US2925729A - Continuous method of recording the progress of the reaction zone in detonating or burning columns - Google Patents

Continuous method of recording the progress of the reaction zone in detonating or burning columns Download PDF

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US2925729A
US2925729A US670590A US67059057A US2925729A US 2925729 A US2925729 A US 2925729A US 670590 A US670590 A US 670590A US 67059057 A US67059057 A US 67059057A US 2925729 A US2925729 A US 2925729A
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reaction zone
recording
detonating
resistance
progress
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US670590A
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Jr Arthur W O'brien
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American Potash and Chemical Corp
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American Potash and Chemical Corp
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N33/00Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
    • G01N33/22Fuels, explosives
    • G01N33/227Explosives, e.g. combustive properties thereof

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  • This invention relates to the measurement of the rate of advance of a reaction through a column of an explosive or a propellant. More particularly, the invention is concerned with a method and apparatus enabling one to determine the velocity of movement of a reaction zone such as may be provided by a detonating explosive column or in a strand of a burning solid propellant.
  • the rate of linear movement of a reaction in a detonating or burning column has been determined by inserting probes into the column, a probe usually consisting of a pair of open-end conductors acting as a switch.
  • the passage of the reaction across the conductors results in closing of the switch because of the high content of ions provided in the reaction zone.
  • Closing of the switch is ordinarily used to operate some type of pulsing and recording system, such as a counter-chronograph operated by a difierentiating circuit.
  • some type of pulsing and recording system such as a counter-chronograph operated by a difierentiating circuit.
  • the time taken by the reaction zone to traverse any measured linear segment of the zone is determined, and the average velocity of the reaction zone obtained. Any number of segments may be measured by the insertion of the necessary number of probes and provision of an adequate number of pulsing and recording devices.
  • the aforementioned method of measurement is discontinuous in the sense that only the average velocity between any two points can be determined.
  • the method and apparatus of the present invention enables one to determine a continuous measurement in the sense that it employs only a single probe which is inserted at an infinite number of points along the path of the reaction zone. Ion concentration is utilized to effect switching, but the switch employed is not simply an on-and-ofi type of switch; instead, the probe consists of a closed loop of resistance wire and the effect of ion concentration in the reaction zone can be likened to that of a slide on a slide wire potentiometer, the reaction zone decreasing the resistance in the loop of resistance wire in advance of the reaction zone at a rate equal to the velocity of movement of the reaction zone. This effect can be readily measured and by relatively simple electrical circuitry.
  • Figure 1 is schematic showing of apparatus and a circuit which can be employed to practice the present invention.
  • Figure 2 is a diagram illustrating the operation of the circuit.
  • Figure 3 is a reproduction of an oscillograph record by the method of this invention.
  • an explosive column as provided by a length of pipe 6 (1" diameter ice by 15" in length) filled with TNT at one end, this being indicated at 7, and with a composition B at the other end, it being desired to determine the relative rate of explosion or detonation of composition B as compared to TNT.
  • a small tetryl booster 9 was placed at one end of the pipe. utilized to initiate the reaction; an olf-on type of probe 12 was utilized to trigger the sweep on an oscillograph, generally indicated at 14, this circuit including a sweep trigger pulsing unit 16, and the variation in the oscillm graph being recorded by a camera 17.
  • a resistance loop 21 consisting of approximately three feet of Chromel wire, 0.15" in diameter. The resistance was measured at approximately 11 ohms; the resistance loop was connected in a series circuit with a three-volt dry cell and an external resistance 22. The voltage change across the external resistance during detonation was monitored by an oscillograph and the sweep recorded by a camera.
  • the circuit utilized consists essentially of two series resistors and a source of constant voltage, as is indicated in Figure 2. As the resistance of probe 21 decreases, the current in the whole series circuit increases. This current increase requires that the voltage across the external resistance also increase. The oscillograph records this voltage in relation to time.
  • the invention is capable of broad application. For example, it can be applied successfully in explosives where the effect of boosters, the diameter eifects on propagation of the detonation, indirect measurement of the power of the explosive, the effects of additives for desensitizing or catalysis, etc., can be determined. Also, the measurements made possible by this invention have value where the point-to-point changes in velocity are important in precise measurements on explosives or pro pellants.
  • the introduction of additional probes, parallel to the one indicated, and with the addition of appropriate external electric circuitry can provide information determining the physical dimensions and configuration of the reaction zone itself.
  • Apparatus for determining the velocity of advance of a linearly moving ionization front of the reaction zone in columns of explosive and propellant comprising: an electrical resistance loop positioned internally of and extending longitudinally with respect to one of said columns; a source of direct current for said loop; an external resistance in said circuit in series with said resistance loop and said direct current source means for determining at successive intervals the voltage drop across said external resistance during the presence of an advancing ionization front as a measure of the voltage drop across said loop; and means for initiating an ionization reaction at one end of said reaction zone whereby said ionization front is caused to advance in a direction parallel to said resistance loop.
  • a linearly moving ionization front of the reaction zone in explosive or propellant columns comprising: an elongated reaction column; a U-shaped, electrical resistance loop positioned internally of' said column and extending longitudinally thereof; a source of direct current for said loop; an external resistance in said circuit and in series with said resistance loop and said direct current source; means for continuously recording the voltage drop across said resistance during the presence of an advancing ionization front, as a measure of the voltage drop across said loop; and means for initiating an ionization reaction at one end of said reaction column whereby said 2,925,729 r V I? p or a 4' v ionization front is caused to advance in a direction parallel to said resistance loop.
  • said means for recording said voltage drop across said external resistance is an oscillograph having means for amplifying a direct current signal.

