RU2138084C1 - Process controlling vacuum luminescent indicators and device for its implementation - Google Patents

Abstract

FIELD: indication equipment. SUBSTANCE: invention refers to indication equipment using vacuum luminescent indicators with directly heated cathodes. Process controlling vacuum luminescent indicators includes supply of voltage to controlling electrodes ( grids and anodes coated with luminophor ), feed of filament voltage to cathodes by pulses from D C power supply source in time intervals of interruption of current to anodes, information display in time intervals between filament pulses. In this case both cathode leads have close or equal potentials. Device controlling vacuum luminescent indicators has commutators of voltages of controlling electrodes which controlling leads are connected to unit of controlling signals and feeding leads - to source of D C power supply voltage of positive and negative polarity which have common point. Cathodes of indicators are connected in series circuit. Device is inserted with filament key which controlling lead is connected to unit of controlling signals. First lead of filament key is connected to first cathode lead of first indicator and second lead of filament key is linked to positive D C power supply source, second lead of last indicator is connected to common point of power supply sources. EFFECT: increased comfort of information reading from vacuum luminescent indicators by way of decrease of nonuniformity of luminophor glow of anode over length of cathodes. 4 cl, 1 dwg

Description

 The invention relates to indicator technology and can be used when applying vacuum fluorescent indicators (VLI) with a direct-heating cathode.

 In the indicator technique, methods and devices for controlling vacuum fluorescent indicators are known, in which the cathode glow voltage is supplied from the secondary winding of the transformer (Gorfinkel B.I. et al. Low-voltage cathodoluminescent indicators. M: Radio and communication, 1983, p. 64). The midpoint of this winding is connected to the negative terminals of the DC power supply supplying the anodes and grids and the positive terminal of the DC power supply to supply a blocking voltage to the anodes and grids.

 However, according to the specified technical solution, it is impossible to achieve a high uniformity of the glow of the phosphor of the anodes in time and along the length of the cathode, especially in indicators installed in objects exposed to vibration, or in indicators having glow voltages comparable with the supply voltages of the anodes and grids.

 Known technical solutions for pulsed heating of incandescent bodies in vacuum (Boguslavsky RE, Severinovsky NS On the dynamic model of miniature incandescent lamps for optoelectronic devices. Semiconductor technology and microelectronics. 1981, issue 33, p. 79-86 )

 However, the indicated technical solution does not use the possible preservation of the emissivity of the filament body as an electron source in a vacuum luminescent indicator to maintain almost the same electric mode of the indicator electrodes during image formation.

 The closest analogue in technical essence to the proposed solution - the prototype is a way to control the VLI and a device for its implementation: a vacuum fluorescent display of stable brightness (US patent N 4859912, CL G 09 G 3/10, publ. 08.29.89). The brightness adjustment circuit for a vacuum fluorescent display having an anode, a grid and a filament electrode comprises a unit for supplying alternating current to the filament electrode, as a result of which the voltage of the cathode-anode and the brightness of the emitted light change in time and in the area of the display, a circuit for aperiodic supply of control pulses destroying the luminescence of the display, a pulse-width modulator for controlling the duty cycle of the control pulses and thereby regulating the brightness of the display and the coordination unit of the candle resolution circuit with the magnitude of the glow current for triggering control pulses or groups of control pulses in sections of the opposite phase of the glow current with a frequency high enough to obtain a uniform display brightness.

 The VLI control method according to US patent N 4859912 is that the cathode glow power from the secondary winding with the midpoint of the transformer is synchronized with the supply of anode and grid control signals. Moreover, in each elementary time period, from the sum of which the image on the indicator is formed, there is the same number of periods of alternating incandescent voltage.

 However, a significant drawback of this technical solution is that the flowing filament current causes voltage drops varying along the length of the cathode in different sections of the cathode relative to the midpoint of the secondary winding of the supply transformer, to which the anode and grid power sources are connected.

где E_g - напряжение источника питания сеток;
L - длина катода;
x - расстояния точек катода, отмеренные от места его крепления.For example, if the total current of the anodes and grids at each moment of time is much less than the glow current, then for rectangular glow pulses the amplitude U _and , measured from the midpoint, the potential difference between the cathode points and the grid U _{g, x} will be

where E _g is the voltage of the power source grids;
L is the length of the cathode;
x are the distances of the cathode points measured from the place of its attachment.

 It is obvious that the indicated variability in the voltage of the cathode – grid point and, similarly, the cathode – anode points leads to uneven luminescence of the luminoform of the anodes of the indicator, which increases as the values of the supply voltages of the grids and anodes approach the glow voltage.

 The invention consists in the following. The problem to which the invention is directed is to increase the comfort of reading information from vacuum fluorescent indicators by reducing the uneven glow of the phosphor of the anodes along the length of the cathodes.

