ITRM20100028A1 - "INNOVATIVE STARTER FOR FLUORESCENT LAMPS" - Google Patents

Description

Description of the industrial invention entitled: INNOVATIVE STARTER FOR FLUORESCENCE LAMPS;

The present invention relates to the lighting sector, and in particular it relates to an innovative starter for fluorescent lamps.

The neon lamp is a type of discharge lamp consisting of a clear glass bulb containing low pressure neon gas.

In common parlance, fluorescent lamps, used for lighting offices and homes, are erroneously called "neon lamps". Unlike the former, however, neon lamps proper emit an orange light of low intensity and are used more for signaling than lighting functions.

The fluorescent lamp is a particular type of discharge lamp in which the visible light emission is indirect, that is, it is not emitted directly by the ionized gas, but by a fluorescent material (hence the name).

As mentioned, this type of lamps are erroneously called neon lamps or neon tubes, but they do not always contain neon and in reality their operation is mainly due to the presence of mercury vapors and fluorescent materials, and not neon.

The fluorescent lamp consists of a glass tube, which can be linear, circular or variously shaped (we distinguish in particular the CFL, Compact Fluorescent Lamp, which have the tube of such shape as to have little space and usually integrate the electronics power supply and are equipped with E27 connection) inside which a vacuum is first practiced, then introduced a noble gas (argon, xenon, neon, or krypton) at low pressure and a small quantity of liquid mercury, which in part evaporates mixing with the noble gas. The inner surface of the tube is coated with a fluorescent material, which looks like a white powder. At the two ends of the tube there are two electrodes.

The electrons moving between the two electrodes excite the mercury atoms contained in the gas, prompting them to emit ultraviolet radiation. The fluorescent material with which the tube is covered, hit by such radiations, in turn emits visible light. Since visible light has a frequency and therefore an energy lower than ultraviolet, the transformation produced by the fluorescent material involves an inevitable loss of energy, in the form of heat, which determines the heating of the tube. A different composition of the fluorescent material allows to produce a warmer or colder light.

The electrodes of a fluorescent tube, unlike an incandescent lamp, cannot be connected directly to the mains because due to its voltage-current characteristic, the lamp must be powered in current limiting. For this reason, a device capable of limiting the current is placed in series with the lamp, usually an inductance, commonly called a reactor, which additionally allows to generate an overvoltage that facilitates triggering, or in very rare cases a resistor is used. E s i s t o n o d u e c a t e g o r i e d i a l i m e n t a t o r i: electromagnetic, which require the use of the so-called starter and electronic, which make the starter unnecessary.

Fluorescent lamps have a longer average life than incandescent ones, but their duration can be strongly influenced by the number of starts and stops, unless an electronic control is used: each of these operations, in fact, reduces the life of the lamp, due to the wear suffered by the electrodes. The value provided by the manufacturers is generally calculated with ignition cycles of 8 hours, and ranges from 12-15000 hours for tubular lamps to 5-6000 hours for compact lamps.

The electronic piloting, on the other hand, thanks to the preheating of the cathodes (electrodes), prevents damage by allowing a practically infinite number of ignitions (over 60,000) and the precision of the control extends its life to at least 10,000 hours. Unlike incandescent lamps, these lamps slightly lose the amount of luminous flux emitted over time, furthermore for older models (generally without preheating) of compact lamps they can generally take a few minutes to reach the maximum possible emission after the 'power on.

The so-called starter or igniter (from the English verb “t o s t a r t” = to start) in the lighting engineering field is a device generally used in discharge lamps to start their operation.

This device causes the lamp electrodes to heat up to a temperature of about 1200-1300 ° K, thus starting the gas ionization process. This then determines the discharge which then allows the complete ionization of the gas and the operation of the lamp at steady state.

The starter must be properly calibrated to obtain the fastest and most decisive ignition. This component, albeit within certain limits, nevertheless has the ability to adapt to discharge lamps of different power.

The starter is basically a switch in which the moving contact is made up of a bimetallic foil which deforms when heated. The sequence of switching on the tube is as follows:

1. Initially (cold starter) the internal contact is open;

2. Applying voltage to the circuit, the gas contained in the starter ionises causing the heating of the internal bimetallic foil which, following thermal expansion, closes the internal contact, at the same time heating the filaments of the lamp thanks to the passage of current;

3. The closure of the internal contact causes the zeroing of the voltage at the ends of the sheet, which then cools by contracting, thus reopening the internal contact after about one second;

4. The opening of the circuit caused by the starter causes, due to the self-induction effect on the reactor, an overvoltage such as to cause the discharge and consequent ionization of the gas of the lamp, with its ignition.

