JP2869000B2 - High frequency accelerator - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high-frequency accelerator such as a high-current electron (positron) storage ring, and more particularly to a high-frequency accelerator capable of removing a higher-order mode causing beam instability.

[0002]

2. Description of the Related Art Generally, when electrons running at a high speed are bent by a magnetic field, a part of energy is emitted as light. However, with the increase in brightness of this light (synchrotron radiation), large current electron accumulation is caused. Demand for rings and the like has been increasing in recent years. Therefore, the problem is the instability of the beam due to the higher mode caused by the large current.

FIG. 6 shows a conference “Mini” held at the Institute of High Energy Physics (KEK) on December 15-17, 1993, for example.
-Workshop on TRISAINIIB-FACTORY (Accelerator) "
FIG. 2 is a side sectional view schematically showing a high-frequency accelerator having a conventional higher-order mode removing mechanism disclosed in US Pat. In the figure,
1 is an acceleration cavity for accelerating charged particles, 2 is a beam pipe connected to the acceleration cavity 1, and 3 is a large-diameter beam pipe for connecting a higher-order mode to the annular radio wave absorber 4. The large-diameter beam pipe 3 has a large diameter in order to lower the cut-off frequency in the pipe. The radio wave absorber 4 is attached to the inner wall of the large-diameter beam pipe 3 and absorbs higher-order modes that are radio waves (electromagnetic waves), and is generally made of ferrite or the like. lb is the distance from the end of the acceleration cavity 1 to one end of the radio wave absorber 4, and lt is the distance from the other end of the radio wave absorber 4 to the end of the large diameter beam pipe 3.

Next, the operation will be described. Normally, the TM ₀₁₀ mode is used as the acceleration mode and is excited in the acceleration cavity 1, but higher-order modes such as TM ₁₁₀ , TM ₀₁₁ and TM ₀₂₀ are also excited simultaneously by the beam. The higher-order mode in the acceleration cavity 1 is TM ₀₁ in the large-diameter beam pipe 3.
Alternatively, it is absorbed by the radio wave absorber 4 in combination with the TE ₁₁ mode or the like.

According to this method, the Q value of the higher-order mode (the energy stored in the accelerating cavity is divided by the power loss and multiplied by the angular frequency) as compared with the method using a normal HOM (higher-order mode) coupler. ), A removal effect of about one to two orders of magnitude higher is obtained. In order to improve the absorption of the radio wave by the radio wave absorber 4, it can be said that the surface area and the thickness, that is, the volume thereof may be increased. However, since the large-diameter beam pipe 3 in which the radio wave absorber 4 is attached to the inner wall is used in a high vacuum, heat generated by energy generated by the radio wave absorber 4 absorbing radio waves cannot be radiated to the space. Heat is radiated from the absorber 4 through the large-diameter beam pipe 3. However, if the thickness of the radio wave absorber 4 is large, its cooling efficiency is deteriorated. Problems such as an increase in impurities (outgas) adsorbed on the surface occur.
Therefore, it is desirable to keep the surface area and thickness of the radio wave absorber 4 as small as possible.

For example, according to the above paper, when ferrite is used as a radio wave absorber, when the Q value of a higher-order mode (the smaller this value is preferable) is a function of the distances lb and lt, the minimum value of the Q value is obtained. Although the value is the same even when the thickness of the ferrite is changed, the dependency on the distances lb and lt tends to be strong. That is, when the thickness of the ferrite constituting the radio wave absorber is reduced, the dependence of the place where the radio wave absorber is installed becomes strong, and the distances lb and lt
Is narrower. Further, when the surface area of the ferrite is small, the dependence of the Q value on the distance lt becomes strong.

For this reason, at present, the conventional high-frequency accelerator has a sufficient ferrite thickness and a wide effective range of the distances lb and lt even if the load on the cooling system is increased. Also, depending on the electromagnetic field distribution, the strength of the electromagnetic field is not uniform in the higher-order mode, so that a temperature gradient is formed in the beam axis direction in the ferrite, and the ferrite may be cracked.

