US2441283A - Apparatus for continuously determining thickness and hardness of metallic strip - Google Patents

Apparatus for continuously determining thickness and hardness of metallic strip Download PDF

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US2441283A
US2441283A US619881A US61988145A US2441283A US 2441283 A US2441283 A US 2441283A US 619881 A US619881 A US 619881A US 61988145 A US61988145 A US 61988145A US 2441283 A US2441283 A US 2441283A
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strip
thickness
gauge
hardness
circuit
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Charles M O'hara
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Carnegie Illinois Steel Corp
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Carnegie Illinois Steel Corp
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01BMEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
    • G01B7/00Measuring arrangements characterised by the use of electric or magnetic techniques
    • G01B7/02Measuring arrangements characterised by the use of electric or magnetic techniques for measuring length, width or thickness
    • G01B7/06Measuring arrangements characterised by the use of electric or magnetic techniques for measuring length, width or thickness for measuring thickness
    • G01B7/10Measuring arrangements characterised by the use of electric or magnetic techniques for measuring length, width or thickness for measuring thickness using magnetic means, e.g. by measuring change of reluctance
    • G01B7/107Measuring arrangements characterised by the use of electric or magnetic techniques for measuring length, width or thickness for measuring thickness using magnetic means, e.g. by measuring change of reluctance for measuring objects while moving
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N3/00Investigating strength properties of solid materials by application of mechanical stress
    • G01N3/40Investigating hardness or rebound hardness
    • G01N3/42Investigating hardness or rebound hardness by performing impressions under a steady load by indentors, e.g. sphere, pyramid

Definitions

  • temper prior to the advent of cold reduction processes, was used to denote hardness developed by the addition of carbon and heat treatments, and more particularly in the class of carbon tool steels to indicate the carbon content.
  • temper as applied to the finished product denotes hardness developed by cold rolling, or the ability to resist indentation or flexing.
  • specimens from the finished material are subjected to deformation tests in order to compare the hardness value with socalled standards, such, for instance, as the Rockwell scale.
  • standards such as the Rockwell scale.
  • Such tests while perhapsnot recognized as standard in the stricter sense, serve very well for plant control of the product, and until better methods are devised, will continue to be acceptable.
  • the specimens are indented beyond their elastic limit and the area of deformation measured and translated into terms of hardness. Based upon hardness indicated, material is either accepted as meeting specifications, re-rolled, or reclassified into other'temper groups.
  • the procedure outlined involves endless repe-' titions which are expensive to practice, and in addition does not include any provision for observing elongation and temper in the material during the continuous rolling process. Elongation is checked only once on each coil processed and variations in gauge of the strip will be reflected as variations in temper, and as result, uneven temper will be created throughout the length of the strip.
  • the present invention has for one important object the provision of means for continuously measuring and recording temper of rapidly moving strip material as it exists from a cold rolling mill. 4
  • a further object is to provide a combination of means which can be used for controlling temper of a rapidly moving strip to a degree where the temper will be maintained evenly and continuously throughout the entire strip length during the rolling operation.
  • the present invention utilizes two somewhat similar gauges located side by side in close proximity to the exit rolls of the mill and extending over the edge of the strip in order that the gauging rolls are positioned a material distance from the edge.
  • One of the gauges measures, only thickness of the strip, while'the second gauge measures both thickness and hardness, and each is provided with a separate electrical circuit which is caused to function variably in response to mechanical movement of the gauge parts during operation.
  • the circuit of the first gauge delivers electricalcurrent of a value representative of strip thickness
  • the circuit of the second gauge delivers electrical current of a greater value representing both thickness and hardness of the strip.
  • reference numeral 6 represents what is known .movement of rollers 1, which movement is indicated on meter 9.
  • This flying micrometer gauge may be of the type described in detail in United States Letters Patent No. 2,001,840, issued July 9, 1935, to spencer B. Terry, and consequently need not be described here in detail.
  • Thickness and temper of the strip are obtained by the use of.
  • a second gauge III which is generally similar to gauge with reference to general design, but in addition to registering variations in thickness simultaneously registers variations in strip hardness or temper also.
  • the contact roll I2 of gauge III is providedwith adiustins means to adjust the opening between rollers I2 and I3 for specific strip thickness while roll I3 is equipped with means for compressing the strip beyond its elasticlimit to determine hardness.
  • Such means comprise screw 2I,'cup 22, and spring.
  • roll I2 remains at all times in a vertically fixed position, as determined by the adjustment of the manual adjusting means it, while roll I3 is capable of relative approaching and separating movement with respect to roll I 2 by reason of the fact that roll I3 is supported in the shank 24, which is slidably contained in the gauge housing.
  • the shank 24 is urged resiliently upwardly by spring 23 in response to manual tuming of the screw 2i, thus establishing the approaching movement of roller I3 to roller I2.
