KR890003061B1 - Flash tube employing multiple flashes - Google Patents

Abstract

A circuit is coupled to the lamp to trigger flashes of light of short duration. The circuit produces at least two successive flashes during a time interval of approximately 30-90 milliseconds. The lamp has a time interval of approxinmately 30-90 milliseconds. The lamp has a flash tube with an amode, a cathode and a trigger electrode. The circuit includes a timer for triggering the successive flashes. Two capacitors are successively discharged to trigger the successive flashes. A pair of silicon controlled rectifiers become conductive to discharge the capacitors on a successive basis.

Description

Flash lamp system and method

1 is an electrical circuit diagram of one embodiment in which the present invention is applied to a double flash tube.

2 is a timing diagram showing exemplary operation of the circuit of FIG.

The present invention relates generally to an alarm system for emergency vehicles and, in particular, to an improved alarm system using one or more flash tubes triggered to generate two or more light flashes in rapid succession.

In particular, and not limited to the particular use shown and described, the present invention relates to an alarm system having one or more flash tubes, wherein the flash is rapidly continuous for about 30-90 msec periods to greatly improve luminance and alarm light indication. Flashes. Since two or more light flashes are closely spaced, they appear to the observer as a light flash.

The purpose of the alarm system is to specify the alarm light that appears best for as many observers as possible within a given area. The flash tube generates a highly efficient alarm light, providing a short but high intensity flash. In general, strobe light is a gas encapsulation tube that supplies a short flash with a period of about 200 μsec. Known techniques designed to supply high intensity flashes have not been able to effectively and rapidly improve brightness implantation.

Short flashes of flash tubes have conventionally been generated continuously to enhance the indication of the alarm light. These systems did not improve the perceived brightness because the spacing between flashes did not affect the perceived brightness in any effective way. The interval between two flashes at about 150 msec, which is much longer than the critical interval developed by the present invention, is common in the prior art.

In 1902, the problem of short flash brightness was discussed in a series of papers by Broca and Sultzer, in which time periods of light stimulating the observer's eye influence the perceived brightness of the light. Was observed. This condition became known as the Broca-Suller effect and demonstrates that there is a critical flash cycle that appears much brighter for the observer than the optical flash is measured differently depending on the experimental instrument.

Subsequent studies can be found in the Broca-Suler publication. Pergamon Press, Vol. 1, Vision Research, published in 1964 4, in a paper by M.S.Catz described in P361-373, and by applying several curves in the Broca-Suller paper, the results of the Broca-Suller effect were dramatically demonstrated. A short flash period of 0.05 seconds for the 170 lux flash is 5-6 times brighter for the human eye than a stable 170 lux light. Thus, when two optical flashes are flashed within a short period of critical range, it is possible to produce high intensity light that appears more intense and brighter, and after that interval the light does not exhibit improved brightness.

It is an object of the present invention to improve latitude awareness using two or more optical flashes in rapid succession.

It is another object of the present invention to generate two or more strobe flashes in a Broca-sulzer cycle to improve the degree of brightness and alarm light indication.

Another object of the present invention is to drive a flash tube to supply two or more continuous flashes at frequencies higher than the flicker joint frequency.

Another object of the present invention is to improve the apparent brightness of the alarm system for observers and to generate better visible light.

This and other objects are achieved with the present invention, and the present invention provides an improved flash tube system utilizing the Broca-Suller effect in a way that allows the observer to better recognize the alarm light with the improved brightness of the flash. An application of the present invention is to account for the Broca-Suller effect by using two or more flashes in rapid succession generated by a flash tube having a 30-90 msec flash period. The two flashes produce five to six times the apparent brightness possible with stable light with similar illumination because the time interval between two or more pulses is within the critical range. Since the frequency of the flash is higher than the so-called flash joint frequency, the two flashes appear as a single flash. Therefore, as an application of the present invention, it is possible to obtain a better recognizable luminance using a standard flash tube than is possible with the prior art using a multi-pulse emitting flash or moving reflector.

It is a further object of the present invention, with the additional features contributing to the present invention and the advantages of the present invention, the above embodiment of the present invention shown with the drawings with the same reference numerals representing corresponding parts throughout the specification. The explanation makes clear.

In the following specification, embodiments of one or more circuits and methods for flash operation in which brightness is recognized by being 5-6 times improved are described. Although various similar circuits and devices may be used, the circuit shown in FIG. 1 is an embodiment of one technique for achieving the object of the present invention.

Using other circuits and systems within the scope of the present invention achieves improved results for the present invention, wherein two or more short flashes supplied by one flash tube are generated for a predetermined time interval appearing with enhanced brightness as a single flash.

According to the present invention, which consists of the circuit of FIG. 1, the flash tube of FIG. 1 is equipped to generate two or more flashes spaced at continuous intervals of 30-90 msec.

The alarm light system using the technique of the present invention appears to be about 5-6 times as bright as light of the same lumens with a stable output, the output depending on the period size within the range of about 30-90 msec. By spacing the flashes from the flash tubes of the present invention very closely, they appear like a single emitting flash having a period approximately equal to the spacing between flashes.

With regard to FIG. 1, the flash lamp 10 has a flash tube 12, a transformer 14, and a capacitor 16 mounted with a contact base and a body portion (not shown).

The flash tube 12 includes a conventional flash tube having a second electrode 22 and an over-metal trigger electrode 24, represented by a cathode for convenience of the first electrode 20, represented by an anode for convenience. Although there is no limitation, the flash tube 12 is equipped with a general electric model FT-106C.