τ_от< 2 мс,
где U_эф - эффективное значение напряжения накала, а отображение информации осуществляют во время между накальными импульсами τ_от , при этом оба катодных вывоза имеют близкие или равные потенциалы.The specified technical result in the implementation of the invention is achieved by the fact that in the known method of controlling vacuum fluorescent indicators, including applying voltage to the control electrodes: grids and phosphor coated anodes, the filament voltage is supplied to the cathode by pulses from a DC power source at the time intervals of the anode current termination, the amplitude glow pulses U _n.i. , their duration τ _and and the time between filament pulses τ _of are related by the relations

τ _from <2 ms,
where U _eff is the effective value of the filament voltage, and the information is displayed during the time between filament pulses τ _from , and both cathode outflows have close or equal potentials.

 The specified technical result in the implementation of the invention is achieved by the fact that in the known control device for vacuum fluorescent indicators, containing voltage commutators of the control electrodes, the control terminals of the switches are connected to the control signal unit, and the power leads are connected to positive and negative polarity direct current sources with a common point , the cathodes of the indicators are connected in a serial circuit, while a filament switch is inserted into the device, the control output of which a unit connected to the control signal, the first terminal of the glow switch connected to the first cathode terminal of the first indicator and the second terminal of the glow key - a power source DC positive polarity, a second terminal of the last indicator connected to the common power supply point.

 In addition, an additional key has been introduced into the control device for the vacuum fluorescent indicators, the control output of which is connected to the control signal unit, the first output of the additional key is connected to the first cathode output of the first indicator, and the second output of the additional key to the common point of the DC power supplies.

 Diodes can be introduced into the control device for vacuum fluorescent indicators, the cathodes of which are connected to the first cathode terminal of the first indicator, and the anodes of which are connected to the first cathode terminals of the second and subsequent indicators, respectively.

Близость или равенство потенциалов выводов катодов индикатора определяется величинами суммарного анодного и сеточного токов и сопротивлением катода при рабочей температуре. Так, например, при сумме токов анодов и сеток, равном 10- мА и сопротивлении катода 30 Ом и соединении с отрицательным зажимом анодного и сеточного источников питания напряжением 27 В только одного вывода катода максимальная разность потенциалов между катодными выводами будет не более 0,3 В, что практически можно принять за эквипотенциальность всех точек катода.The direct-heating cathodes used in vacuum fluorescent indicators heat up when the glow voltage is applied faster than 0.6 - 0.8 ms than cool when the glow voltage turns off 20 - 40 ms. The specific value of the indicated times is determined by the length, mass, emissivity and design of the fastening of the cathodes of various types of indicators. Thus, when the time interval between the filament pulses is less than 2 ms, the cathode temperature will be almost constant. The cathode temperature of the indicators is determined by the average power dissipation. Therefore, the amplitude of the glow pulses should be equal to the product of the effective voltage by the square root of the duty cycle of the pulses, which is equivalent to the expression:

The proximity or equality of the potentials of the terminals of the indicator cathodes is determined by the total anode and grid currents and the cathode resistance at operating temperature. So, for example, with the sum of the currents of the anodes and grids equal to 10 mA and the cathode resistance of 30 Ohms and the negative terminal of the anode and grid power sources of 27 V connected to only one cathode terminal, the maximum potential difference between the cathode terminals will be no more than 0.3 V , which can practically be taken as the equipotentiality of all points of the cathode.

 The drawing shows a control device for vacuum fluorescent indicators.

 The device comprises a first vacuum luminescent indicator 1, a second vacuum luminescent indicator 2, etc. the last vacuum luminescent indicator 3, having anodes 4, grids 5 and straight cathodes 6. Anodes 4 and grids 5 are connected to the switches 7. The first supply leads 8 of the switches 7 are connected to a positive current supply of positive polarity 9, the second supply leads 10 of the switches 7 are connected to a DC power source of negative polarity 11. The control terminals 12 of the switches 7 are connected to the control signal block 13. The device contains a glow switch 14, the control terminal 15 of which is connected to the block control signals 13. The first terminal 16 of the filament switch 14 is connected to the first cathode terminal 17 of the first indicator 1, the second terminal 18 of the filament switch 14 is connected to a positive polarity DC power supply 9. The second cathode terminal 19 of the first indicator 1 is connected to the first cathode terminal 20 of the second indicator 2, etc. sequentially to the first cathode terminal 21 of the last indicator 3. The second cathode terminal 22 of the last indicator 3 is connected to a common point 23 of a positive polarity DC power supply 9 and a negative polarity direct current power supply 11. The device also contains a key 24, the control terminal 25 of which is connected to block control signals. The first terminal 26 of the key 24 is connected to the first cathode terminal 17 of the first indicator 1 and the cathodes 27 of the diodes 28, the anodes 29 of which are connected respectively to the first cathode terminal 20 of the second indicator 2, etc., with the first cathode terminal 21 of the last indicator 3. Second output 30, key 24 is connected to a common point 23.