  • the resiliency of spring 23, when properly adiusted, permits controlled downward movement of shank 24 and separation of the rollers I2 and I3 in response to variations of strip thickness and hardness.
  • Corresponding movements of shank 24 are transmitted to the armature 26 by guides 21 and 28 (see Figure 3), which guides are integral with the shank 24 and maintain intimate contact with armature 26, the armature 26 being attached to the gauge housing by a flexible support 38.
  • circuits shown in Figure 1 are of generally standard construction, those employed for the gauges 5- and, I0 being duplicates and reading directly on United States Letters Patent No. 1,640,464, dated August 30, 1927, and issued to Alfred V. Mershon.
  • the secondary terminal 44 of the transformer 33 is commonly connected at 4
  • the discharging terminals 48 and 49 of inductance 32 are connected respectively to the other terminals 50 and SI of electromagnets 31 and 36, and across potentiometer 34 and rectifier I6 at terminals 52 and 53 on the latter.
  • Thickness meter 29 is connected across the output terminals 64 and 65 of rectifier I6, which converts the alternating current input into direct current output.
  • induced currents are set up in the different branches including windings around electromagnets 36 and 31 within the gauge housing.
  • the intensities of the induced currents in the two branches of the circuit are influenced by the varying distances of armature 26 from the two oppositely positioned magnets 36 and 31, these variations of armature distances being caused by movements of shank 24 in response to variations of strip material being gauged.
  • the variations in current in the two branches connected to terminals 62 and 63 of rectifier I6 function to deflect the pointer of thickness meter 29 connected across the output terminals of the rectifier I6.
  • the potentiometer 34 is used to adjust inductance of the circuit during setting operation or the gauge in order to cause the pointer of meter 29 to register zero.
  • Temper of the metal being gauged is indicated by a microammeter I1, the two lead wires 51 and 56 of which are connected to output terminals 54 of rectifiers I5 and I6, and the tie-in wire 69 connects the opposite output terminals together. It will be seen from Figurel that the meter I1 and'the rectifiers l5 and I6 are connected in series, so that any difference in output from rectifiers I5 and I6 will be indicated by a corresponding movement of the pointer of meter I1. Such ing gauged.
  • gauges 6 and III In operating .the system of the present invention, it is necessary first to set the gauges 6 and III. In the case of gauge 5, the procedure is outlined thoroughly .in the aforementioned Terry patent, and needs no further description here. However, it is to be remembered that the gauge 5 measures only variations in strip thickness which are introduced into the circuit of rectifier I6 in the form of induced currents.
  • roller I2 is retracted by operating the screw 20, and the screw 2! is backed out, thus relieving any compressive force against shank 24.
  • the gauge shoe 56 of prescribed thickness is inserted into the position shown, and causes shank 24 to assume a position whereby the coacting guides 21 and 28 will cause the free end of armature 26 to attain a position exactly midway between the poles of the electromagnets 38 and 31.
  • the pointer 01 meter 29 should register zero, but if it does not, the desired register may be obtained by moving arm 46 of potentiometer 34, which controls induced current in the circuit between cored inductance 32 and 'electromagnets 36 and 31.
  • the screw 2! is now adjusted to a point just short of causing upward movement of shank 26, with consequent unbalancing of the induction circuits and movement of the pointer of meter 29 from the zero register previously attained.
  • the gauge block then is removed and a second standard specimen it, similar to the one still in gauge 5, is placed between rollers I2 and I3.
  • This latter specimen in addition to being in exact duplication of the thickness required, must also possess a hardness value required in the finished metallic strip that is to be rolled.
  • the roller I2 is now adjusted by screw 20 until it contacts the surface of the specimen l4, and care must be exercised in making this adjustment so that the separation of the rollers l2 and I3 will be equiva- Is it only to the thickness of the specimen It. Any overadjustment can readily be detected by movement of the pointer of meter 29 from zero register.
  • gauges As described above, it may be saidthat the circuits thereof are electrically balanced with respect to their output which represents exact thicknessvalue of standard specimens It.
  • gauge ill will be purposely unbalanced and caused to indicate combined values of hardness (H) and thickness (T) which are in excess of the single value (T) as indicated by the other gauge.
  • Movement of the pointer of the meter i'l can be'read directly on the graduations, which in the present case conveniently correspond to'those of the Rockwell scale for hardness, and when the pointer registers the established known value of standard specimen I, no further adjustment is required.
  • the gauge will continuously measure variations in strip thickness as'represented in the value of its circuit, while gaugelil measures combined variations in thickness and hardness as represented in the value of its circuit and the difference in values of the measurements of the two gauges will register continuously on meter I! as hardness, or temper.
  • Figure 2 there are shown the gauges of Figure 1 in position on a moving strip M, for taking the measurements of thickness and temper, following the setting of the gauges, as described above. Only enough of the wiring diagram of Figure 1 is included in Figure 2 to show the rethe additional hardness value H, screw 2
  • the lower portion of the housing is closed on one side by a face plate 60 which is held in position bymeans of machine screws 62 which pass through holes provided therefor in the face plate, which holes register with similar internally threaded holes in the housing.
