Information
-
Patent Grant
-
6247338
-
Patent Number
6,247,338
-
Date Filed
Wednesday, June 21, 200024 years ago
-
Date Issued
Tuesday, June 19, 200123 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Ferster & Company Patent Attorneys Ltd.
-
CPC
-
US Classifications
Field of Search
US
- 066 218
- 066 219
- 066 220
- 066 221
- 066 222
- 066 215
- 066 216
- 066 217
-
International Classifications
-
Abstract
The present invention provides a method for rapidly switching selector feet (52) between activate and deactivate selection positions by friction coupling them to vibratory piezoelectric motors (58) and a fast selector (50) for a knitting machine comprising selector feet friction coupled to piezoelectric motors.
Description
FIELD OF THE INVENTION
The present invention relates to knitting machines, and in particular to selectors which select which latch needles of a knitting machine are activated in the process of knitting a fabric.
BACKGROUND OF THE INVENTION
Automatic knitting machines use banks of large numbers of closely spaced latch needles to interlock threads in a series of connected loops to produce a knitted fabric. The latch needle is a flat needle generally with a long shaft having, at one end, a small hook with a latch, which latch swivels to open and close the hook.
Generally, in a modem knitting machine, many thousands of latch needles are accurately positioned and maintained in a closely packed parallel array. In the process of knitting a fabric, an activation station activates latch needles by moving them forwards and backwards, parallel to their lengths, so that the hook ends of the activated latch needles move towards and away from threads being woven into the fabric. As a latch needle is moved forwards and backwards, its latch swivels back and forth to alternately open and close the latch needle hook so that the latch needle can catch and hold one of the threads being woven into the fabric, pull it to create a loop of fabric, and then release the thread to repeat the cycle.
In rotary knitting machines the needles in an array are held in a cylindrical geometry and rapidly moved, in a rotary motion, into and out of the activation station. Depending upon the fabric being knitted, different ones of the needles moving through the activation station are activated. In linear knitting machines, latch needles are held in parallel slots in large flat needle beds. The activation station is a type of shuttle that moves rapidly back and forth over the needle bed, activating needles appropriate to the weave of the fabric being knitted.
In both rotary and linear knitting machines, a device called a “selector” determines (hereafter referred to as “selects”) whether a needle in the activation station of the knitting machine is to be activated or not. To prevent a needle from being activated, the selector presses on a small protuberance (hereafter referred to as an “activation fin” or “fin”) on the shaft of the needle. When pressure is applied to the activation fin by the selector, the needle moves away from an activating mechanism of the activator station and is “deactivated”. If the selector does not press on the activation fin, the needle is activated.
The selector presses on the fin of a needle, to deactivate the needle, with a “selector foot”. The selector foot has two operational selection positions. In a deactivate selection position, the selector foot presses on the fin of the needle thereby preventing the needle from being activated when the needle passes through the activation station. In an activate selection position, the selector foot does not press on the fin of the needle, thereby allowing the needle to be activated when the needle passes through the activation station. The selector foot is generally switched between the selection positions by displacing the selector foot by a small linear translation or by rotating the selector foot through a small angle.
When a knitting machine is operating, the selector of the knitting machine is set to an appropriate selection position for each latch needle that passes through the activation station of the knitting machine. If the selection positions for two needles that pass consecutively through the activation station are not the same the selector has to be switched from one selection position to the other. Prior art selectors generally use solenoids or piezoelectric bimorph actuators to effect the displacements necessary to switch a selector foot between selection positions. However, using these types of actuators, the time it takes to switch a selector foot between selection positions is too long to match the rate at which modern knitting machines move needles through activation stations.
In order to improve the speed with which prior art selectors operate, prior art selectors generally comprise a multiplicity of selector feet which are operated in parallel. In a selector operating with one selector foot, a decision to switch or not switch the selection position of the selector foot, hereafter referred to as “setting” the selector foot, has to be made and executed for every needle that moves through an activation station. In a selector with N activation feet on the other hand, each foot has to be set once for every N needles that move through the activation station. If the switching time needed to switch a selector foot between selection positions is τ secs, a selector with one foot can select 1/τ needles/sec, or equivalently, operate at a “decision” frequency of 1/τ Hz. A selector with N selector feet in parallel on the other hand, can select N/τ needles/sec, i.e. operate at a decision frequency of N/τ Hz. Switching times for prior art activation feet are on the order of 10 msecs. By operating approximately 10 activation feet in parallel, prior art selectors are able to operate at decision frequencies of up to about 1000 Hz.
