US2587686A - Ore sorting system - Google Patents

Ore sorting system Download PDF

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US2587686A
US2587686A US23561A US2356148A US2587686A US 2587686 A US2587686 A US 2587686A US 23561 A US23561 A US 23561A US 2356148 A US2356148 A US 2356148A US 2587686 A US2587686 A US 2587686A
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mine rock
electrical
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rock
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Robert R Berry
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B07SEPARATING SOLIDS FROM SOLIDS; SORTING
    • B07CPOSTAL SORTING; SORTING INDIVIDUAL ARTICLES, OR BULK MATERIAL FIT TO BE SORTED PIECE-MEAL, e.g. BY PICKING
    • B07C5/00Sorting according to a characteristic or feature of the articles or material being sorted, e.g. by control effected by devices which detect or measure such characteristic or feature; Sorting by manually actuated devices, e.g. switches
    • B07C5/34Sorting according to other particular properties
    • B07C5/344Sorting according to other particular properties according to electric or electromagnetic properties

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  • the invention in general, relates to means for recovering values from mineral deposits, and more particularly relates to an improved electromechanical system affording high speed and efcaceous separation or sorting of values-bearing 5 substances from Waste materials under all conditions of mining operations.
  • the grading or sorting of mine rock has been carried out mainly either by hand sorting or by the utilization of vibratory devices combined with electrical means.
  • hand sorting it has been common practice to make use of a conveyer belt for carrying variable sizes and character of mine rock past a group of operators or soi-ters who hand pick waste material and over-sized rocks from the value-bearing material in order thus to grade the ore prior to delivery to con-centrating tables or devices. It has been found that the cost of hand sorting is so prohibitive as well as ineflicient because predicated solely on visual inspection that this method is somewhat restricted.
  • the handling and grading or sorting of mine rock by electrical means heretofore practiced has presented serious and numerous complications principally because of the heterogeneous nature of the materials being handled and also the inherent difficulties or factors encountered and normally present in mining operations, such as variations in temperature, moisture and vibration. Other inherent difficulties include installation problems under variable conditions at different mining locations or regions, and other handling techniques common to mining and milling. It may be observed that because of the above mentioned complex problems, sorting methods heretofore worked out for packaged products and articles of determinate or certain sizes and shapes are not suitable for mining, especially the sorting of the mine rock.
  • the present invention is directed to the provision of an electro-mechanical combination or system which obviates the foregoing diiiiculties and disadvantages of prior systems and methods, as well as which affords a low cost method to effect ore concentration.
  • a primary object of my invention is to provide an improved ore sorting system containing electro-mechanical means which utilizes the high frequency power factor of the mine rock or mineral materials as the bases for controlling and effecting the physical separation or sorting,
  • Another important object of the present'invention isA to provide an improved ore sorting system' ofthe indicated nature which is' additionally characterized by its simplicity, its low cost of installation and maintenance, its highly efll'caceous performance, and its flexibility or adaptability to all mining conditions however severe and abnormal.
  • a still further object of the invention is to provide an improved ore sorting system for the ready separation of ores and of the aforementioned character, which is readily adaptable to mining equipment already installed and Without material modification of such installed equipment.
  • Another important object of my invention is to provide a system of the indicated nature which increases the speed of handling ore as well as the yield of values therefrom, without restricting its effectiveness of performance.
  • Fig. l is a diagrammatic now sheet depicting a preferred embodiment of the invention.
  • Fig. 2 is an enlarged graph representing the phase shift curve of a resonant circuit, which is variable depending upon the particular materials handled and the frequency of the alternating current supplied, eXemplifying the amount of phase angle displacement between eddy currents resulting from the introduction and presence of an alternating electro-magnetic field in a given material, and the currents producing the field.
  • Fig. 3 is a diagrammatic view of the various electrical elements employed in the preferred embodiment of the invention.
  • Fig. 4v is an elevational sectional view of an electrically controlled air cylinder employed n the preferred embodiment of the invention.
  • Fig. 5 is a graph exemplifying optimum performance curves for the air cylinder depicted in Fig. 4.
  • Fig. 6 is a perspective view of a remote observer unit, ⁇ with cover removed, employed in the preferred embodiment of the invention; this view illustrating the mannerV of mounting theY coilsl of the unit.
  • Fig. '7 is a longitudinal sectional viewas well as diagrammatic view of the' electrical translongitudinal center thereof.
  • Fig. 8 is an elevational sectional View of the unit shown in Fig. '7, with arrow indicators to show air iiow in, through and out'of the unit.
  • Fig. 9 is an enlarged plan view of the overlapping coils of the observer unit depicted in Fig. 6, together with a diagrammatic showing of electrical connections for the coils.
  • Fig. 1,0 is an elevational sectional view of the unit illustrated in Fig. 6.
  • Fig. 11 is a diagrammatic view of the fluid control system.
  • the improved ore sorting system of my invention preferably comprises means for continuously moving pieces of mine rock through compound differential electrical fields which are specially balanced and created by the operation of tuned, high-frequency alternating current circuits, a differential circuit coupled to said alternating current circuits; said differential circuit operating at the same frequency as said alternating current circuits and the ⁇ voltage developed by said differential circuit varying in response to the varying electrical characteristics of different pieces of mine rock passing through said field, together with means responsive electrically to differences involtages developed by said differential circuit for mechanically separating out recurrently and at prei determined times individual pieces of mine rock lof determined electrical characteristics.
  • FIG. 1 of the annexed drawings I have shown schematically various equipment common to mining operations including a primary conveyer II for moving mine rock from ore bins and primary Crusher, not shown, to a vibratory screen I2 which effects the screening of .nes I3 into a hopper I4 without sorting.
  • a motor-driven eccentric unit I5 affords requisite "means for vibrating the screen I2, which is common practice.
  • Fig. 1 I have illustrated the electrical 'unit which creates the aforesaid fields, in block diagram and designated by the reference numeral *25,v and such unit is located beneath the upper run 26 of the conveyer I1 approximately at the As illustrated in Figs.
