Acousticon Transmitter. In Fig. 46 is shown a transmitter adapted for such use. This has been termed by its makers the _acousticon transmitter_. Like all the transmitters previously discussed, this is of the variable-resistance type, but it differs from them all in that it has no damping springs; in that carbon b.a.l.l.s are subst.i.tuted for carbon granules; and in that the diaphragm itself serves as the front electrode.
This transmitter consists of a cup _1_, into which is set a cylindrical block _2_, in one face of which are a number of hemispherical recesses. The diaphragm _3_ is made of thin carbon and is so placed in the transmitter as to cover the openings of the recesses in the carbon block, and lie close enough to the carbon block, without engaging it, to prevent the carbon particles from falling out. The diaphragm thus serves as the front electrode and the carbon block as the rear electrode. The recesses in the carbon block are about two-thirds filled with small carbon b.a.l.l.s, which are about the size of fine sand. The front piece _4_ of the transmitter is of sheet metal and serves to hold the diaphragm in place. To admit the sound waves it is provided with a circular opening opposite to and about the size of the rear electrode block. On this front piece are mounted the two terminals of the transmitter, connected respectively to the two electrodes, terminal _5_ being insulated from the front piece and connected by a thin metal strip with the diaphragm, while terminal _6_ is mounted directly on the front piece and connected through the cup _1_ with the carbon block _2_, or back electrode of the transmitter.
[Ill.u.s.tration: Fig 46. Acousticon Transmitter]
When this transmitter is used in connection with outfits for the deaf, it is placed in a hard rubber containing case, consisting of a hollow cylindrical piece _7_, which has fastened to it a cover _8_. This cover has a circular row of openings or holes near its outer edge, as shown at _9_, through which the sound waves may pa.s.s to the chamber within, and thence find their way through the round hole in the center of the front plate _4_ to the diaphragm _3_. It is probable also that the front face of the cover _8_ of the outer case vibrates, and in this way also causes sound waves to impinge against the diaphragm.
This arrangement provides a large receiving surface for the sound waves, but, owing to the fact that the openings in the containing case are not opposite the opening in the transmitter proper, the sound waves do not impinge directly against the diaphragm. This peculiar arrangement is probably the result of an endeavor to prevent the transmitter from being too strongly actuated by violent sounds close to it. Instruments of this kind are very sensitive and under proper conditions are readily responsive to words spoken in an ordinary tone ten feet away.
[Ill.u.s.tration: Fig. 47. Switchboard Transmitter]
Switchboard Transmitter. Another special adaptation of the telephone transmitter is that for use of telephone operators at central-office switchboards. The requirements in this case are such that the operator must always be able to speak into the transmitter while seated before the switchboard, and yet allow both of her hands to be free for use.
This was formerly accomplished by suspending an ordinary granular-carbon transmitter in front of the operator, but a later development has resulted in the adoption of the so-called breast transmitter, shown in Fig. 47. This is merely an ordinary granular-carbon transmitter mounted on a plate which is strapped on the breast of the operator, the transmitter being provided with a long curved mouthpiece which projects in such a manner as to lie just in front of the operator"s lips. This device has the advantage of automatically following the operator in her movements. The breast transmitter shown in Fig. 47, is that of the Dean Electric Company.
[Ill.u.s.tration: Fig. 48. Transmitter Symbols]
Conventional Diagram. There are several common ways of ill.u.s.trating transmitters in diagrams of circuits in which they are employed. The three most common ways are shown in Fig. 48. The one at the left is supposed to be a side view of an ordinary instrument, the one in the center a front view, and the one at the right to be merely a suggestive arrangement of the diaphragm and the rear electrode. The one at the right is best and perhaps most common; the center one is the poorest and least used.
CHAPTER VI
RECEIVERS
The telephone receiver is the device which translates the energy of the voice currents into the energy of corresponding sound waves. All telephone receivers today are of the electromagnetic type, the voice currents causing a varying magnetic pull on an armature or diaphragm, which in turn produces the sound waves corresponding to the undulations of the voice currents.
Early Receivers. The early forms of telephone receivers were of the _single-pole_ type; that is, the type wherein but one pole of the electromagnet was presented to the diaphragm. The single-pole receiver that formed the companion piece to the old Blake transmitter and that was the standard of the Bell companies for many years, is shown in Fig. 49. While this has almost completely pa.s.sed out of use, it may be profitably studied in order that a comparison may be made between certain features of its construction and those of the later forms of receivers.
