TH45101B - Starters for gas-discharge light sources - Google Patents

Abstract

DC60 starters for gas-discharge light sources are designed to measure Initial resistance of one or more filament fibers of a gas-discharge light source, such as a fluorescent lamp. Each time a gas-fired light source is powered Started via ballast The starter may start a pre-heating cycle to make the filament One or more lines are hot. The duration of the preheating cycle may be optimized. Automatically by a starter on the basis of initial resistance and thermal resistance. The target is calculated by the starter on the basis of the initial resistance. The duration of the cycle Preheating may be automatically optimized by a starter to provide reliability and The life of a gas-discharge light source is optimal. Starters for gas-discharged light sources are designed to measure the The initial resistivity of one or more filaments of a gas-discharge light source, such as a fluorescent lamp. Each time a gas-fired light source is powered Started via ballast The starter may start a pre-heating cycle to make the filament One or more lines are hot. The duration of the preheating cycle may be optimized. Automatically by a starter on the basis of initial resistance and thermal resistance. The target is calculated by the starter on the basis of the initial resistance. The duration of the cycle Preheating may be automatically optimized by a starter to provide reliability and The life of a gas-discharge light source is optimal.

Claims (5)

1.Starters for gas-discharged light sources are included. The current sensor is designed to measure the current flowing through a light source's filament. A gas discharge type and a processor designed to be connected to a current sensor and a filament where the processor can operate to receive current indication from the current sensor. And the pressure of the filament processor that can be worked to calculate the cold resistance of the filament. By indicating the current and voltage each time a gas-fired light source is energized for the first time, the processor can continue to work to pre-heat the filament for a period of time that can Determinable by the processor on the basis of the calculated cold resistance 2. Starter according to claim 1, where the filament is assembled with the filament. The first and the second lines And the starter also consists of a switch that is connected between the filaments The first and second lines and with the processor. Switches can be controlled with a processor that will Is turned off when a discharged light source is first energized to preheat. First and second filament And will be closed after the specified time on the basis of Calculated cold resistance 3. Starter according to claim 2, where the first and second filaments are They are designed to be wired in series with each other and the power source when the switch is switched off and designed to be electrically connected in series with the power source via a plasma present in The light source discharges when the switch is turned on. 4. Starters according to claim 1, where the processor can also work to calculate The heat resistance of the filament line is specific to a gas-fired light source on a basis Of the calculated cold resistance And turn on the switch when the resistance of the filament One and at least one of the lines is greater than or equal to the thermal resistance of the line. Calculated filament 5. Starter according to claim 4, where the processor can also work to compute the The measured resistance of at least one first and at least one strand of filament on the basis of A repetitive current signal and pressure to pre-heat the filament as A period of time which can be determined on the basis of the resistance being measured equal or greater. The thermal resistance of the filament was calculated. 6. Starter according to claim 4, where the processor can also work to measure the time to arrive. The thermal resistance of the filament was calculated. And can also work to arrange pointing Shown when the time required to reach the calculated filament heat resistance exceeds 7. Starters according to claim 1, where the starter is also integrated inside the molded housing. At least part of the gas-fired light source. 8. Starter according to claim 1, where the filament can be supplied with the source. Alternating current power And the processor can also operate to randomize voltage and current at a rate that at least As much as two times the frequency of an alternating current source. 9. Method of starting a gas-discharge light source. The method consists of energizing a gas-fired light source with a power source where the gas-fired light source includes the first and second filaments. Switch-off to connect the first and second filament fibers in series to each other and the power source. Calculation of cold resistance of first and second strands of filament. At least one line of a gas-fired light source each time the light source is discharged. First discharges in the energized gas. Pre-heating of the first and second filaments too The power source is a period based on the calculated cold resistance and the switch-on when the pre-heating is complete 1 0. Method according to claim 9, where the calculation of the cold resistance of the filament. Filament At least one of the first and second strands contains the pressure measurement of the filament. At least one first and at least one strand and the current passing through the first and second filaments. Second, at least one line. Then, 1 1. Method according to claim 9, where pre-heating of the filament fibers The first and second filaments contain pressure measurements of the first and second filaments. At least one strand and at least one current passing through the first and second filament. At the defined interval, when the temperature of the first and second filaments increases 1 2. Method of claim 11, where the source is an alternating current source. And the time interval is defined more than the frequency of the power source 1. 3. Method of claim 11, where the measurement of voltage also consists of calculating the resistance. At least one measured filament of the first and second filaments on Basis of measured current 1 4. Method of claim 13 where the calculation of cold resistance also consists of: Calculate the thermal resistance of the filament target, the norm of emission light source. The gas charge is based on a predetermined bulb resistance ratio. This is especially true for gas-discharging light sources and calculated cold resistance. 1 5. Method of claim 14 where switching on is combined with switching on when The filament resistance is measured to or exceeds the thermal resistance of the filament. Specific targets of the calculated gas-discharged light sources 1 6. Methods of claim 9 also consist of arc generation in light sources. Discharge the gas when the switch is turned on. 1 7. The method of claim 16 also consists of adjusting the timing on the basis of the Cold resistance calculated when arc failure Switching on for preheating the First and second filaments with power sources adjusted for the duration and switched on again after the preheating is complete. 1 8. Starters for gas-discharge light sources. That includes Memory device The command is stored in the memory device to turn off the switch that is wired between the optical fibers. The first and second layers are integrated in series discharge light sources with Source of power A command that is stored in a memory device to calculate the cold resistance of the line. At least one first and second filament, each time at the first filament. And the second is energized for the first time with a power source and commands stored in the memory device to switch on after the time set on Calculated cold resistance basis 1 9. Starters according to claim 18, where the command to calculate cold resistance will Includes instructions stored in the memory device to randomize the measured voltage of the filament. At least one of the first and second lines. And randomly the current measured through the filament that One and at least one second line to calculate cold resistance 2 0. Starters according to claim 18 that also contain instructions stored in the device. Memory to access the characteristic aspect ratio data stored in the memory device and calculate Thermal resistance of at least one first and at least one strand of filament on The basis of the desired pre-determined arc temperature of the first filament and At least one second line is stored in the memory device as well 2. 1. Starter according to claim 20 that also includes instructions stored on the device. Memory to calculate the measured resistance of first and second filaments. At least one line based on monitored current signal and monitored pressure signal. And to turn on the switch when the measured resistance is equal to or exceeds the calculated thermal resistance 2 2. Starter according to Clause 18, which also includes A command that has been stored in the memory device to turn it off again if the arc was not triggered. When the switch is turned on after a period Instructions that are stored in a memory device to increase the desired arc temperature at A preset that is also stored in the memory device and instructions that are stored in the memory device to turn on again after a period of time. The extension is determined on the basis of the calculated cold resistance and the The required arc as a preset has been increased by 2. 3. The starter according to claim 18 that also includes the instructions stored in the device. Memory to indicate when the switch has not been turned on within the preset period of 2 4. The starter according to claim 18 also includes the instructions stored in the device. Memory to keep the switch in the closed position to make the first and second filament Two ignited when the switch is not turned on within the preset time 2. 5. The starter according to claim 18, which also includes the instructions stored in the device. Memory to make the starter unable to operate when the switch has not been turned on for a period of Predetermined