ELECTRON-BEAM WELDING OF 500~MHz ACCELERATION RESOiATORS ....
The structure's weight thereby could also be reduced a great deal. The single.
!
ELECTRON-BEAM WELDINGOF 500~MHzACCELERATION RESOiATORS
ELEKTR~NENSTRAHLSCHWEI~SEN
voN
500-MHZ-BESCHLEUNIGUNGSRESONATOREN
i ____-_.._._^. -____-I____
__--___-----.-.---._-.--
H,
::
‘.(E)‘* If Ti
---. ----..----_
HARTWIG,
KOUPTSIDIS,
K,
REINECKEN
UNKNOWN
STANFORD LINEAR ACCELERATORCENTER Stanford,
J,
-.----_ - -___~---_--.~_-.-- .._. - _._______._- .^_....
California
ADDIS TRANSLATlONS IiVTERNATIONAL 3220 alpine road pork-h valley, cdifornia 94025 (415) 854-6732
1. Introduction The discovery
of new elementary
storage
(1) at the German Electron
rings
burg
and at the Stanford
U.S.
demonstrates
the
elementary-particle Besides
the
two linear
into
Accelerator
Center
importance
of these
instruments
accelerators
tubes
at an energy
are recorded these
the
in modern
R.F.
storage
1973.
can be stored
circumference.
machines
diagrammatically
R.F.
SLAC in
ring
In this and brought
up to 2 x 5 GeV in two separate
collision All
the double
the end of
and positrons
300 m in
detectors. trated
since
approximately
of this
DESY in Ham-
(40 and 300 MeV) and the
at DESY in Hamburg,
electrons
collision
Synchrotron
Linear
DORIS has been in operation ring,
by the use of electron
research.
7 GeV synchrotron
storage
particles
The reaction
and investigated
by sensitive
on the
tract
in Figure
DESY land
vacuum products
are illus-
1.
structure
structure
Figure 1. Diagrammatic illustration of all accelerator installations on the DESY land tract.
PE.TRA
1
Experimental
results
shown that tially
it
is
higher
necessary
expansion
stage
into
collision
long
for
lifetime
of 100 MV is resonators
stored
electrons
and positrons
in two straight
To keep the
total
costs
grammatically
with
coupled
the
will
drift
preferred
2.
The structure sections (3). 2
energy
of and
by radia-
arc of
the
of
this
320 R.F.
of the
storage
system
losses
raising
of
is
the ring.
the
expansion the
a voltage
DORIS storage
first
ring.
ensure
voltage,
stored
stage.
coupling
resonators
be required.
resonators
first
accelerating
energy
acceleration
5 coupled
in Figure
therefore
the
pieces
low and without
64 such resonators
a structure
the
4 MW for
5-cell
substantially, of
into
and in the
to cover is
In the
was
2 x 19 GeV.
accelerating
The 500 MHz frequency
1).
Facility]
and simultaneously
For this
are provided
power required
and is
the
a circumference
the beam, a radio-frequency
The R.F.
inductively
substan-
can be stored
up to
pass
losses
same as in the DESY synchrotron
for
have
reason,
in PETRA lose
as they
energy
necessary.
(Figure
having
at an energy
light
these
ring
and positrons
and positrons
synchrotron
A total
with
For that
to DORIS (2).
storage
electrons
To compensate
losses
rings
rings
Tandem Ring Accelerator
of this l),
The electrons
ring
storage
energies.
1974 as a supplement
2304 m (Figure
of
storage
of PETRA (Positron-Elektron-Tandem-Eingbeschleuniger-
in
brought
electron
to build
[Positron-Electron
proposed
tion
existing
stored-particle
construction Anlage)
from
are proposed.
Two alternatives
are illustrated in Figure
is more economical
dia-
2a with in operation
Acceleration section: Driftsection structure with inductive
WI
I w I
i Acceleration with coupling
section:
via
Iris structure electric field
the
Figure a) Diagrammatic illustration section structure b) Diagrammatic illustration structure 2. Engineering The diameter structure's
requirements: of
the
resonance
A cell
length
is
in the middle
fed
detuning
accelerator
is
range and for
over is
drift-
of
iris
a five-cell
the primary
factor
It
is
ca.
selected.
with ca.
of a five-cell
techniques
frequency.
cell
2
fabrication
X/2 = 300 mm is
and can be detuned This
cells
i
400 mm for
The five-cell
a maximum R.F.
1 MHz by means of
provided
mainly
compensation
of 3
determining
for
frequency
the
power of two tuning operation variations
the
500 MHz. structure 125 kW elements. of the due to
radiation is
exposure
required
during
in measuring
fabrication.
diameters During
operation
outside of the
can rise
tuning
structure
The ultrahigh storage
likewise of
Ncm3/s.cm2
order that
range
water
might
occur.
tight
jumps from
The surface
conductivity
greatly
affects
structure. of
condition in regions
the
With
13 MR/m of
structure
the
combined of high
structure cells'
loading
of the
frequency
drifts
rises,
the drift
good cooling
disks of the
without
is
necessary.
resonator
and
cooling.
