NL8301767A - LOW-VOLTAGE LIGHT BULB WITH PRESSURE CAPACITOR. - Google Patents

Description

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P&C

General Electric Company

Title: Low voltage incandescent lamp with ballast capacitor.

The present application is related to U.S. patent applications 379,410, 379,412, and 379,393.

The invention relates to a ballast and in particular to a capacitive ballast which supplies a low voltage to an incandescent lamp.

As is known, incandescent lamps operating at a nominal voltage of about 120V have a lower efficiency, i.e. less lumens per watt, at the same power as incandescent lamps operating at lower voltages. Known circuits that enable such low voltage operation have an undesirable cost, size, weight or level of electromagnetic disturbance. In particular, some known low voltage power supplies for incandescent lamps use magnetic components for voltage conversion.

The cost of such magnetic components makes such power supplies less attractive economically. Other power supplies use phase control techniques, which require very narrow pulses so that high peak currents flow through the load and often cause electromagnetic interference and reduced reliability.

As disclosed in US patent application 379,412, an incandescent capacitor incandescent lamp, wherein a main capacitor is connected in series with an incandescent lamp load and one or more auxiliary capacitors are electrically connected in parallel to the main capacitor, herein contemplates difficulties. However, the switch member, such as a triac, which is described there and which electrically connects each further capacitor in parallel to the main capacitor, has several drawbacks, including a high cost and a lower maximum operating temperature than is desirable.

The object of the invention is to provide a switching element for a low-voltage incandescent lamp with ballast capacitor at a relatively low cost price and a relatively high maximum operating temperature.

These and other objects are achieved according to the invention with a switching means that electrically switches one or more auxiliary capacitors in parallel with a main capacitor, as described in U.S. patent application 379,412. Each switching member includes a unidirectional conducting member electrically parallel to an active switching device, each combination thereof electrically in series with an auxiliary capacitor. Furthermore, each active switching device according to a preferred embodiment responds to a signal supplied by a control logic.

The Figure is a schematic of a low voltage bias lamp with bias 40 capacitor according to the invention.

8301 767 -2-

As shown in the Figure, a ballast 10 supplies power to a load 11, preferably an incandescent lamp, from an AC voltage source 12 by controlling the current supplied to the load 11 from the AC voltage source 12. The load 11 may consist of a low voltage light bulb that works at a voltage of, for example, between 24V and 36V. The ballast 10 allows the lamp load 11 to operate at an adjustable fixed output power in a relatively narrow brightness range. In such an application, a relatively narrow range of lamp voltages 10 can be maintained, while the current from the AC voltage source 12 varies over a predetermined range, e.g., about 20%.

The ballast 10 forms a capacitive voltage converter in which a minimal current through the lamp consists of the current flowing through the capacitor C1 hereinafter referred to as the main capacitor. A further component of the lamp current is caused by the current flowing through one or more capacitors C2 hereinafter referred to as the auxiliary capacitors. The minimum lamp current and the minimum lamp power therefore occur when no current flows through the auxiliary capacitors C2, i.e. when the capacitive impedance of the ballast 10 is a maximum of 20. Conversely, the maximum lamp current and the maximum lamp power occur when the capacitor current I ^ flows through all auxiliary capacitors C2, causing a minimum capacitive impedance of the ballast. An intermediate value of the lamp current and the lamp power is obtained when the current I2 flows through some, but not all, auxiliary capacitors C2.

Therefore, by changing the number of auxiliary capacitors parallel to the main capacitor C1, the lamp current and lamp power can be adjusted. >

The AC voltage source 12 and the lamp 11 are electrically connected to the terminals 13-14, respectively. 15-16. Capacitor C1 is connected between terminals 13 and 15. For each auxiliary capacitor C2 there is a switching means 17 electrically connected between terminal 15 and one end of each auxiliary capacitor C2. The other end of each auxiliary capacitor C2 is connected to terminal 13. Terminals 14 and 16 are electrically connected directly.

Each switching member 17 provides a low resistance bi-directional current path between the terminal 15 and that end of each auxiliary capacitor C2 facing away from the terminal 13. The switch member 17 comprises a unidirectional conducting device 18, i.e. a rectifier such as a diode, electrically parallel to an active switching device 19.

The active switching device 19 can be any active component that electrically conducts 40 in the opposite direction if the unidirectional conducting device 18, 8301767 -3- or conducts both directions. The active switching device 19 is preferably made conductive and non-conductive in response to the control signal from a control logic 20, and such a control logic is known. Each active switching device 19 may consist of, but is not limited to, a thyristor 21 or a transistor such as a reverse layer transistor or field effect transistor 22.

