DE2311929C3 - Flash unit - Google Patents

Description

The invention relates to a flash device with a flash capacitor and at least two with the flash capacitor connected in series connected gas-filled flash tubes, whose ignition electrodes are interconnected are.

From US-PS 3 237 003 a flash device is known, in which the conventional flash tube by a series connection of two more or less separated Flash tubes is replaced. This series connection is based on the knowledge that to achieve an optimal light yield of the discharge arc and thus the flash tube certain dimensions must have, but on the other hand it is difficult to create a reflector that matches at these dimensions results in an optimal illumination angle. With the well-known flash unit the required total length of the discharge arc is therefore based on two flash tubes connected in series divided, with each flash tube and thus each partial discharge arc a separate reflector assigned. In this way it is possible to achieve a high light output with a good angle of illumination to combine.

In the known flash tube, the charge accumulated in the flash capacitor flows after the flash tube has ignited once, within a very short time via this, so that a maximum current of several one hundred amperes is reached and with an extremely short light emission time the light emission peak occurs almost immediately after triggering. This high current surge and the associated short discharge times result in poor conversion efficiency in the lightning capacitor stored energy in light emission since most of the electricity is converted into heat will.

The object of the invention is to increase the efficiency of a flash unit by having a larger one Part of the energy taken from the flash capacitor is converted into light as before, and at the same time the Extend the duration of the lightning discharge.

According to the invention, this object is achieved by the features of the patent claim. Beneficial Further developments of the invention are contained in the subclaims.

The series connection of at least two flash tubes compared to known flash tubes increased total impedance leads to a lower discharge current, which is associated with higher efficiency and a prolonged flash discharge time. To make sure that despite the series connection two or more flash tubes immediately with the occurrence of an ignition pulse all flash tubes are ignited, it is provided that at least one of the flash tubes with an additional auxiliary electrode is provided. which when connected to a corresponding voltage ensures that the gas of this Tube already before the ignition pulse occurs is ionized to a certain extent. When the ignition pulse occurs, this flash tube is in a discharge state brought so that the other Blitzrönre no longer provided with an auxiliary electrode can be ignited at the same time as the ignition pulse. Without the auxiliary electrode according to the invention a certain time would elapse after the ignition pulse was applied to the ignition electrode, bin Both flash tubes connected in series are in the discharge state and this discharge can take place.

The invention is illustrated in the following with the aid of a schematic Drawings of exemplary embodiments explained neari. Show it:

1 shows the circuit of a known flashlight device,

F i g. 2 curves of the light emission causing Emission current and emission quantity trend from flash tubes in the circuit according to FIG. 1 as well as in a circuit of the flashlight device according to the invention,

3 and 4 circuits of the inventive Flash unit.

Figs. 5 to 7 show the construction of flash tubes as used in the circuits of Figs can and

F i g. 8 shows the circuit of a further embodiment of a flashlight device according to the invention.

Fig. 1 shows the circuit of a known flash device. This circuit contains in detail a circuit part 1 for generating an increased Voltage, a main or lightning capacitor 2 current-limiting resistors 3 and 4 for one Commutation capacitor S, a xenon tube 6 serving as a flash tube, one around the xenon tube « around attached ignition electrode 7, a gate terminal 8 of a thyristor 9 and a gate terminal Terminal 10 of a thyristor 11. If in the circuit according to FIG. 1 after the charging of the lightning capacitor gate 2 an ignition voltage is applied to the ignition electrode "and the gate terminal 8, for example < synchronous with the opening and closing of a comb raverschlusses, then there is a discharge via the xenon tube 6, whereby through the latter un < through the thyristor 9 in the following as an emission

