US2325157A - Seismographic prospecting - Google Patents

Seismographic prospecting Download PDF

Info

Publication number
US2325157A
US2325157A US288156A US28815639A US2325157A US 2325157 A US2325157 A US 2325157A US 288156 A US288156 A US 288156A US 28815639 A US28815639 A US 28815639A US 2325157 A US2325157 A US 2325157A
Authority
US
United States
Prior art keywords
circuit
anode
firing
discharge
tube
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US288156A
Inventor
Alfred C Winterhalter
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Sunoco Inc
Original Assignee
Sun Oil Co
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Sun Oil Co filed Critical Sun Oil Co
Priority to US288156A priority Critical patent/US2325157A/en
Application granted granted Critical
Publication of US2325157A publication Critical patent/US2325157A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/22Transmitting seismic signals to recording or processing apparatus
    • G01V1/223Radioseismic systems

Definitions

  • This invention relates to seismographic prospecting, and particularly to improved means for recording the instant an explosion takes place.
  • the break only is recorded, without any interference due to the making of the firing circuit.
  • a sharp indication of the instant of break may thus be transmitted either by wire or by radio to the re-. cording apparatus.
  • the break is used to produce a voltage adapted to-fire a gas filled tube to produce an impulse arranged to control the operation of a radio transmitter.
  • Figure 1 is a wiring diagram showing the improved circuit applied to firing by means of a blasting machine.
  • Figure 2 is a. partial similar diagram illustrating the modifications necessary in the event that firing is accomplished by the use of a battery.
  • a triode which may be interposed between the oscillator Al and the amplifier 6 of a conven- ;iona1 radio transmitting circuit, or which may 1e one of the amplifying tubes of the amplifier Wstem.
  • the amplifier in any event, feeds the ;ransmitting antenna 8 from which a signal is lent to a remote recording apparatus.
  • a leak :ircuit of the grid ll] of the tube 2 comprises a radio frequency choke l2 and series resistances It and it, the two resistances together forming he proper grid leak for normal operation and he resistance l6 being of proper value for control y the gas tube circuit, as hereafter described.
  • This tube may, for example, be of the OA4-G type and may comprise the anode 20, cathode 24 and starter-anode 26.
  • the operation of this type of tube is well known and involves the initiation of a discharge.
  • the cathode and starter-anode which discharge effects a discharge betweenthe cathode and anode if the anode potential is surficiently high and the starter-anode current exceeds some predetermined value. For example, in a typical case, volts between the starter-anode and cathode will produce a discharge between them. If, then, the anode voltage with respect to cathode is about volts, 2. current of 25 microamperes in the starter-anode circuit will cause a discharge between the cathode and anode. On the other hand, if breakdown of the starter-anode circuit has not occurred, the anode breakdown will not occur until a minimum potential of about 225 volts between the anode and cathode is exceeded.
  • a battery 22 Connected to the junction point of the resistances l4 and i6 is a battery 22 having 2. voltage of, for example, 180 volts.
  • a switch 23 is interposed between the positive side of this battery and the anode 20, this switch serving to interrupt the discharge at a proper time.
  • the cathode 24 may be connected directly to ground and the cathode of the tube 2.
  • the starter-anode 26 is connected through a current limiting resistance 28 to thepositive pole of the blasting machine, indicated at 32.
  • Shunted across the blasting machine are the stabilizing resistance 30, which may have a high value such as one megohm, a safety switch 38, which is closed except at the time of firing, and the leads 34 connected to the igniting filament 36 of the detonator of the charge 31.
  • the leads 34 should be well insulated to prevent leakage and maintain high the resistance across the blasting machine upon breaking of the igniting filament.
  • the safety switch 38 is opened to remove the short circuit from the firing leads and the switch 23 is closed to impose the potential of the battery 22 upon the anode.
  • the potential thus imposed is insuificient to cause discharge in the absence of discharge at the starter-anode, and consequently no current flows through the resistance l6 except the normal grid current of proper amount to provide the bias for the amplifying tube 2.
  • terminal voltage is impressed upon the starteranode and the leads to filament 36, however, is the internal impedance of the blasting machine is sufilciently high so that accompanying the relatively heavy current which flows to the igniting filament there is a terminal voltage considerably less than the 90 volts required to initiate starter-anode discharge.
  • the terminal voltage of v the blasting machine rises instantly to its open circuit value, the high resistance offering no substantial load.
