Ap1_02.vp


1 Introduction
Cyclotron – produced 81Rb (T1/2 = 4.58 H) and its daugh-

ter 81mKr (T1/2 = 13.3 s) constitute a radionuclide generator
for nuclear medicine used as a common tool for lung ventila-
tion studies. The main advantages of this generator are the
good imaging properties of 81mKr and the low radiation
dose in tissue. Because demand for such a system exists,
it was decided to develop an appropriate target and ra-
diopharmaceutical assemblies. These considerations led to
a project to make an apparatus for producing radionuclide

37Rb
81.

The authors have experience in constructing and operat-
ing of filling and recycling apparatus for production of 123I on
electron accelerators [1], [2] for gaseous Xe targets (natural
xenon and xenon enriched by 124Xe). The distinctive charac-
ter of these apparatuses is the irradiation of gaseous targets in
the proximity of the critical point of Xe to guarantee high ef-
fectiveness and reproducible yield of 123I from (�, n) reaction
during irradiation of 124Xe.

By contrast, cyclotron targets work at lower pressure,
resulting from the reaction conditions of protons with the
target material, i.e., from the „square density” parameter and
necessary loss of energy for a given reaction channel, e.g.,

� �36
82

37
81 4 58

36
81 13 32 1 2

1 2
Kr p n Rb Kr

T h m T h

E
, .

. .� �
� ������

� �C E keV, . % .� �190 3 67

For a thick target and proton energy EP = (29 �23) MeV the
yield is about 48 mCi/(�A�h).

When working with expensive krypton, highly enriched in
one of its isotopes, it is necessary to ensure multiple recycling
without significant losses and pollution of the gas.

The recycling of the gas in the apparatus is achieved by
cryogenic pumping at the temperature of liquid nitrogen. Be-
fore the gas transfer, the transport volume of the apparatus
must be evacuated to about 10�2 Pa. The pressure of gas va-
pors at liquid nitrogen temperature for Kr is 133 Pa, which is
three orders of magnitude higher than for Xe (0.1 Pa). To
reduce the losses of Kr gas per one pumping cycle, the vapor
pressure must be reduced by using a suitable solid adsorbent
within the pumped volume.

A diagram of the apparatus is schematically shown in
Fig. 1. For completeness, the radiochemical, drying and tar-
get tube subsystems, which were made in the NPI of CAS,
are indicated in gray. Fig. 2 illustrates the apparatus in devel-
opment.

Fig. 1 shows the apparatus together with the radioche-
mical, drying and target tube subsystems, made in the NPI
of CAS.

The scheme is much more complicated than the appara-
tus in [1] and [3]. This is due partly to the need to use molecu-
lar sieves, partly to satisfy the requirement that it should be
possible to automate the process with the use of a PC and
RS 232 interface.

©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/ 3

Acta Polytechnica Vol. 41  No. 2/2001

Filling and Recycling Apparatus of
a Cyclotron Target with Enriched

Krypton for Production of
Radiopharmaceuticals

M. Vognar, M. Fišer, Č. Šimáně, D. Chvátil

An apparatus for multiple filling of a cyclotron target with enriched Kr gas is described. The system is based on recycling pressurized gas by
cryogenic pumping between the target tube and storage containers. The design and construction makes use of previous experience in the
construction and operation of two analogue apparatuses for Xe124 high pressure gas targets, but major modifications have been
incorporated, evoked by the different physical properties of Kr, by the character of the nuclear reaction, and by the demand for automation
from the side of the end user.

Keywords: generator, Kr gas target, 36K
82(p, 2n) 37Rb

81 reaction.

� � � �EC 67 27% , %�
�

Fig. 1: Scheme of the filling and recycling apparatus:
DP – diaphragm vacuum pump, TMP – turbomolecular
vacuum pump, C1 – working container, C2 – storage
container, MS – molecular sieve, C3 – intermediate high
pressure container (Kr trap), D1 to D3 – Dewar flasks,
LN – liquid nitrogen, F – microfilter, V1 to V13 - valves,
RV1, RV2 – pressure reduction valves, VV – venting valve,
FI – first filling inlet fitting, H1 and H2 – container
thermocoax heating elements, PiM – Pirani vacuum
gauge, PeM – Penning vacuum gauge, PT1 to PT3 – pres-
sure transducers, M1 – manometer, T1, T2 –thermocoax
thermocouples for measuring of the gas temperature,
NLS1 to NLS3 – liquid nitrogen level sensors, NBS1 and
NBS3 – sensors for control nitrogen boiling, NBH1 and
NBH3 – heaters for boiling out liquid nitrogen, FV1,
FV2 – filling volumes



2 Description of the apparatus
The pumping system consists of a diaphragm vacuum

pump DP and a turbomolecular pump TMP, which can be
separated from the rest of the apparatus by the valve V0. To
prevent the transfer of mechanical vibrations from the dia-
phragm pump to the turbomolecular pump, the former is
suspended on spiral springs on a separate stand and con-
nected with the turbomolecular pump, mounted on the main
stand, by a bellow hose provided with additional damping.

