US2346240A - Stop motion for knitting machines and the like - Google Patents
Stop motion for knitting machines and the like Download PDFInfo
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- US2346240A US2346240A US480138A US48013843A US2346240A US 2346240 A US2346240 A US 2346240A US 480138 A US480138 A US 480138A US 48013843 A US48013843 A US 48013843A US 2346240 A US2346240 A US 2346240A
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- fabric
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- electric cell
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- D—TEXTILES; PAPER
- D04—BRAIDING; LACE-MAKING; KNITTING; TRIMMINGS; NON-WOVEN FABRICS
- D04B—KNITTING
- D04B35/00—Details of, or auxiliary devices incorporated in, knitting machines, not otherwise provided for
- D04B35/10—Indicating, warning, or safety devices, e.g. stop motions
Definitions
- This invention relates to stop motions for knitting machines and the like, and relates more particularly to stop or detector motions for use on warp knitting machines.
- An important object of this invention is the provision of improved means for automatically detecting broken threads or similar defects in the fabric being formed on knitting machines and which causes stoppage of the machine or gives warning of the defect.
- Another object of this invention is to provide a stop or detector motion which operates immediately upon the occurrence of a broken thread or other flaw in the fabric being formed.
- a further object of this invention is to provid a photo-electric cell structure, in a stop or detector motion for a knitting machine, which is stationary with respect to the frame of said machine.
- Stop or detector motions for knitting and weaving machines are known and universally employed. These usually consist of electrical contacts made by metallic droppers or other elements that normally are supported by the thread.
- Patent No. 2,290,257 to Stanley and Edwards there is described a stop or detector motion which employs a photo-electric cell and light source that travels back and forth across the fabric and which examines a single spot of fabric at a time. While this device was an improvement over prior stop motions, it suffered from the same difficulty in that in both types a number of stitches could be knitted or a number of weft yarns laid before the break was detected and the signal given or machine stopped, resulting in several inches of imperfect fabric.
- a transverse moving photo-electric cell stop motion cannot be employed in forming a fabric having several warps of heavy yarn alternating with several warps of fine yarn since the photoelectric cell could not detect the difference between an open stitch and mere passage from the heavy warp to the fine warp.
- the present invention scans the entire width or a substantial Width of fabric at one time and is responsive to an over-all change of transmitted light over the entire width of the fabric. This permits of the use of the device with warps having alternate types of warp yarns such as heavy and fine denier, bright and pigmented yarns,
- the device of my invention does not, of course, prevent breaks in the fabric but it will keep the breaks to small size and confine the defect to a small area. The dropped stitches can be worked in by hand, preventing a degrading of the fabric.
- the device also offers a considerable economy due to the larger number of machines that can be handled by a single operator.
- An important advantage of this device is that it can be used on any type of fabric, including mesh fabrics, drop stitch fabrics, figured fabrics, ribbed fabrics, etc.
- the photo-electric cell of the stop motion has merely to be set to the amount of light coming through the particular fabric being manufactured or inspected, so that a slight additional amount of light, such as would be caused by a broken end in the fabric, will cause the stop motion to become operative.
- Fig. 1 isa somewhat diagrammatic view, in side elevation, of a warp knitting machine showing the relation thereto of the light and photoelectric cell,
- Fig. 2 is an enlarged detail view taken on the line 2 -2 of Fig. 1,
- Fig. 3 is a detailed view of a modified form of photo-electric cell structure
- Fig. 4 is a wiring diagram of the electric circuit employing a combined microammeter and switch contact
- Fig. 5 is a wiring diagram of the electric circuit employing amplifier tubes and milliammeter relay.
- Fig. 1 there is shown the frame I of a warp knitting machine on which may be supported one or a plurality of warp beams 2, guide rollers 3 for bringing the warps to the needles 4 and slnkers and rollers 6 and 1 for taking up the finished fabric.
- Many parts of the machine have been eliminated from the drawings for the sake of clarity, and it is to be understood that the device of my invention may be applied to apparatus other than warp knitting machines.
