DE19502772A1 - Electronic ballast for fluorescent lamps - Google Patents

Abstract

An electronic ballast unit for HF operation of one or more fluorescent lamps from the AC mains has the AC rectified in a first module (1). The DC passes through several other modules (2)where it is converted to high frequency AC. The first module has circuits for harmonic suppression and power factor correction plus means to stabilise the rectified output voltage. The output voltage is decoupled by a diode circuit. The voltage is continuously available at one output terminal but at a second terminal it can be switched off selectively. This is done by a bistable flip-flop. The lamp modules have input and output terminals which allow the through connection of switched and non-switched DC.

Description

Fluorescent lamps require a current limit to operate, which for years only achieved by connecting a choke has been.

The high losses of such facilities have resulted in increasingly developing electronic ballasts and use, which is not only a better electrical we degree of efficiency, but also bring a better quality of light.

With the increasing number of electronic ballasts used equipment, however, showed a considerable disadvantage in that these devices do not have a sinusoidal current consumption, but the current peaks that occur lead to network distortions that sometimes even to the collapse of individual power supply networks led.

In addition, the high-frequency fields that occur cause one Electrosmog, which can even lead to health damage.

Finally, the electronic outlay on switching means is around to actually achieve satisfactory results, very high and inhibits the desirable introduction of the beneficial electro African ballasts.

The object of the invention is to avoid the disadvantages mentioned and to come to inexpensive solutions.  

This is achieved by a modular construction according to the invention by placing the power supply in a power supply module ( 1 ) which first converts the AC voltage of the network into DC voltage and then supplies this DC voltage to one or more lamp modules ( 2 ).

This already prevents the occurrence of electrical changes self-fields and significantly reduces the amount of switching equipment.

If one provides switching means in the power supply module ( 1 ) which cause harmonic reduction (Power Factor Correction), this measure already reduces the costs significantly, since they would otherwise have to be used for each individual lamp.

Means of voltage stabilization are only required in the power supply module ( 1 ) and bring perfect operation for all connected lamp modules ( 2 ) even when there are strong voltage fluctuations in the power supply.

The series connection of lamp modules ( 2 ) according to the invention is further simplified by providing connections to the lamp modules ( 2 ) which allow the DC voltage to be connected from one module to the next, which is of the utmost importance for light strips.

A further embodiment of the invention consists in that the direct voltage available at the output of the power supply module ( 1 ) is supplied via a diode circuit which enables a problem-free parallel connection of several power supply modules ( 1 ).

Another idea according to the invention is not only to provide an output connection for the DC voltage at the power supply module ( 1 ), but also a second parallel output connection, which can be switched off and on again by switching means. According to the invention, both connections, switched and unswitched, are supplied to the lamp modules ( 2 ), which means that certain lamps can be switched off in groups, for example in order to achieve significant energy savings during night operation.

Figs. 1 to 6 schematically show the great advantages of the dung OF INVENTION. The power supply module ( 1 ) with its output connections ( 20 ) and ( 21 ) and a negative pole ( 8 ) is located at the network input ( 3 ). The connection ( 20 ) is continuously connected to the output of the Stromversor supply module ( 1 ), however, the connection ( 21 ) can optionally be switched, ie interrupted or switched on again who. The connected lamp modules ( 2 ) and ( 13 ) are supplied with DC voltage via the DC lines ( 4 ) and ( 5 ).

The converter circuit ( 24 ) in the lamp module ( 2 ) now converts the DC voltage at the connection ( 22 ) into a high-frequency AC voltage, as has been used almost exclusively for fluorescent lamps in recent years. Two connections (L) each lead to the heating filaments ( 10 ) at the ends of the fluorescent lamp ( 6 ), which is particularly simple and inexpensive if the corresponding terminals (L) are arranged at the opposite ends of the lamp module ( 2 ).

The series connection of the next lamp module ( 13 ), which supplies the next fluorescent lamp ( 6 ) with its heating filaments ( 10 ) via lines ( 11 ) and ( 12 ), can possibly be switched off by making the connecting lines at the crossing point ( 14 ) ( 4 ) and ( 5 ) can be interchanged. The direct current line ( 4 ), which cannot be switched off, is carried out by the lamp module ( 13 ) between the terminals ( 23 ) - ( 23 ) without function, on the other hand, the converter circuit ( 24 ) of the lamp module ( 13 ) is connected to the switched line ( 5 ) the terminals ( 22 ) - ( 22 ).