  • the observer unitV 25 comprises two tuned 'circuits including coils 21 and 28 which preferably are wound radially in the form of pancakes and so mounted that the axis of each coil is parallel to that of the other coil with the windings overlapping one another, for reasons to be here- .inafter explained, to effect zero electromagnetic i coupling of the coils.
  • two coils 2 and 28 of the observer unit 25 are individually coupled by means of separate transmission lines 29 and 29 to a translator unit which is shown in dotted block diagram and designated by the reference numeral 30.
  • the arrangement is such that all of the resonant circuits involved in the observer and translator units are adjusted to one and the same frequency, which is that of the high-frequency alternating current source depicted in Fig. 3 in full line block diagram and designated by the reference numeral 3l.
  • are conventional and, therefore, are not shown in detail in the drawings.
  • the translator unit 30 is comprised of two separate resonant circuits consisting of secondary coils 32 and 33, together with capacitors 34 and 35, respectively, said circuits being differentially coupled to the high-frequency source by means of primary coils 3I and 3B, It is to be noted that no common coupling exists between these resonant circuits.
  • a resistor 36 in the circuits functions to control the relative amplitudes of the circulating currents Yin the aforesaid branches of the differential circuit of the translator unit 30.
  • the components of the differential circuit are mounted in separate compartments of the translator unit and are energized individually or separately from the highfrequency source 3
  • the two resonant elements of the translator unit 3Bv are so energized that the circulating currents establish voltages in phase opposition which are fed, by means of a series of connections, to an amplier which is depicted generally in dotted block diagram at the right of Fig. 3 and designated generally by the reference numeral 40.
  • the phase relationship within the diierential circuit of the translator unit is such that no signal voltage appears at the input of the amplifier 4i).
  • the presence of a foreign object of certain electrical characteristics in the field of the observer unit 25, however, will reiiect electrically through the transmission lines 29, 29 and the differential circuit of the translator 35, such as the introduction by means of conveyer II of a succession of individual pieces or piles of mine rock 2
  • My improved system is effective with respect to both good electrical conductive material and relatively poor electrical conductive material.
  • the eddy currents which result from the presence of an alternating electro-magnetic field are in phase with the currents producing such eld, and the power factor of the rock approaches unity representing a low-loss condition so that vunder my improved system such mine rock of near unity power factor is readily sortable from other mine rock of different power factor as the rock passes through the field of the observer unit 25.
  • This operation is a function of the de-tuning effect of the circuit elements ofthe observer unit by a foreign object that has good electrical conductivity, although effective ore separation does not depend upon de-tuning.
  • the essence ofthe present invention resides in taking advantage of this high-frequency distinction between types of rock by utilizing one of the properties ofthe electrically resonant or tuned circuit; namely, that portion of the phase shift curve which lies between plus or minus 1% of the preferreol resonantv frequency.
  • I have shown the phase shift curve for a tuned circuit having a Q factor of 450 and a resonant frequency of 100,000 cycles.
  • Q factor is meant the ratio of the reactance to the high-frequency resistance of a tuned circuit (i.
  • the described technique of overlappingv the coils ifo 21 and 23 in the observer unit 25 is-designed primarily to result in zero coupling while maintaining circuit symmetry.
  • the presence of the two overlapping coils is for the purpose of stabilizing the entire differential unit with respect to temperature, vibration and external electrical influences.
  • means are provided for re-currently recording the response of the system to the electrical characteristics of individual pieces or lumps of mine rock passing through the field of the observer unit 25, and re-currently reproducing or picking up the recorded responses for controlling at predetermined times a mechanical separator whereby desired mine rock is separated out from waste or non-value mine rock.
  • These means include an endless steel belt 46 which is driven from the conveyer belt l1 by a set of self-synchronizing motors 41 and 48 which are commercially available under the trade-mark Selsyn; the steel belt 46 and the selsyn motors being schematically illustrated in the lower right of Fig. 3 of the annexed drawings, and the direction of travel of such steel belt 4S being indicated by the arrow 50.
  • the aforesaid means includes a recorder head 5! mounted above but in close proximity to the upper' run 52 of the steel belt 48 and in electrical connection with the relay 42 of the differential circuit of translator unit 30, for actuation by relay e2, and resulting in the delineation of the responses of the system to the electrical characteristics of the mine rock passing on the upper run of -conveyer belt i1 at the location of the observer unit; such delineations being upon the moving endless steel belt 45 and such electrical characteristics of certain mine rock that affect the voltage in the differential circuit of the translator unit 30 being the only responses of the system that will be relayed to the recorder head 5l for delineation on the belt 46.
  • Such recordation and pick-up or reproducing means also include a pick-up unit 53 mounted above but in close proximity to the upper run 52 of belt 45 and at a predetermined distance from the recorder head 5
  • a pick-up unit 53 mounted above but in close proximity to the upper run 52 of belt 45 and at a predetermined distance from the recorder head 5
  • both the conveyer belt i1 and the steel wire belt 46 are continuous and operated in synchronism by the self-synchronous motors 41 and 48, the recordation and reproduction of the responses of the system to the electrical characteristics of the different individual pieces or lumps of mine rock 2l, 22 and 23 is continuous and re-current while the system is in operation.
  • the pick-up or recording unit 53 functions to control and is in electrical connection with a relay 54 which, in turn, controls the operation of a separator gate 56 through a cylinder 51, the piston of which is controlled by a solenoid 58 actuated directly from relay 54.
  • the synchronous motors 41 and 48 effect the exact timing of the mechanical separation of value bearing mine rock from the waste or non-value rock.
  • the solenoid 58 is arranged with the air cylinder 5l for covering and uncovering the ports of the cylinder in which the piston 63 reciprocates as air is admitted from asource of air supply, not shown, rst to one side and then the other side of the piston.
  • the piston rod ES of piston E3 carries a pivotally mounted gate 56 on its exposed end which is adapted to swing into and out of the path of the falling mine rock that drops off the end or terminus 6l of the endless conveyer
  • a suitable multiple channel hopper 58 is arranged beneath the gate 55 to receive in its dverent channels both the waste material t9 and the separated out value-bearing mine rock iii; the latter being deflected by the gate 5S as the gate responds to the movement o the piston 5S of the air cylinder.
