KR20050048596A - Inverter circuit, fluorescent bulb operating device, backlight device, and liquid crystal display device - Google Patents

Abstract

Two inverter circuits each having a transformers are arranged at both ends of a fluorescent bulb for push- pull driving lighting. The feedback windings of the transformers of the respective inverters not used for self-excited oscillation are connected to each other and the transformers whose feedback windings are connected are connected by the same-phase connection or reverse-phase connection. According to the connection method, the connection method of the fluorescent bulb connected to the secondary windings of the transformers is modified, so that when a plurality of fluorescent bulbs are simultaneously driven in a fluorescent bulb operating device, it is possible to uniformly light the entire fluorescent bulb regardless of the length and number of the fluorescent bulbs.

Description

Inverter circuit, fluorescent tube lighting device, backlight device and liquid crystal display device {INVERTER CIRCUIT, FLUORESCENT BULB OPERATING DEVICE, BACKLIGHT DEVICE, AND LIQUID CRYSTAL DISPLAY DEVICE}

The present invention provides an inverter circuit for driving a driven body, a fluorescent tube lighting device for driving a fluorescent tube, a backlight device for providing uniform surface-shaped illumination using a fluorescent tube driving device, and light generated from the backlight device. The present invention relates to a liquid crystal display device capable of displaying an image by assigning a gray scale using a liquid crystal panel.

As a technical example of an inverter circuit which drives a driven member using this boost transformer, Japanese Unexamined Patent Application Publication No. 5-90897 discloses the following technique.

That is, as shown in Fig. 13, the conventional example is for a boost transformer 301a having a primary coil 309a, a secondary coil 305a, and a feedback coil 306, and a pair of push-pull drives. One inverter circuit 304a having transistors 302a and 303a, a boost transformer 301b having a primary coil 309b and a secondary coil 315b, and a pair of push-pull driving transistors 302b and 303b. The inverter circuit 301 of the structure which has the other inverter circuit 304b which has a structure, and uses the feedback coil 306 of the step-up transformer 301a for the self oscillation of the other inverter circuit 304b is described, An alternating voltage of opposite phase is applied between the secondary coil 305a and the secondary coil 305b connected to both ends of the fluorescent tube 307 by the inverter circuit 308.

The inverter circuit 308 of the conventional example described above uses only the feedback coil of the boosting transformer 301a provided in one inverter circuit 314a so that the phase of the output from the secondary coil of both boosting transformers is reversed. The feedback coil of one boost transformer is not used. In such a configuration, the phases of the voltages output from the secondary coils 305a and 306a of the two inverter circuits 304a and 304b cannot be stably reversed, so that driving is unbalanced, so that both ends of the fluorescent tube 307 are separated. It cannot be lit with uniform brightness.

That is, when the inverter circuit which controls the output voltage of the inverter circuit connected to the both ends of a to-be-driven body in the opposite phase is comprised by the prior art mentioned above, since the oscillation frequency which mutual inverter 304a, 304b has differs, , Phase difference occurs and oscillation becomes unstable. Therefore, there arises a problem that the potentials at both ends of the driven body cannot be stably reversed.

Therefore, in view of such a problem, the inverter circuit of the present invention aims to provide an inverter circuit in which the electric potential at both ends of the driven body is stably reversed and the power efficiency of the driven body is improved.

In addition, there is a fluorescent tube as described in the prior art as one driven using such an inverter circuit. It is preferable that the fluorescent tube is uniform in brightness from one end to the other end. However, if the fluorescent tube is turned on using the conventional technique, the phases at both ends do not become stable in opposite phase, and the luminance at both ends is not constant. The problem occurs as described above.

Accordingly, in view of such a problem, in the fluorescent tube drive device of the present invention, by unsteadily shifting the potential applied to both ends of the fluorescent tube, the unbalance of the luminance of the fluorescent tube is corrected and the light is emitted almost uniformly. Moreover, it aims at providing the fluorescent tube drive apparatus which the luminous efficiency of a fluorescent tube improves.

In addition, for example, a backlight device is used as a lighting device of a display device such as a transmissive liquid crystal display device. A fluorescent tube is mainly used as a light source of the backlight device. In such a backlight device, in order to prevent luminance unevenness from occurring on the display screen, uniform luminance is required over the entire screen. However, when the backlight device is driven using a conventional technique, since the voltage across the fluorescent tube cannot be stably reversed, the luminance at both ends is not constant, so that the luminance is uniform across the entire screen. It becomes difficult to get

Therefore, in view of such a problem, in the backlight device of the present invention, the potential applied to both ends of the fluorescent tube is stably reversed, thereby correcting the unbalance of the emission luminance at both ends of the fluorescent tube, and thereby emitting light with a uniform luminance as a whole. An object of the present invention is to provide a backlight device having a distribution and capable of having high light emission efficiency.

In addition, in the liquid crystal display device, it is required to stably assign the gradation to the entire display screen to provide precise image quality. There is a problem that it is difficult to provide.

Therefore, in view of such a problem, in the liquid crystal display device of the present invention, unbalanced light emission luminance at both ends of the fluorescent tube is achieved by stably shifting the potential applied to both ends of the fluorescent tube used for the backlight device of the liquid crystal display device. The present invention aims to provide a liquid crystal display device having a precise image quality and high luminous efficiency based on this, to obtain a uniform surface light emission as a whole.

<Start of invention>

In order to achieve the above object, in the inverter circuit provided with a pair of both ends of a driven body, the fluorescent tube lighting device of the present invention has a mutual inverter circuit such that the alternating current voltage across both ends of the driven body maintains an opposite phase relationship with each other. Is an indirectly connected means. The term &quot; indirectly connected &quot; means that the connection is not accompanied by the movement of a carrier (electron / hole) between the inverter circuits. Specifically, the method is exemplified for the connection between the inverter circuits using the inductive coupling effect represented by coils, transformers and the like.

In addition, the fluorescent tube lighting device of the present invention is the above-described "indirect connection" means, including (1) coupling of higher order coils not used for self-oscillation of mutual inverter circuits, (2) coupling of choke coils of mutual inverter circuits, and the like. It is characterized by using an inductive coupling of at least one coil in each inverter circuit represented by.

In addition, the fluorescent tube lighting device of the present invention is a means of the "coil inductive coupling", in (1) direct coupling, transformer intermediary coupling, parallel coil proximity bonding, etc., (2) transformer intermediary coupling, parallel coil proximity bonding, transformation It is characterized by using a coupling, a simple proximity junction.

In addition, the fluorescent tube lighting device of the present invention is characterized in that the drive of the mutual inverter circuit is in a reverse phase (the opposite phase between the inverters).

According to the configuration of any one of the fluorescent tube lighting devices described above, since the voltage applied to both ends of the driven object becomes stable in the opposite phase, it is possible to apply an alternating voltage of the opposite phase to the same frequency stable at both ends of the driven object. Done.

In addition, the fluorescent tube lighting device of the present invention is characterized in that, when each inverter circuit has two output terminals, the outputs of the respective inverter circuits are in opposite phase relationship (the opposite phase in the inverter).

Further, in the fluorescent tube lighting device of the present invention, as the method of the opposite phase between the inverters, 1) primary coils of two 1 input 1 output inverter transformers are mutually inverse, and 2 one of 1 input 2 output inverter transformers. The secondary coils are mutually inverse, and ③ in two one-input two-output inverter transformers, the secondary coils in the inverter transformer are mutually inverse, and the secondary coils between the inverter transformers are mutually inverse.

According to the configuration of any one of the above-described fluorescent tube lighting apparatuses, it is possible to cancel the electrical or magnetic noise generated in the core and the like by the transformer induction effect in each inverter circuit, and to eliminate the noise generated at both ends of the driven body. .

Here, heaters, such as a sheath heater and a nichrome heater, a fluorescent tube etc. can be used for a driven object. If any one of the inverter circuits is used for the sheath heater and the nichrome heater, since the heat generation state at both ends of the sheath heater can be equalized, it is excellent in use in a situation where a uniform heat generation state is required, and In the case where the inverter circuit is used for the fluorescent tube, since uniform light emission is obtained at both ends of the fluorescent tube, it is excellent in use in a situation where uniformity of luminance is required.

In addition, the means for connecting the feedback coils of the inverter circuits at both ends of the driven body needs to be drawn out by the length of the driven body when arranging the driven body in a linear shape and arranging the inverter circuits at both ends at the end of the driven body. However, when the length of the means for connecting the feedback coils is long, there is a problem such as power loss and noise.

As a specific example of the case where noise is a problem, when the fluorescent tube is driven by using any one of the inverter circuits described above, the fluorescent tube used for the backlight device of the large liquid crystal display device is connected to the feedback coils. Noise is generated from the liquid crystal, which causes a problem of adversely affecting the image of the display screen of the liquid crystal panel.

In order to solve this problem, it is preferable to make the voltage applied to the connection line which the feedback coils of the inverter circuits of both ends of a driven object connected low, and when the voltage is low, noise can also be made small, and power loss is also reduced. Can be reduced.

Therefore, the fluorescent tube lighting apparatus of the present invention is characterized in that both ends of the fluorescent tube of the inverter transformer having a secondary coil of an inverter transformer having a tertiary coil used for self oscillation and a tertiary coil not used for self oscillation It is characterized by being joined by a secondary coil.

The fluorescent tube lighting device of the present invention is characterized in that the number of turns of the tertiary coil used for the indirect connection is smaller than that of the tertiary coil used for oscillation.

According to the configuration of any one of the above-described fluorescent tube lighting apparatuses, it is possible to equalize the power balance applied to the plurality of fluorescent tubes in the multiple-type fluorescent tube lighting apparatus, and to control the degree of coupling between the inverter circuits, It becomes possible to control the intensity of the noise applied to the entire tube lighting device.

In the fluorescent tube lighting apparatus of the present invention, the AC voltage applied to the fluorescent tubes arranged in parallel using a plurality of the fluorescent tube lighting apparatuses is either one for each or the number of fluorescent tubes driven by one fluorescent tube lighting apparatus. It is characterized by indirectly connecting the respective fluorescent tube lighting devices so as to reverse the phase.

In addition, the fluorescent tube lighting apparatus of the present invention, as a means of the "indirect connection", (1) coupling to tertiary coils not used for self-oscillation of each fluorescent tube lighting apparatus, or (2) mutual fluorescent tube lighting apparatus It is characterized by using inductive coupling of at least one coil of each so-called fluorescent tube lighting apparatus represented by coupling with respect to choke coils, etc.

