3B Scientific Teltron Triode D, Helium-filled User Manual

Page 2

Advertising
background image

2

3. Technical data

Gas filling:

Helium

Filament voltage:

≤ 7.5 V AC/DC

Anode voltage:

max. 500 V DC max.

Anode current:

10 mA typ. at U

a

= 300 V

Grid voltage:

max. 30 V

Glass bulb:

130 mm diam. approx

Length of tube:

260 mm approx.


4. Operation

To perform experiments using the gas triode the
following equipment is also required:
1 Tube holder D

1008507

1 DC Power supply 500 V (@115 V) 1003307
or
1 DC Power supply 500 V (@230 V) 1003308
2 Analogue multimeter AM50

1003073


Additionally recommended:
Protective Adapter, 2-Pole

1009961



4.1 Setting up the tube in the tube holder

The tube should not be mounted or removed
unless all power supplies are disconnected.

Push the jaw clamp sliders on the stanchion
of the tube holder right back so that the jaws
open.

Push the bosses of the tube into the jaws.

Push the jaw clamps forward on the stan-
chions to secure the tube within the jaws.

If necessary plug the protective adapter onto
the connector sockets for the tube.


4.2 Removing the tube from the tube holder

To remove the tube, push the jaw clamps
right back again and take the tube out of the
jaws.


5. Example experiments

5.1 Discharge, evidence of positive charge

carriers

Set up the circuit as in fig. 1.

To demonstrate the existence of positive
charge carriers (He

+

ions) for gas discharge

at a maximum heater filament voltage U

F

,

measure the current I

G

taking note of the

sign.

5.2 Non-self-sustaining discharge

Set up the circuit as in fig. 2.

Record a characteristic curve of I

A

against

U

A

(= U

G

) for various filament voltages U

F

(5

V …7.5 V).

At about 25 V the anode current I

A

increases

considerably in the gas triode. This increase is
accompanied by the appearance of a blue lumi-
nescence. It is apparent that there are many
more charge carriers transporting charge than in
the vacuum triode (since there are He

+

ions as

well as thermal electrons).

5.3 Self-sustaining discharge

Set up the circuit as in fig. 3.

Gradually increase the anode voltage U

A

and determine the striking voltage U

S

for the

gas discharge.

Reduce the anode voltage U

A

again until the

self-sustaining discharge ceases. Record
this extinguishing voltage U

E

.


5.4 Simplified Franck-Hertz-set-up
Experiment for demonstrating discontinuous
energy emission resulting from inelastic colli-
sions between between electrons and helium
atoms. The electrons have to travel through a
decelerating reverse-potential field between the
grid and anode, so that they only arrive at the
anode if they possess sufficient kinetic energy.
Only then do they contribute to the current I

A

between anode and ground.

Set up the circuit as in fig. 4.

For a reverse polarity U

R

of 6 V, gradually

raise the accelerating potential U

A

from 0 V

to 70 V and measure the anode current I

A

.

Plot a graph of the anode current as a func-
tion of the accelerating voltage.

Up to an accelerating potential of about 24 V,
the anode current increases but then it drops
suddenly. As the accelerating potential is further
increased the current increases once again but
after another 20 V or so it drops again.
A plot of the anode current should exhibit two
clear maxima. If this is not perceptible, the fila-
ment voltage should be lowered somewhat.








Advertising