  • the motion of the piston 53 of the air cylinder 5'. should follow the curves depicted in Fig. 5 of the annexed drawings so that in one direction the piston should follow curve l and in the reverse direction should follow curve 2.
  • the piston 63 should slow down toward the end oi its stroke and this is accomplished either with the arrangement illustrated in Fig. 4 or the arrangement illustrated in Fig. il of the annexed drawings, and by shaping the ports 13, 14, 'i5 and 'i6 of the cylinder 5l, which are in communication with ducts lil, i9, Si! and 8
  • ports i3 and lli of the air cylinder 5l are so placed that they are closed by the piston 63 at the ends of its stroke to eect a shock absorbing action as well as controlling exhaust opening il in valve head 86.
  • a typical mine compressor arrangement including a motor
  • 31 is provided for supplying air through air inlet
  • the supplied air preferably is stored in a reservoir
  • the air cylinder ports 'l5 and 'i6 communicate with ducts 8E? and 8
  • gate 55 is operated with ⁇ the least amount of time as considerable power .ings, I have illustrated a preferred construction of cabinet 9
  • the two coils of the differential circuit conveniently are housed in formed compartments 92 of the cabinet and shielded by heavy shields 93 and 94 which, together with a base 95 all formed of material of high thermal conductivity, afford optimum mounting of the diierential circuit units.
  • the cabinet is maintained at desirable temperature by providing suitable air circulation throughout the various compartments and to this end the front and end walls of the cabinet 9
  • the direction of air flow through the compartments of the cabinet is indicated by the arrows
  • is provided with two amplitude controls, actuated by knobs
  • 06 is installed in the compartment containing the ampliers and furnishes, through a window
  • the foregoing described ore sorting system eiiects continuous storing of electrical information as to the electrical characteristics of individual pieces of mine rock as such pieces are continuously moved by the conveyer Il through an induction eld produced by the high-frequency alternating current source 3
  • phase shift curve is a straight line, which means that a frequency variation of plus or minus 1% will not disturb a circuit sensitive to .001% or 8% of 1 phase change.
  • the opposed phasing of the overlapping coils 21 and 28 renders the system impervious to outside electrical interference without the necessity oi shielding and, by the same token, there is no radiation.
  • This cancellation of inductive effect makes possible a multiple installation without interaction between units, even though Y side by siderunder the same belt as, for instance.
  • fin especial feature of the present invention resides in the recorder, reproduction and eraser combination for making impressions and erasing the same from the steel Wire itil, thus eiecting a time delay in an otherwise substantially continuous operation.
  • An ore sorting system comprising a high-frequency alternating current circuit, means coupled to said circuit for producing an induction held, a conveyer having a terminal for moving individual pieces of mine rock in single le through said induction iield to detect the electrical characteristics thereof, a tuned circuit coupled with said alternating current circuit; said tuned circuit being adapted variably to respond to variations in voltage impressed thereon as a result of electrical characteristics reflected by certain pieces of said mine rock moving through said eld, a first relay actuated by said tuned circuit, an endless steel wire, means for moving said steel wire in synchronism with the movement of said conveyer, electro-magnetic recorder means electrically connected with said rst relay and mounted in proximity to said wire for impressing and recording on said Wire signals or responses to electrical characteristics of certain mine rock reflected in said tuned circuit and said rst relay, an electro-magnet re' .der mounted adjacent to said hopper, a solenoid for governing the ports of said cylinder, a gate pivotally mounted on the piston rod of the piston

Description

March 4, 1952 R, R. BERRY 2,587,686
ORE SORTING SYSTEM Filed April 27. 1948 5 Sheets-Sheet 1 80 PHASE ANGLE March 4, 1952 R. R. BERRY 2,587,686
ORE SORTING SYSTEM Filed April 27, 1948 5 Sheets-Sheet 2 @uw @c 9K@ INVENTOR.
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ORE SORTING SYSTEM Filed April 27, 1948 5 Sheets-Sheet 5 F'jg. 6- A Iig. '7. H/GH FREQUENCY 30 souRcE o/FFERENr/AL AMPLIFIER 8 RELAY SECT/0 2A rust-[I 2A n/.Q E/
TUA/ED AMPLIFIER 0.0. MPL/F/EE ,Olm ma" ,O2 9'2 /25 A PL/T DE /03 Pfl/:sf VISUAL SENS/T/wry 00N TRoLS ADa/S TME/V; 92 /No/cA T02 60A/7201.5 9a\ l/ .95
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7- 8- zi 52255742@ RUBEN fr. @m1-y @onwaar/wry By ATTORNEY March 4, 1952 R. R. BERRY 2,587,585
ORE SORTING SYSTEM 5 Sheets-Sheet 4 Filed April 27. 1948 Ilz' J0.
m v Z8 t INVENTOR. ROBERT R HERR BY l ATTORNEY March 4, 1952 R. R. BERRY 2,587,686
ORE SORTING SYSTEM Filed April 27, 1948 5 Sheets-Sheet 5 INVENTOR. ROBE/Q7 HER/QV Patented Mar. 4, 1952 UNITED STATES PATENT GFFICE ORE SORTING SYSTEM Robert R. Berry, San Francisco, Calif.
Application April 27, 1948, Serial No. 23,561
l Claim. l The invention, in general, relates to means for recovering values from mineral deposits, and more particularly relates to an improved electromechanical system affording high speed and efcaceous separation or sorting of values-bearing 5 substances from Waste materials under all conditions of mining operations.
