DE202011003952U1 - Illuminants for use in conventional sockets for fluorescent tubes - Google Patents

Abstract

Illuminant for use in conventional sockets for fluorescent tubes, the illuminant being designed as a prismatic tube, which in each case has an electrical connection at the end of the tube, with a luminous element for emitting light, at least one LED being provided as the luminous element, characterized in that the illuminant comprises a recognition which recognizes whether a low-frequency alternating voltage or a high-frequency alternating voltage is present at the illuminant as an operating voltage, that the illuminant is converted into one of two operating modes by this recognition, the supply voltage for the illuminant being rectified in the first operating mode Operating voltage is generated and in the second operating mode, the supply voltage for the luminous element is generated by means of an inductive high-frequency transmission.

Description

The present invention relates to a lighting means for use in conventional fluorescent lamp sockets. Such bulbs usually consist of a prism-shaped agitator with a round cross section, which has at its ends in each case a connection for electrical energy. Electrical energy can be supplied to the lighting means via these connections, as a result of which the lighting means emits light.

The known bulbs use a glass body, a gas mixture within the tubular body, as well as a special coating on the inside of the glass body. Due to the electrical energy, the gas mixture is partially ionized. The ions then generate energy in the form of light emitted by the glass body to the outside as soon as they hit the special coating.

For the operation of such bulbs so-called ballasts are used. In principle, there are two types of ballasts. For one there are conventional ballasts (CCG), consisting of a choke coil and a so-called starter. In the lamp itself, the electrical connections are led out of the lamp as two poles. Between these poles an electrical conductor is attached. The starter initially allows, when switching on the bulb, a current flow through the electrical conductors at the terminals. After a while, then the starter interrupts the current flow and there is a high ignition voltage through the choke coil. This high voltage generates a current flow within the luminous means, which partially ionizes the gas mixture and thus makes it low-impedance. Thereafter, the current flows through the lamp even at normal operating voltage.

On the other hand there are electronic ballasts (ECG). These have no choke coil and / or starter. They generate a high-frequency operating voltage, which hits the resonant frequency of the lamp. The resonance creates a high operating voltage, which is used as ignition voltage for the light source. This high voltage generates a current flow within the luminous means, which partially ionizes the gas mixture and thus makes it low-impedance. Thereafter, the current also flows at normal operating voltage through the light source, which is nevertheless high-frequency by the electronic ballast.

The disadvantage of these conventional bulbs, however, is a relatively high power loss in the CCGs, as well as high production costs for ECGs. Today, more electronic ballasts are in use than the lossy CCGs. However, according to a European directive, these lamps are to be abolished in the medium term and replaced with energy-saving lamps.

As a result, there are already bulbs that use instead of ionized gas in conjunction with coated glass as a luminous body, LEDs as luminous bodies. A disadvantage of these bulbs, however, is that they are not compatible with the existing sockets for the bulbs, as these bulbs do not work with the ballasts mentioned above. A conversion of the socket is thus necessary to operate LEDs as a filament, as they can not be operated with variable and / or high operating voltage. It is thus necessary to regulate the supply voltage of the LEDs appropriately. It is therefore an object of the present invention to provide a luminous means which uses LEDs as a luminous body, which is compatible with the connections of conventional sockets for fluorescent tubes and which is provided by the existing ballasts (KVG or electronic ballast).

This object is achieved by the invention by the features of claim 1. The luminous means according to the invention is likewise designed as a prismatic tube with electrical connections at both ends. As a result, the luminous means according to the invention can be easily introduced into existing sockets for fluorescent tubes. However, instead of the gas mixture and a special coating, the present invention has at least one LED as a luminous body. So that these LEDs are not damaged by variable or too high operating voltages, a supply voltage for the LEDs is generated from the respective operating voltage.

