SAE ARP 1278-1978 Oscilloscopic Method of Measuring Spark Energy《示波法测量火花能量》.pdf

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1、SAE ARP*L278 78 W 8357340 0025499 5 14- 55-47 I ARP 1278 PRACTICE Revised AEROSPACE RECOMMENDED Society of Automotive Engineers, Inc. 400 COMMONWEALTH DRIVE. WARRENDALE. PA. 15096 OSCILLOSCOPIC METHOD OF MEASURING SPARK ENERGY PURPOSE This report provides specific information on instrumentation and

2、procedure for the measurement of capacitance discharge spark energy using an oscilloscope. SCOPE This report descrjbes basic method for measurement of spark energy on all types of capacitance discharge exciters. Reference is made to other methods which may be used if limitations are observed. 1. INT

3、RODUC TION 1.1 A spark between two igniter plug electrodes is the most common and accepted way of igniting a combustible mixture. Wide variations of the combustible mixture and its characteristics are found from combustor to combustor. The design parameters of ignition systems, particularly spark en

4、ergy, are generally arrived at by empirical testing. Thus it is very important that a means be provided for testing and identifying the magnitude and characteristics of a particular spark. 1.2 The oscilloscopic method of measuring spark energy described in this report has been shown to agree satisfa

5、ctorily with the spark calorimeter described in AIR 885. The oscilloscopic method in addition allows identification of the peak power, time duration and power envelope of the spark. Also test readings may be taken in a relatively short time. 1.3 It is sometimes desirable to periodically examine prod

6、uction or service exciters to determine their discharge energy capability. Recommendation is made that short circuit discharge current will provide the necessary information of exciter health. 1.4 “here are several variations of the oscilloscopic method of measuring spark energy in use. While all of

7、 these provide relative spark energy data, most have limitations that preclude use on certain ignition circuits such as the %unipolarity discharge. To aid the occasional user and provide a base for definition, the Sequential voltage and current measurement is presented as the general method. 1.5 Oth

8、er methods such as the simultaneous and chopped mode measurements are identified and their primary limitations noted. 1.6 Instantaneous electronic multiplication of discharge current and voltage and the use of computer techniques are recognized as extensions of energy measurement technique. Such met

9、hods that can be shown to correlate with the results of paragraph 2. or AIR 885 may be used. 2. BASIC PROCEDURE FOR SPARK ENERGY MEASUREMENTS The discharge current and igniter arc voltage are measured in separate setups to eliminate any pos.sibility of ground loops or frequency response problems. Th

10、e resulting sequential voltage and current traces are superimposed and the power discharge curve formed. This Aerospace Recommended Practice was upgraded from an Aerospace Information Report by Committee action April, 978. Copyright 1978 by Society of Automotive Enginean, Inc. F % Printed in U.S.A.

11、All rights reserved. P SAE ARP*1278 i8 a 8357340 0025500 8 m .1 - 2- 2.1 Discharge Current Measurement: 2.1.1 The apparatus is set up as per Fig. 1. Allow approximately 20 minutes warm-up time for the oscilloscope to stabilize. 2.1.2 Set the input amplifier channel selector to the channel being used

12、 and adjust the vertical amplifier to ohin maximum deflection of the waveform within the linear response of the oscilloscope. 2.1.3 Set the triggering mode switch to the most stable and sensitive position. 2.1.4 Set the rltriggeringll dope control to positive, if tle initial slope of the current wav

13、eform is positive, negative if it is negative. 2.1.5 Place the stability control fully clockwise. 2.1.6 Place the Yriggering“ level control fully clockwise for positive going slopes and counter-clockwise for negative. 2.1.7 Rotate the stability control slowly counter-clockwise until the sweep just c

14、eases to appear on the oscilloscope screen. 2.1.8 Rotcite the triggering level control countor-clockwise if positive, clockwise if negative, until the zero level of the leading edge of the wave form is obtained. 2.1.9 Adjust the time/majsr division and multiplier controls to give maximum deflection

15、of the waveform but keeping within the linear portion of the screen. 2.1.10 Take a picture of five consecutivo traces of the resultant waveform including the screen grid lines. Refer to Fig. 2 for typical discharge current waveforms. 2.2 Arc Voltage Illeastirementa: 2.2.1 “he apparatus is set up as

16、per Fig. 3. Allow warm-up time per 2.1.1 if necessary. 2.2.2 Pollovr procedures outlined in 2.1.2 through 2.1.9 with the following additions: a. Use the same zero reference points and sweep setting as used for the current waveform. b. Adjust, if necesary, the polarity of the waveform (normal-invert

17、control) to produce an apparent 180 phase dlfferenee from the current waveform, 2.2.3 Recheck zero reference pointa and take a pickire of five consecutive traces of the resultant waveform including the screen grid lines. Refer to Fig. 4 for typical arc voltage waveforms. 2.2.4 Current and voltage wa