[0008]

Since the conventional high-frequency accelerator is constructed as described above, it is necessary to accurately determine the position of the radio wave absorber when a small amount of radio wave absorber sufficiently absorbs the higher-order mode. When the thickness of the radio wave absorber is increased to weaken the dependence on the position of the radio wave absorber, cooling becomes insufficient and the performance of the radio wave absorber decreases, and the surface area of the radio wave absorber increases. This causes a problem that outgassing occurs.

The present invention has been made to solve such a problem, and an object of the present invention is to provide a high-frequency accelerator capable of sufficiently absorbing a higher mode with a small amount of a radio wave absorber.

[0010]

According to a first aspect of the present invention, there is provided a high-frequency accelerator, comprising: an accelerating cavity for accelerating charged particles;
A large-diameter beam pipe connected to the accelerating cavity, a radio wave absorber attached to the large-diameter beam pipe and absorbing a higher-order mode, and a large-diameter beam pipe positioned at least before and after the radio wave absorber. And a variable pipe length mechanism for changing the pipe length of the large-diameter beam pipe.

According to a second aspect of the present invention, there is provided a high-frequency accelerator for accelerating charged particles, a first large-diameter beam pipe connected to one side of the acceleration cavity, and a first large-diameter beam pipe.
A first radio wave absorber attached to a large-diameter beam pipe and absorbing a higher-order mode, a second large-diameter beam pipe connected to the other side of the acceleration cavity, and a second large-diameter beam pipe A second radio wave absorber that is attached and absorbs a higher mode, and is mounted on the first large-diameter beam pipe so as to be located at least in front of and / or after the first radio wave absorber; A first pipe length changing mechanism for changing a pipe length of the diameter beam pipe; and a second large diameter beam pipe attached to the second large diameter beam pipe so as to be located at least in front of or behind the second radio wave absorber. And a second variable tube length mechanism for changing the length of the diameter beam pipe.

According to a third aspect of the present invention, there is provided a high-frequency accelerator according to the first or second aspect, wherein a high-order mode detecting means for picking up a high-order mode, and a pipe length based on an output of the high-order mode detecting means. Control means for controlling the variable mechanism.

[0013]

[0014]

According to the first aspect of the present invention, the position of the radio wave absorber is optimized by the variable tube length mechanism to sufficiently absorb the target higher order mode. As a result, even if the location dependence of higher-order mode absorption is strengthened, sufficient higher-order mode absorption can be obtained by fine adjustment, and as a result, the thickness of the radio wave absorber is reduced,
The surface area can be reduced, the cooling efficiency of the radio wave absorber can be increased, and the amount of outgas can be reduced.

According to the second aspect of the present invention, the position of the radio wave absorber is optimized by the variable tube length mechanism to sufficiently absorb a specific higher-order mode of interest. As a result, even if the location dependence of higher-order mode absorption is strengthened, sufficient specific higher-order mode absorption can be obtained by fine adjustment, and as a result, the thickness of the radio wave absorber can be reduced and the surface area can be reduced. As a result, the cooling efficiency of the radio wave absorber can be increased, and the amount of outgas can be reduced.

According to the third aspect of the present invention, the higher mode signal is fed back to the variable pipe length mechanism via the control means. This makes it possible to optimize the position of the radio wave absorber every moment corresponding to the heat generation etc. of the radio wave absorber,
Even when the absorption capacity is partially reduced due to heat generation or the like, it can be compensated.

[0017]

[0018]

【Example】

Embodiment 1 FIG. An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a side sectional view schematically showing an embodiment of the present invention, and portions corresponding to those in FIG. 6 are denoted by the same reference numerals, and detailed description thereof will be omitted. In the figure, reference numeral 5 denotes a variable pipe length mechanism which is attached to the large diameter beam pipe 3 so as to be located closer to the acceleration cavity 1 than the radio wave absorber 4 and changes the length of the large diameter beam pipe 3. 5, the length of the large-diameter beam pipe 3 is changed, so that the radio-wave absorber 4 attached to the large-diameter beam pipe 3 is substantially moved to move the radio-wave absorber 4 from the acceleration cavity 1.
Can be varied. Reference numeral 6 denotes an RF contact for contacting the variable pipe length mechanism 5 to make the inside of the large diameter beam pipe 3 continuous.