- Fig. 1 shows the relation of the photo-electric cell 9, its supports or brackets H and source of light
- warps i3 and M are brought from warp beams 2 over guides 3 to the needles 4 where they are knitting into a fabric
- the photo-electric cell 9 may be connected with the amplification and operating circuits, described below, by suitable connecting wires and these circuits may be conveniently located in a cabinet at one end of the machine, however, single stage amplifiers may be inserted in the circuit at various points across the width of the machine to compensate for current losses or line drop.
- Fig. 2 shows, on an enlarged scale, the position of the stop-motion with respect to the fabric.
- 4 pass to the needles 4 where they are formed into a fabric i5 which passes between the source of light I2 and the photo-electric cell 9 supported by brackets
- the source of light may be a fluorescent bulb i6 or other type of bulb containing filaments H.
- the bulb is covered by a reflector l8 having a slotted opening
- a single photoelectric cell 9 may be employed. However, on wider fabrics a number of cells 9 and 9' placed end-to-end, or placed in a staggered relation as shown in Fig. 3, may be employed.
- Figs. 4 and 5 show alternative circuits for supplying current to the bulb and photo-electric cell in conjunction with means for intensifying the small variation of current occurring when the resistance of the photo-electric cell varies in response to a change in light intensity, so that it may be employed for stopping the machine or give the required signal.
- and 22 indicate alternating current supply lines, say, from a 1l5-volt city line which lead into a regular -ampere circuit breaker or fuse box generally indicated by reference numeral 23.
- Bulb I6 is connected to the output side of circuit breaker 23 by conductors 24 and 25.
- a conductor 26 connects supply line 2i to one end of a variable resistance coil 21 and a conductor 28 connects the other end of coil 21 to the filament 29 of an amplifier tube 30.
- the other end of filament 29 is connected by means of conductor 3
- a conductor 35 joins the variable resistance coil 21 to the variable side of photoelectric cell 9. In this modification a plurality of photo-electric cells 9 and 9', which are connected in parallel between conductors 35 and 36, are shown.
- One end of the conductor 36 is connected to the grid 31 of the amplifier tube 30, and the other end thereof is connected to high resistance resistor 36 which in turn is connected to the variable side of the variable resistor 32.
- Plate 39 of the amplifier tube 30 is charged through a circuit comprising a conductor 4
- a combined micro-ammeter and switch 44 is located in a circuit shunted by leads 45 and 46, around condenser 42.
- the micro-ammeter 44 is provided with movable contacts 41 and 48 which with needle 49 act as a switch. Either one, or both, of the contacts 41 and 48 may be connected to a conductor leading to power relay or solenoid 52.
- the needle 49 is connected to a conductor 53 that leads to a secondary terminal of a transformer 54, the other secondary terminal being connected by a conductor 55 to the power relay 52, thus completing the secondary circuit of transformer 54.
- the transformer 54 has a primary circuit directly connected to supply lines 2
- FIG. 5 The embodiment of the invention shown in Fig. 5 employs a one, two or more stages of amplification in place of the micro-ammeter switch 44.
- and 22 pass through a circuit breaker 23, to which conductors 24 and 25 are led to form a circuit for the light bulb l6.
- Conductor 26 connects variable resistance coil 21 with the supply line 2
- Conductor 35 attached to the variable pole of the variable condenser 21 leads to the photo-electric cell 9 with the other contact of cell 9 attached to conductor 36 that leads to the grid 31 of the amplifier tube 30.
- high resistance resistor 38 Connected in parallel with the photo-electric cell 9 is high resistance resistor 38 which ties into the circuit at the variable pole of the variable resistor 32.
- Plate 39 of amplifier tube 38 is connected to supply line 2
- and 34 lead back to supply line 22 thus completing the plate circuit.
- Fig. 5 differs from that shown in Fig. 4 in the following features.
- Connected in parallel with the condenser 42 is a primary circuit of an inductance coil 6
- An ammeter 66 is connected by conductors 61 and 68 to switch 64, so that in setting the circuits for a particular fabric the amperage in the primary circuit of the coil 6
- comprises conductors 89 and II leading to the input side of a single or multiple stage amplifier 12.
