This disclosure generally relates to the field of braided yarn manufacturing and more particularly to braiding systems and methods and to carriers carrying yarns to be braided.
Composite materials are made using textiles made of rigid and resistant fibers, such as carbon fibers and glass fibers, combined to polymers. These textiles are made of fibers, or yarns of fibers, that are assembled to form felts, fabrics, weaves, braids, ropes, unidirectional ribbons, using different fabrication techniques. Braiding machines are typically used for manufacturing ropes and laces. They may be used to manufacture textiles that can form composite materials for various uses, such has aircraft fuselages, pipes, and beams. These braiding machines carry yarns to be braided on spools.
Different techniques of braiding have a common ground: the unwinding of the spools under tension to ensure that the different yarns do not tangle with one another. The different systems used to control the tension in the yarns may not provide a uniform and constant tension during the braiding process, especially when higher speeds are involved. Increases in tension may create shocks on the yarns. These shocks may lead to premature wear of the yarns.
Moreover, the spools carrying the yarns to be braided follow a predefined path. This predefined path creates variations in the distance between the spools and braiding locations. In some cases, this variation in distances may be too high for the tension control system of the spooled yarns to adapt. That may create tension variation in the yarns. This predefined path also prevent independent movements of the spools and prevent variation in geometry of the braid.
Improvements are therefore sought.
A braiding machine architecture that may allow a completely independent carrier movement is presented. The machine may allow controlling the position of each intertwining yarn to create a three dimensional braid. Each carrier or spool can move without affecting the position of neighbouring carriers. This may allow an easier and total control on the position and morphology of each intertwining yarn.
An alternative to typical horn gear design is disclosed. Gears are independently driven. A carrier path can be divided into multiple pre-defined unitary displacements. Driven by the gears, the carriers follow these successive unitary displacements. This may allow 3D-printing textile composites with tailorable mechanical properties.
A braiding machine architecture allowing a completely independent carrier movement while removing the layer of complexity added by the current switching devices driven independently from the horn gears is presented. By enabling an independent movement of the carrier, each carrier may be moved separately without affecting the positions of its neighbors. Yarns may be added or removed from the braid without any human intervention slowing down the process and the braid architecture may no longer be limited by the braiding machine.
In one aspect, there is provided a carrier for supporting a yarn to be used by a braiding machine, comprising: a spool carrying the yarn; a motor drivingly engaged to the spool; at least one sensor for producing data about a condition of the yarn in the spool; and a controller operatively connected to the motor and to the at least one sensor, the controller having a processor and a computer-readable medium operatively connected to the processor and having instructions stored thereon executable by the processor for: receiving said data from the at least one sensor; determining operation parameters of the motor based on the received data; and operating the motor per the determined operation parameters to create the desired tension in the yarn.
In some embodiments, the receiving of the data includes receiving data about a quantity of yarn remaining around the spool.
In some embodiments, the at least one sensor is a potentiometer engaged to an arm pivotably mounted to a housing of the carrier supporting the spool, a distal end of the arm biased in abutment against the yarn of the spool, the distal end of the arm movable toward the spool as the yarn is consumed, the receiving of the data about the quantity of the yarn includes receiving a signal from the potentiometer indicative of the quantity of the yarn remaining.
In some embodiments, the determining of the operation parameters includes determining a torque generated by the motor.
In some embodiments, the determining of the torque includes determining a current to be supplied to the motor to achieve the determined torque.
In some embodiments, the receiving of the data includes receiving data about an angular position of the motor.
In some embodiments, an encoder is operatively coupled to the motor and to the controller, the receiving of the data includes receiving the angular position of the motor from the encoder.
In some embodiments, a battery is operatively connected to the controller and to the motor, the battery located within a housing of the carrier, the spool rollingly engaged to the housing.
In some embodiments, the controller is further configured for transmitting data about the tension in the yarn.
In some embodiments, the spool is disposed around the motor, a shaft of the motor supported by two arms protruding from a housing, the spool rollingly engaged to the housing via the two arms.
In some embodiments, an end of the spool is rollingly engaged to a housing, the spool sized to receive therein a bobbin of the yarn from an opposed free end of the spool, the spool having a tightening mechanism to secure the bobbin to the spool for concurrent rotation.
