System and method for controlling the stopping point of a tufting machine at a preset stop step in a carpet stitch pattern

Information

  • Patent Grant
  • 6205940
  • Patent Number
    6,205,940
  • Date Filed
    Monday, June 22, 1998
    26 years ago
  • Date Issued
    Tuesday, March 27, 2001
    23 years ago
Abstract
A system and method for controlling the stopping point of a tufting machine in relation to a preset stitch pattern. The system includes a controller and an encoder to detect the current location of a tufting machine needle bar in the stitch pattern. Upon receipt of a stop signal, the controller insures that the needle bar is stopped at a preset stop step in the stitch pattern. In a preferred embodiment of the invention, the controller first slows the main drive shaft of the tufting machine to a jogging speed prior to stopping the tufting machine, and stops the machine at the home position of the carpet pattern. Introducing a delay between receipt of the stop signal and deceleration of the main drive shaft minimizes the jogging time of the machine. The method is directed to stopping the tufting machine at a predetermined stop step and at a position relative to degrees of mainshaft rotation.
Description




A Microfiche Appendix consisting of 2 sheets (150 total frames) of microfiche is included in this application, the contents of which are hereby incorporated herein by reference. The Microfiche Appendix contains material which is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the Microfiche Appendix, as it appears in the Patent and Trademark Office patent files or records, but otherwise reserves all copyright rights whatsoever.




FIELD OF THE INVENTION




This invention generally relates to controlling the operation of carpet tufting machines, and more particularly, to a system for controlling the stopping position of the needle bar of a tufting machine in a preset carpet stitch pattern.




BACKGROUND OF THE INVENTION




A tufting machine produces carpet through the use of a needle bar assembly containing a plurality of needles. The needles stitch yarn for producing the carpet while one or more needle bars move in a side-to-side motion. At a first position (i.e., “home” position), the needle bar is disposed at a starting location within the carpet stitch pattern. At a second position, the needle bar may be displaced horizontally to the right while stitching the carpet. At a third position, the needle bar may again be displaced to the right. After a series of such steps and stitches of the carpet pattern, the needle bar is displaced horizontally in the opposing direction. After a number of steps have been completed, for example 22 steps, the needle bar will have returned to the home position in the carpet stitch pattern. The above process is repeated to produce tufted loop carpeting. In one common technique, the carpet produced by this process has a series of zig-zag edges due to the horizontal left and right displacement of the needle bar. This horizontal displacement helps alleviate some of the defects produced in the manufacture of the carpet, or creates a desired visual appearance.




During normal operation, a tufting machine operates by rotating a main drive shaft at about 450 to 1150 revolutions per minute. The main drive shaft is coupled either directly or indirectly to the needle bar(s) that stitches the carpet. A programmable logic controller (“PLC”) and an inverter drive are commonly used to control the starting and stopping (i.e., drive motion) of the tufting machine. A repeating carpet pattern may be created by a shifting needle bar action produced by a mechanical shifter, hydraulic shifter or other linear displacement mechanism to produce the desired carpet pattern. An encoder detecting system may be employed to track the position of the needle bar assembly within the needle stroke. A count of the steps taken within each pattern can then be communicated by the encoder to a controller. Each time the needle bar completes a pattern cycle, the controller counting the steps is reset.




In the event of yarn breakage or other error condition, the operator of the tufting machine can engage a stop button, or another stop mechanism (i.e., end out detectors) can be engaged, to halt the machine. When the stop signal is received, the operation of the tufting machine typically ramps down to approximately sixty revolutions per minute. This speed is commonly referred to as the “jogging speed” of the machine. Due to the physical momentum introduced by the size of a tufting machine, it may take a series of individual steps for the machine to slow down to reach the jogging speed. For example, where a carpet pattern includes 22 steps and the operator hits the stop button at step


4


, it may take 15 steps before the machine reaches the jogging speed. At the jogging speed, therefore, the machine will have progressed to step


19


in the carpet pattern. After reaching the jogging speed, the tufting machine is braked for needed repair or maintenance of the carpet.