- the amplified circuit is carried by conductors l3 and 14 to a sensitive relay 15 that may be of any suitable type, such as a closed iron coil or solenoid. capable of operating a contact switch 16, in a circuit comprising conductors l1 and 18 that are continuations of supply lines 2! and 22, and a power relay 19 that opens contacts 58 of the magnetic switch 59.
- a sensitive relay 15 that may be of any suitable type, such as a closed iron coil or solenoid. capable of operating a contact switch 16, in a circuit comprising conductors l1 and 18 that are continuations of supply lines 2! and 22, and a power relay 19 that opens contacts 58 of the magnetic switch 59.
- the contacts 56 through conductors 51 and 58 control a magnetic starter generally indicated by reference numeral 8
- This starter 8i may be of any conventional type adapted to function with the power supplied by lines 82, 84 and 85. In the type shown, it has a starter circuit comprising conductors 86 and 81, a magnetic switch 59, conductors 51 and 58, an overhead bar 88 and conductor 89.
- the motor 82 can be started, or continues to operate if already started. but when the power relay ((9 in Fig. and 52 in Fig. 4) is energized by the transformed impulse of the light from tube IE on photo-electric cell 9 the contacts 56 are opened and the power to the motor is disconnected.
- any suitable voltage supply may be employed and the various resistors set at a variety of points to balance the set.
- the light is passed through a most dense and then the most open part of a perfect fabric to get the limits of variation in the intensity of light acting upon the photo-electric cell and then adjusting the contacts 41 and 48 in Fig. 4 and the resistance 21 in Fig. 5 so that any greater or lesser surge of current beyond the ascertained limits will cause the operation of the power relays controlling the contacts 56.
- a stop or detector motion for a knitting machine and the like for detecting faults in a fabric comprising a photo-electric cell positioned on one side of said fabric and extending substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric so as to direct light on to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of f auity fabric.
- a stop or detector motion for a knitting machine and the like for detecting faults in a fabric comprising a photo-electric cell positioned on one side of said fabric and extending substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric, means for directing a beam of light from said lightsource on to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
- a stop or detector motion for a knitting machine and the like for detecting faults in a fabric comprising a photo-electric cell positioned on one side of said fabric and extending substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric, means, including a reflector having a slotted opening therein, for directing a beam of light from said light source on to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
- a stop or detector motion for a knitting machine and the like for detecting faults in a fabric comprising a plurality; of photo-electric cells positioned substantially end-to-end on one side of said fabric so as to extend substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric so as to direct light on to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
- a stop or detector motion for a knitting machine and the like for detecting faults in a fabric comprising a plurality of photo-electric cells positioned substantially end-to-end on one side of said fabric so as to extend substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric, means for directing a beam of light from said light source to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
- a stop or detector motion for a knitting machine and the like for detecting faults in a fabric comprising a plurality of photo-electric cells positioned substantially end-to-end on one side of said fabric so as to extend substantially the full width of said fabric, a source of light c0-- extensive with said photo-electric cell and positioned on the opposite side of said fabric, means, including a reflector having a slotted opening therein. for directing a beam of light from said light source on to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
- a stop or detector motion for a knitting machine and the like for detecting faults in a fabric comprising a photo-electric cell positioned on one side of said fabric and extending substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric so as to direct light on to said fabric, and operative means, including a combined microammeter and switch, controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
- a stop or detector motion for a knitting machine and the like for detecting faults in a fabric comprising a plurality of photo-electric cells positioned substantially end-to-end on one side of said fabric so as to extend substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric so as to direct light on to said fabric, and operative means, including a combined microammeter and switch, controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
- a stop or detector motion for a knitting machine and the like for detecting faults in a fabric comprising a photo-electric cell positioned on one side of said fabric and extending substantially the full width of said fabric, a source of light coextensive with said photo-electrlc cell and positioned on the opposite side of said fabric so as to 20 direct light on to said fabric, and operative means controlled by said photo-electric cell, including a plurality of stages of amplification, and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
- a stop or detector motion for a knitting machine and the like for detecting faults in a fabric comprising a plurality of photo-electric cells positioned substantially end-to-end on one side of said fabric so as to extend substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric so as to direct light on to said fabric, and operative means controlled by said photo-electric cell, including a plurality of stages of amplification, and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
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Description
STOP MOTION FOR KNITTING MACHINES AND THE LIKE Filed March 23, 1943 2 Sheets-Sheet l INVENTOR.
