DE245358C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 245358 CLASS 21 a. GROUP

ROBERTO CLEMENS GALLETTI in ROME.

Patented in the German Empire on March 18, 1910.

The invention relates to a method and a device for generating continuous, uninterrupted wave trains by means of primary spark discharges.

The essential feature of the invention is that the generation of the Oscillation circuits used for sparks via resistors and spark gaps connected in parallel continuously consecutive

ίο be energized so that they are in the secondary line induce a continuous wave current. In addition to the capacities provided for each individual oscillation circuit (Capacitors) a capacitor common to all is provided, using which it is achieved that only one spark gap comes into effect. To this In contrast to the capacitors of the individual oscillating circuits, this common capacitor is used for all purposes resistors connected in parallel are charged at the same time, so that the charging takes place again and again very quickly, while the Oscillation circuits of the individual spark gaps are only ever charged via the associated resistor, so that their Charge happens much more slowly and the sparks between the spark gaps cannot skip individual oscillation circles at the same time, but in a certain way Order, which is determined by how long the one with the relevant spark gap related capacitor has been charged.

The devices for carrying out this process are shown schematically in the drawing shown.

Fig. Ι shows how a series of primary sparks can induce an air duct provided in the secondary circuit and used to emit the oscillation energy generated by the sparks into the room. The device consists of a number of equal capacity (capacitors) C _1, C _2, C ₃ ... c _n and a capacitor C ₀ which is equal in size may also be different in size from them as the rest or. These have a common assignment C. One end of a coil L serving as the primary winding of a transformer is connected to the free assignment of the capacitance C ₀ and also the conductor M of the high-voltage DC machine D, and the other end of the coil L is through the spark gaps S ₁ , S _2, S _3, S _n with the capacitances C _1, C _2, C ₃ ... C _n connected, and these are of equal size by resistors ^r v ^{r r} 3 · · · ^r n and the conductor N of connected to the other pole of the dynamo.

The secondary oscillation circuit consists of an air line A located on earth and a winding L ' wound around L , which is induced by all the oscillations generated in the primary oscillation circuits. These primary circles are: C ₀ , L, S ₁ , e _v C; C ₀ , L, S ₂ , C ₂ , C; C ₀ , L, S ₃ , c ₃ , C; ... C ₀ , L, S _n , C _n , C. The spark gap S, which is arranged at any point between the air line and earth, allows the individual wave trains to be observed, which are caused in the secondary line by the primary sparks, there

every induced wave train in 5 produces a spark.

If one considers each spark gap S ₁ , s ₂ ... S _n for itself, one finds that the frequency of the sparks is a certain one for each gap. This frequency is recognizable from the height of the tone that the sparks emit and a function of the virtual lengths of the spark gaps, the size of the resistances, the capacitance, the damping coefficient, the oscillation circuit, etc. All these factors are as equal as possible for each spark gap, and the capacitance c ₀ can also be the same as the capacitances C ₁ , C ₂ , C ₃ ... C _n or different therefrom. The resistors ^r i> ^r z ^r · 3 · ■ ■ ^r n are ^best inductively chosen to avoid violent power swings and to protect the dynamo from vibration.

It has been shown that when in this device C ₀ compared to C ₁ , c _a . . . C _{n is} not chosen too large, the discharges take place one after the other over all spark gaps. The sequence of the primary sparks is self-evident, and the circles of these discharges begin anew, endlessly at regular time intervals, so that the common induction of the primary oscillation circles in L and the secondary wave trains in the air line A follow one another in certain time intervals, which are a multiple is the frequency of the discharges in each spark gap and the number of spark gaps. One can convince oneself of this fact by taking a spark from the air line in S. It gives a musical tone whose number of vibrations is equal to the product of the sound waves generated by each spark gap and the number of spark gaps. This result was observed in a tone that corresponds to a few hundred sparks in S up to the upper hearing limit.

The automatic, mutual influence of the successive sparks of the various paths, which must take place in order to obtain the precision in the sequence of the sparks necessary for the production of a musical tone, is easily explained when one considers that the potential difference at each spark path is a sum of the Voltage of C ₀ and the capacitance associated with this spark gap.