  • a threaded plug 65 having holes therethrough for the reception of insulating bushings 66 through which the leads for the magnets pass.
  • the face plate 60 is a casting having the shape as shown, and is provided with an interior lug 64 having a groove therein for receiving the support 38 for armature 26.
  • the support 38 has suflicient rigidity to maintain the armature 26 in adjusted position, but sufliciently flexible to bend responsively to separating movements between rollers i2 and I3 from their set position.
  • Apparatus for continuously measuring gauge and temper of metallic strip which comprises a pair of micrometer gauges one or which gauges is adapted to measure thickness of the strip, the second of the gauges being adapted to" measure thickness and hardness of the strip, a first electrical circuit for the thickness-measuring gauge, a second circuit for the second gauge, the circuit for the thickness measuring gauge being adapted to deliver current of a value representative of strip thickness, the second circuit being adapted to deliver current representing both thickness and hardness of the strip, a third circuit connected in series with the said first andsecond circuits adapted to match current outputs of the first and second circuits, and means in the third circuit for measuring differences in the current outputs of the first and second circuits, the said difl'erences in current outputs representing hardness of the strip.
  • Apparatus for continuously measuring gauge and temper of metallic strip which comprises a pair of micrometer gauges, one of which gauges is adapted to measure thickness of the strip, the second of the gauges being adapted to measure thickness and hardness of the strip,. instrumentaiities connected to the second of said gauges for converting thickness and hardness of the strip into electrical current of a value corresponding to the thickness and hardness of the strip, instrumentalities connected to the first of said gauges for converting thickness of .the strip into electrical current of a value corre sponding to the thickness of the strip, and electrical means connected to both of said instrumentalities for determining difference in values of the said currents, the said'difierence in current values representing hardness of the strip.
  • Apparatus for continuously measuring gauge and temper of metallic strip which comprises a pair of micrometer gauges, one of which gauges is adapted to measure thickness of the strip. the second of which gauges being adapted to measure thickness and hardness of the strip, an electrical circuit for the strip-thickness gauge adapted to convert thickness of the strip into an electrical current of a value corresponding to the thickness of the strip, a second circuit for the second gauge adapted to convert thickness and hardness of the stripinto electrical current of a value corresponding to the thickness and hardness of the strip, a third circuit connected to the thickness measuring circuit and to the said second circuit, and means in the said third circuit operable responsively. to diiferences in current output of the thickness-measuring circuit and the said second circuit for indicating hardness of the strip.
  • Apparatus for continuously measuring gauge and temper of continuously moving metallic strip which comprises a pair of micrometer gauges, one c! which gauges is adapted to measure thickness or the strip, the second of which gauges is adapted to measure thickness and hardness of the strip, an electrical circuit for the strip-thickness gauge, a second electrical circuit for the second gauge.
  • each of the said circuits having two branches, rectifying means in each of the said circuits, each of the rectifying means having a pair of input terminals and a pair of output terminals, the two branches or each of the said circuits being connected to the input terminals of the respective rectifying means, instrumentalities for inducing alternating currents in both oi!
  • the induced current in the circuit for the thickness-measuring gauge beingoi a value corresponding to the thickness of the strip
  • the induced current in the second circuit being of a value corresponding to the thickness and hardness oi! the strip
  • Apparatus for continuously measuring gauge and temper of continuously moving metallic strip which comprises, in combination, a pair of micrometer gauges one of which gauges is adapted to measure thickness of the strip, the second of which gauges is adapted to measure thickness and hardness-of the strip, an electrical circuit for the strip thickness gauge, asecond electrical circuit for the second gauge, each of the said circuits having two branches, rectifying means in I each of the said circuits, each 01 the rectifying means having a pair of input terminals and a pair of output terminals, the two branches ofeach of the said circuits being connected to the input terminals of the respective rectifying means, ing currents in both of the said circuits, the induced current in the circuit for the thicknessmeasuring gauge being of a value corresponding to the thickness of the strip, the induced current in the second circuit being of a value corresponding to the thickness, and hardness of the strip, means forinitially balancing the currents in both circuits responsively to a setting of the gauges on standard specimens of strip,
  • Apparatus for continuously measuring gauge and temper of continuously moving metallic strip which comprises, in combination, a pair of micrometer gauges, one of which gauges is adapted to measure thickness of the strip, the second of which gauges is adapted to measure thickness and hardness of the strip, on electrical circuit for the strip thickness-measuring gauge, a second electrical circuit for the second gauge, each of the said circuits having two branches, rectifying means in each of the said circuits, each of the rectifying means having a pair of input terminals and a pair of output terminals, the two instrumentalities for inducing altemat-j ness of the strip,
  • each of thesaid circuits being con- 4 nected to the input terminals of therespective ness measuring gauge being of a value correspending to the thickness of the strip
  • the induced current in the second circuit being of a value corresponding to the thickness and hardmeans for initially balancing the currents in both circuits responsively to a setting of the gauges on standard specimen of the strip
  • the second gauge comprising a pair of rolls adapted to engage the strip on opposite of the said pair of rolls being fixedly mounted relative to the strip, resiliently mounted mechanismacting on the other roll of the pair to continuously urge the said roll against the strip with a predetermined force while enabling the roll to yield responsively to variations in thickness and hardness 'of the strip, oppositely spaced electromagnets in the second circuit.