If ignition fails, the starter automatically repeats the sequence described above.

It is evident that the currently known starters are not able to guarantee rapid ignition of the fluorescent lamp over time, and over time their operating characteristics deteriorate, until the lamp turns on. more and their replacement is necessary.

In addition to this, with current starters the ignition of the lamp is not immediate like that of incandescent lamps, and in many cases it is necessary to wait a few minutes to get the maximum brightness from the lamp.

Furthermore, when a fluorescent lamp begins to “wear out”, and when its operating characteristics deteriorate, it must be replaced as currently known starters are unable to ignite it.

The purpose of the present invention is to overcome the aforementioned problems by providing an innovative starter that guarantees instant ignition of the fluorescent lamps and constant operation over time, even in the presence of lamps that no longer turn on with the currently known starters, avoiding the need to replace the lamps themselves with obvious savings in terms of money and manpower.

This has been achieved, according to the invention, by providing a starter adapted to be connected in parallel to the fluorescent lamp, comprising a capacitor connected in series to an electronic device of a known type, able to interrupt the passage of current and to isolate said capacitor when the voltage drops below a certain value due to the ignition of the lamp itself.

A better understanding of the invention will be obtained with the following description and with reference to the attached figures which illustrate, purely by way of non-limiting example, some preferred embodiments of the invention.

In the drawings:

Figure 1A schematically shows a known type power supply circuit for a fluorescent lamp where: S = starter, L = lamp, C = filter capacitor, R = ballast;

Figures 1B and 1C, also related to the known technique such as fig. 1A, respectively show a connection diagram with luminescent starter and a connection diagram with thermal starter;

figure 2 schematically shows a power supply circuit for a fluorescent lamp in which there is a first embodiment of the starter according to the present invention;

figure 3 schematically shows a power supply circuit for a fluorescent lamp in which a second embodiment of the starter according to the present invention is present;

figure 4 schematically shows a power supply circuit for a fluorescent lamp in which there is a third embodiment of the starter according to the present invention;

figure 5 schematically shows a power supply circuit for a fluorescent lamp in which there is a fourth embodiment of the starter according to the present invention;

figure 6 schematically shows a power supply circuit for a fluorescent lamp in which a fifth embodiment of the starter according to the present invention is present;

figure 7, similar to fig. 2, shows a circuit in which the first embodiment of the invention is used to power a new fluorescent lamp devoid of internal filaments;

Figures 8 to 11, similar to the previous figs. 3 to 6, show the use of the different embodiments of the invention to power said new fluorescent lamp without internal filaments;

figure 12 shows a variant of the circuit of fig. 2, in which the internal filaments at each end of a known type of fluorescent lamp are short-circuited;

Figure 13, similar to the previous one, shows the invention which powers and turns on said lamp of a known type even if one of the internal filaments is interrupted;

figure 14 shows a simplified variant of the first embodiment of fig. 2.

The present invention relates to an innovative starter for switching on fluorescent lamps, which is able to guarantee immediate switching on of the fluorescent lamp, even if the lamp runs out over time.

It is well known that if we power a fluorescent lamp in alternating current, the ballast alone is not enough to turn it on. In fact, when the voltage returns to zero at the end of the first half period (positive or negative), the gas particles in the lamp lose their ionization and the lamp does not ignite.

With reference to Figure 2, a first embodiment of the invention provides to connect, in parallel to a fluorescent lamp, a new starter consisting of a capacitor C1 connected in series to a DIAC.

It should be remembered that the DIAC (Diode for Alternating Current: diode for alternating current) is part of the semiconductor devices.

From the functional point of view, it can be thought, as a first approximation, as the coupling of two anti-series Zener diodes or even as a gas arrester. In practice, the DIAC has a high impedance up to a threshold value of potential difference (defined breakover) beyond which the impedance collapses, allowing a high flow of current. Note that unlike normal diodes, the DIAC is not polarized, that is, it is bidirectional.