In addition, the fluorescent tube lighting device of the present invention is a means of the "coil inductive coupling", in (1) direct coupling, transformer intermediary coupling, parallel coil proximity bonding, etc., (2) transformer intermediary coupling, parallel coil proximity bonding, transformation It is characterized by using a coupling, a simple proximity junction.

According to any one of the above-described fluorescent tube lighting apparatuses, driving of the fluorescent tube lighting apparatuses can be synchronized, and noise, flicker, and the like of the fluorescent tube lighting apparatuses can be eliminated.

Such a fluorescent tube lighting device is very suitable for use in a place that requires uniformity of luminance over the entire surface, such as a backlight device for illuminating a liquid crystal panel of a transmissive liquid crystal display device.

Therefore, in the backlight device of the present invention, any one of the above-described fluorescent tube lighting apparatus, a reflecting plate which is disposed opposite to the fluorescent tube included in the fluorescent tube lighting apparatus and reflects light emitted from the fluorescent tube to the fluorescent tube side, A backlight device is provided, comprising a light diffuser plate disposed opposite to a side of the fluorescent tube opposite to an arrangement side of the reflecting plate. Or it is set as the backlight apparatus characterized by including any one of said fluorescent tube lighting apparatuses, and the light guide plate which converts the light which the fluorescent tube with which the fluorescent tube lighting apparatus is equipped emits into planar light. In such a configuration, since the luminance at both ends of the fluorescent tube is constant, it is possible to obtain a backlight device which emits light with a more uniform luminance and in a planar shape.

And when such a backlight device is used for a liquid crystal display device, it is possible to provide a liquid crystal display device of good image quality based on the uniform brightness of the backlight device. Therefore, in the liquid crystal display device of this invention, the liquid crystal panel which displays a predetermined image by changing the transmittance | permeability of the light emitted from a backlight device in the side opposite to the fluorescent tube arrangement | positioning side of the light-diffusion plate of a backlight device is provided. It is set as the liquid crystal display device characterized by the above-mentioned.

Further, a liquid crystal display device comprising a liquid crystal panel that displays a predetermined image by changing the transmittance of light to face the surface emitting light of the light guide plate of the backlight device.

In such a configuration, since uniform light emission is provided from the backlight device, the luminance of the entire display screen can be made uniform, and a liquid crystal display device of high image quality can be obtained based thereon.

1 is a circuit diagram of a fluorescent tube lighting apparatus according to a first embodiment of the present invention.

2 is a circuit diagram of a fluorescent tube lighting apparatus according to a second embodiment of the present invention.

3 is a circuit diagram of a fluorescent tube lighting apparatus according to a third embodiment of the present invention.

4 is a circuit diagram of a fluorescent tube lighting device according to a fourth embodiment of the present invention.

5 is a circuit diagram of a fluorescent tube lighting apparatus according to a fifth embodiment of the present invention.

Fig. 6 is a connection example of a fluorescent tube lighting apparatus in which a plurality of fluorescent tube lighting apparatuses of the present invention are arranged in parallel.

7 is a front view of a backlight device according to a sixth embodiment of the present invention;

8 is a cross-sectional view of a backlight device according to a sixth embodiment of the present invention.

9 is a front view of a backlight device according to a seventh embodiment of the present invention.

10 is a cross-sectional view of a backlight device according to a seventh embodiment of the present invention.

11 is a cross-sectional view of a liquid crystal display device according to an eighth embodiment of the present invention.

12 is a cross-sectional view of a liquid crystal display device according to a ninth embodiment of the present invention.

13 is an exemplary circuit diagram of a conventional fluorescent tube lighting device.

<The best form to perform invention>

This patent application includes all the contents described in Japanese Patent Application No. 2002-228595, which is a basic application claiming priority, and the matters described in the patent application form part of the contents of the patent application. Shall be.

In the specification, the term "inverter transformer" is used in the sense corresponding to the transformer transformer in the above-mentioned basic application. That is, in a basic application, the transformer is used for the meaning of the inverter which converts from what is called DC to AC, and the step-up and step-down conversion in the meaning of the conversion from AC of a primary side to AC of a secondary side. In this specification, the term of an inverter transformer also includes the meaning of the voltage transformer which made the winding ratio of a primary side and a secondary side different.

The higher-order coil is a coil for transformer (including boost and step-down) other than the primary coil, and includes a secondary coil, a tertiary coil, a feedback coil, and the like. The higher-order coil used for self oscillation on the primary side includes any of a high-order coil other than the feedback coil or the primary and secondary coils for self-oscillation, for example, a tertiary coil. For example, the tertiary coil which is not used for self oscillation means the tertiary coil for non-magnetic oscillation.

EMBODIMENT OF THE INVENTION Embodiment which concerns on the inverter circuit which concerns on this invention is described, referring drawings. Hereinafter, a fluorescent tube is taken as an example of a driven body driven by an inverter circuit, and an embodiment in which the inverter circuit according to the present invention is used in the fluorescent tube driving apparatus for driving the fluorescent tube will be described based on FIGS. 1 to 5. Explain.

First, the fluorescent tube lighting apparatus which concerns on 1st Embodiment of this invention is demonstrated, referring FIG. 1 (a)-FIG. 1 (e). FIG. 1A is a diagram illustrating an example of a circuit configuration of a main part of the fluorescent tube lighting apparatus according to the present embodiment. As shown in Fig. 1 (a), the inverter circuits A and B formed by two sets of two inverter transformers 2, 5, or 3 and 4 are connected to two fluorescent tubes 15 and 16 that are driven. It has the structure provided in both ends, respectively. Here, among the inverter transformers 2, 5 or 3, 4 connected to both ends of each of the fluorescent tubes 15 and 16, a configuration (LN) in which both ends of the feedback coils of the boosted transformer not used for oscillation are interconnected with each other is provided. Have

The main components of the apparatus shown in FIG. 1A are two inverter circuits A and B and two fluorescent tubes 15 and 16. Inverter circuits A and B are DC power supply input terminals 1 (1a and 1b), inverter transformers 2 to 5, choke coils 6 and 7, transistors 8 to 11, resonant capacitors 12 and 13, respectively. ), A filter capacitor 14 and the like. Among these components, regarding the inverter transformers 2 to 5, the primary coils L1 and L1 'which form part of the oscillation circuit, and the secondary coils L2 that supply high voltage to the fluorescent tube (L2-1 to L2-2) ') And tertiary coils L3-2 and L3-2' capable of switching transistors 8-11.

Next, the operation principle of each of inverter circuits A and B shown in FIG. In general, an inverter circuit for a fluorescent tube aims to supply a high voltage (for example, several hundreds to several thousand V) of alternating current (frequency is, for example, several tens of frequencies to several tens of frequencies) to a fluorescent tube. Therefore, first, in order to convert the DC voltage input from the input terminal 1a into an AC voltage, an oscillation circuit (consisting of the transformers 2 and 3, the choke coil 6 and the resonance capacitor 12) is provided, Is converting to AC. The frequency is mainly determined by the main inductance of the transformers 2 and 3, and the constants such as the choke coil 6 and the resonant capacitor 12 and the like.

Next, the conversion of the input voltage to the high voltage can be performed by the inverter transformers 2 and 3. That is, by making the turns ratio of the secondary coil L2 to the primary coil L1 of each inverter transformer tens to hundreds of times, it is possible to convert voltages of several tens of V into hundreds to several thousand V in the secondary coil.

In order to control the direction of the current flowing through the primary coil side by the transistors 8 and 9, the inverter transformers 2 and 3 are provided with a tertiary coil L3. In other words, it is appropriately stepped down by the turn ratio of the tertiary coil L3 to the secondary coil L2 so as to alternately apply an appropriate voltage to the base side of the transistors 8 and 9. As a result, the alternating voltage waveform of about V generated in the tertiary coil enables the transistors 8 and 9 to alternately repeat the on / off state and to drive the inverter circuit A stably. Incidentally, when a plurality of inverter transformers are used in one inverter circuit, one third coil to be used is usually sufficient.

Although the above is a general driving principle of the inverter circuit, the means for giving a switching action to the transistors 8 and 9 in this way is the driving scheme of the inverter circuit supplied by the tertiary coils L3-2 and L3-2 'of the inverter transformer. Generally it is called self-food. (Hereinafter, in order to distinguish the tertiary coil which is actually responsible for such a role from the tertiary coil which is not, it will be divided into `` self-oscillating tertiary coil '' and `` non-legatic oscillating tertiary coil '').

And as a structure of the fluorescent tube lighting apparatus in this invention, it is as follows. In the inverter circuit having two fluorescent tubes shown in FIG. 1A, for example, the fluorescent tube 15 is different from the primary coil of the transformer 2 and the primary coil of the transformer 4. It is in the opposite phase, and is in the same phase as the secondary coil of the transformer 2 and the secondary coil of the transformer 5. Regarding the fluorescent tube 16 arranged together with the fluorescent tube 15, the primary coil of the transformer 3 and the primary coil of the transformer 5 are in phase opposite to each other. The secondary coil and the secondary coil of the transformer 4 are in the same phase. In addition, the tertiary coil for non-magnetic oscillation is indirectly connected so that the transformers 3 and 4 or 2 and 5 may be reversed in phase.

One of the primary coils and the secondary coils of the transformers 3 and 4 connected to both ends of one fluorescent tube has the same phase and the other phase has the opposite phase. In case of being indirectly connected by using the oscillation tertiary coil, the tertiary coil is configured to synchronize the inverters A and B in the same phase so that the alternating voltage applied to both ends of the fluorescent tube is in the opposite phase. Indirect connection.

In the fluorescent tube lighting apparatus according to the first embodiment of the present invention, as shown in Fig. 1A, in the two inverter circuits A and B connected to both ends of the fluorescent tubes 15 and 16, an inverter is used. It is characterized by taking the configuration LN in which the non-magnetic oscillating tertiary coils provided in each of circuits A and B are interconnected. Thereby, without forming an electrical coupling between the inverter circuits A and B, phases of each other are induced by an induction effect between the secondary coils L2 and the tertiary coils L3-1 and L3-1 'of the inverter transformers 2 and 4. Can be operated to tune. Thereby, the inverter circuits A and B can be "indirectly connected" by the induction effect.