The coil of this receiver was wound on a round iron core _2_, flattened at one end to afford means for attaching the permanent magnet. The permanent magnet was of laminated construction, consisting of four hard steel bars _1_, extending nearly the entire length of the receiver sh.e.l.l. These steel bars were all magnetized separately and placed with like poles together so as to form a single bar magnet.
They were laid together in pairs so as to include between the pairs the flattened end of the pole piece _2_ at one end and the flattened portion of the tail piece _3_ at the other end. This whole magnet structure, including the core, the tail piece, and the permanently magnetized steel bars, was clamped together by screws as shown. The containing sh.e.l.l was of hard rubber consisting of three pieces, the barrel _4_, the ear-piece _5_, and the tail cap _6_. The barrel and the ear piece engaged each other by means of a screw thread and served to clamp the diaphragm between them. The compound bar magnet was held in place within the sh.e.l.l by means of a screw _7_ pa.s.sing through the hard rubber tail cap _6_ and into the tail block _3_ of the magnet.
External binding posts mounted on the tail cap, as shown, were connected by heavy leading-in wires to the terminals of the electromagnet.
A casual consideration of the magnetic circuit of this instrument will show that it was inefficient, since the return path for the lines of force set up by the bar magnet was necessarily through a very long air path. Notwithstanding this, these receivers were capable of giving excellent articulation and were of marvelous delicacy of action. A very grave fault was that the magnet was supported in the sh.e.l.l at the end farthest removed from the diaphragm. As a result it was difficult to maintain a permanent adjustment between the pole piece and the diaphragm. One reason for this was that hard rubber and steel contract and expand under changes of temperature at very different rates, and therefore the distance between the pole piece and the diaphragm changed with changes of temperature. Another grave defect, brought about by this tying together of the permanent magnet and the sh.e.l.l which supported the diaphragm at the end farthest from the diaphragm, was that any mechanical shocks were thus given a good chance to alter the adjustment.
[Ill.u.s.tration: Fig. 49. Single-Pole Receiver]
Modern Receivers. Receivers of today differ from this old single-pole receiver in two radical respects. In the first place, the modern receiver is of the bi-polar type, consisting essentially of a horseshoe magnet presenting both of its poles to the diaphragm. In the second place, the modern practice is to either support all of the working parts of the receiver, _i.e._, the magnet, the coils, and the diaphragm, by an inner metallic frame entirely independent of the sh.e.l.l; or, if the sh.e.l.l is used as a part of the structure, to rigidly fasten the several parts close to the diaphragm rather than at the end farthest removed from the diaphragm.
Western Electric Receiver. The standard bi-polar receiver of the Western Electric Company, in use by practically all of the Bell operating companies throughout this country and in large use abroad, is shown in Fig. 50. In this the sh.e.l.l is of three pieces, consisting of the barrel _1_, the ear cap _2_, and the tail cap _3_. The tail cap and the barrel are permanently fastened together to form substantially a single piece. Two permanently magnetized bar magnets _4-4_ are employed, these being clamped together at their upper ends, as shown, so as to include the soft iron block _5_ between them. The north pole of one of these magnets is clamped to the south pole of the other, so that in reality a horseshoe magnet is formed. At their lower ends, these two permanent magnets are clamped against the soft iron pole pieces _6-6_, a threaded block _7_ also being clamped rigidly between these pole pieces at this point. On the ends of the pole pieces the bobbins are wound. The whole magnet structure is secured within the sh.e.l.l _1_ by means of a screw thread on the block _7_ which engages a corresponding internal screw thread in the sh.e.l.l _1_. As a result of this construction the whole magnet structure is bound rigidly to the sh.e.l.l structure at a point close to the diaphragm, comparatively speaking, and as a result of this close coupling, the relation between the diaphragm and the pole piece is very much more rigid and substantial than in the case where the magnet structure and the sh.e.l.l were secured together at the end farthest removed from the diaphragm.
[Ill.u.s.tration: Fig. 50. Western Electric Receiver]
Although this receiver shown in Fig. 50 is the standard in use by the Bell companies throughout this country, its numbers running well into the millions, it cannot be said to be a strictly modern receiver, because of at least one rather antiquated feature. The binding posts, by which the circuit conductors are led to the coils of this instrument, are mounted on the outside of the receiver sh.e.l.l, as indicated, and are thus subject to danger of mechanical injury and they are also exposed to the touch of the user, so that he may, in case of the wires being charged to an abnormal potential, receive a shock. Probably a more serious feature than either one of these is that the terminals of the flexible cords which attach to these binding posts are attached outside of the receiver sh.e.l.l, and are therefore exposed to the wear and tear of use, rather than being protected as they should be within the sh.e.l.l. Notwithstanding this undesirable feature, this receiver is a very efficient one and is excellently constructed.