When restarting the machine, a defect may be produced along a given line in the carpet because the tension and feeding of the carpet at that line may result in yarn being tighter or looser than before. To reduce the risk of such a defect, the prior art discloses a method of stopping the needle bar at a given height (i.e., relative position of the drive shaft) within the needle stroke. This technique only alleviates some of the risks of a defect. If the machine is stopped at a point which is far away from a preset stop position, defects may also arise even if the needle bar is stopped at the height taught by the prior art. The prior art thus lacks the advantage of stopping the tufting machine at or about a predetermined step in the stitch pattern such as, for example, the next desired stop position, with a minimum number of jog steps, while at the same time stopping the needle bar at a given height within the needle stroke.




It is therefore an object of the invention to stop a carpet tufting machine at a preset stop step in the carpet pattern.




It is also an object of the invention to stop the needle bar of a carpet tufting machine at the next predetermined stop position and at a certain orientation of mainshaft rotation.




It is a further object of the invention to employ a programmable logic controller and encoder to stop a tufting machine at the next home position.




It is yet another object of the invention to minimize the number of jog steps prior to halting the needle bar at the predetermined stop step.




SUMMARY OF THE INVENTION




In view of the above, a system and method are provided for controlling the stopping point of a tufting machine at a preset stop step in a carpet stitch pattern. According to the system of the invention, a tufting machine for forming pile carpet is provided. The tufting machine includes a frame, a main drive shaft housed within the frame and a series of tufting needles mounted on a reciprocating needle bar assembly connected to the main drive shaft so as to be moveable between raised and lowered conditions. The tufting machine also includes a controller configured to the main drive shaft to control the stopping position of the needle bar assembly at a preset stop step in the carpet stitch pattern. A brake coupled to the main drive shaft is included for stopping the main drive shaft at a predetermined position in the carpet stitch pattern in response to the control means. In the preferred embodiment, the predetermined position is the home position and the tufting machine is slowed to a jogging speed prior to stopping the needle bar.




A method for controlling the stopping point of a tufting machine includes the step of receiving a signal to stop the tufting machine. The tufting machine is then slowed, and the needle bar is stopped at a predetermined stop position within the carpet stitch pattern. In the preferred embodiment of the invention, the predetermined stop position is the home position and the tufting machine is slowed to a jogging speed prior to stopping the needle bar.




In another aspect of the invention, the number of jog steps or jog time required before the tufting machine can be stopped is minimized by controlling the deceleration of the main drive shaft. The deceleration is delayed, from receipt of a stop signal, to a time or position when only a minimum number of jog steps are required before the drive shaft is braked to stop at the predetermined stop step.




According to the present invention, defects created by the stopping and starting of a tufting machine can be reduced or eliminated. By locating the stop position of the needle bar at a preset position in the carpet stitch pattern, fewer defects are created once the tufting machine resumes operation. If a defect is created, however, it is less likely to be detected or observed if located at the same position of the carpet stitch pattern every time the machine is stopped and restarted because the severity of the defect may be reduced. By controlling the location where the needle bar is stopped or halted in response to a need for repair or maintenance of the carpet, the appropriate tension for the yarn used in making the carpet can be properly controlled.




These and other features and advantages of the invention will become apparent upon a review of the following detailed description of the presently preferred embodiments of the invention, taken in conjunction with the appended drawings.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a perspective view of a portion of a carpet tufting machine showing the drive mechanism and control circuitry of the invention;





FIG. 2

is a block diagram of a programmable logic controller and interface for use with the invention shown in

FIG. 1

;





FIG. 3

is a detailed block diagram of the preferred programmable logic controller shown in

FIG. 2

;





FIG. 4

is an alternate embodiment of the programmable logic controller for use with the invention;





FIG. 5

is a flowchart of the operation of the programmable logic controller;





FIG. 6

is a plan view of a control panel used with the interface, where FIG.


