ETC CX1174

E2V Technologies
CX1174
Deuterium-Filled Ceramic Thyratron
The data to be read in conjunction with the Hydrogen
Thyratron Preamble.
ABRIDGED DATA
Deuterium-filled tetrode thyratron with ceramic/metal
envelope, featuring low jitter, firing time and drift. Suitable for
switching high power at high pulse repetition rates or for
switching long pulses. A reservoir operating from a separate
heater supply is incorporated.
Peak forward anode voltage . . . . . .
40
kV max
Peak anode current (see Ratings) . . . . . 6.0 kA max
Average anode current . . . . . . . . 4.0
A max
GENERAL
Electrical
Cathode (connected internally to
one end of heater) . . . . . . . . .
Cathode heater voltage
. . . . . . .
Cathode heater current . . .
Reservoir heater voltage (see note
Reservoir heater current . . .
Tube heating time (minimum) .
Anode to grid 2 capacitance
.
.
1)
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
oxide coated
+ 0.3
. 6.3
V
7 0.0
40
A
. 5.0
V
10
A
15
min
40
pF
Mechanical
Seated height . . . .
Clearance required below
mounting flange . . .
Overall diameter
(mounting flange) . .
Net weight . . . . .
Mounting position (see note
Tube connections . . .
.
212.7 mm (8.375 inches) max
. . 57.15 mm (2.250 inches) min
.
152.4 mm (6.000 inches) nom
. . 3.5 kg (7 3/4 pounds) approx
2) . . . . . . . . . any
. . . . . . . . see outline
Cooling . . . . . . . . . . . liquid or forced-air
Liquid . . . . . . . . . . oil or coolant immersion
Forced-air . . . . . . . . . . . . . . see below
Cooling by oil or coolant immersion is preferred in view of the
high voltages present. Further information is contained in the
relevant section of the Preamble.
The tube may be cooled by forced-air directed mainly onto the
base, and the metal/ceramic envelope should be maintained
below the maximum rated temperature. An air flow of at least
2.83 m3/min (100 ft3/min), depending on the mechanical
layout, will be necessary to keep the tube operating
temperatures under the limits specified below.
In addition to 300 W of heater power, the tube dissipates from
100 W per ampere average anode current, rising to 300 W/A at
the highest rates of rise and fall of anode current.
The cathode end of the tube must be cooled whenever heater
voltages are applied, since the cathode flange will reach a
temperature of 120 8C above ambient in the absence of cooling.
Envelope temperature:
ceramic, anode and grid . . . . . . 150
8C max
cathode flange and base . . . . . . 120
8C max
E2V Technologies Limited, Waterhouse Lane, Chelmsford, Essex CM1 2QU England Telephone: +44 (0)1245 493493 Facsimile: +44 (0)1245 492492
e-mail: [email protected] Internet: www.e2vtechnologies.com
Holding Company: Redwood 2002 Limited
E2V Technologies Inc. 4 Westchester Plaza, PO Box 1482, Elmsford, NY10523-1482 USA Telephone: (914) 592-6050 Facsimile: (914) 592-5148
e-mail: [email protected]
# E2V Technologies Limited 2002
A1A-CX1174 Issue 5, October 2002
527/5630
MAXIMUM AND MINIMUM RATINGS
Environmental
These ratings cannot necessarily be used simultaneously, and
no individual rating must be exceeded.
Min Typical Max
Ambient temperature . . . . . . 750
Altitude . . . . . . . . . . . –
–
Anode (Pulse Modulator Service)
Peak forward anode voltage
(see note 3) . . . . .
Peak inverse anode voltage
(see note 4) . . . . .
Peak anode current . . .
Peak anode current (pulse
repetition rate limited
to 60 pps max) . . . .
Average anode current . .
Rate of rise of anode current
(see notes 5 and 6) . . .
Pulse repetition rate
(see note 7) . . . . .
. . –
8C
km
ft
CHARACTERISTICS
–
. . –
. . –
+90
3
10 000
40
–
6.0
35
–
8.0
4.0
Min Typical Max
kV
kV
kA
. . –
. . –
–
–
kA
A
. . –
10
–
kA/ms
. . –
400
–
pps
Min
Max
Critical DC anode voltage for
conduction (see note 12) .
Anode delay time
(see notes 12 and 13) . .
Anode delay time drift
(see notes 12 and 14) . .
Time jitter (see note 12) . .
Recovery time . . . . .
Cathode heater current
(at 6.3 V) . . . . . .
Reservoir heater current
(at 5.0 V) . . . . . .
. . –
0.5
1.0
kV
. . –
0.1
0.25
ms
. . –
15
50
ns
. . –
1.0
5.0
ns
. . . . . . . see note 7
.
