WO2007148004A1

WO2007148004A1 - Electromagnetic waveguide comprising a tool

Info

Publication number: WO2007148004A1
Application number: PCT/FR2007/051441
Authority: WO
Inventors: Alexej Grudiev
Original assignee: Organisation Europeenne Pour La Recherche Nucleaire
Priority date: 2006-06-23
Filing date: 2007-06-15
Publication date: 2007-12-27
Also published as: FR2902931B1; FR2902931A1

Abstract

A waveguide (1) for electromagnetic waves having at least one wavelength comprises a tool, for example a valve (2) separating two regions, suitable for maintaining a pressure difference between the two regions. The waveguide, at least near the valve, has a circular cross section and is designed in such a way that the main transmission modes are of the TE<SUB>0n</SUB>, where n is a natural integer.

Description

ELECTROMAGNETIC WAVE GUIDE COMPRISING A TOOL

The present invention relates to electromagnetic waveguides, and particularly to waveguides implemented in particle accelerator type devices.

Such waveguides are traversed by electromagnetic waves, and must ensure excellent transmission of electromagnetic waves. These waveguides can notably form circuits for acceleration of the particles.

It is sometimes necessary to maintain the vacuum within these waveguides in one part of the circuit, while having a pressure close to the atmospheric pressure in another part of the circuit. This makes it possible, in particular, to carry out maintenance on the parts under atmospheric pressure, for example by keeping the majority of the circuit at a pressure close to vacuum, or even the simultaneous use of the portion still under vacuum. However, the installation of valves in waveguides would cause disturbances and low RF wave transmission efficiency at the valve.

Similarly, it may be useful to install measuring instruments in these waveguides, but, as for the valves, such instruments arranged in the waveguide disrupt the transmission of electromagnetic waves.

The present invention is intended to overcome these disadvantages.

For this purpose, according to the invention, a waveguide for electromagnetic waves having at least one wavelength, comprises a tool disposed in the waveguide.

According to a current definition of the invention, the waveguide, at least in the vicinity of the tool, is sectioned circular and is dimensioned so that the main modes of transmission are of TE _0n , where n is a natural integer.

Thanks to these provisions, it ensures a good transmission efficiency of electromagnetic waves, while limiting the reflection type disturbances. Indeed, the transmission modes TE _0n circular section waveguides are used due to the absence of axial component of the surface currents (J _z = 0). This zero axial current component makes it possible to use circumferentially shaped tools, such as valves comprising a slot or a circumferential groove, without creating a coupling with this tool, or this slot during transmission. This slot can then be used to introduce the valve wall.

According to one embodiment of the waveguide according to the invention, the tool is a valve separating two zones, adapted to maintain a pressure difference between the two zones. This valve may be formed by a sliding wall in a circumferential groove, between an open position and a closed position. This ensures in a simple manner a hermetic closure between two sections of the waveguide. In addition, as seen above, due to the absence of axial component of surface current, the circumferential shape of the groove does not cause any coupling with the waves transmitted in the waveguide.

According to a variant of the waveguide according to the invention, if the width of the groove is much smaller than the wavelength of the guided electromagnetic waves, then the waveguide is sized so that the electromagnetic waves propagate. mainly with the TE ₀ I transmission mode. Thus, a single mode of transmission can be used to transmit the RF waves through the groove of the valve. When the valve is open, the transmission losses are mainly of two types. First of all reflections are to be expected at the groove. Then, due to the coupling of waves with the waveguide at the groove of other kinds are to be expected. These losses are small if the width of the groove is much smaller than the wavelength of the transmitted electromagnetic waves.

In order to further limit the reflections, it is also possible to provide in the waveguide an attenuation groove disposed at a distance from the groove of the valve, the distance being substantially equal to a quarter of the wavelength, and the attenuation groove being substantially identical to the groove of the valve. According to another variant of the invention, if the width of the groove is of the order of the wavelength of the electromagnetic waves guided, then the waveguide is sized so that the electromagnetic waves propagate mainly with a combination of transmission modes of the TE ₀ I and TE ₀ 2 type. • Indeed, in the case where the width of the groove is approximately equal to the wavelength, the coupling of the waves propagating according to the TE ₀ I mode is important. Transmission losses are high. To reduce this coupling, at least part of the single transmission mode is converted into a combination of two transmission modes TE ₀ I and TE ₀ 2. The amplitudes and the phase relationships of the two transmission modes are selected so as to reduce the transmission. minimum surface magnetic fields in the region of the groove. The magnetic field is then concentrated along the axis of symmetry of revolution of the waveguide, thus reducing the coupling with the groove.

