Wire spring relay

A wire spring relay is a type of relay, primarily manufactured by the Western Electric Company for use by the Bell System in electromechanical telephone exchanges. It was licenced for use around the world, and was commonplace in Japan. A wire-spring relay has springs made from drawn wires of phosphor bronze, rather than cut from flat sheet metal as in the earlier flat spring relay, and has greater reliability than other types of relays. Wire spring relays were the most suitable relays for logic and computing functions. They were used extensively in markers, which were special purpose computers used to route calls in crossbar switch central offices.

Physical Description

A wire spring relay has two major parts, the electromagnet and the contacts. The electromagnet can have an resistance of between 15 and 200 ohms, and is often designed to operate satisfactorily at a common telephony voltage, such as 24 or 48 volts.

The electromagnet can also be modified, by the insertion of metallic slugs (lumps) to create a brief delay before pulling in the contacts, or hold the contacts in place briefly after power is removed.

A wire spring relay typically has many contacts, each plated with precious metals such as palladium. Each contact is either a fixed contact, which does not move, or is a moving contact, and is made from a short piece of wire. The majority of the wire spring relays manufactured in the 1960s had twelve fixed contacts. Each fixed contact, in the shape of a square box, is mounted on the end of a thick wire stem. A "make" contact, a "break" contact, or both can be provided for each fixed contact. A moving contact consists of two wires projecting out of the base of the relay, bent slightly inwards in order to exert pressure against the armature.

The moving contacts are held away from the fixed contacts by a wooden pattern. By changing the depth of the cuts on this form, the contacts can be made to make or break earlier or later than others. This can be used to transfer electrical control or power from one source to another by having a "make" contact operate before the corresponding "break" contact does.

Rough adjustments can be made to the fixed contacts as a whole by inserting a screwdriver blade into a slot in the front support structure and twisting as appropriate. This usually suffices to cause the contacts to make and break when they should. In some cases a special tool to adjust the bend of the springs may be necessary to adjust individual fixed or moving contacts.

Use as Logic

Wire spring relays could be interconnected, with relays feeding back into each other, to create the typical combinatorial and memory logic gates circuits that were later used in silicon design.

The contacts of one or more relays can be used to drive the coil of another relay. To make an OR gate for example, the contacts of several input relays may be placed in parallel circuits and used to drive the electromagnet of a third relay. This, along with series circuits and more complicated schemes such as multiply-wound electromagnets, allows the creation of AND gates, OR gates and Inverters (using the normally closed contact on a relay). Using these simple circuits in combination with De Morgan's Laws, any combinatorial function can be created using relays.

Use as Memory

Memory circuits in the form of latches can also be created by having a relay contact complete the circuit of its own coil when operated. The relay will then latch and store the state to which it was driven. With this capability, relays were used to create special purpose computers for telephone switches in the 1930s. These designs were converted, starting in the 1950s, to wire spring relays, making them faster and more reliable. The majority of Wire Spring Relays were used in 5XB switches.

Reed relays are better suited to data storage. They were used in conjunction with wire spring relays, for example to store digits for sending to other crossbar switching offices. In a multi-frequency sender (the part of a switch which sends routing information about outgoing calls over trunk lines), for example, wire spring relays direct the dialed digits one at a time from reed relay packs to frequency generators, under sequential control of logic implemented with wire spring relays. At the other end, similar relays steered the incoming digits from the tone decoder to a reed relay memory.

ystems

Wire spring releays were also incorporated into the signaling channel units of carrier systems.

For the Stored Program Control exchanges of the early 1970s, many relays were made with steel cores that remained magnetized after current ceased to flow in the winding. This "magnetic latching" feature, different from the use of slugs to delay relay operation, was used in the arrays of reed relays that switched connection paths in the early models of Electronic Switching Systems. A miniature wire spring relay was also produced, starting in approximately 1974 as part of the 1A redesign of the 1ESS switch.

Manufacturing of wire spring relays greatly declined in the late 20th century due to the introduction of digital electronic switching systems that used them in very small numbers.