  • a resiliently mounted armature positioned between the magnets and movable in the second circuit in 10' relatively thereto in response to movement of the said yieldable roll, thereby varying the current amounts corresponding to variations in'the strip, and a third circuit connected in series to the output terminals of the said rectifying means and including a milliammeter graduated in hardness values operable responsively to difierences in current inputs to the rectiflers from the strip thickness-measuring circuit and the said second circuit.

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Description

May H, 1948. c. M. OHARA 1,
, APPARATUS FOR CONTINUOUSLY DETERMINING THICKNESS AND HARDNESS OF METALLIC STRIP Filed Oct 2, 1945 2 Sheets-Sheet 1 INVENTOR 2,441,283 ICKNESS y 1948- c. M. OHARA APPARATUS FOR CONTINUOUSLY DETERMINING TH AND HARDNESS OF METALLIC STRIP Filed Oct. 2, 1945 2 Shets-Sheet 2 INVEI ITOR CharZcsM. OHara Patented May 11, 1948 APPARATUS FOR CONTINUOUSLY DETER- G THICKNESS AND HARDNESS OF METALLIC STRIP Charles M. O'Hara, Gary, Ind asslgnor to Carnegie-Illinois Steel Cor of New Jersey poration, a corporation Application october 2, 1945, Serial No. -c19,ss1
(oi. 'zs vs') 7 Claims. 1
In the art of steel making, the term temper," prior to the advent of cold reduction processes, was used to denote hardness developed by the addition of carbon and heat treatments, and more particularly in the class of carbon tool steels to indicate the carbon content. In connection with strip rolling,.however, the term temper as applied to the finished product denotes hardness developed by cold rolling, or the ability to resist indentation or flexing.
One of the more common methods practiced to obtain temper in metallic strip is to subject it to a skin pass on a cold rolling mill wherein the metal will be elongated slightly. The degree of temper so obtained is in direct relationship to the amount of elongation, and obviously, therefore, it is necessary to measure elongation to control temper imparted to the material during'coid working. Since there is no known method of measuring elongation accurately in a continuous manner, it therefore is necessary to apply spacedapart markings to the strip and measure it after rolling to determine elongation. This operation may be repeated several times on each coil before the correct roll edjustment is secured to provide the extent of elongation .and degree of temper.
As a further check, specimens from the finished material are subjected to deformation tests in order to compare the hardness value with socalled standards, such, for instance, as the Rockwell scale. Such tests, while perhapsnot recognized as standard in the stricter sense, serve very well for plant control of the product, and until better methods are devised, will continue to be acceptable. In order to be conclusive, the specimens are indented beyond their elastic limit and the area of deformation measured and translated into terms of hardness. Based upon hardness indicated, material is either accepted as meeting specifications, re-rolled, or reclassified into other'temper groups.
The procedure outlined involves endless repe-' titions which are expensive to practice, and in addition does not include any provision for observing elongation and temper in the material during the continuous rolling process. Elongation is checked only once on each coil processed and variations in gauge of the strip will be reflected as variations in temper, and as result, uneven temper will be created throughout the length of the strip.
The present invention has for one important object the provision of means for continuously measuring and recording temper of rapidly moving strip material as it exists from a cold rolling mill. 4
A further object is to provide a combination of means which can be used for controlling temper of a rapidly moving strip to a degree where the temper will be maintained evenly and continuously throughout the entire strip length during the rolling operation.
Further objects of the invention will become apparent as the description proceeds, and the features of novelty will be set forth in the appended claims. It is to be understood, also, that the specific embodiment of the invention herein illustrated and described is not intended to be any more than an example of one form of apparatus which may be provided for carrying out the objects of the invention, as the principles of the invention are capable of being incorporated 'into other modifications.
Generally speaking, in order to determine uniformity and degree of temper of a strip as it leaves the final mill pass, the present invention utilizes two somewhat similar gauges located side by side in close proximity to the exit rolls of the mill and extending over the edge of the strip in order that the gauging rolls are positioned a material distance from the edge. One of the gauges measures, only thickness of the strip, while'the second gauge measures both thickness and hardness, and each is provided with a separate electrical circuit which is caused to function variably in response to mechanical movement of the gauge parts during operation. In practice, as the moving strip passes between the rollers of the respective gauges, the circuit of the first gauge delivers electricalcurrent of a value representative of strip thickness, and the circuit of the second gauge delivers electrical current of a greater value representing both thickness and hardness of the strip. By continuously matching the output of the two circuits against each other in a third circuit, the difference existing between the first two named is readily detected and represents hardness or temper of the moving strip.