In another aspect, there is provided a braiding machine, comprising: a support structure; a matrix of gears supported by the support structure, the gears being rotatable about respective rotation axes, the gears engageable to a carrier carrying a yarn for moving the carrier on the support structure, at least some of the gears of the matrix arranged to form a path between a pair of adjacent ones of the gears to lead to at least two distinct paths, the at least two distinct paths defined by pairs of adjacent ones of the gears; bi-directional motors drivingly engaged to at least some of the gears; and a controller operatively connected to the motors, the controller having a processor and a computer-readable medium operatively connected to the processor and having instructions stored thereon executable by the processor for individually controlling the gears by powering the motors for moving the carriers on the support structure to braid the yarns.
In some embodiments, chains each having at least three rollers are interconnected by at least two arms, the at least two arms pivotable one relative the other about at least one pivot axis normal to the plane, the at least three rollers engageable within notches of the gears for moving the chains on the support structure.
In some embodiments, the carriers have spools carrying the yarns to be braided, the carriers secured to the chains.
In some embodiments, the controller is configured for obtaining data about a desired braid geometry.
In some embodiments, the obtaining of the data includes obtaining data about a sequence of movements of the gears to move the carriers engaged to the gears to obtain the desired braid geometry.
In some embodiments, each of the gears has from five to twenty four notches.
In some embodiments, a diameter of the notches corresponds to a diameter of the rollers, a depth of the notches corresponding to a radius of the rollers.
In some embodiments, the gears of the matrix are equidistantly spaced from one another.
In some embodiments, the gears of the matrix are distributed along rows and columns, a distance between two adjacent gears of the same row corresponding to a distance between two adjacent gears of the same column.
In some embodiments, the controlling of the gears includes rotating a first gear to steer one of the carriers in a given direction and rotating second and third gears for moving the one of the carriers in the given direction.
In some embodiments, the individually controlling of the gears including powering a first one of the gears to orient the carrier toward one of the at least two distinct paths and powering at least a second one of the gears distinct than the first one of the gears for moving the carrier in the one of the at least two distinct paths.
Many further features and combinations thereof concerning the present improvements will appear to those skilled in the art following a reading of the instant disclosure.
Braiding is a process including intertwining at least three yarns in order to create a continuous structure that may be referred to as a braid. A twist may be created using only two yarns. The braid may be produced by moving around carriers on a bedplate. A bedplate may be flat, conical, frustoconical, or cylindrical. A bobbin of yarn is placed on top of each carrier. Paths of the carriers, which may be grooved into the bedplate, intersect each other so as to selectively cause the yarns to intertwine together, hence creating the braid. A pulling mechanism is placed on top of the bedplate in order to pull the yarns and the braided product away from the bedplate.
Referring to
The braiding machine 10 may be used to braid yarns of various types, which may include fibers, such as carbon or glass fibers, in a way to meet target geometrical and mechanical performance of a product. The braided fibers may then be impregnated with polymer materials to form a composite material. During braiding, the fibers or yarn are maintained under tension to obtain the target geometry. The carriers 20 disclosed herein may allow to control the tension on the yarn.
Referring to
A control system 30 is located within the housing 21 and will be described herein below with reference to
The carrier 20 may include a yarn level measuring system 27 that is operatively connected to the control system 30 operable for providing data to the control system 30 about a length of fiber remaining in the spool 22. More particularly, as the yarn is wrapped around the spool 22, the yarn increases an effective diameter of the spool 22. As the yarn gets consumed, this effective diameter decreases until no more yarn is wrapped around the spool 22 and in which the effective diameter of the spool 22 becomes the nominal diameter of the spool 22, that is, the diameter of the spool 22 when it is free of yarn. This change in diameter may affect how a torque generated by motor 25 varies the tension in the yarn. Particularly, for a same torque generated by the motor 25, the tension in the yarn will be greater if the effective diameter is smaller.
In the embodiment shown, the yarn level measuring system 27 includes an arm 27a pivotably engaged to the housing 21 via a mount 27b, which is secured to the housing 21. Idler wheels 27c are rotatably supported at a distal end of the arm 27a and used to rollingly engage the yarn. The idler wheels 27c maintain a slight pressure against the yarn thanks to a biasing member 27d, such as a spring, engaged to the arm 27a and to the mount 27b. A sensor, herein a potentiometer 27e, may be located within the mount 27b and may be operatively connected to the arm 27a. The potentiometer 27e is operatively connected to the control system 30 to supply data to the control system 30 about a level or condition of yarn in the spool 22. For instance, a magnitude of a current going through the potentiometer 27e is altered in function of a position of the arm 27a.