Heretofore, the grading or sorting of mine rock has been carried out mainly either by hand sorting or by the utilization of vibratory devices combined with electrical means. In hand sorting, it has been common practice to make use of a conveyer belt for carrying variable sizes and character of mine rock past a group of operators or soi-ters who hand pick waste material and over-sized rocks from the value-bearing material in order thus to grade the ore prior to delivery to con-centrating tables or devices. It has been found that the cost of hand sorting is so prohibitive as well as ineflicient because predicated solely on visual inspection that this method is somewhat restricted. The handling and grading or sorting of mine rock by electrical means heretofore practiced has presented serious and numerous complications principally because of the heterogeneous nature of the materials being handled and also the inherent difficulties or factors encountered and normally present in mining operations, such as variations in temperature, moisture and vibration. Other inherent difficulties include installation problems under variable conditions at different mining locations or regions, and other handling techniques common to mining and milling. It may be observed that because of the above mentioned complex problems, sorting methods heretofore worked out for packaged products and articles of determinate or certain sizes and shapes are not suitable for mining, especially the sorting of the mine rock. The present invention is directed to the provision of an electro-mechanical combination or system which obviates the foregoing diiiiculties and disadvantages of prior systems and methods, as well as which affords a low cost method to effect ore concentration.
A primary object of my invention is to provide an improved ore sorting system containing electro-mechanical means which utilizes the high frequency power factor of the mine rock or mineral materials as the bases for controlling and effecting the physical separation or sorting,
Another important object of the present'invention isA to provide an improved ore sorting system' ofthe indicated nature which is' additionally characterized by its simplicity, its low cost of installation and maintenance, its highly efll'caceous performance, and its flexibility or adaptability to all mining conditions however severe and abnormal.
A still further object of the invention is to provide an improved ore sorting system for the ready separation of ores and of the aforementioned character, which is readily adaptable to mining equipment already installed and Without material modification of such installed equipment. l
Another important object of my invention is to provide a system of the indicated nature which increases the speed of handling ore as well as the yield of values therefrom, without restricting its effectiveness of performance.
Other objects of the invention, together with some of the advantageous features thereof, will appear from the following description 0f a preferred embodiment of the invention which is illustrated in the accompanying drawings. It is to be understood that I am not to be limited to the precise embodiment shown, nor to the precise arrangement of the various parts, as my invention, as defined in the appended claim, can be embodied in a plurality and variety of forms.
Referring to the drawings:
Fig. l is a diagrammatic now sheet depicting a preferred embodiment of the invention.
Fig. 2 is an enlarged graph representing the phase shift curve of a resonant circuit, which is variable depending upon the particular materials handled and the frequency of the alternating current supplied, eXemplifying the amount of phase angle displacement between eddy currents resulting from the introduction and presence of an alternating electro-magnetic field in a given material, and the currents producing the field.
Fig. 3 is a diagrammatic view of the various electrical elements employed in the preferred embodiment of the invention.
Fig. 4v is an elevational sectional view of an electrically controlled air cylinder employed n the preferred embodiment of the invention.
Fig. 5 is a graph exemplifying optimum performance curves for the air cylinder depicted in Fig. 4.
Fig. 6 is a perspective view of a remote observer unit,` with cover removed, employed in the preferred embodiment of the invention; this view illustrating the mannerV of mounting theY coilsl of the unit.
Fig. '7 is a longitudinal sectional viewas well as diagrammatic view of the' electrical translongitudinal center thereof.
3 lator unit employed in a preferred embodiment of the invention.
Fig. 8 is an elevational sectional View of the unit shown in Fig. '7, with arrow indicators to show air iiow in, through and out'of the unit.
Fig. 9 is an enlarged plan view of the overlapping coils of the observer unit depicted in Fig. 6, together with a diagrammatic showing of electrical connections for the coils.
Fig. 1,0 is an elevational sectional view of the unit illustrated in Fig. 6.
Fig. 11 is a diagrammatic view of the fluid control system.
In its preferred form, the improved ore sorting system of my invention preferably comprises means for continuously moving pieces of mine rock through compound differential electrical fields which are specially balanced and created by the operation of tuned, high-frequency alternating current circuits, a differential circuit coupled to said alternating current circuits; said differential circuit operating at the same frequency as said alternating current circuits and the `voltage developed by said differential circuit varying in response to the varying electrical characteristics of different pieces of mine rock passing through said field, together with means responsive electrically to differences involtages developed by said differential circuit for mechanically separating out recurrently and at prei determined times individual pieces of mine rock lof determined electrical characteristics.
At the left side of Fig. 1 of the annexed drawings I have shown schematically various equipment common to mining operations including a primary conveyer II for moving mine rock from ore bins and primary Crusher, not shown, to a vibratory screen I2 which effects the screening of .nes I3 into a hopper I4 without sorting. A motor-driven eccentric unit I5 affords requisite "means for vibrating the screen I2, which is common practice. Mine rock of approximately 11/2 inches in cross-section, and greater, passes over the vibratory screen I2 and into a hopper I6 for delivery to a second conveyer I'I, preferably a belt of the endless type; the outlet of the hopper I6 ,leading to a mechanism, indicated by the dotted block and reference numeral I8, designed to cause the mine rock to be deposited onto the belt I'I yeither in single pieces approximately 6 inches in cross-section or in six inch piles of smaller 11/2 inch cross-section, all in single file, and to be moved in such arrangement thereon, as shown.
vIn accordance with my invention, the individual pieces or piles of mine rock, designated by the reference numerals 2I, 22 and 23, generally,
vare caused to pass through compound differential electrical elds created by the operation of Ytuned, high-frequency alternating current cir- I,'cuits. In Fig. 1 I have illustrated the electrical 'unit which creates the aforesaid fields, in block diagram and designated by the reference numeral *25,v and such unit is located beneath the upper run 26 of the conveyer I1 approximately at the As illustrated in Figs. 3, 6, 9 and 10 of the accompanying drawings, the observer unitV 25 comprises two tuned 'circuits including coils 21 and 28 which preferably are wound radially in the form of pancakes and so mounted that the axis of each coil is parallel to that of the other coil with the windings overlapping one another, for reasons to be here- .inafter explained, to effect zero electromagnetic i coupling of the coils.
As particularly illustrated in Figs. 1 and 3, the
two coils 2 and 28 of the observer unit 25 are individually coupled by means of separate transmission lines 29 and 29 to a translator unit which is shown in dotted block diagram and designated by the reference numeral 30. The arrangement is such that all of the resonant circuits involved in the observer and translator units are adjusted to one and the same frequency, which is that of the high-frequency alternating current source depicted in Fig. 3 in full line block diagram and designated by the reference numeral 3l. The elements of the high-frequency alternating current source 3| are conventional and, therefore, are not shown in detail in the drawings.
