2) d'une machine à tricoter circulaire
avec les butées (42) pour cames sur les leviers vérins (40), leviers enclenchés sur
les extrémités inférieures des aiguilles (3) à tricoter sur la base d'un plan prédéterminé
de tricot, et ce mécanisme pour actionner les aiguilles comprend une pluralité de
doigts (11) pratiquement superposés à intervalles le long de la ligne de coulissement
des aiguilles à tricoter et un mesure d'osciller dans la direction de coulissement
des aiguilles (3) car ils sont munis de pivots dans des points (16) proches de leurs
parties centrales (19), un dispositif électromagnétique (30) d'actionnement des doigts
pour l'oscillation sélective des doigts correspondants, et un logement (20) qui soutient
la pluralité des doigts (11) et le dispositif électromagnétique (30) d'orientation
des doigts; on a prévu des aimants permanents (17) sur l'extrê- mité des doigts; les
extrémités (12) des doigts les plus proches du cylindre pour tricoter ont des surfaces
de poussée (15, 15') ayant la forme d'une colline ou d'une semi-colline sur le plan
horizontal et ont une épaisseur prédéterminée dans la direction verticale; ce dispositif
électromagnétique (30) d'orientation des doigts comprend une pluralité d'électro-aimants
(31, 35) dont les pôles S et N sont fixés sur le logement. Ce logement (20) comprend
une pluralité de pivots (16) qui soutienent les doigts (11) dans leurs parties centrales
(19) et il est caractérisé par le fait que ce dispositif électromagnétique (30) d'orientation
des doigts est positionné derrière les doigts (11); que ces aimants permanents (17)
sont prévus aux extrémités des doigts éloignés du cylindre (2) de la machine à tricoter
dans une position telle que les lignes qui relient les deux pôles correspondent substantiellement
à la direction longitudinale des doigts; que ce dispositif électromagnétique (30)
d'orientation des doigts comprend une pluralité d'électro-aimants (31, 35) dont les
pôles S et N sont positionnés, à intervalles, en direction verticale de façon à être
substantiellement tournés vers la surface terminale des aimants permanents (17) des
doigts (11) quand ceux-ci se trouvent dans la position supérieure et dans la position
inférieure du mouvement d'oscillation des doigts; qu'un couple de coulisses (25, 25')
pour les doigts guide les doigts (11) sur le côté de poussée en direction verticale;
que les surfaces (24) des coulisses (25, 25') pour les doigts, tournés vers le cylindre
(2) de la machine à tricoter sont parallèles à la longueur du cylindre de la machine
et s'étendent dans une direction qui s'éloigne des doigts (11) de façon à former des
surfaces de guidage pour les butées (41) pour les doigts des leviers vérins (40) qui
forment opposition sur les extrémités inférieures des aiguilles (11) de la machine
et que les électro-aimants (31, 35) du dispositif électromagnétique (30) d'orientation
des doigts sont parcourus, de façon sélective, par des courants positifs ou négatifs
selon un plan prédéterminé, c'est pour quoi les doigts (11) oscillent et sélectionnent
l'engagement entre les surfaces (15,15') de poussée des doigts (11) et les butées
(41) pour les doigts sur les leviers vérins (40), donc l'engagement entre des cames
(43) de levage et les butées (42) pour cames des leviers vérins est déterminé ainsi:
on peut donc tricoter selon le schéma prédéterminé.
2. Un mécanisme d'actionnement des aiguilles des machines à tricoter selon la revendication
1, caractérisé par le fait que les positions relatives entre les doigts susdits (11)
et les coulisses (25, 25') des doigts sont déterminées de façon que, dans la position
d'orientation où les surfaces de poussée (15, 15') des doigts engagent les butées
(41) pour les doigts des leviers vérins (40) insérées aux extrémités inférieures des
aiquilles de la machine à tricoter; des deux côtés des pièces en forme de colline
les plus éloignées du cylindre ou d'un côté de la pièce en forme de semi-colline qui
forment les surfaces de poussé des doigts, le plus loin du cylindre de la machine
à tricoter. Ces surfaces sont positionnées sur le même plan que les surfaces de coulissement
de la butée sur les coulisses pour doigts ou en une position plus interne sur les
coulisses par rapport à ces surfaces de coulissement pour la butée pour doigts.
3. Un mécanisme d'actionnement des aiguilles des machines à tricoter selon les revendications
1 ou 2, caractérisé par le fait que ces extrémités (14) des doigts (11) les plus proches
du cylindre de la machine à tricoter ont une forme de colline sur le plan horizontal
qui constitue ces surfaces de poussée (15, 15').
4. Un mécanisme d'actionnement des aiguilles des machines à tricoter selon les revendications
1 ou 2, caractérisé par le fait que ces extrémités (14) des doigts (11) les plus proches
du cylindre (2) de la machine à tricoter ont une forme de semi- collime sur le plan
horizontal qui constitue ces surfaces de poussée (15, 15').