The present disclosure relates generally to a knitting machine and, more particularly, relates to a knitting machine with a biased cam member for actuating a sinker.
Various knitting machines have been developed that can automate the knitting process. For example, knitting machines can include a plurality of knitting needles, a carriage, and one or more feeders. The carriage can move the feeder relative to the needles as the feeder feeds yarn toward the needles. The needles can, in turn, form the knitted component from the yarn. These actions can repeat until the knitted component is fully formed.
Knitting machines can also include sinkers that perform various functions during the knitting process. For example, sinkers can assist in formation of loops from the yarn. Sinkers can also hold down formed loops of the knitted component as the needles add new loops to the component. Moreover, sinkers can perform so-called “knock over,” in which the sinker supports a previously-formed loop as a new loop is drawn through the previously-formed loop.
In one general aspect, an embodiment of a knitting machine for knitting a knitted component is disclosed. The knitting machine includes a sinker configured to move between an open position and a closed position. The knitting machine also includes a sinker actuator system having a first configuration and a second configuration. The sinker actuator system, in the first configuration, is configured to actuate the sinker from the open position toward the closed position. Also, the sinker is configured to change the sinker actuator system from the first configuration to the second configuration when the sinker receives an input force above a predetermined threshold in the movement from the open position toward the closed position. The sinker actuator system, in the second configuration, allows the sinker to move away from the closed position toward the open position.
The knitting machine may have a yarn feeder, where a first ramped surface of the yarn feeder is configured to contact the sinker to provide the input force when the sinker impacts the yarn feeder. The sinker may have a second ramped surface configured to contact the yarn feeder when the sinker impacts the yarn feeder.
In another general aspect of the present disclosure, an embodiment of a includes a sinker configured to move between an open position and a closed position. The knitting machine further includes a sinker cam assembly configured to actuate the sinker between the open position and the closed position. The sinker cam assembly includes a cam member configured to move between a first position and a second position. The sinker cam assembly further includes a biasing member that biases the cam member toward the first position with a predetermined threshold force. The cam member, in the first position, is configured to move relative to the sinker to actuate the sinker away from the open position toward the closed position. Also, the cam member is configured to receive an input force from the sinker that moves the cam member away from the first position to the second position when the input force exceeds the predetermined threshold force, thereby allowing the sinker to move away from the closed position toward the open position.
In another general aspect of the present disclosure, a method of actuating a sinker of a knitting machine between an open position and a closed position with a cam assembly is disclosed. The method includes providing a cam member of the cam assembly configured to move between a first position and a second position. The method also includes biasing the cam member with a biasing member toward the first position with a predetermined threshold force. Moreover, the method includes moving the cam member relative to the sinker when the cam member is in the first position to move the sinker between the open position toward the closed position. Furthermore, the method includes moving the cam member relative to the sinker, causing the cam member to receive an input force from the sinker. Additionally, the method includes moving the cam member away from the first position to the second position when the input force exceeds the predetermined threshold force, thereby allowing the sinker to move away from the closed position toward the open position.
Other systems, methods, features and advantages of the embodiments will be, or will become, apparent to one of ordinary skill in the art upon examination of the following figures and detailed description. It is intended that all such additional systems, methods, features and advantages be included within this description and this summary, be within the scope of the embodiments, and be protected by the following claims.
The present disclosure can be better understood with reference to the following drawings and description. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the present disclosure. Moreover, in the figures, like reference numerals designate corresponding parts throughout the different views.
The following discussion and accompanying figures disclose a variety of concepts relating to knitting machines, knitted components, and the manufacture of knitted components.
Various exemplary embodiments of a knitting machine are disclosed below. The knitting machine can include a plurality of sinkers that facilitate the knitting process. These sinkers can be mounted to the knitting machine for movement between an open position and a closed position. By moving toward the closed position, the sinker can assist in formation of loops during formation of a knitted component, can hold down previously-formed loops as new loops are added, and/or can perform “knock-over” and support a previously-formed loop as a new loop is drawn through the previously-formed loop.
The movement of the sinker can be predetermined and controlled by an actuator system. For example, the actuator system can include a cam assembly. As components of the cam assembly move, the cam assembly can actuate the sinker between its open and closed positions.
In some situations, the sinker can receive a load that transfers to the cam assembly. If the load exceeds a predetermined threshold, then the cam assembly can allow the sinker to move away from the closed position toward the open position. Also, the cam assembly can absorb and dampen forces from the sinker and also allow the sinker to move more freely under predetermined conditions. This can, in turn, allow for a wider range of uses of the knitting machine 100 and allow new types of knitted components to be produced.