The decision frequencies at which prior art selectors operate limit the rate at which needles can be moved through a knitting machine activation station and therefore limit the rate at which fabric can be produced. In order to increase the rate at which knitting machines produce fabric, it is desirable to have selectors that can operate at frequencies higher than 1000 Hz.
SUMMARY OF THE INVENTION
It is an object of some aspects of the present invention to provide a selector for knitting machines that can operate at decision frequencies substantially higher than 1000 Hz.
A selector, in accordance with a preferred embodiment of the present invention, achieves decision frequencies higher than those of conventional selectors by decreasing the switching time of selector feet comprised in the selector to less than the switching times of selector feet in conventional selectors.
When in operation, a selector foot constantly switches back and forth between selection positions at a rapid rate. When switching between selection positions, the selector foot generally moves a distance of about 2 mm in about 10 msecs. This change is resisted by friction, forces arising from part wear, machine design and tolerances, and random motional forces that occur during machine operation. The sum of these forces is on the order of between 0.2 and 0.5 Newton. Because of the close spacing within modem knitting machines and the small sizes of many of their components there is little room available for motors or actuators to provide the work required to accomplish the switching. An actuator or motor that can be used to improve the switching time of a selector foot in a selector must therefore be small, capable of switching direction rapidly and able to provide work at a greater rate than that available from motors or actuators in conventional selectors.
Piezoelectric motors can be produced that are small and powerful for their size and that can provide large accelerations of moveable elements in directions which can be reversed in time periods of microseconds. The switching time of a selector foot can be reduced to less than the switching times of selector feet in conventional selectors by using an appropriate piezoelectric motor to switch the selector foot between selection positions, in accordance with a preferred embodiment of the present invention. A selector foot, in accordance with a preferred embodiment of the present invention, is coupled to a piezoelectric motor that can displace a moveable element at a rate of about 400 mm/sec against a force opposing the motion which is on the order of from 0.2 to 0.5 Newton. Preferably, the selector foot comprises a friction coupling surface region suitable for friction coupling with the piezoelectric motor. Preferably, the selector foot is coupled to the piezoelectric motor by resiliently pressing a surface region of the piezoelectric motor, or an appropriate hard friction nub attached to the surface of the piezoelectric motor, to the friction coupling surface region of the selector foot. Preferably, the piezoelectric motor coupled to the selector foot is of a type described in U.S. Pat. No. 5,453,653, which is incorporated herein by reference. As a result, a selector foot in a selector, in accordance with a preferred embodiment of the present invention, can be switched between selection positions in a time on the order of 5 msec (2 mm/[400 mm/sec]=5 msec).
A selector, in accordance with a preferred embodiment of the present invention, comprises a multiplicity of activation feet, in accordance with a preferred embodiment of the present invention, operated in parallel. Preferably, the number of the multiplicity of selector feet is on the order of 10. With a switching time for the selector feet of 5 msec, in accordance with a preferred embodiment of the present invention, this results in a decision frequency for the selector in the range of 2000 Hz (the decision frequency=N/τ with N=10 and τ=5 msec).
There is therefore provided in accordance with a preferred embodiment of the present invention a selector for a knitting machine, which knitting machine comprises a plurality of latch needles and an activation station, such that when a latch needle of the plurality of latch needles is in the activation station, said selector determines whether said latch needle is activated or not activated, comprising: at least one selector foot selectively positionable to an activate or a deactivate selection position, wherein said selector foot has a friction coupling surface; and a piezoelectric motor coupled to said friction coupling surface of the at least one selector foot; wherein vibrations in said piezoelectric motor cause said at least one selector foot to switch between activate and deactivate selection positions. Preferably, the piezoelectric motor is coupled to the friction coupling surface by a resilient force which presses a contact surface of the piezoelectric motor to the friction coupling surface. Alternatively, the piezoelectric motor has a friction nub and the piezoelectric motor is coupled to the friction coupling surface by a resilient force which presses the friction nub to the friction coupling, surface.
In some preferred embodiments of the present invention the friction coupling surface is cylindrical. In other preferred embodiments of the present invention the friction coupling surface is planar.