  • This open circuit potential is generally about 150 volts, quite suflicient to initiate the starter-anode discharge.
  • the voltage is sumciently high to cause to fiow through the starter anode and its series resistance 28 a current of suflicient value to initiate anode discharge under the 180 volts provided by the battery 22.
  • the potential drop between the anode and cathode reaches a value substantially constant at '70 volts, and hence the difierence voltage between the voltage of the battery and this potential drop is imposed across the resistance l6, biasing the tube 2 to cut-ofi. Since there is no large impedance in the circuit capable of producing any appreciable delay, it will be evident that for all practical purposes the cut-off of the tube 2 occurs at the instant of the firing of the shot. Thus this instant may be transmitted to secure a record of extremely high accuracy.
  • the resistance 28 likewise prevents damage which might be caused by excessive starter-anode current.
  • the leak resistor 30 must be provided to avoid accidental tube discharges which may occur in the event that the starter-anode is free.
  • FIG 2 there is illustrated the modification' necessary to adapt the circuit to battery firing.
  • the tube It! may be of the same type as that of Figure 1, for example an OA4-G.
  • the firing battery is indicated at Ml, While at 42 there is indicated the internal resistance of the battery or, in the event that that is insufficient, an auxiliary resistance adapted to insure that, when the circuit is closed for firing by means of the switch 43, the terminal voltage is insuflieient to cause a starter-anode discharge. In case a battery is used, the voltage necessary to produce starter-anode discharge would be considerably in excess of the voltage desired for firing the detonator.
  • m bias battery 44 is introduced adapted to maintain on the starter-anode a voltage, insuffici nt to cause its discharge upon closure of th firing circuit, but suflicient to produce discharge when added to the open circuit voltage of the battery t ll, which is imposed across the resistance 30 as soon as the filament is disrupted by the explosion.
  • the circuit is, of course, the same as that of Figure 1.
  • a firing circuit for an explosive charge for an explosive charge, current supplying means for said circuit, signal transmitting means, and means for controlling the transmitting means to transmit a signal upon disruption of the firing circuit by explosion of a charge
  • said last named means comprising a grid controlled electronic tube of relay type having its grid input circuit connected across said current supplying means in shunt with said firing circuit so that upon disruption of the firing circuit the potential of the grid is raised sufficiently to cause discharge of said tube.
  • a firing circuit for an explosive charge for an explosive charge, current supplying means for said circuit, signal transmitting means, and means for controlling the transmitting means to transmit a signal upon disruption of the firing circuit by explosion of a charge
  • said last named means comprising a grid controlled electronic tube of relay type having its grid connected to said firing circuit in a manner to render it operative upon disruption of the firing circuit.
  • a firing circuit for an ex plosive charge for an ex plosive charge, current supplying means for said circuit, signal transmitting means, means for controlling the transmitting means to transmit a signal upon disruption of the firing circuit by explosion of a charge which simultaneously causes an electrical change in the firing circuit
  • said last named means comprising a grid controlled electronic tube of relay type arranged to discharge by rise of grid potential, and connections between the tube and firing circuit whereby said electrical change efi'ects a rise of grid potential to the discharge point upon disruption of the firing circuit.
  • a firing circuit for an explosive charge for an explosive charge, current supplying means for said circuit, signal transmitting means, means for controlling the transmitting means to transmit a signal upon disruption of the firing circuit by explosion of a charge which simultaneously causes an increase of voltage across the firing circuit, said last named means comprising an electronic tube of. relay type, and connections between the tube and the firing circuit whereby it is arranged to discharge in response to said increase of voltage across the firing circuit upon disruption thereof.
  • a firing circuit for an explosive charge comprising a thermionic vacuum tube having a grid, and means for controlling the transmitting means to transmit a signal upon disruption of the firing circuit by explosion of a charge which simultaneously causes an electrical change in the firing circuit
  • said last named means comprising an electronic tube of relay type, and connections between the last mentioned tube and the firing circuit whereby it is arranged to discharge upon the disruption of the firing circuit, and connections through which such discharge changes the bias on said grid.

