CN209329127U - A kind of telescopic waveguide and accelerator system - Google Patents

Abstract

The utility model relates to microwave device technology field, in particular to a kind of telescopic waveguide and acceleration system, the telescopic waveguide include: first wave conduit；Second waveguide pipe, the second waveguide tube portion cover on the first wave conduit, and the second waveguide pipe can be relative to the straightforward sliding of first wave conduit；First choke structure is arranged in the first wave conduit and/or the second waveguide pipe；When work, first choke structure is located at the second waveguide pipe and the first wave conduit overlapping interval.It stretches by the above-mentioned means, the utility model embodiment can be such that waveguide length realizes.

Description

A kind of telescopic waveguide and accelerator system

Technical field

The utility model embodiment is related to microwave device technology field, particularly, is related to a kind of telescopic waveguide and acceleration Device system.

Background technique

Microwave device refer to work in the device of microwave band (frequency be 300~300000 megahertzs), such as: waveguide is exactly For the microwave device of directional guide microwave frequency electromagnetic wave.By circuit design, these combination of devices there can be spy at various Determine the microwave circuit of function, for example, being assembled into transmitter, receiver, antenna system, display etc. using these devices, is used for The electronics such as radar, electronic warfare system and communication system.Microwave device has very in field of radar, accelerator field and military affairs It is widely applied.

The inventor of the utility model has found in the practice of the invention: existing microwave device is applied mostly quiet The only equipment of state, such as accelerator system.Microwave device relative power source be it is static, after being installed, microwave device and The relative position of accelerating tube will be unable to change, and length can not change by the way that linear movement is flexible.But with the development of science and technology, The linear movement demand of waveguide device is increasing.

Summary of the invention

In view of the above drawbacks of the prior art, the main purpose of the utility model is to provide a kind of telescopic waveguide and acceleration Device system realizes that waveguide length can stretch change.

In order to solve the above technical problems, the technical solution that the utility model uses is: providing a kind of telescopic waveguide, wrap It includes:

First wave conduit；

Second waveguide pipe, second waveguide tube portion cover on first wave conduit, and second waveguide pipe can be relative to first The straightforward sliding of waveguide；

First choke structure is arranged in first wave conduit and/or second waveguide pipe；When work, the first choke structure is located at Second waveguide pipe and first wave conduit overlapping interval.

Optionally, the first choke structure shifts for realizing short-circuit face, when preventing microwave transmission, in first wave conduit and It leaks two waveguide junctions.

Optionally, the periphery wall of first wave conduit is arranged in the first choke structure, and the quantity of the first choke structure is at least One.

Optionally, the internal perisporium of second waveguide pipe is arranged in the first choke structure, and the quantity of the first choke structure is at least One.

Optionally, the quantity at least two of the first choke structure, the periphery wall of first wave conduit is at least provided with one One choke structure, the internal perisporium of second waveguide pipe is at least provided with first choke structure.

Optionally, setting includes the first choke groove and the second choke groove in supravasal first choke structure of first wave；

First choke groove is set on the periphery wall of first wave conduit, and around first wave conduit；

Second choke groove is set between the internal perisporium and periphery wall of first wave conduit, and around first wave conduit；

One end of second choke groove is connected to the first choke groove, and the one side wall of the second choke groove and the first choke groove Slot bottom is concordant.

Optionally, the first choke structure being arranged on second waveguide pipe includes the first choke groove and the second choke groove, the One choke groove is set on the internal perisporium of second waveguide pipe, and around second waveguide pipe；

Second choke groove is set between the internal perisporium and periphery wall of second waveguide pipe, and around second waveguide pipe；

One end of second choke groove is connected to the first choke groove, and the one side wall of the second choke groove and the first choke groove Slot bottom is concordant.

Optionally, first wave conduit and second waveguide pipe are round tube.

Optionally, first wave conduit and second waveguide pipe are rectangular tube.

Optionally, second waveguide pipe and first wave guide interface tube end caliber size are in step variation.

Optionally, at least one first choke structure is divided into several segments, and several segments are respectively arranged on the periphery wall of first wave conduit With the internal perisporium of second waveguide pipe, several segments combination is projected as surrounding in the cross section of first wave conduit or second waveguide pipe Shape.