The variable pipe length mechanism 5 includes, for example, a supporting portion 5a provided on the large diameter beam pipe 3, a pair of flanges 5b extending upward from the supporting portion 5a at a predetermined interval, and a portion between the pair of flanges 5b. And a screw 5d screwed between a pair of flanges 5b.
And a contact piece 5e extending from one side of the support portion 5a to the inside of the vacuum bellows 5c. By adjusting the screw 5d, the expansion and contraction of the vacuum bellows 5c and the contact piece 5
e moves while making contact with the RF contact 6, and as a result, the variable-length tube mechanism 5 moves the radio wave absorber 4 while maintaining the vacuum state in the large-diameter beam pipe 3, and moves the distance from the acceleration cavity 1 to the radio wave absorber 4. Can be varied.

Next, the operation will be described. Acceleration cavity 1
The higher-order modes such as TM ₀₁₁ , TM ₁₁₀ , TE _{111 and the} like generated in the portion of the large diameter beam pipe 3 combine with the TM ₀₁ mode or the TE ₁₁ mode generated in the portion of the large diameter beam pipe 3 and are absorbed by the radio wave absorber 4. Substantially eliminated. At this time, the length of the large-diameter beam pipe 3 is varied between the accelerating cavity 1 and one end of the radio wave absorber 4 by using the variable pipe length mechanism 5 to move the position of the radio wave absorber 4 so that the target higher order Position of the radio wave absorber 4 in accordance with the electromagnetic field distribution of the mode,
That is, the adjustment is performed so that the above-described Q value becomes the minimum value. Thereby, the position of the radio wave absorber 4 is optimized, and the absorption of the target higher order mode can be sufficiently absorbed.

As described above, in this embodiment, the radio wave absorber 4
Since the position of can be optimized to sufficiently absorb the higher-order mode of interest, even if the location dependence of higher-order mode absorption is strengthened, sufficient adjustment of higher-order modes can be obtained by fine adjustment. As a result, the thickness of the radio wave absorber 4 can be reduced, and the distance from the heat receiving portion to the heat radiating portion that absorbs higher modes of the radio wave absorber 4 can be shortened, so that the cooling efficiency of the radio wave absorber 4 increases and Since the surface area of No. 4 can be reduced, the amount of outgas can also be reduced. Furthermore, since the radio wave absorber 4 can be moved, the corresponding higher-order mode can be changed, for example, from TE ₁₁₁ to TM _020. That is, the optimal position of the radio wave absorber 4 can be changed according to the higher-order mode. Can be changed.

Embodiment 2 FIG. FIG. 2 is a side sectional view schematically showing another embodiment of the present invention. 2, parts corresponding to those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof will be omitted. In this embodiment, the variable pipe length mechanism 5 is attached to the large diameter beam pipe 3 so as to be located on the terminal side of the large diameter beam pipe 3 from the radio wave absorber 4 so that the length of the large diameter beam pipe 3 can be varied. . Other configurations are the same as those in FIG.

Next, the operation will be described. Acceleration cavity 1
The higher-order modes such as TM ₀₁₁ , TM ₁₁₀ , TE _{111 and the} like generated in the portion of the large diameter beam pipe 3 combine with the TM ₀₁ mode or the TE ₁₁ mode generated in the portion of the large diameter beam pipe 3 and are absorbed by the radio wave absorber 4. Substantially eliminated. At this time, the length of the large-diameter beam pipe 3 is changed between the other end of the radio wave absorber 4 and the end of the large-diameter beam pipe 3 by using the variable pipe length mechanism 5 to move the position of the radio wave absorber 4, According to the electromagnetic field distribution of the target higher order mode, the radio wave absorber 4
Is adjusted so that the position where there is should be, that is, the above-described Q value becomes the minimum value. As a result, the position of the radio wave absorber 4 is optimized, and the target higher order mode can be sufficiently absorbed.