The invention will be understood more readily scription of mary winding of tive view of a portion of the sectioned left-hand gauge- Reierring more particularly to the drawings,
reference numeral 6 represents what is known .movement of rollers 1, which movement is indicated on meter 9. This flying micrometer gauge may be of the type described in detail in United States Letters Patent No. 2,001,840, issued July 9, 1935, to spencer B. Terry, and consequently need not be described here in detail.
Thickness and temper of the strip are obtained by the use of. a second gauge III, which is generally similar to gauge with reference to general design, but in addition to registering variations in thickness simultaneously registers variations in strip hardness or temper also. The contact roll I2 of gauge III is providedwith adiustins means to adjust the opening between rollers I2 and I3 for specific strip thickness while roll I3 is equipped with means for compressing the strip beyond its elasticlimit to determine hardness.
Such means comprise screw 2I,'cup 22, and spring.
23. By manually adjusting the screw 2I upwardly, movement is imparted to shank 24 and coacting roll I3. A collar 26, which is integral with shank 24, functions as a stop to prevent,
overtravel of the latter and resultant damage to armature 26.
As will be apparent from the construction of the gauge III, roll I2 remains at all times in a vertically fixed position, as determined by the adjustment of the manual adjusting means it, while roll I3 is capable of relative approaching and separating movement with respect to roll I 2 by reason of the fact that roll I3 is supported in the shank 24, which is slidably contained in the gauge housing. The shank 24 is urged resiliently upwardly by spring 23 in response to manual tuming of the screw 2i, thus establishing the approaching movement of roller I3 to roller I2. The resiliency of spring 23, when properly adiusted, permits controlled downward movement of shank 24 and separation of the rollers I2 and I3 in response to variations of strip thickness and hardness. Corresponding movements of shank 24 are transmitted to the armature 26 by guides 21 and 28 (see Figure 3), which guides are integral with the shank 24 and maintain intimate contact with armature 26, the armature 26 being attached to the gauge housing by a flexible support 38.
The circuits shown in Figure 1 are of generally standard construction, those employed for the gauges 5- and, I0 being duplicates and reading directly on United States Letters Patent No. 1,640,464, dated August 30, 1927, and issued to Alfred V. Mershon.
To avoid needless repetition, the following dethe duplicate circuits for gauges 6 and II) will be confined to the circuit of gauge It, in which the incoming voltage from power line 33 is regulated to an even value by voltage regulator 3i before being fed into the gauge circuit. One
side of the power line is connected at 39 to pritransformer 33, and regulator 3i is connected between the opposite side of the power line and the opposite terminal 49 of the winding of-the transformer 33. As a pri result of'the combination described, the voltage available for secondary terminals 44 and 46 is stepped down to. within safe operating limits, and
' in addition is maintained at the even value necessary for eiiicient functioning of the gauge circuit.
The secondary terminal 44 of the transformer 33 is commonly connected at 4| to windings 42 and 43 of a cored inductance 32, and the adjusting arm 46 of potentiometer 34 and secondary terminal 45 of transformer 33 is commonly connected at 41 to respective windings of oppositely disposed electromagnets 36 and 31 positioned on each side of the gauge-armature 26 of gauge I6. The discharging terminals 48 and 49 of inductance 32 are connected respectively to the other terminals 50 and SI of electromagnets 31 and 36, and across potentiometer 34 and rectifier I6 at terminals 52 and 53 on the latter. Thickness meter 29 is connected across the output terminals 64 and 65 of rectifier I6, which converts the alternating current input into direct current output.
The above-described circuits and parts described above are duplicated in the circuit of gauge 5.
In the circuit described above, induced currents are set up in the different branches including windings around electromagnets 36 and 31 within the gauge housing. The intensities of the induced currents in the two branches of the circuit are influenced by the varying distances of armature 26 from the two oppositely positioned magnets 36 and 31, these variations of armature distances being caused by movements of shank 24 in response to variations of strip material being gauged. The variations in current in the two branches connected to terminals 62 and 63 of rectifier I6 function to deflect the pointer of thickness meter 29 connected across the output terminals of the rectifier I6. The potentiometer 34 is used to adjust inductance of the circuit during setting operation or the gauge in order to cause the pointer of meter 29 to register zero.
Temper of the metal being gauged is indicated by a microammeter I1, the two lead wires 51 and 56 of which are connected to output terminals 54 of rectifiers I5 and I6, and the tie-in wire 69 connects the opposite output terminals together. It will be seen from Figurel that the meter I1 and'the rectifiers l5 and I6 are connected in series, so that any difference in output from rectifiers I5 and I6 will be indicated by a corresponding movement of the pointer of meter I1. Such ing gauged.
