Synchro Systems

Table 13-1.—Comparison of Binary-Coded Decimal (BCD), Gray Code, and Natural Binary Code Synchro Systems The term synchro is an abbreviation of the word synchronous. It is the name given to a variety of rotary, electromechanical, position sensing devices. Synchro signals are used to transmit the angular position (0 to 360 degrees) of a rotor shaft in a synchro transmitter. When the signals are applied to one or more synchro receivers, the rotor shaft in each receiver is positioned to match the transmitter’s shaft position (figure 13-4). In this example, the receiver shaft in turn drives an indicator dial to display the transmitted information. The combination of synchro transmitter and receivers is called a synchro system. There are two major classifications of synchro systems: torque systems and control systems. Figure 13-4.—Torque synchro system transmitter and receivers. Torque systems provide torque or turning force to drive light loads such as indicator dials, pointers, or other mechanical outputs. Control synchro systems provide an electrical output used to control the power that performs mechanical work. The control synchro normally feeds a control transformer, not a control receiver. The control transformer output is fed to devices such as a servo system to control larger systems and devices. The synchro signals converted by CDS equipment may be either control synchro signals or torque synchro signals; however, control synchro signals are preferred because they are generally more accurate than torque synchro signals. OPERATING VOLTAGES AND FRE- QUENCIES. —Most shipboard synchro systems operate on a supply voltage of 115 volts ac at a frequency of 60 or 400 Hz. Synchros operating at 115 volts 400 Hz are generally more accurate than the 60-Hz synchros. Most newer weapon systems use 400-Hz synchros exclusively. SINGLE-SPEED, MULTISPEED, AND DUAL-SPEED SYNCHRO SYSTEMS. —The accuracy of the data to be transmitted is a factor in any synchro system. If the data covers a wide range of values, then the basic synchro system is unable to detect small changes in the data. When this happens, the accuracy of the system decreases. Multispeed synchro systems were developed to correct this deficiency. Multispeed synchro systems use more than one speed of data transmission. The speed of data transmission is the number of times the synchro transmitter rotor must turn 360 degrees to transmit a fuIl range of values. In a 1-speed system, one rotation of the transmitter rotor covers the full range of values. The 13-5