With particular reference to the translator unit 30, it is to be observed that it is comprised of two separate resonant circuits consisting of secondary coils 32 and 33, together with capacitors 34 and 35, respectively, said circuits being differentially coupled to the high-frequency source by means of primary coils 3I and 3B, It is to be noted that no common coupling exists between these resonant circuits. i A resistor 36 in the circuits functions to control the relative amplitudes of the circulating currents Yin the aforesaid branches of the differential circuit of the translator unit 30. Preferably, the components of the differential circuit are mounted in separate compartments of the translator unit and are energized individually or separately from the highfrequency source 3|, as illustrated in Fig. 3 of the drawings.
The two resonant elements of the translator unit 3Bv are so energized that the circulating currents establish voltages in phase opposition which are fed, by means of a series of connections, to an amplier which is depicted generally in dotted block diagram at the right of Fig. 3 and designated generally by the reference numeral 40.
Under operating conditions, without having any foreign object introduced into the field of the observer unit 25, the phase relationship within the diierential circuit of the translator unit is such that no signal voltage appears at the input of the amplifier 4i). The presence of a foreign object of certain electrical characteristics in the field of the observer unit 25, however, will reiiect electrically through the transmission lines 29, 29 and the differential circuit of the translator 35, such as the introduction by means of conveyer II of a succession of individual pieces or piles of mine rock 2|, 22, and 23 continuously through the eld created by the high-frequency alternating current and the elements of the observer unit 25.
My improved system is effective with respect to both good electrical conductive material and relatively poor electrical conductive material. In the case of mine rock of good electrical conductivity, the eddy currents which result from the presence of an alternating electro-magnetic field are in phase with the currents producing such eld, and the power factor of the rock approaches unity representing a low-loss condition so that vunder my improved system such mine rock of near unity power factor is readily sortable from other mine rock of different power factor as the rock passes through the field of the observer unit 25. This operation is a function of the de-tuning effect of the circuit elements ofthe observer unit by a foreign object that has good electrical conductivity, although effective ore separation does not depend upon de-tuning. 'On the other hand, in the case of mine rock of relatively poor electrical conductivity, the eddy currents resulting from passing of such type of mine rock through the field of the observer unit are out of phase with the currents producing such field and the power factor of the rock is less than unity, representing a condition of some loss. In short, mine rock materials having certain assemblages of elements will support eddy currents having characteristic power factors in specific relationship to the produced field of the observer unit 25 through which the mine rock is passed. It is obvious, therefore, that the magnitude of the loss due to the power factor depends upon the nature of the rock material and the frequency of the alternating current employed to produce the initial field. The essence ofthe present invention resides in taking advantage of this high-frequency distinction between types of rock by utilizing one of the properties ofthe electrically resonant or tuned circuit; namely, that portion of the phase shift curve which lies between plus or minus 1% of the preferreol resonantv frequency. Thus, it is possible to distinguish and effect mechanical separation of rocks because of their difference in electrical conductivity. In Fig. 2 of the annexed drawings, I have shown the phase shift curve for a tuned circuit having a Q factor of 450 and a resonant frequency of 100,000 cycles. By Q factor is meant the ratio of the reactance to the high-frequency resistance of a tuned circuit (i. e., ratio of energy stored to energy dissipated per cycle) and such factor, therefore, is a ligure of merit of a circuit; the high frequency resistance being the sum total of all the losses inherent in the tuned circuit plus the losses reflected from a foreign object, such as mine rock coming through the iield of the inductive component. Hence, if an object of high power factor comes within the field of the observer unit 25, the Q factor is lowered and the slope of the phase shift curve is changed; a result of the increase in circuit. losses produced by the introduction of such object, and the change in Q factor is transmitted as a change in load through transmission lines 29 and 29 to the other circuits above described which are adjusted to the same resonant frequency as that of the observer unit 25. It may also be noted that the introduction of loss into the differential circuit, or change in load through the aforesaid transmission lines, by the presence of mine rock of low electrical conductivity in the observer unit eld, not only brings about a variable change in the slope of the phase shift curve but a variable change in the voltage developed by the differential circuit. This difference in voltage is amplified sufficiently, by means of conventional amplier means, illustrated at the lower left of Fig. 3 of the drawings and designated generally by the reference numeral 4|, to cause the operation of a relay 42 in the translator circuit 3D.
In order to preserve the function of the differential circuit, no common coupling can exist between the resonant elements of the differential circuit. Insofar as the coils 21 and 23 of the observer unit 25 are coupled individually to their separate resonant elements in the differential circuit, it can be seen that any coupling between the coils of the observer unit 25 would be reflected as coupling between the resonant elements, thus destroying the initial premise. Therefore, it becomes necessary to adjust the coils of the observer unit 25 so that zero coupling results between the two coils 21 and 28.
The described technique of overlappingv the coils ifo 21 and 23 in the observer unit 25 is-designed primarily to result in zero coupling while maintaining circuit symmetry. In addition, the presence of the two overlapping coils is for the purpose of stabilizing the entire differential unit with respect to temperature, vibration and external electrical influences.
