US2288387A - Apparatus for straightening woven material - Google Patents

Description

June 30, 1942. T. M. BERRY 2,283,387

AiPARATUS FOR STRAIGHTENING WOVEN MATERIAL Original Filed April 22, 1938 Apparatuls fbr' ampfifying autpuvf of phoo-e/cc'ric devices and far charging cap a.cior

6'4 in accordance w/fh the difference in qwpub frequencies Inventor i Theodore M. Bert-y,

b M (J y His Attorney.

Patented June 30, 1942 APPARATUS FOR STRAIGHTENING WOVEN MATERIAL Theodore M. Berry, Schenectady, N. Y., assignor to General Electric Company, a corporation of New York Original application April 22, 1938, Serial No.

Divided and this application December 29, 1939, Serial No. 311,537

(Cl. 17520J 4 Claims.

My invention relates to apparatus for straightening woven material, my present application being a division of my copending application Serial No. 203,551, filed April 22, 1938, entitled Apparatus for straightening woven material. In the La Pierre et al., Patent 2,106,612 and in the La Pierre Patent 2,106,611 means are disclosed and claimed for detecting and correcting any skew that may be present in a moving strip of woven material thus straightening it. With apparatus such as that disclosed in those patents, it has been found that under certain conditions the correcting mechanism sometimes had a tendency to oscillate or hunt to an objectionable extent before coming to a final position at which the skew was corrected.

My invention is designed to correct this objection by means of apparatus which is adapted to be substituted for certain parts of theapparatus disclosed in the above mentioned La Pierre Patent 2,106,611. With the apparatus involving my invention when skew appears in the advancing strip of woven material the correct ing means is operated intermittently, that is, it alternately operates and remains at rest for brief periods, the periods of rest serving to delay further correction until the need thereof is found necessary. Moreover, the length of the operating periods depends upon the amount of skew present. If, for example, there is but a small amount of skew in the material the operating periods will be short and the intervening rest periods will be long; conversely, if there is a large amount of skew present the operating periods will be long and the rest periods short. Should the amount of skew detected in the advancing strip increase for any reason notwithstanding the operation of the correcting apparatus the length of the operating periods automatically increases and the length of the rest periods decreases. Likewise, if the amount of skew detected decreases as a result of the operation of the correcting apparatus or otherwise, the length of the operating periods decreases or reduces to zero depending upon the particular conditions present and the length of the rest periods increases. If, however, the detected skew decreases suddenly to substantially zero the straightening means will be operated briefly in the reverse manner, thus in effect anticipating the probable arrival of a reverse skew in the material.

In the above brief description I have used the term skew and shall use it hereinafter in a broad sense covering both that condition of the weft members of the material commonly spoken of as skew and as illustrated by Fig. 4 of the aforesaid Patent 2,106,611 and that condition of the weft members commonly spoken of as bow and as illustrated by Fig. 5 of that patent. Since the skew may occur in either direction, the apparatus which I have devised is constructed to make the necessary correction for either as in the aforesaid patent.

My invention will be better understood from the following description taken in connection with the accompanying drawing, and its scope will be pointed out in the appended claims.

Referring to the drawing which is a combined circuit diagram and fragmentary perspective view of apparatus illustrating an embodiment of my invention, the capacitor 64 is arranged to be given a charge of one polarity or of the opposite polarity in accordance with the presence of skew in one direction or the other in an advancing strip of woven material, the amount of the charge of either polarity being dependent upon the amount of skew being detected in the material. For giving the capacitor 64 a charge in accordance with the character and the amount of skew in the material, I may employ any known apparatus but preferably I employ the apparatus disclosed in the above-mentioned La Pierre Patent 2,106,611 in which-the capacitor 64 corresponds with the capacitor 64 of the present application. For correcting skew in the material to thereby straighten it I may employ an known means such, for example, as that shown in the aforesaid La Pierre et al. Patent 2,106,612 where the relative speeds of the two edges of the strip of woven material is varied by the use of the reversible motor 41 acting through the differential connection with the tenter chains. Instead of the above mentioned apparatus I may employ the straightening means disclosed in the aforesaid Patent 2,106,611 where the reversible motor 22 operates through mechanism of a different type to effect the correction of the skew. In the present application the relays l6 and Ill take the place of the relays 69 and 10 of the patent. The skew detecting apparatus and the skew correctingapparatus disclosed in the aforesaid Patent 2,106,611 may be briefly described as comprising the tenter chains 2 for moving the strip of woven material I, the optical and photoelectric equipment 3; the skew correcting apparatus I, and the reversible motor 5 for operating the same. The electrical apparatus for amplifying the output of the photo-electric devices and for charging the capacitor 84 in accordance l8, the resistance I4 and- IS. The resulting potential dropthrough the 2 with the difference in the output frequencies of those devices is represented by the rectangle 5.