current designated current flows. When the light directed at an object and illuminating it is the X. nonröhre has reached a predetermined value, which can be determined by a control circuit, then A gate voltage can be applied to the gate terminal 10 of the thyristor 11 by this control circuit will. The control circuit can, for example, be in an integration circuit and have an element which illuminating light of the xenon tube 6 used to illuminate the object receives. Because of the gate voltage from the control circuit, the thyristor 11 is conductive, so that the positive charge of the commutation capacitor 5 via the Thyristor 11 reaches the cathode of thyristor 9 and puts it in the locked state. The emission current through the xenon tube 6 is then interrupted and the xenon tube stops emitting light. During the emission time of the xenon tube 6 some 100 amperes of emission current flow through the thyristor 9 of the circuit shown, so that it is necessary is to use an element with high current carrying capacity and high voltage resistance. That means, that the value of the emission current that flows from the capacitor 2 into the xenon tube is derived from it shows that the charging voltage of the lightning capacitor 2 by the impedance of the thyristor 9 in the on state divides, so that the rush current in the thyristor 9 corresponding to the aforementioned emission current of a few 100 amps also reached some 100 amps. In order to stop the emission of the xenon tube in the vicinity of the m.i \ imal current value, it is necessary to that the commutation capacitor 5 has such a large capacity that the stored in it Sufficient energy to bring the thyristor 9 into the blocking state. With the known circuit you have to Therefore, a thyristor 9 and a commutation circuit for him should be provided, which is an additional Must have a high current-carrying capacity and high voltage resistance, which is the cost of the device elevated.

The disadvantage of the known circuit of FIG. 1 is that the xenon tube at the time of ignition is instantly brought to emission, as indicated by curve A in FIG. 2 is illustrated. It is therefore very difficult to be in the middle of the emission curve set the time for stopping the emission of the xenon tube, so that an accurate control the amount of emissions is difficult to cope with.

Fig. 3 shows a first embodiment for a circuit of the flashlight device according to the invention. 11 is a battery with low voltage, to which a known voltage-increasing DC voltage converter 12 can be connected _{via a main switch S 0. The lightning capacitor C 0 is} connected to the output of the DC voltage converter 12 which supplies the increased voltage. The circuit has xenon tubes 13 and 14 as flash tubes, each with an anode 13/4 or 14/4, a cathode 13K or 14K, an ignition electrode 13Γ or 14Γ and an auxiliary anode 14S of the xenon tube 14. R 1 and R2 are resistors connected in series with a capacitor Cl. The capacitor C1 is connected to the auxiliary anode 145 of the xenon tube 14. The ignition electrodes 137 and 147 ″ of the xenon tubes 13 and 14 are connected to a secondary winding of an ignition transformer T , while an auxiliary capacitor CT for ignition and an ignition contact .S'7 are connected to the primary winding of the ignition transformer. The auxiliary capacitor (T is connected via a resistor Λ3 charged.

The circuit described with reference to FIG. 3 works as follows:

When the main switch .V _{0 is} closed, the DC / DC converter 12 generates an increased voltage from the low voltage of the battery 11, to which the lightning capacitor C _{0 is} charged.

ίο At the same time, the capacitor Cl is charged via the resistors Rl and R2. Since the capacitance of the lightning capacitor C _{0 is} greater than the capacitance of the capacitors CT and Cl, the latter are charged much faster. When the capacitor C1 is charged, the output voltage of the DC converter 12 is applied to the auxiliary anode 14V of the xenon tube 14, so that the sealed gas between the anode 14v4 and the cathode 14 / C of the xenon tube is ionized and consequently has an extremely low impedance. After the BJitzkondensatori'o has been charged and the ignition contact ST has been closed synchronously with the shutter of a camera, a short-circuit current flows from the capacitor (T through the primary winding of the ignition transformer '/', in whose secondary winding an ignition voltage is induced. This voltage is applied to the ignition electrodes 137 and 14Γ of the xenon tubes 13 and 14, si) that these are ignited and excited to emit light. Since the xenon tube 14 is already in the emission standby state, an emission current of the xenon tube 13 through the xenon tube 14 can be called so that the xenon tube 13 does not emit. Since the ignition voltage is applied at the same time to the xenon tube 14, this is also ignited and emits light. In fact, the xenon tubes 13 and 14 emit almost simultaneously. The maximum emission current that flows through both xenon tubes at the time of emission is reduced by half compared to the usual, because the total impedance of the xenon tubes is doubled compared to a single flash tube. In Fig. 2, curve b characterizes the time course of the emission current in the xenon tubes 13 and 14. As a result of the lower emission current through the xenon tubes 13 and 14, the flash capacitor C ₀ is also discharged with a lower current, so that the emission duration of the xenon tubes 13 and 14 is lengthened, as is illustrated by curve B in FIG. By reducing the emission current, the emission efficiency is also improved, ie the proportion of electrical energy converted into radiation by the xenon tubes increases compared to conventional circuits.