ALL AN C. THOMAS.
panama A. c. THOMAS STOP MOTION FOR KNITTING MACHINES AND THE LIKE Filed March 23, 1945 2 Sheets-Sheet 2 m m w m ALLAN C- THOMAS BY 5 W M m'mwe vs Patented Apr. 11, 1944 STOP MOTION FOR KNITTING MACHINES AND THE LIKE Allan Clair Thomas, Cumberland, Md., assignor to Celanese Corporation of America, a corporation of Delaware Application March 23, 1943, Serial No. 480,138
Claims.
This invention relates to stop motions for knitting machines and the like, and relates more particularly to stop or detector motions for use on warp knitting machines.
An important object of this invention is the provision of improved means for automatically detecting broken threads or similar defects in the fabric being formed on knitting machines and which causes stoppage of the machine or gives warning of the defect.
Another object of this invention is to provide a stop or detector motion which operates immediately upon the occurrence of a broken thread or other flaw in the fabric being formed.
A further object of this invention is to provid a photo-electric cell structure, in a stop or detector motion for a knitting machine, which is stationary with respect to the frame of said machine.
Other objects of this invention, together with certain details of construction and combinations of parts, will appear from the following detailed description and claims.
Stop or detector motions for knitting and weaving machines are known and universally employed. These usually consist of electrical contacts made by metallic droppers or other elements that normally are supported by the thread. In Patent No. 2,290,257 to Stanley and Edwards, there is described a stop or detector motion which employs a photo-electric cell and light source that travels back and forth across the fabric and which examines a single spot of fabric at a time. While this device was an improvement over prior stop motions, it suffered from the same difficulty in that in both types a number of stitches could be knitted or a number of weft yarns laid before the break was detected and the signal given or machine stopped, resulting in several inches of imperfect fabric. Moreover, a transverse moving photo-electric cell stop motion cannot be employed in forming a fabric having several warps of heavy yarn alternating with several warps of fine yarn since the photoelectric cell could not detect the difference between an open stitch and mere passage from the heavy warp to the fine warp. The present invention scans the entire width or a substantial Width of fabric at one time and is responsive to an over-all change of transmitted light over the entire width of the fabric. This permits of the use of the device with warps having alternate types of warp yarns such as heavy and fine denier, bright and pigmented yarns,
colorless and colored yarns or combinations of these.
In accordance with my invention, I construct a stop or detector motion, for warp knitting machines, looms, fabric inspection tables, etc., having substantial width and including a source of light adapted to act on a photo-electric cell in such a manner that the increase or decrease of light, transmitted to the photo-electric cell by a missing yarn or a double yarn in the fabric, is amplified in one modification and moves a contact microammeter in another modification to operate a switch controlling the main drive or to operate a visible or audible signal to the machine operator. The device of my invention does not, of course, prevent breaks in the fabric but it will keep the breaks to small size and confine the defect to a small area. The dropped stitches can be worked in by hand, preventing a degrading of the fabric. The device also offers a considerable economy due to the larger number of machines that can be handled by a single operator.
An important advantage of this device is that it can be used on any type of fabric, including mesh fabrics, drop stitch fabrics, figured fabrics, ribbed fabrics, etc. The photo-electric cell of the stop motion has merely to be set to the amount of light coming through the particular fabric being manufactured or inspected, so that a slight additional amount of light, such as would be caused by a broken end in the fabric, will cause the stop motion to become operative.
Referring now to the drawings for a detailed description of this invention.
Fig. 1 isa somewhat diagrammatic view, in side elevation, of a warp knitting machine showing the relation thereto of the light and photoelectric cell,
Fig. 2 is an enlarged detail view taken on the line 2 -2 of Fig. 1,
Fig. 3 is a detailed view of a modified form of photo-electric cell structure,
Fig. 4 is a wiring diagram of the electric circuit employing a combined microammeter and switch contact, and
Fig. 5 is a wiring diagram of the electric circuit employing amplifier tubes and milliammeter relay.
