SK500092011A3 - The electronic control system for light-emitting diodes LED - Google Patents

Abstract

In the present invention, there is disclosed a system for electronic control of light emitting diodes (LED) intended particularly for visual signaling in railway traffic, comprising at least one column (SLi1 through SLik) of light emitting diodes (LEDs) with additional circuits. The system alternating or direct current voltage input is connected to a measuring circuit (MOUI) of input voltage and current wherein said measuring circuit (MOUI) output is connected to the block of a boosting converter (ZM) comprising a pulse generator (GI) and a switch (SP). The outputs of the input voltage and current measuring circuit (MOUI) are connected respectively to a first and a second control blocks (CPUiA, CPUiB), which are connected with each another, are independent of each another and are individually connected to a first and a second blocks (BSiA, BSiB) of a safe passage of an exciting signal of the switch (SP). These blocks (BSiA, BSiB) of the safe passage of the switch (SP) exciting signal are connected in series between the pulse generator (GI) output and the switch (SP). Both a measuring circuit (MOUC) of said boosting converter (ZM) output voltage and at least one column (SLi1 through SLik) of light emitting diodes (LEDs) with additional circuits are connected to said boosting converter (ZM) block output . The outputs of the boosting converter (ZM) output voltage measuring circuit (MOUC) are individually connected to the first and second control blocks (CPUiA, CPUiB). Each column (SLi1 through SLik) of the light emitting diodes (LED) comprises series connected LEDs that are series connected with a LEDs current source (PZ) and a current measuring circuit (MOI) and further with a voltage measuring circuit (MOU) to a series combination of the current source (PZ) of both the LEDs and the current measuring circuit (MOI). The outputs of the current measuring circuit (MOI) and the outputs of the voltage measuring circuit (MOU) of the series combination of the LEDs current source (PZ) and the current measuring circuit (MOI) are individually connected to the first and second control blocks (CPUiA, CPUiB) for its control to the first control block (CPUiA) and/or the second control block (CPUiB), whereby the input of the LEDs current source is connected to the second control block (CPUiB) while the first control block (CPUiA) is connected to a coding circuit (KO).

Description

Electronic control system for light emitting LEDs

Technical field

The present invention relates to an electronic control system for light emitting LEDs, in particular for optical signaling in rail transport.

BACKGROUND OF THE INVENTION

At present, light bulbs and LED lamps are used for optical signaling in rail transport.

The advantage of the bulb is its filament parameters, which have a low impedance when cold, thus eliminating the influence of its function due to capacitive and induced voltages and currents in the cable paths in which the cables to which the lamps are connected are routed.

When the bulb is switched on, its filament temperature rises, increasing its impedance and thus decreasing the power required to illuminate. A further advantage is the existence of the filament itself which, in the required illumination in the case of its integrity, conducts a current detectable by the higher-level control system and the bulb emits light or does not flow when the filament breaks and does not emit light. The disadvantage of the bulb is its low fiber life, especially in the case of oscillating light signaling.

The advantage of LED luminaires is their long service life. The disadvantage of LED lamps is the risk of light emission based on capacitive or induced voltages and currents. A further disadvantage may then be the undetectable reduction in the light emitted due to the failure of the individual LEDs of the luminaire.

It is an object of the present invention to find a solution for the electronic part of an LED lamp eliminating the above-mentioned drawbacks of incandescent lamps and the LED lamps previously used.

SUMMARY OF THE INVENTION

The invention relates to an electronic control system for light emitting LEDs, in particular for optical signaling in railway traffic, comprising at least one column of LEDs with

-2additional circuits. The principle of the invention consists in that the input voltage and current measuring circuit is connected to the AC or DC voltage input of the system, which is connected to an inverter block containing a pulse generator, a choke, a diode and a switch. By their measurement outputs, the input voltage and current measuring circuit is individually connected to the first and second control blocks, which are interconnected, independent of each other, and are individually connected to the first and second block of the safe passage of the switch drive signal. These excitation block safe passages, which are embedded in the inverter boost circuits, are connected in series between the pulse generator output and the switch. The output circuit of the boost converter is connected to the output voltage of the boost converter and at least one column of LEDs with additional circuits. The outputs of the output voltage measuring circuit of the increasing converter are individually connected to the first and second control blocks. Each LED column contains serially coupled LEDs in series with the LED power supply and the current measuring circuit, and a voltage measuring circuit on the serial combination of the LED power supply and the current measuring circuit. The current measuring circuit outputs and the voltage measuring circuit outputs on the series combination of the LED power supply and the current measuring circuit are individually connected to the first and second control blocks, the LED power supply input being connected to the first control block and / or the second control block for control. A coding circuit controlled by the first control block and / or the second control block is connected downstream of the input voltage and current measuring circuit.