For this purpose, it is first necessary that the light source detects whether a CCG or a ballast is used to operate the bulb. To detect an AC voltage identification is provided in the bulb. This can be done by means for a frequency measurement and / or by voltage measurement. During the frequency measurement, it is determined whether a high-frequency operating voltage is currently being applied to the connections. Since the high-frequency voltages of the ECGs are much higher than the normal mains frequency of 50 or 60 Hz (for example, at 40 kHz), they are easily detected by frequency measurement. In the voltage measurement, the height of the voltage is measured. Since the ECGs try to cause a resonance in the lamp, higher operating voltages than in KVGs in connection with the device according to the invention arise. By a means for inductive high-frequency transmission (for example, by a commercial high frequency or RF transformer) is the electrical resistance at the connection of the lamp similar to the resistance at the connection of commercially available fluorescent tubes. Thus, it can also be easily determined by voltage measurement, which type of ballast is used.

After the successful detection of the ballast, a supply voltage for the lamp must be generated from the existing operating voltage. For this purpose, two separate voltage generations are provided within the lamp. So that they are not operated simultaneously, they are separated from each other by circuitry. This separation is carried out by at least one electrical or electronic switch. This can be, for example, a relay, a TRIAC or similar. These relays are controlled by AC voltage identification. This creates two operating modes in the light source.

In the first operating mode, a low-frequency voltage is detected as the operating voltage (KVG). The operating voltage of the lamp is supplied to a rectification. This can be done for example by an AC / DC standard LED driver. The alternating voltage identification controls the switch now so that the rectified operating voltage of the lamp is supplied as a supply voltage to the LEDs.

In the second operating mode, a high-frequency voltage is detected as the operating voltage (ECG). The high-frequency operating voltage of the luminous means is inductively transmitted via means for inductive high-frequency transmission and fed to a second, corresponding rectification. This can be done for example by a high-frequency transformer with LED driver. The operating voltage can be sinusoidal, sawtooth or rectangular. The alternating voltage identification controls the switch now so that the rectified high-frequency operating voltage of the lamp is supplied as a supply voltage to the LEDs. The means for inductive high-frequency transmission thus serves to transmit the supply voltage and thus the supply current in the case of electronic ballasts and at the same time as a simulated electrical line at the terminals in the case of CCGs and electronic ballasts.

As a result of the simulated connections, the illuminants according to the invention are recognized as normal illuminants even in the case of fault detection, as they are performed by electronic ballasts, and are not declared as faulty.

At least one phase judge and / or zero judge is provided to protect against reverse polarity of the terminals. These detect the phase position of the electrical connections. About the AC identification and the switch, the phase and / or zero rectifier are connected only in the case of KVGs. In the second operating mode, a reverse polarity is irrelevant, since the supply voltage is generated only via the inductive transmission. In the first operating mode, however, a correct polarity must be ensured.

The supply voltage is then supplied to the luminous element. The LEDs then emit energy in the form of light. In this case, the number of LEDs can vary in order to realize different luminous intensities.

By means of these illuminants according to the invention, it is possible to operate them without conversion existing versions for fluorescent tubes with any ballasts. A simple replacement of the bulb is sufficient.

Instead of KVGs or ECGs often called so-called VVGs. These have the same functional principle as KVGs, only the VVGs optimized so that less power loss arises when operating such lamps. However, since the operating principle is the same as the CCGs, the lighting device according to the invention can also be operated with VVGs.

In the drawing, the subject invention is shown in one embodiment. It shows:

1 An electrical switching principle of the luminous means according to the invention

In the 1 is a switching principle shown with an exemplary structure of a lamp according to the invention. All elements shown are arranged inside the lamp. Two electrical connections (G13 plug) are provided, via which electrical energy can be supplied to the light source. This is the operating voltage of the lamp. At one of the two connections, the AC voltage is tapped and fed to an AC identification (90-265 VAC identification). In this embodiment, AC voltages between 90 and 265 volts are detected at 50 or 60 Hz. The AC identification controls two relays (Rel1 and Rel2). These separate the two operating modes from each other.