In the same way, one can proceed with further lamp modules in order to place them either on the non-switched direct current line ( 4 ) or on the switched direct current line ( 5 ).

With several lamp modules you can of course do this Combine order in groups as you wish.

Figs. 2 and 3 schematically illustrate an example of inventive design modules, the exporting represented approximately forms in any way limiting are to be regarded as today already very many different constructions elec tronic ballasts on the market.

Fig. 2 shows a simple power supply module with the power terminals ( 25 ) with ground connection. According to the invention, the power supply module ( 1 ) is designed for a plurality of lamp modules and, in addition to the usual AC-DC converter with radio interference suppression ( 31 ), contains other important components, for. B. for the reduction of harmonics (Power Factor Correction) ( 28 ), as they occur in the conventional rectifier circuits ( 31 ). The accommodation of sta bilization circuits ( 29 ) of the delivered DC voltage can be realized efficiently since it only has to be provided once for all lamp modules.

Fig. 4 also schematically shows a further feature of the invention that at least 2 DC outputs ( 20 ) or ( 21 ) are provided and a connection, for. B. ( 21 ) can be switched off by switching means ( 33 ). This can e.g. B. done in a known manner by a bistable flip-flop circuit, which switches off or on again for a brief interruption of the power supply in the AC part of the switchable output ( 21 ).

It is also equivalent to control the shutdown or reclosure in the power supply module ( 1 ) in a known manner by means of a network-modulated signal.

Figs. 5, 6 and 7 show an exemplary embodiment of a lamp module (2) or (13).

The two 5-pin terminal strips ( 18 ) each have two connections (L) on the end faces ( 15 ) to which the heating filaments of the fluorescent lamps ( 6 ) are connected via lines ( 11 ) and ( 12 ). The terminals ( 8 ), ( 22 ) and ( 23 ) of the left end surface ( 15 ) are connected to the corresponding terminals of the right end surface ( 15 ) in order to be able to connect further lamp modules. The converters ( 24 ) lie on the terminals ( 22 ) or on the minus pole ( 8 ), as shown in FIG. 7.

The terminals ( 23 ) are used only for the through connection in the lamp module and have no connection and function in the lamp module ( 2 ) itself.

The advantageous symmetrical arrangement of the non-switched output ( 20 ) and the switched output ( 21 ) around the negative pole ( 8 ) allows in the manner shown in Fig. 1 the simple possibility of switching a lamp module or unswitched via the DC lines ( 4 ) or ( 5 ) by swapping them.

However, further features according to the invention emerge from FIGS. 2 to 7:
So z. B. the assembly shown in a profile ( 7 ), in which end faces ( 15 ) with the power terminals ( 25 ) or the DC terminals ( 26 ) are inserted. A simple housing ( 16 ) encloses the components of the power supply module ( 1 ).

Since the power supply modules ( 1 ) are required for different outputs, the size of the power supply module can be adapted to all requirements using the end faces ( 15 ) and by extending the housing ( 16 ) or the profile ( 7 ).

The situation is different for lamp modules ( 2 ) and ( 13 ) or other lamp modules, all of which are identical in their design. Therefore, such a module, as shown in Fig. 5 to 7 Darge, from a single plastic housing ( 19 ), which also carries the 5-pin terminal strips ( 18 ). This Ge housing ( 19 ) can be inserted into a profile ( 7 ), so that - if desired - a power supply module ( 1 ) and a lamp module ( 2 ) can be arranged on a common profile ( 7 ) with mounting holes ( 17 ).

According to the invention, the number of lamp modules ( 2 ) to be supplied is increased by connecting power supply modules ( 1 ) in parallel. For this purpose, it is proposed according to the invention to decouple the DC outputs of the power supply modules from one another by the arrangement of diodes ( 32 ), as in FIG. 6 with the schematically illustrated module ( 30 ) for decoupling and switching off.

Fig. 8 shows a circuit example, which has the further advantage that according to the invention the use of 2 power supply modules and the group switching of the lamp modules, as in Fig. 1, is possible. It is possible to select a normal or economy circuit by switching on the power supply module ( 1 ) or ( 27 ).