In operating .the system of the present invention, it is necessary first to set the gauges 6 and III. In the case of gauge 5, the procedure is outlined thoroughly .in the aforementioned Terry patent, and needs no further description here. However, it is to be remembered that the gauge 5 measures only variations in strip thickness which are introduced into the circuit of rectifier I6 in the form of induced currents.
In the Terry patent, it is to be understood that the desired setting of the gauge .5 regarding the exact thickness or the material to be gauged is accomplished by the use of a gauge block which is representative of the thickness. After this portion of the setting-up operation is performed, a standard specimen I4 0! the exact thickness of 'the material to be gauged is inserted betw een rollers 1, and the pointer of meter 8 should indicate zero. Specimen H is left in place during the setting of gauge l0.
To set gauge i0, roller I2 is retracted by operating the screw 20, and the screw 2! is backed out, thus relieving any compressive force against shank 24. The gauge shoe 56 of prescribed thickness is inserted into the position shown, and causes shank 24 to assume a position whereby the coacting guides 21 and 28 will cause the free end of armature 26 to attain a position exactly midway between the poles of the electromagnets 38 and 31. Under the conditions outlined, the pointer 01 meter 29 should register zero, but if it does not, the desired register may be obtained by moving arm 46 of potentiometer 34, which controls induced current in the circuit between cored inductance 32 and ' electromagnets 36 and 31.
The screw 2! is now adjusted to a point just short of causing upward movement of shank 26, with consequent unbalancing of the induction circuits and movement of the pointer of meter 29 from the zero register previously attained. The gauge block then is removed and a second standard specimen it, similar to the one still in gauge 5, is placed between rollers I2 and I3. This latter specimen, in addition to being in exact duplication of the thickness required, must also possess a hardness value required in the finished metallic strip that is to be rolled. The roller I2 is now adjusted by screw 20 until it contacts the surface of the specimen l4, and care must be exercised in making this adjustment so that the separation of the rollers l2 and I3 will be equiva- Is it only to the thickness of the specimen It. Any overadjustment can readily be detected by movement of the pointer of meter 29 from zero register.
Having set the gauges as described above, it may be saidthat the circuits thereof are electrically balanced with respect to their output which represents exact thicknessvalue of standard specimens It. In practicing the method of the present invention, it is proposed to utilize one of the gauges to measure hardness of the strip in addition to thickness, and to accomplish this, gauge ill will be purposely unbalanced and caused to indicate combined values of hardness (H) and thickness (T) which are in excess of the single value (T) as indicated by the other gauge. By
matching the combinedvalues H and T of one circuit against the singlevalue T of the other in a third circuit, it is practical to subtract the smaller from the greater, and obtain the difference, which is H, or hardness.
Continuing the setting of gauge ill to secure indicated in the manner previously described, on meter i7.
Movement of the pointer of the meter i'l can be'read directly on the graduations, which in the present case conveniently correspond to'those of the Rockwell scale for hardness, and when the pointer registers the established known value of standard specimen I, no further adjustment is required.
The specimens It now are removed from the respective gauges andthe latter are positioned over the strip edge in the desired location, as indicated in Figure 2. As the moving strip passes between the opposed rollers of the two gauges, the gauge will continuously measure variations in strip thickness as'represented in the value of its circuit, while gaugelil measures combined variations in thickness and hardness as represented in the value of its circuit and the difference in values of the measurements of the two gauges will register continuously on meter I! as hardness, or temper.
If metallic strip were commercially produced with no variations in thickness, it would be pos- -sible to measure hardness continuously by using only gauge i0 and meter 29 of the present invention, in which event lead 59 would be removed and lead 58 of meter I! would be con-'- nected either to terminals 53 or 55 of the rectifier i6. However, since it is still impracticable to produce commercially metallic strip without variations in thickness, it is found to be necessary to include the second gauge to measure thickness variations only Oif the moving strip and use the same for a reference, as described above.
In Figure 2 there are shown the gauges of Figure 1 in position on a moving strip M, for taking the measurements of thickness and temper, following the setting of the gauges, as described above. Only enough of the wiring diagram of Figure 1 is included in Figure 2 to show the rethe additional hardness value H, screw 2| is addusted further in order to overcome resistance of spring 23 and impart upward movement to shank 24, and as a result, upper andlower surface indentations of micro-metric proportion will be imparted to specimen H by rollers I2 and i3. Movement of the shank 28 is reflected in correspondingly magnified movement of the free end of armature 26, displacing the latter with respect to the midway or balanced position between magnets 36 and 31 and therefore unbalancing the gauge circuit and altering the value of the output from rectifier i6. Meter 29 responds by indicating the new value of the circuit which, in effect; is actually a measure of hardness and thickness or H and T, as above described. Since the output of rectifier it has been increased in value over that of rectifier IS, the difference will be lationship between the parts of the system, it being understood that the complete wiring diagram is as shown in Figure 1.
