JPH0633675Y2 - Fluorescent light inverter device - Google Patents

Description

[Detailed description of the device]

[Industrial field of application] The present invention relates to a fluorescent lamp inverter device, and more particularly to a fluorescent lamp inverter device that can be automatically turned on again when it goes out. [Prior Art] A conventional fluorescent lamp inverter device is disclosed in, for example, JP-A-61-29669
Those disclosed in Japanese Patent Laid-Open No. 5 and Japanese Patent Laid-Open No. 61-218095 are known. In the former case, the operating frequency of the separately excited inverter circuit is periodically switched alternately to the first frequency and the second frequency by the control circuit including the V / F conversion circuit, the variable resistor, the oscillation circuit and the drive circuit. In this way, the first frequency is configured to change by adjusting the variable resistor, and the discharge lamp is dimmed by adjusting the first frequency. The second frequency is a fixed frequency near the series resonance frequency of the inductor L and the capacitor C, and a high voltage is applied across the discharge lamp even when the dimming becomes deep and the discharge lamp goes out. To re-ignite, and to maintain lighting. In the latter, the switching frequency is set to a first frequency apart from the resonance frequency of the series resonance circuit in the first period, and is set in the second period other than the first period after the re-ignition of the discharge lamp. Discloses a discharge lamp lighting device that includes a control circuit that sets the switching frequency to a second frequency close to the resonance frequency of the series resonance circuit, and that makes the ratio of the first and second periods variable.

[Problems to be solved by the device]

Since both of the above-mentioned conventional types are configured to periodically output two types of frequencies, a first frequency and a second frequency, for example, a plurality of fluorescent lamps having slightly different resonance frequencies are connected. In the case of a fluorescent lamp in a showcase, or when the ambient temperature is low and the frequency at the time of re-ignition deviates from the fluorescent lamp in the normal atmosphere, the fluorescent lamp that has extinguished after being turned on must be reliably turned on again. It is difficult to get it done. Therefore, even when a plurality of fluorescent lamps having slightly different resonance frequencies are connected, or even when the fluorescent lamps are mounted in the showcase, the fluorescent lamps that have gone out after being turned on can be reliably re-lighted. Therefore, a technical problem to be solved in order to solve the above problem arises, and an object of the present invention is to solve the problem.

[Means for Solving the Problems]

This invention has been proposed in order to achieve the above-mentioned object, and a fluorescent lamp is connected to a fluorescent lamp inverter device via a resonance circuit composed of a choke coil and a capacitor, and the fluorescent lamp inverter device is provided with a control circuit section. In a fluorescent lamp inverter device configured to provide a modulating circuit, the modulating circuit modulates an oscillation frequency of an oscillating circuit, and the resonant frequency of the resonant circuit appears in a constant cycle in an output current of the fluorescent lamp inverter device. , A preheating circuit is provided in the control circuit section of the fluorescent light inverter device, and when the power is turned on, the preheating circuit operates to make the frequency of the output current of the fluorescent light inverter device higher than the resonance frequency, and
After the power is turned on, the modulation circuit modulates the oscillation frequency of the oscillation circuit to change the frequency of the output current of the fluorescent lamp inverter device at a constant cycle and within a predetermined range including the resonance frequency. The present invention provides a fluorescent lamp inverter device.

[Action]