Description

y 1943- A. c. WINTERHALTER 2,325,157
Filed Aug. 5, 1939 AMPLIFIER [vhf/E55" fi rcal Wzl z ria/zer y i w Patented July 27, 1943 SEISMOGRAPHIC PROSPECTING Alfred C. Winterhalter, Beaumont, Tex., assignor to Sun Oil Company, Philadelphia, Pa., a corporation of New Jersey Application August 3,1939, Serial No. 288,156
Claims. This invention relates to seismographic prospecting, and particularly to improved means for recording the instant an explosion takes place.
In seismographic work it is essential that the instant of explosion be determined on the record to a high degree of accuracy, and it is customary, therefore, to record the instant at which the firing circuit is disrupted by the explosion. Diificulties are sometimes encountered, particularly when th instant of break is transmitted by radio to a remote recording station in securing a sharp indication of the instant whem the break occurred. Usually both the make and break of the firing circuit are noted, and in the event that the break is not sharply indicated, the time of break may be determined with mor or less accuracy from the less significant instant when the circuit is made, using the knowledge of the approximate delay between the make of the circuit and the break occasioned by the explosion.
In accordance with the present invention, the break only is recorded, without any interference due to the making of the firing circuit. A sharp indication of the instant of break may thus be transmitted either by wire or by radio to the re-. cording apparatus. Specifically, in accordance with the invention, the break is used to produce a voltage adapted to-fire a gas filled tube to produce an impulse arranged to control the operation of a radio transmitter.
The broad and subsidiary objects of the invention will become apparent from the following description, read in conjunction with the accompanying drawing, in which:
Figure 1 is a wiring diagram showing the improved circuit applied to firing by means of a blasting machine; and
Figure 2 is a. partial similar diagram illustrating the modifications necessary in the event that firing is accomplished by the use of a battery.
Referring first to Figure .1, there is illustrated at 2 a triode, which may be interposed between the oscillator Al and the amplifier 6 of a conven- ;iona1 radio transmitting circuit, or which may 1e one of the amplifying tubes of the amplifier Wstem. The amplifier, in any event, feeds the ;ransmitting antenna 8 from which a signal is lent to a remote recording apparatus. A leak :ircuit of the grid ll] of the tube 2 comprises a radio frequency choke l2 and series resistances It and it, the two resistances together forming he proper grid leak for normal operation and he resistance l6 being of proper value for control y the gas tube circuit, as hereafter described.
At t it there is indicated a gas triode of the coldcathode starter-anode type. This tube may, for example, be of the OA4-G type and may comprise the anode 20, cathode 24 and starter-anode 26. The operation of this type of tube is well known and involves the initiation of a discharge.
between the cathode and starter-anode, which discharge effects a discharge betweenthe cathode and anode if the anode potential is surficiently high and the starter-anode current exceeds some predetermined value. For example, in a typical case, volts between the starter-anode and cathode will produce a discharge between them. If, then, the anode voltage with respect to cathode is about volts, 2. current of 25 microamperes in the starter-anode circuit will cause a discharge between the cathode and anode. On the other hand, if breakdown of the starter-anode circuit has not occurred, the anode breakdown will not occur until a minimum potential of about 225 volts between the anode and cathode is exceeded.
Connected to the junction point of the resistances l4 and i6 is a battery 22 having 2. voltage of, for example, 180 volts. A switch 23 is interposed between the positive side of this battery and the anode 20, this switch serving to interrupt the discharge at a proper time.
The cathode 24 may be connected directly to ground and the cathode of the tube 2.
The starter-anode 26 is connected through a current limiting resistance 28 to thepositive pole of the blasting machine, indicated at 32. Shunted across the blasting machine are the stabilizing resistance 30, which may have a high value such as one megohm, a safety switch 38, which is closed except at the time of firing, and the leads 34 connected to the igniting filament 36 of the detonator of the charge 31. The leads 34 should be well insulated to prevent leakage and maintain high the resistance across the blasting machine upon breaking of the igniting filament.
In the operation of this arrangement, following the proper placing of the charge and the rendering of the radio transmitter operative to transmit a continuous wave, the safety switch 38 is opened to remove the short circuit from the firing leads and the switch 23 is closed to impose the potential of the battery 22 upon the anode. The potential thus imposed is insuificient to cause discharge in the absence of discharge at the starter-anode, and consequently no current flows through the resistance l6 except the normal grid current of proper amount to provide the bias for the amplifying tube 2.
When the blasting machine 32 is operated, its
terminal voltage is impressed upon the starteranode and the leads to filament 36, however, is the internal impedance of the blasting machine is sufilciently high so that accompanying the relatively heavy current which flows to the igniting filament there is a terminal voltage considerably less than the 90 volts required to initiate starter-anode discharge.
