III. CHARACTERISTIC CURVES.

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Figure 1, Page 8, shows the variations of the candle power with the voltage, current and watts. Figure II shows the relation between candle power and the efficiency, watts per horizontal candle power, and also the variation of the candle power with the resistance.

An empirical formula for the candle power expressed as a function of the watts is cp=KWx where K is a constant of the lamp and W denotes the watts. From the curve when cp=5, watts=11.1 and when cp=15, watts=17.5 dividing

cp1/cpa=KW1x/KWax

substituting

5/15=11.1x/17.5x

and

log3+xlog11.1=xlog17.5
.4771+1.0453x=1.2430x
.198x=.4771
x=2.41

solving for the constant K

5=K11.12.41
5=332K
K=.0150

and the final equation for the candle power is

cp=.0150×w2.41

In the same way, the candle power may be expressed in terms of the voltage and this is found to be

cp=334×10-9E3.68

This formula checks precisely with the one used in the engineering department of the General Electric Company at their lamp works, Harrison, N.J.

The horizontal distribution curve of a lamp with its filament mounted as is the modern tungsten is nearly a circle. This is not true, however, in the case of vertical distribution and this curve is shown, Figure III. As will be noted, the tip candle power is only about 23 per cent of the horizontal.

Life Tests.

The results of the life tests were very surprising. The lamps upon the test under ideal conditions, namely, no vibrations and constant voltage, had only an average life of 460 hours, while every one of those upon the shock test are still burning at the present time, having been burned 300 hours. In order to make the test still more severe, the lamps were subjected to vibrations without voltage being impressed, and as yet, not a filament has broken, the total time being 400 hours. It was impossible to give more time to these lamps as was done for those under ideal conditions, for the reason it was thought unadvisable to leave the motor, which gave the vibrations, running over night.

The curves have the same general form for the two conditions but the variations are far more great for the lamps which were upon the shock test. The reason for this is that the vibrations were so severe as to shake parts of the filament together thus giving a partial short circuit, causing great variations in candle power.

Fig I
Characteristic Curves for 15 watt tungsten lamps
Lamp of average rating used

Fig II
Characteristic Curves for 15 watt tungsten lamps
Lamp of average rating used

Fig III
Vertical Distribution for 15 watt 115 volt Tungsten lamp

Life Tests
15 Watt 115 Volts Tungstens
Conditions Ideal
o—Burned Out

Life Tests
15 watt 114 volts tungsten
Shock Conditions
All lamps still Burning

                                                                                                                                                                                                                                                                                                           

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