35
. . 8.0
40
45
A
10
12
A
Anode (Single Shot, see note 8)
DC forward anode voltage .
Peak anode current . . .
Rate of rise of anode current
Total conducted charge:
capacitor discharge . .
power supply follow-on .
Repetition frequency . . .
. . . . –
30
kV
. . . . –
40
kA
. . . . . . . see note 5
. . . . –
0.4
C
. . . . –
18
C
. . . . 1 pulse per 10 s max
Grid 2
Unloaded grid 2 drive pulse
(see note 9) . . . .
Grid 2 pulse duration . .
Rate of rise of grid 2 pulse
(see note 6) . . . .
Grid 2 pulse delay . . .
Peak inverse grid 2 voltage
Loaded grid 2 bias voltage
Forward impedance of
grid 2 drive circuit . .
voltage
. . . . 500
. . . . . 0.5
.
.
.
.
.
.
.
.
.
.
.
.
2000
–
V
ms
.
10
–
kV/ms
. . 0.5
3.0
ms
. . –
450
V
. 750 7180
V
. . . .
50
500
O
1000
–
V
ms
Grid 1 – Pulsed
Unloaded grid 1 drive pulse
(see note 9) . . . .
Grid 1 pulse duration . .
Rate of rise of grid 1 pulse
(see note 6) . . . .
Peak inverse grid 1 voltage
Loaded grid 1 bias voltage
Peak grid 1 drive current
voltage
. . . . 400
. . . . . 2.0
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
. 1.0
–
kV/ms
. –
450
V
. . . . see note 10
. 0.5
1.5
A
Grid 1 – DC Primed (See note 11)
DC grid 1 unloaded priming voltage .
DC grid 1 priming current . . . .
75
75
150
150
V
mA
Cathode
Heater voltage . . . . . . . . .
Heating time
. . . . . . . .
6.3
15
+ 0.3
7 0.0
–
V
min
Reservoir
Heater voltage (see note 1) . . . . . 4.5
Heating time
. . . . . . . .
15
CX1174, page 2
6.5
–
NOTES
1. The reservoir heater must be decoupled with a suitable
capacitor to avoid damage by spike voltages. The
recommended reservoir heater voltage for each individual
tube is stamped on the tube envelope. This recommended
value is determined for hold-off at the maximum anode
voltage under DC conditions. For lower voltages and
modulator operation the reservoir heater voltage should be
increased to a value consistent with voltage hold-off at the
operating level. Maximum reservoir voltage (i.e. maximum
gas pressure in the tube) is one prerequisite for maximum
thyratron life. The reservoir voltage should be stabilised to
+ 0.05 V.
2. The tube must be mounted by means of its mounting
flange.
3. Under resonant charging conditions a maximum anode
voltage of 35 kV is recommended. Using command
charging techniques, where the voltage appears at the
anode for only a short time (51 ms), this thyratron may be
operated at up to 40 kV.
4. The peak inverse voltage including spike must not exceed
10 kV for the first 25 ms after the anode pulse. Amplitude
and rate of rise of inverse voltage contribute greatly to tube
dissipation and electrode damage; if these are not
minimised in the circuit, tube life will be shortened
considerably. The aim should be for an inverse voltage of
3 – 5 kV peak with a rise time of 0.5 ms.
5. For single-shot or burst mode applications this parameter
can exceed 150 kA/ms. The ultimate value which can be
attained depends to a large extent upon the external
circuit.
6. This rate of rise refers to that part of the leading edge of
the pulse between 25% and 75% of the pulse amplitude.
7. This thyratron has a long recovery time (50 – 100 ms). The
amount of time available for thyratron recovery must be
maximised by circuit design, and reliable operation may
necessitate the use of command charging techniques. The
amount of time required for recovery is affected by gas
pressure, peak current, pulse duration and load mismatch
which keeps the thyratron in a conducting state.
V
min
# E2V Technologies
8. Under fault conditions most of the coulombs are often in
the power supply follow-on current, rather than the storage
capacitor discharge.
9. Measured with respect to cathode. Pre-pulsing of grid 1 is
recommended for modulator and high rate of rise
applications. The last 0.25 ms of the top of the grid 1 pulse
must overlap the corresponding first 0.25 ms of the top of
the delayed grid 2 pulse.
10. DC negative bias voltages must not be applied to grid 1.
When grid 1 is pulse driven, the potential of grid 1 may
vary between 710 and +5 V with respect to cathode
potential during the period between the completion of
recovery and the commencement of the succeeding grid
pulse.
11. When DC priming is used on grid 1, a negative bias of 100
to 180 V must be applied to grid 2 to ensure anode voltage
hold-off. Also the higher grid 1 is pulsed, the larger the grid
2 negative bias must be to prevent the tube firing on the
grid 1 pulse.