In order to solve the above technical problems, the technical solution that the utility model uses is: another telescopic waveguide is provided, Include:

First wave conduit；

Second waveguide pipe, first wave conduit and second waveguide tube portion are socketed, and second waveguide pipe can be relative to first The straightforward sliding of waveguide；

First choke structure is arranged in first wave conduit and/or second waveguide pipe；When work, the first choke structure is located at Second waveguide pipe and first wave conduit overlapping interval；

Third waveguide, second waveguide pipe and third waveguide section are socketed, and third waveguide can be relative to second The straightforward sliding of waveguide；

Second choke structure is arranged in second waveguide pipe and/or third waveguide；When work, the second choke structure is located at Second waveguide pipe and third waveguide overlapping interval.

Optionally, first wave conduit and third waveguide are partially covered respectively at two ends of second waveguide pipe.

Optionally, two ends of second waveguide pipe are respectively fitted on first wave conduit and third waveguide.

In order to solve the above technical problems, the technical solution that the utility model uses is: a kind of accelerator system is provided, It include: microwave power source, accelerating tube and above-mentioned telescopic waveguide.

The beneficial effect of the utility model embodiment is: the waveguide being different from the prior art, which can only rotate, can not achieve line Property flexible the case where changing length, the utility model embodiment passes through setting first wave conduit and second waveguide pipe, the second wave Conduit portion covers on the second first wave conduit, and second waveguide pipe can relative to the straightforward sliding of first wave conduit, first Waveguide and/or second waveguide pipe overlay region are provided with the first choke structure, for realizing the transfer of short-circuit face, when microwave signal exists When transmitting in the waveguide, prevent microwave from leaking in the junction of first wave conduit and second waveguide pipe, so that this is flexible when reaching Waveguide enables its length to stretch change by the linear movement of first wave conduit and second waveguide pipe.

Detailed description of the invention

It, below will be right in order to illustrate more clearly of specific embodiment of the present invention or technical solution in the prior art Specific embodiment or attached drawing needed to be used in the description of the prior art are briefly described.In all the appended drawings, similar Element or part are generally identified by similar appended drawing reference.In attached drawing, each element or part might not be according to actual ratios It draws.

Fig. 1 is the local exploded-view of the utility model telescopic waveguide embodiment；

Fig. 2 is the main view of the utility model telescopic waveguide embodiment；

Fig. 3 is the explosive view of the utility model telescopic waveguide embodiment；

Fig. 4 is the utility model telescopic waveguide embodiment A-A cross-sectional view；

Fig. 5 is the portion the utility model telescopic waveguide embodiment B the first choke structure partial enlargement diagram；

Fig. 6 is the A-A cross-sectional view of another embodiment of the utility model telescopic waveguide；

Fig. 7 is the explosive view of another embodiment of the utility model telescopic waveguide.

Specific embodiment

It is described in detail below in conjunction with embodiment of the attached drawing to technical solutions of the utility model.Following embodiment is only For clearly illustrating the technical solution of the utility model, therefore it is only used as example, and it is originally practical to cannot be used as a limitation limitation Novel protection scope.

It should be noted that unless otherwise indicated, technical term or scientific term used in this application should be this reality The ordinary meaning understood with novel one of ordinary skill in the art.

In the description of the present application, it is to be understood that the orientation of the instructions such as term " center ", " length " "inner", "outside" Or positional relationship is to be based on the orientation or positional relationship shown in the drawings, and is merely for convenience of description the utility model and simplification is retouched It states, rather than the device or element of indication or suggestion meaning must have a particular orientation, be constructed and operated in a specific orientation, Therefore it should not be understood as limiting the present invention.

In addition, term " first ", " second " etc. are used for description purposes only, it is not understood to indicate or imply relatively important Property or implicitly indicate the quantity of indicated technical characteristic.The meaning of " plurality " is two in the description of the present invention, More than, unless otherwise specifically defined.

In this application unless specifically defined or limited otherwise, term " installation ", " connected ", " connection ", " fixation " etc. Term shall be understood in a broad sense, for example, it may be being fixedly connected, may be a detachable connection, or integral；It can be mechanical connect It connects, is also possible to be electrically connected；It can be directly connected, can also can be in two elements indirectly connected through an intermediary The interaction relationship of the connection in portion or two elements.It for the ordinary skill in the art, can be according to specific feelings Condition understands the concrete meaning of above-mentioned term in the present invention.