According to another variant of the invention, if the width of the groove is much greater than the wavelength of the guided electromagnetic waves, then the waveguide such that electromagnetic waves propagate primarily with a combination of a plurality of TE-type transmission modes _0n - Amplitudes and phase relationships of transmission modes are selected to minimize fields surface magnetic in the region of the groove. The magnetic field is then concentrated along the axis of symmetry of revolution of the waveguide, thus reducing the coupling with the groove. According to the invention, the waveguide comprises a first and a second end section, sized so that the waves propagate according to at least one respective transmission mode, the valve being disposed in a median section between the end sections. Each end section is connected to the median section via a respective first and second transmission mode converters, which are adapted to convert the wave transmission modes in the respective first or second end sections to the mode. transmission of the median section. It is therefore possible, as we have seen previously, to convert the modes normally used in the waveguides (for example TEi ₀ , with a rectangular section) into modes ensuring good transmission at the valve. Thus, one can have first and second sections having a rectangular section, which are connected to the rest of the circuit, while ensuring excellent transmission.

According to a variant of the invention, the tool disposed in the waveguide is a measuring instrument. Thus, the measuring instrument only slightly disturbs the transmission of electromagnetic waves in the waveguide.

Other features and advantages of the invention will become apparent from the following description of one of its embodiments, given by way of non-limiting example, with reference to the accompanying drawings. In the drawings: FIGS. 1A-1C show schematically a waveguide according to a first embodiment of the invention; FIG. 2 diagrammatically represents a waveguide according to a second embodiment of the invention; FIG. 3 schematically represents a waveguide according to a third embodiment of the invention; Figure 4 schematically shows a waveguide according to a fourth embodiment of the invention.

In the different figures, the same references designate identical or similar elements.

During the propagation of electromagnetic waves in waveguides, the electric and magnetic fields composing these waves have particular orientations, as well as eigen modes of transmission. In waveguides with rectangular section or circular section, we note the free modes of the transverse electric fields TE _nm , where n and m are integers, defining the solutions of the propagation equation of the considered modes. In a rectangular section waveguide, n and m define the modes according to a Cartesian reference, arranged on the surfaces of the guide, while in a circular section waveguide, the modes are defined in a cylindrical coordinate system.

Depending on the values of n and m, the waves have different properties. In addition, it should be noted that the values of n and m are closely related to the dimensions of the waveguide considered.

FIG. 1A schematically represents a waveguide 1 in longitudinal section in accordance with the invention. This waveguide includes a tool arranged to the interior, for example a valve 2, formed of a wall 2a, sliding in a groove 2b. In Figure IA, the valve 2 is in the open position, leaving free the passage of electromagnetic waves. This tool can also be a malfunction monitoring device or a measuring instrument.

In FIG. 1B, the valve 2 is in the closed position, hermetically sealing the two zones. Thus, the vacuum can be maintained on one side of the wall 2a while leaving the other zone at atmospheric pressure. This allows the maintenance of the waveguide on the side at atmospheric pressure.

Due to the presence of the groove 2b, interference is expected, which can cause losses. If the wavelengths of the waves propagating in the waveguide are much greater than the width d of the groove, the dimensioning of the waveguide so that it is circular in section with a transmission TE ₀ I can greatly reduce transmission losses.

To further improve the transmission, it is possible to provide an attenuation groove 2c, as shown in Figure IC, separated from the groove 2b by a distance close to a quarter of the wavelength. Thus, the reflections of the waves arriving at the grooves are canceled.

According to a second embodiment of the invention illustrated in FIG. 2, when the wavelength is approximately equal to the width of the groove, the waveguide is dimensioned in the vicinity of the valve so that the modes of transmission are a combination of modes TE ₀ I and TE ₀ 2 • In order to minimize losses, the amplitudes and the phase relationships of the different modes of transmission in the vicinity of the valve 2 are determined. This minimizes the magnetic fields surface areas in the groove 2b region. The magnetic field is then concentrated along the axis of symmetry of revolution X of the waveguide, thus reducing the coupling with the groove 2b. It is not necessary to impose such modes of transmission throughout a waveguide circuit. With the structure illustrated in FIG. 2, one can convert circular transmission modes TE ₀ I present at extreme sections into said combination of modes at the level of the valve 2. In fact, the waveguide 1 comprises a median section. 3 in which the valve 2 is disposed. This median section 3 is sized to transmit the waves according to the combination of the TE ₀ I and TE ₀ 2 modes. The extremal sections 4 a and 4 b are adapted to the transmission modes of the rest of the guide circuit. wave not shown, here a mode TE ₀ I circular section. Each extremal section is connected to the median section by a transmission mode converter 5a and 5b. This ensures compatibility of the transmission with conventional waveguide circuits.