The charge given to the capacitor 64 and hence the average potential difference across it is proportional to the amount of skew in that part of the material passing the point at which the skew is being detected. Connected across the capacitor 64 whose capacitance, for example, may be .02 m. f., through the resistors I and 8, whose resistance may be one-quarter of a megohm each, isthe capacitor 9 whose capacitance,- for example, ma be 1.0 m. 13., this circuit constituting a filter circuit which smooths out the rapid variations in the potential difference across the capacitor 64.

When there is no charge on the capacitor 9, the electron discharge devices I and I0 each pass current through their anode circuits sumcient to operate t e relays II and II therein. Device ID passes current because its grid is connected with its cathode through the resistors l2, l3 and I4 whose respective resistances, for example, may be 2 megohms, megohms and 2 megohms'. Likewise the device It passes current because its grid is connected with the oathode thereof through the resistors |2, l3 and I4 whose resistances also may be 2 megohms, 5 megohms and 2 megohms'respectively. The relays and I I being energized, the windings of the relays l8 and I6 are deenergized since they are arranged to be supplied from the source of current l5 through the back contacts of the relays II and II. The relay "5 is provided with-the 'two armatures l1 and I8 which are arranged to act simultaneously and for this reason are shown tied toget er by a dotted line. The armature II controls one circuit of the reversible motor by which it is caused to rotate in one direction. The other armature l8 operates between the back con- ,tact I9 which connects with one side of the capacitor 9 and the front contact 20 which connects with the upper end of the resistor l3. Connected between these two contacts is the capacitor 2| whose capacitance, for example, may be 0.5 m. f.

The relay l6 like the relay I6 has the two armatures I1 and I8, the armature l1 serving to control the other circuit of the reversible motor by which the motor is caused to operate in the opposite direction and the armature I8 operating between the back contact I9 and the front contact 20 connected respectively with the opposite side of the capacitor 9 and the lower end of the resistor l3. Across these contacts is the capacitor 2| whose capacitance is the same as capacitor 2|. Other capacitors 22, 23, 22 and 23 areemployed to filter out or absorb voltage impulses ar isving from the operation of relays I6 and I6.-

ith no charge on the capacitor 9 the several relays will be in the,position'illustrated'and the reversible motor 5 will be stationary. If an appreciable amount of skew is present in that part of the woven material passing the detecting means, the capacitor 9 will receive a charge which will be maintained substantially uniform by the apparatus l as long' as the amount of skew re-' mains the same. Assuming that this charge makes the upper plate" of the capacitor positive there will be a current flow through the armature I4, and the armature resistor M will make the grid of the device l9 positive whereby the relay II is more strongly energized. The potential drop'through'the"re sistor l4", however, will make the grid of the device |0 sufficiently negative to so reduce the ourrent flow therethrough that the relay II will open. This release of the relay II will cause the energization of relay IS. .The resulting actuation of the armature II will close one circuit of the reversible motor whereby the motor will rotate in the proper direction to cause the straightening means driven thereby to correct the skew in the material. By the actuation of the armature I8 the capacitor 2| is placed in a circuit including the resistors l4 and I4 across the capacitor 9 whereby it receives a charge from that capacitor. The charging of the capacitor 2| requires a certain time interval depending upon its capacitance, the charge on capacitor 9 and the resistance of the resistors I4 and I4. It is during this time interval that the motor 5 is operative. When the potential difference across the capacitor 2 becomes nearly equal to that across the capacitor 9, the potential drop across resistor I4 is insufficient to prevent the device It from passing enough current to operate the relay II. This relay therefore picks up its armature, thereby de-energizing relay I6. Upon the release of this relay the motor circuit 4 is opened whereby the straightening means ceases to function and the armature I8 by reengaging contact I9 allows the capacitor 2| to discharge through it and the resistor I3. The potential drop across the resistor I3 of the discharge current holds the grid of the device I0 positive hence the relay II is maintained energized. When the capacitor 2| has discharged to a certain extent and the discharge current thereof accordingly has become reduced to such a value that the potential difference across the resistor l3 can no longer hold the grid of device l0 positive over the effect of the potential drop across resistor I4 due to the discharge current from capacitor 9, the grid of device l0 again becomes negative and the above mentioned procedure is repeated.