In accordance with my present invention, means are provided for re-currently recording the response of the system to the electrical characteristics of individual pieces or lumps of mine rock passing through the field of the observer unit 25, and re-currently reproducing or picking up the recorded responses for controlling at predetermined times a mechanical separator whereby desired mine rock is separated out from waste or non-value mine rock. These means include an endless steel belt 46 which is driven from the conveyer belt l1 by a set of self-synchronizing motors 41 and 48 which are commercially available under the trade-mark Selsyn; the steel belt 46 and the selsyn motors being schematically illustrated in the lower right of Fig. 3 of the annexed drawings, and the direction of travel of such steel belt 4S being indicated by the arrow 50. In addition to the foregoing, the aforesaid means includes a recorder head 5! mounted above but in close proximity to the upper' run 52 of the steel belt 48 and in electrical connection with the relay 42 of the differential circuit of translator unit 30, for actuation by relay e2, and resulting in the delineation of the responses of the system to the electrical characteristics of the mine rock passing on the upper run of -conveyer belt i1 at the location of the observer unit; such delineations being upon the moving endless steel belt 45 and such electrical characteristics of certain mine rock that affect the voltage in the differential circuit of the translator unit 30 being the only responses of the system that will be relayed to the recorder head 5l for delineation on the belt 46. Such recordation and pick-up or reproducing means also include a pick-up unit 53 mounted above but in close proximity to the upper run 52 of belt 45 and at a predetermined distance from the recorder head 5|, as illustrated in Fig. 3 of the drawings, thus affording a lapse of time between the time of recordation of the response of each individual piece or lump of mine rock having certain power factor characteristics to effect the aforesaid voltage variation, and the time" of reproducing or picking up the response as delineated on the steel wire belt 4E. It is to be understood that since both the conveyer belt i1 and the steel wire belt 46 are continuous and operated in synchronism by the self- synchronous motors 41 and 48, the recordation and reproduction of the responses of the system to the electrical characteristics of the different individual pieces or lumps of mine rock 2l, 22 and 23 is continuous and re-current while the system is in operation. The pick-up or recording unit 53 functions to control and is in electrical connection with a relay 54 which, in turn, controls the operation of a separator gate 56 through a cylinder 51, the piston of which is controlled by a solenoid 58 actuated directly from relay 54. The synchronous motors 41 and 48 effect the exact timing of the mechanical separation of value bearing mine rock from the waste or non-value rock. Conventional amplier means, not shown, arev interposed in the circuit containing the pick-up or reproducing unit 53 and the relay 54 foreffective operation of the solenoid 58 through the relay 54. In order that the recorder unit and the pick-up or reproducing head 53 be eiective for their recurrent operations, I provide a magnetic eraser 6i for clearing any electrical response character delineations applied to the steel wire Il@ on each complete run of the belt 636, and prior to the time the recorder unit 5| operates.
As particularly illustrated in Figs. l and 4 of the accompanying drawings, the solenoid 58 is arranged with the air cylinder 5l for covering and uncovering the ports of the cylinder in which the piston 63 reciprocates as air is admitted from asource of air supply, not shown, rst to one side and then the other side of the piston. The piston rod ES of piston E3 carries a pivotally mounted gate 56 on its exposed end which is adapted to swing into and out of the path of the falling mine rock that drops off the end or terminus 6l of the endless conveyer A suitable multiple channel hopper 58 is arranged beneath the gate 55 to receive in its diilerent channels both the waste material t9 and the separated out value-bearing mine rock iii; the latter being deflected by the gate 5S as the gate responds to the movement o the piston 5S of the air cylinder.
For optimum operation and minimum wear, the motion of the piston 53 of the air cylinder 5'. should follow the curves depicted in Fig. 5 of the annexed drawings so that in one direction the piston should follow curve l and in the reverse direction should follow curve 2. In other words, the piston 63 should slow down toward the end oi its stroke and this is accomplished either with the arrangement illustrated in Fig. 4 or the arrangement illustrated in Fig. il of the annexed drawings, and by shaping the ports 13, 14, 'i5 and 'i6 of the cylinder 5l, which are in communication with ducts lil, i9, Si! and 8|, respectively, as indicated in Fig. fl, leading from ports 82, 83, Sli and 85, respectively, in valve head 8%. It may be added that ports i3 and lli of the air cylinder 5l are so placed that they are closed by the piston 63 at the ends of its stroke to eect a shock absorbing action as well as controlling exhaust opening il in valve head 86. In the arrangement in Fig. ll of the drawings there are illustrated a typical mine compressor arrangement including a motor |26 with belt drive 21 to the ily wheel |28 of a compressor unit |29. In this arrangement, an air head |31 is provided for supplying air through air inlet |32 controlled by check valve |33 and the supply Yof air from the compressor is delivered from air v yhead |3| to an outlet conduit |35 which also is- .controlled by a check valve |34.
The supplied air preferably is stored in a reservoir |36 from which it is delivered through a conduit |31 to a T-coupling ISS for diverting the air iiow through conduits and 45,2 to the ports i3 and 1t, respectively, of the air cylinder 5l within which is reciprocated the piston Q3. As in the prior described arrangement, the air cylinder ports 'l5 and 'i6 communicate with ducts 8E? and 8|, respectively, leading to a valve head 86a which is controlled by a slider valve Stb. By the foregoing arrangements gate 55 is operated with `the least amount of time as considerable power .ings, I have illustrated a preferred construction of cabinet 9| for housing not only the equipment and circuits of the high-frequency alternating current source 3| but also the units of the differential circuit constituting the translator unit 30, together with the tuned amplier circuit 49, the D. C. amplifier il and the relay 42 of the translator unit. The two coils of the differential circuit conveniently are housed in formed compartments 92 of the cabinet and shielded by heavy shields 93 and 94 which, together with a base 95 all formed of material of high thermal conductivity, afford optimum mounting of the diierential circuit units. The cabinet is maintained at desirable temperature by providing suitable air circulation throughout the various compartments and to this end the front and end walls of the cabinet 9| are formed with- air inlets 96 and 91, and air outlets 93 and 99, respectively. The direction of air flow through the compartments of the cabinet is indicated by the arrows |99. The high-frequency alternating current source 3| is provided with two amplitude controls, actuated by knobs |0| and i on theexterior front of the cabinet; the phase adjustment of the translator unit and cir- Vcuits is controlled through a knob |03 extending at the front of the cabinet, and the amplifiers are controlled for sensitivity by hand-knobs ll and |95 also extending at the front of the cabinet. A suitable meter |06 is installed in the compartment containing the ampliers and furnishes, through a window |0'i at the front of the cabinet, visual indication of the status of such amplifiers at a given moment. In Figs. 6 and l0 of the annexed drawings, I have shown preferred mounting of the over-lapping coils 2l and 2S of the observer unit, such mounting being effected by two overlapping plates |99 and H9 supported on standards lli.
