JPH10276001A - Rotary joint of microwave transmission and reception part - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify a structure and to provide a light-weight small-sized rotary joint of microwave transmission/reception part by directly connecting a motor for rotating an antenna part to a dielectric connected to a rotator in a rotary mechanism. SOLUTION: To a fixed waveguide 1, the thin and long dielectric 10 of an almost round bar shape is installed almost vertically to a magnetic field surface inside the tube of the fixed waveguide 1 from the rotator 4 so as to be passed through the fixed waveguide 1. One end of the dielectric 10 is connected to the antenna part. The other end of the dielectric 10 is connected to the motor 8 and the antenna part, the rotator 4 in the rotary mechanism 9 and a probe 2 are rotated. The rotary mechanism 9 is formed by the rotator 4, a bearing part 5, the motor 8 and a boss 12 for choke and the antenna part connected to the rotator 4 is rotated. Then, when microwaves are outputted, the microwaves are transmitted to the rotated antenna part and radiated in all directions. Thus, the fixed transmission/reception part of a pulse radar and the rotated antenna part are smoothly connected.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus provided with a microwave transmitting / receiving unit, particularly a kind of microwave equipment used for a pulse radar and the like, for connecting a fixed transmitting / receiving unit and a rotating antenna unit. And a structure of a microwave transmission / reception unit rotary joint. In a conventional microwave transmitting / receiving unit rotary joint, a motor for rotating an antenna unit is connected to a rotating body in a rotating mechanism via a plurality of gears. As a result, the weight of the entire microwave transmission / reception unit rotary joint has not been reduced. On the other hand, in the microwave transmission / reception unit rotary joint of the present invention, the motor for rotating the antenna unit is directly connected to the dielectric connected to the rotating body in the rotating mechanism. Since the motor was directly connected to the dielectric without using gears, the overall weight of the microwave transmitting / receiving unit rotary joint was reduced in size and weight, and the cost was reduced. That is, the present invention relates to a reduction in weight and cost of a microwave transmission / reception unit rotary joint.

[0002]

2. Description of the Related Art A typical structure of a conventional microwave transmitting / receiving section rotary joint is shown in FIGS.
FIG. 4 is a cross-sectional view, and the prior art is briefly described below. First, the rotary joint of the microwave transmission / reception unit shown in FIG. 3 has a fixed waveguide 1, one end of which is connected to a magnetron which is a microwave supply source, and the other end of which is a microwave transmission / reception. Connected to limiter for switching. A probe 2 for coupling and transmitting microwaves is coupled to the fixed waveguide 1 from the rotating waveguide 3 by an electric field substantially perpendicular to a magnetic field surface in the fixed waveguide 1. The probe 2 is loop-coupled to the rotating waveguide 3. The rotator waveguide 3 is for transmitting microwaves with the antenna unit, and is held by the rotator 4 and rotates together with the probe 2. The rotating body 4 is held by a bearing portion 5 and is kept out of contact with the fixed waveguide 1 by a choke structure for preventing microwave leakage. The rotating body 4 is connected to a motor 8 via two gears 6 and 7. Rotating body 4, bearing part 5, gear 6
, A gear 7 and a motor 8 form a rotating mechanism 9 for rotating an antenna unit connected to the rotating waveguide 3.
Now, when microwaves are output from the magnetron in this state, the probe 2 couples with the microwaves in the fixed waveguide 1 which is fixed, and sends the microwaves to the rotating rotating waveguide 3. Transmit. Then, the microwave is transmitted to the rotating antenna unit and radiated in all directions. In other words, the fixed transmitting / receiving section of the pulse radar and the rotating antenna section are smoothly connected.

[0003] Next, the rotary joint of the microwave transmission / reception section in FIG. 4 has a fixed waveguide 1, and this fixed waveguide 1 is connected to a duplexer for switching between transmission and reception of microwaves. A probe 2 for coupling and transmitting microwaves is coupled to the rotating waveguide 3 from the fixed waveguide 3 by an electric field substantially perpendicular to a magnetic field surface in the rotating waveguide 3. The probe 2 is loop-coupled to the fixed waveguide 1. The rotator waveguide 3 is for transmitting microwaves with the antenna unit, and is rotated by the rotator 4. However, since the probe 2 is held by the fixed waveguide 1, it does not rotate. The rotating body 4 is held by a bearing portion 5 and is kept out of contact with the fixed waveguide 1 by a choke structure for preventing microwave leakage. And rotating body 4
Is connected to a motor 8 via two gears 6 and 7. Rotating body 4, bearing part 5, gear 6 and gear 7, motor 8
To form a rotating mechanism 9 for rotating the antenna unit connected to the rotating waveguide 3. In this state, when a microwave is output from the magnetron connected via the duplexer in this state, the probe 2 couples with the microwave in the fixed waveguide 1 which is fixed, and the rotating The microwave is transmitted to the body waveguide 3. Then, the microwave is transmitted to the rotating antenna unit and radiated in all directions. As a result, the fixed transmitting / receiving unit of the pulse radar and the rotating antenna unit are smoothly connected as in FIG.