 The device operates as follows.

First, the cathodes of 6 indicators 1, 2, 3 are heated for a time τ _p . For this, the control signal unit 13 supplies such voltages to the voltage switches 7, the incandescent switch 14 and the key 24, which connect the grids 5 (anodes 4) to the negative power source 11, close the first cathode terminal 17 of the first indicator 1 with a positive polarity direct current power supply 9, and the key 24 is opened.

или

где U_эф1, U_эф2, ..., U_эф - эффективные значения напряжений накала катодов 6 индикаторов 1, 2, 3, в последовательной цепочке.Further, at the end of the heating time τ _p , the mapping time τ _from comes. For this, the control signal unit 13 supplies such voltages to the switches 7 that correspond to the information currently being displayed, closing the anodes 4 and the grid 5 with a direct current power supply of positive polarity 9 or a direct current power supply of negative polarity 11. In this case, the glow switch 14 and closes the key 24. The currents of the anodes 4 and the grids 5 of the indicators 1, 2, 3 in this case flow in parallel through the first cathode terminal 17, the key 24 to a common point 23, through the cathode terminals 19, 20, 21, diodes 28 and the key 24 on general then piece 23, through the second cathode output 22 of the last indicator 3 to a common point 23. At the end of the display time τ _from , the cathode heating process of 6 indicators 1, 2, 3, etc. is repeated. The heating time between the pulses of the cathodes 6 should be less than 2 ms, and the duty cycle of the pulses Q _n and their amplitude U _etc. are related by the ratio:

or

where U _eff1 , U _eff2 , ..., U _eff are the effective values of the cathode glow voltages of 6 indicators 1, 2, 3, in a sequential chain.

 Naturally, indicators 1, 2, 3 with the same glow current are included in a sequential chain of cathodes 6.

 If the indicators have different glow currents, then it is necessary to use the combinations of parallel connections of the cathodes 6, using, if necessary, additional external loads, to achieve the same current for each successive chain link.

 The device for controlling two indicators of the ILV2-16 / 5X7 type, having an effective filament voltage of 6B and anode voltage of 35 V, made according to the described scheme, made it possible to obtain an image uniform in time and length of the cathodes with a duty cycle of filament pulses of 8 over the entire frame frequency range from 40 Hz to 10 kHz.

 Thus, the separation in time of the processes of heating the indicator cathodes and displaying information with sufficient equalization of the cathode potentials reduces the unevenness of the luminosity of the phosphors of the anodes of vacuum fluorescent indicators with direct-heating cathodes both in time and along the length of the cathode.

 Using the proposed technical solutions of the method for controlling vacuum fluorescent indicators and a device for its implementation can improve the comfort of reading information by reducing the irregularity of the phosphor luminescence of the anodes both along the length of the cathode and in time, as well as to use a number of specific implementations as a source of incandescent voltage of a constant current power source current designed to power the anodes, which reduces the overall dimensions of the indicator devices.

Claims (4)

1. A method of controlling vacuum fluorescent indicators, including applying voltage to the control electrodes, characterized in that the filament voltage is supplied to the cathode by pulses from a DC power source at the time intervals of the anode current termination, the amplitude of the filament pulses is U _n. , their duration τ _and and the time between filament pulses τ _of are related by the relations

τ _from <2 ms,
where U _eff is the effective value of the filament voltage,
and the display of information is carried out during the time between the filament pulses τ _from , while both cathodic outputs have close or equal potentials.  2. A control device for vacuum fluorescent indicators, comprising switches connected to the anodes and grids of indicators, the first supply terminals of which are connected to a positive polarity direct current power supply, the second supply terminals of the switches are connected to a negative polarity direct current power supply, and the control terminals of the switches are connected to a unit control signals, DC power supplies of positive and negative polarity have a common point, distinguish in that the cathodes of the indicators are connected in a serial circuit, while the incandescent key is inserted into the device, the control output of which is connected to the control signal unit, the first output of the incandescent key is connected to the first cathode output of the first indicator, and the second output of the incandescent key to a constant power supply current of positive polarity, the second terminal of the last indicator is connected to a common point of DC power supplies of positive and negative polarity.  3. The device according to claim 2, characterized in that an additional key is inserted into it, the control output of which is connected to the control signal unit, the first output of the additional key is connected to the first cathode output of the first indicator, and the second output of the additional key to the common point of the power sources direct current.  4. The device according to claim 2 or 3, characterized in that diodes are introduced into it, the cathodes of which are connected to the first cathode terminal of the first indicator, and the anodes of which are connected to the first cathode terminals of the second and subsequent indicators, respectively.