An input filter can be connected between the AC or DC input of the system and the input voltage and current measuring circuit to suppress interfering signals.

A choke is connected to the output of the rectifier, to the opposite end to which the switch is connected, by its second pole grounded and by its anode diode, to the cathode to which one pole of capacitor is connected, by its other pole grounded, this choke, diode and capacitor are A boost converter block, the output of which is a capacitor, to which is connected both the output voltage measuring circuit of the boost converter and at least one LED column with additional circuits.

The first or second or both control blocks may be coupled to the power supply of the LED column with additional circuits to control the intensity of the light emitted.

In the case of system input AC voltage, a rectifier is connected between the output voltage and current measuring circuit output and the inverter block.

Advantages of the present invention include, inter alia, a substantial increase in the lifetime of optical signaling in rail traffic for railroad warning signals and train control signals. Particularly important is the safe detection and illumination of a sufficient number of LEDs based on the measured voltages and currents, with the possibility of safely switching off the system in the case of insufficient number of illuminated LEDs. Equally important, it is particularly safe to detect a possible system error state by coding the current draw of the system.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawing, an example of an embodiment of the present invention is shown, in the following paragraph, a detailed description thereof is provided with an explanation.

DETAILED DESCRIPTION OF THE INVENTION

The electronic control system of the light emitting LEDs for optical signaling in rail traffic comprises one or more columns of SLi to SL _K LEDs with additional circuits. The input voltage and current measuring circuit MOUI is connected to the input of the system AC or DC voltage via the input filter F, which is connected via its rectifier U to the ZM block of the inverter. This ZM boost converter block includes a pulse generator GI and a switch SP. It further comprises a choke L connected to the output of the rectifier U, to the opposite end of which the switch SP is connected by its second pole and by its anode diode D, to the cathode to which one pole of the capacitor C is connected by its other pole. The output of the incrementing converter ZM is a cathode of diode D, to which is connected both the measuring circuit MOUC of the output voltage of the incrementing converter ZM and on the other hand at least one column SLi to SLk LED

-4 diode with additional circuits.

The MQUI input voltage and current measuring circuit is individually connected to its first and second CPU control blocks by its measuring outputs. CPUr. which are interconnected and further connected individually to the safe product BS, to the first and second BSa blocks. BSr for safe passage of the SP switch excitation signal. These blocks BSa. BSr of the safe passage of the drive signal of the SP switch are connected in series between the output of the pulse generator GI and the switch SP. To the output of the incrementing converter block ZM is connected, on the one hand, the measuring circuit MOUC of the output voltage of the incrementing converter ZM and, on the other hand, at least one LED column with additional circuits SLi to SLk. The outputs of the measuring circuit MOUC of the output voltage increasing converter ZM are individually connected to the first and second CPU control blocks a, CPUr.

Each LED column SLi to SLk contains serially coupled LEDs in series with the LED power source PZ and the MOI current measuring circuit, and a voltage measuring circuit MOU on the serial combination of the LED power source PZ and the MOI current measuring circuit. The outputs of the MOI current measuring circuit and the MOU voltage measuring circuit outputs on a series combination of the LED current source PZ and the MOI current measuring circuit are individually connected to the first and second CPU control blocks a. CPUr. The PZ power LED input is connected to a second CPUr control block. alternatively, it may be connected to the first CPU control block or simultaneously to both the CPU control blocks; and. CPUr. The input of the coding circuit KO is connected to the first CPU control block a. alternatively, it may be connected to a second CPU control block or simultaneously to both CPU control blocks; and. CPUr.

When the input AC or DC voltage is connected, the first and second CPU control blocks a and. CPUr. which evaluate the predefined correct voltage and current magnitudes, in this case all of the measured quantities of the MQUI input voltage and current measuring circuit, the MOL to MOL current measuring circuit, the MOL to MOL voltage measuring circuit on a series PZi to PZk power supply brightness and measuring circuit MOUC of the output voltage increasing converter ZM. At the same time there is

-5 communication between the two CPU control blocks and. CPUr. it is for the exchange and comparison of measured data. If the data is in both CPU and CPU control blocks. CPUr evaluated as valid, i.e. having a predetermined value, both CPU control blocks and. CPUr generate fixed frequency dynamic signals (changing signals) that are individually fed to the first and second block BSa. BSr for safe passage of the SP switch excitation signal. To ensure security, these dynamic signals are mutually controlled by CPU and CPU control blocks. CPUr with each other. In other words, the first CPU control block a verifies the function of the second CPU control block and vice versa. If a mismatch is detected, the control block that detected the mismatch terminates its operation, in particular generating a dynamic signal for the corresponding first or second block BSa. BSr for safe passage of the SP switch excitation signal. Co-existence of dynamic signals at inputs of BSa blocks. BSr of the safe passage of the drive signal of the switch SP allows the signal from the pulse generator GI to pass to the switch SP which subsequently starts its operation, i.e. switches at the frequency from the pulse generator GI.