In some preferred embodiments of the present invention vibrations in the piezoelectric motor cause the selector foot to switch between selection positions by rotating the selector foot through a given angle. Preferably, the vibrations in the piezoelectric motor rotate the selector foot through the given angle in a period of time less than
10
msec. More preferably, the vibrations in the piezoelectric motor rotate the selector foot through the given angle in a period of time less than 7 msec. Most preferably vibrations in the piezoelectric motor rotate the selector foot through the given angle in a period of time less than 5 msec. In some preferred embodiments of the present invention, the vibrations in the piezoelectric motor rotate the selector foot through the given angle in a period of time substantially equal to 5 msec.
In yet other preferred embodiments of the present invention vibrations in the piezoelectric motor cause the selector foot to switch between selection positions by causing a given linear displacement in the position of the selector foot. Preferably, the vibrations in the piezoelectric motor cause the given linear displacement in the position of the selector foot in a period of time less than 10 msec. More preferably, vibrations in the piezoelectric motor cause the given linear displacement in the position of the selector foot in a period of time less than 7 msec. Most preferably the vibrations in the piezoelectric motor cause the given linear displacement in the position of the selector foot in a period of time less than 5 msec. In some preferred embodiments of the present invention vibrations in the piezoelectric motor cause the given linear displacement in the position of the selector foot in a period of time substantially equal to 5 msec.
In some preferred embodiments of the present invention the at least one selector foot comprises a plurality of selector feet and each latch needle is associated with a particular one of the plurality of selector feet and when a latch needle is in the activation station the latch needle is activated or not activated according to the selection position of the particular selector foot of the plurality of selector feet with which the latch needle is associated. Preferably, each of the plurality of selector feet is coupled to a different piezoelectric motor.
There is further provided, in accordance with a preferred embodiment of the present invention, a method for switching a selector foot between an activate selection position and a deactivate selection position comprising: a) providing said selector foot with a friction coupling surface; b) coupling a piezoelectric motor to said friction coupling surface; and c) using vibrations of said piezoelectric motor to switch said selector foot between said activate selection position and said deactivate selection position. Preferably, coupling the piezoelectric motor to the friction coupling surface comprises pressing a contact surface of the piezoelectric motor to the friction coupling surface with a resilient force. Preferably, the piezoelectric motor has a friction nub and coupling the piezoelectric motor to the friction coupling surface comprises pressing the friction nub to the friction coupling surface with a resilient force.
Preferably, providing the selector foot with a friction coupling surface comprises forming a cylindrical friction surface. Alternatively, providing the selector foot with a friction coupling surface comprises forming a planar friction surface.
In some preferred embodiments of the present invention using vibrations of the piezoelectric motor to switch the selector foot between the activate selector position and the deactivate selector position, comprises using the vibrations to rotate the selector foot through a given angle. Preferably, using vibrations of the piezoelectric motor to switch the selector foot comprises using the vibrations to rotate the selector foot through the given angle in a period of time less than 10 msec. More preferably, using vibrations of the piezoelectric motor to switch the selector foot comprises using the vibrations to rotate the selector foot through the given angle in a period of time less than 7 msec. Most preferably, using vibrations of the piezoelectric motor to switch the selector foot comprises using the vibrations to rotate the selector foot through the given angle in a period of time less than 5 msec. In some preferred embodiments of the present invention using vibrations of the piezoelectric motor to switch the selector foot, comprises using the vibrations to rotate the selector foot through the angle in a period of time substantially equal to 5 msec.
In other preferred embodiments of the present invention, using vibrations of the piezoelectric motor to switch the selector foot, comprises using the vibrations to cause a given linear displacement in the position of the selector foot. Preferably, using vibrations of the piezoelectric motor to switch the selector foot, comprises using the vibrations to cause the given linear displacement in a period of time less than 10 msec. More preferably, using vibrations of the piezoelectric motor to switch the selector foot, comprises using the vibrations to cause the given linear displacement in a period of time less than 7 msec. Most preferably, using vibrations of the piezoelectric motor to switch the selector foot, comprises using the vibrations to cause the given linear displacement in a period of time less than 5 msec. In some preferred embodiments of the present invention using vibrations of the piezoelectric motor to switch the selector foot, comprises using the vibrations to cause the given linear displacement in a period of time substantially equal to 5 msec.