The complete filling and recycling apparatus consists of
working pressure container C1, storage container C2, high
pressure intermediate container C3 (Kr trap), high pressure
and vacuum tight, pneumatically actuated high pressure bel-
low valves V0 to V6, an electrically controlled pressure air
distribution system to the valves, pressure transducers PT1 to
PT3, and Penning type PeM and Pirani type PiM vacuum
gauges. The system is mounted together with the correspond-
ing armatures and tubing on the supporting plate on the
main stand. The apparatus is accessible for the first filling by
the fitting F1, which is permanently all time blinded during
operation. For the connection with the target, the other end
of the apparatus is provided with a tube coupling of Ultraseal
type for evacuation and with two Swagelock couplings for
filling the target from the intermediate container and for
chemical treatment of the product.

The stainless steel Dewar flasks for freezing the gas in con-
tainers C1 and C2 are mounted on an auxiliary plate on the

main stand. The Dewar flask D3 for freezing the gas in the
intermediate container C3 is suspended on the main sup-
porting plate.

The thermocouples NLS1 to NLS3, for sensing the liquid
nitrogen level in the Dewar flask during automatic filling and
refilling, are fixed on Dewar flasks D1 to D3 as well as the
thermocouples NBS1 and NBS3 for control of boiling out the
nitrogen in Dewar flasks D1 and D3.

Containers C1 and C2 are provided with thermocoax
heating elements H1 and H2 wound in spiral grooves on the
outer surfaces. The resistance of the heating elements is
approx. 6 ohms, and the heating power is 150 W. The surface
temperature of the containers is measured by thermo-
coax thermocouples T1 and T2, wound along the heating
elements in several grooves and connected to two-level com-
parators. The working temperature is stabilized at 320 °C. In
the event of accidental overheating the comparators automat-
ically switch off the heaters at 350 °C. Restarting must be done
manually.

The pressure of the gas in the containers during heating
and transfer is controlled by pressure transducers PT1 to PT3,
which are high vacuum tight and work up to 20 MPa. Pressure
transducer PT3 indicates the pressure of the gas in the target,
when valves V5 and V3 are closed.

Heating elements NBH1 to NBH3 (4 ohm resistor wire),
for quick removal of liquid nitrogen by boiling it out, are
installed on the bottom in Dewar flasks D1 and D3. The
heating power in the presence of liquid nitrogen in the
flask is 145 W. When the nitrogen has been boiled out and
the temperature, as measured by thermocouples NBS1 and
NBS3, reaches 0 °C the power is automatically reduced to
35 W. At this heating power the temperature is stabilized at
about 80 °C. The switching and stabilization is accomplished
by two level thermostats. At the beginning, when heating
starts, low power heating is set automatically. High power
heating is switched on by a starting impulse, activated only if
there is liquid nitrogen in the Dewar flask.

The Penning type PeM vacuum gauge indicates the high
vacuum level in the tubing between the turbomolecular pump
and valve V0. The Pirani vacuum gauge for indicating pres-
sure from 10�1 to 103 Pa can be separated from the rest of the
apparatus by valve V6, which must be closed before the pres-
sure in the connecting tubing rises above 0.1 MPa, otherwise
its vacuum tightness will be lost.

The complete production system consisting of the target,
the filling and recycling apparatus, together with auxiliary
parts, is mounted on a mobile carriage. For irradiation, the
carriage is moved to the proton beamline. All the electronic
blocks are kept at a sufficient distance from the beam to
prevent radiation damage.

3 Target construction
The scheme of the target system is sketched in Fig. 3; the

assembly of the target is shown in Fig. 4. All parts of the sys-

4 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 41  No. 2/2001

Fig. 2: Overall view of the filling and recycling apparatus at the
development stage

Fig. 3: Schematic drawing of the Kr target



Acta Polytechnica Vol. 41  No. 2/2001

tem are made of material that is only to a small extent acti-
vated by scattered particles of the beam. A thin compact Ni
layer coats the interior of the tube, the entrance window of the
target is made of Ti foil, and the material of the scatter foil is
pure Al. A beam stopper is integrated at the tube outlet,
which, like the surfaces of the other parts, is cooled by water.
The target system is electrically insulated from the output
accelerator flange.

