journal menu
short communications
 | JOURNAL OF SYNCHROTRON RADIATION |
Allowable aperture size of the front end for the high-heat-load undulator beamlines of SPring-8
aJAERI-RIKEN SPring-8 Project Team, Kamigori, Ako-gun, Hyogo 678-12, Japan
*Correspondence e-mail: oura@sp8sun.spring8.or.jp
A systematic study to determinine the allowable aperture size of the front end for the SPring-8 high-heat-load undulator beamlines has been performed, from the viewpoint of protecting the front-end Be window from thermomechanical failure, and based on the results of ANSYS finite-element analyses. These results have revealed that the allowable aperture size of the front end ranges approximately from 1.06 mm2 to 3.2 mm2 depending on the K-parameter and the filter thickness.
1. Introduction
The SPring-8 standard in-vacuum undulator, whose magnetic period length is 32 mm and number of periods is 140, radiates extremely high-heat-load radiation (Kitamura, 1996![[Kitamura, H. (1996). Hoshakou, 9, 403-412. (In Japanese.)]](../../../../../../logos/arrows/s_arr.gif "Kitamura, H. (1996). Hoshakou, 9, 403-412. (In Japanese.)")
). Its total radiated power and peak will reach 10.7 kW and 451 kW mrad−2, respectively, when the undulator gap is set to be minimum. If such a very intensive undulator beam irradiates an uncooled portion of the beamline component or an unexpected part beyond its cooling ability, serious problems will arise, resulting in vacuum failure. Each beamline component for such a high-heat-load undulator beamline should be designed so as to avoid such a problem.
One of the major functions of the front end for the SPring-8 undulator beamline is to reduce the heat load on the downstream beamline components and to avoid accidental irradiation onto an unexpected portion. The SPring-8 front end consists of many components (Sakurai et al., 1995) and its typical length is about 33 m between the light source and the terminal Be window assembly, which isolates the ultrahigh vacuum of the storage ring from the high vacuum of the monochromator. Among those components, several are used to reduce the heat load by limiting the spatial size of the undulator beam or employing a filtering material such as graphite foil.
A fixed mask with a small circular exit aperture is located 21.3 m from the light source. Although its main function is to avoid the accidental irradiation, it cuts off the off-axis part of the undulator beam. In the normal operating condition of the undulator beamline the majority of the radiated power is handled by utilizing the pre-slit (Takahashi et al., 1998) followed by the XY-slits assembly (XY-SLIT) (Oura et al., 1998). The pre-slit, which is located 26.4 m from the source, has a 4 mm-diameter circular aperture as its exit and is equipped with precision linear actuators to allow the vacuum vessel to be moved into the optimum position. The pre-slit will absorb almost half of the radiated power but the residual power is still high enough to damage the downstream components. The XY-SLIT, whose centre is located 28.9 m from the source, has an adjustable aperture and can be manipulated into a variety of aperture shapes so as to enable most fundamental radiation photons to pass through the assembly but most waste photons to be shut off. Its aperture size should be determined from the viewpoint of protecting the downstream component, such as the front-end Be window assembly, which is utilized under direct irradiation.
In considering the criterion for the thermomechanical failure of the Be window in practical use, some experimental results provide useful information. Shen et al. (1989) have performed an experiment simulating the failure condition of the Be window by means of electron bombardment, showing that the 250 µm window breaks at a power level of 660 W, which corresponds to a maximum temperature on the window of about 633 K. Asaoka et al. (1992) have conducted an experiment on the direct irradiation of the undulator beam onto the Be window. They observed irreversible buckling due to and release of inner mechanical stress resulting in a slow vacuum leak at an absorbed power density exceeding ∼2 W mm−2, at which the maximum temperature of the window was ∼673 K. They concluded that the thermomechanical failure occurred when the temperature difference between the window centre and its peripheral edges exceeded ∼473 K, which was in good agreement with a simple maximum shearing stress theory for the failure condition.