12. Typical figures are obtained on test using conditions of
minimum grid drive. Improved performance can be
expected by increasing grid drive.
13. The time interval between the instant at which the rising
unloaded grid 2 pulse reaches 25% of its pulse amplitude
and the instant when anode conduction takes places.
14. The drift in delay time over a period from 10 seconds to
10 minutes after reaching full voltage.
SCHEMATIC DIAGRAM
6890A
GRID 2 DELAYED
WITH RESPECT TO GRID 1
GRID 2 VOLTAGE
500 – 2000 V,
1 ms
G2
G1
CATHODE
HEATER
SUPPLY
R2
R1
C1
0
NEGATIVE BIAS VOLTAGE
GRID 1 CURRENT
0.5 – 1.5 A,
2 ms
0.5 ms MIN
GRID 1/GRID 2 DELAY
RESERVOIR
HEATER
SUPPLY
C2
(VARIABLE)
RECOMMENDED GRID, CATHODE AND RESERVOIR HEATER CONNECTIONS
R1
=
Grid 1 series resistor. 12 W vitreous enamelled wirewound is recommended, of a total impedance to match the grid 1
drive pulse circuit.
R2
=
Grid 2 series resistor. 12 W vitreous enamelled wirewound is recommended, of an impedance to match the grid 2 drive
pulse circuit.
C1, C2 7
reservoir protection capacitors with a voltage rating 5500 V;
C1 =
1000 pF low inductance (e.g. ceramic),
C2 =
1 mF (e.g. polycarbonate or polypropylene).
Components R1, R2, C1 and C2 should be mounted as close to the tube as possible.
# E2V Technologies
CX1174, page 3
OUTLINE
(All dimensions without limits are nominal)
1C
2185D
ANODE CONNECTION
FITTED WITH
/4-20 UNC SCREW
1
GRID 2 CONNECTION
FITTED WITH
8–32 UNC SCREW
A
L
D
Ref
Millimetres
Inches
A
B
C
D
F
G
H
J
K
L
212.7 max
152.4
147.0
3.18
106.3 max
177.8 min
6.35
8.0
135.7
117.35
8.375 max
6.000
5.787
0.125
4.187 max
7.000 min
0.250
0.315
5.344
4.620
Inch dimensions have been derived from millimetres.
MOUNTING FLANGE
SEE NOTE 1
SEE NOTE 2
Outline Notes
1F
SEE NOTE 3
GRID 1 LEAD (GREEN)
G LONG, TAG TO SUIT 1H
RESERVOIR HEATER LEAD (RED)
G LONG, TAG TO SUIT 1H
1. The mounting flange is the connection for the
cathode, cathode heater return and reservoir
heater return.
2. A minimum clearance of 57.15 mm (2.250 inches)
must be allowed below the mounting flange.
3. The recommended mounting hole is 108 mm
(4.250 inches) diameter.
1B
4 MOUNTING HOLES 1J
EQUISPACED ON K PCD
CATHODE HEATER LEAD (YELLOW)
G LONG, TAG TO SUIT 1H
HEALTH AND SAFETY HAZARDS
E2V Technologies hydrogen thyratrons are safe to handle and
operate, provided that the relevant precautions stated herein are
observed. E2V Technologies does not accept responsibility for
damage or injury resulting from the use of electronic devices it
produces. Equipment manufacturers and users must ensure that
adequate precautions are taken. Appropriate warning labels and
notices must be provided on equipments incorporating E2V
Technologies devices and in operating manuals.
High Voltage
Equipment must be designed so that personnel cannot come
into contact with high voltage circuits. All high voltage circuits
and terminals must be enclosed and fail-safe interlock switches
must be fitted to disconnect the primary power supply and
discharge all high voltage capacitors and other stored charges
before allowing access. Interlock switches must not be
bypassed to allow operation with access doors open.
X-Ray Radiation
All high voltage devices produce X-rays during operation and
may require shielding. The X-ray radiation from hydrogen
thyratrons is usually reduced to a safe level by enclosing the
equipment or shielding the thyratron with at least 1.6 mm
( 1/16 inch) thick steel panels.
Users and equipment manufacturers must check the radiation
level under their maximum operating conditions.
Whilst E2V Technologies has taken care to ensure the accuracy of the information contained herein it accepts no responsibility for the consequences of any use
thereof and also reserves the right to change the specification of goods without notice. E2V Technologies accepts no liability beyond that set out in its standard
conditions of sale in respect of infringement of third party patents arising from the use of tubes or other devices in accordance with information contained herein.
CX1174, page 4
Printed in England
# E2V Technologies