JP2002033056A - Pulse magnetron device and method of manufacturing the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pulse magnetron device at a low cost and to provide a method of manufacturing the same. SOLUTION: A pulse magnetron device of this invention is provided with a positive electrode cylinder 11 forming a resonance cavity, a negative electrode 12 positioned at a central part of the positive electrode cylinder 11, a plurality of positive electrode vanes 13 radially provided inside the positive electrode cylinder 11, a pulse magnetron having an output part for taking the high frequency output from the resonance cavity for the predetermined output, and an external output waveguide 21 connected to the output part of the pulse magnetron. In this pulse magnetron device, an output part flange 22 forming an outer conductor part of the output part is pressed into an opening 21b of a tube wall part 21a of the external output waveguide 21, and the outer conductor part of the output part and the tube wall part 21a of the external output waveguide 21 are electrically connected to each other.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pulse magnetron device for supplying a high-frequency pulse signal generated by a pulse magnetron to a load via an external output waveguide connected to its output, and a method of manufacturing the same.

[0002]

2. Description of the Related Art A pulse magnetron is an electron tube for generating a high-frequency pulse signal, and is used as a microwave transmission source of a marine radar. An external output waveguide is connected to the output of the pulse magnetron, and a high-frequency pulse signal generated by the pulse magnetron is supplied to a load via the external output waveguide.

Here, a conventional pulse magnetron device will be described with reference to FIG. Reference numeral 30 denotes an electron tube main body that generates a high-frequency pulse signal. The electron tube main body 30 includes a cylindrical anode 31, a cathode 32 positioned at the center of the cylindrical anode 31, and a cylindrical shape arranged radially from the cylindrical anode 31 to the cathode 32. A plurality of anode vanes 33 forming a resonance cavity inside the anode 31; a ferromagnetic pole piece 34a provided so as to cover openings at both upper and lower ends of the cylindrical anode 31;
34b and the like.

A stem 35 is provided on one side of the electron tube main body 30, for example, in the upper part of the figure, and a lead wire 36 for applying a voltage to the cathode 32 connects the stem 35. A metal exhaust pipe 37 is provided on the other side of the electron tube main body 30, for example, below the figure.

An output antenna lead wire 38 is provided through the side wall of the cylindrical anode 31, and the output antenna lead wire 38 is connected to an output antenna 39. The tip of the output antenna 39 is protected by the insulator 40 and protrudes into the external output waveguide 41. A connection flange 42 is formed on an outer conductor portion surrounding the output antenna 39, and the connection flange 42 is electrically connected to the tube wall portion 41a of the external output waveguide 41 by soldering or the like, and is mechanically fixed. Have been.

The pole piece 3 constituting the electron tube main body 30
Outside the 4a, 34b, permanent magnets 43a, 43b formed in a substantially cylindrical shape are arranged. Permanent magnet 43a,
The magnetic pole inside 43b is magnetically connected to the pole pieces 34a, 34b. The outer magnetic pole of each of the permanent magnets 43a and 43b is a U-shaped ferromagnetic yoke plate 44.
And are magnetically connected. In this case, for example, starting from one of the permanent magnets 43a, the pole pieces 34a, 34
b, a magnetic circuit is formed which passes through the other permanent magnet 43b and the yoke plate 44 and returns to the permanent magnet 43a.

Reference numeral 45 denotes an opening wall of the external output waveguide 41, and the opening wall 45 also serves as a mounting member for mounting a magnetron.

The electron tube body 3 of the pulse magnetron
The components constituting the magnetic circuit with the magnets 0 include the attractive force of the permanent magnets 43a and 43b arranged on both sides of the electron tube main body 30, and the mechanical force of the yoke plate 44 arranged between the permanent magnets 43a and 43b. Has been fixed by.
The electron tube main body 30 and the output waveguide 41 are connected to the yoke plate 4.
4 is fixed to the external output waveguide 41 with screws or the like, and the output portion of the electron tube main body 30 is fixed to the external output waveguide 41 by soldering or the like.