Regarding the connection to the fluorescent tubes 15 and 16, the secondary of the inverter transformer from each of the inverter circuits A and B so that the voltages applied to both ends of the fluorescent tubes 15 and 16 are in opposite phases with each other. One terminal of the coil L2 may be taken out and connected.

By the circuit configuration as described above, the fluorescent tubes 15 and 16 are AC waveforms without waveform distortion, and sufficient high voltage can be applied, so that the fluorescent tubes can be stably driven. In addition, the luminous efficiency with respect to the power of the fluorescent tube can also be improved by about 10% compared with the case of driving one fluorescent tube with one inverter transformer.

Incidentally, the indirect connection method between the inverter circuits is a simple method because the configuration of directly connecting the non-magnetic oscillating coils like the broken line M in Fig. 1B does not increase the number of parts, but according to the present embodiment "Indirect connection method" is not limited to the method shown to Fig.1 (b). In addition, in the broken-line part M, as shown in FIG.1 (c), the structure which mediated a transformer and used the induction effect (transformer intermediary coupling), or as shown in FIG.1 (d), It is also possible to use the structure (coil proximity) which the coil CL1, CL2 connected in parallel to the oscillation tertiary coil mutually arrange | positioned mutually, and these structures are also included in the scope of the present invention.

Moreover, as an indirect connection method between inverter circuits, as long as it is the structure in which the voltage of a reverse phase is applied to both ends of a fluorescent tube, it may be a reverse phase or the same phase. However, considering the effects of common circuit design, such as wiring patterns of electronic components and inverter boards, or countermeasures against electrical and magnetic noise of transformers, the above-described effects can be obtained by reverse phase connection, and the effects can be reduced. Since it is possible to do this, it is preferable.

In addition, if the high-voltage alternating voltage applied to each of the fluorescent tubes 15 and 16 is in phase with each other, the radiation noise generated from each of the fluorescent tubes can be canceled, so that the noise can be reduced. In addition, the above-mentioned principle may have more than two drive numbers of a fluorescent tube, and even in this case, it is within the scope of the present invention.

In addition, the connection method of the inverter transformer of the fluorescent tubes 15 and 16, for example, the fluorescent tube 15 is via the inverter transformers 2 and 4, and the fluorescent tube 16 is the inverter transformers 3 and 5, for example. In the case of the connection through the above, even if the specifications and the performance of the fluorescent tubes 15 and 16 are the same, the brightness may not be the same. The fluorescent tubes 15 are connected by inverter transformers having the third coils L3-1 and L3-1 'for non-magnetism oscillation, and the fluorescent tubes 16 are cut and the third coils L3-2 and L3 for oscillation. This is because the inverter transformers having a -2 'are connected to each other. That is, since the power applied to the inverter transformer differs depending on whether or not the third coil is used for oscillation, the power applied to each of the fluorescent tubes 15 and 16 may be different.

Therefore, in the present embodiment, the combination of the fluorescent tubes 15, 16 and the inverter transformers 2, 5, 3, 4 connected to both ends thereof is applied to the two fluorescent tubes 15, 16 as follows. Research has been made to equalize power. That is, as shown in Fig. 1A, one terminal of the fluorescent tube 15 has the secondary coil L2- of the inverter transformer 2 having the tertiary coil L3-1 for non-magnetizing oscillation of the inverter circuit A. 1 and the other terminal of the fluorescent tube 15 are connected to the secondary coil L2-1 'of the inverter transformer 5 having the self-oscillating tertiary coil L3-2' of the inverter circuit B. Similarly, the fluorescent tube 16 is also given a combination with the same inverter transformer (see FIG. 1A).

By selecting the combination of the fluorescent tubes 15 and 16 and the two inverter transformers as described above, the power applied to the two fluorescent tubes 15 and 16 is adjusted in the direction of equalization. Therefore, since two fluorescent tubes have almost the same brightness as long as they have the same specification and performance, the luminance unevenness when the fluorescent tube lighting apparatus according to the present embodiment is used, for example, for illumination of a backlight device can be improved.

In addition, in the fluorescent tube lighting device according to the present embodiment, indirect connection between the inverter circuits is possible, and noise of one inverter circuit may be easily propagated to the other. For example, in the case of adopting the dimming means of the duty dimming method, ripple noise generated at the start-up of one inverter circuit is propagated to the other, resulting in higher ripple noise of higher voltage and higher current.

Therefore, in the fluorescent tube lighting device according to the present embodiment, it is preferable to make the number of turns of the non-magnifying oscillation tertiary coil smaller than that of the self-oscillating tertiary coil. In the self-oscillating tertiary coil, it is usually necessary to generate an alternating electromotive force of up to several V so that the base (or gate) of the transistor is turned on. There is no need, so even if the number of turns is about 0.5 turns, you can fulfill that role. In addition, since the number of turns can be produced even in the current state of transformer design technology, it is possible to sufficiently fulfill the role of indirect connection between inverter circuits. This method is also effective as a method of reducing the power applied to the tertiary coils L3-1 and L3-1 'of the inverter transformer because the voltages applied to the tertiary coils L3-1 and L3-2' may be low voltages. This makes it possible to suppress voltage or current noise that may occur inside the fluorescent tube lighting device as much as possible, and at the same time, it is possible to minimize the power applied to the indirect connection between the inverter circuits to the minimum.

In addition, in the inverter circuit, as described above, noise may also be generated in the interior itself, and in particular, an adverse effect caused by noise on electronic components (liquid crystal panels, etc.) having different magnetic fields generated from the inverter transformers 2 to 5. There is also a possibility.

Therefore, in the fluorescent tube lighting apparatus according to the present embodiment, the outputs of the secondary coils L2 of the two inverter transformers 2 and 3 are in opposite phases so as to suppress noise generated in each inverter circuit A and B. FIG. Characterized in that. Specifically, in Fig. 1A, the primary coils L1 connected in parallel with the inverter transformers 2 and 3 are mutually reversed, or both terminals of the primary coils L1 are interchangeably connected or secondary. It is possible to think of a method such that the coils are in the reverse range.

As described above, according to the fluorescent tube lighting apparatus according to the present embodiment, since the noise applied to one inverter circuit to the other inverter circuit can also be reduced, the noise of the entire fluorescent tube lighting apparatus is also reduced, and the other electrons. It also reduces adverse effects such as noise on components. In addition, the specification of the inverter transformer in this embodiment does not have a restriction | limiting in particular, For example, it is not limited about the design of cores, such as a closed type / an individual type.

In addition, the inverter circuit as shown to Fig.1 (a) is a basic structure to the last, and the same function is completed also in the inverter circuit which added some improvement and improvement with respect to this embodiment. For example, when an additional function such as an error detection circuit accompanying a dimming circuit, a lamp wave, or the like is added, only one of the base terminals of the transistors 8 and 9 is connected to the input terminal 1, The inverter circuit that has been improved to reduce oscillation noise also falls within the scope of the present invention.

Next, the fluorescent tube lighting apparatus which concerns on the modification of this embodiment is demonstrated, referring FIG. 1 (e). FIG. 1E is a diagram showing a configuration example in the case where one input two output type (hereinafter referred to as "2 in 1 type") is used for an inverter transformer in a fluorescent tube lighting device. Inverter transformers (2, 3) each have two tertiary coils, one of which is self-oscillating tertiary coils L3-2, L3-2 ', the other of which is a non-magnetic oscillating tertiary coil L3-1, L3. It is used as -1 '.

As shown in Fig. 1E, the main components of the fluorescent tube lighting apparatus according to the modification of the present embodiment include two inverter circuits A and B and two fluorescent tubes 15 and 16. . Inverter circuits A and B include DC power supply input terminals 1 (1a and 1b), inverter transformers 2 and 3, choke coils 6 and 7, transistors 8 to 11, and resonant capacitors ( 12 and 13 and the filter capacitor 14 are comprised. Among these components, the inverter transformers 2 and 3 include the primary coils L1 and L1 ', two secondary coils L2-1, L2-1', L2-2, L2-2 'and two tertiary coils. L3-1, L3-2 (L3-1 ', L3-2') is comprised. In the fluorescent tube lighting apparatus according to the present modification, the self-oscillating tertiary coils are L3-2 and L3-2 ', and the non-magnetic oscillating tertiary coils are L3-1 and L3-1'. have.

Also in the fluorescent tube lighting apparatus which has such a structure, it has the same advantage as the case of the structure of the fluorescent tube lighting apparatus shown to Fig.1 (a).

By the circuit configuration as described above, the fluorescent tubes 15 and 16 are AC waveforms without waveform distortion, and sufficient high voltage can be applied, so that the fluorescent tubes can be stably driven.

In addition, according to the fluorescent tube lighting device according to the present embodiment, for example, the number of turns of the non-magnifying oscillation tertiary coils L3-1 and L3-1 'of the inverter transformers 2 and 3 is determined by the third order for oscillation. By reducing the number of turns of the coils L3-2 and L3-2 ', noise applied to one inverter circuit to the other inverter circuit can also be reduced. In addition, by designing the two secondary coils L2-1 and L2-2 of the inverter transformers 2 and 3 in a mutually inverse region, radiation noise generated in the fluorescent tubes 15 and 16 driven in the opposite phase is canceled, Noise of the entire fluorescent tube lighting device is also reduced, so that adverse effects such as noise applied to other electronic components are reduced.

Incidentally, as an indirect connection method between the inverter circuits, similarly to the case of FIG. 1 (a), the configuration of directly connecting the coils for non-magnetic oscillation like the broken line M of FIG. 1 (b) does not increase the number of components. Although it is a simple method, the "indirect connection method" according to the present modification is not limited to the method shown in Fig. 1B. In addition, in the broken-line part M, as shown in FIG.1 (c), the structure which mediated a transformer and used the induction effect, As shown in (d) of FIG. It is also possible to use the structure which the coil CL1 and CL2 connected in parallel to the coil mutually arrange | positioned, and these structures are also included in the scope of the present invention.

In addition, in this embodiment, although two tertiary coils L3-1 and L3-2 are provided in one inverter transformer, the number of the coils is not limited to two, Even if it installs three or more as needed. (For details, refer to the fifth embodiment (Fig. 5 (c)).

Next, the fluorescent tube lighting apparatus which concerns on 2nd Embodiment of this invention is demonstrated, referring FIG.2 (a)-FIG.2 (d).