[0004]

However, the conventional microwave transmission / reception unit rotary joint according to the above description has the following problems. That is, two gears 6 and 7 are required to indirectly rotate the antenna unit by the motor 8, and it is difficult to reduce the weight and size of this part. Furthermore, the shape of the rotating body 4 is also restricted because the gear 6 is installed, and it is also difficult to reduce the weight and size of this part.
As a result, the development of a lightweight and compact microwave transmission / reception unit rotary joint has been impeded, and the development of a lightweight and compact pulse radar as a whole has been impeded. Therefore, the present invention has been made to solve the above-mentioned problem, and has a simple, lightweight, and small-sized microwave transmitting / receiving section rotary joint having a structure in which an antenna section is directly rotated by a motor 8 without using gears. It is intended to provide.

[0005]

The present invention has solved the above-mentioned problems by the following first and second means. First of all, for connecting the fixed transmitting and receiving unit of the device with the microwave transmitting and receiving unit and the rotating antenna unit,
In a microwave transmission / reception unit rotary joint including a fixed waveguide 1 fixed and a rotation mechanism 9 for rotating the antenna unit, a rotating body 4 in the rotation mechanism 9 is used.
Dielectric 1 in the shape of an elongated round rod, which is the axis of rotation at the center of
0 is penetrated substantially perpendicularly to the magnetic field surface inside the fixed waveguide 1, and an elongated substantially circular circle for transmitting microwaves from the transmitting / receiving unit to the antenna unit is provided at the center of one end of the dielectric 10. A rod-shaped probe 2 is installed in a coaxial shape, and the probe 2 forms a part of a center conductor of a coaxial transmission line of the antenna unit, and the other end of the dielectric 10 includes the antenna unit and the rotating mechanism. A motor 8 for rotating the rotating body 4 in 9 is provided.

Second, the effective length (in terms of the guide wavelength (λ)) of the outer diameter of the dielectric 10 on the side where the probe 2 is installed and the rotating body 4 in the rotating mechanism 9 corresponding to the outer diameter of the dielectric 10 are set. λ /
4 + nλ / 2, n = 0, 1, 2,...)
1 is provided, whereby the dielectric 10 is fixed.

[0007]

1 and 2 show an embodiment of the present invention using the above first and second means. FIG.
1 is a sectional view of an embodiment of the present invention, and the outline of the structure is as follows. First, the rotary joint of the microwave transmission / reception unit shown in FIG. 1 has a fixed waveguide 1, one end of which is connected to a magnetron which is a microwave supply source, and the other end of which is a microwave transmission / reception. Connected to limiter for switching. In the fixed waveguide 1, an elongated substantially round rod-shaped dielectric 10 is provided from the rotating body 4 so as to be substantially perpendicular to the magnetic field surface in the fixed waveguide 1 and penetrate the fixed waveguide 1. I have. One end of the dielectric 10 is connected to the antenna unit. Further, an elongated probe 2 having a substantially round rod shape for transmitting microwaves between the transmitting / receiving section and the antenna section is coaxially formed with the dielectric 10 at the center of one end thereof, and is provided inside the fixed waveguide 1. It is installed almost perpendicular to the magnetic field plane. One end of the probe 2 forms a part of the center conductor of the coaxial transmission line of the antenna section, and the other end is electrically coupled in the fixed waveguide 1. On the other hand, the other end of the dielectric 10 is connected to the motor 8 and rotates the rotating body 4 and the probe 2 in the antenna unit and the rotating mechanism 9. The dielectric 10 is held by a bearing 5 provided so as to sandwich the fixed waveguide 1 from the outside. The fixed waveguide 1 is formed by a choke boss 12 for preventing microwave leakage. Thus, non-contact is maintained. Rotating body 4, bearing part 5, motor 8,
The rotating mechanism 9 is formed by the choke boss 12, and the antenna unit connected to the rotating body 4 is rotated. Now, when microwaves are output from the magnetron in this state,
The probe 2 couples with the microwave in the fixed waveguide 1, and the microwave is transmitted to the rotating antenna unit and emitted in all directions. In other words, the fixed transmitting / receiving section of the pulse radar and the rotating antenna section are smoothly connected.

In order to prevent microwave leakage from the dielectric 10 penetrating the bearing 5, the diameter (a) of the dielectric 10
And the penetration length (L) from the fixed waveguide 1 is set by the following equation. Here, λ: guide wavelength ε: dielectric constant of the dielectric 10.