18、veforms may be photographed on individual films or taken superimposed on the same film. Wing superimposed wccveform pictures is a common procedure to those familiar with oscillographic technique. 2.3 Power Curva Formation: 2.3.1 Place the waveform pictiire in an opaque pichire projector. This will h

19、ave to be repeated if tk current nnd voltage waveforms are on separate pictures. The zero level and zero time points nt the leading edge of both waveforms must be carefully superimposed. SAE ARPUL278 78 E 83573qO 002.5501 T E -3- I ARP1278 2.3.2 Project the picture of the waveforms onto 10-square-to

20、-the-inch graph paper (Dietzgen No. 340A or equivalent). 2.3.3 Lhe up the projector such that one major grid line (usually on centimeter) on the picture represents one inch on the graph paper. 2.3.4 Line up the waveforms vertical zero and horizontal zero references to the corresponding zero referenc

21、e lines on the graph paper. 2.3.5 Trace the waveform (both current and voltage). The center of the width of the consecutive traces is followed in the tracing. 2.3.6 Multiply the current and voltage waveforms together. Multiply vertical amplitude at each O. 1 inch time interval on the horizontal axis

22、. 2.3.7 Plot a volt-ampere (power) curve from the resultant data. See Fig. 5 for typical power curve data. Note: Multiplication of tb voltage and current curves and subsequent area calculation for energy may be accomplished by computer techniques directly from the photographs eliminating the project

23、ion step. 2.4 Calculation of Spark Enerpy : 2.4.1 Integrate the area under the power waveform with the planimeter. 2.4.2 Calculate the energy from the formula: ei eV Kv At R J= J = Arc Energy (Jodes/Spark) ei = Amplifier Calibration for the Current Waveform (volts/major div. ) eV = Amplifier calibra

24、tion for the Voltage Waveform (voltdmajor div. ) Kv = Voltage Divider Multiplying Factor t = Oscilloscope Sweep Setting (second/major div. ) R = Resistance of the Current Shunt (ohms) A = Total Area under the Power Curve 2.5 Description of Equipment: 2.5.1 General: Selection of oscilloscop , plug in

25、 unit, voltage adapter , voltage divider , and current shunt should be such that their combination, whether measuring discharge current or arc voltage, has a rise time which is O. 1 times the rise time to be measured and a band width which is at least ten times the frequency of the parameter being m

26、easured. SE-ARPxL278 78 357340 0025502 I ARP 1278 I I -4 - 2.5.2 2.5.3 2.5.4 2.5.5 2.5. G 2.5.7 Oscilloscope and Amplifier: Tektroniz 530 or 540 series or equivalent which includes accurately calibrated vertical amplifiers and horizontal sweep circuitB. The plug-in is type 1Al or equivalent. Current

27、 Shunt: nie insertion of the current shunt should have minimum effect on the discharge circuit. A basic four terminal coaxially constructed resistor is satisfactory i the impedance characterietic is flat and reeistive to one megacycle. Spical resistance value should be 0,005 ohms, Lower valiics such

28、 as O. O01 will eliminate any question of insertion loss in all cases. miter Voltage Adapter: This adapter permits the measurement of the voltage drop across the ignitw plug spark plasma. It makes contact to the center electrode and the shell of the igniter plug. The needle contact, contacting the c

29、enter electrode must be enclosed in an insulating sleeve. Certain igniter tip configurations will give erroneous resulta due to disturbance of the arc. in these cases igniter cm be modified to obtain connection to the center electrode through the side of the plug:. This connection should be as close

30、 as possible to the arc, preferably not more than one inch from the igniter firing tip. Voltage Divider: me voltage divider must withstand the igniter ionization voltage (up to 25 KV) and yet measure the igaiter arc voltage (approximately 75 volts). To accomplish this, isolation of 25 KV and an atbn

31、uation ratio of 1OO:l or less is desirable. The 25 KV isolation is not necessary for low tension syisteme and clipping or other means of suppression may be used on high tension systems. 10 K ResiBtOr: A 10 K resistor is often required on the input to the voltage divider to prevent ringing with appli

32、cation of steep wave fronts and resultant high frequency iifuzzii superimposed on the voltage waveform. The resistor should be composition film type capable of 15 kilovolts and 3 watt& WC: MIX-3 has performed satisfactorily. Oscilloscopic Record Camera: Tektroniz C-27 or equivalent using Polaroid fi

33、lm 107 or equivalent. 3. OTHER SPARK ENEBGY MEASUREMENT METHODS 3.1 Simultaneous Current and Voltage Measurement: The simultaneous method of spark energy measure- ment is very valuable as 8 time eaver when used by n person well trained in tie art of energy measure- ments. Limitations exist that prec

34、lude its use in certain cases and therefore make it undesirable to tho occasional user. 3.1.1 Dual Chmel Current and Voltage Display: 3.1.1.1 The typical setup ie as depicted in Fig. 6. The current and voltage are traced simultaneously by the dunl beams of the oscilloscope. An isolation transformer