The foregoing described ore sorting system eiiects continuous storing of electrical information as to the electrical characteristics of individual pieces of mine rock as such pieces are continuously moved by the conveyer Il through an induction eld produced by the high-frequency alternating current source 3| through observer unit 25 located beneath the upper run of the conveyer at a predetermined point, and such stored information is repeated at a delayed and/or proper time through the recorder unit '5| and reproducer or pick-up unit 53'operating on the endless steel wire 46 and thus eiiecting the mechanical separation of value bearing mine rock from the waste or non-value bearing material at a point remote from the observer unit 25. A symmetrical electrical system is effectively maintained by the use of the two over-lapping coils 2l and 28 of the observer unit, and the separate transmission lines 29 and 29 leading to the'differential circuit of the translator unit 39, thus preventing temperature variations and frequency drift from disturbing the balance of the system. From Fig. 2 of the drawings, it can be seen that within the region of plus or minus 1% of the preferred resonant frequency, the phase shift curve is a straight line, which means that a frequency variation of plus or minus 1% will not disturb a circuit sensitive to .001% or 8% of 1 phase change. Also, the opposed phasing of the overlapping coils 21 and 28 renders the system impervious to outside electrical interference without the necessity oi shielding and, by the same token, there is no radiation. This cancellation of inductive effect makes possible a multiple installation without interaction between units, even though Y side by siderunder the same belt as, for instance.
the observer unit 25 and the synchronous motor 5S under the upper run of the conveyer belt ll. fin especial feature of the present invention resides in the recorder, reproduction and eraser combination for making impressions and erasing the same from the steel Wire itil, thus eiecting a time delay in an otherwise substantially continuous operation. As a result, there is accomplished high speed separation of value bearing mine rock from valueless mine rock (when such rock is associated with diiicerences in power factor), all made possible by the combination of the foregoing time delay mechanism together with power operation of the separator gate 55 through controlled air cylinder and pneumatic damping thereof.
1t is to be understood that the appended claim is to be accorded a range of equivalents comnsnrate in scope with the advance made over the prior art.
1 claim:
An ore sorting system comprising a high-frequency alternating current circuit, means coupled to said circuit for producing an induction held, a conveyer having a terminal for moving individual pieces of mine rock in single le through said induction iield to detect the electrical characteristics thereof, a tuned circuit coupled with said alternating current circuit; said tuned circuit being adapted variably to respond to variations in voltage impressed thereon as a result of electrical characteristics reflected by certain pieces of said mine rock moving through said eld, a first relay actuated by said tuned circuit, an endless steel wire, means for moving said steel wire in synchronism with the movement of said conveyer, electro-magnetic recorder means electrically connected with said rst relay and mounted in proximity to said wire for impressing and recording on said Wire signals or responses to electrical characteristics of certain mine rock reflected in said tuned circuit and said rst relay, an electro-magnet re' .der mounted adjacent to said hopper, a solenoid for governing the ports of said cylinder, a gate pivotally mounted on the piston rod of the piston of said cylinder; said gate being adapted in one pivoted position to deiiect certain of said mine rock from its normal path of fall, and means electrically connected to said second relay for actuating said solenoid to effect reciprocation of the piston of said cylinder and pivoting of said. gate on each reproduction of the recorded electrical responses of electrical characteristics of certain of said mine rock reflecting said electrical characteristics into a predetermined channel of said hopper.
ROBERT R. BERRY.
REFERENCES CITED The following references are of record in the ille of this patent:
UNITED STATES PATENTS Number Name Date 1,537,228 Gargan May 12, 1925 2,129,058 Bedden Sept. 6, 1938 2,217,342 Ladrach Oct. 8, 1940 2,329,810 Zuschlag Sept. 21, 1943 2,439,446 Begun Apr. 13, 1948 FOREIGN P ATENTS Number Country Date 284,307 Great Britain Jan. 29, 1929 574,808 Great Britain Jan. 22, 1946
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US20030098978A1 (en) * 2001-11-09 2003-05-29 Norimasa Ikeda Color sorting apparatus for granular object with optical detection device consisting of CCD linear sensor
US20030127366A1 (en) * 2001-12-06 2003-07-10 Norimasa Ikeda Color sorting apparatus for granular objects with function to sorting out foreign magnetic metal matters
US6629611B2 (en) * 2000-06-16 2003-10-07 Satake Corporation Granular object sorting apparatus
US6708385B1 (en) 1954-07-28 2004-03-23 Lemelson Medical, Education And Research Foundation, Lp Flexible manufacturing systems and methods
US20040206409A1 (en) * 2003-04-18 2004-10-21 Takeshi Yano Piezoelectric air valve and multiple-type piezoelectric air valve
US20050067332A1 (en) * 2003-09-04 2005-03-31 Norimasa Ikeda Granule color sorting apparatus with display control device
WO2005050823A1 (en) * 2003-11-21 2005-06-02 Sult Gmbh Device for sorting different materials with the aid of a conveyor belt and an electromagnetic actuator
US7065856B1 (en) 1954-07-28 2006-06-27 Lemelson Jerome H Machine tool method
US20070187299A1 (en) * 2005-10-24 2007-08-16 Valerio Thomas A Dissimilar materials sorting process, system and apparata
US7343660B1 (en) 1954-07-28 2008-03-18 Lemeison Medical, Education & Research Foundation, Limited Partnership Machine tool system
US20080257794A1 (en) * 2007-04-18 2008-10-23 Valerio Thomas A Method and system for sorting and processing recycled materials
US20080257793A1 (en) * 2007-01-05 2008-10-23 Valerio Thomas A System and method for sorting dissimilar materials