Thus, according to the third embodiment illustrated in FIG. 3, mode converters 5a and 5b adapted to extremal sections 4a and 4b with a rectangular section can be used. Indeed, the transmission mode TEi ₀ rectangular section is used very commonly in the waveguides.

According to a fourth embodiment, the median section 3 is sized to ensure a transmission formed by a combination of eigenmodes TE _0n , for example, n ranging from 1 to 5. The amplitudes and the phases of the modes of transmission are chosen in order to focus the magnetic fields at the longitudinal axis X.

This is possible by imposing pre-determined boundary conditions in the design of the waveguide.

This embodiment is particularly advantageous when the wavelength is much less than the width of the groove, that is to say for high frequencies. It is obvious that the extremal sections may, according to the third embodiment, be adapted to transmit waves in a transmission mode TEi ₀ to rectangular section or other. In this way, these sections are compatible with commonly used waveguides.

This ensures a good transmission of electromagnetic waves at the valve.

In place of the valve, it is possible to provide for each of the previous embodiments measuring instruments, such as electromagnetic radiation detectors. Thanks to the provisions of the invention, these measuring instruments do not disturb the transmission of electromagnetic waves.

Claims

A waveguide (1) for electromagnetic waves having at least one wavelength, comprising a tool (2) disposed in a section of the waveguide, and the waveguide being, at least in a the vicinity of the tool, of circular section and dimensioned so that the main transmission modes are of the TE _0n type, where n is a natural integer, said waveguide being characterized in that the tool is a valve ( 2) separating two zones, adapted to maintain a pressure difference between the two zones, and formed by a wall (2a) sliding in a circumferential groove (2b) between an open position and a closed position.

2. waveguide (1) according to claim 1, wherein the width of the groove (2b) is much smaller than the wavelength of the guided electromagnetic waves, and wherein the waveguide is dimensioned such so that the electromagnetic waves propagate mainly with a TE ₀ I type transmission mode.

The waveguide (1) according to claim 1, wherein the width of the groove (2b) is of the order of the wavelength of the guided electromagnetic waves, and wherein the waveguide is sized so that the electromagnetic waves propagate mainly with a combination of TE ₀ I and TE ₀₂ transmission modes.

A waveguide (1) as claimed in claim 1, wherein the width of the groove (2b) is much greater than the wavelength of the guided electromagnetic waves, and wherein the waveguide is dimensioned such that so that electromagnetic waves propagate mainly with a combination of a plurality of TE _0n transmission modes -

5. Waveguide (1) according to any one of the preceding claims, comprising a first and a second extremal section (4a, 4b), sized so that the waves propagate in each of said end sections according to at least one embodiment. respective transmission, the valve (2) being arranged in a median section (3) between the extremal sections, the median section being dimensioned so that the waves propagate according to a transmission mode TE _0n , each extremal section being connected to the median section by via first and second converters (5a, 5b) of respective transmission modes adapted to convert the wave transmission modes in the respective first or second end sections to the transmission mode of the middle section.

6. waveguide (1) according to claim 5, wherein the first and second end sections (4a, 4b) have a rectangular section.

Waveguide (1) according to any of the preceding claims taken in combination with claim 3, comprising an attenuation groove (2c) disposed at a distance from the groove (2b) of the valve (2). , the distance being substantially equal to a quarter of the wavelength, the attenuation groove being substantially identical to the groove of the valve.

8. Waveguide (1) for electromagnetic waves having at least one wavelength, comprising a tool (2) disposed in a section of the waveguide, and the waveguide being, at least in a Neighborhood of the tool, section circular and dimensioned so that the main transmission modes are of the TE _0n type, where n is a natural integer, said waveguide being characterized in that the tool is a measuring instrument adapted to perform measurements in the waveguide.

A waveguide according to claim 8, comprising first and second end sections (4a, 4b) sized to propagate waves in each of said end portions in at least one respective transmission mode, the valve (2). ) being disposed in a median section (3) between the extremal sections, the median section being dimensioned so that the waves propagate according to a transmission mode TE _0n , each extremal section being connected to the median section via a first and a second respective transmission mode converters (5a, 5b) adapted to convert the wave transmission modes in the respective first or second end sections to the transmission mode of the middle section.

Waveguide according to claim 9, wherein the first and second end sections (4a, 4b) have a rectangular section.