It may be assumed that in the arrangement shown in FIG. Ι only the three spark circles S ₁ , S ₂ and S ₃ are present and power is supplied to all of them together. Although these spark circles are to be assumed to be of the same type, one of them must nonetheless come to discharge first, e.g. B. S ₁ , L, C ₀ , C ₁ , and the _{spark jumping over at S 1} will prevent that at S ₂ , S ₃ , even if sparks are about to jump over there, sparks will jump over, because at every moment the potential difference at any one of the Funkenstreckeri S ₁ , S ₂ , S _{3 is} equal to the sum of the potential differences of the capacitors connected over it. If one expresses the potential differences at the spark gaps _{through S 1} , S ₂ , S _3, through C ₀ , C ₁ , C ₂ , C ₃ the potential differences of the capacitors, one obtains the following equations:

5 ₁ - C ₀ -j- C ₁

5 ₂ = C ₀ -f- C ₂

5 ₃ = C ₀ -f C ₃ .

The spark that skips at S ₁ cancels out, if not the entire potential difference of S ₁ , at least a large part, and thus also the potential difference of C ₀ -j-C ₁ . This voltage drop is distributed between C ₀ and C ₁ according to a certain ratio. The jump of the spark at S ₁ therefore causes a voltage drop of c ₀ and consequently also a decrease in the potential differences of s ₂ and s ₃ , so that no sparks can jump over these spark gaps s ₂ and S _3.

As soon as the spark has jumped over _{at S 1 , the capacitor C 0} is charged again very quickly via the three resistors A ₁ , R ₂ , R ₃ connected in parallel, while the capacitor C ₁ via the resistor R ₁ alone is much slower than the capacitor c ₀ is reloaded. The capacitors C ₂ and c ₃ have not been discharged, and therefore a spark will now jump either at s ₂ or s ₃ as soon as the voltage of the capacitor C ₀ has increased so much that it, together with the potential difference of the capacitor c ₂ or C _{3 reaches} the discharge voltage of 20,000 volts. Let it be assumed that _{a spark now skips at s 2.} During this process, a spark cannot skip either at S ₁ or at s ₃ because the voltage of the capacitor c _{0 has} fallen.

After the transition of the spark at S ₂ , the capacitor C _{0 is} charged again quickly via the three resistors R ₁ , R ₂ , R _s connected in parallel, while the capacitor C ₁ via the resistor A ₁ and the capacitor c ₂ less quickly via the Resistor R _{2 is} charged.

The capacitor c ₃ has not yet been discharged and therefore has its full voltage. Therefore, a spark must now jump over at s _3.

After the transition of the spark at s ₃ , the capacitor C _{1 has been} charged during the period of two sparks, ie the spark at S ₂ and S ₃ , while the capacitor c _{2 is} only charged during one spark period, namely

borrowed the spark at s _{3 has been} charged. For this reason, the voltage of the capacitor C _{1 is} higher than that of the capacitor c _2> and the. A discharge voltage of 20,000 volts will therefore be reached more quickly _{at S 1 than at S 2} , so that after the spark transition at S _3, a spark will jump over again at S _1. After this spark at S ₁ , the capacitor c _{2 is} during

ίο the duration of the sparks at s ₃ and S ₁ , and the capacitor c _{3 has} only been charged during a spark duration, namely the spark at S ₁ ^ On the spark at S _1, a spark must jump over at s ₂ , etc. in the Sequence S ₁ , S ₂ , Sg, S ₁ , S ₂ , S ₃ ...; "■

These primary discharges now induce wave trains in the secondary line, as shown schematically in FIG. 2, in which the wave trains generated by four primary oscillation circles P ₁ , P ₂ , Ps ^and Pt in a secondary circuit are plotted on a time axis Z. There can be a time interval t between the beginning and the end of two successive primary wave trains, or they can overlap in time; it is sufficient for this to select the number of waves per second to be sufficiently large and their damping coefficient to be small. This temporal overlapping of the primary sparks (waves) can be avoided in practice by using rapidly successive and rapidly ending waves, or vice versa, the number of sparks coming to the unit of time must be limited if they are of a long duration, i.e. you Oscillation circuit has a small damping coefficient. If there are time intervals between primary sparks or between spark circles, the necessary connection can be obtained by adding a common spark gap. This variant is shown in FIG. 3. The spark gap xy is arranged between the free plate of the capacitance c ₀ and the primary induction L and is connected with this directly to one pole of the dynamo. As long as the discharges last via the spark gaps S ₁ , S ₂ ... S _n , the distance xy is also bridged. This can be accepted as a leader. If no more discharges take place with this arrangement, the result, although the resistance of the section xy is low compared to that of the sections S ₁ , s ₂ , s _n, is that despite the static electricity quantities accumulating in χ , the result is directly through the feed line coming current, which brings the small capacity of χ in a very short time to such a voltage that a discharge must take place, this does not take its course over xy , but over one of the paths S ₁₁ S ₂ , ... s _n . The reason for this is that the free plate of capacitance e _d and y is completely isolated from the other pole of the machine. For alternating current this would of course not be the case; the small distance xy would be before the distances S ₁ , s ₂ . .: s " bridged, because with this type of current y would induce quantities of electricity. It follows from this that no noticeable time interval can arise between two primary wave trains; because, if xy were not bridged and a dielectric intermediate layer were formed, it would become the. Isolation of a very small capacitance in χ follow and the potential can be increased so that a discharge through one of the spark gaps S ₁ , S ₂ ... s _n would be brought about in a very short time.