[Ill.u.s.tration: Fig. 51. Kellogg Receiver]
Kellogg Receiver. In Fig. 51 is shown a bi-polar receiver with internal or concealed binding posts. This particular receiver is typical of a large number of similar kinds and is manufactured by the Kellogg Switchboard and Supply Company. Two straight permanently magnetized bar magnets _1-1_ are clamped together at their opposite ends so as to form a horseshoe magnet. At the end opposite the diaphragm these bars clamp between them a cylindrical piece of iron _2_, so as to complete the magnetic circuit at the end. At the end nearest the diaphragm they clamp between them the ends of the soft iron pole pieces _3-3_, and also a block of composite metal _4_ having a large circular f.l.a.n.g.e _4"_ which serves as a means for supporting the magnet structure within the sh.e.l.l. The screws by means of which the disk _4"_ is clamped to the shouldered seat in the sh.e.l.l do not enter the sh.e.l.l directly, but rather enter screw-threaded bra.s.s blocks which are moulded into the structure of the sh.e.l.l. It is seen from this construction that the diaphragm and the pole pieces and the magnet structure itself are all rigidly secured together through the medium of the sh.e.l.l at a point as close as possible to the diaphragm.
Between the magnets _1-1_ there is clamped an insulating block _5_, to which are fastened the terminal plates _6_, one on each side of the receiver. These terminal plates are thoroughly insulated from the magnets themselves and from all other metallic parts by means of sheets of fiber, as indicated by the heavy black lines. On these plates _6_ are carried the binding posts for the receiver cord terminals. A long tongue extends from each of the plates _6_ through a hole in the disk _4"_, into the coil chamber of the receiver, at which point the terminal of the magnet winding is secured to it. This tongue is insulated from the disk _4"_, where it pa.s.ses through it, by means of insulating bushing, as shown. The other terminal of the magnet coils is brought out to the other plate _6_ by means of a similar tongue on the other side.
In order that the receiver terminals proper may not be subjected to any strain in case the receiver is dropped and its weight caught on the receiver cord, a strain loop is formed as a continuation of the braided covering of the receiver cord, and this is tied to the permanent magnet structure, as shown. By making this strain loop short, it is obvious that whatever pull the cord receives will not be taken by the cord conductors leading to the binding posts or by the binding posts or the cord terminals themselves.
A number of other manufacturers have gone even a step further than this in securing permanency of adjustment between the receiver diaphragm and pole pieces. They have done this by not depending at all on the hard rubber sh.e.l.l as a part of the structure, but by enclosing the magnet coil in a cup of metal upon which the diaphragm is mounted, so that the permanency of relation between the diaphragm and the pole pieces is dependent only upon the metallic structure and not at all upon the less durable sh.e.l.l.
Direct-Current Receiver. Until about the middle of the year 1909, it was the universal practice to employ permanent magnets for giving the initial polarization to the magnet cores of telephone receivers. This is still done, and necessarily so, in receivers employed in connection with magneto telephones. In common-battery systems, however, where the direct transmitter current is fed from the central office to the local stations, it has been found that this current which must flow at any rate through the line may be made to serve the additional purpose of energizing the receiver magnets so as to give them the necessary initial polarity. A type of receiver has come into wide use as a result, which is commonly called the _direct-current receiver_, deriving its name from the fact that it employs the direct current that is flowing in the common-battery line to magnetize the receiver cores. The Automatic Electric Company, of Chicago, was probably the first company to adopt this form of receiver as its standard type.
Their receiver is shown in cross-section in Fig. 52, and a photograph of the same instrument partially disa.s.sembled is given in Fig. 53. The most noticeable thing about the construction of this receiver is the absence of permanent magnets. The entire working parts are contained within the bra.s.s cup _1_, which serves not only as a container for the magnet, but also as a seat for the diaphragm. This receiver is therefore ill.u.s.trative of the type mentioned above, wherein the relation between the diaphragm and the pole pieces is not dependent upon any connection through the sh.e.l.l.
[Ill.u.s.tration: Fig. 52. Automatic Electric Company Direct-Current Receiver]
[Ill.u.s.tration: Fig. 53. Automatic Electric Company Direct-Current Receiver]
The coil of this instrument consists of a single cylindrical spool _2_, mounted on a cylindrical core. This bobbin lies within a soft iron-punching _3_, the form of which is most clearly shown in Fig. 53, and this punching affords a return path to the diaphragm for the lines of force set up in the magnet core. Obviously a magnetizing current pa.s.sing through the winding of the coil will cause the end of the core toward the diaphragm to be polarized, say positively, while the end of the enclosing sh.e.l.l will be polarized in the other polarity, negatively. Both poles of the magnet are therefore presented to the diaphragm and the only air gap in the magnetic circuit is that between the diaphragm and these poles. The magnetic circuit is therefore one of great efficiency, since it consists almost entirely of iron, the only air gap being that across which the attraction of the diaphragm is to take place.
