JPH0393193A - Lighting circuit for discharge tube - Google Patents

Abstract

PURPOSE:To perform the stable lighting control of multiple discharge tubes with one constant-current power source by connecting primary windings of all current transformers in series to the output current circuit of the constant- current power source, and connecting discharge tubes to secondary windings of current transformers respectively. CONSTITUTION:A discharge tube lighting circuit is constituted of many current transformers 3 connected with primary windings 4 in series to an inverter 1 which is a constant-current power source and n electric wire 2, and fluorescent lamps 6 are connected to secondary windings 5 of transformers 3 respectively. When a transformer 3 is magnetically saturated and the high pulse voltage is induced in its winding 5 and a fluorescent lamp 6 starts discharging, the load impedance of the corresponding transformer 3 is lowered, a constant current corresponding to the rated discharging current flows in the winding 5, the terminal voltage is dropped to the discharging voltage of the fluorescent lamp 6 and stabilized. All fluorescent lamps 6 likewise start discharging in sequence in a short time, and the discharging current after lighting becomes the constant current. Stable lighting control can be performed.

Description

[Detailed description of the invention]

Field of Industrial Application 1 This invention relates to a discharge tube lighting circuit for lighting a plurality of discharge tubes using one constant f2 current power source.

[Conventional technology]

Conventionally, there is no known device that controls the lighting of a plurality of discharge tubes at the same time using one constant current power source. Since the discharge characteristic of a discharge tube is negative resistance, it is necessary to perform current control other than control during lighting. Therefore, in a fluorescent lamp lighting circuit, a ballast consisting of a choke coil is installed in series with the fluorescent lamp. III so that the current value after lighting is constant! IL, I'm there. However, choke coils have a large number of thin conductor wires wound around them to increase inductance and have a large resistance value, so there is a large ohmic loss in the choke coil, and there is also iron loss in the core.
Power loss in the ballast accounts for 30% of the total power consumption of fluorescent lights.
Furthermore, since all of this loss is converted into heat, the ballast generates a large amount of heat.

[Problem to be solved by the invention]

The purpose of this invention is to eliminate power consumption and heat generated by a ballast without using a ballast, and to
An object of the present invention is to provide a discharge tube lighting circuit capable of efficiently and stably lighting or controlling a discharge tube using one constant current power source. Means for Solving Problems] In order to achieve the above object, the discharge tube lighting circuit of the present invention includes a constant current power source of 1II, a primary winding, and a secondary winding whose number of turns is much larger than that of the primary winding. The primary windings of all current transformers are connected in series to the output current circuit of a constant current power supply, and the discharge tubes are connected to the secondary windings of each current transformer. That's what I do.

[Effect 1] Before the discharge tube starts discharging, no load current flows through the It current transformer to which the discharge tube is connected, so the current transformer is magnetically saturated and a pulse-like high voltage is applied to its secondary winding. When the discharge tube starts discharging due to this induced voltage, a constant current determined by the turns ratio flows through the secondary winding, and the discharge tube continues to stably discharge. K*Embodiment An embodiment of the present invention will be described with reference to the drawings. The radiator I tube lighting circuit includes an inverter 1 which is a constant current power supply connected to a commercial lithium source, an electric wire 2 which is an output current circuit of the inverter 1, and a large number of, for example, 2 to 8 inverters, each having a primary winding 114 connected in series to the electric wire 2. ] consists of current transformers 3, and a fluorescent ffi6 is connected to the secondary winding 1i15 of each current transformer 3, respectively. The inverter 1 outputs a constant current of (for example) 20 KHz, IOA to the output current circuit IIA2, and its conversion efficiency is extremely high and the loss is almost negligible.The output frequency of the inverter 1 is from this Even if it is low (
For example, even at a commercial frequency), it is possible to implement the II current transformer extremely small, which is advantageous in making the device compact. The electric current lI2 can be made sufficiently long. For example, it is also possible to provide only 11 inverters 1 in one room and connect all the fluorescent fi6 in the room to the output current circuit '1112. Each current transformer 3 has a primary winding ring 4 and a secondary winding 1 on an annular iron core or a ferrite core on which amorphous boards are laminated.
It has the characteristic of being magnetically saturated with a relatively weak magnetomotive force. The primary winding of each current transformer 3 [
14 has a small number of turns (for example, 1 to 10 turns), and the failure of the secondary winding 1115 is much larger than that of the primary winding (for example, 100 to 1000 turns), and its turns ratio is Fluorescence! It is set according to the rated discharge current of t6. If fluorescent lights with different ratings are mixed,
The winding ratio of each connected current transformer 3 may be changed as appropriate according to the rated discharge current. The fluorescent light 1t6 is commercially available (7 to 40 WPi! degree), and one terminal of each of the two heaters 7 is connected to both terminals of the secondary winding 5 of the current transformer 3, and the other terminal of the heater 7 is connected to both terminals of the secondary winding 5 of the current transformer 3. A condenser gC is connected between them. Although it is possible to carry out the present invention without connecting the capacitor C, it has been experimentally confirmed that by providing the capacitor C, it becomes easier to light up the fluorescent lamp K16 and the noise exerted on peripheral equipment is reduced. Next, the operation at the time of lighting will be explained. When flii[ is inserted, none of the fluorescent ffi6 is discharging at first, and the load of each current transformer 3 is a series circuit of two heaters 7 and capacitor C, so the impedance of this circuit is fluorescent! 1 of 26 discharge impedances
If it is set to about 0 times or more, the current transformer 3 will be magnetically saturated and a high pulse-like voltage will be induced in its secondary winding 5. Then, due to this high voltage, a certain fluorescence f
! ! 6 starts discharging, the load impedance of the corresponding current transformer 3 decreases, and a constant current corresponding to the rated discharge current, which is the primary current multiplied by the turns ratio, flows through the secondary winding I15, and its terminal voltage increases. It stabilizes when the voltage drops to the discharge voltage of fluorescent ffi6. Similarly, all the fluorescence ffi6 start discharging one after another within a short period of time. The discharge current of each fluorescent lamp 6 after lighting becomes a constant current corresponding to the rated discharge current determined by the unique turns ratio of the connected current transformer 3, so its operation is extremely stable. Although fluorescent lamps are used in the above embodiments, the present invention is not limited to this, and other discharge lamps such as neon lamps may also be used. Effects of the Invention 1 As explained above, unlike conventional devices, the discharge tube lighting circuit of the present invention does not use a ballast, so there is no power consumption in the ballast, so the power efficiency is extremely high. There is no heat generated from the stabilizer, and there is very little heat generated from constant current power supplies, etc., so the overall power efficiency including the cooler in pill power design can be significantly improved.
Since it is a current control system, the operation is extremely stable and control is easy. Multiple discharge tubes with different rated discharge currents can be stably controlled by a single constant current power supply by simply changing the turns ratio of the current transformer. Moreover, even if the discharge tubes are placed apart from each other, lighting can be controlled by a single constant current power supply, which has the unique effect of reducing the installation space of the entire device. .

[Brief explanation of drawings]

The figure is a circuit diagram of one embodiment of the invention. 1... Inverter 2... Electric wire 3... Current transformer 4... Primary winding 5... Secondary winding 1116... Fluorescent light 7... Heater

Claims (1)

[Claims] Consisting of (a) one constant current power supply, and (b) a plurality of current transformers each having a primary winding and a secondary winding with a much larger number of turns than the primary winding, (c) A discharge tube lighting circuit characterized in that the primary windings of all current transformers are connected in series to the output current circuit of a constant current power supply, and discharge tubes are respectively connected to the primary windings of each current transformer.