CN215680602U - Waveguide energy transmission structure for traveling wave tube and traveling wave tube - Google Patents

Abstract

The utility model provides a waveguide energy transmission structure for a traveling wave tube and the traveling wave tube, wherein the waveguide energy transmission structure comprises an energy transmission window; the first output waveguide is positioned on one side of the energy transmission window and connected with the slow wave structure of the traveling wave tube; and a second output waveguide located on the other side of the energy delivery window; a step waveguide transmission structure arranged along the transmission direction of the waveguide is formed on the inner wall of the first output waveguide; the first output waveguide comprises a through hole which is arranged opposite to the step waveguide transmission structure; the waveguide energy transmission structure also comprises an inner conductor; the inner conductor penetrates through the through hole and is fixedly combined with the end face, close to the through hole, of the stepped waveguide transmission structure; the axis of the inner conductor is perpendicular to the transmission direction of the waveguide. The size of the traveling wave tube can be reduced through the waveguide energy transmission structure.

Description

Waveguide energy transmission structure for traveling wave tube and traveling wave tube

Technical Field

The utility model relates to the technical field of microwave vacuum electronic devices. And more particularly, to a waveguide energy transfer structure for a traveling wave tube and a traveling wave tube.

Background

The traveling wave tube is a microwave vacuum electronic device, can amplify signals of different frequency bands, has the characteristics of high power, wide frequency band, high gain and high efficiency, and is widely applied to the fields of electronic countermeasure, radar, satellite communication and the like. As shown in fig. 5, the traveling wave tube is mainly composed of five parts, namely an electron gun, a focusing magnetic system, a slow wave structure, an input-output coupler device and a collector. The working principle is that the electron gun generates an electron beam with required size and current, the electron beam passes through a slender slow wave structure after coming out of the electron gun, and a high-frequency signal enters a traveling wave tube through an input coupler device to form a traveling wave transmitted along the slow wave structure. The task of the slow wave structure is to reduce the phase velocity of the electromagnetic wave to be substantially the same as the moving velocity of the electrons, so that the electron beam and the electromagnetic wave interact to exchange energy. Due to the focusing effect of the magnetic field, the electron beam advances in the slow wave structure along the axial direction of the slow wave structure, the electron advancing process is accompanied with the interaction with the electromagnetic wave, the kinetic energy of the electrons is converted into the energy of the electromagnetic wave, and therefore the energy amplification of the input high-frequency signal is achieved. The high-frequency signal is output through the output coupler device, and the electrons giving out most of energy are finally sent to the collector to be converted into heat energy.

However, the size and weight of the conventional traveling wave tube are too large to be easily processed and maintained, and the size of the traveling wave tube is gradually reduced as the application fields are developed.

SUMMERY OF THE UTILITY MODEL

In view of the above problems, it is an object of the present invention to provide a waveguide energy transmission structure for a traveling-wave tube, by which the size of the traveling-wave tube can be reduced.

In order to achieve the purpose, the utility model adopts the following technical scheme:

the utility model provides a waveguide energy transmission structure for a traveling wave tube, which comprises:

an energy transmission window;

the first output waveguide is positioned on one side of the energy transmission window and connected with the slow wave structure of the traveling wave tube; and

a second output waveguide located on the other side of the energy delivery window;

a step waveguide transmission structure arranged along the transmission direction of the waveguide is formed on the inner wall of the first output waveguide;

the first output waveguide comprises a through hole which is arranged opposite to the step waveguide transmission structure;

the waveguide energy transmission structure also comprises an inner conductor;

the inner conductor penetrates through the through hole and is fixedly combined with the end face, close to the through hole, of the stepped waveguide transmission structure; the axis of the inner conductor is perpendicular to the transmission direction of the waveguide.

Furthermore, it is preferable that the first output waveguide, the second output waveguide, and the power transmission window are coaxially disposed.

In addition, it is preferable that the feeding mode of the waveguide energy transmission structure is a feedback mode.

In addition, it is preferable that an end of the second output waveguide close to the energy transmission window includes a first waveguide flange; the cross section of the first waveguide flange is rectangular.

Furthermore, it is preferred that the first waveguide flange has dimensions of 19.1mm by 14mm by 1.2 mm.

In addition, it is preferable that the inner conductor and the step waveguide transmission structure are fixed by soldering.

In addition, it is preferable that the energy transmission window includes a butt joint structure thereon for flange connection with the first waveguide; the size of the butt-joint structure is 19.1mm 14mm 1.8 mm.

