Microwave rotary joint for high-power satellite tracking system
Link Microtek, the specialist designer and manufacturer of microwave and RF components, has developed an X-band microwave rotary joint to meet the extremely demanding requirements of a satellite tracking system that transmits at a high pulsed power of 100kW, with a mean power of four kilowatts, over a wide frequency band of two gigahertz.
Designed to transmit and receive at frequencies from 8.5 to 10.5GHz, the tracking system uses long runs of WR90 rigid waveguide, with six of the special single-channel rotary joints providing the necessary movement for elevation, azimuth and tilt.
Steve Cranstone, Managing Director of Link Microtek, said: “While single-channel rotary joints in themselves aren’t particularly tough to make, when you have that frequency bandwidth and those levels of power, it becomes a massive challenge.
“Any losses, even tiny ones, will generate a significant amount of heat, so thermal modelling was key in preventing internal overheating of the devices. What’s more, the customer’s system was unpressurised, so that made it very difficult to keep breakdown voltages to acceptable levels.”
Drawing on years of experience in this field, Link Microtek’s engineering team used CST electromagnetic simulation software to model those crucial aspects of the design and eventually came up with a rotary joint that could satisfy the stringent requirements of the customer’s specification.
Incorporating a ten millimetre thick heatsink to conduct the excess heat away, the rotary joints achieve a low insertion loss of less than 0.2dB and a VSWR of 1.2:1. They are manufactured from aluminium and measure 122mm in length with a heatsink diameter of 75mm.
As the satellite tracking system is installed in an exposed coastal location, the rotary joints also feature chromium-free passivation for corrosion resistance and IP65 sealing to prevent the ingress of moisture and dust.
Cranstone added: “This project really pushed us to the limits of the power that can be handled in such relatively small waveguide size. You might expect to be dealing with a 100kW peak power level at lower frequencies, but at X-band we had to be very, very careful to minimise the losses at every stage of design and production. Happily, our engineering team rose to the challenge and the customer was delighted with the result.”