It will be appreciated that any other suitable sensor operable to indicate a level of yarn into the spool 22 is contemplated. For instance, an optical sensor or an ultrasonic distance sensor may be used.
Referring more particularly to
Referring more particularly to
The control system 30 includes a controller 31 having a processor 31a and a computer-readable medium 31b operatively connected to the processor 31a, the readable medium 31b being for example a non-transitory computer-readable memory communicatively coupled to the processor 31a and comprising computer-readable program instructions executable by the processor 31a. The controller 31 is operatively connected to the encoder 26, to the motor 25, and to a transmission module 32 that is used to supply data to the carrier 20 and retrieve data 20 from the carrier 20. The transmission module 32 is herein a wireless module. In the embodiment shown, the transmission module 32 is a Raspberry Pi™ zero wireless. All of the controller 31, the transmission module 32, the battery management system 28a, the battery 28, the transmission module 32 are contained within the housing 21. The controller 31 may have a voltage regulator 31c that is operatively connected to the encoder 26 and to the motor 25. The voltage regulator 31c is operable to control a power supplied to the motor 25 to control the tension in the yarn. The controller 31 is further operatively connected to the potentiometer 27e to receive data about a level of yarn remaining in the spool 22.
The motor 25 may be a BR2212 BLDC motor. The encoder 26 may be a AMT102-V encoder. The controller 31 may be a BDDrive V1 with an on-board voltage regulator XL6009. Any other suitable components may be used without departing from the scope of the present disclosure. In the depicted embodiment, the housing 21 has a diameter of about 11 cm. The carrier 20 has a height of about 26.5 cm. The controller 31 may be an ODrive Robotics™ circuit.
Referring now to
In the pultrusion process, the yarns are pulled and the carriers 120 are used to control a rate at which the yarns get unwound from the spool to control the tension in the yarns. The carriers 120 do not need to move one relative to the other as may be the case for the braiding machine 10 of
The carrier 120 has a housing 121 and a spool 122 rotatably supported by the housing 121. The spool 122 is a rotary axle sized to engage bobbins and a tightening mechanism 123 is used to tighten the bobbins on the spool 122 so that the bobbins and the spool 122 rotate concurrently. In the embodiment shown, the tightening mechanism 123 includes a sprocket wheel 123a having a member secured thereto threadingly engaged to the spool 122. The spool 122 defines a plurality of sections 123b, which are cantilevered. The sections 123b are radially deformable relative to a rotation axis A of the spool 122. Fastening the sprocket wheel 123a and its member secured thereto into the spool 122 deforms the sections 123b radially outwardly away from the rotation axis A until the sections 123b are abutted against and frictionally engaged to the bobbin. The housing 121 is sized to receive the motor 125, the encoder 26, and a control system 130. A connector 129 is secured to the housing 21 and is operatively connected to the control system 130 for powering the carrier 120. The encoder 26 is secured above the motor 125 to obtain the position of the motor 125. The motor 125 may be a MC5206 BLDC motor. The connector 129 may receive an input voltage from 12 to 24 Volts.
Referring to
The housing 121 defines inner walls 121d and guides 121e. The guides 121e are sized for receiving the alimentation cables therebetween. The inner walls 121d may extend along an entire height of the housing 121, from a top wall to a bottom wall thereof, and may substantially define a first chamber 121f (
As illustrated in
Referring to
Referring now to
The control system 130 is similar to the control system 30 described above with reference to
Referring to
The computer-readable medium 31b may comprise any suitable known or other machine-readable storage medium. The computer-readable medium 31b may comprise non-transitory computer readable storage medium, for example, but not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus, or device, or any suitable combination of the foregoing. The computer-readable medium 31b may include a suitable combination of any type of computer memory that is located either internally or externally to device, for example random-access memory (RAM), read-only memory (ROM), compact disc read-only memory (CDROM), electro-optical memory, magneto-optical memory, erasable programmable read-only memory (EPROM), and electrically-erasable programmable read-only memory (EEPROM), Ferroelectric RAM (FRAM) or the like. Computer-readable medium 31b may comprise any storage means (e.g., devices) suitable for retrievably storing machine-readable instructions executable by processing unit 31a.