Like reference numerals indicate like parts throughout the several views of the drawings.
In Fig. 1 there is shown the frame I of a warp knitting machine on which may be supported one or a plurality of warp beams 2, guide rollers 3 for bringing the warps to the needles 4 and slnkers and rollers 6 and 1 for taking up the finished fabric. Many parts of the machine have been eliminated from the drawings for the sake of clarity, and it is to be understood that the device of my invention may be applied to apparatus other than warp knitting machines. Fig. 1 shows the relation of the photo-electric cell 9, its supports or brackets H and source of light |2 to the fabric being formed. Thus, warps i3 and M are brought from warp beams 2 over guides 3 to the needles 4 where they are knitting into a fabric |5 that immediately passes between the source of light I2 and the photoelectric cell 9 to the fabric take-up rolls 6 and 1. The photo-electric cell 9 may be connected with the amplification and operating circuits, described below, by suitable connecting wires and these circuits may be conveniently located in a cabinet at one end of the machine, however, single stage amplifiers may be inserted in the circuit at various points across the width of the machine to compensate for current losses or line drop.
Fig. 2 shows, on an enlarged scale, the position of the stop-motion with respect to the fabric. In this view the warp yarns |4 pass to the needles 4 where they are formed into a fabric i5 which passes between the source of light I2 and the photo-electric cell 9 supported by brackets The source of light may be a fluorescent bulb i6 or other type of bulb containing filaments H. The bulb is covered by a reflector l8 having a slotted opening |9 directed toward the fabric. Where the fabric is not too wide a single photoelectric cell 9 may be employed. However, on wider fabrics a number of cells 9 and 9' placed end-to-end, or placed in a staggered relation as shown in Fig. 3, may be employed. Whether the cells are placed end-to-end or staggered depends somewhat on the fineness of the yarns being knitted and on the particular type of electric connections employed on the cells. It is immaterial if the cells overlap as the whole bank of cells is set as one unit, as will appear from a description of Figs. 4 and 5.
Figs. 4 and 5 show alternative circuits for supplying current to the bulb and photo-electric cell in conjunction with means for intensifying the small variation of current occurring when the resistance of the photo-electric cell varies in response to a change in light intensity, so that it may be employed for stopping the machine or give the required signal. Referring particularly to Fig. 4, wherein a combined microammeter and switch is employed, reference numerals 2| and 22 indicate alternating current supply lines, say, from a 1l5-volt city line which lead into a regular -ampere circuit breaker or fuse box generally indicated by reference numeral 23. Bulb I6 is connected to the output side of circuit breaker 23 by conductors 24 and 25.
A conductor 26 connects supply line 2i to one end of a variable resistance coil 21 and a conductor 28 connects the other end of coil 21 to the filament 29 of an amplifier tube 30. The other end of filament 29 is connected by means of conductor 3| to a variable resistor 32 and a constant resistor 33, which are connected in parallel to a conductor 34 leading back to the supply line 22. A conductor 35 joins the variable resistance coil 21 to the variable side of photoelectric cell 9. In this modification a plurality of photo-electric cells 9 and 9', which are connected in parallel between conductors 35 and 36, are shown. One end of the conductor 36 is connected to the grid 31 of the amplifier tube 30, and the other end thereof is connected to high resistance resistor 36 which in turn is connected to the variable side of the variable resistor 32. Plate 39 of the amplifier tube 30 is charged through a circuit comprising a conductor 4| leading to a condenser 42 which is connected to the plate by conductor 43.
A combined micro-ammeter and switch 44 is located in a circuit shunted by leads 45 and 46, around condenser 42. The micro-ammeter 44 is provided with movable contacts 41 and 48 which with needle 49 act as a switch. Either one, or both, of the contacts 41 and 48 may be connected to a conductor leading to power relay or solenoid 52. The needle 49 is connected to a conductor 53 that leads to a secondary terminal of a transformer 54, the other secondary terminal being connected by a conductor 55 to the power relay 52, thus completing the secondary circuit of transformer 54. The transformer 54 has a primary circuit directly connected to supply lines 2| and 22. When the needle 49 closes the secondary circuit of the transformer, it operates the power relay 52 to open contacts 56 connected by conductors 51 and 58 to a signal or to a holding coil circuit of a magnetic switch generally indicated at 59 in Fig. 5.