F i g. 4 shows a modified embodiment of the flash light device according to the invention, which differs from FIG. 3 in that xenon tubes 23 and 24, which correspond to tubes 13 and 14 of FIG. 3, a further xenon tube 25 is connected in series. In Fig. 4 are the rest of the circuit of F i g. 3 corresponding circuit elements are denoted by the same reference numbers. In the circuit of FIG. 4, an additional charging circuit is provided which comprises the capacitor C2 and the resistor R4 and is connected to the increased voltage of the DC voltage converter. When the low capacitance capacitor C2 is fully charged. lies the increased

Voltage of the DC converter between the anode and the cathode of the xenon tube 23 is applied, so that this tube is brought into a state suitable for ignition. Furthermore, a charging circuit, which comprises the resistor RS and the capacitor C'3, is used to put the xenon tube 25 back into a state in which ignition can take place, as is the case with respect to the xenon tube 24 by means of the capacitor C1 and the Resistance Rl happens. The capacitors C1 and C3 have small capacities.

The above with reference to FIG. 4 works as follows:

When the ignition contact ST is closed after the flash capacitor C _{0 has been} charged and the xenon tubes 23, 24 and 25 are in a state ready for light emission, each xenon tube is ignited by applying the ignition voltage to all ignition electrodes. If the xenon tubes 23, 24 and 25 have essentially the same properties and the total or sum impedance of the xenon tube for the flash capacitor C _{0 is} three times the value of a conventional single flash tube, the time during which the light emission is maintained is increased becomes, as was the case with the embodiment of FIG.

Figs. 5 to 7 illustrate the structure of flash or discharge tubes used in the aforementioned Flash devices can be used. In Figs. 5 and 6, an arrangement is shown, in which the xenon tubes 13 or 23 and 14 or 24 are integrally formed. In the F i g. 5 and 6 111 and 211 represent the base body and base housing, while 112 and 212 are ignition electrodes. the Assemblies also include xenon-filled vacuum parts sealed at 113, 114 and 213 and 214, respectively, and are located within base housings 111 and 211, respectively. Within the respective vacuum parts are an anode 113i4,114 / 4 or 213/1, 214/4, a cathode 113AT, 114K or 213K, 214A 'and (if necessary) an auxiliary anode 114S or 214S. In Fig. 5 are the Flash tubes integrated in series, while the two flash tubes in Fig. 6 integrated in parallel are arranged.

F i g. 7 shows an embodiment in which the xenon tubes 313, 314 and 315 are integrated are mounted in series on a base body or a base housing 311 and a common one Have ignition electrode 312. This embodiment is for example for the circuit according to FIG. 4th suitable.

F i g. 8 shows another exemplary embodiment of FIG Invention. In this FIG. 401 represents the voltage-increasing circuit part known per se approximately in Form of a DC / DC converter. 402 is the lightning capacitor that connects to the output of the voltage-increasing Circuit part 401 is connected. 403 and 404 are resistors to limit the Charging current of a commutation capacitor 405. 406 is a thyristor which is connected to the commutation capacitor 405. 407 denotes the The gate connection of the thyristor 406.408 is a xenon tube as a flash tube, which has an anode 40 & 4, a cathode 408K and an ignition electrode 408Γ. Another xenon tube is labeled 409, she has an anode 409.4 connected to the cathode 408A 'of the xenon tube 408, and also one Cathode 409K, an ignition electrode 409Γ and an auxiliary anode 409Λ. With the ignition electrodes 4087 and 4097 is a connection 410 for applying an ignition

voltage connected. A thyristor is used to interrupt the emission current. The thyristor has a gate terminal 412. A capacitor 413 and a resistor 414 and a capacitor 416 and a resistor 415 each constitute one

jo Ladckrcis. Capacitors 413 and 416 have a small capacitance, so that it depends on the output voltage of the voltage-increasing voltage component 401 can be charged very quickly; the charge circles serve to the xenon tubes 408 and