It will be seen from Figure 2 that in order to permit access to the interior of the housing of gauge Iii for assembling the parts thereof, the lower portion of the housing is closed on one side by a face plate 60 which is held in position bymeans of machine screws 62 which pass through holes provided therefor in the face plate, which holes register with similar internally threaded holes in the housing. Also for enabling connection of the leads to magnets 36 and 31,-the rear of the housing is provided with a threaded plug 65 having holes therethrough for the reception of insulating bushings 66 through which the leads for the magnets pass. The face plate 60 is a casting having the shape as shown, and is provided with an interior lug 64 having a groove therein for receiving the support 38 for armature 26. The support 38 has suflicient rigidity to maintain the armature 26 in adjusted position, but sufliciently flexible to bend responsively to separating movements between rollers i2 and I3 from their set position.
It will be understood that the invention contemplates variations in'detail in the above-described apparatus without departing from the substance and spirit of the invention; and it will beunderstood that it is intended and desired to embrace within the invention such modification and changes as-may be necessary to adapt it to varying conditions and cases within the scope of the following claims.
v ing temper or hardness of the strip.
2. Apparatus for continuously measuring gauge and temper of metallic strip, which comprises a pair of micrometer gauges one or which gauges is adapted to measure thickness of the strip, the second of the gauges being adapted to" measure thickness and hardness of the strip, a first electrical circuit for the thickness-measuring gauge, a second circuit for the second gauge, the circuit for the thickness measuring gauge being adapted to deliver current of a value representative of strip thickness, the second circuit being adapted to deliver current representing both thickness and hardness of the strip, a third circuit connected in series with the said first andsecond circuits adapted to match current outputs of the first and second circuits, and means in the third circuit for measuring differences in the current outputs of the first and second circuits, the said difl'erences in current outputs representing hardness of the strip.
3. Apparatus for continuously measuring gauge and temper of metallic strip, which comprises a pair of micrometer gauges, one of which gauges is adapted to measure thickness of the strip, the second of the gauges being adapted to measure thickness and hardness of the strip,. instrumentaiities connected to the second of said gauges for converting thickness and hardness of the strip into electrical current of a value corresponding to the thickness and hardness of the strip, instrumentalities connected to the first of said gauges for converting thickness of .the strip into electrical current of a value corre sponding to the thickness of the strip, and electrical means connected to both of said instrumentalities for determining difference in values of the said currents, the said'difierence in current values representing hardness of the strip.
4. Apparatus for continuously measuring gauge and temper of metallic strip, which comprises a pair of micrometer gauges, one of which gauges is adapted to measure thickness of the strip. the second of which gauges being adapted to measure thickness and hardness of the strip, an electrical circuit for the strip-thickness gauge adapted to convert thickness of the strip into an electrical current of a value corresponding to the thickness of the strip, a second circuit for the second gauge adapted to convert thickness and hardness of the stripinto electrical current of a value corresponding to the thickness and hardness of the strip, a third circuit connected to the thickness measuring circuit and to the said second circuit, and means in the said third circuit operable responsively. to diiferences in current output of the thickness-measuring circuit and the said second circuit for indicating hardness of the strip.
5. Apparatus for continuously measuring gauge and temper of continuously moving metallic strip, which comprises a pair of micrometer gauges, one c! which gauges is adapted to measure thickness or the strip, the second of which gauges is adapted to measure thickness and hardness of the strip, an electrical circuit for the strip-thickness gauge, a second electrical circuit for the second gauge. each of the said circuits having two branches, rectifying means in each of the said circuits, each of the rectifying means having a pair of input terminals and a pair of output terminals, the two branches or each of the said circuits being connected to the input terminals of the respective rectifying means, instrumentalities for inducing alternating currents in both oi! the said circuits, the induced current in the circuit for the thickness-measuring gauge beingoi a value corresponding to the thickness of the strip, the induced current in the second circuit being of a value corresponding to the thickness and hardness oi! the strip, means for initially balancing the currents in both circuits.
and a third circuit connected in series to the output terminals of the rectifying means and ineluding a meter graduated in hardness values operable responsively to difierences in current input to the rectifiers from the strip thicknessmeasuring circuit and the said second circuit.
6. Apparatus for continuously measuring gauge and temper of continuously moving metallic strip, which comprises, in combination, a pair of micrometer gauges one of which gauges is adapted to measure thickness of the strip, the second of which gauges is adapted to measure thickness and hardness-of the strip, an electrical circuit for the strip thickness gauge, asecond electrical circuit for the second gauge, each of the said circuits having two branches, rectifying means in I each of the said circuits, each 01 the rectifying means having a pair of input terminals and a pair of output terminals, the two branches ofeach of the said circuits being connected to the input terminals of the respective rectifying means, ing currents in both of the said circuits, the induced current in the circuit for the thicknessmeasuring gauge being of a value corresponding to the thickness of the strip, the induced current in the second circuit being of a value corresponding to the thickness, and hardness of the strip, means forinitially balancing the currents in both circuits responsively to a setting of the gauges on standard specimens of strip, adjustable mechanism in the second gauge actuable responsively to variations in thickness and hardness of the strip being measured to vary the current in the second circuit in amounts corresponding to variations in the strip, and a third circuit connected in series to the output terminals of the said rectifying means and including a meter graduated in hardness values operable responsively to difierences in current inputs to the rectifiers from the strip thickness-measuring circuit and the said second circuit.