In this application unless specifically defined or limited otherwise, fisrt feature in the second feature " on " or " down " may be used To be that the first and second features directly contact or the first and second features pass through intermediary mediate contact.Moreover, fisrt feature But fisrt feature is directly above or diagonally above the second feature above the second feature " above ", " above " and " above ", or only table Show that first feature horizontal height is higher than second feature.Fisrt feature can be under the second feature " below ", " below " and " below " Fisrt feature is directly under or diagonally below the second feature, or is merely representative of first feature horizontal height less than second feature.

In one embodiment, referring to Fig. 1, a kind of telescopic waveguide 100, comprising: the first coupler 10, first wave conduit 20, the first connector 30, second waveguide pipe 40, the first choke structure 45, the second connector 50 and the second coupler 60.First coupling Clutch 10 is connect with one end of first wave conduit 20, and the other end of first wave conduit 20 and one end of second waveguide pipe 40 are socketed, The other end of second waveguide pipe 40 is connect with the second coupler 60.

Specifically, as shown in Figures 1 to 5:

For above-mentioned first coupler 10, it is equipped with the first connectivity port 11.

It is hollow round tube for above-mentioned first wave conduit 20, one end of first wave conduit 20 is equipped with first entrance end 21, the other end is equipped with first exit end 22, the direction of the mouth of the internal perisporium of first exit end 22 radially away from first entrance end 21 Ascending is in step variation, and first wave conduit 20 is connected to the first connectivity port 11 by first entrance end 21, and leads to The mode for crossing welding makes first wave conduit 20 and the first coupler 10 be fixed together.Certain first wave conduit 20 is coupled with first Device 10 can also be by integrally formed mode as one.

For above-mentioned first connector 30, the first of the first coupler 10 is installed on by the modes such as being socketed or weld and is connected The periphery wall of the periphery wall of port 11 or the first entrance end 21 of first wave conduit 20 is connect, at work, the first connector is also It is connected with other external components, to be used to support first wave conduit 20 and the first coupler 10.

It is hollow round tube for above-mentioned second waveguide pipe 40, the bore of internal perisporium is slightly larger than first wave conduit 20 Periphery wall bore, one end be equipped with second entrance end 41, the other end be equipped be equipped with second outlet end 42, second outlet end 42 Internal perisporium mouth radially away from second entrance end 41 direction it is ascending be in step variation, second entrance end 41 is socketed on Outside first exit end 22, so that 40 part of second waveguide pipe is socketed on first wave conduit 20, and second waveguide pipe 40 can phase To the straightforward sliding of first wave conduit 20, change length by flexible between the two to realize.

It should be understood that the bore of the internal perisporium of first exit end 22 be in step variation, second outlet end 42 it is interior The bore of peripheral wall is in step variation, is the first wave conduit 20 and the second wave in order to keep microwave different in internal perisporium caliber size It is in the structure of step variation by internal perisporium bore when being transmitted between conduit 40, is superimposed the reflection between microwave and offsets, from And microwave is made to be at the state of matching transmission.First wave conduit 20 and second waveguide pipe 40 coaxial design between the two, institute The material of use is metal material, such as: copper metal or aluminum metal etc..

In some embodiments, the structure of first wave conduit 20 and second waveguide pipe 40 is not limited to above-mentioned round tube knot Structure is also possible to other tubular structures, such as: rectangular tube.

One is at least to the quantity with above-mentioned first choke structure 45, the first choke structure 45, this at least one first Choke structure 45 may be provided at the periphery wall of first wave conduit 20, alternatively, at least one first choke structure 45 is arranged second The internal perisporium of waveguide 20；Or first choke structure 20 quantity at least two, the periphery wall of first wave conduit 20 is extremely It is equipped with first choke structure 45 less, the internal perisporium of second waveguide pipe 40 is at least provided with first choke structure 45, and first Choke structure 45 is used in waveguide transmission microwave, realizes short-circuit face transfer, prevents microwave transmission in first wave conduit 20 and the It leaks two waveguides, 40 junction.

Specifically, in some embodiments, the first choke structure 45 includes: the first choke groove 451 and the second choke groove 452.One end of second choke groove 452 is connected to the first choke groove 451, and the one side wall of the second choke groove 452 is gripped with first The slot bottom of chute 451 is concordant.