35、is required to prevent phase shift. it8 insertion cm, however, cause parasitic oscillations on the current waveform. The isolation transformer cannot be used if unipolarity discharge is being measured due to its blocking effect of the Dc current component. This method must then be used without the i

36、solation transformer and close watch kept for phase shift effect. 3.1.1.2 Most dual beam oscilloscopes are deficient in the amount and lineariiy of vertical deflection and/or tracking of tho dunl time bases. 3.1.1.3 If either phase ehift, oscillatiom or non-linearity exist, the individual method of

37、paragraph 2. should bo used. 3.1.2 Cbspwd Ditil Channel Current and Voltage Display: SAE ARP*L278 i8 = 8357340 0025503 3 1 ARP 1278 -5- I 3.1.2.1 A setup may be made as shown in Fig. 7 where a single beam oscilloscope is used with a plug-in operating in the chopped mode. This allows full deflection

38、possibilities on the screen and eliminates the deflection problems of a dual beam scope. The resulting wave form will appear as dotted traces similar to the applicable waves of Fig. 2 and 4 superimposed. 3.1.2.2 This method can be used only where the natural discharge frequency is approximated l/lOO

39、.th of the chop rate of the oscilloscope amplifier. 3.1.2.3 The phase shift and oscillation problems associated with the use of a current isolation transformer are present and may preclude. use. 3.1.3 Two Probe Isolation Current and Voltage Display: 3.1.3.1 Equipment may be set up as shown in Fig. 8

40、. This method uses matched H. V. probes in the arc voltage circuit to isolate curreht and voltage waveforms. Typically a dual beam scope is used. 3.1 3.2 The use of the two probe method allows measurement of unipolarity systems without the problems associated with the current isolation method. 3.1.3

41、.3 The H. V. probes must be very closely matched for response and kept as a pair for all measure- ments. The deflection limitations of the dual beam screen may also suggest reverting to the individual method in some cases. 3.2 Alternative methods of measuring spark energy are outlined in AR 951. 4.

42、EXCITER EVALUATION 4.1 It is often desirable to measure the discharge energy capability of an exciter unit to determine its variation from base line value. A common way this is done is to measure spark energy with a designated lead and plug. 4.2 This technique encompasses the problems of igniter arc

43、 voltage variation, multiple vendors and maintaining llstandardfl leads and plugs. These conditions can result in considerable confusion and make true quality measurements of the exciter impossible. 4.3 The discharge waveforms in this report are typical of nearly all exciter units in the following w

44、ay. The peak power is relative to peak current, time duration of power waveform is relative to current duration and spark energy is relative to current waveform. 4.4 Capacitance discharge exciters basically apply the energy stored in a capacitor at a predetermined voltage to a load including the ign

45、iter arc gap. The igniter arc gap is known to vary over rather wide limits from spark to spark or igniter to igniter. Therefore when making discharge capability measure- ments to evaluate the exciter, it is highly desirable to eliminate the igniter plug. 4.5 Short circuit discharge current from a ty

46、pical exciter varies only slightly from that when firing an igniter. It further has the characteristic of being stable from discharge to discharge. 4.6 It is recommended that short circuit current be used as a means of determining the discharge capability of capacitance dischaxge exciters. This can

47、be accomplished by making a short circuit record of an exciter that provides the desired spark energy with a complete system by replacing the igniter with a current shunt as described in 2.5.3. SAE ARP*E78 78 83573LiO 0025504 5 ARP1278 I J -6- 4.7 Tho short circuit current waveform is then 8 “finger

48、print! of the exciter and peak current, time duration, number of loops and discharge frequency become items that can be measured with repeatability PREPAFED BY SAE COMMITTEE E-30, IGNITION RESEARCH SAE ARP*L278 78 m 83573LiO O025505 7 m -7- I ARP 1218 W m O I- SA ARP*l278 78 W 8357340 00E!550b 4 ARP

49、1278 I CURRENT c, CURREN I -8- os c TIME LLATORY DISCHARGE TIME UN I POLAR I TY O I S CHARGE TYPICAL CUIIRENT DISCHARGE WAVE FORMS FIGURE 2 SAE ARP*L278 78 m 8357340 0025507 O m Y z -J W 3 o n - d 3 Y 0 U I I I 4 I I I 1 I I I I I I I -9- I O W a O Y) t - w X u m W m O t- s 3 O W W 20 WU -a =JA 0- WU rn I-Q z WW W#- w I-a 22 rr rna q 28 SAE ARPml1278 78 = 83573LiO 0025508 2 U I ARP 1278 J VOLTAGE VOLTAGE - 10 - TIME OSC I LLATORY D I SCHARGE TIME UNIPOLARITY DISCHARGE TYPICAL ARC VOLTAGE WAVE FORMS FIGURE 4 SAE ARP*1278 78 83573qO 0025507