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  • Life Sciences & Earth Sciences (AREA)
  • Engineering & Computer Science (AREA)
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  • Medicinal Chemistry (AREA)
  • Food Science & Technology (AREA)
  • Combustion & Propulsion (AREA)
  • Physics & Mathematics (AREA)
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Description

EMT
196% A. w. O'BRIEN, JR 2,925,729
CONTINUOUS METHOD OF RECORDING THE PROGRESS OF THE REACTION ZONE IN DETONATING OR BURNING COLUMNS Filed July 8, 1957 2 Sheets-Sheet l Sly/ml 70 Oscil/ograph V Dry cells 22 Probe res/sfance Exfema/ reslsfance INVENTORY. Arf/rur 14/ OBrien, Jr-
- EC/(HOFF J SLICK 1969 A. w. O'BRIEN, JR 232,72
CONTINUOUS METHOD OF RECORDING THE PROGRESS OF THE REACTION ZONE IN DETONATING OR BURNING COLUMNS Filed July 8, 1957 2 Sheets-Sheet 2 Campos/ ion B INVENTOR. Arthur W O'Br/en, Jr:
EC/(HOFF 2 SL/CK NEYS w an By A MEMBER OF THE #72 United States Patent CONTINUOUS METHOD OF RECORDING THE PROGRESS OF THE REACTION ZONE IN DET- ONATING OR BURNING COLUMNS Arthur W. OBrien, In, Hanover Center, Mass., assignor to American Potash & Chemical Corporation, a corporation of Delaware Application July 8, 1957, Serial No. 670,590
3 Claims. (Cl. 73-35) This invention relates to the measurement of the rate of advance of a reaction through a column of an explosive or a propellant. More particularly, the invention is concerned with a method and apparatus enabling one to determine the velocity of movement of a reaction zone such as may be provided by a detonating explosive column or in a strand of a burning solid propellant.
Heretofore, the rate of linear movement of a reaction in a detonating or burning column has been determined by inserting probes into the column, a probe usually consisting of a pair of open-end conductors acting as a switch. The passage of the reaction across the conductors results in closing of the switch because of the high content of ions provided in the reaction zone. Closing of the switch, in turn, is ordinarily used to operate some type of pulsing and recording system, such as a counter-chronograph operated by a difierentiating circuit. In this manner, the time taken by the reaction zone to traverse any measured linear segment of the zone is determined, and the average velocity of the reaction zone obtained. Any number of segments may be measured by the insertion of the necessary number of probes and provision of an adequate number of pulsing and recording devices.
The aforementioned method of measurement is discontinuous in the sense that only the average velocity between any two points can be determined. The method and apparatus of the present invention enables one to determine a continuous measurement in the sense that it employs only a single probe which is inserted at an infinite number of points along the path of the reaction zone. Ion concentration is utilized to effect switching, but the switch employed is not simply an on-and-ofi type of switch; instead, the probe consists of a closed loop of resistance wire and the effect of ion concentration in the reaction zone can be likened to that of a slide on a slide wire potentiometer, the reaction zone decreasing the resistance in the loop of resistance wire in advance of the reaction zone at a rate equal to the velocity of movement of the reaction zone. This effect can be readily measured and by relatively simple electrical circuitry.
It is in general the broad object of the present invention to provide a novel method and apparatus for the measurement of advance of a reaction zone through a column of explosive or propellant.
The invention includes other objects and features of advantage, some of which, together with the foregoing, will appear hereinafter wherein the preferred form of apparatus is represented schematically. In the drawing accompanying and forming a part hereof,
Figure 1 is schematic showing of apparatus and a circuit which can be employed to practice the present invention.
Figure 2 is a diagram illustrating the operation of the circuit.
Figure 3 is a reproduction of an oscillograph record by the method of this invention.
Referring to the drawing, I have indicated an explosive column as provided by a length of pipe 6 (1" diameter ice by 15" in length) filled with TNT at one end, this being indicated at 7, and with a composition B at the other end, it being desired to determine the relative rate of explosion or detonation of composition B as compared to TNT. A small tetryl booster 9 was placed at one end of the pipe. utilized to initiate the reaction; an olf-on type of probe 12 was utilized to trigger the sweep on an oscillograph, generally indicated at 14, this circuit including a sweep trigger pulsing unit 16, and the variation in the oscillm graph being recorded by a camera 17.
Located centrally of the pipe was a resistance loop 21 consisting of approximately three feet of Chromel wire, 0.15" in diameter. The resistance was measured at approximately 11 ohms; the resistance loop was connected in a series circuit with a three-volt dry cell and an external resistance 22. The voltage change across the external resistance during detonation was monitored by an oscillograph and the sweep recorded by a camera.