This function of the path xy can be demonstrated experimentally by a series of primary sparks of such number and duration that time intervals take place between the individual discharges by using an arrangement according to FIG. 1 and then switching on the path xy. This interconnection immediately gives the necessary increase in the discharge frequency in order to bring about the desired relationship between the individual wave trains. The sound generated by the spark in xy has the same tone as the spark S in the secondary oscillation circle.

It goes without saying that if the path xy is to work in the manner described, its electrodes must be protected against overheating so that the production of hot gases does not keep the path permanently conductive. Especially when using many primary oscillation circuits, which require a large charging current, and where xy is exposed to very strong oscillations, which strongly heat the electrodes of this section, it is better to place between the free plates or assignments of the capacities C ₁ , C ₂ . .. c _n and its feeder switches on similar auxiliary spark gaps at xy (x _v X ₂ , X _n , Fig. 4).

As long as a primary spark lasts, its alternating potential induces all capacities, but as soon as this strong source of oscillation ceases, the paths X ₁ , x ₂ , x _n tend to prevent the supply of current to their capacities, and this is mainly the case for the capacity that is most heavily charged, since its charging current is already in the process of stopping by itself. The most heavily charged capacitance is therefore first isolated by X ₁ , x ₂ or x _n , and therefore the discharge will also take place first through the corresponding spark gap s.
. Generally speaking, the purpose of the intermediary

The generation of the spark circle obtained through resistors connected in parallel and spark gaps unlimited quantities of vibration energy without overheating the spark gaps, and without losing a lot of energy in the resistors.

From the foregoing it follows that the primary sparks of a spark circle and these circles uninterrupted with no time intervals

ίο can be generated sequentially, so that this creates an uninterrupted wave train in the secondary line, which is more constant in its width, the smaller the damping in the secondary circuit is.

Whichever is the damping capacity of the secondary circuit, e.g. B. the big one powerful air duct, able to instantly dissipate all energy from each primary spark.

ao, it is sufficient for wireless telephony that the spark periods in each circle and the succession of these circles lie above the audible tones.

Practical benefits are available in the wireless telegraph when the spark discharges of a circle made uninterrupted and time intervals between the circles be left. This creates groups of already constants in the secondary line Receive wave trains.

Claims (3)

Patent Claims: i. Method for generating uninterrupted wave trains by means of primary spark circuits, characterized in that these oscillating circuits are excited in succession by means of resistors and spark gaps connected in parallel, in that a capacitor (c ₀ ) common to all oscillating circuits is via the resistors connected in parallel (V ₁ , r _%.. .) is always charged again quickly, while the charging of the capacitor belonging to each resonant circuit only takes place via the relevant resistor and therefore much more slowly, so that the spark circuits take effect one after the other. 2. Apparatus for carrying out the method according to claim 1, characterized through several capacities, which all have a shared occupancy, and of which the one with its free assignment to one pole of the electrical Feed line and connected to a primary coil of a transformer, while all others with their free assignments by means of equal resistance to the other pole of the feed line are connected, with similar spark gaps are arranged between each of the latter capacities and the former, so that the latter capacitance and the primary coil at all vibrations caused by the successive discharges are generated in the spark gaps, participate and the secondary coil is constantly induced. 3. Apparatus according to claim 2, characterized by the arrangement of auxiliary spark gaps between the free occupancy of capacities and the connection points between these and the feed line, in order to avoid temporal interruptions of the spark circles and thus an uninterrupted one secondary wave train. 1 sheet of drawings.