DE3033191A1 - FLASH LIGHTING DEVICE - Google Patents

Description

description

The invention relates to a flash lighting device and relates in particular to a power supply for a flashlight lamp that supplies the lamp with precisely the amount of energy supplies that is necessary to achieve a desired exposure value.

When an object is either photographic or electrophotographic via a flash exposure of a photosensitive Material is reproduced or copied, the density of the object (dark and bright lights) must be in some way Manner can be determined so that a compensation for the exposed material can be made to thereby the Maintain uniformity of playback. Exposure is known from a large number of publications to control automatically. When taking pictures, an automatic Exposure control for an electronic flashlight device, an exposure meter and an electronic circuit included, which perceives the instantaneous amount of light, which from the · subject to be photographed on the light-sensitive Element of the light meter is reflected. The light meter contains a circuit that controls that of the light receiving element derived signal integrated. When the integrated signals reach a certain level that the corresponds to the required film exposure, the flash is extinguished.

The power for the flashlight is typically provided by a capacitor or a series of Capacitors charged to a desired comparison voltage will or will, and that the capacitor or capacitors then over the lamp and the associated Discharge circuit that generate the flashlight illumination is or are discharged. The lamp is typically through

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Delete switched off when gin reaches the specified value is. This can be done via a commutation circuit that A series switch (SCR) is used which, when opened, causes the lamp to go out Rectifier bridge, the SCR can also be connected in parallel to the lamp, so that when it is closed shuts off the power to the lamp. When using a commutation circuit, a considerable amount of energy The amount of time it takes to open the SCR switch. The switch must also have a short switch-off time, which is what the Device cost increases. In a rectifier bridge, the unused (erased) energy generally has the form of magnetic losses or ohmic losses.

It is already an energy supply with variable output energy has been proposed for successive discharge of the capacitors across the flashlamp ensures until a locking signal is generated by a circuit, which continuously monitors the current exposure value and compares it with a specified comparison value Depending on the exposure requirements of the device, a relatively large number of capacitors with kle ηem charge increase may be required in order to obtain the required degree of accuracy.

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The invention relates to a flashlight illumination device which supplies a flashlight lamp with precisely the amount of energy that is required for each exposure situation. The device does not require a quenching circuit, has a high degree of energy efficiency and requires a relatively small number of charging capacitors. The device according to the invention has a capacitor device which discharges the stored electrical energy in units via a flashlight lamp _/ and a device which calculates the exact amount of energy required for correct exposure of the object to be reproduced, this device e

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Generates a signal that only discharges those capacitors that are necessary for correct exposure are.

A particularly preferred idea of the invention consists in an energy supply, a flashlight lamp with energy supplied and has a number of capacitors that. are connected in parallel and their outputs with the flashlight are connected. The capacitors v / ground responsively discharge to a circuit that provides the required exposure value either predicts or calculates in real time at the object level.

In the following, preferred embodiments of the invention are described in more detail with reference to the accompanying drawings:

FIG. 1 shows in a block diagram an exemplary embodiment of the device according to the invention in the area the flash lighting of a copier.

Figure 2 shows schematically a first embodiment of a circuit according to the invention.

Figure 3 shows schematically a second embodiment of a circuit according to the invention.

FIG. 4 shows an exemplary embodiment in a block diagram the device according to the invention in the area. a flashlight fuser.

The following is an embodiment of an inventive Power supply with variable output energy described that a flash lighting device for Exposing originals in a full-frame copier, i.e. a copier with full-size reproduction with energy provided. It goes without saying, however, that the design according to the invention can also be applied to other types of devices is that a flashlight illumination of an object with different

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subsequent exposure of a light or heat sensitive Use materials. These include other types of copier systems, reprographic microfilm and microfiche devices and to understand cameras that need automatic and continuous exposure control responsive to changes in the reflectivity of the objects to be photographed appeals to. As will be described later in detail, the training according to the invention can also do this can be used to melt developed images on a photoconductive surface by a flash.

As shown in Figure 1, a plate 10 is provided, which carries a template 12. A flash lamp 13 which is energized in the manner described below can provide the lighting of the original. The reflected light from the original passes through a lens 15 and exposes a photoconductive image plane 16 which creates a latent image pattern which can then be developed. The energy supply for the lamp 13 is supplied by the energy supply 18 with variable output energy.