The function of the capacitor C1 is precisely to accumulate the electrical charges thanks to the voltage across the lamp during the first half-period and, concurrently with the voltage inversion of the second half-period, a voltage of 220 V is generated across the fluorescent lamp. which is sufficient to trigger the ignition of the ionized gas inside it.

Once the lamp is switched on (for example 40 W), the voltage at the ends of the lamp decreases, stabilizing at about 120 V and consequently the DIAC interrupts the branch of the circuit by isolating the connector C1, so that the fluorescence is in series with the reactor without having any circuit component in parallel.

According to a peculiar characteristic of the present invention, the starter just described reduces the consumption of electric energy since the capacitor C1 does not absorb energy when the lamp is switched on, while the capacitor of the currently known starters always remains connected in parallel to the lamp even when it is on

A second embodiment of the invention, shown in Figure 3, provides a starter connected in parallel to the fluorescent lamp, in which the DIAC described above is replaced by a TRIAC connected in parallel to a DIAC: in this case, the two poles of the DIAC are connected respectively to the gate of the TRIAC and to its anode opposite to the capacitor C1.

Also with this second embodiment, when the fluorescent lamp is on, the voltage across it is lowered to about 120 V and consequently the DIAC increases its impedance thus also deactivating the TRIAC.

It should be remembered that the TRIAC (from the English Triode for Alternating Current) is a semiconductor electronic component specifically designed to control alternating current loads. The TRIAC is used essentially in two ways: as a relay and as a dimmer (power regulator).

It is a device with three terminals, of which two are called anodes and are the passageway for the controlled current, while the third, called gate, is the control input. Ideally, the T RIA C has two SC Rs connected in antiparallel with the gate in common. Each element conducts only in the half-period of the wave in which it is directly biased, from when a current pulse is applied to the gate (higher than a minimum sensitivity threshold) up to the zero crossing of the current. In the case of the 50 Hz industrial power grid, the half-period lasts 0.01 seconds. Note that the TRIAC does not regulate the current, but can only be in conduction or inhibit modes. This is not a disadvantage, on the contrary it allows to manage high powers with small command signals and with limited heat dissipation.

A third embodiment of the invention, shown in figure 4, provides a starter connected in parallel to the fluorescent lamp, in which the DIAC described above is replaced by a TRIAC connected in parallel to two opposing diodes D1 and D2, with the terminals common anode: in this case, the two anode terminals of the diodes are connected respectively to the gate of the TRIAC and to its anode opposite to the capacitor C1.

It should be remembered that commercially available diodes have a reverse voltage value beyond which a reverse current passes through the diode itself.

Operation is similar to that described for the first and second embodiments of the invention.

It should be noted that advantageously, the presence of two diodes D1 and D2 with the central zero makes it possible to use both half-waves of the alternating current.

A fourth embodiment of the invention, shown in Figure 5, provides a starter connected in parallel to the fluorescent lamp, in which the DIAC described above is replaced by a TRIAC connected in parallel to a diode D1: in this case, the cathode terminal of the diode is connected to the gate of the TRIAC and the anode terminal of the diode D1 is connected to the anode of the TRIAC opposite the capacitor C1.

Apart from the fact that the presence of a single diode D1 causes the starter to work only with a half wave of the alternating current, the operation is the same as described for the previous embodiments.

A fifth embodiment of the invention, shown in figure 6, provides for a starter connected in parallel to the fluorescent lamp, in which the DIAC described above is replaced by a TRIAC connected in parallel to a small Neon lamp L2: in this case, the two poles of the Neon bulb are connected respectively to the gate of the TRIAC and to its anode opposite to the capacitor C1.

Operation is similar to that described for the previous embodiments of the invention.

A second peculiar feature of the present invention consists in the fact that the innovative starter described up to now can also be used with fluorescent lamps without internal metal filaments.

Figure 7 schematically shows one of these fluorescent lamps devoid of the classic internal filaments, powered with a starter according to the first embodiment already described and shown in fig. 2.

The following figures from 8 to 11, similar to the previous figures from 3 to 7, show a fluorescent lamp without internal filaments which comes respectively with each of the embodiments of the invention described up to now.

With particular reference to figure 12, it is interesting to note that with the starter according to the present invention, it is possible to power and switch on fluorescent lamps of a known type even if the electrodes of each end are short-circuited, as clearly shown in said figure .