As described above, also in this embodiment, the radio wave absorber 4
Since the position of can be optimized to sufficiently absorb the higher-order mode of interest, even if the location dependence of higher-order mode absorption is strengthened, sufficient adjustment of higher-order modes can be obtained by fine adjustment. As a result, the thickness of the radio wave absorber 4 can be reduced, and the distance from the heat receiving portion to the heat radiating portion that absorbs higher modes of the radio wave absorber 4 can be shortened, so that the cooling efficiency of the radio wave absorber 4 increases and Since the surface area of No. 4 can be reduced, the amount of outgas can also be reduced. Also,
Since the radio wave absorber 4 can be moved, the corresponding higher-order mode can be changed from, for example, TE ₁₁₁ to TM _020. That is, the radio wave absorber 4 can be changed according to the higher-order mode.
The optimal position can be changed.

Further, since the variable pipe length mechanism 5 is attached to the large-diameter beam pipe 3 so as to be located on the terminal side of the large-diameter beam pipe 3 with respect to the radio wave absorber 4, the radio wave absorber 4 is provided.
In the case of FIG. 1, when the cycle of the optimum position of the radio wave absorber 4 is shifted from the position of the optimum position of the radio wave absorber 4, the length of the cycle of the optimum position of the radio wave absorber 4 is considered in the case of FIG. Although it is necessary to attach the absorber 4, in the case of FIG. 2, it is only necessary to consider the deviation, which is advantageous in terms of space and the like when this high-frequency accelerator is incorporated in an accelerator.

Embodiment 3 FIG. FIG. 3 is a side sectional view schematically showing another embodiment of the present invention. 3, parts corresponding to those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof will be omitted. In this embodiment, the variable pipe length mechanism 5 is attached to the large-diameter beam pipe 3 so as to be located closer to the acceleration cavity 1 than the radio wave absorber 4 so that the length of the large-diameter beam pipe 3 can be changed. 1 is connected to another large-diameter beam pipe 3A on the opposite side of the large-diameter beam pipe 3, and a variable-length pipe mechanism 5 is attached to the large-diameter beam pipe 3A so as to be positioned closer to the acceleration cavity 1 than the radio wave absorber 4. The length of the large-diameter beam pipe 3A is made variable. Other configurations are the same as those in FIG.

Next, the operation will be described. Acceleration cavity 1
Two higher-order modes that occur simultaneously in the section
₀₁₁ and TE ₁₁₁ is coupled to the TM ₀₁ mode or the TE ₁₁ mode generated in the portion of the large diameter beam pipe 3 and 3A,
One higher-order mode such as TM ₀₁₁ is simultaneously absorbed by the radio wave absorber 4 provided in the large-diameter beam pipe 3, and the other higher-order mode such as TE ₁₁₁ is simultaneously absorbed by the radio wave absorber 4 provided in the large-diameter beam pipe 3 A. To be substantially removed. At this time, the length of the large-diameter beam pipes 3 and 3A is varied between the acceleration cavity 1 and one end of the radio wave absorber 3 by using the variable pipe length mechanism 5 to move the position of the radio wave absorber 4 and become an object. In accordance with the electromagnetic field distribution of the higher order mode, the position of the radio wave absorber 4, that is, the Q value is adjusted so as to be the minimum value. Thereby, the position of the radio wave absorber 4 is optimized, and it is possible to sufficiently absorb at least two higher-order modes that contribute to beam instability.

As described above, also in this embodiment, the radio wave absorber 4
Can be sufficiently absorbed by optimizing the position of at least two higher-order modes of interest, so that even if the location dependence of higher-order mode absorption is increased, sufficient adjustment of higher-order modes can be achieved by fine adjustment. As a result, the thickness of the radio wave absorber 4 can be reduced, and the distance from the heat receiving portion that absorbs higher-order modes of the radio wave absorber 4 to the heat radiating portion can be shortened, so that the cooling efficiency of the radio wave absorber 4 increases. Since the surface area of the radio wave absorber 4 can be reduced, the amount of outgas can also be reduced. Further, since it is possible to move the wave absorber 4, from the corresponding higher order modes e.g. TE ₁₁₁ TM
₀₂₀ , that is, the optimum position of the radio wave absorber 4 can be changed according to the higher-order mode.