In a first embodiment, an auxiliary pre-flash lamp is used 17 with low energy after applying the template 12 to the plate but a few milliseconds before derr Illumination of the main lamp 13 brought to light. The irradiance of this pre-flash light is determined by a Photo sensor 19 measured and converted by a processor 20 from the analog value to a digital value. The processor 20 then predicts the exposure value required for the original 12 and provides a signal of the power supply 18, whereby it is programmed so that it supplies only this amount of energy to the lamp 13.

When a copy command is given, a trigger pulse energizes the lamp 13 so that it lights up. That of lamp 13 gel: The required energy depends on the calculated value given by d:

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Pre-flash light larape 17 and the processor 20 is determined. The image of the original 12 passes through the lens 15, so that it selectively discharges parts of the photoconductive image plane 16 and forms a latent image of the original thereon.

In Figure 2 are the functional components of the circuits 18 and 20 shown schematically. The power supply 18 with variable output power comprises a number of capacitors C1 to CN, which are connected in parallel. The capacities are chosen so that energy is delivered in powers of XN where N is usually 2 for a system operating at maximum efficiency. For example, if X = 1 joule, N = 2 and η = 0,1,2,3, ... η then they are Energy values for capacitors C1 to C7 = 1,2,4,8,16,32 and 64 joules with a resolution of within one joule. Of course, other values for X, N and η can also be used can be selected depending on the system requirements.

The capacitors are completely conventional in the beginning DC power supply source 22 charged. they are possibly switched via an inductance 24 over the electrodes of a hsrköirjrJLichen xenon flash lamp 13, if the associated switches S1 to SN, which are designed as normally open contacts, are closed.

Circuit 20 includes an integrator 28 and a conventional one Analog / digital converter 30, the output of which is connected to the digital processor 32. The processor 32 generates a series of output signals a, b, ... n, which do not have one The circuit shown can be applied to switches S1 to SN in order to operate these switches selectively, i.e. to close them.

During operation, the photosensor 19 generates an output signal I (t), its amplitude directly related to the intensity of the incident Light from the pre-flash lamp 17 on the light

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receiver 16, ie with the original exposure in relation
stands. This analog signal is generated by the integrator 28
integrated and converted into a digital signal by the analog-digital converter 30. The digital signal is compared with predetermined values that are stored in the processor. When the correct exposure value is reached,
the processor 32 correlates these values with one or more capacitors that will provide the energy required to achieve these values. For example, if the required. Exposure value is 75 joules, the processor 32 will generate signals a, b, d and g which the switches S1, S '. Close S4, S7. In a real-time sequence, the receipt of a trip voltage across the winding 36 of the lamp 13 ionizes the gas in the lamp, thereby reducing its resistance. The switches S1, S2, S4 and S7 are currently selected and closed so that the energy stored in the capacitors C1, C2, C4 and C7 is discharged through the lamp and thus a flash of light is generated with exactly the energy required for exposure the respective template is required. It should be noted that the lamp efficiency can change with regard to the respective energy level. The processor can be programmed to a factor for this change.

The second option for determining the required energies is provided by the circuit shown in FIG. In this embodiment, the pre-flash lamp 17 and is missing
the real-time perception is carried out by the processor 32 '. The power supply 1-8 with variable output power in turn contains a number of capacitors C1 to CN, which are connected in the manner described above to the lamp 13, except that the switch S1 is replaced by a diode D1.
In this embodiment of the invention, the capacitances are arranged in a different way. The capacitor C1 is initially charged with an energy approximately equal to or less than the smallest expected energy required for the

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Exposure of the original is necessary, for example equal to or less than 70 joules. The capacitors C2 to CN then have the previously defined logical progression, namely C2 = 1 joule, C3 = 2 joule, C4 = 4 joule etc.

During operation, the lamp 13 is triggered and is the capacitor C1 automatically through the diode D1 through the Processor 32 'unloaded. The photodetector 19 generates an analog signal I (t) which integrates by the integrator 40 is, 'by the analog-to-digital converter 32 into a digital signal is converted and sent to the processor 32 '. Of the Processor 32 'compares this signal with a group of exposure comparison values stored in a memory unit is. These values are correlated with the time intervals that have passed since the start of the flash. That has as a result, the processor 32 'receives the incoming integrated signals within a few microseconds of the start of the flash will relate to a given set of exposure values the total exposure required for the original will predict and select those additional capacitors to actuate that will provide the energy beyond the original amount of energy is required. For example, if the processor determines that an additional amount of 10 joules of energy is required will be, actuation signals are supplied to switches S3 and S5 to close and capacitors C3 and C5 can discharge via the lamp 13.