The method 200 for operating the carrier 20 and/or the carrier 120 described herein may be implemented in a high level procedural or object oriented programming or scripting language, or a combination thereof, to communicate with or assist in the operation of a computer system, for example the controller 31. Alternatively, the method 200 may be implemented in assembly or machine language. The language may be a compiled or interpreted language. Program code for implementing the method 200 may be stored on a storage media or a device, for example a ROM, a magnetic disk, an optical disc, a flash drive, or any other suitable storage media or device. The program code may be readable by a general or special-purpose programmable computer for configuring and operating the computer when the storage media or device is read by the computer to perform the procedures described herein. Embodiments of the method 200 may also be considered to be implemented by way of a non-transitory computer-readable storage medium having a computer program stored thereon. The computer program may comprise computer-readable instructions which cause a computer, or more specifically the processing unit 31a, to operate in a specific and predefined manner to perform the functions described herein, for example those described in the method 200.
Computer-executable instructions may be in many forms, including program modules, executed by one or more computers or other devices. Generally, program modules include routines, programs, objects, components, data structures, etc., that perform particular tasks or implement particular abstract data types. Typically the functionality of the program modules may be combined or distributed as desired in various embodiments.
The method 200 comprises the steps of receiving data about a desired tension in the yarn 202; determining operation parameters of the motor 25, 125 based on the received data 204; and operating the motor 25, 125 per the determined operation parameters to create the desired tension in the yarn 206.
In the embodiment shown, the receiving of the data includes receiving data about a quantity of yarn remaining around the spool 22, 122. The receiving of the data about the quantity of the yarn may include receiving a signal from a sensor such as the potentiometer 27e indicative of the quantity of the yarn remaining. Determining of the operation parameters includes determining a torque generated by the motor 25, 125. The determining of the torque includes determining a current and/or tension to be supplied to the motor 25, 125 to achieve the determined torque. The receiving of the data includes receiving data about an angular position of the motor. The angular position may be supplied by the encoder 26.
The control system 30, 130 is configured to control an input current supplied to the motor 25, 125 to control the torque generated by the motor 25, 125. Based on the quantity of yarn remaining on the spool 22, 122, which is provided by the yarn level measuring system 27, the controller 31 is able to calculate the tension exerted on the yarn.
The controller 31 may be able to store a database to operate the carrier 20, 120. The controller 31 may be able to supply data that is visualized by a user in real time. This data may include, for instance, current to the motor, tension of the power supplied to the motor, the amount of yarn remaining in the spool 22, 122, tension in the yarns, and so on. Each of the communication module 32 of each of the carriers 20, 120 of the braiding machine 10 or pultrusion machine may communicate with a central controller operable by a user, who can visualize the data and control operation of the processes. That is, a user may wirelessly send control commands to the carriers 20, 120 in real time. The user may control the tension wirelessly in real time via the communication module 32.
In a particular embodiment, the carriers 20, 120 allow the programming on-demand of each of the carriers of the braiding machine 10 individually (
Referring to
Referring more particularly to
The braiding architecture in a textile fabric has a great impact on its mechanical properties. The position of each intertwined yarn, dictated by the speed and trajectory of the carriers, defines the braid geometry. With the horn gear system depicted in
Referring now to
Referring to
The chain 410 includes three or more rollers 411, also referred to as cylindrical shafts, disposed longitudinally about a longitudinal axis L of the chain 410. The rollers 411 are connected to one another via arms or links 412. In the embodiment shown, the chain 410 of three rollers 411 defines a pivot axis P allowing the chain 410 to change shape. That is, the chain 410 has two or more sections 413 connected to one another at a pivot point 414 and pivotable one relative to the other about the pivot axis P defined by the pivot point 414. The pivot axis P is normal to the plane of the support structure 401. It will be appreciated that the chain may include more than three rollers and define more than two sections. For a chain of “n” rollers, the chain has “n-1” sections and “n-2” pivot points. For instance, a 4-roller chain has three sections connected to one another via two pivot points. The rollers 411 have a cylindrical shape in order to fit in notches 402a of the gears 402. The rollers 411 may be rotatable about respective roller central axes.
Opposed ends of the chain 410 define flanges 415 that protrude away from the longitudinal axis L. These flanges 415 may provide stability to the carriers 20, 120, 220 when the carriers 20, 120, 220 are moving, or ensure that the chains 410 are constrained to a planar movement in a plane of the support structure 401. In the embodiment shown, some of the flanges 415 are defined by the links 412. Some other of the flanges 415 are defined by separate parts secured to the chain 410.
It will be appreciated that a braiding machine may include any of the carriers 20, 120 described herein above with reference to
Referring to
Referring to
The dimension x may be calculated as follows:
x=(√{square root over (3)}−1)R
Whereas the dimension b is calculated as follows:
Where N is the number of notches 502a of the gear 502.