BRIEF DESCRIPTION OF FIGURES
The invention will be more clearly understood by reference to the following description of a preferred embodiment thereof read in conjunction with the attached figures listed below, wherein identical structures, elements or parts which appear in more than one of the figures are labeled with the same numeral in all the figures in which they appear, and in which:
FIG. 1
shows a schematic of parts of a conventional selector used with a shuttle type activation station in a linear knitting machine having a needle bed;
FIGS. 2A-2C
show details of the construction and operation of a conventional selector foot;
FIG. 3
shows schematically parts of a selector, in accordance with a preferred embodiment of the present invention for use with the same shuttle type activation station and linear knitting machine shown in
FIG. 1
; and
FIGS. 4A-4C
show the details of construction and operation of a selector foot in accordance with a preferred embodiment of the present invention.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
FIG. 1
shows a schematic of parts of a conventional selector
20
used with a shuttle type activation station in a linear knitting machine having latch needles held in a needle bed. In this and in the other figures only those parts of the knitting machine, selector and latch needles are shown that are needed for understanding the operation of the selector shown in the figure. The knitting machine needle bed holds a plurality (typically thousands) of latch needles with shafts
22
formed with activation fins
24
in a closely packed parallel array in which the needles are equally spaced from each other. Activation fins
24
are staggered at different positions along the lengths of shafts
22
, and shafts
22
are positioned in the needle bed in such a manner, that activation fins
24
are accurately aligned in N parallel equally spaced rows perpendicular to shafts
22
. In
FIG. 1A
, N=10. The rows are indicated by dashed lines
25
and the first two activation fins
24
of each row are shown. Between any two consecutive activation fins
24
in a row of activation fins
24
there are N−1 latch needles, i.e., the distance between two consecutive activation fins
24
in a same row of activation fins
24
is N times the distance between adjacent latch needles.
Selector
20
comprises a selector frame (not shown) and an array of N selector feet
26
. Selector feet
26
are mounted in a row in the selector frame so that they are parallel to each other and equally spaced one from the other. Each selector foot
26
is mounted to the frame by means of a pin
28
around which selector foot
26
is rotatable. A bimorph activator
30
is coupled to each selector foot
26
by a U coupler
32
having arms
34
and
36
. The space between adjacent selector feet
26
is equal to the space between adjacent rows of activation fins
24
.
Selector
20
moves together with the shuttle activation station of the knitting machine as the activation station shuttles back and forth over the knitting machine's needle bed. Selector
20
moves over and parallel to the needle bed and in a direction parallel to the rows, i.e., parallel to lines
25
, of activation fins
24
, with each selector foot
26
maintained accurately aligned over and close to a different row of activation fins
24
. Each selector foot
26
therefore moves over latch needle shafts
22
in the needle bed along a different row of activation fins
24
and encounters an activation fin
24
once for every N needle shafts
22
that the selector foot
26
passes.
FIGS. 2A-2C
show details of the construction and operation of a selector foot
26
.
FIG. 2A
shows a bimorph activator
30
coupled to selector foot
26
. Bimorph activator
30
is a long thin rectangular strip of piezoelectric material having large face surfaces
38
and ends
40
and
42
. End
40
is situated between arms
34
and
36
of a U connector
32
. End
42
of bimorph
30
is fastened to the frame (not shown) of selector
20
. Bimorph activator
30
bends when a potential difference is applied between faces
38
, otherwise bimorph
30
is straight. In
FIG. 2A
there is no potential difference between face surfaces
38
, and bimorph
30
is straight. When a potential difference is applied between face surfaces
38
, bimorph
30
bends into an arc shape with one of face surfaces
38
concave and the other convex. The direction of the bend depends upon the polarity of the applied potential. The bend causes end
40
to displace and, depending on the polarity of the applied potential, push against and apply a force to arm
34
or arm
36
of U coupler
32
.
FIG. 2B
shows bimorph
30
when a potential difference is applied between face surfaces
38
that causes bimorph
30
to bend so that end
40
presses on arm
36
of U connector
32
. The pressure exerted by end
40
on arm
36
causes selector foot
26
to rotate clockwise through a small angle.
FIG. 2C
shows bimorph
30
when a potential difference is applied between face surfaces
38
which is opposite in polarity to the potential difference applied to face surfaces
38
in FIG.
2
B. In this case bimorph
30
bends in a direction opposite to the bend direction shown in
FIG. 2B
, and end
40
of bimorph
30
presses on arm
34
of U connector
32
. The pressure exerted by end
40
on arm
34
causes selector foot
26
to rotate counterclockwise through a small angle. The size of the angle through which selector foot
26
rotates when end
40
presses on one of arms
34
or
36
depends upon the amplitude of the voltage applied between face surfaces
38
.