The target is operated at a pressure of 1–2 MPa, with
proton beam energy Ep = 28 MeV and energy loss of 6–7 MeV
in the target gas.

4 Operating procedure
The molecular sieves in the storage (working) containers

C2 (C1) are activated by heating them to 320 °C under contin-
uous pumping by the turbomolecular pump TMP and the
diaphragm vacuum pump DP. If the nominal vacuum is
reached, valve V2 (V1) is closed. Then the apparatus is eva-
cuated to 10�2 Pa.

The gas from the transport flask (625 cm3 at 1 bar, 20 °C)
is attached to the first filling fitting F1. The apparatus, includ-
ing the fitting armature, is evacuated and when the pressure
descends to 10�2 Pa, and all valves are closed. The Dewar flask
of the working container C1 is filled with liquid nitrogen and
the valves of the transport flask and valve V1 of the working
container C1 are opened. When the pressure, indicated on
PT1, descends to negative values, valve V6 is opened, and the
pressure is measured by the Pirani gauge. At a pressure below
0.5 Pa the valve V1 and the valve of the transport flask are
closed, as is V6. The transport flask is removed and filling
fitting F1 is blinded. By opening valves V0 and V4, the
aerated volume is evacuated again to 10�2 Pa, and after valves
V0 and V4 have been closed the apparatus is ready for the first
cycle, i.e., for the transfer of the gas in the target.

For this purpose, the Dewar flask of the intermediate
container (Kr trap) C3 is filled with liquid nitrogen and
container C1 is heated by thermocoax heating element H1 to

320 °C. If there is liquid nitrogen present in container C1,
heater NBH1 is switched on and liquid nitrogen is boiled out.
After that, valves V1 and V2 will be opened and the gas
from C1 will freeze in container C3. At pressure lower than
0.1 MPa, valve V6 is opened and further decrease of the pres-
sure is measured by the Pirani gauge. When the pressure
decreases below 150 Pa, valve V5 is closed. In following steps
the heating of C1 is switched off, D1 is filled with liquid nitro-
gen and the rest of the gas between valves V2, V4, V5 and the
blinded filling fitting is transferred by cryogenic pumping to
C1. Valve V1 is closed when the pressure descends below
0.5 Pa. After that, heater NBH3 in C3 is switched on and
the liquid nitrogen boiled out. The pressure in the target,
measured by pressure transducer PT3, rises to approxima-
tely 2 MPa and from this moment the target is ready for
irradiation by protons from the cyclotron. After the end of
the irradiation the gas is transferred by cryogenic pumping
back either to working container C1 or to storing container
C2, the volume of which is larger than the volume of C1, and
the danger of escape of the gas during long-term storage is
minimized.

Then the radioisotope deposited on the walls of the
irradiation container is eluted for subsequent radiochemical
preparation of the end product. The details are explained in
[4]. After elution, the apparatus must be dried out, evacuated
to working vacuum and prepared for the next recycling.

5 Approximate duration of individual
process cycles

1. Nominal working vacuum is attained in about 50 to 90
minutes from the start of the TM, depending on the
duration for which the apparatus has been held under
atmospheric pressure.

2. Heating container C1 (C2) to 320 °C and stabilizing the gas
pressure at 1.52 MPa (0.073 MPa) takes about 32 minutes.

3. After opening valves V1 and V5, when gas transfer starts
from container C1, pressure stabilization (measured by
PT3) at 0.64 MPa is attained in about 2 minutes.

4. Freezing out the gas in trap C3 takes about 10 minutes.
5. Heating trap C3 and transferring the gas to the target till

the pressure attains 2.17 MPa and the target is ready for
irradiation takes about 32 minutes.

5

Fig. 4: Photograph of the pressure gas target

-0,5

0

0,5

1

1,5

2

0 10 20 30 40 50 60

Time [min]

P
r
e

s
s

u
r
e

[M
P

a
]

Fig. 5: Pressure of the gas in container C1 as a function of time elapsed
from the beginning of heating from 20 °C to 320 °C with
135 W heating power. The temperature is stabilized at
320 °C; valve V1 remains closed during heating



6 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 41  No. 2/2001

6. Recuperation of the gas in the tubing and in the dead
volumes of the valves, by freezing it in C1, after the target
has been filled and separated from the rest of the appara-
tus, lasts about 20 minutes.

7. Back transfer of the gas from the target by freezing it in
working container C1 lasts about 15 minutes.

The pressure increase in container C1, containing 628 cm3

(20 °C; 0.1MPa) during heating from room temperature to
320 °C and from –193 °C to 320 °C (including evaporation of
liquid nitrogen) is plotted in Fig. 5 and Fig. 6.