The number of notches is selected as to prevent the chain 410 from buckling. This may imply that b is less than x. If b is greater than x, the chain 410 might cause a mechanical blockage when transitioning from a gear 502 to the adjacent gears 502. Moreover, to facilitate the engagement of the chain 410 in the adjacent gears 502, which is responsible for steering, b is close to x.
To determine the number of notches N, the following equations are resolved:
This yields:
This means that N is greater than 8.3835. This design equation fixes the number of notches for the hexagonal compact arrangement of gears to 9. In the embodiment shown, the gears have a gear radius R of 33.25 mm. The dimension x is 24.3 mm. Each notch 502a and chain rollers 411, have a diameter of D of 21.92 mm.
Referring now to
In order to move the chain 410 around the support structure 401, the gears 402 cooperate to orient the chain 410. As shown in
As shown in
In the depicted embodiment, at least some of the gears of the matrix arranged to form a path between a pair of adjacent ones of the gears to lead to two distinct paths P1, P2 with other adjacent ones of the gears, each of the two distinct paths defined by two of the gears, the two of the gears including one of the pair of the adjacent ones of the gears and another gear.
In the embodiment shown, the cycle of displacement can be divided into two sequential steps: a 10-degree rotation of the gear responsible to steer the chain 410 in a particular direction; and a 60-degree rotation of the three adjacent gears 402 allowing to move the 402 in the direction selected by the steering gear 402. Therefore, the gears 402 perform two roles: moving the chain 410; and steering the chain 410. This dual role of the gears 402 is such that no other mechanism, such as a switch, a guiding foot, or a transfer mechanical system, is required to steer and move the chain 410, and the carrier 20, 120, 220 secured thereto on the support structure 401. The gears 402 are rotated in accordance with a determined sequence. In the embodiment shown, a gear 402 can only house one roller 411 at a time. This may allow a completely independent carrier movement and the carrier may move around the support structure 401 by successively operating sets of three gears 402.
Referring to
In
Using the disclosed gears 402 and chains 410, a cross-section of the braid may be varied along its length. This may be done by having one of the chains 410, and carrier 220 secured thereto, set aside thereby winding only two yarns of the remaining carriers 220. The chain 410 that was set aside can, after the two yarns have been wound around one another, rejoin them to continue the normal braiding process. With reference to
Consequently, by individually controlling any number of chains 410 by individual control of the motors moving the gears 402, complex geometries of structure may be created. This is enabled by allowing a plurality of possible paths for each of the chains 410. Each of the chains 410 and carriers 20, 120, 220 supported thereto is movable independently from the others. One or more of the chains/carriers may be parked on the side to punctually change the geometry of the braided structure and may re-integrate at any moment to resume the nominal geometry of the braided structure.
The disclosed system may allow to create braid with many thicknesses all connected to one another, within a single fabrication cycle. This is not possible using the horn gear system of
Referring to
Referring to
In this matrix of gears, the chain 410 may be directed toward one of three different paths P5, P6, P7. In this embodiment, once the chain 410 reaches a crossroads of the three paths P5, P6, P7, two gears are powered in opposite direction to direct the chain in either one of those paths. For instance, to direct the chain in the vertically upward path P5, the two gears between which the vertically upward path P5 is defined may be powered to move the chain in said path. Similarly, to direct the chain in the horizontal path P6, the two gears between which said path is defined are powered, and so on for the vertically downward path P7. Once the chain is engaged in one of these three paths P5, P6, P7, a third gear may be powered to move the chain. For instance, when the chain engages any of these three paths P5, P6, P7, the two gears that define the original path PO containing the chain as it reaches the crossroads of the three paths P5, P6, P7 may be powered to move the chain.
In the embodiment shown, at least some of the gears of the matrix are arranged to form a path between a pair of adjacent ones of the gears to lead to three distinct paths P5, P6, P7 with other adjacent ones of the gears, one of the three distinct paths defined by two of the gears, the two of the gears including, for the path P5 or P7, one of the pair of the adjacent ones of the gears and another gear, or, for the path P6, two other gears, each of the two other gears adjacent a respective one of the gears of the pair of adjacent ones of the gears. The pair of adjacent ones of the gears defining the original path P0.
Referring to
Referring to
Referring now to
Referring to
That is, the computer-readable medium 804 may have stored thereon instructions characteristics of a given braid geometry to be created. These instructions may include a sequence of movements to be carried by each of the carriers 220 to achieve the braid geometry. The controller 800 therefore execute the instructions and control rotation of the gears 402 with their respective motors 403 to move the different carriers 220 with respect to the sequence of movements.