Embodiment 4 FIG. FIG. 4 is a side sectional view schematically showing another embodiment of the present invention. 4, parts corresponding to those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof will be omitted. In the present embodiment, a high-order mode monitor 7 attached to the large-diameter beam pipe 3 and serving as a high-order mode detecting means for picking up a high-order mode, and a tube length variable mechanism based on the output of the high-order mode monitor 7 5 is provided with a feedback mechanism 8 as a control means for controlling the control mechanism 5. The feedback mechanism 8 is, for example, an A / D converter 8a for A / D converting the output of the higher-order mode monitor 7, and a stepping motor (not shown) which performs logical processing on the output of the A / D converter 8a with logic or the like. 5d of the pipe length variable mechanism 5 using
And a control mechanism 8b for driving the portion of the large-diameter beam pipe 3 by automatically driving the variable-tube-length mechanism 5 by the feedback mechanism 8. Other configurations are the same as those in FIG.

Next, the operation will be described. Acceleration cavity 1
The higher-order modes such as TM ₀₁₁ , TM ₁₁₀ , TE _{111 and the} like generated in the portion of the large diameter beam pipe 3 combine with the TM ₀₁ mode or the TE ₁₁ mode generated in the portion of the large diameter beam pipe 3 and are absorbed by the radio wave absorber 4. Substantially eliminated. At this time, the higher-order mode is picked up by the higher-order mode monitor 7, sent out to the A / D converter 8a, A / D-converted and supplied to the control mechanism 8b, where it is logically processed, and the pipe length is varied by its output. The mechanism 5 is driven to change the length of the large-diameter beam pipe 3 between the accelerating cavity 1 and one end of the radio wave absorber 4 to move the position of the radio wave absorber 4 to obtain a target higher-order mode electromagnetic field distribution. Is adjusted so that the position where the radio wave absorber 4 should be, that is, the above-described Q value becomes the minimum value. As a result, the position of the radio wave absorber 4 at every moment corresponding to the heat generation of the radio wave absorber 4 is optimized, and the target higher order mode can be sufficiently absorbed, and partially absorbed by the heat generation and the like. Even if the performance is reduced, it can be compensated.

As described above, also in this embodiment, the radio wave absorber 4
Position can be optimized to sufficiently absorb the absorption of the higher-order mode of interest, so that even if the location dependence of higher-order mode absorption is strengthened, sufficient adjustment of the higher-order mode can be obtained by fine adjustment. As a result, the thickness of the radio wave absorber 4 is reduced,
Since the distance from the heat receiving portion that absorbs the higher order mode of the radio wave absorber 4 to the heat radiation portion can be shortened, the cooling efficiency of the radio wave absorber 4 can be increased, and the surface area of the radio wave absorber 4 can be reduced, so that the outgassing can be reduced. The amount can also be reduced.
Further, since the radio wave absorber 4 can be moved, the corresponding higher-order mode can be changed from, for example, TE ₁₁₁ to TM _020. That is, the optimum position of the radio wave absorber 4 can be changed according to the higher-order mode. Can be changed. Further, since the higher-order mode signal is fed back to the variable tube length mechanism 5 via the feedback mechanism 8, it is possible to optimize the position of the radio wave absorber 4 every moment corresponding to heat generation of the radio wave absorber 4. Thus, even when the absorption capacity is partially reduced due to heat generation or the like, it can be compensated.

Embodiment 5 FIG. FIG. 5 is a sectional view schematically showing another embodiment of the present invention, in which a portion where the radio wave absorber 4 is attached is cut away. 5, parts corresponding to those in FIGS. 1 to 4 are denoted by the same reference numerals, and detailed description thereof will be omitted. In the above embodiment, the radio wave absorber 4 is simply attached to the inner wall of the large-diameter beam pipe 3 as a cooling mechanism. In the present embodiment, however, the large-diameter beam pipe 3 to which the radio wave absorber 4 is attached is attached. A heat pipe 9 longer than the length of the radio wave absorber 4 in the beam axis direction;
Is buried as cooling means. Thereby, the radio wave absorber 4
The heat generated non-uniformly is transmitted by a heat pipe 9 in which the direction of heat transfer is taken in the beam axis direction, the temperature distribution in the beam axis direction of the radio wave absorber 4 becomes substantially uniform, and the temperature gradient disappears, and Cracks of the absorber 4 and separation from the attached material, that is, the large-diameter beam pipe 3 are prevented.