In this article, we describe systematic studies on the allowable aperture size of the front end, namely the XY-SLIT, based on the results of the finite-element method. The heat load on the Be window is calculated as a function of the aperture size of the XY-SLIT, the thickness of the graphite filter and the deflection parameter K of the insertion device. ANSYS finite-element analysis is conducted to understand the thermal and thermomechanical properties of the window, and the failure criterion is discussed.
2. Finite-element model of the Be window
The Be window is a 250 µm-thick foil brazed onto a water-cooled Cu holder and the window opening is 10 mm in diameter. A couple of these windows and the ion pump attached to the middle section between two windows constitute the Be window assembly. The inner diameter of the cooling channel of the Cu holder is 6 mm and the average flow rate of the water has been measured to be in excess of 5 l min−1.
An ANSYS finite-element model was formed for the quadrant structure of the Be window. We assumed a convective heat-transfer coefficient of 12000 W m−2 K−1 and a water temperature of 303 K in conservative calculations. The constant of 134 W m−1 K−1 for Be was consistently used for the present analyses. Strictly speaking, a temperature-dependent value should be used, but the employed is for the condition at 573 K and this results in a severe estimation in the temperature range below 573 K. We did not take account of thermal radiation cooling for the Be foil because we have concluded from the preliminary calculation that it is not so effective in the range of temperature for the present analyses even if it is under the most severe case. Thermal and mechanical properties used in the analyses are listed in Table 1.
| ||||||||||||||||||||
3. Absorbed power distribution
The finite-element analyses were preceded by estimating the absorbed power distribution in the window. For this purpose, the spectral and angular distributions of the undulator beam were calculated by using the computer code SPECTRA (Kitamura & Tanaka, 1996). The spatial distribution of the fundamental radiation in the horizontal (σx) and vertical (σy) directions at the location of the XY-SLIT was deduced from these computations so as to accept more than 68% photons of fundamental radiation. Deduced parameters of the spatial distribution and the aperture sizes used in the analyses are summarized in Table 2. Each acceptance Ax (horizontal) and Ay (vertical), the product of Ax and Ay being the aperture size, was chosen to be in units of the corresponding spatial distribution (σx and σy) and the six aperture sizes were determined for the analyses by keeping the ratio Ax/Ay constant. If we set the aperture size to 36Rσy2, almost all photons of fundamental radiation pass through the aperture. In the normal operating mode of the beamline, however, setting the aperture size beyond 36Rσy2 has no advantage even if the Be window withstands the heat load passing through the XY-SLIT.
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
The total absorbed power, PT, in the foil is approximated by integrating all non-transmitted photons through the foil in which we assumed that Compton-scattered photons are also absorbed in the foil. This assumption gives rise to an overestimation of about 10% in the total absorbed power and a rigorous analysis needs to incorporate the Monte Carlo simulation.
In order to determine the spatial distribution of the absorbed power in the window, a number of off-axis photon-flux-density spectra were computed and those of the absorbed power density were calculated in the same manner as mentioned above. These results were adopted in the fitting procedure using the following equation,
![[F(h,v)=(2^{1/2}/\pi^{3/2})(P_T/\sigma H)\exp(-v^2/2\sigma^2) (1-h^2/H^2)^{1/2}\, \delta(h,v),]](teximages/az3057fd1.gif)
where h and v are the horizontal and vertical distances, respectively, measured from the centre of the window, σ is the standard deviation of the spatial distribution of the absorbed power in the vertical direction, H is the half width of the spatial distribution of the absorbed power in the horizontal direction, δ(h, v) is the δ-function which becomes unity when the coordinate (h, v) resides in the projection of the aperture size of the XY-SLIT on the window. The absorbed power in the window as a function of the aperture size of the XY-SLIT, the thickness of the filter and the deflection parameter K are calculated using obtained parameters, at which the XY-SLIT is assumed to be located at 30 m from the source.