Fig. 2A is a second embodiment showing the main circuit diagram of the fluorescent tube lighting apparatus according to the present invention. The inverter transformer adopts a type of 2 in 1, and is connected to one end of the inverter transformer so that both ends of the fluorescent tube have voltages opposite to each other, and the tertiary coil for self-oscillation of each inverter circuit On the other hand, the mutual inverter circuits are indirectly connected by interconnecting each other using coils provided in parallel with each other.

The main components of FIG. 2A are two inverter circuits A and B and two fluorescent tubes 15 and 16. Inverter circuits A and B include DC power supply input terminal 1a, 2 in 1 type inverter transformers 2 and 3, choke coils 5 and 6, transistors 8, 9, 8 ', 9', Resonant capacitors 11 and 12, filter capacitors 14, and the like. Among these, for the inverter transformers 2 and 3, the primary coils L1 and L1 ', the secondary coils L2-1, L2-1', L2-2 and L2-2 'tertiary coils L3-1 and L3- It consists of 1 ', L3-2, L3-2'. In this embodiment, self-oscillating tertiary coils are used as L3-2 and L3-2 '.

In the fluorescent tube lighting apparatus according to the present embodiment, as a means for indirectly joining the inverter circuits A and B, a configuration example in the broken line portion M is given. Some examples are given as examples. This embodiment is characterized by connecting in parallel between the two terminals drawn from the self-oscillating tertiary coils L3-2 and L3-2 'of the inverter circuits A and B via a coil or a transformer in parallel. As a more specific structure, as shown in FIG.2 (b), the structure (transformer intermediary coupling) which connects through two coils L4 and L4 'of a transformer in broken line M is mentioned.

In addition, as shown in Fig. 2 (c), it is also possible to have a configuration of connecting through two transformers. An advantage of using two transformers as shown in FIG. 2C will be described by taking straight fluorescent tubes extending straight. As shown in FIG. 2 (b), when only one transformer is used, the transformer is mounted only on one of the inverters A and B, and the power difference of the inverters A and B is not equal, so that a luminance difference occurs at both ends of the fluorescent tube. Easy to be However, as shown in Fig. 2C, when two transformers are used, since transformers can be mounted one by one in inverters A and B, power can be allocated to both inverter circuits A and B evenly. The luminance balance between the left and right sides of the fluorescent tube can be maintained. Further, in the two transformers in this embodiment, the number of turns of the coils L5 and L5 'on the output side is smaller than that of the coils L4 and L4' on the input side, thereby output coils L5 and L5 '(FIG. 2C) (17). The function of lowering the voltage applied to the function functions to suppress the extra noise component of the voltage components transmitted between the mutual inverter circuits A and B as much as possible. In addition, if any one of the coils L4, L5, L4 ', and L5' on the input side and the output side becomes mutually inverse, noise components generated in each other's transformers are canceled, and stably oscillating the mutual inverter circuits A and B It becomes possible.

As shown in Fig. 2 (d), coils CL4 and CL4 'are simply connected in parallel to each of the self-oscillating coils of the inverter transformers 2 and 3, and the coils CL4 and CL4' are close to each other. Arrangement (coil proximity) may be sufficient. Also with this configuration, the voltage phase of the induced electromotive force applied to the coils CL4 and CL4 'is synchronized by the magnetic field generated from the cores of the coils CL4 and CL4', so that the alternating current applied to both ends of the fluorescent tube is driven in the opposite phase. Similarly to the fluorescent tube lighting apparatus according to the first embodiment, both ends of the fluorescent tube can be driven.

When the mutual inverter circuit AB is driven in reverse phase, as shown in Fig. 2B, the coils L4 or L4 'connected in parallel to the mutually oscillating tertiary coils may be connected in reverse. This makes it possible to drive both ends easily while commonizing the component configurations and wiring patterns of the inverter circuits A and B.

In addition, similarly to the fluorescent tube lighting apparatus according to the first embodiment of the present invention, it is also possible to cause the two outputs of the inverter transformers to be in opposite phases in each inverter circuit. In addition, the case where 1 in 1 type is employ | adopted as an inverter transformer is also within the scope of the present invention. In that case, the inverter transformer connected to both ends of the fluorescent tube may be a combination of having a self-oscillating tertiary coil and having a non-magnetic oscillating tertiary coil. By doing in this way, the effect similar to the case of the fluorescent tube lighting apparatus which concerns on said 1st Embodiment can be exhibited.

Next, the fluorescent tube lighting apparatus which concerns on 3rd Embodiment of this invention is demonstrated, referring drawings. FIG. 3A is a diagram illustrating a configuration example of the fluorescent tube lighting apparatus according to the present embodiment. The structure shown in FIG. 3A is a synchronization means of two inverter circuits A and B, and is provided between each of the center taps CT1 and CT2 drawn out from the primary coils L1 and L1 'and the input terminal 1a. The choke coils (not shown) are indirectly connected to each other, and the indirect connection includes a first configuration in which inverters A and B are driven in reverse phase, and secondary coils L2-1 and L2-1 in inverter circuits A and B. ', L2-2 and L2-2' are each characterized by a second configuration in which the region is reversed. As a result, the magnetic field of the core is canceled.

The fluorescent tube lighting apparatus according to the present embodiment has the above-described first configuration, so that the voltage applied to both ends of the fluorescent tube can be reversed without increasing the number of parts (in a simple configuration). In addition, by having the second configuration, the magnetic field generated in the core is removed. Noise in the inverter circuit can be reduced.

As a fluorescent tube lighting apparatus which concerns on another modified example of this embodiment, four structural examples are mentioned as a structure in the broken line part M as a means which indirectly joins inverter circuits A and B. As shown in FIG. These four structural examples are characterized in that the indirect connection structures of the choke coils are provided as synchronization means for the inverter circuits A and B so that the center towers can be synchronized with each other.

As a more specific indirect connection structure, as shown in FIG.3 (b) (coil proximity type), it has the coil proximity type structure by arrange | positioning coil CL1, CL2 in the broken line part M. FIG. In addition, as shown in Fig. 3C, it is also possible to have a transformer mediation type structure indirectly connected through two transformers. According to this configuration, the number of components can be reduced from the configuration of two coils in FIG. 3B to the configuration of one transformer. In addition, as shown in Fig. 3D, it is also possible to have a configuration in which the two transformers T1 and T2 are connected. In the configuration shown in FIG. 3D (transformer intermediation type), for example, when the inverter circuits A and B are separated from each other in order to light up a straight tube fluorescent tube, one of the inverters A and B is one transformer. Since the power balance of both inverters is broken and the brightness of both ends of the fluorescent tube is not equalized, the two transformers are mounted one by one on both inverters, thereby providing power to both inverter circuits A and B. It can be allocated evenly, and there is an advantage that the luminance balance between the left and right sides of the fluorescent tube can be maintained. Therefore, the configuration shown in (d) of FIG. 3 exhibits its technical effect when driving both ends of the linear lamp extending linearly.

In the two transformers in this embodiment, the number of turns of the coil L5 'on the output side is less than that of the coil L4' on the input side, thereby reducing the voltage applied to the output coil L5 '. It is possible to restrain the extra noise component of the voltage components transmitted between B as much as possible. In addition, when the input and output coils are configured to be in a reverse range, noise components generated in each other's transformers are canceled, so that mutual inverter circuits A and B can be stably oscillated.

In addition, even in the type as shown in Fig. 3E, the number of coils used for indirect connection can be reduced and combined with weak inductive coupling. In the configuration shown in FIG. 3E, two coils CL31 and CL41 form a pair to form a transformer. In this manner, synchronization can be achieved while suppressing noise generated in the mutual inverter circuit as much as possible.

Moreover, as an indirect connection method between inverter circuits, as long as it is the structure which the voltage of a reverse phase is applied to both ends of a fluorescent tube, it may be a reverse phase, may be the same phase, and makes it the scope of this invention.

Next, the fluorescent tube lighting apparatus which concerns on 4th Embodiment of this invention is demonstrated, referring drawings. 4 is a view for explaining a configuration example of the fluorescent tube lighting apparatus according to the present embodiment using a 2 in 1 type as an example. As shown in FIG. 4, in the fluorescent tube lighting apparatus according to the present embodiment, inverter A and inverter B are indirectly connected through step-down transformers 3 and 5 having primary coils L1 ′ and L3 ′. Has a configuration

In each of the inverters A and B, the primary coils L1 'and L3' on the step-down transformers 3 and 5, which extract the voltage smaller than the voltage of the primary coil from the secondary coil, are located on the inverter transformer (step-up transformer) side. It is connected in parallel with the primary coils L1 and L3, respectively. The primary coils L1 'and L3' constitute transformers 3 and 5 by secondary coils L2-2 and L2-2 'for stepping down, respectively. The secondary coils L2-2 and L2-2 'are connected to each other indirectly or directly.

In the fluorescent tube lighting apparatus according to the present embodiment, as the means for indirect connection, the transformers 3 having transformer primary coils L1 'and L3' which form part of the oscillation circuits drawn out from the mutual inverter circuits A and B, respectively, Indirect connection is made through the secondary coils L2-2 and L2-2 'of 5). That is, each secondary coil L2-2, L2-2 'of these transformers 3 and 5 which has these primary coils L1' and L3 'is connected so that the phase of inverter circuits A and B may be reversed. That is, the characteristic of this modification is that the secondary coil of a transformer which is a means for voltage-connecting both ends of a fluorescent tube is used for indirect connection, instead of being used for power supply of a fluorescent tube.

By forming the above configuration, the center tap CT1 'is applied to each of the primary coils L1' and L3 'of the step-down transformers 3 and 5, similarly to the primary coils L1 and L3 of the boost transformers 2 and 4, respectively. The direction of the current flowing from CT2 'is constantly changed in accordance with the switching conditions of the transistors 8 to 11, and the secondary coils L2-2 and L2 of the step-down transformers 3 and 5 are caused by variations in the core magnetic flux of the transformer. An alternating voltage waveform is generated at -2 '. As these secondary coils are coupled to each other as shown in Fig. 4, the phases of the mutual inverter circuits are synchronized to opposite phases, so that the secondary coils L2-1 and L2-1 'of the boosting transformers 2 and 4 have high voltages of opposite phases. This happens. Therefore, by connecting these two terminals to both ends of the fluorescent tube 15, it becomes possible to drive the fluorescent tube 15 at a stable frequency. The fluorescent tube 16 can also be applied on the same principle.