The action of this receiver will be understood when it is stated that in common-battery practice, as will be shown in later chapters, a steady current flows over the line for energizing the transmitter. On this current is superposed the incoming voice currents from a distant station. The steady current flowing in the line will, in the case of this receiver, pa.s.s through the magnet winding and establish a normal magnetic field in the same way as if a permanent magnet were employed.
The superposed incoming voice currents will then be able to vary this magnetic field in exactly the same way as in the ordinary receiver.
An astonishing feature of this recent development of the so-called direct-current receiver is that it did not come into use until after about twenty years of common-battery practice. There is nothing new in the principles involved, as all of them were already understood and some of them were employed by Bell in his original telephone; in fact, the idea had been advanced time and again, and thrown aside as not being worth consideration. This is an ill.u.s.tration of a frequent occurrence in the development of almost any rapidly growing art. Ideas that are discarded as worthless in the early stages of the art are finally picked up and made use of. The reason for this is that in some cases the ideas come in advance of the art, or they are proposed before the art is ready to use them. In other cases the idea as originally proposed lacked some small but essential detail, or, as is more often the case, the experimenter in the early days did not have sufficient skill or knowledge to make it fit the requirements as he saw them.
Monarch Receiver. The receiver of the Automatic Electric Company just discussed employs but a single electromagnet by which the initial magnetization of the cores and also the variable magnetization necessary for speech reproduction is secured. The problem of the direct-current receiver has been attacked in another way by Ernest E.
Yaxley, of the Monarch Telephone Manufacturing Company, with the result shown in Fig. 54. The construction in this case is not unlike that of an ordinary permanent-magnet receiver, except that in the place of the permanent magnets two soft iron cores _1-1_ are employed.
On these are wound two long bobbins of insulated wire so that the direct current flowing over the telephone line will pa.s.s through these and magnetize the cores to the same degree and for the same purpose as in the case of permanent magnets. These soft iron magnet cores _1-1_ continue to a point near the coil chamber, where they join the two soft iron pole pieces _2-2_, upon which the ordinary voice-current coils are wound. The two long coils _4-4_, which may be termed the direct-current coils, are of somewhat lower resistance than the two voice-current coils _3-3_. They are, however, by virtue of their greater number of turns and the greater amount of iron that is included in their cores, of much higher impedance than the voice-current coils _3-3_. These two sets of coils _4-4_ and _3-3_ are connected in multiple. As a result of their lower ohmic resistance the coils _4-4_ will take a greater amount of the steady current which comes over the line, and therefore the greater proportion of the steady current will be employed in magnetizing the bar magnets. On account of their higher impedance to alternating currents, however, nearly all of the voice currents which are superposed on the steady currents, flowing in the line will pa.s.s through the voice-current coils _3-3_, and, being near the diaphragm, these currents will so vary the steady magnetism in the cores _2-2_ as to produce the necessary vibration of the diaphragm.
[Ill.u.s.tration: Fig. 54. Monarch Direct-Current Receiver]
This receiver, like the one of the Automatic Electric Company, does not rely on the sh.e.l.l in any respect to maintain the permanency of relation between the pole pieces and the diaphragm. The cup _5_, which is of pressed bra.s.s, contains the voice-current coils and also acts as a seat for the diaphragm. The entire working parts of this receiver may be removed by merely uns.c.r.e.w.i.n.g the ear piece from the hard rubber sh.e.l.l, thus permitting the whole works to be withdrawn in an obvious manner.
Dean Receiver. Of such decided novelty as to be almost revolutionary in character is the receiver recently put on the market by the Dean Electric Company and shown in Fig. 55. This receiver is of the direct-current type and employs but a single cylindrical bobbin of wire. The core of this bobbin and the return path for the magnetic lines of force set up in it are composed of soft iron punchings of substantially =E= shape. These punchings are laid together so as to form a laminated soft-iron field, the limbs of which are about square in cross-section. The coil is wound on the center portion of this _E_ as a core, the core being, as stated, approximately square in cross-section. The general form of magnetic circuit in this instrument is therefore similar to that of the Automatic Electric Company"s receiver, shown in Figs. 52 and 53, but the core is laminated instead of being solid as in that instrument.