According to the above configuration, the output portion of the electron tube main body 30 is coupled to the external output waveguide 41 by coaxial-waveguide conversion, and the high-frequency pulse signal generated in the electron tube main body 30 is supplied to the external output waveguide 41. To a load (not shown).

At this time, a high-frequency current flows through a junction between the output section of the electron tube main body 30 and the external output waveguide 41. Therefore, if the contact resistance of the joint is large, high-frequency loss increases, and if there is a gap in the joint, discharge may occur. In the case of a pulse magnetron device having a relatively small output, soldering is generally used for joining the output portion of the electron tube main body 30 and the external output waveguide 41.

[0011]

In the conventional pulse magnetron device, when the output portion of the electron tube main body 30 and the external output waveguide 41 are connected and fixed, for example, soldering is used. Pulse magnetron devices used for ships and the like are required to be inexpensive and require a reduction in man-hours, but soldering requires a lot of man-hours. In soldering, in order to improve the reliability, the material of the material to be joined is limited, and it is necessary to clean the surface, which also makes it difficult to reduce the cost.

When the surface of the joint is cleaned, a flux or the like is used. When using flux,
The residue may corrode the joining metal and cause deterioration of the degree of vacuum inside the electron tube body. Therefore, after the soldering, a cleaning step for removing the flux is required, and the number of steps increases accordingly.

In the case of a pulse magnetron device mounted on a ship, the external output waveguide is made of Al, Zn, or A.
It is manufactured by casting an alloy containing l or Zn as a main component. These castings are difficult to join by soldering, and electroless N
It is soldered by performing a plating process such as i-plating. In this method, the plating process is expensive and has a large effect on the environment such as treatment and discharge of a waste liquid. Further, a material containing Pb as a main component is used for the solder, and it is required to reduce the soldering itself from the influence on the environment.

An object of the present invention is to provide a pulse magnetron device which can solve the above-mentioned drawbacks and can reduce the cost, and a method of manufacturing the same.

[0015]

According to the present invention, there is provided an anode cylinder forming a resonance cavity, a cathode located at the center of the anode cylinder, and a plurality of anode cylinders provided radially from the anode cylinder in the direction of the cathode. A plurality of anode vanes forming a resonance cavity, a pulse magnetron having an output unit for extracting a high-frequency output from a predetermined output resonance cavity among the plurality of resonance cavities, and a pulse magnetron connected to the output unit of the pulse magnetron A pulse magnetron device having an external output waveguide, wherein an output portion flange forming an outer conductor portion of the output portion is press-fitted into a tube wall opening of the external output waveguide, and an outer conductor of the output portion is provided. The portion and the tube wall portion of the external output waveguide are electrically connected. Further, the present invention provides a pulse magnetron having an anode cylinder forming a plurality of resonance cavities, and an output unit for extracting a high-frequency output from a predetermined output resonance cavity among the plurality of resonance cavities. A method for manufacturing a pulse magnetron device, comprising: one step; and a second step of connecting an outer conductor portion forming the output portion of the pulse magnetron and a tube wall of an external output waveguide. The output portion flange, in which a protrusion is provided on at least one of the outer surface of the output portion flange and the inner surface of the opening provided in the tube wall of the external output waveguide, is connected to the outside in a region where the protrusion is provided. The method is characterized by including a step of press-fitting into an opening of the output waveguide.

[0016]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to FIG. FIG. 1A is a sectional view of the pulse magnetron and each section of the external output waveguide connected to the output section of the pulse magnetron, taken along the tube axis direction.
(B) is a diagram viewed from the tube axis direction, and a part thereof is shown in a cross section.

Reference numeral 10 denotes an electron tube main body of a pulse magnetron for generating a high-frequency pulse signal.
A cylindrical anode 11 and a cathode 12 located at the center of the cylindrical anode 11; and a plurality of radially arranged from the cylindrical anode 11 toward the cathode 12 to divide the inside of the cylindrical anode 11 into a plurality and form a resonant cavity. Anode vane 13 and cylindrical anode 11
And ferromagnetic pole pieces 14a and 14b provided so as to cover the openings at the upper and lower ends of the ferromagnetic material.