The embodiment of the invention shown in Fig. 5 employs a one, two or more stages of amplification in place of the micro-ammeter switch 44. Just as in the modification shown in Fig. 4 supply lines 2| and 22 pass through a circuit breaker 23, to which conductors 24 and 25 are led to form a circuit for the light bulb l6. Conductor 26 connects variable resistance coil 21 with the supply line 2|, while conductor 28 is led from the constant pole of the coil 21 to the filament 29 of an amplifier tube 30, the other contact of the filament 29 being connected to conductor 3| which. in turn, is connected to the variable resistor 32 and the constant resistor 33 connected in parallel between the conductors 3| and 34 leading back to the supply line 22, thus forming the filament circuit of the amplifier tube. Conductor 35 attached to the variable pole of the variable condenser 21 leads to the photo-electric cell 9 with the other contact of cell 9 attached to conductor 36 that leads to the grid 31 of the amplifier tube 30. Connected in parallel with the photo-electric cell 9 is high resistance resistor 38 which ties into the circuit at the variable pole of the variable resistor 32. Plate 39 of amplifier tube 38 is connected to supply line 2| to be charged thereby by means of conductor 4| leading to condenser 42 to which is joined conductor 43 leading to plate 33. Conductors 3| and 34 lead back to supply line 22 thus completing the plate circuit.
The modification shown in Fig. 5 differs from that shown in Fig. 4 in the following features. Connected in parallel with the condenser 42 is a primary circuit of an inductance coil 6|, which circuit is formed by a conductor 62 connecting conductor 43 with coil 6| and conductor 63 passing through a double-action switch 64 to a conductor 64 leading back to conductor 4|. An ammeter 66 is connected by conductors 61 and 68 to switch 64, so that in setting the circuits for a particular fabric the amperage in the primary circuit of the coil 6| may be measured. The secondary circuit of coil 6| comprises conductors 89 and II leading to the input side of a single or multiple stage amplifier 12. The amplified circuit is carried by conductors l3 and 14 to a sensitive relay 15 that may be of any suitable type, such as a closed iron coil or solenoid. capable of operating a contact switch 16, in a circuit comprising conductors l1 and 18 that are continuations of supply lines 2! and 22, and a power relay 19 that opens contacts 58 of the magnetic switch 59.
As shown in the embodiment diagrammed in Fig. 5, the contacts 56 through conductors 51 and 58 control a magnetic starter generally indicated by reference numeral 8| of a three-phase motor 82 that may be the source of power for a warp knitting machine, loom, fabric inspection table, etc. This starter 8i may be of any conventional type adapted to function with the power supplied by lines 82, 84 and 85. In the type shown, it has a starter circuit comprising conductors 86 and 81, a magnetic switch 59, conductors 51 and 58, an overhead bar 88 and conductor 89. When contacts 56 are closed the motor 82 can be started, or continues to operate if already started. but when the power relay ((9 in Fig. and 52 in Fig. 4) is energized by the transformed impulse of the light from tube IE on photo-electric cell 9 the contacts 56 are opened and the power to the motor is disconnected.
Obviously, any suitable voltage supply may be employed and the various resistors set at a variety of points to balance the set. To tune the set the light is passed through a most dense and then the most open part of a perfect fabric to get the limits of variation in the intensity of light acting upon the photo-electric cell and then adjusting the contacts 41 and 48 in Fig. 4 and the resistance 21 in Fig. 5 so that any greater or lesser surge of current beyond the ascertained limits will cause the operation of the power relays controlling the contacts 56.
It is to be understood that the foregoing detailed description is given merely by way of illustration and that many variations may be made therein without departing from the spirit of my invention.
Having described my invention what I desire to secure by Letters Patent is:
1. A stop or detector motion for a knitting machine and the like for detecting faults in a fabric, comprising a photo-electric cell positioned on one side of said fabric and extending substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric so as to direct light on to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of f auity fabric.