By the above structure, the direction of the electric current which flows through the center tap CT1 to the primary coil L1 of the boosting transformer 2, and the direction of the electric current which flows through the center tap CT2 to the primary coil L3 of the boosting transformer 4 are reversed. Since it is operated, between the secondary coil L2-1 of the boost transformer 2 wound around the same phase and the secondary coil L2-1 'of the boost transformer 4, an alternating current of opposite phase is applied to the voltage waveform. Can be created without generating distortion.

Therefore, when a pair of inverter circuits are provided at both ends of the fluorescent tubes 15 and 16 and the fluorescent tubes are driven in parallel, the voltage generated in the secondary coils connected to the fluorescent tubes of the respective inverter circuits is reversed in phase. Since the synchronization can be controlled, the differential voltage can be applied to both ends of each fluorescent tube with equal magnitude, so that the brightness can be equalized even if the length of the fluorescent tube is long.

Incidentally, in the above example, the secondary coil was used to connect the step-down transformers, but a feedback coil (tertiary coil) may be further provided to the step-down transformer, and the feedback coils may be connected to each other.

In addition, the coupling method of the secondary coils of the step-down transformers 3 and 5 may be a coupling through a coil, a transformer, or the like, as described above, without staying in direct coupling, which is within the scope of the present invention.

Moreover, as an indirect connection method between inverter circuits, as long as it is the structure which the voltage of a reverse phase is applied to both ends of a fluorescent tube, it may be a reverse phase and may be the same phase, and it is set as the scope of the present invention.

Next, the fluorescent tube lighting apparatus which concerns on 5th Embodiment of this invention is demonstrated, referring FIG. 5 (a)-FIG. 5 (d). The fluorescent tube lighting apparatus according to the present embodiment has a first configuration using an indirect connection means between the inverter circuits at both ends of the fluorescent tube and a second configuration using an indirect connection means between the fluorescent tube lighting devices. do.

In the fluorescent tube lighting device shown in Fig. 5A, the first and second configurations are as follows. That is, the 1st structure which is an indirect connection means between the inverter circuits of both ends of a fluorescent tube is Transformer (71 or 73) which has the coil connected in parallel to the self-oscillation tertiary coil of inverter circuit A or B, and inverter circuit C A transformer 75 or 77 having a coil connected in parallel to the oscillation tertiary coil of D or similarly indicates a means LN1 or LN2 connected by a coil facing the coil. On the other hand, the second configuration using the indirect connection means between the fluorescent tube lighting devices is the means LN3 for connecting both ends of the tertiary coil for non-magnetic oscillation of the inverter circuits A and B or the tertiary oscillation third for the inverter circuits C and D. At least one of the means LN4 which connects both ends of a coil is comprised.

In the first configuration LN1 and LN2 connection methods, any of the fluorescent tubes 51 to 54 may be used as long as they are driven so that the phases of the inverter circuits A and C or B and D are in the same or opposite phases. What is necessary is just to connect so that the voltage applied to the both ends may become a reverse phase.

As for the second configuration LN3 and LN4 connection methods, any one may be used so long as the phases of the inverter circuits A and B are driven in the same phase or in the opposite phase, but the phase of the AC voltage applied to the fluorescent tubes 51 to 54 is It is preferable to connect so that it may invert for every number of fluorescent tubes which one or one fluorescent tube lighting apparatus has. That is, for example, when the phases of the alternating voltages applied to the fluorescent tubes 51 and 52 in one fluorescent tube lighting apparatus are in phases opposite to each other, the indirect connection means LN3 or LN4 represents inverter circuits A and B or C and D. Is connected to be driven in phase, the phases of the alternating voltage applied to the fluorescent tubes 51 to 54 are always inverted one by one. On the contrary, in the case where the phases of the alternating voltages applied to the fluorescent tubes 51 and 52 in one fluorescent tube lighting device are mutually in phase, the indirect connection means LN3 or LN4 has the inverter circuits A and B or C and D in opposite phases. When connected so as to drive, the phases of the alternating voltage applied to the fluorescent tubes 51 to 54 are reversed by two, that is, by the number of fluorescent tubes included in one fluorescent tube lighting apparatus. In this way, by inverting the phase of the alternating voltage applied to the fluorescent tube for each or the number of fluorescent tubes of one fluorescent tube lighting device, it is possible to mutually cancel the unnecessary radiation noise generated from the fluorescent tube, thereby reducing the low-noise fluorescent tube The lighting device can be supplied.

In addition, as a specific method for sequentially inverting the phase of an alternating voltage applied to such a fluorescent tube, a method such as sequentially replacing the connecting terminal to the fluorescent tube of the transformer's secondary coil and the GND terminal for each secondary coil in addition to the above method Even possible. Therefore, for the phase inverting means of the fluorescent tube, a method of making the two secondary coils L2-1 and L2-2 of the respective inverter circuits A to D mutually inverse are not necessarily required, even if they are turned in the same direction. And fall within the scope of the present invention.

Incidentally, even if any of these indirect connection means LN1 to LN4 is insufficient, there is no problem since the synchronization of the inverter circuits A to D is performed, but there is no problem. do.

According to the fluorescent tube lighting device having the above-described configuration, the noise applied to the liquid crystal panel from the fluorescent tube can also be reduced, for example, and its application range and effect are further widened and high.

Next, the fluorescent tube lighting apparatus which concerns on the 1st modified example of this embodiment is demonstrated, referring FIG. 5 (b). In the fluorescent tube lighting device according to the first modification of the present embodiment, the first configuration, which is an indirect connection means between the inverter circuits at both ends of the fluorescent tube, is connected to both ends of the nonmagnetic oscillation tertiary coils of the inverter circuits A and C. The means LN1 and the means LN2 for connecting both ends of the non-magnetic starter tertiary coils of the inverter circuits B and D are indicated. On the other hand, the second configuration using the indirect connection means between the fluorescent tube lighting devices includes a transformer 71 or 75 having a coil connected in parallel to the self-oscillating tertiary coil of the inverter circuit A or C and the inverter circuit B or D. Similarly, a transformer 73 or 77 having a coil connected in parallel to the oscillation tertiary coil constitutes means LN3 or LN4 connected by a coil facing the coil. That is, it is a structure by which the means of the 1st structure and the 2nd structure in the original embodiment (FIG. 5 (a)) mentioned above were replaced, respectively. Therefore, the effect also has an effect similar to that of FIG.

In addition, also in the first modification of the present invention, as in the previous embodiment, whether the indirect connection means is reversed or in the same phase is determined by the inversion state of the phase of the AC voltage applied to the fluorescent tubes 51 to 54. What is necessary is just to design according to it, and it shall suppose that both the same phase and the opposite phase correspond suitably. According to the fluorescent tube lighting device having such a configuration, since the unnecessary radiation component generated from the fluorescent tube is canceled between the fluorescent tubes, it is possible to reduce noise from the fluorescent lamp, for example, to the liquid crystal panel.

Further, even if any of these indirect connection means LN1 to LN4 is insufficient, there is no problem since the synchronization of the inverter circuits A to D is achieved, but all four may be configured as necessary, for example, to increase the synchronization between the inverter circuits.

Next, the fluorescent tube lighting apparatus which concerns on the 2nd modified example of this embodiment is demonstrated, referring FIG. 5C. In the fluorescent tube lighting apparatus according to the second modification of the present embodiment, three tertiary coils are provided in the inverter transformer, and one of them is used as the oscillation tertiary coil. It can be used as a tertiary coil for oscillation. For this reason, these tertiary coils for non-magnetic oscillation can be used for both the first configuration, which is an indirect connection means between the inverter circuits at both ends of the fluorescent tube, and the second configuration using the indirect connection means between the fluorescent tube lighting devices. Therefore, the 1st structure which is an indirect connection means of the inverter circuits of both ends of a fluorescent tube is used for the non-magnetic oscillation of the means LN1 and the inverter circuits B and D of the means which connect both ends of the non-magnetic starter tertiary coil of inverter circuits A and C. The means LN2 for connecting both ends of the tertiary coil is indicated. On the other hand, the second configuration using the indirect connection means between the fluorescent tube lighting device is the third non-magnetic oscillation of the means LN3 and the inverter circuits C, D for connecting both ends of the non-magnificent oscillation tertiary coils of the inverter circuits A and B. The means LN4 which connects both ends of a coil is comprised. Although (a) and means of FIG. 5 are different, since the objectives of each indirect connection means are respectively the same, the effect also has an effect similar to (a) of FIG.

In addition, also in the second modification of the present invention, as in the previous embodiment, it is determined whether or not the indirect connection means is reversed or in the same phase. The reversal state of the phase of the AC voltage applied to the fluorescent tubes 51 to 54 is determined. It may be designed in accordance with the configuration, and any of the same or opposite phases can be appropriately matched. According to the fluorescent tube lighting apparatus having such a configuration, since unnecessary radiation components generated from the fluorescent tube cancel out between the fluorescent tubes, it is possible to reduce noise from the fluorescent lamp, for example, to the liquid crystal panel.

In addition, even if either of these indirect connection means LN1 to LN4 is insufficient, there is no problem since the synchronization of the inverter circuits A to D is achieved, but all four may be configured as necessary, for example, to increase synchronization between the inverter circuits.

Next, the fluorescent tube lighting apparatus which concerns on the 3rd modified example of this embodiment is demonstrated, referring FIG. 5D. In the fluorescent tube lighting device according to the third modification of the present embodiment, the first configuration, which is an indirect connection means between the inverter circuits at both ends of the fluorescent tube, is connected to both ends of the non-magnetic starter tertiary coils of the inverter circuits A and C. The means LN1 and the means LN2 for connecting both ends of the non-magnetic starter tertiary coils of the inverter circuits B and D are indicated. On the other hand, the 2nd structure using the indirect connection means between fluorescent tube lighting apparatuses comprises the indirect connection means 90 or 90 'by the choke coils of inverter circuit A and B or C and D. 5 (a) and the means are different, but the purpose of each indirect connection means is the same (90, 90 'corresponds to LN3, LN4), and the effect thereof is the same as that of FIG. Has an effect.