At the output of the inverter block ZM, there is an increased DC voltage required for proper operation of the LEDs SLi to SLk with additional circuits, i.e., the LEDs lit, with the current value set by the current source PZi to PZk to regulate the brightness of these LEDs. The current in the columns SLi to SLk of the LEDs with additional circuits, and thus the intensity of the individual columns of the LEDs SLi to SLk, is adjusted by means of the current source PZi to PZk. controlled from the respective control block by CPU blocks. CPUr.

Based on the evaluation of all measured variables in the MOUI input voltage and current measuring circuit, the MOIi to MOL current measuring circuit, the MOUi to MOUu voltage measuring circuit, and the MOUC output voltage measuring circuit of the ZM converter, and their validation, are coded in a controlled manner. KO, ie controlled change of current consumption of the whole system. This change in current is evaluated by the master system, which is evaluated as the correct function of the system according to the invention. A superior system is an intelligent control and supervisory circuit for system operation.

-6The system allows to detect LED illumination faults as described above and decide whether their illumination is still sufficient or not to meet the luminance parameters. If the illumination is reduced but still sufficient, the master system is informed via the coding circuit ΚΌ. If it is insufficient, the system function is the termination of at least one CPU control block and. CPUr managed terminated. A shutdown may also occur within the system, such as a failure of one of the CPU control blocks and. CPUr and the like. In this case, the fixed frequency dynamic signals (shifting signals) disappear from the CPU control blocks a. The CPUr and thus the operation of the increasing ZM converter is terminated and at the same time the ability of the system to code the drawn current ceases.

By using a specific signal at the output of the GI pulse generator, a harmonious current draw by the system is achieved.

Industrial usability

The electronic control system of the light emitting LEDs according to the invention is particularly useful for optical signaling in rail transport.

Claims (3)

A system for the electronic control of light emitting LEDs, in particular for optical signaling in rail transport, comprising at least one column (SLi to SLk) of LEDs with auxiliary circuits, characterized in that a measuring circuit () is connected to the AC or DC voltage input of the system. MOUI) of the input voltage and current, which is connected to its inverter block (ZM) comprising a pulse generator (GI) and a switch (SP) by its output, its input voltage and current measuring circuit (MOUI) being individually connected to the first and a second control block (CPUa, CPUb), which are connected to each other, are independent of one another and are respectively connected to first and second block (BSA, BSB) safe passage of the excitation signal of the switch (SP), wherein the blocks (BS _a, BSB) the safe passage of the switch driver (SP) is connected in series between the pulse generator output (GI) and the switch (SP), and wherein the output of the inverter's output voltage (ZM) is connected to the output of the inverter block (ZM) and at least one of the LEDs with additional circuits (SLi to SLk), MOUC) of the output voltage boost converter (ZM) are individually connected to the first and second control blocks (CPUa, CPUb), each LED column (SLi to SLk) containing serially coupled LEDs in series with the LED current source and the measurement a current circuit (MOI) and a voltage measuring circuit (MOU) on a serial combination of the LED power supply (PZ) and a current measuring circuit (MOI), where the current measuring circuit outputs (MOI) and the voltage measuring circuit outputs (MOU) on the serial combination the LED current source (PZ) and the current measurement circuit (MOI) are individually connected to the first and second control blocks (CPUa, CPUb), wherein the input of the LED current source (PZ) is connected to the first a control circuit (CPUa) and / or a second control block (CPUb) is connected to the control circuit, while a coding circuit (KO) is connected downstream of the measuring circuit (MOUI) of the input voltage and current, controlled by the first control block (CPUa) and / or the second control block ( CPUb). System according to claim 1, characterized in that an input filter (F) is connected between the AC or DC voltage input of the system and the input voltage and current measuring circuit (MOUI). -93. System according to claim 1 or 2, characterized in that a choke (L) is connected to the output of the rectifier (U), to which the switch (SP) is connected with its second pole and its diode (D) connected to the opposite end. , to the cathode to which one pole of capacitor (C) is connected, with its other pole grounded, where the choke (L), diode (D) and capacitor (C) are part of the inverter block (ZM) outputting capacitor (C), to which is connected, on the one hand, the measuring circuit (MOUC) of the output voltage increasing converter (ZM) and, on the other hand, at least one column (SLj to SLk) of the LEDs with additional circuits. System according to one of claims 1 to 3, characterized in that, in the case of an input AC voltage of the system, a rectifier (U) is connected between the output of the input voltage and current measuring circuit (MOUI) and the inverter block (ZM).