Referring initially to
Knitting machine 100 can include a plurality of needles 102 and a plurality of sinkers 104, which are illustrated schematically in
First needles 106 and first sinkers 108 can be arranged generally in a first bed 110 of knitting machine 100. In some embodiments, first bed 110 can be substantially planar. As shown in
First bed 110 and second bed 116 can be spaced apart from each other as shown in
As shown in
Feeders 124 can move longitudinally along the respective rail 122 while feeding yarn 125 toward needles 102. It will be appreciated that feeders 124 can be configured to feed any type of yarn, fiber, wire, cable, filament, or other strand toward needles 102.
Needles 102 can receive yarn 125 and can perform various knitting procedures for incorporating yarn 125 into a knitted component 129 as represented in
Needles 102 can be configured to move relative to intersection 120 and relative to other needles 102 within the respective bed. For example, as shown in
In some embodiments, in addition to moving along the longitudinal direction 121, feeder 124 can be configured to move relative to needles 102 between a retracted position and an extended position. In the embodiment of
It will be appreciated that, in other embodiments, feeder 124 can have a single, fixed position relative to intersection 120. For example, in some embodiments, feeder 124 can remain above the intersection 120 as feeder 124 moves in the longitudinal direction 121 of knitting machine 100. Also, in some embodiments, feeder 124 can remain below the intersection 120 as feeder 124 moves in the longitudinal direction 121 of knitting machine 100.
Referring now to
It will be appreciated that sinker 104 and its movement, as illustrated in
In some embodiments, sinker 104 can generally include a yarn engaging surface 141. Yarn engaging surface 141 can be disposed proximate to the gap 118 that is defined between first bed 110 and second bed 116. Yarn engaging surface 141 can move as sinker moves between the open position and the closed position. In some embodiments, movement of yarn engaging surface 141 can be substantially rotational (i.e., angular) as represented by arrow 178 in
As a result of this movement, yarn engaging surface 141 can move relative to the gap 118. For example, yarn engaging surface 141 can be disposed closer to gap 118 and, in some embodiments, disposed within gap 118 when sinker 104 is in the closed position (see
As will be discussed, this movement of sinker 104 can occur during the knitting process. For example, as shown in
Knitting machine 100 can further including a sinker actuator system 127 for actuating sinkers 104 between the open position and the closed position. Actuator system 127 can include one or more cams, electric motors, pneumatic or hydraulic actuators, or other devices that actuate sinkers 104.
For example, in the illustrated embodiments, actuator system 127 can include a cam assembly 128. Cam assembly 128 is indicated schematically in
Cam assembly 128 can be supported by a carriage 126 as shown in
During some operations of knitting machine 100, sinker 104 may receive a relatively high force (i.e., an input load) from something other than cam assembly 128. For example, sinker 104 can be impacted by another object as sinker 104 moves from the open position toward the closed position. In some embodiments, sinker 104 can impact feeder 124 as sinker 104 moves toward the closed position as represented in
As will be discussed, cam assembly 128 can include one or more features that allow sinker 104 to move back toward the open position as a result of the input load. For example, cam assembly 128 can include “break-away” features that allow sinker 104 to move toward the open position when sinker 104 receives an input load that exceeds a predetermined threshold. As such, cam assembly 128 can absorb and dampen forces from sinker 104 and also allow sinker 104 to move more freely under some conditions.
Referring now to
Generally, sinker 104 can include a first member 145, a second member 147, and support structure 144. In some embodiments, support structure 144 can be fixed to surrounding structures of knitting machine 100. First member 145 and/or second member 147 can be attached and supported by support structure 144. Also, first member 145 and/or second member 147 can move relative to support structure 144 as sinker 104 moves between the open position and the closed position.
First member 145 can include a rounded base 146 in some embodiments. Base 146 can be attached to the support structure 144 via a pivot joint 148.
Also, first member 145 can include an arm 150 with a first end 152 and a second end 154. First end 152 can be attached to base 146 and can project radially outward from base 146. Arm 150 can curve circumferentially about base 146. Second end 154 can be disposed proximate to the gap 118 between first needle bed 110 and second needle bed 116.
First member 145 can also include a hook 156 in some embodiments. Hook 156 can project and curve outwardly from arm 150 and can be disposed proximate first end 152.
Additionally, first member 145 of sinker 104 can include an outer abutment surface 157. Abutment surface 157 can be defined partially on hook 156 and on an outer area of arm 150 that is proximate hook 156. Abutment surface 157 can engage second member 147 of sinker 104 as will be discussed.
Moreover, first member 145 can define a head 140. In some embodiments, head 140 can project radially outwardly from arm 150. Head 140 can include yarn engaging surface 141, which is configured to engage the knitted component 129 as shown in
Second member 147 of sinker 104 can include a base 162. Base 162 can include an elongate slot 164. Slot 164 can be axially straight in some embodiments. Also, slot 164 can receive a post 166 of the support structure 144.