Although the above embodiments in one application a flash exposure device have been described the inventive training can also be applied to the flash melting of an image pattern. As shown in Figure 4 is, a melting station 50 is provided with a flashlight 52 which is located in the cavity indicated by a curved reflector 54 is formed. A copy material support surface 56, which on part of its surface a

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Carries toner image 58 passes under this flash light arrangement in the indicated direction. The reflector 54 is like this shaped so that each flash of light from lamp 52 will irradiate the entire toner image 58. A pre-flash lamp 60 and a photodetector 62 operate in the same manner as the lamp 17 and photodetector 19 in that shown in FIG Exposure embodiment. A power supply 70 and processor 80 operate in the same way as it has been described using the exemplary embodiment shown in FIG. The values of the capacitors in the power supply 70 are higher, as there is a higher energy range from, for example, 500 to 800 joules for flash melting is required. A typical sequence of capacities is therefore C1 = 25, C2 = 50, C3 = 100, C4 = 200, C5 = 400. With a previously determined energy value of 525 joules, the capacitors C1, C3 and C5 are in the previously described Way operated.

The melting can also take place using real-time perception, as has been described with reference to FIG.

The digital processor described above can be used on the specific mentioned purposes or designed for a system processor that simultaneously performs other tasks can perceive. The design of these processors is well known. The embodiment with previous determination the amount of energy can also be made using "other facilities." be designed to provide a pre-flash light illumination. For example, one that works continuously Lamp can be used with a shutter, or the main flash lamp can be designed so that it can be used as a Pre-flash lamp work with a lower energy level

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Claims (12)