6 Main technical parameters
• Diaphragm vacuum pump 2MD4, Alcatel, pumping speed

3.3 m3/h, ultimate pressure 200 Pa.
• Turbomolecular vacuum pump ATH 20/40, Alcatel,

pumping speed 25/45/l/s, ultimate pressure < 10�8 Pa
(when in tandem with diaphragm vacuum pump).

• Container C1 – volume 60 cm3 including tubing and the
dead volume of valve V1 and filter F, maximum pres-
sure 2 MPa, filled in the cooled and heated region with
38.2 g of Merck zeolite, type 5A, provided with filters (glass
wool, stainless sieve, sintered stainless filter 50 �m) against
escape of zeolite powder, range of temperature –195 to
350 °C.

• Container C2 – volume 463 cm3 including tubing and
the dead volume of valve V2 and filter F, 60 cm3 of
which belongs to the cooled and heated section, maximum
pressure 2 MPa, filled in the cooled and heated region with
39 g of Merck zeolite, type 5A, provided with filters (glass
wool, stainless sieve, sintered stainless filter 50 �m) against
escape of zeolite powder, range of temperature of the
heated section –195 to 350 °C.

• Container C3 (Kr trap) – volume about 1.5 cm3, maximum
pressure 20 MPa.

• Valves V0 to V6 pneumatically actuated high-pressure bel-
lows valves, pressure max. 24 MPa, vacuum tight.

• Tubing – stainless steel, OD from 1/16” to 3/8”, maximum
pressure 20 MPa, silver brazed, removable vacuum tight
joints.

• Target – volume approx. 30 cm3 including dead volumes
of tubing and adjacent valves.

7 Conclusion
Since the end of 2000, the apparatus has been in use for

production of Rb81/Kr81m by irradiation of krypton in gas
form enriched to 99 % by 36Kr

82.
Our experience, confirmed in long-term experiments

with natural krypton, has shown that the filling and recycling
apparatus can guarantee up to 500 cycles without significant
loss or pollution of the gas, if the operation instructions are
strictly observed. This is very important, when the filling gas is
nearly monoisotopic 36Kr

82, which is expensive ($20/cm3).
The apparatus can also be used for production of radio-
isotopes by other nuclear reactions, for example 37Rb

82m in
the (p, n) reaction on 36Kr

82 on krypton with 90 % content of
this isotope.

Acknowledgement
The authors would like to record their gratitude to

Mr. J. Kříž and Mr. V. Němec from the Department of
Dosimetry and Application of Ionizing Radiation for their
valuable collaboration and assistance in constructing the
apparatus and in solving some technical problems during
production of the mechanical and electronic sections of the
apparatus.

References
[1] Vognar, M., Šimáně, Č.: Laboratory Apparatus for Pre-

paration 123I from 124Xe by Photonuclear Reaction.
Acta Polytechnica, Vol. 36, No. 5/1996, pp. 49–56

[2] Vognar, M., Šimáně, Č., Chvátil, D.: Recyklační aparatura
pro přípravu 123I fotojadernou reakcí na 124Xe. Závěrečná
zpráva k SO č. 403396, KDAIZ FJFI, Praha, 1997

[3] Groszowski, J.: Technika vysokého vakua. SNTL Praha,
1981

[4] Fišer, M., Hanč, P., Lebeda, O., Hradílek, P., Kopič-
ka, K.: Development and production of 81Rb / 81mKr radio-
nuclide generator in NPI. Czech J. Phys. 49 (1999), Suppl. S1,

pp. 811–816

Ing. Miroslav Fišer
Dept. of Radiopharmaceuticals
e-mail: fiser@ujf.cas.cz
Nuclear Physics Institute of CAS
250 68 Řež

Ing. Miroslav Vognar
Prof. Ing. Čestmír Šimáně, DrSc.
Ing. David Chvátil
Dept. of Dosimetry & Appl. of Ionizing Radiation
phone: +420 2 2323657, +420 2 2315212
fax: +420 2 2320861
e-mail: Vognar@br.fjfi.cvut.cz

Czech Technical University in Prague
Faculty of Nucleus Sciences and Physical Engineering
Břehová 7, 115 19 Praha 1, Czech Republic

-0,5

0

0,5

1

1,5

2

0 10 20 30 40 50 60

Time [min]

P
r
e

s
s

u
r
e

[M
P

a
]

Fig. 6: Pressure of the gas in container C1 as a function of time
from the beginning of heating from –193 °C to 320 °C.
The beginning of the curve corresponds to the boiling
out of liquid nitrogen from the Dewar flask with heating
power 270 W. When the temperature rises above zero, the
power is reduced to 165 W. The temperature is stabilized
at 320 °C. During heating valve V1 remains closed.