2. A stop or detector motion for a knitting machine and the like for detecting faults in a fabric, comprising a photo-electric cell positioned on one side of said fabric and extending substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric, means for directing a beam of light from said lightsource on to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
3. A stop or detector motion for a knitting machine and the like for detecting faults in a fabric, comprising a photo-electric cell positioned on one side of said fabric and extending substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric, means, including a reflector having a slotted opening therein, for directing a beam of light from said light source on to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
4. A stop or detector motion for a knitting machine and the like for detecting faults in a fabric. comprising a plurality; of photo-electric cells positioned substantially end-to-end on one side of said fabric so as to extend substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric so as to direct light on to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
5. A stop or detector motion for a knitting machine and the like for detecting faults in a fabric, comprising a plurality of photo-electric cells positioned substantially end-to-end on one side of said fabric so as to extend substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric, means for directing a beam of light from said light source to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
6. A stop or detector motion for a knitting machine and the like for detecting faults in a fabric, comprising a plurality of photo-electric cells positioned substantially end-to-end on one side of said fabric so as to extend substantially the full width of said fabric, a source of light c0-- extensive with said photo-electric cell and positioned on the opposite side of said fabric, means, including a reflector having a slotted opening therein. for directing a beam of light from said light source on to said fabric, and operative means controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
7. A stop or detector motion for a knitting machine and the like for detecting faults in a fabric, comprising a photo-electric cell positioned on one side of said fabric and extending substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric so as to direct light on to said fabric, and operative means, including a combined microammeter and switch, controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
8. A stop or detector motion for a knitting machine and the like for detecting faults in a fabric, comprising a plurality of photo-electric cells positioned substantially end-to-end on one side of said fabric so as to extend substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric so as to direct light on to said fabric, and operative means, including a combined microammeter and switch, controlled by said photo-electric cell and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
9. A stop or detector motion for a knitting machine and the like for detecting faults in a fabric, comprising a photo-electric cell positioned on one side of said fabric and extending substantially the full width of said fabric, a source of light coextensive with said photo-electrlc cell and positioned on the opposite side of said fabric so as to 20 direct light on to said fabric, and operative means controlled by said photo-electric cell, including a plurality of stages of amplification, and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
10. A stop or detector motion for a knitting machine and the like for detecting faults in a fabric, comprising a plurality of photo-electric cells positioned substantially end-to-end on one side of said fabric so as to extend substantially the full width of said fabric, a source of light coextensive with said photo-electric cell and positioned on the opposite side of said fabric so as to direct light on to said fabric, and operative means controlled by said photo-electric cell, including a plurality of stages of amplification, and adapted to stop the machine or give a warning indication on undue variation of the amount of light entering said photo-electric cell by reason of faulty fabric.
ALLAN CLAIR THOMAS.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US480138A US2346240A (en) | 1943-03-23 | 1943-03-23 | Stop motion for knitting machines and the like |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US480138A US2346240A (en) | 1943-03-23 | 1943-03-23 | Stop motion for knitting machines and the like |
