The construction of the European Spallation Source (ESS) in Lund, Sweden was begun in the summer of 2014 [1]. ESS source (without neutron instruments) consists of a linear accelerator that delivers a 2 GeV, 5 MW proton beam to a rotating tungsten target. The final high-energy beam transport (HEBT – shown in Fig. 1) region is approx. 50 m long, to allow for possible upgrades, and the proton beam travels through it at the final energy [2]. The region is close to the target, which is activated during the irradiation by a high-energy, high-power beam. Although the losses of the beam in the HEBT region are almost negligible, the intensity of radiation from the activated target is high enough to limit any intervention in the HEBT region during the beam-off time. Such interventions are necessary for repairs, maintenance, or other actions. Therefore, an estimation of residual dose rates is an important task for operational radiation protection, e.g., for the work and dose planning related to interventions in the accelerator facility. The level of residual radiation intensity in the HEBT region depends on the distance from the tungsten target, on the time of irradiation by the proton beam, and on the time elapsed since the last irradiation (the so-called cooling time). Based on Monte-Carlo simulations using the FLUKA package [3], it has been observed that the main problem comes from gamma radiation that can penetrate the HEBT region via the beam pipe. Therefore, a special element to stop the gamma radiation must be designed and installed in the ESS – from here on this element will be called the gamma blocker (GB).
The GB is foreseen in the accelerator-to-target (A2T) region (see Fig. 2), in the line of sight of a target wheel, upstream of the neutron shield wall (NSW) [1]. Its function is to absorb residual radiation from the activated target during the beam-off mode. During the normal work of the accelerator, GB must not be placed in the beam pipe.
The FLUKA Monte-Carlo simulation package [3] can provide estimates for residual dose rates for a given irradiation profile and specified cooling time. First calculations were performed to find out the dose equivalent rate (DOSE EQ) inside the A2T tunnel for the following cooling times: 0 (no cooling), 1 hour, 4 hours, 1 month. The source of radiation was located on the surface of the tungsten target. Its spectrum, shown in Fig. 3, was obtained by simulation of 5-year continuous irradiation of the tungsten target by the proton beam with parameters specified in Table 1.
Proton beam parameters used in the simulation
Beam properties | |
---|---|
Energy (GeV) | 2.00 |
Power (MW) | 5.00 |
Pulse current (mA) | 62.50 |
Average current (mA) | 2.50 |
Implementation of the radiation source on the tungsten target surface is shown in Fig. 4. During the simulations, the NSW was nominally 2 m thick, but its final thickness will be determined after detailed neutronic calculations.
Figure 5 shows the calculated residual dose rates after five years of continuous exposure, inside the accelerator tunnel, in the last part of the A2T section.
Figure 6 shows residual dose rates presented transversally to the accelerator tunnel, at
Installation of the GB element inside the beam pipe should remove the very intensive central peak. Therefore, in the next step, the calculations with the installed GB element were performed to select proper GB thickness. Figure 7 presents residual dose rates in the last part of the A2T section, after five years of continuous irradiation and no cooling time, for different GB thicknesses. All simulations were prepared for GBs made of steel due to the ESS material requirements. GB diameter is equal to 200 mm, while the beam pipe radius is equal to 80 mm.
The level of the dose rate was calculated in two localizations of the A2T section, i.e., on the GB contact at
The GB removes the central intense peak inside the beam pipe. However, it also increases the radiation levels at larger transverse distances in the GB neighbourhood due to radiation scattering.
At
Dose rates inside the beam pipe, after five years of exposure and various cooling times, for different GB thicknesses
GB thickness (mm) | Dose rate after five years of exposure (μSv/h) | |||
---|---|---|---|---|
No cooling | 1 hour cooling | 4 hours cooling | 1 month cooling | |
0 | 3800 ± 152 | 2060 ± 103 | 1700 ± 68 | 230 ± 9.2 |
50 | 850 ± 32 | 460 ± 14.8 | 370 ± 11 | 58 ± 2.8 |
100 | 180 ± 7.2 | 92 ± 3.4 | 72 ± 2.8 | 9 ± 0.36 |
150 | 40 ± 1.6 | 21 ± 0.84 | 18 ± 0.72 | 2.2 ± 0.09 |
200 | 14 ± 0.5 | 6 ± 0.24 | 5 ± 0.2 | 0.8 ± 0.03 |
400 | 1.150 ± 0.046 | 0.850 ± 0.034 | 0.54 ± 0.02 | 0.200 ± 0.008 |
To fulfill the required dose rate limit of 100 μSv/h, a 200 mm thick GB has been proposed for further engineering design, to include the additional safety factor equal 2. Such thickness should allow for access to the zone immediately after switching off the proton beam and moving GB to the “blocking” position.
To allow the intervention in the A2T section of the ESS accelerator, GB is needed to minimize gamma radiation emitted during the beam-off time from the activated tungsten target. This element will be automatically placed inside the beam pipe for the duration of the beam-off time. Before engineering design, Monte-Carlo simulations had to be performed, to select the optimum GB thickness. The residual dose rates in the accelerator tunnel were calculated using the FLUKA package and presented in the article for different GB thicknesses. Taking into account a safety factor equal to 2, a 200 mm thick, 200 mm diameter steel GB was proposed. Such dimensions will limit the dose rate in the accelerator tunnel to a maximum of 100 μSv/h, which is the allowed dose rate limit.