As long as any skew is detected, the apparatus undergoes successive cycles'of operation like that described above and because of the resulting intermittent operation of the skew correcting apparatus 4, which comprises the load on the correcting system, that part of the apparatus connected between the capacitor 84 and the electron discharge devices It and I0 functions as an antihunting means thus avoiding the aforesaid objection. The length of each cycle comprises an interval during which the capacitor 2| is receiving a certain amount of charge from the capacitor 9 and an interval during which the capacitor 2| discharges to a certain extent through the resistor l3. When the amount of skew detected is small and the charge maintained on the capacitor 9 accordingly is small the charging intervals of the capacitor 2| are short in comparison with the discharging intervals thereof, hence the periods of operation of the straightening means are short in comparison with the intervals between those periods.

If a greater amount of skew is detected, a

greater charge is given to the capacitor 9 and the charging intervals of the capacitor 2| are "longer than before but the discharge intervals are shorter. Hence, with a greater amount of'skew the periods of operation of the straightening means are longer and the intervals between those'periods are shorter; Likewise, if the amount of skew increases in spite of theeffort of the apparatus .to reduce it, the peri ds of operation of the straightening means increase in length and the intervals between those periods decrease in length or entirely disappear.

The capacitor 2! Conversely ir the amount of skew decreases,

the amount of charge given to the capacitor 8 accordingly decreases and the charging intervals 01 the capacitor 2| decrease while the discharge intervals thereof increase. Hence, with a decrease in the amount of skew the periods of operation ofv the straightening means decrease in length and the intervals between those periods increase in length. When there is no longer any skew detected the with the relays in the positions illustrated.

Sometimes the skew detecting means shows by its operation that a material amount of skew present suddenly decreases to substantially zero and is immediately followed by a skew in the 15 opposite direction. Such a condition has been found to exist when a seam is passed by which two lengths or the material are Joined end to end and particularly when care has not been taken in making the seam to have on one'side thereof parallel to those on the other. When the straightening apparatus which I have devised encounters such a condition of reverse skew it appears to anticipate the demand for a quick readjustment of the straightening mechanism and does it in the manner now to be described.

The sudden reduction of the first skew to a very small or zero value not only releases the relay IS in the manner already described thereby stopping the motor 5 but also starts the motor rotating in the opposite direction in anticipation 01 a probable opposite skew to follow.

during the sequence of operations just described has, nevertheless, acquired a small charge by reason of the previous potential diiference across the capacitor 9 and the grid current of the device IIJ. This charge it will be noted is such that the plate grid is negative. When, therefore, the charge on the capacitor 9 suddenly reduces to zero or approximately so the grid of I is made suiiiciently negative by the charge on the capacitor 2| to cause it to release the relay H and thus, acting 45 through the relay 56, to cause the motor, to operate in the reverse direction. 'I'he capacitor 2| soon becomes discharged, however, so the relay I! is actuated, the relay [6 is released and the motor stops unless the reverse skew condition or the following portion or the material causes the continued operation thereof.

In the above description, it has been assumed apparatus remains at rest 10 the weft elements although substantially inactive of the capacitor 2| connected with the that the charge given to the capacitor 8 was of a certain polarity. Should this capacitor be given, instead, a charge of the opposite polarity in response to a skew in the opposite direction the apparatus obviously will operate in a manner to cause the motor driving the straightening means to operate in the reverse manner to correct the opposite skew. In that case the grid of the device I 0 is made negative, the relay II is released, the relay l6 is-energized and the other motor circuit is energized all in the same manner as has been described above in the case of the corresponding elements III, II and I6 respectively.

What I claim as new and desire to secure by Letters Patent of the United States is:

1. In combination, a capacitor, an electroresponsive device, means controlled by a charge on said capacitor for causing said device to have alternate periods of operation and non-operation, and means in cooperation with said means for causing the length or the periods of operation to increase and the length of the periods of nonoperation to decrease in response to an increase in said charge.

2. In combination, a capacitor, an electroresponsive device constructed to operate in either of 'two opposite senses, means responsive to a charge on said capacitor for causing said device to operate in one sense, and means responsive to a sudden predetermined decrease insaid charge for causing said device to operate in the opposite sense.

3. In combination, a capacitor, an electroresponsive device, means controlled by a charge on said capacitor for causing said device to have alternate periods of energization and non-energization, and means arranged to cooperate with said means for causing the length of the periods of energization and the length of the periods of non-energization to vary inversely in response to a given change in said charge.

4. In combination, a capacitor, an electroresponsive device, means controlled by a charge on said capacitor for causing said device to have alternate periods of energization and non-energization, and means constructed and arranged to cooperate with said means for causing the rela-

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