In
FIG. 2C
, the potential difference applied between face surfaces
38
of bimorph
30
is sufficient to cause selector foot
26
to rotate clockwise by an angle large enough so that selector foot
26
is in a deactivate selection position. In this selection position, as selector
20
moves along rows of activation fins
24
, selector foot
26
will “collide” with and depress any activation fin
24
that it encounters. This will deactivate the needle to which the activation fin
24
is connected.
In
FIG. 2B
, on the other hand, a potential difference is applied between face surfaces
38
of bimorph
30
which has a polarity opposite to the potential difference applied to face surfaces
38
in FIG.
2
C and which is large enough to cause selector foot
26
to rotate clockwise into an activate selection position. In this position selector foot
26
is out of the way of onrushing activation fins and when it encounters an activation fin
22
, it will not collide with the activation fin
24
. It will “miss” and pass by the activation fin
24
and not depress it. The latch needle to which the activation fin
24
is connected will therefore be activated by the activation station.
FIG. 3
shows schematically parts of a selector
50
, in accordance with a preferred embodiment of the present invention, for use with the same shuttle type activation station and linear knitting machine with which the prior art system shown in
FIG. 1
is used.
Selector
50
preferably comprises a selector frame (not shown) and an array of N selector feet
52
. N is preferably on the order of 10 (
FIG. 3
is shown with N=10). Selector feet
52
are preferably mounted in a row in the selector frame so that selector feet
52
are preferably parallel to each other and equally spaced one from the other. Each selector foot
52
is mounted to the frame by means of a pin
54
around which selector foot
52
is rotatable. Selector foot
52
is preferably formed with, or mounted with, a friction coupling surface
56
. Friction coupling surface
56
is preferably a circularly cylindrical surface with axis congruent with the axis of pin
54
. Friction coupling surface
56
couples selector foot
52
to a piezoelectric motor
58
which is mounted to the selector frame by methods known in the art. The space between adjacent selector feet
52
is equal to the space between adjacent rows of activation fins
24
.
FIGS. 4A-4C
show the details of construction and operation of a selector foot
52
. Referring to
FIG. 4A
, selector foot
52
is shown between activate and deactivate selection positions, in the same orientation with respect to the needle bed of the knitting machine as the orientation of selector foot
26
in FIG.
2
A.
Piezoelectric motor
58
is preferably formed in the shape of a thin rectangular plate having two large planar faces
60
, and short edge surfaces
62
and
64
. For exciting vibrations in the body of piezoelectric motor
58
one planar face surface
60
preferably has at least two surface electrodes and the other planar face surface
60
preferably has at least one surface electrode. Preferably, piezoelectric motor
58
has four quadrant surface electrodes
66
on one face surface
60
and a ground surface electrode on the other, hidden face surface
60
. Piezoelectric motor
58
preferably has a friction nub
68
fixed to edge surface
62
, for coupling to friction coupling surface
56
. Preferably, piezoelectric motor
58
is of the type described in U.S. Pat. No. 5,453,653.
Friction nub
68
is preferably pressed to friction coupling surface
56
by a resilient force
70
applied between short edge
64
and a frame (not shown)of selector
50
. Quadrant electrodes
66
and the ground electrode of piezoelectric motor
58
are preferably connected to a control circuit (not shown) which electrifies them to produce vibrations in the body of piezoelectric motor
58
as described in U.S. Pat. No. 5,453,653. The vibrations preferably produce clockwise or counterclockwise elliptical motion in friction nub
68
which produce respectively clockwise or counterclockwise frictional forces tangent to friction coupling surface
56
. These frictional forces produce torques which rotate selector foot
52
clockwise and counterclockwise to switch selector foot
52
respectively into a deactivate selection position or an activate selection position.
FIG. 4B
shows selector foot
52
in a clockwise, activate selection position, and
FIG. 4C
shows selector foot
52
in a counterclockwise, deactivate selection position.
Preferably, piezoelectric motor
58
can displace a moveable element at a rate of about 400 mm/sec against a force opposing the motion on the order of from 0.2 to 0.5 Newton. At this rate of displacement, assuming the radius of friction coupling surface
56
is 10 mm, piezoelectric motor
58
can rotate selector foot
52
at an angular velocity of about 40 radians/sec or about 2350°/sec. Assuming selector foot
52
must be rotated about 15° to switch selector foot
52
from a deactivate to an activate selection position, selector foot
52
can be switched between selection positions, according to a preferred embodiment of the present invention, in a switching time of about 5 msec.