When the first choke structure 45 is set to first wave conduit 20, the first choke groove 451 is set to first wave conduit 20 Periphery wall on, and around first wave conduit 20, the second choke groove 452 is set to internal perisporium and the periphery of first wave conduit 20 Between wall, and around first wave conduit 20.

When the first choke structure 45 is set to second waveguide pipe 20, the first choke groove 451 is set to second waveguide pipe 40 Internal perisporium on, and around second waveguide pipe 40, the second choke groove 452 is set to internal perisporium and the periphery of second waveguide pipe 40 Between wall, and around second waveguide pipe 40.

It is worth noting that: in order to improve the technical effect that the first choke structure 45 prevents microwave from leaking, when the first chokes When structure 45 is set to first wave conduit 20, the first choke structure 45 can also meet following calculation formula:

When the first choke structure 45 is set to first wave conduit 20, ₁For 22 end face of first exit end to the first chokes The distance of the opening of slot 451, ₁For the distance of the opening of 41 end face of second entrance end to the first choke groove 451, and ₁It is corresponding Microwave phase ₁, the distance between the opening of opening to the second choke groove 452 of the first choke groove 451 is ₂, and ₂It is right The microwave phase answered is ₂, the distance between the slot bottom of opening to the second choke groove 452 of the second choke groove 451 is ₃, and And ₃Corresponding microwave phase is ₃, whereinFor natural number,For use telescopic waveguide 100 microwave phase.

It is to be understood that in further embodiments, the first choke structure 45 may be other may be implemented in wave When leading transmission microwave, realizes short-circuit face transfer, prevent microwave transmission outside 40 junction of first wave conduit 20 and second waveguide pipe The choke structure let out.First choke structure 45 can be made of several segments, these several segments are in first wave conduit 20 or the second wave The cross section of conduit 40 is projected as closed ring-type.These several segments can be provided entirely in the inner circumferential of first wave conduit 20 First wave conduit 20 is arranged in wall, or whole periphery walls for being set to second waveguide pipe 40 or these several segments parts Internal perisporium is partially set to the periphery wall of second waveguide pipe 40.

For above-mentioned second connector 50, the second of second waveguide pipe 40 is installed on by the modes such as be socketed or be spirally connected and is entered The periphery wall of the first exit end 22 of mouth end 41 and first wave conduit 20, and first wave guide is sealed by sealing element (not shown) Joint gap between pipe 20 and second waveguide pipe 40, at work, the second connector 50 are also connect with other external components, with It is used to support first wave conduit 20 and second waveguide pipe 40.

For above-mentioned second coupler 60, it is equipped with second connection end mouth 61, the second outlet end 42 of second waveguide pipe 40 connects Second connection end mouth 61 is connect, and second waveguide pipe 40 and the second coupler 60 is made to be fixed together by welding.It can With understanding, second waveguide pipe 40 and the second coupler 20 can also be by integrally formed modes as one.

It should be noted that；First coupler 10 and the second coupler 60 are used to convert the TM01 mode and TE10 mould of microwave Formula, so that TM01 mode or TE10 mode are angularly being uniformly distributed in the waveguide of microwave.

In the utility model embodiment, it is inserted in second waveguide pipe 40 by the first exit end 22 of first wave conduit 20 In second entrance end 41, so that first wave conduit 20 can change length with respect to the straightforward movement of second waveguide pipe 40, and by flexible Degree is provided with the first choke structure 45 in the periphery wall of first wave conduit 20 and/or the internal perisporium of second waveguide pipe 40, realizes short The transfer on road surface avoids microwave from leaking in the junction of first wave conduit 20 and second waveguide pipe 40.By being arranged in first wave The bore of the internal perisporium at the second outlet end 42 of the internal perisporium and second waveguide pipe 40 of the first exit end 22 of conduit 20 is in ladder The structure of formula variation when transmitting microwave in the waveguide of different caliber sizes, the reflection of microwave is superimposed and is offset, so that micro- Wave is constantly in the state of matching transmission in the waveguide of different bores.