At the instant the filament is disrupted by the filament 36. The of low resistance and the explosion, however, the terminal voltage of v the blasting machine rises instantly to its open circuit value, the high resistance offering no substantial load. This open circuit potential is generally about 150 volts, quite suflicient to initiate the starter-anode discharge. Furthermore, the voltage is sumciently high to cause to fiow through the starter anode and its series resistance 28 a current of suflicient value to initiate anode discharge under the 180 volts provided by the battery 22. As soon as discharge is initiated, the potential drop between the anode and cathode reaches a value substantially constant at '70 volts, and hence the difierence voltage between the voltage of the battery and this potential drop is imposed across the resistance l6, biasing the tube 2 to cut-ofi. Since there is no large impedance in the circuit capable of producing any appreciable delay, it will be evident that for all practical purposes the cut-off of the tube 2 occurs at the instant of the firing of the shot. Thus this instant may be transmitted to secure a record of extremely high accuracy.
the radio. The value of the resistance l6 must,
be such as to limit the anode current to asafe value to prevent damage to the tube l8. The resistance 28 likewise prevents damage which might be caused by excessive starter-anode current. The leak resistor 30 must be provided to avoid accidental tube discharges which may occur in the event that the starter-anode is free.
While a cold cathode gas tube has been specifically described, it will be evident that hot cathode types may be equally well used. The grid or starter-anode control may be either positive or negative, depending upon the type of tube, suitable biasing being provided if necessary. In general, gas rather than vapor tubes are to be recommended because of the possible instability and accidental discharge of vapor types.
In Figure 2 there is illustrated the modification' necessary to adapt the circuit to battery firing. The tube It! may be of the same type as that of Figure 1, for example an OA4-G. The firing battery is indicated at Ml, While at 42 there is indicated the internal resistance of the battery or, in the event that that is insufficient, an auxiliary resistance adapted to insure that, when the circuit is closed for firing by means of the switch 43, the terminal voltage is insuflieient to cause a starter-anode discharge. In case a battery is used, the voltage necessary to produce starter-anode discharge would be considerably in excess of the voltage desired for firing the detonator. Accordingly, m bias battery 44 is introduced adapted to maintain on the starter-anode a voltage, insuffici nt to cause its discharge upon closure of th firing circuit, but suflicient to produce discharge when added to the open circuit voltage of the battery t ll, which is imposed across the resistance 30 as soon as the filament is disrupted by the explosion. In all respects except those noted, the circuit is, of course, the same as that of Figure 1.
What I claim and desire to protect by Letters Patent is:
1. In combination, a firing circuit for an explosive charge, current supplying means for said circuit, signal transmitting means, and means for controlling the transmitting means to transmit a signal upon disruption of the firing circuit by explosion of a charge, said last named means comprising a grid controlled electronic tube of relay type having its grid input circuit connected across said current supplying means in shunt with said firing circuit so that upon disruption of the firing circuit the potential of the grid is raised sufficiently to cause discharge of said tube.
2. In combination, a firing circuit for an explosive charge, current supplying means for said circuit, signal transmitting means, and means for controlling the transmitting means to transmit a signal upon disruption of the firing circuit by explosion of a charge, said last named means comprising a grid controlled electronic tube of relay type having its grid connected to said firing circuit in a manner to render it operative upon disruption of the firing circuit.
3. In combination, a firing circuit for an ex plosive charge, current supplying means for said circuit, signal transmitting means, means for controlling the transmitting means to transmit a signal upon disruption of the firing circuit by explosion of a charge which simultaneously causes an electrical change in the firing circuit, said last named means comprising a grid controlled electronic tube of relay type arranged to discharge by rise of grid potential, and connections between the tube and firing circuit whereby said electrical change efi'ects a rise of grid potential to the discharge point upon disruption of the firing circuit.
4. In combination, a firing circuit for an explosive charge, current supplying means for said circuit, signal transmitting means, means for controlling the transmitting means to transmit a signal upon disruption of the firing circuit by explosion of a charge which simultaneously causes an increase of voltage across the firing circuit, said last named means comprising an electronic tube of. relay type, and connections between the tube and the firing circuit whereby it is arranged to discharge in response to said increase of voltage across the firing circuit upon disruption thereof.
5. In combination, a firing circuit for an explosive charge, current supplying means for said circuit, signal transmitting means comprising a thermionic vacuum tube having a grid, and means for controlling the transmitting means to transmit a signal upon disruption of the firing circuit by explosion of a charge which simultaneously causes an electrical change in the firing circuit, said last named means comprising an electronic tube of relay type, and connections between the last mentioned tube and the firing circuit whereby it is arranged to discharge upon the disruption of the firing circuit, and connections through which such discharge changes the bias on said grid.
ALFRED C. WINTERHALTER.
US288156A 1939-08-03 1939-08-03 Seismographic prospecting Expired - Lifetime US2325157A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US288156A US2325157A (en) 1939-08-03 1939-08-03 Seismographic prospecting