In order to prevent undesired phenomena and limit the current through each switching device 17, each switching device 17 is preferably switched on by the control logic 20, only if the voltages V1 and V2 across the main capacitor and the auxiliary capacitors are approximately equal and / or at approximately the maximum voltage of the waveform of the alternating voltage generator 12, so that any loop currents through the auxiliary capacitors C2 and the main capacitor C1 are substantially suppressed-

Furthermore, any switching means 17 containing a transistor as an active switching device 19 can operate at a temperature of at least 130 ° C, compared to known embodiments, such as triacs, which have a maximum operating temperature of 100 ° C. A typical triac becomes conductive at a temperature of about 100 ° C, and remains conductive in the absence of a gate signal, rendering its operation unacceptable.

As previously described, the invention provides a ballast 10 that controls the power supplied to the light bulb 11 by varying the capacitance electrically in series therewith. The total capacitance electrically in series with the incandescent lamp 11 is equal to the parallel connection of the main capacitor C1 and all auxiliary capacitors C2, the switching member 17 of which is conductive. Therefore, by varying the number of auxiliary capacitors C2 of which the switching member 17 is conducting, the total capacitance in series with the incandescent lamp can be varied, thereby obtaining a ballast 10 which controls the power supplied to the incandescent lamp 11 and thereby the temperature of the filament of the lamp 30.

Furthermore, each switching means 17 may parallel or disconnect an auxiliary capacitor from the main capacitor during one or more complete periods of the waveform of the AC voltage source 12.

It should also be noted that the auxiliary capacitors C2 can each have the same capacity or different capacities. Each auxiliary capacitor can also be switched independently of any other auxiliary capacitor. According to a preferred embodiment, the main capacitor C1 has a capacitance of about 25pF, the total auxiliary capacitance is 25 µF, the AC voltage source 12 has a voltage of about 120V at 60Hz and the lamp 40 operates at about 36V, 60W. The number of auxiliary capacitors electrically connected 8301767 -4- to. the main capacitor C1 and the capacitance of each capacitor may vary according to a number of factors, including the voltage of the AC voltage source 12, the desired lamp current, the desired lamp brightness, the desired lamp operating voltage, and the like.

The device as described here is therefore able to compensate for voltage variations of the AC voltage source. As the voltage of the AC voltage source 12 increases or decreases, the auxiliary capacitance C2 can be reduced or decreased. to obtain a substantially constant current or power 10 or both from the lamp 11.

Furthermore, the lamp current, the lamp power and the lamp bright hero can be adjusted manually as well as automatically by means of the active switching devices 19. It is clear that a control logic 20 can be applied in which a negative feedback signal is applied e.g. to the gate 15 of a thyristor or field-effect transistor to make the active switching device conductive or non-conductive and thereby set automatic total capacitance between terminals 13 and 15. Such a feedback signal can, for example, react to the current through the load 11.

Also, as described in U.S. Patent Application No. 20,379,412, by the use of a capacitive ballast supplying a lower voltage to the lamp 11, it is possible to avoid undesirably high levels of electrical interference, such as occur in known embodiments.

In contrast to the embodiment according to US patent application 379,412, a device according to the invention can be manufactured at a low cost and when a transistor is used as the active switching device, the maximum operating temperature can be higher.

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Claims (10)

Control gear for controlling the power supplied from an alternating voltage source to an incandescent lamp at a voltage lower than the voltage of the alternating voltage source, characterized by: i (a) a first capacitive component electrically in series with the lamp is connected across the input terminals of the ballast? (B) one or more auxiliary capacitive components; and (c) a switching means for electrically connecting each of the auxiliary capacitive components to the first capacitive component for one or more full periods of an AC source waveform, each auxiliary capacitive component being connected in series with a switching means one-way conducting device electrically connected in parallel to an active switching device. 2. Ballast according to claim 1, characterized in that the unidirectional conducting device is a diode. Ballast according to claim 1, characterized in that each active switching device consists of a thyristor, a reverse layer transistor or a field effect transistor. Ballast according to claim 1, characterized in that each active switching device is made conductive and non-conductive in response to a control signal. Ballast according to claim 4, characterized in that the control signal depends on the current through the incandescent lamp. 6. Ballast according to claim 1, characterized in that the switching members are switched independently of each other. Ballast according to claim 1, characterized in that at the time when each capacitive auxiliary element is electrically connected in parallel to the first capacitive element, the voltage across all capacitive auxiliary elements which are electrically connected in parallel to the first capacitive component is approximately is equal to the voltage across the first capacitive component. 8. Ballast according to claim 1, with a transistor as active switching device, characterized in that the switching member can operate at a temperature of at least 130 ° C. 40 Ballast according to claim 1, characterized in 8301767 1 * * / --6 - that the incandescent lamp operates at about 36V and about 60Wf, the first capacitor having a capacity of about 25μΡ and one or more auxiliary capacitors having a total capacity of about 25μΡ, while the ~ 5 voltage from the alternating voltage source is about 120V at 60Hz. 10 15 20 '25 30 35 40 830 1 76 7