6


(


a


) shows a first panel display and FIG.


6


(


b


) shows a second panel display; and





FIG. 7

is a plan view of a graphic user interface for use with a presently preferred industrial computer, where FIG.


7


(


a


) shows a pattern programming screen, FIG.


7


(


b


) lists the stopping steps of a programmed carpet pattern, and FIG.


7


(


c


) lists the programmed deceleration stitches.











DETAILED DESCRIPTION OF THE PRESENTLY PREFERRED EMBODIMENTS




Referring to the drawings, where like reference numerals refer to like objects throughout, a partial view of the pertinent portions of a tufting machine


10


is generally shown in FIG.


1


. The tufting machine


10


includes a main drive shaft


12


, which extends laterally across the top portion of the tufting machine


10


in a manner generally known in the art. The drive shaft


12


is coupled to a needle drive


18


to control the operation of one or more needle bars


20


. Disposed along the length of each needle bar


20


are a plurality of needles


22


used in the formation or stitching of pile carpeting. As the drive shaft


12


rotates, the needle drive


18


causes the needles


22


to move in an up and down (reciprocating) manner to stitch predetermined patterns into rows of tufted loops. The tufted loops are formed from yarn fed into the tufting machine


10


in a manner generally known in the art.




At one end of the drive shaft


12


, a mechanical coupling


14


is positioned for communication or translation of drive shaft


12


operation to an encoder


24


. As shown in

FIG. 1

, the mechanical coupling


14


can comprise a belt driven gear system having a driven gear


15




a


and a drive gear


15




b


. The mechanical coupling


14


preferably includes a translation ratio of 1:1, although other translation ratios are contemplated without departing from the spirit and scope of the invention. Further, other systems to translate drive shaft


12


operation to the encoder


24


are envisioned that may not include a translation mechanism, such as resolvers, or optical, magnetic, or other sensors. In such systems, for example, the drive shaft


12


may be directly coupled to the encoder


24


.




The encoder


24


is used to monitor operation of the tufting machine


10


by tracking the relative position of the needle bar(s)


20


in a carpet stitch pattern. The encoder


24


preferably comprises a wheel or disk (not shown) mounted on a shaft. The wheel or disk is perforated along its perimeter with one or more apertures. As discussed in more detail below, an electric eye or other light sensitive apparatus is employed to count the rotation of the holes or apertures as the wheel or disk rotates in relation to the drive shaft


12


. The count can then be communicated to and translated by the programmable logic controller


28


into a relative position of the needle bar


20


. The counting of the holes by the programmable logic controller


28


enables monitoring the location of the needle bar


20


in the carpet stitch pattern and thus operation of the tufting machine


10


.




The information obtained by the encoder


24


is communicated to the programmable logic controller


28


by means of a communication link


26


. Preferably, the programmable logic controller


28


comprises a Toshiba II PLC. As discussed in more detail below, the programmable logic controller


28


is programmed to operate the tufting machine


10


to stop at a predetermined stop step in the step pattern. The programmable logic controller


28


accordingly controls the stopping of the tufting machine


10


in a manner to reduce or eliminate defects in the carpet being produced.




The system further includes an interface


30


that allows for operator supervision of the tufting machine


10


. According to the preferred embodiment of the invention, the interface


30


comprises an industrial computer, model no. SB586P/100, manufactured by Industrial Computer Source of San Diego, Calif. (described in detail below in connection with FIG.


7


). Alternatively, the interface


30


can comprise a Panelmate Operator Interface manufactured either by Eaton Corporation or Modicon Corporation (described below in connection with FIG.


6


). The interface


30


facilitates the set-up, calibration and programming of the tufting machine


10


to stop the needle bar


20


at a predetermined position (and orientation) in the carpet stitch pattern. According to the preferred embodiment of the invention, the predetermined position is the home position of the carpet stitch pattern, however, any preset stop position within the step count of the carpet stitch pattern can be employed without departing from the spirit and scope of the invention. The interface


30


is coupled to the programmable logic controller


28


and an inverter drive


32


via a coupling


36


. The coupling


36


is an electrical coupling for the communication of signals between the programmable logic controller


28


, the interface


30


and the inverter drive


32


. As those skilled in the art will appreciate, however, other couplings can be employed and are contemplated.