In addition, also in the third modification of the present invention, as in the previous embodiment, it is determined whether the indirect connection means is reversed or in the same phase. The phase of the phase of the AC voltage applied to the fluorescent tubes 51 to 54 is inverted. What is necessary is just to design according to it, and it shall suppose that both the same phased and the opposite phased correspond appropriately. According to the fluorescent tube lighting apparatus having such a configuration, since unnecessary radiation components generated from the fluorescent tube are canceled between the fluorescent tubes, it is possible to reduce noise from the fluorescent lamp, for example, to the liquid crystal panel.

In addition, in the indirect connection means 90 or 90 'of FIG. 5D, as a connection method of inverter circuits A and B or C and D, the structure of the transformation coupling which uses each coil of a transformer as a choke coil is used. Although taken, the structure by the example similar to 3rd Embodiment (FIG. 3 (b)-(e)) may be taken.

Indirect connection means LN1, LN2, 90, 90 'is not a problem because the inverter circuits A to D are synchronized even if they are all insufficient, but there are no problems. You may also

As mentioned above, although 5th Embodiment was described, the various coils in an inverter circuit can be either a 1st structure as an indirect connection means between inverter circuits of both ends of a fluorescent tube, and a 2nd structure as an indirect connection means between fluorescent tube lighting devices. By using the above, as a result of transmitting the resonant frequencies generated in the mutual inverter circuit through the magnetic flux generated from the induced electromotive force generated therein, the principle of resonating the resonant frequency of the mutual inverter circuit is synchronized. Therefore, the above-described various coils can also be used in any of the first and second configurations, which fall within the scope of the present invention. In addition, about the said 2nd structure, even if it connects the 3rd or more coils for non-magnetic oscillation in 3 or more fluorescent tube lighting apparatuses in parallel, it is possible to indirectly connect 3 or more fluorescent tube lighting apparatuses, and a fluorescent tube The number of people of the lighting device is not limited and falls within the scope of the present invention. The number of fluorescent tubes that one fluorescent tube lighting apparatus can have is not particularly limited. Even in that case, with respect to the selection of the same phase / inverse phase of the phase of the fluorescent tube lighting apparatus in the second configuration, the number of fluorescent tubes having one phase of the voltage applied to the fluorescent tube or one fluorescent tube lighting apparatus has As long as it is indirectly connected so that it may become inverted every, any may be sufficient, and this is also in the scope of the present invention.

When the tertiary coil is used for indirect connection, the number of turns of the tertiary coil is smaller than that of the tertiary coil used for self oscillation. For example, in FIG. 1A, the number of turns of the tertiary coil L3-1 used for indirect connection is at least about 0.5 to 3 turns. On the other hand, the number of turns of the tertiary coil L3-2 used for self-oscillation is, for example, the number of turns of turning the base side of the transistors 8 and 9 on, for example, several times. By taking the difference in the number of turns in this way, the control of the voltage applied to the fluorescent lamp can be made even at a low voltage, and the influence of noise can be reduced. In addition, as shown in (e) of FIG. 1, also in the case of the tertiary coil in the same transformer, in the tertiary coil used for self-oscillation and the tertiary coil used for indirect connection, the case of FIG. Similarly it is possible to change the number of turns.

In addition, although the embodiment shown as an indirect connection means so far is all about the coils of the same part of each inverter circuit, the definition of an indirect connection means is based on the inductive coupling effect which does not involve the movement of a carrier between inverter circuits. It is a bond. Therefore, various coils shown so far (ie, tertiary coils not used for self-oscillation, choke coils, secondary coils not used for power supply of the driven body, coils connected in parallel to tertiary coils used for self oscillation) The combination by a suitable combination of indirect connection is also considered to be an indirect connection. For example, direct connection of a "tertiary coil not used for self-oscillation" and "a secondary coil not used for power supply of a driven body" may be used, and the "choke coil" and a "tertiary coil used for self-oscillation may be used." Transformed coupling of coils connected in parallel ”may be used.

In the above, as an application example of the fluorescent tube lighting device described as the first to fifth embodiments, for example, a backlight used for a display device that requires a uniform planar light from the back, such as a transmissive liquid crystal display device The example applied to the apparatus is demonstrated.

<Example as Back Light>

The backlight device according to the present embodiment can be classified into two when classified into two, one of which is provided with a fluorescent tube facing a portion of the display screen, and diffuses the light emitted from the fluorescent tube into the light diffusion plate. It is a so-called direct backlight device which illuminates a display screen by making surface shape into uniform light, The other is the uniformity which installs a fluorescent tube in the side of a display screen, and illuminates a display screen with the light of a fluorescent tube by a light guide plate. It is a so-called side edge type backlight device which converts into one-sided light to illuminate the display screen.

The fluorescent tube lighting device described in the first to fifth embodiments can be applied to any type of backlight device. Hereinafter, as a sixth embodiment, the fluorescent tube lighting device is referred to as a direct type backlight device with reference to FIGS. 6 to 8. An application example will be described, and an application example to the side edge type backlight device will be described with reference to FIGS. 9 to 10 as the seventh embodiment.

FIG. 6 is a diagram showing a configuration example of a circuit used in the direct type backlight device according to the sixth embodiment of the present invention, wherein a plurality of fluorescent tube lighting devices according to the first embodiment of the present invention are provided, The configuration for synchronizing the simultaneous driving of the fluorescent tubes is shown. In FIG. 6, n represents a natural number, and n represents a designer selecting an optimal value (that is, the number of fluorescent tubes) according to the use state.

7 is a front view of the direct type backlight device which concerns on this embodiment, and FIG. 8 is a figure which shows the X-X arrow display cross section in FIG. In addition, although FIG. 7 and FIG. 8 in 4th Embodiment of this invention show the case where n value shown in FIG. 5 is 3 (that is, when the number of fluorescent tubes is 6), this is only an example, The number of fluorescent lamps can be changed as appropriate depending on the application.

As shown in Fig. 6, the fluorescent tube lighting apparatus according to the present embodiment includes the input terminals 1 and 2, the inverter circuits A1-B1, A2-B2,... And An-Bn, and each inverter circuit is provided with the first components LN1 to LNn, the second components LNa and LNb, and fluorescent lamps 15 and 16 as indirect connection means.

As shown in FIG. 7, FIG. 8, the direct type | mold backlight apparatus 30 connects and installs three sets of fluorescent tube lighting apparatuses described in the said 1st embodiment in parallel with DC power supply, and each fluorescent tube ( 15, 16 are uniformly spaced apart by a predetermined width, and between the shield frame 31 for accommodating the fluorescent tubes 15, 16, and between the shield frame 31 and the fluorescent tubes 15, 16. Fixing the formed reflecting plate 32, the light diffusing plate 33 disposed opposite to the side opposite to the reflecting plate 32 arrangement side of the fluorescent tubes 15, 16, and both ends of the fluorescent tubes 15, 16 Both ends of the fixing jig 34 and a center fixing jig 35 for fixing the center of the fluorescent tubes 15 and 16.

When the structure of each part except the part which was already demonstrated about the fluorescent tube lighting apparatus is demonstrated, the shield frame 31 is provided with the flange part extended in the direction opposite to the opening side in the outer periphery of the housing which one side opens. It is a shape, for example, can be formed by processing the board | plate material which consists of iron, aluminum, or a magnesium alloy by press work.

In addition, the reflecting plate 32 is formed of, for example, a film made of PET (polyethylene terephthalate) or the like containing a high reflectance material, and the majority of the light emitted from the fluorescent tube to the reflecting plate 32 arrangement side is formed. It is reflected by fluorescence observation. In addition, as this aspect, the reflecting plate 32 can also use what was formed by applying the high reflectance material to the shielding frame 31.

The light diffusion plate 33 is formed by, for example, containing a material having a high diffusivity in a transparent material of acrylic or polycarbonate, and uniformly diffuses light incident on the incident surface from the fluorescent tubes 15 and 16, thereby incidence It radiates from the radiation plane at the position opposite the plane.

In addition, the both ends fixing jig 34 supports both ends of the fluorescent tubes 15 and 16 in order to arrange | position them at a predetermined position, and the inverter circuits A and B are outside the this both ends fixing jig 34, and the shield part ( 31) is placed between. The central fixing jig 35 prevents the fluorescent tubes 15 and 16 having a long length from being bent by their own weight or the like.

The operation of the direct type backlight device 30 configured as described above will be described below. When a direct current is applied to the inverter circuits A and B, as described in each of the above embodiments, the inverter circuits A and B are oscillated, and the sinusoidal wave shapes of opposite phases are formed at both ends of the fluorescent tubes 15 and 16. Voltage is applied stably. As a result, the luminance at both ends of the fluorescent tubes 15 and 16 is made uniform. Then, the light generated from the fluorescent tube is incident on the incident surface of the light diffusion plate 33 and diffused, and is emitted from the radiation surface. At this time, since the luminance of both ends of each fluorescent tube is uniform, the light emitted from the emitting surface of the light diffusion plate 33 is uniformly emitted over the entire surface.

As mentioned above, according to the fluorescent tube lighting apparatus which concerns on this embodiment, the direct type backlight apparatus 30 which emits the light of uniform brightness from the light-diffusion plate 33 can be comprised. In addition, in this embodiment, although the example using the fluorescent tube lighting apparatus described in 1st Embodiment was described, the same effect can be acquired also when using the fluorescent tube lighting apparatus which concerns on 2nd-5th embodiment. .

Further, various modifications can be made to the arrangement positions of the inverter circuits A and B. For example, the inverter circuit may be provided on the side opposite to the reflecting plate 32 arrangement side of the shield 31. However, when the connection line between the secondary coil and the fluorescent tubes 15 and 16 becomes a high voltage, the power loss increases, and indeterminate factors such as stray capacitance are also likely to affect, which may cause noise. It is preferable to provide the portion as close as possible to both ends of the fluorescent tubes 15 and 16.

FIG. 9 is a front view of the backlight device using the fluorescent tube lighting device according to the seventh embodiment of the present invention, and FIG. 10 is a cross-sectional view showing a Y-Y arrow mark in FIG. 9. In addition, although FIG. 9 and FIG. 10 in 6th Embodiment show the case where n value in FIG. 6 is 2 (that is, when the number of fluorescent tubes is four), this is only an example and the The number above or below may be sufficient.

As shown in FIG. 9, the side edge type backlight device 40 arrange | positions the fluorescent tubes 15 and 16 in the side of the inside of the box-shaped housing 44 which has an opening part, and implements 1st implementation. The two fluorescent tube lighting apparatuses according to the form are connected in parallel to the DC power supply, and the light guide plate 41 disposed in the housing 44 to face the fluorescent tubes 15 and 16 and the fluorescent tube 15, 16, a reflecting plate 42 having an opening, and a rear reflecting plate 43 provided to face the surface on the side opposite to the radiation surface of the light guide plate 41. The configuration to install.