A stem 15 is provided on one side of the electron tube main body 10, for example, in the upper part of the figure, and a lead 16 for applying a voltage to the cathode 14 connects the stem 15. A metal exhaust pipe 17 is provided on the other side of the electron tube main body 10, for example, below the figure.

An output antenna lead 18 is provided through the side wall of the cylindrical anode 11. The output antenna lead wire 18 constitutes an output unit for extracting a high-frequency output from a predetermined output resonance cavity among a plurality of resonance cavities formed inside the cylindrical anode 11, and forms, for example, an output resonance cavity. One end is connected to the anode vane. The other end of the output antenna lead wire 18 is connected to the output antenna 19. The distal end portion of the output antenna 19 is hermetically sealed by a hermetic window 20, and the end protrudes into the external output waveguide 21.

A connection flange 22 is formed on an outer conductor portion surrounding the output antenna lead wire 18 and the output antenna 19 constituting the output portion to be connected to the tube wall portion 21a of the external output waveguide 21. . In this case, for example, a circular opening 21b is formed in a part of the tube wall portion 21a, and a step portion 21c is formed on the inner surface of the opening 21b. The opening 21b portion of the tube wall portion 21a has a large diameter portion A having a large inner diameter. , And a small diameter portion B having a smaller inner diameter. Further, a plurality of protrusions 2 are provided on the inner surface of the large-diameter portion A in the circumferential direction thereof.
1d are formed at regular intervals, for example.

The connection flange 22 is press-fitted into a region where the projection 21d is formed at the large diameter portion A of the tube wall portion 21a. When the connection flange 22 is press-fitted, the protrusion 21d is deformed, the connection flange 22 is fitted inside the opening 21b, and the outer conductor portion of the output portion and the tube wall portion 21a are electrically connected, and , Mechanically fixed.

Outside the pole pieces 14a, 14b constituting the electron tube main body 10, permanent magnets 23a, 23b formed in a substantially cylindrical shape are arranged. Permanent magnet 2
The magnetic poles inside 3a, 23b are pole pieces 14a, 14
b and is magnetically connected. Permanent magnets 23a, 23b
Each outer magnetic pole is magnetically connected to a U-shaped ferromagnetic yoke plate 24. In this case, for example, starting from one permanent magnet 23a, the pole piece 14a,
14b, a magnetic circuit which returns to the permanent magnet 23a through the other permanent magnet 23b and the yoke plate 24 is formed.

Reference numeral 25 denotes an opening wall of the external output waveguide 21, and the opening wall 25 also serves as a mounting member for mounting a magnetron.

Here, the tube wall portion 2 of the external output waveguide 21
Regarding a method of press-fitting an output portion flange constituting an output portion of the magnetron into the opening 1a, referring to a plan view of FIG. 1B in which an external output waveguide portion of FIG. explain. In FIG. 2, parts corresponding to those in FIG. 1 are denoted by the same reference numerals, and duplicate description will be partially omitted.

On the inner surface of the opening 21b of the external output waveguide 21, for example, the inner surface of the large diameter portion A in FIG.
d are formed at regular intervals in the circumferential direction. In this case, as shown in FIG. 2B in which a portion of the protrusion 21d is enlarged, a connection flange in which an inner diameter d1 of a circle R formed by connecting respective ends of the protrusion 21d is indicated by a dotted line. 22 is formed smaller than the outer diameter d2. Therefore, when the output unit flange 22 is press-fitted into the opening 21b in the region where the protrusion 21d is formed, for example, by pressing the surface on the electron tube main body side, the protrusion 21d or the connection flange 22 is deformed, and the connection 21 The flange 22 is fitted,
The tube wall portion 21a and the connection flange 22 are electrically connected, and at the same time, mechanically fixed.

According to the above configuration, the output flange is press-fitted into the opening of the tube wall of the external output waveguide, and the two are electrically connected and mechanically fixed. In this method, since no soldering is required, the number of steps can be reduced, the cost can be reduced, and a pulse magnetron device with less influence on the environment and a manufacturing method thereof can be realized.