The inverter drive


32


preferably receives a signal from the programmable logic controller


28


to stop the tufting machine


10


. Upon receipt of a stop signal, the inverter drive


32


communicates a signal over the solenoid link


34


to a solenoid


16


mounted on the tufting machine


10


. The signal communicated to the solenoid


16


operates to engage a brake pad


40


and a brake disk


38


coupled to the drive shaft


12


. In this manner, the tufting machine


10


can be stopped at the predetermined position in the stitched carpeting. In the preferred embodiment, the inverter drive


32


receives both a signal to slow and another signal to stop the tufting machine


10


in an effort to reduce the number of jog steps that may occur. By properly sequencing and controlling the generation of these signals, the needle bar(s)


20


can be slowed to the jogging speed and stopped at the next predetermined position.




In the preferred embodiment of the invention, the programmable logic controller


28


generates a signal to begin deceleration of the needle bar(s)


20


. In order to minimize the number of jog steps required after the needle bar


20


has slowed and before the predetermined stop position is reached, a predetermined deceleration stitch position can be programmed into the programmable logic controller


28


to delay deceleration until that position is reached. Preferably, the delay is set to take into account the minimum number of deceleration stitches or steps required for a given tufting machine


10


, at a certain speed, plus one or more jog stitches if necessary. A reduction or elimination in jog time is acheived, therefore, by delaying the generation of the deceleration signal after the operator engages the stop button (not shown) to take into account the number of steps to the next predetermined stop position.




Upon restarting of the tufting machine


10


, the inverter drive


32


communicates a start signal over the solenoid link


34


to the solenoid


16


. In response to the start signal, the solenoid


16


disengages the brake disk


38


and brake pad


40


, thus allowing resumed rotation of the drive shaft


12


. In the preferred embodiment of the invention, the drive shaft


12


is stopped consistently at the same orientation every time. Preferably, the solenoid


16


comprises an air solenoid although other forms of solenoids, and other forms of braking systems, can be employed as those skilled in the art will appreciate.




Referring now to

FIG. 2

, a block diagram of the control elements of the system is shown. As illustrated, the interface


30


is coupled via the coupling


36


to the programmable logic controller


28


. As mentioned above, the programmable logic controller


28


is programmed to properly synchronize the stopping and starting of the tufting machine


10


. As discussed in more detail below in connection with

FIG. 5

, two alternate control programs for the programmable logic controller


28


are included in the Microfiche Appendix. The programs provided in the Microfiche Appendix are presented in a “ladder logic” format generally known in the art for programming programmable logic controllers of the type employed herein.




An expanded block diagram of the system shown in

FIG. 2

is provided in FIG.


3


. As can be seen, a plurality of signals are communicated over the coupling


36


between the interface


30


, the programmable logic controller


28


and the tufting machine


10


. These signals comprise an RS-232 compatible serial communication link


44


, as well as a ground signal


50


, a voltage reference


52


, a neutral reference signal


54


, a slow speed reference input signal


56


and a stop signal output


58


. Preferably, the voltage reference signal


52


is the standard 110-volt signal of alternating current used in the United States. The slow speed reference input signal


56


is received from the inverter drive


32


over the communication link


36


. The stop signal output


58


is communicated to the tufting machine


10


via the solenoid link


34


. In addition, an input


46


communicates a signal received upon engagement of the stop button (not shown). An output


48


is also provided, which communicates a deceleration signal to the inverter drive


32


that can be delayed to minimize jogging time, as described above. In the preferred embodiment, the need and magnitude of any delay is determined by the programmable logic controller


28


.