The frequency of the output current changes linearly in a predetermined range including the resonance circuit at a constant cycle. Therefore, when a plurality of fluorescent lamps having slightly different resonance frequencies are connected, or the fluorescent lamp is installed in the showcase, and the ambient temperature of the fluorescent lamp is low, the frequency during re-ignition is usually Even if the fluorescent lamp is deviated from the atmosphere, the fluorescent lamp that has gone out after being turned on is surely turned on again. Furthermore, since the control circuit section has a preheating circuit, when the power is turned on,
The preheating circuit operates to make the frequency of the output current of the fluorescent lamp inverter device sufficiently higher than the resonance frequency. Therefore, as described above, even when the fluorescent lamp is installed in the showcase, or even when the ambient temperature is low in the winter, the preheating circuit operates, and the fluorescent lamp is preheated in advance when the fluorescent lamp is turned on. Therefore, the fluorescent lamp can be reliably turned on, and the fluorescent lamp can be stably turned on even when the ambient temperature is low. [Embodiment] An embodiment of the present invention will be described below in detail with reference to the attached drawings. For convenience of description, technical matters that are conventionally known will be described at the same time. Figure 1 shows a fluorescent lamp inverter device (1).
3 is a circuit diagram showing the configuration of FIG. In the figure, (2) is a power line of a general commercial power source, which is AC100V or AC200V (50 / 60H
z). The fluorescent light inverter device (1) is provided by a noise filter (3) provided at the power input stage.
It prevents the switching noise generated inside the power transmission line (2) from being propagated. Further, (4) is a rectifying diode for the power source, and (5) is a smoothing capacitor for the power source. On the other hand, the lower power transformer (6) supplies power to the control circuit section (7) of the fluorescent lamp inverter device (1). The power supply circuit (8) of the control circuit unit (7) converts AC into DC and supplies it to other circuits. Then, the preheating circuit (9) controls the oscillation circuit (10), the modulation circuit (11) and the waveform shaping circuit (12) to start lighting when the power is turned on. The oscillating circuit (10) oscillates a fundamental frequency and alternately performs a power MOS FET (13) (14).
In order not to be turned on at the same time, the pause time is set so that both are turned off when the operation is changed. In this embodiment, the rest time is set to 1 to 2 μs. The modulation circuit (11) modulates the oscillation frequency of the oscillation circuit (10) so that the fluorescent lamp (15) described later is automatically turned on again when it goes out. The waveform shaping circuit (12) is a power MOS FET (13) (14).
The ratio of the “on” time of both is set to 1: 1 and the rest time is inserted. The gate drive circuit (16) at the next stage of the waveform shaping circuit (12) converts the current into a proper waveform and impedance for the power MOS FET (14) and applies a voltage to the gate (17). The pulse transformer drive circuit (18) has the same function as the gate drive circuit (16) and operates the pulse transformer (19). The pulse transformer (19) insulates the gate (20) of the power MOS FET (13) from the control circuit section (7) and transmits the voltage waveform required for driving the gate (20). And (21) (22)
Is an overcurrent protection circuit, power MOS FET (13) (14)
The purpose is to prevent the destruction of. Further, the output noise filter circuit (23) reduces switching noise and protects the power MOS FETs (13) (14) from noise intruding from the outside. Further, (24) is a DC blocking capacitor, which requires a capacitance that does not affect the resonance frequency of the resonance circuit (25) described later, and therefore is about 1 μF to 10 μF due to the impedance of the load. Thus, the output terminals (26) (27) have a plurality of fluorescent lamps (15).
(15) ... Can be connected and are connected to the resonance circuits (25) (25) .. The resonance circuits (25) (25) ... connect the filaments (28) (29) of the fluorescent lamps (15) (15) ... to one side through capacitors (30), and the other side of the filaments (29) Chiyoke coil (3
It is connected to the output terminal (27) via 1). And
The other side of the filament (28) is connected to the output terminal (26). Also, even if the connections of the output terminals (26) and (27) are exchanged, there is no problem in lighting. The capacitor (30) causes a preheating current to flow through the filaments (28) (29) at the start of lighting, and generates a high voltage at the start of discharge due to the resonance phenomenon with the chioke coil (31). In addition, the chiyoke coil (3
In 1), the discharge current is kept constant during stable lighting to prevent the filaments (28) (29) from burning. A large number of the resonance circuits (25) can be connected in parallel to the output terminals (26) and (27) by a power source capacity. The type of fluorescent lamp (15) can be applied regardless of the number of Watts as long as it is a starter lamp for general lighting. When using fluorescent lamps with different numbers of watts together in one fluorescent lamp inverter device (1), set the values of the capacitor (30) and chioke coil (31) that match the number of watts of the fluorescent lamp used, It can be used by matching the resonance frequency with the set resonance frequency of the fluorescent lamp inverter device (1). Resonance frequency _R is the capacity of the capacitor (30)
Let C ₁ and the inductance of the chioke coil (31) be L Then, when the fluorescent lamp inverter device (1) is powered on, the preheating circuit (9) controls the oscillation circuit (10), the modulation circuit (11) and the waveform shaping circuit (12), and the second It operates to produce the output shown in the figure. During the period T ₁ after the power is turned on, the filaments (28) (29) are preheated by the frequency _O which is sufficiently higher than the resonance frequency _{R so} that the filaments (28) (29) do not glow red. The At a this embodiment _O is 90~110KHz, T ₁ is set at approximately 2 seconds. Next, the frequency shifts to T ₂ and the frequency is lowered while preheating the filaments (28) (29) to the extent that they glow red.