In the case of the above embodiment, a projection is provided on the tube wall of the external output waveguide. However, a projection may be provided on the outer periphery of the output portion flange. In this case, the outer diameter of a circle formed by connecting the tips of the plurality of protrusions provided on the outer surface of the output portion flange is formed so as to be larger than the inner diameter of the tube wall opening at the portion to be press-fitted.

Further, it is possible to provide projections on both the inner surface of the tube wall portion of the output waveguide and the outer surface of the output portion flange.

[0029]

According to the present invention, it is possible to realize a pulse magnetron device and a method for manufacturing the same, which can reduce the cost.

[Brief description of the drawings]

FIG. 1 is a schematic structural view for explaining an embodiment of the present invention, and a part thereof is shown in a cross section.

FIG. 2 is a schematic structural view showing an opening of an external output waveguide used in an embodiment of the present invention.

FIG. 3 is a schematic structural view for explaining a conventional example, and a part thereof is shown in a cross section.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 ... Electron tube main body 11 ... Anode cylinder 12 ... Cathode 13 ... Anode vane 14a, 14b ... Pole piece 18 ... Lead wire for output antenna 19 ... Output antenna 20 ... Airtight window 21 ... External output waveguide 21a ... External output waveguide 21b: Opening of external output waveguide 21d: Projection of external output waveguide 22: Connection flange 24: Yoke plate

Claims (7)

[Claims] 1. An anode cylinder forming a resonance cavity, a cathode located at the center of the anode cylinder, and a plurality of radiators provided radially from the anode cylinder toward the cathode to form a plurality of resonance cavities together with the anode cylinder. The anode vane, a pulse magnetron having an output unit for extracting a high-frequency output from a predetermined output resonance cavity of the plurality of resonance cavities, and an external output waveguide connected to the output unit of the pulse magnetron. In the pulse magnetron device provided, an output portion flange forming an outer conductor portion of the output portion is press-fitted into a tube wall opening of the external output waveguide, and the outer conductor portion of the output portion and the external output waveguide are inserted. A pulse magnetron device characterized in that the tube wall portions of the above are electrically connected. 2. The pulse magnetron device according to claim 1, wherein a projection is provided on at least one of the inner surface of the tube wall opening of the external output waveguide and the outer surface of the output portion flange. 3. A plurality of projections are provided on an inner surface of a tube wall opening of an external output waveguide, and an inner diameter of a circle formed by connecting tips of the plurality of projections is equal to the output portion flange. The pulse magnetron device according to claim 1, wherein the pulse magnetron device is formed so as to be smaller than an outer diameter of the pulse magnetron. 4. A plurality of protrusions are provided on an outer surface of an output portion flange, and an outer diameter of a circle formed by connecting tips of the plurality of protrusions has a tube wall opening of the external output waveguide. The pulse magnetron device according to claim 1, wherein the pulse magnetron device is formed so as to be larger than an inner diameter of the portion. 5. A first pulse magnetron having an anode cylinder forming a plurality of resonance cavities, and an output unit for extracting a high-frequency output from a predetermined output resonance cavity among the plurality of resonance cavities. And a second step of connecting an outer conductor portion constituting the output section of the pulse magnetron and a tube wall of an external output waveguide, wherein the second step comprises: The output unit flange, in which a protrusion is provided on at least one of the outer surface of the unit flange and the inner surface of the opening provided in the tube wall of the external output waveguide, is connected to the external output in a region where the protrusion is provided. A method for manufacturing a pulse magnetron device, comprising a step of press-fitting into an opening of a waveguide. 6. A plurality of projections formed on the inner surface of the opening of the external output waveguide, wherein the inner diameter of a circle formed by connecting the respective tips is smaller than the outer diameter of the output portion flange. A method for manufacturing a pulse magnetron device according to claim 5. 7. A plurality of projections formed on the outer surface of the output portion flange, the outer diameter of a circle formed by connecting the respective tips being larger than the inner diameter of the opening of the external output waveguide. A method for manufacturing a pulse magnetron device according to claim 5.