Furthermore, it is preferable that the outer diameter of the energy transmission window is 15.5 mm.

Another object of the present invention is to provide a traveling-wave tube including the waveguide energy transmission structure as described above.

In addition, preferably, the traveling wave tube includes a first connecting piece fixed to the slow wave structure, the first output waveguide includes a second connecting piece, and the first connecting piece and the second connecting piece are fixed to each other.

The utility model has the beneficial effects that:

according to the utility model, the transmission of signals is realized through the connection of the stepped waveguide transmission structure and the inner conductor, and meanwhile, the axis of the inner conductor is vertical to the transmission direction of the waveguide, so that the signal transmission direction is directly changed to 90 degrees without additionally using other accessories to realize the steering of the transmission signals, the distance between the waveguide energy transmission structure and the traveling wave tube is greatly shortened, the size of the traveling wave tube is effectively reduced, the miniaturization of the traveling wave tube is promoted, and the application range of the traveling wave tube is expanded.

Drawings

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic diagram of the structure of a first output waveguide of the present invention.

Fig. 3 is a schematic view of the utility model in conjunction with a collector.

Fig. 4 is a schematic diagram of a waveguide switching structure in the prior art.

FIG. 5 is a schematic structural view of a traveling wave tube.

Detailed Description

Various exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It should be noted that: the relative arrangement of the components and steps, the numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present invention unless specifically stated otherwise.

The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the utility model, its application, or uses.

Techniques and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail, but are intended to be considered a part of the specification where appropriate.

In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, further discussion thereof is not required in subsequent figures.

Compared with a solid-state microwave amplifier, the conventional traveling wave tube can provide enough output power, but the operating voltage is required to be increased, so that the conventional traveling wave tube is not convenient to use by power up in practical operation. In addition, the size and weight of the traveling wave tube are too large for the user to use. Therefore, in response to the challenges of solid-state microwave amplifiers, there is an increasing need to develop practical low-voltage, high-reliability miniaturized traveling-wave tubes. The Microwave Power Module (MPM) adopts a solid-state amplifier as an exciting stage and a traveling wave tube as an output stage, integrates the solid-state amplifier and the traveling wave tube, has the advantages of a solid-state device and an electric vacuum device, and is widely applied to various military and civil fields such as electronic weapon equipment systems, satellite communication and the like. The development of MPM also requires the traveling wave tube to be more and more miniaturized. The traveling wave tube is designed in a miniaturized mode, and the application range of the traveling wave tube can be expanded.

Miniaturization of the traveling wave tube can be achieved by individually miniaturizing the length (L), height (H), and width (W) thereof. For example, the length can be satisfied by shortening the slow-wave structure, and the height can be satisfied by reducing the radial dimensions of its electron gun, high-band, and collector; in comparison, it is difficult to miniaturize the width of the traveling wave tube. The reasonable width of the miniaturized traveling wave tube is necessary for fully utilizing the internal space of the MPM and improving the integration level of the MPM. The input and output device of the traveling wave tube, i.e. the energy transmission structure, plays an important role in determining the width dimension of the traveling wave tube.

The output structure of the traveling wave tube is a structural part which outputs the radio-frequency signal amplified by the traveling wave tube to the next stage of equipment. Generally, a coaxial structure is adopted when the frequency is lower or the power is lower; otherwise, a waveguide structure is used. For millimeter wave band high power (output power is tens watt level or more) traveling wave tube, the signal output part adopts waveguide structure.

Referring to fig. 4, the distance from the outer edge of the energy transmission structure of the waveguide in the prior art to the axial center line of the traveling wave tube is 40.47mm, and the distance from the transverse central axis of the energy transmission structure of the waveguide in the prior art to the axial center line of the traveling wave tube is 27.72 mm. The size of the traveling wave tube is overlarge; and the rightmost waveguide assembly can not be disassembled and assembled, and can not be recycled repeatedly, so that the cost of the traveling wave tube is increased.

And the feed mode of the conventional waveguide energy transmission structure adopts a direct feed mode, namely, the inner conductor is parallel to the transmission direction of the stepped waveguide in the waveguide on the left side of the energy transmission window, and in order to realize the axial output power of the traveling wave tube, the bent waveguide needs to be additionally added, so that the size of the traveling wave tube is further increased. In addition, the energy transmission window in the prior art is arranged outside the collector, so that the size of the traveling wave tube is increased.