Here, the manufacturing method will be described. First, for example, copper is used as a material of the large-diameter beam pipe 3, and a groove is cut on the inner wall side of the large-diameter beam pipe 3 so that the heat pipe 9 fits in the beam axis direction. The length of the heat pipe 9 is longer than the length of the radio wave absorber 4 in the beam axis direction. Next, the heat pipe 9 is placed in the cut groove and fixed by brazing or the like. The heat pipe 9 is provided with a mechanism such as a wick in order to take the direction of heat transmission in the horizontal direction. Then, the radio wave absorber 4 is attached to the heat pipe 9 by brazing or the like.

As described above, in this embodiment, the same effects as those of the above embodiment can be obtained, and further, in this embodiment,
Since the heat pipe 9 longer than the length of the radio wave absorber 4 in the beam axis direction is buried as a cooling means in the large diameter beam pipe 3 to which the radio wave absorber 4 is attached,
The temperature distribution in the beam axis direction of the radio wave absorber 4 becomes substantially uniform, and the temperature gradient is eliminated, thereby preventing the radio wave absorber 4 from being cracked or separated from the attached material, that is, from the large diameter beam pipe 3.

Embodiment 6 FIG. In the third embodiment, the case where the variable tube length mechanism 5 is attached to the large-diameter beam pipes 3 and 3A so as to be positioned closer to the acceleration cavity 1 than the radio wave absorber 4 has been described. The variable pipe length mechanism 5 may be attached to the large-diameter beam pipes 3 and 3A so as to be located on the terminal side of the large-diameter beam pipe 3 with respect to the radio wave absorber 4. Further, the first and second embodiments may be used together, and the variable tube length mechanism 5 may be provided before and after the radio wave absorber 4. Further, the fourth embodiment is substantially the same as the first embodiment.
Although the case where the feedback mechanism is added to the structure described above has been described, the present invention can be similarly applied to the above-described other embodiments other than the first embodiment, and the same effects can be obtained.

[0036]

As described above, according to the first aspect of the present invention, an acceleration cavity for accelerating charged particles, a large-diameter beam pipe connected to the acceleration cavity, and attached to the large-diameter beam pipe, A radio wave absorber that absorbs a higher-order mode, and a pipe length variable mechanism that is attached to the large-diameter beam pipe so as to be located at least before or after the radio wave absorber and that changes the pipe length of the large-diameter beam pipe. Therefore, the position of the radio wave absorber can be optimized to sufficiently absorb the higher-order mode of interest, and even if the location dependence of higher-order mode absorption is increased, sufficient high-order mode can be obtained by fine adjustment. Mode absorption is obtained, the thickness of the radio wave absorber can be reduced, the surface area can be reduced, the cooling efficiency of the radio wave absorber can be improved, and the amount of outgas can be reduced,
Moreover, there is an effect that the optimum position of the radio wave absorber can be changed according to the higher order mode. In addition, if the variable pipe length mechanism is installed so as to be located at the end of the large diameter beam pipe after the radio wave absorber, only the difference between the cycle of the optimal position of the radio wave absorber and the position of the radio wave absorber to be actually installed Since it is sufficient to take this into consideration, there is an effect that it is advantageous in terms of space and the like when this high-frequency accelerator is incorporated in an accelerator.