A selector
50
, in accordance with a preferred embodiment of the present invention, having 10 selector feet
52
operating with a switching time of 5 msec operates at a decision frequency of 2000 Hz.
The present invention has been described using a non limiting detailed description of a preferred embodiment thereof. Variations of the embodiment described will occur to persons of the art. For example, a selector foot can be constructed so that instead of being rotated to switch between selection positions, the selector foot is displaced linearly to switch between selection positions. In this case a friction coupling surface of the selector foot would be a planar surface and selector feet would be mounted to a selector frame so that they slide along appropriate linear guides in the selector. It should also be realized that switching time is a function of the way in which the piezoelectric motor is coupled to the selector foot, the dimensions of the selector foot and the amplitude of the motion needed to switch the selector foot between selection positions. For the cylindrical friction coupling surface described above and a piezoelectric motor of constant speed (and variable power output), for example, switching time is proportional to the radius of the friction coupling surface. Additionally, while the detailed description of a preferred embodiment of the present invention refers to a selector used with a linear knitting machine, a selector in accordance with a preferred embodiment of the present invention, is similarly constructed for selecting latch needles in rotary knitting machines.
Claims
- 1. A selector for a knitting machine, which knitting machine comprises a plurality of latch needles and an activation station, such that when a latch needle of the plurality of latch needles is in the activation station, said selector determines whether said latch needle is activated or not activated comprising:at least one selector foot selectively positionable to an activate or a deactivate selection position, wherein said selector foot has a friction coupling surface; and a piezoelectric motor coupled to said friction coupling surface of the at least one selector foot; wherein vibrations in said piezoelectric motor cause said at least one selector foot to switch between activate and deactivate selection positions.
- 2. A selector according to claim 1 where in said piezoelectric motor is coupled to said friction coupling surface by a resilient force which presses a contact surface of said piezoelectric motor to said friction coupling surface.
- 3. A selector according to claim 1 where in said piezoelectric motor has a friction nub and wherein said piezoelectric motor is coupled to said friction coupling surface by a resilient force which presses said friction nub to said friction coupling surface.
- 4. A selector according to claim 1 wherein said friction coupling surface is cylindrical.
- 5. A selector according to claim 1 wherein vibrations in said piezoelectric motor cause said selector foot to switch between selection positions by rotating said selector foot through a given angle.
- 6. A selector according to claim 5 wherein vibrations in said piezoelectric motor rotate said selector foot through said given angle in a period of time less than 10 msec.
- 7. A selector according to claim 5 wherein vibrations in said piezoelectric motor rotate said selector foot through said given angle in a period of time less than 7 msec.
- 8. A selector according to claim 5 wherein vibrations in said piezoelectric motor rotate said selector foot through said given angle in a period of time less than 5 msec.
- 9. A selector according to claim 5 wherein vibrations in said piezoelectric motor rotates said selector foot through said given angle in a period of time substantially equal to 5 msec.
- 10. A selector according to claim 1 wherein said friction coupling surface is planar.
- 11. A selector according to claim 1 wherein vibrations in said piezooelectric motor cause said selector foot to switch between selection positions by causing a given linear displacement in the position of said selector foot.
- 12. A selector according to claim 11 wherein vibrations in said piezoelectric motor cause said given linear displacement in the position of said selector foot in a period of time less than 10 msec.
- 13. A selector according to claim 11 wherein vibrations in said piezoelectric motor cause said given linear displacement in the position of said selector foot in a period of time less than 7 msec.
- 14. A selector according to claim 11 wherein vibrations in said piezoelectric motor cause said given linear displacement in the position of said selector foot in a period of time less than 5 msec.
- 15. A selector according to claim 11 wherein vibrations in said piezoelectric motor cause said given linear displacement in the position of said selector foot in a period of time substantially equal to 5 msec.
- 16. A selector according to claim 1 wherein the at least one selector foot comprises a plurality of selector feet and wherein each latch needle is associated with a particular one of the plurality of selector feet and when a latch needle is in the activation station said latch needle is activated or not activated according to the selection position of the particular selector foot of the plurality of selector feet with which said latch needle is associated.
- 17. A selector according to claim 16 wherein each of the plurality of selector feet is coupled to a different piezoelectric motor.