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US288156A US2325157A (en) 1939-08-03 1939-08-03 Seismographic prospecting

Publications (1)

Publication Number Publication Date
US2325157A true US2325157A (en) 1943-07-27

Family

ID=23105984

Family Applications (1)

Application Number Title Priority Date Filing Date
US288156A Expired - Lifetime US2325157A (en) 1939-08-03 1939-08-03 Seismographic prospecting

Country Status (1)

Country Link
US (1) US2325157A (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2641749A (en) * 1951-12-15 1953-06-09 Standard Oil Dev Co Time break recording in seismic prospecting

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2641749A (en) * 1951-12-15 1953-06-09 Standard Oil Dev Co Time break recording in seismic prospecting

Similar Documents

Publication Publication Date Title
US2306386A (en) Electronic apparatus
US2554905A (en) Seismic signal amplifier
US2437876A (en) Signal receiver and warning device
US2395368A (en) Audible indication for radar
US2523017A (en) Detonation detector system
US2976485A (en) Continuity testing device for explosive igniting circuits
US2325157A (en) Seismographic prospecting
US2572832A (en) Tube protection circuit
US2868940A (en) Electronic arc-suppressor
FR1401241A (en) Flame ignition, protection and control device, for oil burner type burner or the like
US2845529A (en) Protective circuits
US2567247A (en) Pulse generator
US2623922A (en) Electric pulse-forming shot-firing device
US2334530A (en) Protective means for transmitters
US2673899A (en) Automatic volume control system
US2713620A (en) Automatic volume control system
US2722602A (en) Saturable reactor controlled delay multivibrator
US3220503A (en) Seismic shooting sequence timer
US2559959A (en) Automatic cutoff for radio receivers
US2503730A (en) Amplifying and quenching circuits for radiation detectors
US2275316A (en) Apparatus for sending and recording time impulses
US2300127A (en) Protective device
US3878790A (en) Seismic blaster circuit
US2369081A (en) Apparatus for transmitting seismic signals
US2830263A (en) Metal detector