In order to reduce the size of the traveling wave tube, the progress of miniaturization of the traveling wave tube is promoted. The utility model provides a waveguide energy transmission structure for a traveling wave tube, which is shown in fig. 1 to 3, and specifically comprises: an energy delivery window 11; a first output waveguide 12 located on one side of the energy transmission window 11 and connected with the slow wave structure of the traveling wave tube; and a second output waveguide 13 on the other side of the power delivery window 11; a step waveguide transmission structure 121 arranged along the transmission direction of the waveguide is formed on the inner wall of the first output waveguide 12; the first output waveguide 12 comprises a through hole 122 opposite to the step waveguide transmission structure 121; the waveguide energy transmission structure 10 further comprises an inner conductor 14; the inner conductor 14 passes through the through hole 122 and is fixedly combined with the end face, close to the through hole 122, of the stepped waveguide transmission structure 121; the axis of the inner conductor 14 is perpendicular to the direction of propagation of the waveguide. In this embodiment, a stepped impedance transformation step, i.e., a stepped waveguide transmission structure 121, is designed in the waveguide cavity of the first output waveguide 12, and then the inner conductor 14 is fixed on the highest impedance transformation step, i.e., the inner conductor 14 is combined and fixed with the end surface of the stepped waveguide transmission structure 121 close to the through hole 122, so as to implement impedance transformation from a coaxial low impedance to a waveguide high impedance and transmission mode conversion from a coaxial TEM mode to a waveguide TE mode. The inner conductor 14 is perpendicular to the waveguide transmission direction, so that the traveling wave tube omits a bent waveguide, thereby reducing the size of the traveling wave tube.

In order to reduce the width and height of the traveling wave tube and promote the miniaturization of the traveling wave tube, specifically, the distance from the outer edge of the waveguide energy transmission structure 10 to the axial center line of the traveling wave tube is 24.45mm, while the distance in the prior art is 40.47mm, the distance is reduced by 40% in the utility model; the distance from the transverse central axis of the waveguide energy transmission structure 10 to the axial central line of the traveling wave tube is 14.88mm, and compared with the 27.72mm in the prior art, the distance is reduced by 46%. Therefore, the size of the traveling wave tube is effectively reduced, and the size occupied by the waveguide energy transmission structure 10 on the height of the traveling wave tube is reduced from 22.7mm to 19.1mm, reduced by 3.6mm and reduced by 16%. Therefore, the miniaturization of the traveling wave tube is facilitated, and the application scenes of the traveling wave tube are widened.

It can be understood that the energy transmission window 11 is an important component of the power output of the traveling wave tube, and the energy transmission window 11 plays a role in isolating the vacuum environment in the tube from the external atmosphere and ensuring that the radio frequency signal can pass through with low loss; a second output waveguide 13 is connected behind the power transmission window 11 for connection to an external structure.

In a specific embodiment, the waveguide energy transmission structure 10 is fed in a feedback manner. The feed mode of waveguide conversion is changed from a direct feed mode to a backward feed mode, namely, an inner conductor is perpendicular to the transmission direction of a stepped waveguide transmission structure in a first output waveguide, the backward feed type waveguide transmission can enable a traveling wave tube to save bent waveguides, signal transmission direction conversion is directly achieved by 90 degrees, the first output waveguide 12, the second output waveguide 13 and the energy transmission window 11 are coaxially arranged, axial output of signals of the traveling wave tube is achieved by overlapping and butting of transverse center lines, the distance from a transverse central axis of the waveguide energy transmission structure 10 to the axial center line of the traveling wave tube is reduced from 27.72mm to 14.88mm and reduced by 45%, and therefore the size of the traveling wave tube is reduced.

In a specific embodiment, the inner conductor 14 and the step waveguide transmission structure 121 are fixed by soldering. The lower end of the inner conductor 14 is welded and fixed with the spiral line of the traveling wave tube through the transition antenna, and good matching between the slow wave structure and the energy transmission structure is guaranteed. The upper end of the inner conductor 14 is vertically inserted into the end face of the stepped waveguide transmission structure 121 close to the through hole 122, that is, the highest stepped impedance transformation step of the stepped waveguide transmission structure 121, and the stepped impedance transformation step is provided with a matching hole, and the inner conductor 14 is fixed in the matching hole by soldering.