In another embodiment, the utility model provides a kind of telescopic waveguide 100, as shown in Figure 6 to 7, this implementation Example with above-described embodiment the difference is that:

Telescopic waveguide 100 further include: third waveguide 70, the second choke structure 75, third connector 80 and the 4th connection Device 90.Third waveguide 70 is equipped with third arrival end 71 and third outlet end 72, the bore of the internal perisporium of third arrival end 71 to Ascending direction far from third outlet end 72 is in step variation, and third outlet end 72 is connected to second connection end mouth 61, And it is fixed together third waveguide 70 with the second coupler 60.It is understood that the Three waveguides 70 and the second coupler 60 can also be by integrally formed modes as one.The periphery wall of third waveguide 70 Bore be slightly less than second waveguide pipe 40 internal perisporium bore, the lowest calibre and first wave of the internal perisporium of third waveguide 70 The lowest calibre size of the internal perisporium of conduit 20 is identical.The third arrival end 71 of third waveguide 70 is nested into second waveguide pipe 40 Second outlet end 42 in, and third waveguide 70 can be with respect to the straightforward sliding of second waveguide pipe 40, so that third waveguide 70 Length can be changed by straightforward sliding extension between second waveguide pipe 40.

Second choke structure 65 is arranged on second waveguide pipe 40 and/or third waveguide 70, and telescopic waveguide 100 At work, the second choke structure 65 is located at 70 overlapping interval of second waveguide pipe 40 and third waveguide, prevents microwave transmission from existing Second waveguide pipe 40 and 70 junction of third waveguide are leaked.The structure phase of second choke structure 65 and the first choke structure 45 Together, it can be arranged refering to the first choke structure 45, no longer repeat one by one herein.

Third connector 80 is socketed or is spirally connected etc. second outlet end 42 and the third that modes are installed on second waveguide pipe 40 The periphery wall of the third arrival end 61 of waveguide 60, for sealing between the connection between second waveguide pipe 40 and third waveguide 70 Gap, when work, third connector 80 is connect with external components, can support second waveguide pipe 40 and third waveguide 70. The modes such as the welding of the 4th connector 90 or socket are installed on the periphery wall or third of the second connection end mouth 71 of the second coupler 60 The periphery wall of waveguide 70, when work, third connector 80 is also connect with other external components, can support third waveguide Pipe 70 and the second coupler 60.

In the utility model embodiment, first wave conduit 20 and third waveguide 70 are socketed on second waveguide pipe 40 respectively Second entrance end 41 and second outlet end 42 within, and first wave conduit 20 and third waveguide 70 can be with respect to second waveguides The straightforward sliding of pipe 40, so that by that can be changed by flexible between first wave conduit 20, second waveguide pipe 40 and third waveguide 70 Elongated degree.

It is to be understood that in further embodiments, first wave conduit 20, second waveguide pipe 40 and third waveguide 70 Between the mode of socket be not limited to aforesaid way, be also possible to other modes, such as: the second entrance end of second waveguide pipe 40 41 are socketed in the first exit end 22 of first wave conduit 20, and the second outlet end 42 of second waveguide pipe 40 is socketed on third waveguide In the third arrival end 61 of pipe 70, at this point, third waveguide 70 and 20 internal perisporium of first wave conduit are in the structure of step variation It is then separately positioned on first entrance end 21 and third outlet end 72, and the internal perisporium mouth at first entrance end 21 is radially away from first Descending outlet end 22 is in step variation, and the mouth of the internal perisporium of third outlet end 72 is radially away from third arrival end 71 by big To small in step variation formula.

The utility model also provides a kind of accelerator system embodiment, and accelerator system includes microwave power source, accelerating tube With telescopic waveguide 100, the structure and function of the telescopic waveguide 100 is identical as the structure and function of above-mentioned telescopic waveguide 100, herein No longer repeat one by one.

Finally, it should be noted that the above various embodiments is only to illustrate the technical solution of the utility model, rather than it is limited System；Although the present invention has been described in detail with reference to the aforementioned embodiments, those skilled in the art should Understand: it is still possible to modify the technical solutions described in the foregoing embodiments, or to some or all of Technical characteristic is equivalently replaced；And these are modified or replaceed, it does not separate the essence of the corresponding technical solution, and this is practical new The range of each embodiment technical solution of type, should all cover in the claim of the utility model and the range of specification. Especially, as long as structural conflict is not present, items technical characteristic mentioned in the various embodiments can combine in any way Get up.The utility model is not limited to specific embodiment disclosed herein, but including falling within the scope of the appended claims All technical solutions.