A simple example explains this idea:
It should B. Light strips with 12 lamps can be installed, of which only 4 or 8 should remain switched on in economy mode. The simple solution is to provide 2 power supply modules for 4 or 8 lamps and to connect 8 of the lamp modules to the DC line ( 5 ) and the remaining 4 lamp modules to the non-switched DC line ( 4 ).

Depending on your wishes, you can now switch on 4, 8 or 12 lamp modules, without increasing the installation effort.

The example is shown in FIG . The fluorescent lamps to be operated by the current supply module ( 1 ) are designated with (A), the fluorescent lamps to be operated by the power supply module ( 27 ) are designated with (B). Accordingly, the power supply module ( 1 ) for 8 lamps and the power supply module ( 27 ) would have to be designed for 4 lamps. As shown in Fig. 8, one could in such a case, all A modules with the DC lines ( 4 ) to the power supply module ( 1 ) and the DC line ( 5 ) could accordingly be connected to the power supply module ( 27 ). The negative pole ( 8 ) would be led to both power supply modules and passed through all lamp modules.

In order to obtain the appropriate distribution of the switched on and off lamp modules, it is sufficient to cross the DC lines ( 4 ) and ( 5 ) at the specified points. Crossing points are marked with ( 9 ).

If you close the power switch ( 34 ), all of the lamp modules labeled (A) would receive voltage from the power supply module ( 1 ) via the DC line ( 4 ), whereas only the DC line ( 4 ) would be carried out without the lamp modules (B) active influence.

Conversely, when the mains switch ( 35 ) is switched on, the power supply module ( 27 ) would be activated and the DC line ( 5 ) would receive voltage. Ie only lamp modules marked with (B) would be switched on actively.

If you want to put all 12 fluorescent lamps into operation, it is sufficient to switch on both power switches ( 34 ) and ( 35 ). If, on the other hand, you want an economy circuit with 8 lamps, only the power supply module ( 1 ) is switched on, if you want an extreme economy circuit, e.g. B. overnight, then the power switch ( 34 ) remains open and the power switch ( 35 ) is closed.

All these installations have in common that the mains voltage is only led up to the power supply modules and on closing by the direct current supply of the lamp modules kei is caused by all kinds of electrosmog.

A look at Fig. 8 is enough to recognize the enormous simplification and thus savings in installation effort.

The variety of possibilities is already evident from this example detect. It is irrelevant to the scope of the invention Lich, whether switching by hand or time-controlled or in other rer type is influenced depending on the program. For all of these reasons the above description cannot be considered complete be, but only to explain the much larger Scope of the invention.

Claims (9)

1. An electronic ballast for high-frequency operation of one or mains several fluorescent lamps from an AC, characterized in that, in a first power supply module (1) converting the alternating current into direct current and one or more light modules (2), only DC current is supplied via terminals is , And in these lamp modules ( 2 ) converters are available, converting the DC voltage into high-frequency AC voltage for operating the fluorescent lamps ( 6 ). 2. Electronic ballast according to claim 1, characterized in that in the power supply module ( 1 ) switching means for harmonic suppression (Power Factor Correction) are available. 3. Electronic ballast according to claim 1 or 2, characterized in that in the Stromversor supply module ( 1 ) switching means for stabilizing the rectified output voltage are available. 4. Electronic ballast according to claim 1, 2 or 3, characterized in that the same directional output voltage ent by a diode circuit is coupled.   5. Electronic ballast according to one or more of the preceding claims, characterized in that the rectified output voltage of the power supply module ( 1 ) is once directly available at connections and that at least one further connection is present, which can optionally be switched off. 6. Electronic ballast according to claim 5, characterized characterized that the interruption of the switchable output via a bistable flip-flop circuit takes place in the event of brief interruptions in the power supply tion in the AC section switches off the switchable output or switches on again. 7. Electronic ballast according to claim 5, characterized characterized that the shutdown or how switched on by a network-modulated signal. 8. Electronic ballast according to one or more of the preceding claims, characterized in that the lamp modules ( 2 ) have input and output connections, which allow the connection of the switched th and the non-switched DC voltage. 9. Electronic ballast one or more of the vorste existing claims, characterized in that the lamp modules ( 2 ) can be switched in series connection by simply interchanging the wire connections to switched or non-switched operation.