Referring to the configuration of each part except the fluorescent tube lighting device described above, the light guide plate 41 is made of a high transmittance material such as acrylic or polycarbonate having a predetermined thickness, and the fluorescent tubes 15 and 16 disposed on both sides. Light is incident from the side surface and emits light of approximately uniform surface shape from the radiation surface 45.

And the reflecting plate 42 and the back reflecting plate 43 are board | substrates provided with the film which consists of PET (polyethylene terephthalate) etc. which contain a high reflectivity material inside, for example, board | plate material of high reflectivity, and a board | plate material In this configuration, the light emitted from the fluorescent tube is reflected to the light guide plate 41 without attenuating as much as possible.

The operation of the edge light type backlight device 40 formed as described above will be described. When DC current is applied to the inverter circuits A and B, the inverter circuits A and B are self-contained as described in the above embodiments. The oscillation is performed, and a sinusoidal voltage of opposite phase is stably applied to both ends of the fluorescent tubes 15 and 16. As a result, the luminance at both ends of the fluorescent tubes 15 and 16 is made uniform. Since each fluorescent tube is synchronized, the luminance at both ends is uniform in any fluorescent tube.

The light generated from the fluorescent tube is incident on the incident surface of the light guide plate 41 and diffused, and is emitted from the radiation surface 45. At this time, since the luminance at both ends of each fluorescent tube is uniform, the luminance at both ends of the radiation surface of the light guide plate is also uniform.

As mentioned above, according to this embodiment, the side edge type backlight apparatus 40 which emits the light of uniform brightness in the plane from the radiation surface 45 of the light guide plate 41 can be used. In addition, in this embodiment, although the example using the fluorescent tube lighting apparatus described in 1st Embodiment was described, the same effect can be acquired even if using the fluorescent tube lighting apparatus described in 2nd-5th embodiment. have. Also, of course, the arrangement positions of the inverter circuits A and B are not limited to those shown in the seventh embodiment, of course.

As described above, in the backlight devices shown in the sixth and seventh embodiments, the shape of the fluorescent tube is based on a straight pipe shape, but the shape of the fluorescent tube is not limited in the first half of the present invention. , U, C letter, etc. may be used as appropriate. However, the straight tube type has a distance between two inverter circuits connected to both ends of the fluorescent tube from its shape, and as the lamp length increases, the distance increases, needless to say, the indirect connection shown up to now becomes effective.

In such a backlight device, the fluorescent tube may be arranged horizontally rather than vertically. This is because the horizontal arrangement makes the mercury distribution inside the fluorescent tube uniform without deflecting to either electrode, thereby extending the life of the fluorescent tube. Therefore, this makes it possible to uniformly control the light emission luminance distribution of the backlight device and to extend the lifespan of the backlight device.

Although the embodiments in the direct type backlight device and the embodiments in the side edge type backlight device have been described above, the liquid crystal panel is disposed so as to form a liquid crystal display device facing the radiation surface of these backlight devices. Since the uniformity of the light radiated | emitted from a backlight device is high, the liquid crystal display device with a favorable image quality with a uniform brightness | luminance over the whole screen can be comprised.

Next, an embodiment as an LCD will be described.

As an embodiment of this liquid crystal display, an example using a direct backlight device will be described as an eighth embodiment, and an example using a side edge backlight device will be described as a ninth embodiment.

<In the case of direct expression>

11 is a side view illustrating a configuration example of an LCD according to an eighth embodiment of the present invention. In addition, since the structure of a direct backlight apparatus is the same as that of the structure demonstrated in 6th Embodiment, description is abbreviate | omitted. As shown in FIG. 11, the liquid crystal display device 50 has a side opposite to the reflecting plate 32 arrangement side of the light diffusion plate 33 of the direct backlight device 30 (that is, the light diffusion plate ( On the radiation surface side of the light from 33), the optical sheet 52 and the liquid crystal panel 51 are arranged in this order. A liquid crystal panel driving device (not shown) is connected to the liquid crystal panel 51, and a gray scale signal of each pixel of the liquid crystal panel 51 is output from the liquid crystal panel driving device to display a desired image on the display screen.

When the structural example of each part is demonstrated, any liquid crystal panel 51 can be used as long as it is a transmissive liquid crystal panel, For example, what is a TFT (Thin Film Transistor) system can be used. Moreover, although the function requested | required by the kind of liquid crystal panel 51 etc. differs, the optical sheet 52 generally contains a polarizing film, a light-diffusion film, etc. However, as long as the liquid crystal panel 51 is a specification which does not require the optical sheet 52, the optical sheet 52 can be omitted.

As described above, since the uniform surface light is irradiated to the liquid crystal panel 51 from the direct backlight device 30 provided in the formed liquid crystal display device 50, the entire screen has a uniform luminance. An image with high image quality can be displayed.

<Edge light type>

It is a side view which shows the structural example of the liquid crystal display device which concerns on 9th Embodiment of this invention. In addition, since the structure of a side edge type backlight device is the same as that of what was demonstrated by the said 7th Embodiment, description is abbreviate | omitted.

As shown in FIG. 12, the liquid crystal display device 60 faces the radiation surface 45 of the side edge type backlight device 40, and is arranged in the order of the optical sheet 52 and the liquid crystal panel 51. It is. Incidentally, the optical sheet 52 and the liquid crystal panel 51 are the same as those described in the sixth embodiment, and the liquid crystal panel 51 is provided with a driving device of a liquid crystal panel not shown in the drawings. The same holds true for adjusting the gradation of a pixel.

Since the substantially uniform surface light is irradiated to the liquid crystal panel 51 from the side edge type backlight device 40 provided in the liquid crystal display device 60 having the above-described configuration, the entire screen has high quality with uniform luminance. Can display an image.

As described above, in the liquid crystal display devices shown in the eighth and ninth embodiments, the shape of the fluorescent tube is based on a straight tube shape, but the shape of the fluorescent tube is not limited in the first half of the present invention. If necessary, it can be used appropriately for the c-shaped building. However, the straight tube type has a distance between the two inverter circuits connected to both ends of the fluorescent tube from its shape, and the larger the lamp length is, the larger the distance is, and it goes without saying that the indirect connection shown up to now becomes effective.

In such a liquid crystal display device, the arrangement of the fluorescent tubes may be arranged horizontally with respect to the ground rather than in the vertical direction. This is because the mercury distribution inside the fluorescent tube in the horizontal arrangement becomes uniform without deflecting to either electrode, thereby extending the life of the fluorescent tube. Therefore, it becomes possible to uniformly control the light emission luminance distribution of a liquid crystal display device, and also to extend the lifetime as a liquid crystal display device.

As described above, when the inverter circuit according to the present invention is used, the voltage applied to both ends of the driven body can be stably reversed, so that the outputs of both ends of the driven body can be equalized.

In addition, since the fluorescent tube driving device according to the present invention can stably reverse the voltage across the fluorescent tube, the fluorescent tube driving device can be a fluorescent tube driving device capable of uniformly driving the luminance at both ends of the fluorescent tube. have.

In addition, the fluorescent tube driving apparatus according to the present invention is a fluorescent tube driving apparatus capable of uniformly driving the luminance of both ends of the fluorescent tube by using inverter circuits having mutually common specifications by connecting inverter circuits in opposite phases to each other. can do.

Moreover, the fluorescent tube drive apparatus which concerns on this invention can be set as the fluorescent tube drive apparatus with uniform brightness of two or more fluorescent tubes.

Moreover, since the fluorescent tube drive device which concerns on this invention can reduce the noise in each inverter circuit, it can be set as a low noise fluorescent tube drive device.

Moreover, since the fluorescent tube drive apparatus which concerns on this invention can reduce the noise transmitted between inverter circuits, it can be set as a low noise fluorescent tube drive apparatus.

Further, in the backlight device according to the present invention, since both ends of the fluorescent tube used in the backlight device emit light with uniform brightness, the backlight device can provide a uniform planar light emission.

Further, in the liquid crystal display device according to the present invention, since uniform light emission is provided from the backlight device, the luminance of the entire display screen can be made uniform, and a liquid crystal display device of high image quality can be obtained based thereon. .

Claims (42)

