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Konusu 'Elektronik Devreler' forumundadır ve guclusat tarafından 1 Ekim 2016 başlatılmıştır.

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    guclusat Tanınmış Üye Süper Moderatör

    14 Haziran 2009
    Ödül Puanları:
    Theory of Operation

    Magneto telephones were the first widespread type of instrument. They derive their name from the use of a magneto (small hand generator) to develop an alternating current of about 100 Volts to signal the other party or operator. The advantages of magneto circuits are simplicity, ruggedness, and ability to operate over long and poor-quality lines. The disadvantages are the requirement of separate batteries at each location (hence the use of the term "local battery" to describe magneto instruments) and inefficient switchboard use.
    Figure 1: The basic WALL PHONE diagram of a Magneto Circuit

    Figure 2: Alternate magneto wall telephone circuit
    (redrawn from Northern Electric diagram).
    Note the addition of the pushbutton, which permits the
    user to ring either the switchboard or other parties.

    Candlestick and cradle instrument circuits. The basic circuit shown in Figures 1 and 2 is used in wall-mounted magneto phones having a separate transmitter and receiver. Later types used a candlestick instrument with a separate wall-mounted ringer box, and still more "modern" types used a cradle phone with separate ringer box. The circuit for the former is shown in Figure 3 and for the latter in Figure 4. Theory of 3 operation is identical for each, the major difference being in the hookswitch configuration.

    Figure 3: Candlestick circuit; use with
    wall-mounted ringer box above.

    Figure 4: Cradle circuit; use with
    wall-mounted ringer box above.

    There are three parts to a Magneto Circuit
    The Talking Circuit; The Receiving Circuit; and The Signalling Circuit.

    Talking Circuit
    The talking circuit consists of the transmitter (microphone), the hookswitch, the primary of the induction coil (transformer), and the battery. Thetransmitter is a carbon microphone, composed of loosely packed carbon granules affixed to a metal (later a fiber or impregnated cloth) diaphragm. The diaphragm vibrates in response to the sound waves from the speaker’s voice, alternately compressing and releasing the carbon granules, thereby varying their resistance. The varying current produced, flowing through the primary of the induction coil, induces a current into the secondary, which is carried by the line (connected to L1 and L2) to the receiver of the distant party. The purpose of the hookswitch is to interrupt the battery current when the instrument is not in use, extending the life of the battery.
    Receiving Circuit
    The receiving circuit consists of the receiver (earphone), secondary of the induction coil, hookswitch, and external line. The receiver is a diaphragmof magnetic material, separated by a small distance from the permanent magnet which is also the core of a winding of fine-gauge wire. Alternatingcurrent reaching the receiver from the external line, through the induction coil and hookswitch, varies the magnetic field produced by the permanentmagnet core, setting the diaphragm in motion to reproduce the sound waves impinging on the transmitter diaphragm of the distant telephone. The purpose of the hookswitch in the receiver circuit is to remove the phone from the line when not in use. Were this not done, energy would beabsorbed by the transmitter and receiver circuits, diminishing the power received by other instruments on the line, and interfering with the ringingsignals.
    Signalling Circuit
    The signalling circuit consists of two parts: the magneto and the ringer. When cranked the magneto generates 80 to 100 Volts a.c., at about 20 Hertz (cycles per second). It also contains a switch which disconnects the magneto from the circuit when not being cranked (possibly thereby connectingthe ringer--see Figure 1b). The ringer is a bell resonating at 20 Hertz with a high impedance at voice frequencies to prevent loss of talking power.There are several possible configurations of the signalling circuit. One method (solid lines in Figure 1a) shows the ringer connected across the two line wires, and the magneto connected from L1 to ground. The distant instrument in such a system (or the switchboard) would use the configurationshown by the dashed lines. In this way one party rings the other across the line wires, and the other rings the first from L1 to ground. Thus neitherrings his own bell. An alternative is shown in Figure 1b. Here the magneto switch disconnects the bell when the magneto is cranked. The solid lines thus are identical to the circuit shown in Figure 1a. However, if the movable magneto wire is transferred from ground to L2, the system is adapted to a multi-party line (i.e. one without switchboard). Any party can ring all other parties, while not ringing his own bell. Each instrument is then wired identically.
    Rebuilding and Troubleshooting
    Magneto instruments may be checked out and improved for operation on magneto lines as follows.

    Talking circuit: Old-style carbon granule transmitters can still be used, but verify that they are not open; resistance should measure between 50 and 300 ohms. However, more clarity can be obtained by replacing old-style transmitters with new "capsule" units used in modern telephones. Either F-1 units (2-1/4 inches in diameter) or T-1 units (1-3/4 inches) may be used, depending on space. Electret units, providing even greater clarity, are packaged in T-1 form and sold by Walker Equipment and others for G-style handsets. The even smaller N-1 units, only 1-1/4 inches in diameter, are sold by Roanwell as Model 200 for use in Model 52 operator sets. Leads should not be soldered to their terminals due to the risk of heat damage; instead utilize electrically conductive epoxy. European-style desk and wall phones with "French" handsets have less internal space for the transmitter, which may be replaced if necessary with the above-mentioned N-1 unit. Care should be exercised in removing the front cap of such transmitters: in certain units the carbon granules are loose and will spill out if the handset is not held with the transmitter opening upward during disassembly. The induction coil should also be checked for continuity if the phone is not working. The primary should measure between one and four ohms and the secondary between 10 and 40 ohms. Defective cords are a common source of trouble on old phones. Resistance of each wire should be no more than five ohms and should not vary when the cord is flexed.

    Receiving circuit: Common difficulties are accumulation of dirt between the diaphragm and magnet faces on long-pole receivers; too little or too much gap; loss of magnetism; or open coils. Units can be checked by temporarily substituting a receiver from a modern instrument; if there is a substantial difference in volume, a new receiver can be purchased. Remember in replacing or remounting cords to anchor the cord in such a way as to provide a strain relief. Low-volume capsule or non-capsule receivers in handset instruments can usually be replaced by an HC-3 capsule receiver, only 1-9/16 inches in diameter. (See rear of this booklet for suggested suppliers of these parts.)

    Signalling circuit: Bells can be checked for continuity--coil resistance should measure a few hundred to a thousand ohms. A common difficulty is accumulation of dirt or magnetic filings between the magnet cores and the armature which moves the clapper. Magnetos should produce between 80 and 100 V. Failure may be due to an internal open circuit or simply to dirty or improperly gapped contacts on the switch which connects the magneto when cranked.
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