[Ill.u.s.tration: Fig. 55. Dean Steel Sh.e.l.l Receiver]
The most unusual feature of this Dean receiver is that the use of hard rubber or composition does not enter into the formation of the sh.e.l.l, but instead a sh.e.l.l composed entirely of steel stampings has been subst.i.tuted therefor. The main portion of this sh.e.l.l is the barrel _1_. Great skill has evidently been exercised in the forming of this by the cold-drawn process, it presenting neither seams nor welds. The ear piece _2_ is also formed of steel of about the same gauge as the barrel _1_. Instead of screw-threading the steel parts, so that they would directly engage each other, the ingenious device has been employed of swaging a bra.s.s ring _3_ in the barrel portion and a similar bra.s.s ring _4_ in the ear cap portion, these two being slotted and keyed, as shown at _8_, so as to prevent their turning in their respective seats. The ring _3_ is provided with an external screw thread and the ring _4_ with an internal screw thread, so that the receiver cap is screwed on to the barrel in the same way as in the ordinary rubber sh.e.l.l. By the employment of these bra.s.s screw-threaded rings, the rusting together of the parts so that they could not be separated when required--a difficulty heretofore encountered in steel construction of similar parts--has been remedied.
[Ill.u.s.tration: Fig. 56. Working Parts of Dean Receiver]
The entire working parts of this receiver are contained within the cup _5_, the edge of which is f.l.a.n.g.ed outwardly to afford a seat for the diaphragm. The diaphragm is locked in place on the sh.e.l.l by a screw-threaded ring _6_, as is clearly indicated. A ring _7_ of insulating material is seated within the enlarged portion of the barrel _1_, and against this the f.l.a.n.g.e of the cup _5_ rests and is held in place by the cap _2_ when it is screwed home. The working parts of this receiver partially disa.s.sembled are shown in Fig. 56, which gives a clear idea of some of the features not clearly ill.u.s.trated in Fig. 55.
It cannot be denied that one of the princ.i.p.al items of maintenance of subscribers" station equipment has been due to the breakage of receiver sh.e.l.ls. The users frequently allow their receiver to fall and strike heavily against the wall or floor, thus not only subjecting the cords to great strain, but sometimes cracking or entirely breaking the receiver sh.e.l.l. The innovation thus proposed by the Dean Company of making the entire receiver sh.e.l.l of steel is of great interest. The sh.e.l.l, as will be seen, is entirely insulated from the circuit of the receiver so that no contact exists by which a user could receive a shock. The sh.e.l.l is enameled inside and out with a heavy black insulating enamel baked on, and said to be of great durability. How this enamel will wear remains to be seen. The insulation of the interior portions of the receiver is further guarded by providing a lining of fiber within the sh.e.l.l at all points where it seems possible that a cross could occur between some of the working parts and the metal of the sh.e.l.l. This type of receiver has not been on the market long enough to draw definite conclusions, based on experience in use, as to what its permanent performance will be.
Thus far in this chapter only those receivers which are commonly called _hand receivers_ have been discussed. These are the receivers that are ordinarily employed by the general public.
[Ill.u.s.tration: Fig. 57. Operator"s Receiver]
Operator"s Receiver. At the central office in telephone exchanges the operators are provided with receivers in order that they may communicate with the subscribers or with other operators. In order that they may have both of their hands free to set up and take down the connections and to perform all of the switching operations required, a special form of receiver is employed for this purpose, which is worn as a part of a head-gear and is commonly termed a _head receiver_. These are necessarily of very light construction, in order not to be burdensome to the operators, and obviously they must be efficient. They are ordinarily held in place at the ear by a metallic head band fitting over the head of the operator.
[Ill.u.s.tration: GRANT AVENUE OFFICE OF HOME TELEPHONE COMPANY, SAN FRANCISCO, CAL. A Type of Central-Office Buildings in Down-Town Districts of Large Cities.]
Such a receiver is shown in cross-section in Fig. 57, and completely a.s.sembled with its head band in Fig. 58. Referring to Fig. 57 the sh.e.l.l _1_ of the receiver is of aluminum and the magnets are formed of steel rings _2_, cross-magnetized so as to present a north pole on one side of the ring and a south pole on the other. The two L-shaped pole pieces _3_ are secured by screws to the poles of these ring magnets, and these pole pieces carry the magnet coils, as is clearly indicated.
These poles are presented to a soft iron diaphragm in exactly the same way as in the larger hand receivers, the diaphragm being clamped in place by a hard rubber ear piece, as shown. The head bands are frequently of steel covered with leather. They have a.s.sumed numerous forms, but the general form shown in Fig. 58 is the one commonly adopted.