BACKGROUND OF THE INVENTION
The present invention relates generally to RF rotary joints, or microwave rotary joints, and more particularly to an apparatus having a plurality of conductive fiber brush bundles and a coaxial conductor to transfer RF signal(s) between relatively rotatable objects.
Rotary joints are used to change the direction of microwave propagation between two guides by rotating one with respect to other. RF rotary joints are electromechanical devices that consist of rotational (rotors) and stationary (stators) members. They allow the transmission of RF\microwave signals and power from their rotors to stators or vise verse.
A conventional RF rotary joints consists of either a contacting or non-contacting interface to transfer RF\microwave signals and power.
In non-contacting rotating interfaces, electrical continuity for RF is typically achieved by using λ/4 chokes, to correspond to the quarter wavelength of a particular frequency which eliminate the need for physical contact at the rotating junction. The advantage of a non-contacting interface is that all physical wear is eliminated. Disadvantages of this approach are size and weight, particularly at lower frequencies, which have longer wavelengths and therefore require longer chokes.
In contacting rotating interfaces, two relative rotatable conductive parts keep sliding contact by spring, or other actuators. The advantage of a contacting rotating interfaces is that size can be greatly reduced when compared to a ¼ wavelength choke interface. Disadvantages of contacting rotating interfaces are increased torque, the need for a tight and perfectly concentric fit of the rotating interface, and the fact that contact stress in rotation causes wear and the wear debris would cause electrical failure at the rotating interface. Please see the prior arts: U.S. Pat. No. 3,229,234 A and US2005\0264377A1.
Fiber brush technology has been successfully used in electrical slip ring industry, where, a brush assembly comprising a multifilament conductive fiber brush contacts with a conductive slip ring surface. The brush assembly is constructed with thousands of hair-fine silver alloy fibers running on their tips, offer significant improvement over carbon brushes in both data and current transfer, offering extended brush and slip ring service life, high current capacity, and significant decreases in service acoustic and electrical noise. Please see U.S. Pat. No. 4,398,113 A.
SUMMARY OF THE INVENTION
The objective in the current invention is to create soft contacting rotational interfaces for RF rotary joint with long service life, maintenance free, and high reliability by using a plurality of conductive fiber brush bundles and a coaxial line to transfer RF signal(s) between relatively rotatable objects.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 illustrates the main embodiment of the RF rotary joint in the present invention.
FIG. 2 is the detailed view of the stationary shield conductor assembly in the present invention.
FIG. 3 is the detailed view of the stationary core conductor assembly in the present invention.
FIG. 4 shows the configuration of the rotational core conductor of the coaxial line in the present invention.
FIG. 5 shows the configuration of the rotational shield conductor of the coaxial line in the present invention.
FIG. 6a is a braided conductive tube assembly before deformation in the present invention.
FIG. 6b is a braided conductive tube assembly after deformation in the present invention.
DETAIL DESCRIPTION OF THE INVENTION
A detailed explanation of preferred embodiment in the present invention with reference to FIG. 1, to FIG. 6 is as follows.
FIG. 1 shows a longitudinal sectional view of a single channel coaxial line RF rotary joint with soft contacting rotational interfaces in the present invention. The RF rotary joint consists mainly of a coaxial line with the soft contacting rotational interfaces, the stationary member and rotational member assembly and the RF receptacles (or connectors).
In FIG. 1, the numbered items are described as follows:
- 10 - - - rotational RF receptacle (or connector)
- 11 - - - stationary core conductor;
- 12 - - - fiber brush bundle, stationary core conductor;
- 13 - - - rotational core conductor;
- 14 - - - rotational insulating spacer;
- 15 - - - stationary insulating spacer;
- 20 - - - stationary RF receptacle (or connector)
- 21 - - - stationary shield conductor;
- 22 - - - fiber brush bundle, stationary shield conductor;
- 23 - - - rotational shield conductor;
- 24 - - - bearing spacer;
- 26 - - - rotational shield conductor;
- 30 - - - bearing;
- 31 - - - bearing;
- 35 - - - seal;
- 40 - - - housing;
- 41 - - - end cap;
- 71 - - - core soft contacting rotational interface;
- 72 - - - shield soft contacting rotational interface;
- 80 - - - rotation axis of the RF rotary joint and the common geometric axis of all listed parts;
FIG. 2 is the detailed view of stationary shield conductor assembly. It consists of the stationary RF receptacle (or connector) 20, stationary shield conductor 21 and the conductive fiber brush bundle 22. Said fiber brush bundle 22 contains a plurality of hair-thin silver alloy filaments to form a symmetrical “hair tube” relative to axis 80. Said fiber brush bundle 22 has two end portion, 221 and 222. Said end portion 221 is coaxially and electrically fixed with stationary shield conductor 21.
FIG. 3 is the detailed view of stationary core conductor assembly. It consists of the stationary core conductor 11 and the fiber brush bundle 12. Said fiber brush bundle 12 contains a plurality of hair-thin silver alloy filaments to form a symmetrical “hair tube” relative to axis 80. Said fiber brush bundle 12 has two end portion, 121 and 122. Said end portion 121 is coaxially and electrically fixed with stationary core conductor 11.
FIG. 4 shows the configuration of the rotational core conductor 13 of the coaxial line in the present invention. The rotational core conductor 13 have a coaxial tapered round head 132.
FIG. 5 shows the configuration of the rotational shield conductor 26 of the coaxial line in the present invention. The rotational shield conductor 26 have a coaxial tapered round head 262.
Back to FIG. 1, said stationary core conductor assembly in FIG. 2 is coaxially fixed in the center bore of stationary shield conductor assembly and separated from stationary shield conductor 21 by stationary insulating spacer 15. The rotational shield conductor assembly includes rotational shield conductor 23 and 26. They are supported by two ball bearings 30 and 31 and rotatable relative to housing 40. Said rotational shield conductor 26 is fixed at the internal end portion of the rotational shield conductor 23. The rotational core conductor 13 in FIG. 5 is coaxially fixed in the center bore of said rotational shield conductor assembly and separated from rotational shield conductor 23 by rotational insulating spacer 14. The end portion 122 of the fiber brush bundle 12 is sized to have a constant physical contact with said tapered round head 132 of the rotational core conductor 13 during the rotation between the rotational RF receptacle (or connector) 10 and stationary RF receptacle (or connector) 20, so as to form the core soft contacting rotational interface 71 around the tapered round head 132 of the rotational core conductor 13. Similarly, the end portion 222 of the fiber brush bundle 22 is sized to have a constant physical contact with said tapered round head 262 of the rotational shield conductor 26 during the rotation between the rotational RF receptacle (or connector) 10 and stationary RF receptacle (or connector) 20, so as to form the shield soft contacting rotational interface 72 around the tapered round head 262 of the rotational shield conductor 26. The stationary insulating spacer 15 and rotational insulating spacer 14 have an overlap so that the core conductors are completely separated from shield conductors by dialectical material. The RF coaxial line is sealed by end cap 41 and shaft seal 35.
An alternative way to form soft contacting rotational interfaces is to use braided conductive tube assembly instead of conductive fiber brush bundles. The braided conductive tube is commercially available. They are flexible. FIG. 6a shows a braided conductive tube assembly in the present invention, which includes conductive ring 90, 92, and braided conductive tube 91. They are disposed concentrically. FIG. 6b is a braided conductive tube assembly after deformation by mating with the tapered round head of either core, or shield conductors in the present invention.