As shown in

FIG. 3

, the programmable logic controller


28


includes a power supply


60


, a central processor (“CPU”)


62


, a high speed counter module


64


, an input module


66


and a relay output module


68


. According to the preferred embodiment, the power supply


60


comprises a Toshiba #TTS261-S power supply; the CPU


62


comprises a Toshiba #TTU224-S central processor unit; the high speed counter module


64


comprises a Toshiba #EX10-MPI21 pulse modulator; the input module


66


comprises a Toshiba #EX10-MIN51 110-volt AC input module; and the relay output module


68


comprises a Toshiba #EX10-MRO61 relay module. The above elements are preferably housed within a Toshiba #TBU266-S frame or rack (not shown).




As mentioned above, the location of the needle bar


20


is monitored by the encoder


24


and communicated to the programmable logic controller


28


. A signal is therefore generated by the encoder


24


that represents the counting or positioning of the needle bar


20


and needles


22


within the preset carpet stitch pattern. This signal is communicated over the communications link


26


to the programmable logic controller


28


. As shown in

FIG. 3

, some of the signals are directly communicated to the high speed counter module


64


. Once the number of positions within the preset carpet stitch pattern is programmed into the programmable logic controller


28


(see below), the position of the needle bar


20


and needles


22


can be determined as a relative position within the stitch pattern. Having the position of the needle bar


20


and needles


22


, the programmable logic controller


28


can cause the needle bar


20


to stop at the predetermined stop position each time a stop signal is received. A detailed description of the programming of the programmable logic controller


28


is provided below in connection with FIG.


6


.




Referring now to

FIG. 4

, one alternate preferred embodiment for tracking and determining the position of the needle bar(s)


20


is shown. According to the alternate embodiment, a cam


70


is mounted on or coupled to the drive shaft


12


of the tufting machine


10


. Two fiber optic cables


72


are positioned in optical proximity to the cam


70


. The fiber optic cables


72


are coupled at their distal ends to photosensors


74


, which are in turn coupled to the programmable logic controller


28


. The fiber optic cable


72


is preferably manufactured by Banner Engineering Corporation, part no. MQDC-315RA. The fiber within the fiber optic cable


72


is also manufactured by Banner Engineering Corporation, part no. PIT26U, as are the photosensors


74


, part no. SM2A312FPQD. A two-position switch


76


is employed to allow for either manual or automatic operation of the system. Preferably, the switch (part no. 52SA2AAB) is disposed on a testing machine (not shown) and mounted on a no-contact block (part no. BAK).




The alternate embodiment shown in

FIG. 4

preferably operates at 110-volts AC, and directly senses through the photosensors


74


the rotation and/or positioning of the cam


70


. In one embodiment, the cam


70


can include perforations along its perimeter, as described above. Alternately, other markings can be disposed on the cam


70


, which are sensed or detected by the photosensors


74


, or relative linear displacement may be monitored. This in formation is coupled to the programmable logic controller


28


to count electrical/optical pulses received from the photosensors


74


in the manner described above. The programmable logic controller


28


can thus locate the position of the needle bar


20


and can control stopping the needle bar


20


at the predetermined position.




A flow chart identifying the sequence of steps for controlling the tufting machine


10


is shown in FIG.


5


. At step


80


, the number of steps in the preset carpet stitch pattern is programmed into the programmable logic controller


28


. At step


82


, the number of steps desired prior to stopping the needle bar


20


is also inputted. (This allows for the preferred slowing of the tufting machine


10


to the jogging speed.) A delay time may also be inputted at step


84


. At step


86


, the tufting machine


10


is started. The machine


10


continues operation until receipt of a stop signal. Once the stop signal has been detected at step


88


, the program slows the tufting machine


10


at step


90


, and generates a braking signal to stop the machine


10


at the preprogrammed position.