For
exhaust gas rate (2, 4 *. QD \< 10 -9 Ncm3/s Welds
and vacuum must be avoided localization
and repair
must be heatable
to ultrahigh
of
to
in leaks
at least
vacuum in the
event
of
15OOC to 3OOC. and roughness
impedance
a smooth structure with
the
we have:
The structure
temperature
To avoid
be realized
a fast
15OOC and must remain
thermal
conditions
channels
to make possible
on the
the
of
and leaktightness
cooling
tolerances
due to temperature
cannot
the
of
accuracy
mm.
25 kW.
vacuum operating
ring
between
to
high
dimensions the
20.15
and especially
components
lo-lo
range
Accordingly,
critical
at maximum power,
cells the
the
effects.
For example,
are in the
individual
all
and thermal
and thus
copper
of the
surface,
the R.F.
field-strengths
cooling in order
duction
surface
losses
in the
a maximum impedance
can be achieved
intensive
inner
(3). is
A good surface
required to prevent
especially the pro-
of a multipactor plasma there due to field emission and 1 cm3 under * Tr. note: Ncm3 is that amount of gas which occupies "standard conditions" of O°C and 760 Torr. 4
secondary
emission
Heretofore, by the
(4).
acceleration
electroforming
method
can be fabricated highest-grade realized mally
with
easily
for
ration
the
methods times
seams with
with
minimal
the material.
it
thermal
This
relatively
facilities
weldment
out
of the
OFHC * copper
a relatively * Tr.
note:
high
the
This
conductivity
OFHC = oxygen-free
to achieve
costs
for
very
that good weld
distortion
so that
structure
of
developed
and
the welding
in existing
preliminary welding
unit
tests and a
was proposed. was selected
to OFHC copper, alloy
which
is
as
the use of
can be welded
high-conductivity 5
would
of PETRA accele-
was chosen
conductivity
Parallel
it
fabrication
series
10 years,
electrical
opti-
the PETPA accelera-
has been further
structure
is
be
work was to investigate
Accordingly,
was examined.
good thermal
of
and minimal
an electron-beam
material.
alloy
possible
acceleration
acceleration
with
fabricating
AlMgSi0.5
with
series,
welding
in the past
large
of a small
large
method
can also method
to reduce
loading
can be performed.
were carried
the
is
welding
has become widespread of the
it
structures from
this
the present
relatively
the
electrolytically
costs
Electron-beam
because
method,
Although
in order
preferably
water-cooling
fabrication
of the
structures.
purpose
method.
The aim of
new fabrication and delivery
accuracy
the production
raise
structures.
By this
An intensive
by this
applicable
were fabricated
(5).
higher
copper.
substantially tion
resonators
required
well,
has
to cool
the
and can be readily
structure,
weight
thereby
drawback, could
i.e.
could
also
lower
electrical
be obviated
lytically
The proposed ported
a great
conductivity the
The single
deal.
compared
inner
surface
to copper, electro-
sputtering.
weldment
in the
be reduced
by copper-plating
or by d.c.
The structure's
machined.
and the welding
results
achieved
are re-
following.
3. Weldment Figure for
3 shows the weldment The disks
PETRA.
welded
together
The disks
of
machined disk
must
undesired would
weld
This
for
greater
and weld
These weld problems,
sections
of
the
resonator
cavity.
are made from
operation
of
5-10 W/cm2.
as close
as possible
requirement
would
great
rounds
effort
and
of the
and for
the
Therefore, to the
lead
vacuum and water
with
forged
temperatures
1OOOC during load
structure
are electron-beam
The surface
seams between only
acceleration
a good
inner
sur-
unavoidably channels,
by taking
to
which apart
the
structure.
Therefore, of bores
than
the disk
be repairable
acceleration
rings
thermal
necessary.
drift
shape.
lower
of
a 5-cell
sections
final
remain
water-cooling is
the
the drift
maximum occurring
face
of the
with
to the
of
seams on the
seams are readily since
water
safety,
they
outside
repairable
need only
cooling (Figure
the
disk
by means
4) was proposed.
and present
be water-tight 6
of
(test
no special pressure
=
9 bar)
after
proposed fully
several
cooling
adequate
thermal
suffices for
a copper
shocks
for
from
a disk disk
15OOC to
30°C.
made of AlMgSi0.5
due to the better
The and is
thermal
con-
ductivity.
b%Nhdb*X
Detail
sdur’n
scfdf*-B bVLI1,
c-o
Section
C-D
EzizalhdbwI
‘Detail.
Neldment structure.
7
X
-
Section A&B (onZy .?,!
Figure 3 of a five-cell
at
PETFW acceleration
at Y --i
s&at
CD
Sbction L CD '.