In a specific embodiment, one end of the second output waveguide 13 close to the energy transmission window 11 comprises a first waveguide flange 131; the first waveguide flange 131 has a rectangular cross section. In this embodiment, the first waveguide flange 131 has dimensions of 19.1mm by 14mm by 1.2 mm. In order to facilitate miniaturization of the traveling wave tube, the second output waveguide 13 is a long and thin straight waveguide at the middle position, and a first waveguide flange 131 and a standard waveguide flange are respectively provided at both ends. The end face of the first waveguide flange 131 is rectangular 19.1mm by 14mm, and the area of the first waveguide flange 131 is reduced 1/3 compared with the size phi 22.7mm of a circular waveguide flange abutting against the energy transmission window 11 in the prior art. The highest position in the height direction of the traveling wave tube is a waveguide flange butted with the energy transmission window 11, the end face of the standard waveguide flange is a square with the length of 19.1mm, when the energy transmission window 11 is butted with the second output waveguide 13, in order to not increase the height dimension of the traveling wave tube and reduce the width dimension of the traveling wave tube, the long side (19.1mm) of the first waveguide flange 131 is placed in the height direction of the traveling wave tube, the short side (14mm) is placed in the width direction of the traveling wave tube, the occupied size in the height direction of the traveling wave tube is reduced from 22.7mm to 19.1mm, the occupied size is reduced by 3.6mm and 16%, and the occupied size in the width direction of the traveling wave tube is reduced from 22.7mm to 14mm and is reduced by 38%.

Meanwhile, in order to place the energy transmission window 11 and the first waveguide flange 131 in a narrow space between the collector 20 and the inner conductor 14 so as to further reduce the width dimension of the traveling wave tube, the first waveguide flange 131 is designed to be thin, so that the thickness of the first waveguide flange is only 1.2mm, which is 1/2 of the thickness of the conventional flange.

In a specific embodiment, the energy transmission window 11 includes a docking structure 111 for connecting with the first waveguide flange 131; the size of the docking structure 111 is 19.1mm 14mm 1.8 mm. In order to match with the detachable screw installation of the first waveguide flange 131, the butt joint structure 111 with a rectangular cross section is added on the energy transmission window 11, the size of the butt joint structure 111 is 19.1mm × 14mm × 1.8mm, the position of the butt joint structure 111 is designed in the middle of the energy transmission window 11, the thickness size of the energy transmission window 11 is not occupied, the energy transmission window 11 and the first waveguide flange 131 can be placed in a narrow space in front of the collector 20, and therefore the size reduction of the traveling wave tube is facilitated.

In a specific embodiment, the second output waveguide 13 is screwed with the energy transmission window 11, so that the second output waveguide 13 is detachable and reusable, and the cost of the traveling wave tube is reduced. Specifically, after the energy transmission window 11 and the second output waveguide 13 are fitted on the mating surface, the docking structure 111 fixed in the middle of the energy transmission window 11 and the first waveguide flange 131 are connected and fixed by 4 screws passing through corresponding threaded holes.

In a specific embodiment, the size of the outer diameter of the energy transmission window 11 is 15.5 mm. In order to further reduce the width and height dimensions of the traveling wave tube. The energy transmission window 11 is designed in a miniaturized structure, the size of the energy transmission window 11 is reduced, the size of the energy transmission window 11 in the width direction of the traveling wave tube is phi 15.5mm, compared with the existing energy transmission window with the outer diameter of phi 22.7mm, the size of the energy transmission window 11 in the width direction of the traveling wave tube is reduced by 1/3, and the size of the energy transmission window 11 in the height direction of the traveling wave tube is reduced from 22.7mm to 15.5mm and is reduced by 7.2 mm. The size of the energy transmission window 11 after being butted with the first waveguide flange 131 is phi 15.5mm 7.03mm, and compared with the size phi 22.7mm 12.41mm in the prior art, the volume is reduced by 2/3. Compared with the layout of the existing energy transmission window arranged outside the collector, the size of the traveling wave tube adopting the waveguide energy transmission structure 10 is obviously smaller.

It can be understood that the first output waveguide 12 and the energy transmission window 11 are welded and fixed through argon arc welding, so that air tightness is ensured; the first waveguide flange 131 is fixed to the matching portion of the straight waveguide and the standard waveguide flange by brazing to form the second output waveguide 13, and the second output waveguide 13 does not need to be airtight. Through the arrangement, the connection between the waveguide energy transmission structure 10 for the traveling wave tube and the high frequency band of the traveling wave tube is completed, the power output is realized in the axial direction of the traveling wave tube, the miniaturization of the traveling wave tube is promoted, and the cost of the traveling wave tube is reduced.

