3B Scientific Teltron Diode D User Manual

3B SCIENTIFIC

Instruction sheet

08/12 ALF

6

5

®

PHYSICS

Diode D 1000646

4

21

3

1 4-mm plug for connect-

ing anode
2 .Anode
3 Boss
4 Cathode filament
5 Filament backing plate
6 4-mm sockets for

cathode and filament

3

1. Safety instructions

Hot cathode tubes are thin-walled, highly
evacuated glass tubes. Treat them carefully as
there is a risk of implosion.

• Do not subject the tube to mechanical

stresses.

• Do not subject the connection leads to any

tension.

• The tube may only be used with tube holder

D (1008507).

If voltage or current is too high or the cathode is
at the wrong temperature, it can lead to the tube
becoming destroyed.

• Do not exceed the stated operating parameters.

When the tube is in operation, the terminals of
the tube may be at high voltages with which it is
dangerous to come into contact.

• Only change circuits with power supply

equipment switched off.

• Only exchange tubes with power supply

equipment switched off.

When the tube is in operation, the stock of the
tube may get hot.

• Allow the tube to cool before dismantling.

The compliance with the EC directive on elec­tromagnetic compatibility is only guaranteed
when using the recommended power supplies.

2. Description

The diode allows basic experiments to be per­formed on the Edison effect (thermionic effect),
demonstrates how the emission current de­pends on the power supplied to heat the hot
cathode, allows recording diode characteristics
and shows the use of the diode as a rectifier.
The diode is a highly evacuated tube with a pure
tungsten heater filament (cathode) and a circular
metal plate (anode) inside a clear glass bulb.
The cathode filament and the anode plate are
parallel to one another. This planar configuration
corresponds to the conventional symbol for a
diode. A circular metal plate is attached to one
of the filament leads. This ensures that the elec­tric field between the anode and cathode is uni­form.

1

3 Technical data

Filament voltage: ≤ 7.5 V
Filament current:

≤ 3 A approx.

Anode voltage: max. 500 V
Anode current: 2.5 mA typical

at U

= 300 V,

A

U

= 6.3 V DC

F

Length of tube: 300 mm approx.
Diameter: 130 mm approx.
Distance between

cathode and anode: 15 mm approx.

4. Operation

To perform experiments using the diode, the
following equipment is additionally required:

1 Tube holder D 1008507
1 DC power supply 500 V (@230 V) 1003308

or
1 DC power supply 500 V (@115 V) 1003307

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. Sample experiments

5.1 Generation of charge carriers by a hot
cathode (thermionic effect) and meas­urement of the anode current in depend­ency on the power supplied to the cath­ode filament

Additionally required:
1 Analogue multimeter AM50 1003073

• Set up the circuit as in Fig. 1. Connect the

minus-pole of the anode voltage to the 4­mm socket marked with a minus.

• Start with the filament cold (filament voltage

U

= 0).

F

• Vary the anode voltage U

between 0 and

A

300 V.

Practically no current (< 0.1 µA) flows between
the cathode filament and the anode, even at
high voltages.

• Apply 6 V to the filament so that it gets hot,

gradually increase the anode voltage and

measure the anode current I

• Set the filament voltage back to zero, let it

.

A

cool, then gradually increase the filament
voltage with a fixed anode voltage and ob­serve the effect on the anode current.

When the filament voltage is fixed, the anode
current increases in proportion to the anode
voltage.

With the anode voltage fixed, the anode current
increases in proportion to the filament voltage.

5.2 Recording diode characteristics

• Set up the circuit as in Fig. 1. Connect the

minus-pole of the anode voltage to the 4­mm socket marked with a minus.

• Set filament voltages of 4.5 V, 5 V and

6 V.

• Determine how the anode current I

pends on the anode voltage U

for each of

A

de-

A

the filament voltages by raising the anode
voltage step by step from 40 V to 300 V.

• Plot the values of I

and U

A

on a graph.

A

With increasing the anode voltage the anode
current rises to an approximately steady value
known as the saturation current.

With increasing the filament voltage the anode
current rises.

5.3 Diode rectifier

Additionally required:
1 10 kΩ resistor
1 power supply for 16 V AC
1 oscilloscope

• Set up the circuit as in Fig. 3 with U

and U

• Using an oscilloscope to measure the volt-

= 16 V AC

A

= 6.3 V

F

age across the 10 kΩ resistor, observe the
rectifier operation of the diode

When the anode circuit operates as a diode, an
AC voltage is rectified in that during one half of
the current waveform the current is prevented
from flowing.

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