When it becomes _R , a voltage oscillation phenomenon occurs in the resonance circuit (25), a high voltage is generated, and the fluorescent lamp (15) starts discharging. After that, in consideration of the variation in the resonance frequency _R of the resonance circuit (25), the frequency shifts to a further lower frequency _L and stable lighting is performed. This T ₂ is about 1 second and _R is 55 ~ 65KH
z and _L are set to 30 to 45 KHz. The output waveform during stable lighting is shown in FIG. The fundamental frequency is described above
_L is a modulation circuit (11) at regular intervals T _S (2 to 3 ms).
Generates _S close to the resonance frequency _R. This modulation allows the fluorescent lamp (15) to be turned on again when it goes out. That is, the equivalent resistance R _K of the fluorescent lamp in the stable lighting state (15), for example because it is 100~200Ω and small in FL20S type, _S = never voltage resonance also occurs shall apply in _R. When the fluorescent lamp (15) goes out, R _K disappears,
The equivalent resistance value of the fluorescent lamp (15) is close to the tube wall resistance MΩ.
Since it becomes a stand, a current flows through the resonance circuit (25) to cause resonance, a high voltage is generated, and the light is turned on again. Further, since this _S does not appear continuously, it does not reduce the life of the fluorescent lamp (15). Further, the fluorescent lamp inverter device (1) can also cope with extinction in a state where the illuminance is reduced by the dimming switch (32). In FIG. 1, when the dimming switch (32) connected to the modulation circuit (11) is switched, the output waveform is modulated by the modulation circuit (11) as shown in FIG. The degree of dimming is determined by the frequency of _C. This is due to the action of the cheek yoke coil (31). Since _C is higher than _L shown in FIG.
The current limiting function of 1) works and the fluorescent lamp (15) becomes dark. Uni _C to accommodate when goes out in this state, it is necessary to set the close or _C in _R a higher frequency than _R. This is because the frequency fluctuates between _C and _e having a frequency lower than _{C. The} reason for providing _e is that it is better for the lighting performance of the fluorescent lamp (15) to change the frequency. This is because Then, when the fluorescent lamp (15) is stably lit, even if _C has a frequency close to _R , the resonance phenomenon does not occur in the resonance circuit (25) as described above, and the resonance phenomenon occurs only when the fluorescent lamp (15) goes out. ) Lights up again. It should be noted that the present invention can be variously modified without departing from the spirit of the present invention, and it goes without saying that the present invention extends to the modified version. [Effects of the Invention] As described in detail in the above-described one embodiment, the present invention changes the frequency of the output current of the fluorescent lamp inverter device at a constant cycle,
Moreover, the frequency of the output current changes in a range including the resonance frequency, and the resonance frequency of the resonance circuit appears in the output current in a constant cycle. It linearly changes within a predetermined range including the resonance frequency. Thus, when multiple fluorescent lamps with slightly different resonance frequencies are connected, or because the ambient temperature is low like the fluorescent lamp in the showcase, the frequency of re-ignition is less than that of a fluorescent lamp in a normal atmosphere. Even in the case of deviation, it is possible to reliably relight the fluorescent lamp that has gone out after lighting. Further, since the control circuit section is provided with the preheating circuit, the preheating circuit operates when the power is turned on, and the frequency of the output current of the fluorescent lamp inverter device can be made sufficiently higher than the resonance frequency. Therefore, for example, when a fluorescent lamp is provided in a showcase, or even when the ambient temperature is low in the winter season, the fluorescent lamp is preheated by the operation of the preheating circuit so that the fluorescent lamp is preheated and reliably turned on. Therefore, it is possible to stably maintain the lighting of the fluorescent lamp even when the ambient temperature is low.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows an embodiment of the present invention, FIG. 1 is a circuit explanatory diagram of a fluorescent lamp inverter device, FIG. 2 is an explanatory diagram showing an output waveform at the start of lighting, and FIG. FIG. 4 is an explanatory view showing an output waveform during normal stable lighting, and FIG. 4 is an output waveform during dimming. (1) …… Fluorescent lamp inverter device (7) …… Control circuit part (8) …… Power supply circuit, (9) …… Preheating circuit (10) …… Oscillation circuit, (11) …… Modulation circuit (12) ...... Waveform shaping circuit, (15) …… Fluorescent lamp (24) …… DC blocking capacitor (25) …… Resonance circuit, (26) (27) …… Output terminal (28) (29) …… Filament, (30) …… Capacitor (31) …… Choke coil, (32) …… Dimming switch

Claims (1)

[Scope of utility model registration request] 1. A fluorescent lamp is connected to a fluorescent lamp inverter apparatus via a resonance circuit composed of a choke coil and a capacitor, and a modulation circuit is provided in a control circuit section of the fluorescent lamp inverter apparatus. In a fluorescent lamp inverter device configured to modulate the frequency so that the resonance frequency of the resonant circuit appears in a constant cycle in the output current of the fluorescent lamp inverter device, a preheating circuit is provided in a control circuit section of the fluorescent lamp inverter device. When the power is turned on, the preheating circuit operates to make the frequency of the output current of the fluorescent lamp inverter device higher than the resonance frequency, and after the power is turned on, the modulation circuit modulates the oscillation frequency of the oscillation circuit. It is configured to change the frequency of the output current of the fluorescent lamp inverter device at a constant cycle and within a predetermined range including the resonance frequency. Fluorescent lamp inverter apparatus characterized by.