- 18. A method for switching a selector foot between an activate selection position and a deactivate selection position comprising:a) providing said selector foot with a friction coupling surface; b) coupling a piezoelectric motor to said friction coupling surface; and c) using vibrations of said piezoelectric motor to switch said selector foot between said activate selection position and said deactivate selection position.
- 19. A method according to claim 18 wherein coupling said piezoelectric motor to said friction coupling surface comprises pressing a contact surface of said piezoelectric motor to said friction coupling surface with a resilient force.
- 20. A method according to claim 19 wherein said piezoelectric motor has a friction nub and wherein coupling said piezoelectric motor to said friction coupling surface comprises pressing said friction nub to said friction coupling surface with a resilient force.
- 21. A method according to claim 18 wherein providing said selector foot with a friction coupling surface comprises forming a cylindrical friction surface.
- 22. A method according to claim 18 wherein using vibrations of said piezoelectric motor to switch said selector foot between said activate selector position and said deactivate selector position, comprises using said vibrations to rotate said selector foot through a given angle.
- 23. A method according to claim 22 wherein using vibrations of said piezoelectric motor to switch said selector foot comprises using said vibrations to rotate said selector foot through said given angle in a period of time less than 10 msec.
- 24. A method according to claim 22 wherein using vibrations of said piezoelectric motor to switch said selector foot comprises using said vibrations to rotate said selector foot through said given angle in a period of time less than 7 msec.
- 25. A method according to claim 22 wherein using vibrations of said piezoelectric motor to switch said selector foot comprises using said vibrations to rotate said selector foot through said given angle in a period of time less than 5 msec.
- 26. A method according to claim 22 wherein using vibrations of said piezoelectric motor to switch said selector foot, comprises using said vibrations to rotate said selector foot through said angle in a period of time substantially equal to 5 msec.
- 27. A method according to any of claims 18-20 wherein providing said selector foot with a friction coupling surface comprises forming a planar friction surface.
- 28. A method according to claim 18 wherein using vibrations of said piezoelectric motor to switch said selector foots comprises using said vibrations to cause a given linear displacement in the position of said selector foot.
- 29. A method according to claim 28 wherein using vibrations of said piezoelectric motor to switch said selector foot, comprises using said vibrations to cause said given linear displacement in a period of time less than 10 msec.
- 30. A method according to claim 28 wherein using vibrations of said piezoelectric motor to switch said selector foot, comprises using said vibrations to cause said given linear displacement in a period of time less than 7 msec.
- 31. A method according to claim 28 wherein using vibrations of said piezoelectric motor to switch said selector foot, comprises using said vibrations to cause said given linear displacement in a period of time less than 5 msec.
- 32. A method according to claim 28 wherein using vibrations of said piezoelectric motor to switch said selector foot, comprises using said vibrations to cause said given linear displacement in a period of time substantially equal to 5 msec.
- 33. A selector according to claim 1 wherein said piezoelectric motor has a contact surface that is resiliently pressed to said friction coupling surface.
- 34. A selector according to claim 33 wherein said piezoelectric motor comprises a friction nub and said contact surface is a surface of the friction nub.
- 35. A selector for a knitting machine, which knitting machine comprises a plurality of latch needles and an activation station, such that when a latch needle of the plurality of latch needles is in the activation station, said selector determines whether said latch needle is activated or not activated, comprising:at least one selector foot selectively positionable to an activate or a deactivate selection position, wherein said selector foot has a friction coupling surface; and a piezoelectric motor having a contact surface pressed against said friction coupling surface of the at least one selector foot to couple the motor to the at least one selector foot; wherein vibrations in said piezoelectric motor cause said at least one selector foot to switch between activate and deactivate selection positions.
- 36. A selector for a knitting machine according to claim 35 wherein said motor is resiliently pressed to said friction coupling surface.
PCT Information
Filing Document |
Filing Date |
Country |
Kind |
102e Date |
371c Date |
PCT/IL97/00426 |
|
WO |
00 |
6/21/2000 |
6/21/2000 |
Publishing Document |
Publishing Date |
Country |
Kind |
WO99/34048 |
7/8/1999 |
WO |
A |
US Referenced Citations (8)
Foreign Referenced Citations (3)
Number |
Date |
Country |
210790 |
Feb 1987 |
EP |
0 784 349 |
Jul 1997 |
EP |
0 796 939 |
Sep 1997 |
EP |