' 7. Apparatus for continuously measuring gauge and temper of continuously moving metallic strip, which comprises, in combination, a pair of micrometer gauges, one of which gauges is adapted to measure thickness of the strip, the second of which gauges is adapted to measure thickness and hardness of the strip, on electrical circuit for the strip thickness-measuring gauge, a second electrical circuit for the second gauge, each of the said circuits having two branches, rectifying means in each of the said circuits, each of the rectifying means having a pair of input terminals and a pair of output terminals, the two instrumentalities for inducing altemat-j ness of the strip,
, sides thereof, one
branches of each of thesaid circuits being con- 4 nected to the input terminals of therespective ness measuring gauge being of a value correspending to the thickness of the strip, the induced current in the second circuit being of a value corresponding to the thickness and hardmeans for initially balancing the currents in both circuits responsively to a setting of the gauges on standard specimen of the strip, the second gauge comprising a pair of rolls adapted to engage the strip on opposite of the said pair of rolls being fixedly mounted relative to the strip, resiliently mounted mechanismacting on the other roll of the pair to continuously urge the said roll against the strip with a predetermined force while enabling the roll to yield responsively to variations in thickness and hardness 'of the strip, oppositely spaced electromagnets in the second circuit. a resiliently mounted armature positioned between the magnets and movable in the second circuit in 10' relatively thereto in response to movement of the said yieldable roll, thereby varying the current amounts corresponding to variations in'the strip, and a third circuit connected in series to the output terminals of the said rectifying means and including a milliammeter graduated in hardness values operable responsively to difierences in current inputs to the rectiflers from the strip thickness-measuring circuit and the said second circuit.
- CHARLES M. OHARA.
The following references are of record inthe file of this'patent:
UNITED STATES PATENTS Langer et al. Feb. 5, 1946.
US619881A 1945-10-02 1945-10-02 Apparatus for continuously determining thickness and hardness of metallic strip Expired - Lifetime US2441283A (en)

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2650432A (en) * 1949-01-26 1953-09-01 Monsanto Chemicals Rolling contact extensometer
US2834202A (en) * 1955-06-27 1958-05-13 Gen Electric Apparatus for measuring hardness
US2834203A (en) * 1955-06-27 1958-05-13 Gen Electric Apparatus for measuring hardness
US3194061A (en) * 1961-07-20 1965-07-13 Beloit Corp Instrument for measuring hardness of the surface of a resilient roll
US3541842A (en) * 1968-08-15 1970-11-24 Shell Oil Co Continuous hardness tester

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1839093A (en) * 1928-06-07 1931-12-29 Inland Mfg Co Device for testing hardness of rubber
US1928457A (en) * 1929-09-12 1933-09-26 Gen Electric Electric gauge
US2007840A (en) * 1932-05-09 1935-07-09 Pratt & Whitney Co Thickness gauge
US2022040A (en) * 1929-01-26 1935-11-26 Bendix Aviat Corp Brake lining testing machine
US2281960A (en) * 1939-07-26 1942-05-05 Gulf Research Development Co Apparatus for logging bores
US2394079A (en) * 1944-05-05 1946-02-05 Westinghouse Electric Corp Strain measuring system

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1839093A (en) * 1928-06-07 1931-12-29 Inland Mfg Co Device for testing hardness of rubber
US2022040A (en) * 1929-01-26 1935-11-26 Bendix Aviat Corp Brake lining testing machine
US1928457A (en) * 1929-09-12 1933-09-26 Gen Electric Electric gauge
US2007840A (en) * 1932-05-09 1935-07-09 Pratt & Whitney Co Thickness gauge
US2281960A (en) * 1939-07-26 1942-05-05 Gulf Research Development Co Apparatus for logging bores
US2394079A (en) * 1944-05-05 1946-02-05 Westinghouse Electric Corp Strain measuring system

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2650432A (en) * 1949-01-26 1953-09-01 Monsanto Chemicals Rolling contact extensometer
US2834202A (en) * 1955-06-27 1958-05-13 Gen Electric Apparatus for measuring hardness
US2834203A (en) * 1955-06-27 1958-05-13 Gen Electric Apparatus for measuring hardness
US3194061A (en) * 1961-07-20 1965-07-13 Beloit Corp Instrument for measuring hardness of the surface of a resilient roll
US3541842A (en) * 1968-08-15 1970-11-24 Shell Oil Co Continuous hardness tester

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