Transformer 14 is generally a small transformer, although without limitation, transformer 14 includes a Siemens ZS-1062 transformer. Capacitor 16 is primarily a disk ceramic capacitor and, although without limitation, capacitor 16 includes a Sprague 5 GAS-S10 capacitor.

The electrical lead 30 couples the anode 20 to the lead 32 of the capacitor 16, while the lead 32 of the capacitor 16 is connected to one axis 36 of the transformer primary. The lead wire 40 connects the other side of the transformer primary coil 40 to the ground contact of the lamp 10 and one side of the transformer secondary coil 42, while the lead wire 44 is the trigger electrode 26. Is connected to the other side of the transformer secondary coil 48. The conductive wire 45 connects the coil element to the ground of the power supply PS ₁ .

The cathodes of the pair of silicon controlled rectifiers SCR ₁ and SCR ₂ are connected together by electrical conductors 46 and 48 extending from the conductor 30.

An anode (SCR ₁ and SCR ₂₎ are connected to the power supply (PS ₁₎ through a lead wire (50 and 52) in series with a diode (CR ₁ and CR ₂₎ the SCR ₁ and SCR _2. The flash capacitors C ₁ and C _{2 are} connected between the leads 50 and 52 and the leads 45 by the leads 54a, b and 56a, b, respectively. Gates 60 and 62 of SCR ₁ and SCR ₂ are connected to timing circuit 64 via transformer 66, respectively. Timing circuit 64 may include any suitable device, such as a National Semiconductor, timer of model LM ₅₅₅ .

In operation, power supply PS ₁ charges capacitors C ₁ and C _{2 at} desired energy levels through diodes CR ₁ and CR ₂ during time interval t ₁ . An end of time t ₁ occurs at terminal 1 of timing circuit 64 where the positive edge conducts SCR ₁ . When SCR ₁ becomes conductive, a positive pulse appears on capacitor 16 to emit flash tube 12 and to discharge capacitor C ₁ . After the time t ₂ (broca-sulfur spacing), a negative edge appears in the step 1 of the timing circuit 14 to conduct SCR ₂ . The flash tube 12 emits light again to discharge the capacitor C ₂ . The capacitors C ₁ and C ₂ discharge at about 2 msec, limiting the minimum of the time interval t ₂ .

For purposes of explanation, the timing graph shows an embodiment of the energy level and the time interval supplied by the circuit of FIG. It should be understood that other energy levels and time intervals t ₁ and t ₂ may be used, so that the flash tube 12 is continuously flashed within the same interval as the threshold range of about 30-90 msec in accordance with the present invention. Optimal brightness usually occurs in the middle of this range. In FIG. 2, the timer 64 generates an output of 5V during the interval t ₂ of 75 msec. Capacitors C ₁ and C ₂ are charged up to 450V through diodes CR ₁ and CR ₂ . The circuit applies a voltage of 450 V across capacitor 16 for one period and then generates two consecutive flashes of about 2 msec spaced at a time period of about 75 msec within the critical range. The flash occurs at frequencies above the flicker joint frequency, perceived as 5-6 times normal brightness with a period of 75 msec, and appears as a single light flash with improved alert light indication.

The flash lamp 12 operated in accordance with the present invention may be used with other similar flash lamps in any suitably designed alarm system. The invention disclosed herein also achieves the object of the present invention by flashing strobe light for longer than two consecutive flashes as long as the time between flashes is within an interval of 30-90 msec.

While the invention has been described with respect to the above embodiments, it may be varied in the art without departing from the scope of the invention and the elements may be replaced by the same. In addition, various modifications may be made to apply particular conditions or materials in accordance with the principles of the invention without departing from the essential scope of the invention.

Accordingly, as the best rods observed for carrying out the invention, the invention is not limited to the examples described above but includes all embodiments within the scope of the appended claims.

Claims (11)

A flash lamp system comprising: a flash lamp means, circuit means connected to a lamp means for triggering a flash for a single-cycle optical flash, and means for triggering the flash lamp means for at least two consecutive flashes for a time interval of about 30-90 msec. Flash lamp system having a circuit means for. A flash lamp system according to claim 1, wherein the flash lamp means has a flash tube with an anode, a cathode and a trigger electrode. A flash lamp system according to claim 1, wherein the circuit means incorporates a timer means for a continuous flash trigger. A flash lamp system according to claim 1, wherein the circuit means incorporates a pair of capacitors connected to the flash lamp, the capacitors being discharged continuously to trigger a continuous flash. 5. A flash lamp system according to claim 4, wherein the circuit means further incorporates a pair of silicon controlled rectifiers, each connected to a capacitor, the rectifier being continuously conducted to discharge the capacitor in the continuous base object. Flash lamp system. A flash lamp system according to claim 5, wherein the circuit means incorporates a timer means for controlling the conduction period of the rectifier. A flash lamp system, comprising: a flash lamp, the flash lamp having a flash tube for flash light, and means connected to flash lamps for successively emitting two or more flashes for a time interval of about 30-90 msec. A flash lamp according to claim 7, wherein the continuous flash is represented as a single flash. A flash lamp according to claim 7, comprising a series of two or more continuous flash supply circuit means. A method of improving the brightness of a flash tube, the method comprising: flashing a portion of the flash to flash with at least two continuous flashes during an interval of about 30-90 msec between the step of flashing light of a short period from the flash tube and the continuous flash; . A flash lamp method according to claim 10, comprising the step of generating a continuous flash with the same intensity of short periods.

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