If the two relays (Rel1 and Rel2) are in the rest position, operating mode 2 has been detected. This means that a high-frequency signal is present as operating voltage at the terminals and thus an ECG is present. About the inductive high-frequency transmission, which is shown as two transformers, the high-frequency operating voltage is tapped and supplied to a voltage and current adjustment (high-frequency transformation LED driver). Via the two outputs of the adaptation (OUT and OUT +) and the relays Rel1 and Rel2, the adjusted operating voltage is supplied as supply voltage to the luminous element, which consists of LEDs. These will light up.

Due to the inductive voltage transmission very low loss lines can be realized.

If the AC identification detects an AC voltage within 90-265 volts at 50 or 60 Hz, it triggers the two relays (Rel1 and Rel2), which then switch both from the rest position to the operating position. In doing so, they switch the supply voltage so that it is now taken from another rectification (AC / DC standard LED driver) at its outputs (OUT and OUT +). This rectification is powered by the normal operating voltage.

In addition, the two relays (Rel1 and Rel2) switch two phase rectifiers (phase / neutral rectifier) to the operating voltage at the electrical connections, which have the task of preventing reverse polarity of the connections. The two phase rectifiers ensure that at the input of the rectification in operating mode 1 there is always an operating voltage with the same phase position. They thus prevent unwanted damage to the bulb.

For suppression and further prevention of power loss, a compensation of the inductive high-frequency transformer is provided (capacitive compensation). This is intended to prevent a phase shift between transmitted voltage and the generated current flow, which would bring about corresponding power losses.

In the drawing, the subject invention is realized only for example. This is not limited to this. Rather, other designs and modifications are conceivable. For example, the compensation of the inductive high-frequency transmission by other means instead of capacitive could happen or it can be used other than LEDs, such as OLEDs or plasma lamps. Likewise, the prismatic tube is not limited to a round cross-section. Likewise, angular, oval or other cross-sections are conceivable.

Claims (15)

Illuminant for use in conventional sockets for fluorescent tubes, wherein the illuminant is formed as a prismatic tube having an electrical connection at the end of the tube, with a luminous element for emitting light, wherein at least one LED is provided as a luminous element, characterized in that the luminous means comprises a detection which detects whether the operating voltage is a low-frequency AC voltage or a high-frequency AC voltage applied to the light source, that the light source is converted by this detection in one of two operating modes, wherein in the first operating mode, the supply voltage for the luminous means by means of the rectified Operating voltage is generated and the supply voltage for the luminous element is generated by means of a high-frequency inductive transmission in the second operating mode. Illuminant according to Claim 1, characterized in that the detection within the luminous means for switching between the two operating modes is effected by means for a frequency measurement. Illuminant according to Claim 1 or 2, characterized in that the detection within the luminous means for switching between the two operating modes is effected by means for a voltage measurement. Illuminant according to one of claims 1 to 3, characterized in that the inductive high frequency transmission is done by a commercial high-frequency or RF transformer. Illuminant according to one of claims 1 to 4, characterized in that the supply voltage for the luminous body is rectified. Illuminant according to one of claims 1 to 5, characterized in that the inductive high-frequency transmission is capacitively compensated, in particular by capacitors. Illuminant according to one of claims 1 to 6, characterized in that in the second operating mode, the operating voltage is sinusoidal. Illuminant according to one of claims 1 to 6, characterized in that in the second operating mode, the operating voltage is sawtooth. Illuminant according to one of claims 1 to 6, characterized in that in the second operating mode, the operating voltage is rectangular. Illuminant according to one of claims 1 to 9, characterized in that at least one phase judge is provided to ensure protection against reverse polarity of the electrical connections. Illuminant according to one of claims 1 to 9, characterized in that at least one zeroing is provided to ensure protection against reverse polarity of the electrical connections. Illuminant according to one of claims 1 to 11, characterized in that the switching between the two operating modes is done by at least one relay. Illuminant according to one of claims 1 to 12, characterized in that the electrical connections each have two poles. Illuminant according to claim 13, characterized in that the operating voltage is tapped at both poles of a terminal. Illuminant according to claim 13, characterized in that the operating voltage is tapped off at least one pole of both terminals.

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