According to the second aspect of the present invention, the acceleration cavity for accelerating the charged particles, the first large-diameter beam pipe connected to one side of the acceleration cavity, and the first large-diameter beam pipe A first radio wave absorber attached to absorb higher-order modes, a second large-diameter beam pipe connected to the other side of the acceleration cavity, and attached to the second large-diameter beam pipe; A second radio wave absorber for absorbing
Attached to the first large-diameter beam pipe so as to be located at least before or after the first radio wave absorber;
A first pipe length variable mechanism for changing the pipe length of the first large-diameter beam pipe; and a second large-diameter beam pipe attached to the second large-diameter beam pipe so as to be located at least before or after the second radio wave absorber. A second variable length mechanism for varying the length of the second large-diameter beam pipe, so that the position of the radio wave absorber is optimized to sufficiently absorb at least two specific higher-order modes of interest. Therefore, even if the location dependence of higher-order mode absorption is strengthened, sufficient absorption of a specific higher-order mode can be obtained by fine adjustment, and the thickness of the radio wave absorber is reduced and the surface area is reduced. Thus, the cooling efficiency of the radio wave absorber can be improved, the amount of outgas can be reduced, and the optimum position of the radio wave absorber can be changed according to the higher-order mode. In addition, if the variable pipe length mechanism is installed so as to be located at the end of the large diameter beam pipe after the radio wave absorber, only the difference between the cycle of the optimal position of the radio wave absorber and the position of the radio wave absorber to be actually installed Since it is sufficient to take this into consideration, there is an effect that it is advantageous in terms of space and the like when this high-frequency accelerator is incorporated in an accelerator.

According to the third aspect of the present invention, in the first or second aspect of the present invention, the high-order mode detecting means for picking up the high-order mode and the pipe length variable mechanism based on the output of the high-order mode detecting means are provided. With the control means for controlling, in addition to the effect of the invention of claim 1 or 2, it is possible to further optimize the position of the radio wave absorber every moment corresponding to the heat generation of the radio wave absorber, There is an effect that even when the absorption capacity is partially reduced due to heat generation or the like, it can be compensated.

[0039]

[Brief description of the drawings]

FIG. 1 is a side sectional view showing one embodiment of a high-frequency accelerator according to the present invention.

FIG. 2 is a side sectional view showing another embodiment of the high-frequency accelerator according to the present invention.

FIG. 3 is a side sectional view showing another embodiment of the high-frequency accelerator according to the present invention.

FIG. 4 is a side sectional view showing another embodiment of the high-frequency accelerator according to the present invention.

FIG. 5 is a cross-sectional view showing another embodiment of the high-frequency accelerator according to the present invention.

FIG. 6 is a side sectional view showing a conventional high-frequency accelerator.

[Explanation of symbols]

1 Acceleration cavity, 3,3A large diameter beam pipe, 4 radio wave absorber, 5 pipe length variable mechanism, 6 RF contact, 7
Higher order mode monitor, 8 feedback mechanism, 9 heat pipe.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References Japanese Utility Model Sho 63-160700 (JP, U) Akai et al. , "Development of Crab Cavity for CESR-B", KEK Preprint 93-17, May 1993 S.D. Mitsunobu et al. , "Superconductor RF Activities at KEK", KEK Preprint 91-194, January 1992 (58) Fields investigated (Int. Cl. ⁶ , DB name) H05H 7/00-13/12 JICST file (JOIS)

Claims (3)

(57) [Claims] 1. An acceleration cavity for accelerating charged particles, a large-diameter beam pipe connected to the acceleration cavity, a radio wave absorber attached to the large-diameter beam pipe and absorbing a higher-order mode, A high-frequency accelerator, comprising: a beam length variable mechanism attached to the beam pipe so as to be positioned at least before or after the radio wave absorber and configured to vary the length of the large-diameter beam pipe. 2. An accelerating cavity for accelerating charged particles, a first large-diameter beam pipe connected to one side of the accelerating cavity, and attached to the first large-diameter beam pipe to absorb higher-order modes. A first radio wave absorber, a second large-diameter beam pipe connected to the other side of the accelerating cavity, and a second radio wave attached to the second large-diameter beam pipe and absorbing a higher-order mode. An absorber, a first large-diameter beam pipe attached to the first large-diameter beam pipe so as to be located at least before or after the first radio-wave absorber, and configured to vary a pipe length of the first large-diameter beam pipe; And a variable-length pipe mechanism attached to the second large-diameter beam pipe so as to be located at least in front of and / or after the second radio wave absorber, and varies the pipe length of the second large-diameter beam pipe. Second pipe length A high-frequency accelerator having a variable mechanism. 3. A high-order mode detection means for picking up a high-order mode, and control means for controlling the variable pipe length mechanism based on an output of the high-order mode detection means. Or the high-frequency accelerator according to 2.