The embodiment of the utility model also discloses a traveling wave tube with the waveguide energy transmission structure 10, which has the characteristic of miniaturization. After the traveling wave tube with the waveguide energy transmission structure 10 is tested, the voltage standing wave ratio of the structure reaches below 1.4 within a frequency band of 26 GHz-40 GHz, and a good impedance matching level is achieved.

In addition, the traveling wave tube comprises a first connecting piece 15 fixedly combined with the slow wave structure, the first output waveguide comprises a second connecting piece 16, and the first connecting piece 15 and the second connecting piece 16 are fixedly combined. The first connecting piece 15 and the second connecting piece 16 are both cylindrical, the second connecting piece 16 is fixedly sleeved in the first connecting piece 15, specifically, an annular boss is formed in the first connecting piece 15, and the bottom edge of the second connecting piece 16 is abutted to the annular boss; the inner conductor 14 passes through a cavity formed by the first connecting piece 15 and the second connecting piece 16, and the bottom of the inner conductor 14 is welded with the spiral line of the slow-wave structure in an overlapping mode.

In summary, the utility model realizes signal transmission by connecting the stepped waveguide transmission structure with the inner conductor, and the axis of the inner conductor is perpendicular to the transmission direction of the waveguide, thereby directly realizing 90-degree signal transmission direction conversion without additionally using other accessories to realize signal transmission steering, greatly shortening the distance between the waveguide energy transmission structure and the transverse central axis of the traveling wave tube, effectively reducing the size of the traveling wave tube, promoting the miniaturization of the traveling wave tube, and expanding the application range of the traveling wave tube. In addition, the fixing mode between the second output waveguide and the energy transmission window is improved from conventional argon arc welding to detachable screw connection, so that recycling is realized, and the manufacturing cost of the traveling wave tube is reduced.

It should be understood that the above-mentioned embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention, and it will be obvious to those skilled in the art that other variations or modifications may be made on the basis of the above description, and all embodiments may not be exhaustive, and all obvious variations or modifications may be included within the scope of the present invention.

Claims (10)

1. A waveguide energy delivery structure for a traveling wave tube, comprising:

an energy transmission window;

the first output waveguide is positioned on one side of the energy transmission window and connected with the slow wave structure of the traveling wave tube; and

a second output waveguide located on the other side of the energy delivery window;

a step waveguide transmission structure arranged along the transmission direction of the waveguide is formed on the inner wall of the first output waveguide;

the first output waveguide comprises a through hole which is arranged opposite to the step waveguide transmission structure;

the waveguide energy transmission structure also comprises an inner conductor;

the inner conductor penetrates through the through hole and is fixedly combined with the end face, close to the through hole, of the stepped waveguide transmission structure; the axis of the inner conductor is perpendicular to the transmission direction of the waveguide.

2. The waveguide energy delivery structure for a traveling wave tube according to claim 1, wherein the first output waveguide, the second output waveguide, and the energy delivery window are coaxially disposed.

3. The waveguide energy transfer structure for a traveling wave tube according to claim 1, wherein the feeding manner of the waveguide energy transfer structure is a back feeding type.

4. The waveguide energy delivery structure for a traveling wave tube of claim 1, wherein an end of the second output waveguide near the energy delivery window comprises a first waveguide flange; the cross section of the first waveguide flange is rectangular.

5. A waveguide energy transfer structure for a traveling wave tube according to claim 4, wherein the first waveguide flange has dimensions of 19.1mm by 14mm by 1.2 mm.

6. The waveguide energy delivery structure for a traveling-wave tube according to claim 1, wherein the inner conductor and the stepped waveguide energy delivery structure are fixed by brazing.

7. The waveguide energy delivery structure for a traveling wave tube according to claim 4, wherein the energy delivery window includes a docking structure thereon for flange connection with the first waveguide; the size of the butt-joint structure is 19.1mm 14mm 1.8 mm.

8. The waveguide energy delivery structure for a traveling wave tube according to claim 1, wherein the outer diameter dimension of the energy delivery window is 15.5 mm.

9. A traveling wave tube comprising the waveguide energy delivery structure according to any of claims 1-8.

10. The traveling-wave tube according to claim 9, comprising a first connector fixedly coupled to the slow-wave structure, and a second connector fixedly coupled to the first connector, wherein the first output waveguide comprises a second connector.

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