I n t a l e c a s o, s e c o n d o u n a u l t e r i o r and a peculiar feature of the invention, it is also possible to use the starter described so far to turn on fluorescent lamps of a known type, that is with internal filaments, in which one or both internal filaments have "burned out" that is interrupted.

This case is shown, purely by way of example, in figure 13 with reference to the first embodiment of fig. 2, but evidently also applies to all the other embodiments already described.

Finally, a simplified variant of all the embodiments described up to now, shown in figure 14, provides as an alternative to the DIAC described for the first embodiment and connected in series to the capacitor C1, a simple power button is provided, of the type normally open, which is initially pressed only to turn on the fluorescent lamp and then released when it has turned on.

Advantageously, the efficiency of the innovative starter described up to now also allows "exhausted" fluorescent lamps to be turned on, that is, starters of the type known so far are no longer able to ignite.

Claims (4)

CLAIMS: 1. Device for the instantaneous ignition of fluorescent lamps, or starter, characterized in that it comprises a capacitor (C1) connected in series to an electronic device of a known type, able to interrupt the passage of current and to isolate said capacitor when the voltage drops below a certain value due to the ignition of the lamp itself, in which said starter is adapted to be connected in parallel to the fluorescent lamp; the function of the capacitor (C1) being precisely that of accumulating the electrical charges thanks to the voltage present at the ends of the lamp during the first half-period, thus obtaining that, in conjunction with the voltage inversion of the second half-period, at the ends of the fluorescent lamp generates a voltage, e.g. of 220V, which is sufficient to trigger the ignition of the ionized gas present inside. 2. Device according to the preceding claim, characterized in that said electronic device of known type, connected in series to the capacitor (C1), is a DIAC; thus obtaining that once the fluorescent lamp is switched on, the voltage at the ends of the lamp decreases, stabilizing for example at about 120 V, and consequently the DIAC interrupts its branch of the circuit by isolating the capacitor (C1), so that the lamp at fluorescence is in series with the reactor without having any circuit component in parallel; thus obtaining that when the lamp is switched on the capacitor does not absorb energy, reducing energy consumption with respect to currently known starters in which the capacitor remains always connected in parallel to the lamp even when it is switched on. 3. Device according to claim 1, characterized in that said electronic device of known type, connected in series to the capacitor (C1), consists of a TRIAC connected in parallel to a DIAC having the two poles which are respectively connected to the gate of the TRIAC and its anode opposite the capacitor (C1); thus obtaining that when the fluorescent lamp is turned on, the voltage across it is lowered, for example up to about 120 V, and consequently the DIAC increases its impedance thus also deactivating the TRIAC. 4. Device according to claim 1, characterized in that said electronic device of known type, connected in series to the capacitor (C1), consists of a TRIAC connected in parallel to two opposite diodes (D1 and D2), with their terminals common anode, in which the two anode terminals of the diodes are connected respectively to the gate of the TRIAC and to its anode opposite the capacitor (C1); the presence of the two diodes (D1 and D2) with the central zero allowing to use both half-waves of the alternating current. 6. Device according to claim 1, characterized in that said electronic device of known type, connected in series to the capacitor (C1), consists of a TRIAC connected in parallel to a diode (D1), in which the cathode terminal of the diode is connected to the gate of the TRIAC and the anode terminal of the diode (D1) is connected to the anode of the TRIAC opposite the capacitor (C1). 7. Device according to claim 1, characterized in that said electronic device of known type, connected in series to the capacitor (C1), consists of a TRIAC connected in parallel to a small Neon lamp (L2), in which the two Poles of the Neon bulb are connected respectively to the gate of the TRIAC and to its anode opposite to the capacitor (C1). 8. D i s p o s i t i v o s e c o n d o u n a d e l l and the preceding claims, characterized in that it can also be used to ignite fluorescent lamps without internal metal filaments. Device according to one of claims 1 to 7, characterized in that it can be used to power and light fluorescent lamps of a known type in which the electrodes of each end are short-circuited to each other. 10. Device according to the preceding claim, characterized in that it is adapted to ignite fluorescent lamps of a known type, ie with internal filaments, in which one or both of the internal filaments are interrupted. 11. Device according to claim 1, characterized by the fact that said known type device, connected in series to the capacitor (C1), consists of a simple ignition button, of the normally open type, able to be initially pressed - by the user - only to turn on the fluorescent lamp and then released when it has turned on.