Publications (1)
Publication Number | Publication Date |
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US2346240A true US2346240A (en) | 1944-04-11 |
Family
ID=23906799
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US480138A Expired - Lifetime US2346240A (en) | 1943-03-23 | 1943-03-23 | Stop motion for knitting machines and the like |
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US (1) | US2346240A (en) |
Cited By (18)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2421092A (en) * | 1944-08-18 | 1947-05-27 | Celanese Corp | Stop motion for knitting machines and the like |
US2429529A (en) * | 1945-07-23 | 1947-10-21 | Crompton & Knowles Loom Works | Electronic weft detector for looms |
US2429528A (en) * | 1945-04-05 | 1947-10-21 | Crompton & Knowles Loom Works | Electronic weft detector for looms |
US2431650A (en) * | 1946-06-06 | 1947-11-25 | Crompton & Knowles Loom Works | Electric weft detecting system for looms |
US2432171A (en) * | 1945-06-30 | 1947-12-09 | Crompton & Knowles Loom Works | Weft detecting system for looms |
US2432793A (en) * | 1945-06-30 | 1947-12-16 | Crompton & Knowles Loom Works | Photoelectric weft detector for looms |
US2466332A (en) * | 1946-07-26 | 1949-04-05 | Crompton & Knowles Loom Works | Control for loom electronic systems |
US2570381A (en) * | 1947-12-13 | 1951-10-09 | Celanese Corp | Stop motion for textile machines |
US2609553A (en) * | 1949-01-11 | 1952-09-09 | United Shoe Machinery Corp | Machine cycle control system |
US2611097A (en) * | 1946-05-23 | 1952-09-16 | Celanese Corp | Photoelectric controlled device for knitting machines |
US2694305A (en) * | 1951-04-27 | 1954-11-16 | Raymonde Lebocey | Circular single or multineedle bed knitting machine |
US2852697A (en) * | 1954-03-10 | 1958-09-16 | Clarence A Davenport | Optical system for measurement and control |
US2859603A (en) * | 1956-06-12 | 1958-11-11 | Photobell Company | Stop motion device for fabric producing machines |
US2991639A (en) * | 1957-11-15 | 1961-07-11 | Meiners Optical Devices Ltd | Fault finder |
US3001080A (en) * | 1956-01-11 | 1961-09-19 | Special Instr Lab Inc | Inspection apparatus |
US3065615A (en) * | 1959-06-01 | 1962-11-27 | Abrams Abraham | Material examining apparatus |
US3116621A (en) * | 1960-09-02 | 1964-01-07 | Fabric Res Lab Inc | Fabric flaw detector |
US3530690A (en) * | 1968-03-29 | 1970-09-29 | Appalachian Electronic Instr | Yarn inspection apparatus |
-
1943
- 1943-03-23 US US480138A patent/US2346240A/en not_active Expired - Lifetime
Cited By (18)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2421092A (en) * | 1944-08-18 | 1947-05-27 | Celanese Corp | Stop motion for knitting machines and the like |
US2429528A (en) * | 1945-04-05 | 1947-10-21 | Crompton & Knowles Loom Works | Electronic weft detector for looms |
US2432171A (en) * | 1945-06-30 | 1947-12-09 | Crompton & Knowles Loom Works | Weft detecting system for looms |
US2432793A (en) * | 1945-06-30 | 1947-12-16 | Crompton & Knowles Loom Works | Photoelectric weft detector for looms |
US2429529A (en) * | 1945-07-23 | 1947-10-21 | Crompton & Knowles Loom Works | Electronic weft detector for looms |
US2611097A (en) * | 1946-05-23 | 1952-09-16 | Celanese Corp | Photoelectric controlled device for knitting machines |
US2431650A (en) * | 1946-06-06 | 1947-11-25 | Crompton & Knowles Loom Works | Electric weft detecting system for looms |
US2466332A (en) * | 1946-07-26 | 1949-04-05 | Crompton & Knowles Loom Works | Control for loom electronic systems |
US2570381A (en) * | 1947-12-13 | 1951-10-09 | Celanese Corp | Stop motion for textile machines |
US2609553A (en) * | 1949-01-11 | 1952-09-09 | United Shoe Machinery Corp | Machine cycle control system |
US2694305A (en) * | 1951-04-27 | 1954-11-16 | Raymonde Lebocey | Circular single or multineedle bed knitting machine |
US2852697A (en) * | 1954-03-10 | 1958-09-16 | Clarence A Davenport | Optical system for measurement and control |
US3001080A (en) * | 1956-01-11 | 1961-09-19 | Special Instr Lab Inc | Inspection apparatus |
US2859603A (en) * | 1956-06-12 | 1958-11-11 | Photobell Company | Stop motion device for fabric producing machines |
US2991639A (en) * | 1957-11-15 | 1961-07-11 | Meiners Optical Devices Ltd | Fault finder |
US3065615A (en) * | 1959-06-01 | 1962-11-27 | Abrams Abraham | Material examining apparatus |
US3116621A (en) * | 1960-09-02 | 1964-01-07 | Fabric Res Lab Inc | Fabric flaw detector |
US3530690A (en) * | 1968-03-29 | 1970-09-29 | Appalachian Electronic Instr | Yarn inspection apparatus |
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