Referring to

FIG. 6

, one control panel for use with the interface


30


is shown: The control panel is employed with a Precision Needle Positioner and Data Key Encore System manufactured by Tuftco. Prior to use of the Precision Needle Positioner, the system should be properly set-up and calibrated. To set-up and calibrate the system, the tufting machine


10


is preferably set for a straight stitch pattern and the machine


10


is jogged until the needles


22


are disposed at the top of their stroke. A pattern key is then inserted and a step pattern is loaded. A calibration key (not shown) is employed while determining the next step using the back bar (not shown) of the tufting machine


10


. Once the next step is determined for the carpet stitch pattern, it will remain the same each time the particular pattern is loaded. Accordingly, the number of stitches per repeat, any stitch correction, the number of stitches to stop on in a straight stitch register, and a stop delay can then be entered or computed. The tufting machine


10


is next jogged to verify that the Precision Needle Positioner and the tufting machine


10


are in calibration. The tufting machine


10


can then be started and stopped as described above. If defects (i.e., stop marks) are visible as a result of such stopping and restarting of the machine


10


, they can preferably be corrected by adding advance if the defect is low or subtracting advance if the defect is high.




As shown, FIG.


6


(


a


) illustrates a first page (e.g., page


0


) of the control panel, and FIG.


6


(


b


) shows a second page (e.g., page


1


) of the same control panel. Both panels include input buttons


100


, and a display area


102


. The display area


102


identifies the page number, as well as specific information about the stitch pattern. This information includes the data entered or determined through the calibration steps described above. As shown in FIG.


6


(


b


), the display area


102


includes page information as well as an entry table for the particular stitch pattern programmed into the tufting machine


10


. Input squares


104


, a cancel button


106


, and a numeric keypad


108


are also provided at the bottom of each panel shown in FIGS.


6


(


a


) and


6


(


b


). Both of the panels shown in FIGS.


6


(


a


) and


6


(


b


) also include arrows


110


that point to the input buttons


100


according to the program in a manner generally known in the art. A set of instructions for setting-up, calibrating, and programming the tufting machine


10


using this interface


30


is included in the Microfiche Appendix, along with a configuration file for one typical carpet stitch pattern.




Referring now to

FIG. 7

, a plan view of the presently preferred graphic user interface for use with the preferred industrial computer is shown. The graphic user interface is provided on a visual display screen (not shown) such as a cathode ray tube, liquid crystal or other display generally known in the art. In FIG.


7


(


a


), a pattern programming screen is provided having a pattern length window


120


. A user or operator can input or program a particular carpet pattern length by providing the number of steps through an input device (not shown). As those skilled in the art will appreciate, such input devices can include keyboards, numeric keypads, or the like, and are generally known in the art. The input pattern thus appears and is displayed in the pattern length window


120


. An actual stop position is displayed in the actual stop position window


122


according to the relative position of main drive shaft


12


rotation in number of pulses. Additional windows are provided to receive a machine speed


124


, a step correction


126


, a back bar step


128


, a stop delay


130


, a prestop/deceleration


132


, a begin correction


134


, a stopping step


136


and


138


, and a register reset


140


.




As described above, by properly selecting the above variables the user or operator can program the programmable logic controller


28


to generate and/or delay the deceleration and stop signal for communication to the tufting machine


10


. The actual stop position window


122


receives the pre-programmed stop step. Based on the revolutions per minute provided in the machine speed window


124


and the value included in the step correction window


126


a stop delay value and a deceleration value can be calculated and displayed in windows


130


and


132


. The number of stopping steps can be inserted by the user or operator and is displayed in windows


136


and


138


. The programmable logic controller


28


can thus determine when to begin deceleration of the tufting machine


10


.




As shown in FIG.


7


(


b


), the stopping steps can be displayed to the operator through stopping step windows


142




a


,


142




b


. A step number and a value for that step is thus displayed to the operator. On the left hand side of the display


142




a


stopping steps


1


-


50


are listed, and on the right hand side of the display


142




b


stopping steps


51


-


100


are listed (for carpet patterns having 100 or fewer steps).




Referring now to FIG.