[0009]

(Equation 1)

[0010] Equation (1) in Equation 1 is an equation derived from the fact that microwaves are transmitted in the fundamental mode in the coaxial line. Equation (2) of Equation 1 is an equation derived from the fact that it is necessary to attenuate microwave leakage from the penetrating portion of the dielectric 10 by 30 dB or more. By the way, dielectric 1
The diameter (a) of 0 is substantially (1/1) as compared with the diameter of the rotating body 4 of the conventional microwave transmitting / receiving section rotary joint.
√ε).

Further, the dielectric 10 has an effective length (λ / 4 + nλ /) with respect to the guide wavelength (λ) in the screw portion 11 of the rotating body 4.
2, n = 0, 1, 2,...) And fixed with screws. This is to constitute a (λ / 4) transformer for matching the dielectric 10 with the antenna unit. Assuming that the impedance of the dielectric 10 is Z0 and the impedance of the antenna section is Z1, the impedance of the (λ / 4) transformer Z2 is as follows: Z2 = √ (Z0 × Z1) (3) The above equation (3) holds only when the effective length (λ / 4 + nλ / 2, n = 0, 1, 2,...) With respect to the guide wavelength (λ).

FIG. 2 is an enlarged sectional view of the screw portion 11, and the dimensions of each portion are determined as follows. Dielectric 1
Since 0 is not only a coaxial portion but also a rotation axis for rotating the antenna portion, a constant axial strength is required for the dielectric 10, so that the impedance (Z0) is 5
It is set to 0 (Ω) or more. On the other hand, the impedance (Z1) of the antenna section is generally set to 50 (Ω). For this purpose, it is necessary to install a (λ / 4) transformer in the screw part 11 which is the conversion part. Then, since the impedance (Z2) of the (λ / 4) transformer is expressed by the equation (3), now, b: the effective diameter of the threaded portion 11 c: the outer diameter of the probe 2, √ (Z0 × Z1) = Z2 = (138 / √ε) log (b / c) (4) From the equation (4), the ratio of (b / c) can be set. Since this (λ / 4) transformer also has a filter characteristic, it is effective in suppressing unnecessary harmonic components in microwaves.

Further, in this embodiment, polypropylene having an outer dimension of φ6 mm is used as a material of the dielectric 10, but any dielectric can be used as long as it has sufficient axial strength and can be used as a microwave transmission line. Example 1 Teflon Example 2. Polyethylene resin Example 3 All poly 4-methylpentene resins have been used for various components of microwave equipment such as magnetrons. The mode of use is the same as in the above embodiment.

[0014]

As described above, since the motor 8 for rotating the antenna unit is directly connected to the dielectric 10 instead of the rotating body 4, the gears 6 and 7 are not required. Further, since the outer dimensions of the dielectric 10 can be made smaller than the outer dimensions of the rotating body 4, the bearing 5 can also be made smaller. As a result, the size of the entire microwave transmission / reception unit rotary joint can be suppressed, so that the weight and size have been reduced and the cost has been reduced.

[Brief description of the drawings]

FIG. 1 is a sectional view of a microwave transmission / reception unit rotary joint according to an embodiment of the present invention.

FIG. 2 is an enlarged cross-sectional view of a screw portion of FIG.

FIG. 3 is a cross-sectional view of a conventional microwave transmission / reception unit rotary joint.

FIG. 4 is a cross-sectional view of another conventional microwave transmission / reception unit rotary joint.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Fixed waveguide 2 ... Probe 3 ... Rotating body waveguide 4 ... Rotating body 5 ... Bearing part 6 ... Gear 7 ... Gear 8 ... Motor 9 ... Rotating mechanism 10 ... Dielectric Body 11: Screw part 12: Choke boss

Claims (2)

[Claims] 1. A fixed fixed waveguide for connecting a fixed transmitting / receiving unit of a device having a microwave transmitting / receiving unit and a rotating antenna unit, and a rotating mechanism for rotating the antenna unit. In the microwave transmitting and receiving unit rotary joint, an elongated substantially round rod-shaped dielectric which is a rotation axis at the center of the rotating body in the rotating mechanism is penetrated substantially perpendicularly to a magnetic field surface in the fixed waveguide tube. At the center of one end of the dielectric, an elongated, generally round rod-shaped probe for transmitting microwaves from the transmitting / receiving section to the antenna section is installed in a coaxial shape, and the probe is coaxial with the antenna section. A micro-motor, which forms a part of a center conductor of the transmission line and is provided at the other end of the dielectric with a motor for rotating the antenna unit and a rotating body in the rotating mechanism; wave Transmitter / receiver rotary joint. 2. An effective length (λ / 4 + nλ / 2, λ / 4 + nλ / 2) for a guide wavelength (λ) is provided between an outer diameter of the dielectric on a side where a probe is installed and a corresponding rotating body in the rotating mechanism.
2. The microwave transmission / reception unit rotary joint according to claim 1, wherein a screw portion having a length of n = 0, 1, 2,...) is provided, whereby the dielectric is fixed.