4. Results and discussion
The results from a series of ANSYS calculations are summarized in Table 3. Figs. 1(a) and 1(b) show, respectively, the typical results of the maximum surface temperature and the maximum equivalent stress, i.e. Mizes's equivalent stress, in the window for K = 1.95 as a function of aperture size. In order to determine the allowable aperture size of the front end, we have employed the following highly conservative criterion to avoid thermomechanical failure of the window: Mizes's equivalent stress should not exceed the yield strength of Be (280 MPa) since, if the maximum stress in the window exceeds the yield strength, plastic deformation and fatigue in the window will arise and result in a diminution of the life-cycle of the window.
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
![[Figure 1]](az3057fig1thm.gif) | Figure 1 Maximum surface temperature (a) and maximum equivalent stress (b) in the Be window for K = 1.95, as a function of the aperture size of the XY-SLIT and the filter thickness. Curves in the figure are guides to the eye. |
The deduced allowable aperture sizes of the XY-SLIT are depicted as a function of the K parameter and the filter thickness in Fig. 2. The corresponding maximum temperatures of the window range between 423 and 433 K. These values are lower than those estimated by the simple maximum shearing stress theory and are enough to use the Be window in safety. According to the present analyses, we can set an upper limit of the aperture size of the XY-SLIT to be 3.11 (H) × 1.03 (V) mm. The practical aperture size, however, should be determined by taking account of the acceptance of the first optical component and its cooling ability. For example, at the condition of K = 1.95 and no filter, the allowable aperture size estimated by the present analyses is 2.03 (H) × 0.73 (V) mm. In this case, the transmitted of fundamental radiation and the transmitted power through the XY-SLIT can be calculated as almost 70% of the total and 1.03 kW, respectively.
![[Figure 2]](az3057fig2thm.gif) | Figure 2 Deduced allowable aperture size of the XY-SLIT as a function of the deflection parameter and the filter thickness. Curves in the figure are guides to the eye. |
The present results are only based on the elastic analysis. The analysis will have to be extended to take account of buckling phenomena. Further study is in progress.
Footnotes
‡Present address: Ishikawajima-Harima Heavy Industries Co. Ltd, 1 Shin-Nakahara-cho, Isogo-ku, Yokohama, Kanagawa 235, Japan.
References
Asaoka, S., Maezawa, H., Kamiya, Y. & Yanagihara, M. (1992). Rev. Sci. Instrum. 63, 473–476. CrossRef CAS Web of Science
Kitamura, H. (1996). Hoshakou, 9, 403–412. (In Japanese.)
Kitamura, H. & Tanaka, T. (1996). SPECTRA. Synchrotron Radiation Calculation Program. Version 1.1 for Windows 3.2. Insertion Device Group, SPring-8, Hyogo 678-12, Japan.
Oura, M., Sakurai, Y. & Kitamura, H. (1998). J. Synchrotron Rad. 5, 606–608. Web of Science CrossRef CAS IUCr Journals
Sakurai, Y., Oura, M., Sakae, H., Usui, T., Kimura, H., Oikawa, Y., Kitamura, H., Konishi, T., Shiwaku, H., Nakamura, A., Amamoto, H. & Harami, T. (1995). Rev. Sci. Instrum. 66, 1771–1773. CrossRef CAS Web of Science
Shen, Q., Bedzyk, M. J., Keeffe, M. J. & Schildkamp, W. (1989). Rev. Sci. Instrum. 60, 1464–1467. CrossRef CAS Web of Science
Takahashi, S., Sakurai, Y. & Kitamura, H. (1998). J. Synchrotron Rad. 5, 581–583. Web of Science CrossRef CAS IUCr Journals
© International Union of Crystallography. Prior permission is not required to reproduce short quotations, tables and figures from this article, provided the original authors and source are cited. For more information, click here.
| JOURNAL OF SYNCHROTRON RADIATION |