7


(


c


), a second machine speed window


144


, a prestop window


146


, and a deceleration and jog stitches window


148


are displayed. Based upon the particular machine speed and the programmed prestop value, the number of deceleration stitches can be determined. A window


150


is provided that lists the number of deceleration and jog stitches


152


necessary according to the relative speed of the tufting machine


10


. Accordingly, the step at which deceleration begins can be controlled and delayed by the programmable logic controller


28


in order to minimize or reduce the amount of jogging time required by the tufting machine


10


. A presently preferred computer program listing for control and operation of these functions on the preferred industrial computer is included in the Microfiche Appendix.




As can be seen, the present invention allows for stopping a carpet tufting machine at a predetermined stop position of a preset carpet stitch pattern. The tufting machine can be preferably programmed and controlled to stop at the predetermined stop position when a stop signal is received independent of the current needle bar position. By stopping the needle bar at the predetermined stop position, and at a specific orientation, defects produced when restarting the tufting machine are greatly reduced or eliminated. Moreover, defects that do occur are better hidden and less noticeable if they occur at the same selected stop step of the stitch pattern every time. Introducing a delay between operator engagement of the stop control and the deceleration of the tufting machine also minimizes the number of jog steps initiated or required.




It is to be understood that a wide range of changes and modifications to the embodiments described above will be apparent to those skilled in the art and are contemplated. It is therefore intended that the foregoing detailed description be regarded as illustrative, rather than limiting, and that it be understood that it is the following claims, including all equivalents, that are intended to define the spirit and scope of this invention.