The controller 800 is configured for rotating the gears by powering the motors 403 for moving the chains 410 on the support structure 401 to braid the yarns. The controller 800 may be configured to obtaining data about a desired braid geometry. The data about the desired braid geometry may include obtaining data about a sequence of movements of the gears to move the chains on the support structure to obtain the desired braid geometry. The controller 800 may be able to create the sequence of movements in function of a desired braid geometry.
In a particular embodiment, the controller 800 of the gears 403 is operatively connected to the controllers 31 of each of the carriers 20 to allow a control of the tension the yarn in function of the position of the carriers 20 on the support structure, a speed of the carriers 20, and any other suitable properties.
Referring now to
A central one of the rollers 603 remains substantially immobile relative to the top and bottom plates 601, 602. The lateral ones of the rollers 603 are able to move along direction depicted by arrow A1 in relationship to the top and bottom plates 601, 602. In this regard, each of the top and bottom shanks 603B, 603C of the lateral rollers 603 rides within slots 601A, 602A defined by the top and bottom plates 601, 602. These slots 601A, 602A extend generally transversally to a longitudinal axis L along which the rollers 603 are distributed. The slots may be curvilinear, but any suitable shape is contemplated.
In the embodiment shown, biasing members 604 are used to bias the lateral rollers 603 toward a central position, a.k.a., neutral position, in which they are substantially centered within their respective slots 601A, 602A and aligned with the longitudinal axis L. The biasing members 604 includes herein biasing rods 605 that are fixedly secured at their center to one or both of the top and bottom plates 601, 602. Each of the two biasing rods 605 therefore defines two cantilevered rod portions 605A, 605B. The cantilevered rod portions 605A, 605B are able to exert a force on the top shanks 603B of the lateral rollers 603. The biasing rods 605 are able to ride within a recess 601B, which may be shaped like a bowtie, and defined by the top plate 601. In some embodiments, two additional rods may be mounted within a similar recess defined by the bottom plate 602. As an alternative, leaf springs may be used as well.
The link 600 includes a guiding foot 606, or guide 606, that protrudes from the bottom plate 602. The guiding foot 606 includes a front wedge 606A and a rear wedge 606B that may assist in guiding the link 600 within a correspondingly sized track as will be discussed below. The guiding foot 606 may be connected to the bottom plate 602 via fillets. Any suitable shape of the guiding foot 606 is contemplated.
It will be appreciated that a link may include more than three rollers. For instance, a link with five rollers, hence with five axes, may be used without departing from the scope of the present disclosure. More or less rollers may be used.
Referring now to
As shown in
In use, the guiding foot 606 enters the convergent section 901B and is guided toward the straight section 901C, which registers with a location where two adjacent gears are the closest to one another. When it exits the straight section 901C, the divergent section 901D allows the link to move along either one of the two possible directions depending of the rotation of the gears 902. When such engagement is achieved, the link 600 is constrained to movement in a single translational degree of freedom.
The track 901A may help in guiding the links 600 namely during their transition between the different gears 902. This may prevent the links 600 from getting stuck between the gears 902. Therefore, when the guiding foot 600 is located within the straight section 901C of the track 901A, it becomes constrained to a single degree of freedom, thereby reducing the risk of the link 600 getting blocked.
Because of the track 901A in the plate 901, it may be possible to increase a number of the teeth of the gears 902, and, consequently, to increase a number of the notches defined between the teeth of the gears 902. Herein, the gears 902 have 12 notches, but they may have more or less notches. In some embodiments, gears with twenty four notches may be used. These twenty four notch gears may be used with links having 5 rollers. In some embodiments, the notches of the gears may be deeper or shallower than illustrated in
To control the gears 902, a controller, such as the controller 800 described above with reference to
As can be seen therefore, the examples described above and illustrated are intended to be exemplary only. The scope is indicated by the appended claims.
The present application is a divisional application of U.S. patent application Ser. No. 17/493,242, filed on Oct. 4, 2021, that claims the priority of U.S. Patent Application No. 63/086,871, filed on Oct. 2, 2020, the contents of both of which is incorporated herein by reference.
Number | Date | Country | |
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63086871 | Oct 2020 | US |
Number | Date | Country | |
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Parent | 17493242 | Oct 2021 | US |
Child | 18544827 | US |