Furthermore, in some embodiments, second member 147 can include an arm 168. Arm 168 can extend from base 162 and can be curved in some embodiments. More specifically, arm 168 can extend from base 162 in a direction away from first member 145, and arm 168 can curve at a rear end 170 back toward first member 145 of sinker 104. Additionally, in some embodiments, arm 168 can terminate at a hook end 172. Hook end 172 can abut and engage surface 157 of first member 145. Arm 168 can be flexible and resilient in some embodiments. For example, arm 168 can flex to vary the distance between hook end 172 and base 162. This flexibility can ensure engagement between hook end 172 and surface 157 of first member 145 during movement of sinker 104.
Second member 147 can further include a butt 174 that projects from base 146 in a direction generally away from arm 168. In some embodiments, butt 174 can be disposed generally between slot 164 and rear end 170 of arm 168. Butt 174 can include a first surface 173 and a second surface 175. First surface 173 and second surface 175 can face in opposite directions from each other. First and second surfaces 173, 175 of butt 174 can abut and engage cam assembly 128 for moving sinker 104 between the open position and the closed position as will be discussed.
Movement of sinker 104 from open position of
To move from the open position toward the closed position, cam assembly 128 can apply a force to first surface 173 of butt 174 as represented by arrow 181 in
Then, sinker 104 can move back toward the open position when cam assembly 128 applies the force to second surface 173 of butt 174 as represented in
Moreover, second member 147 can move substantially in a linear direction (i.e., move along a substantially linear path) as sinker 104 moves between the open position and the closed position. This linear movement can be guided due to abutment and sliding of post 166 within slot 164. Thus, second member 147 can be referred to as a “linear actuation member” of sinker 104 in some embodiments.
In contrast, first member 145 can rotate about pivot joint 148 and can move along a substantially angular path as sinker 104 moves between the open position and the closed position. Thus, first member 145 can be referred to as a “rotational actuation member” member of sinker 104 in some embodiments.
As mentioned above, sinker 104 can be actuated between the closed position and the open position by an actuator system 127, such as a cam assembly 128. Cam assembly 128 is shown in detail according to exemplary embodiments in
Cam assembly 128 can be mounted for movement relative to sinkers 104. For example, cam assembly 128 can be supported by carriage 126. As carriage 126 moves, cam assembly 128 can engage and actuate predetermined ones of the sinkers 104 between the open position and the closed position.
Thus, cam assembly 128 can transfer forces to the sinker 104 for moving the sinker 104. In some cases, however, sinker 104 can transfer forces to the cam assembly 128, which causes cam assembly 128 to move from a first position to a second position. As such, cam assembly 128 can absorb and dampen forces from sinker 104 and also allow sinker 104 to move more freely under some conditions. This can, in turn, allow for a wider range of uses of the knitting machine 100 and allow new types of knitted components to be produced.
As shown in
First and second cam members 180, 182 can be spaced apart at a distance 187. In other words, first and second surfaces 184, 186 can define a track 188 having a width that is equal to the distance 187 indicated in
It is noted that although
It will be appreciated that first and second surfaces 184, 186 defining track 188 can be shaped, sized, and arranged in a wide variety of ways without departing from the scope of the present disclosure.
It will be appreciated that second cam surface 186 can abut and push butt 174 of sinker 104 as butt 174 travels in the ascending segment 202 to move sinker 104 toward the closed position. Also, it will be appreciated that first cam surface 184 can abut and push butt 174 of sinker 104 as butt 174 travels in the descending segment 204 to move sinker 104 toward the open position.
In some embodiments, first cam member 180 can be a unitary member such that portions of track 188 defined by first cam surface 184 are substantially fixed.
Also, in some embodiments, second cam member 182 can include a support structure 220 with one or more openings 222. For example, as shown in
Second cam member 182 can also include one or more biased cam members 224. Biased cam member 224 can be received within opening 222. Thus, in the embodiment of
Biased cam members 224 can include an ascending surface 226, a plateau surface 228, and a descending surface 230. Plateau surface 228 can extend between ascending surface 226 and descending surface 230. Biased cam members 224 can further include a peripheral side 229 and an underside 231. Peripheral side 229 can extend about a lower periphery of cam member 224, for example, at the outer periphery of underside 231. Also, underside 231 can face the bottom 236 of opening 222.
When attached to support structure 220, biased cam member 224 can cooperate to define track 188. For example, ascending surface 226 and first cam surface 184 can cooperate to define ascending segment 202 of track 188. Plateau surface 228 and first cam surface 184 can cooperate to define upper level segment 203 of track 188. Descending surface 230 and first cam surface 184 can cooperate to define descending segment 204.