Claims (15)

1. a kind of telescopic waveguide characterized by comprising

First wave conduit；

Second waveguide pipe, the second waveguide tube portion cover on the first wave conduit, and the second waveguide Guan Kexiang Sliding straightforward for first wave conduit；

First choke structure is arranged in the first wave conduit and/or the second waveguide pipe；When work, first chokes Structure is located at the second waveguide pipe and the first wave conduit overlapping interval.

2. telescopic waveguide according to claim 1, which is characterized in that

First choke structure shifts for realizing short-circuit face, when preventing microwave transmission, in first wave conduit and second waveguide It leaks pipe junction.

3. telescopic waveguide according to claim 2, which is characterized in that first choke structure is arranged in the first wave The quantity of the periphery wall of conduit, first choke structure is at least one.

4. telescopic waveguide according to claim 2, which is characterized in that first choke structure is arranged in second wave The quantity of the internal perisporium of conduit, first choke structure is at least one.

5. telescopic waveguide according to claim 2, which is characterized in that the quantity of first choke structure is at least two A, the periphery wall of the first wave conduit is at least provided with first choke structure, and the internal perisporium of the second waveguide pipe is at least Equipped with first choke structure.

6. according to claim 1, the described in any item telescopic waveguides in 2,4 and 5, which is characterized in that

Setting includes the first choke groove and the second choke groove in supravasal first choke structure of the first wave；

First choke groove is set on the periphery wall of the first wave conduit, and around the first wave conduit；

Second choke groove is set between the internal perisporium and periphery wall of the first wave conduit, and around the first wave Conduit；

One end of second choke groove is connected to first choke groove, and the one side wall of second choke groove with it is described The slot bottom of first choke groove is concordant.

7. according to claim 1, the described in any item telescopic waveguides in 2,3 and 5, which is characterized in that

It includes the first choke groove and the second choke groove that first choke structure on the second waveguide pipe, which is arranged in, and described the One choke groove is set on the internal perisporium of the second waveguide pipe, and around the second waveguide pipe；

Second choke groove is set between the internal perisporium and periphery wall of the second waveguide pipe, and around second wave Conduit；

One end of second choke groove is connected to first choke groove, and the one side wall of second choke groove with it is described The slot bottom of first choke groove is concordant.

8. telescopic waveguide according to claim 2, which is characterized in that the first wave conduit and the second waveguide Guan Jun For round tube.

9. telescopic waveguide according to claim 2, which is characterized in that the first wave conduit and the second waveguide Guan Jun For rectangular tube.

10. telescopic waveguide described in -5 any one according to claim 1, which is characterized in that the second waveguide pipe with it is described First wave guide interface tube end caliber size is in step variation.

11. telescopic waveguide described in -5 any one according to claim 1, which is characterized in that at least 1 first chokes knot Structure is divided into several segments, and the several segments are respectively arranged on the periphery wall of the first wave conduit and the inner circumferential of the second waveguide pipe Wall, several segments combination the cross section of the first wave conduit or second waveguide pipe be projected as surround shape.

12. a kind of telescopic waveguide characterized by comprising

First wave conduit；

Second waveguide pipe, the first wave conduit and the second waveguide tube portion are socketed, and the second waveguide Guan Kexiang Sliding straightforward for first wave conduit；

First choke structure is arranged in the first wave conduit and/or the second waveguide pipe；When work, first chokes Structure is located at the second waveguide pipe and the first wave conduit overlapping interval；

Third waveguide, the second waveguide pipe and the third waveguide section are socketed, and the third waveguide can phase Sliding straightforward for second waveguide pipe；

Second choke structure is arranged in the second waveguide pipe and/or the third waveguide；When work, second chokes Structure is located at the second waveguide pipe and the third waveguide overlapping interval.

13. telescopic waveguide according to claim 12, which is characterized in that the first wave conduit and the third waveguide It is partially covered respectively at two ends of the second waveguide pipe.

14. telescopic waveguide according to claim 12, which is characterized in that two ends of the second waveguide pipe are respectively fitted over institute It states on first wave conduit and the third waveguide.

15. a kind of accelerator system, including microwave power source, accelerating tube, which is characterized in that including such as claim 1-5,8-9, Telescopic waveguide described in 12-14 any one.