PATENT CLAIMS Flash lighting device characterized by a flash lamp (13,52) for Illuminate an object in an object plane, through a Energy supply (18,70) with variable output energy, which is connected to the flash lamp (13,52) and a plurality of capacitors (C1-CN), each of which stores a discrete amount of electrical energy, and has a plurality of switches (S1-SN) connected between the respectively associated capacitors (C1-CN) and the lamp (13,52) are connected, and by a device (20,80), which calculates the exact amount of energy required to achieve the desired exposure of the object in an exposure plane and which only closes those switches (S1-SN) that belong to those capacitors (C1-CN) whose combined stored energy is equal to the calculated amount of energy, causing the lamp (13.52) to use exactly that amount of energy is supplied, which is charged for the required exposure 1 30014/1091 TELEPHONE (OBS) 22 28 62 TELEX ΟΒ-ΟΘ3ΒΟ TELEGRAMS MONAPTH is required. 2. Flash lighting device according to claim 1, characterized in that the capacitors (C1-CN) can supply energies in unit ^{quantities which increase in accordance with the relationship XN n} , where X is a value in joules, N is the base and ή denotes the power, on which the base is raised. 3. Flash lighting device according to claim 1, characterized in that one of the capacitors (C1) supplies a first unit amount of energy which is equal to a predetermined value, and that the other capacitors (C2-CN) can supply energy in values corresponding to the relationship XN ⁿ , where X is a value in joules, N is the base and η denotes the power to which the base is raised. 4. bit light illumination device according to claim 2 or 3 characterized in that N equals 2. 5. Flash lighting device gekennzeich net by a first flash lamp (13,52) for lighting of an object in an object plane, through an energy supply (18, 70) with variable output energy, which with the flashlight lamp (13,52) is connected and a plurality of capacitors (C1-CN), each of which is a discrete electrical Stores the amount of energy, and furthermore has a plurality of switches (S1-SN), which are connected between the respective associated Capacitors (C1-CN) and the lamp (13,52) are connected by a second pre-measuring lamp (17,60) which flash and can illuminate the object in time before the illumination by the first lamp (13, 52), by a photosensor (19,62), which reflected this from the object over a time interval Picks up light that follows the pre-measuring light flash, the potentiometer (19,62) generating an analog signal, 1 3001 A / 109 1 COPY ORIGINAL INSPECTS © its amplitude directly corresponds to the intensity of the recorded Light is related by an integration circuit (28,40) connected to the photosensor (19,62) and a time-integrated output signal of the analog signal can generate, by an analog-to-digital converter (30,42), which 'is connected to the integration circuit (28,40) and the integrated analog signal can be converted into a digital signal by a digital processor (32,32 ') operating between the changeable energy supply (18.70) and the converter (30,42), the processor (32,32 ') having an input, direction that compares the digital integrated signal with previously stored signals, each of which is a specific one Corresponds to energy value represented by a group of capacitors (C1-CN), and those Selects the value corresponding to the integrated digital signal, a device for the selective actuation of switches. (S1-SN), belonging to the selected capacitor group (G1-CN), and having a device which the first flash lamp (13, 52) brings into the conductive state, whereby the preselected capacitor group (C1-CN) via the actuated switch (S1-SN) is discharged through the first lamp (13,52) and thus the exact amount of energy is supplied, which is necessary for exposure of the object in the required thickness is required. 6. Flash lighting device according to claim 5, characterized in that the capacitors (C1-CN) can supply energy in unit amounts which increase in accordance with the relationship XN ⁿ , where X is a value in joules, N is the base and η denotes the power, in which the base is raised. 7. flash lighting device according to claim 6, characterized in that X = 1 ', that N = 2 and that η = 0,1,2,3, ... η. 1 3001 A / 1091 COPY 8. Flash lighting device according to claim 5, characterized in that the processor (32,32 ') furthermore has a device which changes the lamp efficiency when the lamp is actually present Energy compensated. 9. Flash lighting device characterized by a flash lamp (13) for illuminating an object in an object plane, by a power supply (18) with variable output energy, which is connected to the flash lamp (13) and a plurality of capacitors (C1-CN), of which each stores a discrete unit amount of electrical energy, and furthermore has a large number of switches (S2-SN) which are connected between the respective associated capacitors (C2-CN) and the lamp (13), a first capacitor (C1) is switched so that it delivers an initial energy discharge in the lamp (13) at the point of Zei triggering, by a device that brings the lamp (13) into the conductive state and causes the lamp (13) to emit a flash of light by a Photosensor (19), which picks up the light reflected by the object after the triggering of the flash of light and generates an analog signal, the amplitude of which is directly related to the Inte The intensity of the recorded light is related, through an integration circuit (40) which is connected to the photosensor (19) and can generate a time-integrated output signal of the analog signal, through an analog-digital converter (42) connected to the integration circuit (40) is connected and can convert the integrated analog signals into digital signals and by a digital processor (32 ¹ ) dei between the variable power supply (18) and the converter (42) is connected, the processor (32 ') having a device which compares the digital integrated signals with previously stored signals, reproduces the exposure values at different time intervals after the light flash] and the incoming integrated signals with a certain] 1 3001 A / 1091 Brings exposure sequence in relation, and further comprises a device that selectively those switches (S2-SN) operated, which belong to those capacitors (C2-CN) whose energy when it is added to the energy supplied by the first capacitor / switch · (C1, D1) provides the exact amount of energy for the lamp that is required for the identified exposure situation is. 10. Flash lighting device according to claim 9, characterized in that the first capacitor (C1) stores a certain amount of energy that is approximately equal to the smallest expected amount of energy that is required for the exposure of the object. 11. Flash lighting device according to claim 9 or 10, characterized in that the other capacitors (C2-CN) can deliver energies in values which increase in accordance with the relationship XN ⁿ , where X is a value in Joule, N is the base and η the Is the potency to which the base is raised. ■ 12. Flash melting device for a copier characterized by a first flash lamp (52) for irradiating toner images on a copier ialträgerf lache to melt the images on it, by a power supply (70) with changeable Output power connected to the flashlight lamp (52) and a plurality of capacitors, each of which stores a discrete unit amount of electrical energy, and has a similar number of switches interposed between the associated capacitors and the lamp (52) are connected, and by means (80) that the exact amount of energy calculated that is required to melt the toner image and that only closes those switches that are closed those capacitors belong to their combined energy 1300U / 1091 - ^β ~ is equal to the calculated amount of energy, causing the lamp is supplied with exactly the amount of energy that is necessary to bring about the required melting. 1300 U / 1091