»To keep 5 409 in an ignition-enabling condition. When the xenon tubes 408 and 409 through Applying the ignition voltage to the ignition electrodes are made to emit, the impedance of the xenon tubes connected in series approximately the double

ao th value of that which would result if the xenon tubes 408 and 409 were switched on individually. Therefore, the emission current flowing in the thyristor 411 becomes compared to that in the thyristor 9 of Fig. 1 flowing emission current to half

* 5 reduced, so that a thyristor is relatively smaller Current rating can be used.

When in the aforementioned circuit structure respective capacitors 402, 405, 413 and 416 are charged and the ignition voltage is

A control circuit (not shown) is applied synchronously with the opening process of the shutter (e.g. a camera) to the connection 410, then the xenon tubes 408 and 409 emit light. The curve b in FIG. 2 gives the approximate course of the

Emission current again at this time, and it can be seen that the size of the peak current decreases is while the time of discharge of the flash condenser 402 through the xenon tubes 408 and 409 is extended is. In accordance with the above

In the exemplary embodiments described, this has an emission profile corresponding to the curve B ir F i g. 2 result in which the issue is maintained for a longer period of time. At the same time, the emission current of the xenon tubes 408 and 409 is so low that

the emission efficiency, d. Si. the transformation the electrical energy in radiation energy medium: the xenon tubes increases, so that the total emis sion increases.

If then by means of a tax not shown

circuit a signal to stop the emission to the Gate connection is applied and the thyristor 406 is made to conduct ", the positive charge of the capacitor Sators 405 applied to the thyristor 411 and this ii put the blocking state.

The fact that in the exemplary embodiment described, the flash tubes connected in series ai the lightning capacitor as an emission current source lie conditions, the emission current is reduced and di Emission effect as well as the life of the lightning

tubes enlarged. Besides, the time will come true that the issue is maintained is extended so it is easier to set the time to stop the emis to determine the sion process. In addition, switching elements such as thyristors with small

Ampacity can be used, so that and a low-capacity control circuit, as at for example a commutation circuit can be used. Although in the above-described execution

Example thyristors can of course be used to switch the emission current in their place also similar or different elements in the form of switching half-liter elements for example, power transistors are used.

According to the invention, the flash tubes are connected in series to the emission current source in order to discharge and emission with a relatively small current

and to achieve an increase in the time select the emission is sustained. Through this Synchronizing the emission easier than conventional flash units that only have one; have clearly short emission times. Ai the flash tubes are designed so that they m small electricity can be operated so Ben an increase in the amount of emissions ai increase in the service life is achieved.

For this purpose 2 sheets of drawings

Claims (3)

23 Π Patent claims: I flash unit with a flash capacitor and at least two gas-filled flash tubes connected in series, connected to the flash capacitor, whose ignition electrodes are sounded together, characterized in that that at least one of the two or more flash tubes (13, 14; 23, 24, 25; 113, 114; 213, 214; 313, 313, 314, 315; 408, 409) connected in series to increase the total flash tube impedance are, on their anode side has an auxiliary electrode (14S, 114S, 214S, 409S), which is used to generate a pre-ionization of the in this flash tube «The enclosed gas has a certain voltage potential. 2. Flash device according to claim I, characterized in that a relatively small circuit breaker element (411) is connected in series with the flash tubes, and that a discharge circuit by locking this element is opened to stop the light emission. 3. Flash device according to one of claims 1 or 2, characterized in that the flash tubes (113. 114; 213,214; 313, 314 and 315) to one single tube are combined.