CAVITY-DISK Figure 4 W a ter cooling of the drift-section The rings
of the
resonator
forged
part
rolled
to a circle.
beam weld
with
the neck for
required
for
would make the alteration square the
water
final
chosen, tially
of
the
here
thermal
by using
since
(especially
loading
eutectic
and phosphorus-containing
of
welding copper
8
welded
surface. the
ring
ring
material filler
inert
amounts of
a copper
weldment)
difficult
For cooling
are electron-beam inner
by two electron-
large
for
of the
properties.
the
the
the
due to ring,
or TIG welded When a TIG weld
can be reduced (AlSill metal
for
a
and a sheet
A TIG [tungsten
machining
the metal's
of
flange
are connected
also,
method
subsequent
machining
the lateral
longitudinally.
with that
pipes
are made from two parts:
The two parts
seams executed
weld was dispensed heat
cavity
disk.
for
before is
substanAlMgSi0.5
copper).
Only
gas]
a good thermal
contact
required
for
The most
difficult
disks
these
since
the entire
that
all
addition,
for
residues
that
formation can
of
4. Preliminary Preliminary welding parts
two welded
the
disk
welding unit
with
operating
pumps.
beam gun with maximum current rotationally equipped
the
tests
static
root
is
filled
up in
can be removed. must
In
be as smooth
Therefore,
as
it
was
as in Figure
separating
line
3:
prevents
due to a 30'
the
inclination,
pockets.
of
range
with
an electron-beam
company in Hamburg on lo-mm-thick and AlMgSiO.5
The unit's
alloy.
2.6 x 2.6 x 2.6 m could reach -4 mbar within 10 minutes of 10
The built-in
60 mA.
(but
and dynamic
relocatable)
voltage
The welded
and longitudinally with
root
were performed
a maximum operating of
between
For vacuum-related
which,
gas
weld
and results
dimensions
of diffusion
is
of the weld
be prepared
root
at an aircraft
pressure
final
or holes.
parts
beneath
made of OFHC copper
tainer
the
forming
tests
the
agents
no drops
the
without
3).
cleaning
an uncontrolled
now appear
by
machining
(Figure
frequencies
proposed
of
presented
gap must be completely
of
and must exhibit
The offset
is
there
possible
or tightness
welds.
welding
radio
strength
a post-weld
impossible
reasons, order
braze problem
and rings,
practically
and no high
parts
by jigs. deflection
of
conthe by means
electron-
150 kV supplied could
The unit of
the
be moved was also beam.
a
Macrosections
of weld
are illustrated unit
seams obtained
in Figure
are compiled
in Table
5.
on copper
The associated
and AlMgSiO.5 data
for
the welding
1.
b)
4
Figure 5 Macrosections of electron-beam weld on copper (a) and AlMgSi0.5 (b). Parameter Sheet thickness Beam voltage Beam current Focal point Welding speed Wagging form Wagging frequency Wagging direction Wagging amplitude
seams
OFHC copper 10 mm 150 kV 52 mA -100 mm 9.7 mm/s i-u 400 Hz Parallel to the seam 2mm
Table 1 Choice of parameters for electron-beam welding of lo-mm-thick OFHC copper and AlMgSi0.5 alloy.
10
AlMgSi0.5 10 mm 120 kV 34 mA 0 31 mm/s AM 2 kHz Parallel to the seam 2mm
The copper bath
parts
before
were pickled
welding
and rinsed
AlMgSiO.5
parts,
machining
and subsequent
For the
the best
copper
beam would In both along All
of
the
rather weld
than
welds
best
By the middle acceleration
of
structures
with
R.F.
a dry
only
of the
with
electron
surface. by wagging
the beam
seam.
and withstood
several
heatings
treatments.
two aluminum
1976,
point
the weld
(6) the weld
shock
For the
weld was possible
were achieved
seams were vacuum-tight
after
pickling
(6).
The focal
results
acid
water.
were obtained
degreasing
across
nitric
deionized
100 mm below
to 15OOC and subsequent
tested
with
the beam.
have to lie
cases,
the usual
a lo-mm-deep
parts,
an underfocussing
with
prototypes
are to be fabricated
of
the
by this
PETRA method
and
power.
Acknowledgements The authors
are indebted
discussions
and suggestions
Boernsen
and W. Mcller
H. Gerke for
to Mister
for
and to Messrs. performing
the
clarifying
G. Benedetti, trial
P.
welds.
References (1) Science: Charm.
The New Particle Science,
(2) PETRA Proposal,
Mystery:
189 (19751, German Electron
(1974). 11
pp.
Solid
Clues
Now Lead to
443-445. Synchrotron
DESY, Hamburg
(3) Gerke,
H.,
(4) Priest,
communication.
Multipactor
D.H.:
high-power cf.
private
microwave
effects
and their
Microwave
tubes.
prevention
Jour.,
in
10 (1963)
55.
(5) Gerke,
H. and W. Quarz:
double-ring
storage
Cavity
resonators Kerntechnik
system.
for
a 3 GeV
5 (1974)
pp.
246-
251. (6) Sanderson, weldability 4 (1972)
A., of 7, pp.
A.N. three
Taylor
and R.J.
aluminum
250-255.
12
alloys.
Stearn: Metal
Electron-beam Construction