Claims
  • 1. In a tufting machine for forming pile carpet according to a stitch pattern comprised of a predetermined number of steps, the machine having a frame, a main drive shaft housed within the frame, a plurality of tufting needles mounted on a reciprocating needle bar assembly operatively connected to said main drive shaft so as to be moveable between a raised position and a lowered position, a yarn feed system operatively connected to said main drive shaft for feeding yarns to said plurality of needles and drive means for driving said main drive shaft so as to feed yarn and successively form rows of tufted loops from the yarns, the improvement comprising:control means for controlling the stopping of the tufting machine at a preset stop step in the stitch pattern, the preset stop step being selected in relation to a step count in the stitch pattern; and brake means operatively connected to said main drive shaft for stopping said main drive shaft in response to said control means.
  • 2. The tufting machine defined in claim 1, further comprising means for determining the location of the needle bar in the stitch pattern.
  • 3. The tufting machine defined in claim 1 wherein the preset stop step is selected so as to be a home position in the stitch pattern.
  • 4. The tufting machine defined in claim 1, further comprising means for stopping the needle bar in response to a signal, the needle bar being consistently stopped at the same place and same orientation of drive shaft revolution.
  • 5. The tufting machine defined in claim 1, further comprising means for slowing the needle bar to a jogging speed.
  • 6. A tufting machine for forming pile carpet according to a stitch pattern comprised of a predetermined number of steps, the tufting machine comprising:a frame; a main drive shaft housed within the frame; a plurality of tufting needles mounted on a reciprocating needle bar operatively connected to said main drive shaft so as to be moveable between a raised position and a lowered position; a controller operatively connected to the main drive shaft to control the stopping of the needle bar at a preset stop step in the stitch pattern, the preset stop step being selected in relation to a step count in the stitch pattern; and a brake coupled to the main drive shaft for stopping the main drive shaft with the needle bar in the preset stop step.
  • 7. The tufting machine defined in claim 6, further comprising an encoder for locating the position of the needle bar in the stitch pattern.
  • 8. The tufting machine defined in claim 6, further comprising an inverter coupled to the controller, the inverter to start operation of the main drive shaft upon receipt of a starting signal.
  • 9. The tufting machine defined in claim 6, further comprising means for slowing the tufting machine to a jogging speed.
  • 10. The tufting machine defined in claim 6, wherein the the preset stop step is selected so as to have the needle bar in a home position within the stitch pattern.
  • 11. A method for controlling the stopping point of a tufting machine needle bar adapted to be raised and lowered according to a stitch pattern comprised of a predetermined number of steps, the method comprising the steps of:selecting a preset stop step in the stitch pattern in relation a step count in the stitch pattern; receiving a signal to stop the tufting machine; braking the tufting machine in response to the signal to stop the tufting machine so as to stop the needle bar at the preset stop step.
  • 12. The method defined in claim 11, further comprising the step of slowing the tufting machine to a jogging speed prior to stopping the tufting machine at the preset stop step.
  • 13. The method defined in claim 11, further comprising the step of restarting the tufting machine.
  • 14. The method defined in claim 11, wherein the preset stop step comprises a home position within the stitch pattern.
  • 15. The method defined in claim 11, wherein the needle bar is stopped at a predetermined orientation of revolution of a main drive shaft.
  • 16. A tufting machine for forming pile carpet, according to a stitch pattern comprised of a predetermined number of steps, the tufting machine comprising:a frame; a main drive shaft housed within the frame; a plurality of tufting needles mounted on a reciprocating needle bar assembly operatively connected to said main drive shaft so as to be moveable between a raised position and a lowered position; a controller operatively configured to the main drive shaft to control the stopping of the needle bar assembly at a preset stop step in the stitch pattern, the preset stop step selected in relation to a step count in the stitch pattern; means for controlling the deceleration of the main drive shaft; and a brake coupled to the main drive shaft, the brake for stopping the main drive shaft at the preset stop step.
  • 17. The tufting machine defined in claim 16, further comprising an encoder for locating the position of the needle bar in the stitch pattern.
  • 18. The tufting machine defined in claim 16, further comprising an inverter coupled to the controller, the inverter to start operation of the main drive shaft upon receipt of a starting signal.
  • 19. The tufting machine defined in claim 16, further comprising means for slowing the tufting machine to a jogging speed.
  • 20. The tufting machine defined in claim 16, wherein the preset stop step is selected so as to have the needle bar in a home position within the stitch pattern.
  • 21. The tufting machine defined in claim 16, wherein the means for controlling deceleration introduces a delay to said deceleration of the main drive shaft.
  • 22. A method for controlling the stopping point of a tufting machine needle bar in relation to a preset stop step in a stitch pattern comprising the steps of:receiving a signal to stop the tufting machine; controlling the deceleration of the tufting machine after receipt of the stop signal; braking the tufting machine in response to the signal to stop the tufting machine; and stopping the needle bar at the preset stop step in the stitch pattern.
  • 23. The method defined in claim 22, further comprising the step of slowing the tufting machine to a jogging speed prior to stopping the tufting machine at the preset stop step.
  • 24. The method defined in claim 22, further comprising the step of restarting the tufting machine.
  • 25. The method defined in claim 22, wherein the preset stop step comprises a home position within the stitch pattern.
  • 26. The method defined in claim 22, further comprising the step of stopping the needle bar at a predetermined orientation of revolution of a main drive shaft.
  • 27. The method defined in claim 22, wherein the step of controlling deceleration of the tufting machine further comprises the step of delaying said deceleration.
Parent Case Info

This application is a continuation of Ser. No. 08/791,607, filed on Jan. 31, 1997, now U.S. Pat. No. 5,769,012, which claims benefit of provisional application Ser. No. 60/010,964, filed Feb. 1, 1996, the contents of which are hereby incorporated by reference herein.

US Referenced Citations (11)
Number Name Date Kind
3529560 Jackson Sep 1970
3687095 Jackson Aug 1972
3762346 Cobble Oct 1973
3800718 Johnson Apr 1974
4103635 Sedlaczek Aug 1978
4151805 Long et al. May 1979
4241680 Hinch et al. Dec 1980
4478160 Ohniwa Oct 1984
4586446 Cooper May 1986
4627370 Nakamura Dec 1986
4895087 Amos Jan 1990
Provisional Applications (1)
Number Date Country
60/010964 Feb 1996 US
Continuations (1)
Number Date Country
Parent 08/791607 Jan 1997 US
Child 09/102486 US