The electrical considerations in the preliminary circuit are simple and require only the application of the Ohms law in its elemental form: E=IR. The circuit utilized consists essentially of two series resistors and a source of constant voltage, as is indicated in Figure 2. As the resistance of probe 21 decreases, the current in the whole series circuit increases. This current increase requires that the voltage across the external resistance also increase. The oscillograph records this voltage in relation to time.
In Figure 3, I have shown an oscillographic record utilizing the apparatus described, this being a graph of voltage against time. Indirectly, it represents the measure of the changing resistance of the probe loop in relation to time and, further, provides a measure of the position of the reaction zone in relation to time. Thus, the velocity of the zone becomes the slope of the curve, and changes in velocity, acceleration and deceleration, are indicated by positive and negative changes in the slope of the curve. Further, it enables the relative velocity of reaction of composition B and of TNT to be compared.
The invention is capable of broad application. For example, it can be applied successfully in explosives where the effect of boosters, the diameter eifects on propagation of the detonation, indirect measurement of the power of the explosive, the effects of additives for desensitizing or catalysis, etc., can be determined. Also, the measurements made possible by this invention have value where the point-to-point changes in velocity are important in precise measurements on explosives or pro pellants.
Also, the introduction of additional probes, parallel to the one indicated, and with the addition of appropriate external electric circuitry can provide information determining the physical dimensions and configuration of the reaction zone itself.
I claim:
1. Apparatus for determining the velocity of advance of a linearly moving ionization front of the reaction zone in columns of explosive and propellant, comprising: an electrical resistance loop positioned internally of and extending longitudinally with respect to one of said columns; a source of direct current for said loop; an external resistance in said circuit in series with said resistance loop and said direct current source means for determining at successive intervals the voltage drop across said external resistance during the presence of an advancing ionization front as a measure of the voltage drop across said loop; and means for initiating an ionization reaction at one end of said reaction zone whereby said ionization front is caused to advance in a direction parallel to said resistance loop.
2. Apparatus for determining the velocity of advance A No. 8 blasting cap, indicated at 11, was
of a linearly moving ionization front of the reaction zone in explosive or propellant columns, comprising: an elongated reaction column; a U-shaped, electrical resistance loop positioned internally of' said column and extending longitudinally thereof; a source of direct current for said loop; an external resistance in said circuit and in series with said resistance loop and said direct current source; means for continuously recording the voltage drop across said resistance during the presence of an advancing ionization front, as a measure of the voltage drop across said loop; and means for initiating an ionization reaction at one end of said reaction column whereby said 2,925,729 r V I? p or a 4' v ionization front is caused to advance in a direction parallel to said resistance loop.
3. The apparatus of claim 2 wherein said means for recording said voltage drop across said external resistance is an oscillograph having means for amplifying a direct current signal.
References Cited in the file of this patent Nisewanger et al Mar. 5, 1946
US670590A 1957-07-08 1957-07-08 Continuous method of recording the progress of the reaction zone in detonating or burning columns Expired - Lifetime US2925729A (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3027751A (en) * 1957-09-20 1962-04-03 Canadian Ind Apparatus for determining detonation or burning velocities of materials
US3267721A (en) * 1963-11-15 1966-08-23 Kenneth H Jacobs Apparatus for determining the burning rates of solid rocket propellants
US20050247109A1 (en) * 2002-03-28 2005-11-10 Meyer Eric N System and method for monitoring features of a blast

Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2395902A (en) * 1945-02-27 1946-03-05 Us Government Electronic chronoscope for measuring rates of detonation

Patent Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2395902A (en) * 1945-02-27 1946-03-05 Us Government Electronic chronoscope for measuring rates of detonation

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3027751A (en) * 1957-09-20 1962-04-03 Canadian Ind Apparatus for determining detonation or burning velocities of materials
US3267721A (en) * 1963-11-15 1966-08-23 Kenneth H Jacobs Apparatus for determining the burning rates of solid rocket propellants
US20050247109A1 (en) * 2002-03-28 2005-11-10 Meyer Eric N System and method for monitoring features of a blast
US7370513B2 (en) * 2002-03-28 2008-05-13 Orica Explosives Technology Pty. Ltd. System and method for monitoring features of a blast

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