In some embodiments, the size of opening 222 can correspond to the size of biased cam member 224. Thus, biased cam member 224 can move into and out of opening 222 between a first position and a second position.
Additionally, in some embodiments, sides 235 of opening 222 can be proximate to the peripheral side 229 of biased cam member 224. Also, sides 235 and/or structures supported by sides 235 can engage biased cam member 224 to guide movement of biased cam member 224 into and out of opening 222. For example, in some embodiments, peripheral side 229 of biased cam member 224 can abut and slide along sides 235 of opening 222 when moving between the first position (
Also, second cam member 182 can include one or more biasing members 232. In some embodiments, biasing members 232 can be helical compression springs 234. However, it will be appreciated that biasing members 232 could include hydraulic springs, leaf springs, pneumatic springs, or other types of biasing members. Biasing members 232 can be attached at one end to the bottom 236 of opening 222 and attached at the opposite end to the underside 231 of the biased cam member 224.
It will also be appreciated that cam assembly 128 can include any number of biasing members 232. In the illustrated embodiments, for example, each biased cam member 224 is supported by two respective biasing members 232.
Moreover, biasing members 232 can bias cam member 224 toward the first position represented in
Accordingly, as butt 174 of sinker 104 moves within track 188 as represented in
However, under certain conditions, an input load can be applied to sinker 104, and sinker 104 can transfer this load to cam assembly 128. For example,
The input force 240 can be transferred from the first sinker member 145 to the second sinker member 147 as represented in
As a result, biased cam member 224 can recess into opening 222. Stated differently, the input force 240 can cause biased cam member 224 to move away from the first position (
Once the input force 240 is reduced, biasing member 232 can bias cam member 224 back toward the first position (
Biasing member 232 can provide a predetermined threshold biasing force that biases cam member 224 toward the first position. If the input force 240 resulting from the impact with feeder 124 exceeds the predetermined threshold force, then biased cam member 224 can recess into opening 222 toward its second position. However, if the input force 240 is below the threshold, then cam member 224 can remain in its first position. It will be appreciated that the predetermined threshold force can be selected to allow the biased cam member 224 to move to the second position under the influence of relatively high loads, such as when impacting the feeder 124. However, the threshold can be high enough to retain the biased cam member 224 in the first position under the influence of lower loads, such as during normal knitting operations.
Also, in some embodiments, the threshold force provided by biasing member 232 can be varied between a first threshold force and a second threshold force. For example, the biasing member 232 can have a variable stiffness. Also, in some embodiments, the cam assembly 128 can include an actuator 250 that is operably connected to the biasing member 232. The actuator 250 is represented schematically in
In summary, the cam assembly 128 of the knitting machine 100 can actuate the sinkers 104 in an efficient and effective manner for facilitating the knitting process. However, if the sinkers encounter excessive resistance when moving toward the closed position, the cam assembly 128 can allow the sinker 104 to move back toward the open position. For example, if the knitted component 129 is pushing back on the sinker 104 an excessive amount, the cam assembly 128 can give way and allow the sinker 104 to move back toward the open position. Also, if the sinker 104 impacts the feeder 124 when moving toward the closed position, the sinker 104 can push back on the cam assembly 128. The cam assembly 128 can, in turn, allow the sinker 104 to move back toward the open position. Also, cam assembly 128 can absorb and dampen forces from sinker 104. Additionally, in some embodiments, the feeder 124 can remain within the gap 118 below the intersection 120 of the beds 110, 116 of the knitting machine 100. Accordingly, the feeder 124 can be used in a wide variety of positions relative to the beds 110, 116 of the knitting machine 100.
Referring to
In some embodiments, including the embodiment of a knitting machine 400 depicted in
Embodiments with a ramped surface on the feeder and/or the sinker are particularly advantageous when the knitting machine 400 includes a biasing member (e.g., biasing member 232 of
While various embodiments of the present disclosure have been described, the description is intended to be exemplary, rather than limiting, and it will be apparent to those of ordinary skill in the art that many more embodiments and implementations are possible that are within the scope of the present disclosure. Accordingly, the present disclosure is not to be restricted except in light of the attached claims and their equivalents. Also, various modifications and changes may be made within the scope of the attached claims.
This application claims is a continuation of International Application No. PCT/US2016/015126, filed Jan. 27, 2016, which claims the benefit of priority of U.S. Provisional Application Ser. No. 62/108,625, filed Jan. 28, 2015. These applications are both hereby incorporated by reference in their entireties.
Number | Date | Country | |
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62108625 | Jan 2015 | US |
Number | Date | Country | |
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Parent | PCT/US2016/015126 | Jan 2016 | US |
Child | 15659124 | US |