US20080257795A1 (en) * 2007-04-17 2008-10-23 Eriez Manufacturing Co. Multiple Zone and Multiple Materials Sorting
US20090250384A1 (en) * 2008-04-03 2009-10-08 Valerio Thomas A System and method for sorting dissimilar materials using a dynamic sensor
US20090255857A1 (en) * 2008-04-14 2009-10-15 Alley Industries Llc Filtering flow box for mounting to a silo
US20100005926A1 (en) * 2008-06-11 2010-01-14 Valerio Thomas A Method And System For Recovering Metal From Processed Recycled Materials
US20100013116A1 (en) * 2008-07-21 2010-01-21 Blyth Peter C Method and System for Removing Polychlorinated Biphenyls from Plastics
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US2729214A (en) * 1950-03-09 1956-01-03 American Mach & Foundry Detecting and control apparatus
US2703495A (en) * 1950-07-17 1955-03-08 Ohio Crankshaft Co Temperature control for billet heating apparatus
US2773596A (en) * 1951-06-23 1956-12-11 California Packing Corp Comestible sorting apparatus
US2784851A (en) * 1951-11-22 1957-03-12 Int Standard Electric Corp Arrangement for use in conveying plants employing magnetic destination characteristics
US2950640A (en) * 1951-11-28 1960-08-30 United States Steel Corp Mechanism and method for classifying and assorting metal sheets
US2977003A (en) * 1954-03-15 1961-03-28 A J Bayer Company Conveyor
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US7343660B1 (en) 1954-07-28 2008-03-18 Lemeison Medical, Education & Research Foundation, Limited Partnership Machine tool system
US2941666A (en) * 1955-08-12 1960-06-21 Sperry Rand Corp Magnetic selecting device
US2825476A (en) * 1956-03-09 1958-03-04 A J Bayer Company Control means for conveyor and associated apparatus
US3049247A (en) * 1956-04-10 1962-08-14 Jerome H Lemelson Automated storage
US2980848A (en) * 1956-12-24 1961-04-18 Shell Oil Co Weld seam testing apparatus
US3023851A (en) * 1957-04-08 1962-03-06 Bruno V Stiller Electronic marketing system and apparatus
US2996186A (en) * 1957-11-01 1961-08-15 David E Loughran Mechanical sorter for uranium ore
US3071262A (en) * 1957-12-26 1963-01-01 Bosch And Robert W La Tour Automatic production-conveying and warehousing systems
US3011634A (en) * 1958-03-03 1961-12-05 K & H Equipment Ltd Method and apparatus for sorting materials
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US3272332A (en) * 1961-03-14 1966-09-13 Nuclear Materials & Equipment Classification method and apparatus
US3283899A (en) * 1963-02-27 1966-11-08 Mayer & Co Inc O Automatic food quality control means
US3675768A (en) * 1969-03-17 1972-07-11 Gildardo Legorreta Sanchez Method and apparatus for classifying and segregating particles with electrical and optical means
US3901793A (en) * 1971-11-10 1975-08-26 Rech Geolog Miniere Process for the preconcentration of ores by induced measure of the superficial contents
US4281764A (en) * 1980-02-01 1981-08-04 Fmc Corporation Sorting apparatus for potatoes and the like
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US4830193A (en) * 1981-06-10 1989-05-16 United Kingdom Atomic Energy Authority Gold ore sorting
US4685569A (en) * 1983-01-18 1987-08-11 Kanzaki Paper Mfg. Co., Ltd. Method of detecting and sorting pieces of insulating materials admixed in small pieces of conductive materials
US4544005A (en) * 1983-05-06 1985-10-01 Atlas Pacific Engineering Company Can detection and switch mechanism for can filling apparatus
US5090574A (en) * 1988-09-27 1992-02-25 T. J. Gundlach Machine Company Auto tramp removal system
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US5638657A (en) * 1994-05-09 1997-06-17 Merck & Co., Inc. System and method for automatically feeding, inspecting and diverting tablets for continuous filling of tablet containers
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US6784996B2 (en) 2001-11-09 2004-08-31 Satake Corporation Color sorting apparatus for granular object with optical detection device consisting of CCD linear sensor
US20030098978A1 (en) * 2001-11-09 2003-05-29 Norimasa Ikeda Color sorting apparatus for granular object with optical detection device consisting of CCD linear sensor
US6817474B2 (en) 2001-12-06 2004-11-16 Satake Corporation Color sorting apparatus for granular objects with function to sorting out foreign magnetic metal matters
US20030127366A1 (en) * 2001-12-06 2003-07-10 Norimasa Ikeda Color sorting apparatus for granular objects with function to sorting out foreign magnetic metal matters
US20040206409A1 (en) * 2003-04-18 2004-10-21 Takeshi Yano Piezoelectric air valve and multiple-type piezoelectric air valve
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US7298870B2 (en) 2003-09-04 2007-11-20 Satake Corporation Granule color sorting apparatus with display control device
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US7786401B2 (en) * 2008-06-11 2010-08-31 Valerio Thomas A Method and system for recovering metal from processed recycled materials
US20100013116A1 (en) * 2008-07-21 2010-01-21 Blyth Peter C Method and System for Removing Polychlorinated Biphenyls from Plastics
US20110067569A1 (en) * 2009-04-28 2011-03-24 Mtd America Ltd (Llc) Apparatus and Method for Separating Materials Using Air
US8627960B2 (en) 2009-04-28 2014-01-14 Mtd America Ltd (Llc) Apparatus and method for separating materials using air
US20110017644A1 (en) * 2009-07-21 2011-01-27 Valerio Thomas A Method and System for Separating and Recovering Like-Type Materials from an Electronic Waste System
US20110147501A1 (en) * 2009-07-31 2011-06-23 Valerio Thomas A Method and System for Separating and Recovering Wire and Other Metal from Processed Recycled Materials
US20110024531A1 (en) * 2009-07-31 2011-02-03 Valerio Thomas A Method and System for Separating and Recovering Wire and Other Metal from Processed Recycled Materials
US8360347B2 (en) 2009-07-31 2013-01-29 Thomas A. Valerio Method and system for separating and recovering wire and other metal from processed recycled materials
US8757523B2 (en) 2009-07-31 2014-06-24 Thomas Valerio Method and system for separating and recovering wire and other metal from processed recycled materials
US9764361B2 (en) 2009-07-31 2017-09-19 Tav Holdings, Inc. Processing a waste stream by separating and recovering wire and other metal from processed recycled materials

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