A pair of inverter circuits installed so that an alternating voltage is applied to each of both ends of the driven body, And an indirect connection means for indirectly connecting the pair of inverter circuits. The method of claim 1, And an alternating current voltage applied to each of both ends of the driven member has a phase relationship with each other. The method according to claim 1 or 2, The indirect connection means is a connection that does not involve movement of the conduction carrier of the pair of inverter circuits. The method according to any one of claims 1 to 3, And said indirect connection means is a connection using an inductive coupling effect. The method of claim 4, wherein The indirect connection means uses an inductive coupling of coils provided in each inverter circuit. The method of claim 5, The inductive coupling of the coil is used for coupling of tertiary coils which are not used for self-oscillation of the mutual inverter circuit, for coupling of choke coils of mutual inverter circuit, or for supplying power to a driven member of the mutual inverter circuit. An inverter circuit comprising couplings of secondary coils which are not provided or couplings of coils connected in parallel to tertiary coils used for self-oscillation. The method of claim 6, Couplings between tertiary coils not used for self-oscillation or couplings between secondary coils not used for power supply of the driven body include direct coupling, transformer intermediary coupling, or parallel coil proximity bonding. Inverter circuit, characterized in that. The method according to claim 6 or 7, When the inductive coupling of the coil is a coupling about tertiary coils not used for self oscillation of the mutual inverter circuit, the number of turns of the tertiary coils used for the indirect connection is less than that of the tertiary coils used for self oscillation. Inverter circuit. The method according to any one of claims 6 to 8, When the inductive coupling of the coil is a coupling about tertiary coils which are not used for self oscillation of the mutual inverter circuit, the secondary coils of the inverter transformer each having the tertiary coils used for self oscillation at both ends of the driven body And a secondary coil of an inverter transformer having a tertiary coil not used for oscillation. The method of claim 6, Couplings related to the choke coils or couplings of coils connected in parallel to tertiary coils used for self oscillation include transformer intermediary coupling, parallel coil proximity bonding, transforming coupling, or simple proximity bonding. Circuit. The method according to any one of claims 1 to 10, In the inverter circuit using the indirect connection means, Each inverter circuit includes two one input one output inverter transformers, and the primary coils of the two inverter transformers are mutually inverse windings. The method according to any one of claims 1 to 10, In the inverter circuit using the indirect connection means, Each inverter circuit is equipped with one 1 input 2 output inverter transformer, Inverter circuit, characterized in that the two secondary coils of the inverter transformer are mutually inverse. The method according to any one of claims 1 to 10, In the inverter circuit using the indirect connection means, Each inverter circuit has two 1 input 2 output inverter transformers, The two secondary coils of each inverter transformer are mutually inverse, Inverter circuit, characterized in that each of the primary coils of the two inverter transformers are mutually inverse. An inverter circuit according to any one of claims 1 to 13, A fluorescent tube lighting device having a fluorescent tube that is a driven body connected to the inverter circuit. The method of claim 14, It is a fluorescent tube lighting apparatus comprised using the said fluorescent tube lighting apparatus in plurality, The fluorescent tube lighting device is arranged so that all the fluorescent tubes are arranged in parallel, And an indirect connection means for indirectly connecting the respective fluorescent tube lighting apparatuses so that the applied voltage applied to each fluorescent tube is in a reversed phase for each one or the number of fluorescent tubes possessed by each fluorescent tube lighting apparatus. Fluorescent tube lighting device. The method of claim 15, The indirect connection means between the said fluorescent tube lighting apparatus uses the inductive coupling of the coil provided in each fluorescent tube lighting apparatus, The fluorescent tube lighting apparatus characterized by the above-mentioned. The method of claim 16, In the indirect connection means between the fluorescent tube lighting devices, the inductive coupling of the coils is a coupling about tertiary coils not used for self-oscillation of the mutual inverter circuit, or a coupling about choke coils of the mutual inverter circuit, or A coupling for a secondary coil not used for power supply of a driven body of a mutual inverter circuit, or a coupling for coils connected in parallel to a tertiary coil used for self oscillation. The method of claim 17, In the indirect connection means between the fluorescent tube lighting devices, the coupling about the tertiary coils not used for the self-oscillation or the coupling about the secondary coils not used for power supply of the driven member is a direct coupling or a transformer. A fluorescent tube lighting device comprising an intermediate coupling or a parallel coil proximity junction. The method of claim 17, In the indirect connection means between the fluorescent tube lighting devices, the couplings of the choke coils or the couplings of the coils connected in parallel to the tertiary coils used for self-oscillation include transformer intermediary coupling, parallel coil proximity bonding, and transformation coupling. Or a simple proximity junction. The backlight device which has the said fluorescent tube lighting device of any one of Claims 14-19. The fluorescent tube lighting display device of any one of claims 14 to 19, A reflecting plate disposed to face the fluorescent tube provided in the fluorescent tube lighting device and reflecting light emitted from the fluorescent tube to the fluorescent tube side; A light diffusion plate disposed to face the side opposite to the placement side of the reflection plate with the fluorescent tube; Back light device, characterized in that having a. The method of claim 20 or 21, A backlight device, wherein the fluorescent tubes are all arranged in parallel and in a horizontal direction. 23. A backlight apparatus according to any one of claims 20 to 22, and a liquid crystal panel which is provided to face the light emitting surface of the backlight apparatus, and that displays a predetermined image by varying light transmittance stepwise. Liquid crystal display device. An inverter circuit having a plurality of transformer transformers having a primary coil and a higher-order coil for converting a voltage input to the primary coil, and a self-oscillating circuit for converting direct current input to the primary coil into alternating current, are driven. In the inverter circuit provided at both ends of the At least one of the plurality of transformers of each inverter circuit has a plurality of higher order coils, means for connecting one of the higher order coils of the inverter transformer having the plurality of higher order coils with the self oscillating circuit, and the other An inverter transformer having a means for connecting to a driven body, a higher-order coil of an inverter transformer other than an inverter transformer having a higher-order coil connected to the self-oscillating circuit of one inverter circuit, and a higher-order coil connected to the self-oscillating circuit of the other inverter circuit. An inverter circuit comprising means for connecting a higher-order coil of another inverter transformer. An inverter transformer having at least one secondary coil and a plurality of feedback coils for one primary coil, and a self-oscillating circuit for converting a direct current input to the primary coil into an alternating current and generating the secondary coil; In an inverter circuit in which a pair of inverter circuits are provided at both ends of a driven body, At least one of the feedback coils of the feedback coils of the inverter transformer of each inverter circuit and the means for connecting the self-oscillating circuit, and at least one of the feedback coils not connected to the self-oscillating circuit of the inverter transformer of one inverter circuit; An inverter circuit comprising means for connecting at least one of a feedback coil which is not connected to the self-oscillating circuit of the inverter transformer of the inverter circuit. Install at least two inverter transformers having a primary coil, a secondary coil, and a feedback coil, connect the primary coils of each inverter transformer in parallel, and connect a common resonant capacitor in parallel with the primary coil of each inverter transformer. And attaching a center top to the primary coil of each inverter transformer and connecting each center top to a DC power source through a common choke coil, wherein both ends of the feedback coils of at least one inverter transformer of each inverter transformer Each output pole of the pair of switching elements is connected to both ends of the resonance capacitor, and the emitters of the pair of switching elements are grounded to each of the pair of switching elements. An inverter circuit in which a pair of self-oscillating inverter circuits for driving an element by a push-pull is provided at both ends of a driven body, Means for connecting both ends of the feedback coil of at least one inverter transformer not used for self oscillation in each inverter circuit, and means for grounding the other end of the secondary coil of the inverter transformer in each inverter circuit. Inverter circuit. The method of claim 24 or 26, An inverter having one of the secondary coils of the inverter transformer having a feedback coil used for self oscillation among the inverter transformers of one inverter circuit and an inverter having a feedback coil not used for self oscillation among the inverter transformers in the other inverter circuit An inverter circuit comprising one end of a secondary coil of a transformer connected through a fluorescent tube. At least one inverter transformer having a plurality of secondary coils and a plurality of feedback coils for one primary coil, a common resonant capacitor connected in parallel with the primary coil of each inverter transformer, and the A center top is attached to the primary coil, and each center top is connected to a DC power supply through a common choke coil, and at least one of the plurality of feedback coils of each inverter transformer of each inverter transformer is connected to a pair of switching elements. Each of the output poles of the pair of switching elements is connected to both ends of the resonant capacitor, and the emitters of the pair of switching elements are grounded to push-pull the pair of switching elements. As an inverter circuit provided with a pair of self-oscillating inverter circuits driven at both ends of a driven body, Each inverter circuit uses at least one feedback coil of the plurality of feedback coils of the inverter transformer to oscillate, At least one of the feedback coils of the inverter transformer of one inverter circuit other than the feedback coil used for self oscillation, at least one of the feedback coils of the inverter transformer of the other inverter circuit other than the feedback coil used for self oscillation Means for connecting the both ends of the feedback coil of the inverter coil, one end of each secondary coil of the inverter transformer of one inverter circuit, and one end of each secondary coil of the inverter transformer of the other inverter circuit, respectively, through a driven member. Means; and a means for grounding the other end of each secondary coil of the inverter transformer in each inverter circuit. The method according to any one of claims 24 to 28, An inverter circuit, wherein the number of turns of the feedback coils connected between the feedback coils of the inverter transformers of each inverter circuit is set smaller than the number of turns of the feedback coil to be used for oscillation. A fluorescent tube lighting device comprising: the inverter circuit according to any one of claims 24 to 29, and a fluorescent lamp is turned on by the inverter circuit using a fluorescent tube as the driven member. A plurality of inverter circuits according to any one of claims 24 to 29 are provided, and a fluorescent tube lighting device is connected to each inverter circuit as the driven member. The fluorescent tube lighting apparatus of Claim 30 or 31, the reflecting plate arrange | positioned facing the fluorescent tube with which the fluorescent tube lighting apparatus is equipped, and reflects the light emitted by a fluorescent tube to a fluorescent tube side, and the arrangement of the said reflecting plate of the said fluorescent tube And a light diffusion plate disposed opposite to the side opposite to the side. 32. A backlight device comprising the fluorescent tube lighting device according to claim 30 or 31 and a light guide plate for converting light emitted from the fluorescent tube included in the fluorescent tube lighting device into planar light. A liquid crystal panel comprising the backlight device according to claim 33, wherein the liquid crystal panel displays a predetermined image by varying the transmittance of light generated from the backlight device on the side opposite to the fluorescent tube arrangement side of the light diffusion plate of the backlight device. The liquid crystal display device characterized by the above-mentioned. A liquid crystal panel comprising the backlight device according to claim 34, wherein the liquid crystal panel is configured to display a predetermined image by changing a transmittance of light generated from the backlight device to face a surface emitting light of the light guide plate of the backlight device. A liquid crystal display device characterized by the above-mentioned. In the inverter circuit provided at both ends of the driven body, Means for connecting mutual inverter circuits such that alternating voltages across the driven body maintain opposite phase relations with each other. The inverter circuit of claim 36, And a fluorescent tube which is a driven member connected to the inverter circuit. The method of claim 37, As a fluorescent tube lighting apparatus comprised using the said fluorescent tube lighting apparatus in multiple numbers, The fluorescent tube lighting device is arranged so that all the fluorescent tubes are arranged in parallel, And an indirect connection means for indirectly connecting the respective fluorescent tube lighting apparatuses so that the applied voltage applied to each fluorescent tube is in a reversed phase for each one or the number of fluorescent tubes possessed by each fluorescent tube lighting apparatus. Fluorescent tube lighting device. The backlight device which has the fluorescent tube lighting device of Claim 37 or 38. The fluorescent tube lighting device of claim 37 or 38, A reflecting plate disposed to face the fluorescent tube provided in the fluorescent tube lighting device and reflecting light emitted from the fluorescent tube to the fluorescent tube side; A light diffusion plate disposed to face the side opposite to the placement side of the reflection plate with the fluorescent tube; Back light device, characterized in that having a. 41. The method of claim 39 or 40, And all of said fluorescent tubes are arranged in parallel and in a horizontal direction. 42. The backlight device according to any one of claims 39 to 41, And a liquid crystal panel which is provided to face the light emitting surface of the backlight device, and that displays a predetermined image by changing the transmittance of light in stages.