CN201435376Y

CN201435376Y - Electroless lamp

Info

Publication number: CN201435376Y
Application number: CN2009200577121U
Authority: CN
Inventors: 钟继业; 钟少乾
Original assignee: ZHONGSHAN CITY ZHONGMING ELECTRIC APPLIANCE CO Ltd
Current assignee: ZHONGSHAN CITY ZHONGMING ELECTRIC APPLIANCE CO Ltd
Priority date: 2009-06-02
Filing date: 2009-06-02
Publication date: 2010-03-31
Anticipated expiration: 2019-06-02

Abstract

The utility model discloses an electroless lamp, which comprises an electroless lamp body. The electroless lamp body is internally provided with an electroless lamp circuit which comprises an input filter, a slow-boosting rectifying circuit, a constant-voltage trigger circuit, a self-oscillation high-frequency convertor, and the like, wherein the slow-boosting rectifying circuit is connected withan output end of an input filter circuit. The utility model adopts the working principle that commercial power is converted into direct current firstly; the direct current is converted into high-frequency electric energy which generates a strong magnetic field through an induction coil at the central part of a bulb; magnetic field energy induces into the bulb to ensure that gas in the bulb is ionized to form plasma; activated mercury atoms in the plasma radiates ultraviolet with the wavelength of 254 nm; and fluorescence powder on the inner wall of the bulb is irradiated by the ultraviolet tobe converted into visible light. The utility model has the advantages of high lighting effect, high color rendering, no stroboscopic effect and long service life.

Description

A kind of electrodeless lamp

Technical field

The utility model relates to a kind of lighting device, particularly a kind of electrodeless lamp.

Background technology

At present, people the luminous lighting that generally uses with having fluorescent lamp, electricity-saving lamp, incandescent lamp etc., the operation principle of these light sources all heat by filament or the filament ionized gas luminous.But, they all ubiquity luminous efficiency low, power factor (PF) is low, logical light rate variance, color rendering is poor, has many shortcomings such as power frequency flicker of 50 hertz, and useful life instability, fragile.

The utility model content

In order to solve the above problems, the purpose of this utility model is to provide a kind of simple in structure have high light efficiency, high-color rendering, no stroboscopic and long-life electrodeless lamp.

The technical scheme that the invention for solving the technical problem adopted is: a kind of electrodeless lamp, and it comprises: electrodeless lamp lamp body, be provided with nonpolar lamp circuit in it, described nonpolar lamp circuit comprises:

Input filter, it can filtering import noise and high-frequency interferencing signal, and its input connects to exchange to be imported;

Slow boost rectifying circuit, the output of it and input filter circuit joins, and is used to export direct-current working volts;

Passive filter circuit, it links to each other with the output of slow boost rectifying circuit, can adjust power;

The level pressure circuits for triggering, it links to each other with the output of passive filter circuit, can guarantee the electron rectifier clean boot;

The self-oscillation high-frequency converter, it links to each other with the output of level pressure circuits for triggering, changes direct current into high-frequency ac, and then drives electrodeless lamp discharge cavity and carry out luminous work.

As the further improvement of above-mentioned execution mode, described passive filter circuit is for pursuing the stream filter circuit.

As the further improvement of above-mentioned execution mode, described input filter comprises common mode inductance and is connected across the filter capacitor at its two ends.

Further improvement as above-mentioned execution mode, described slow boost rectifying circuit comprises the bridge rectifier of being made up of first rectifier diode, second rectifier diode, the 3rd rectifier diode and the 4th rectifier diode, and described the 3rd rectifier diode is parallel with boost capacitor.

As the further improvement of above-mentioned execution mode, described passive filter circuit comprises the first low frequency filtering electric capacity, the second low frequency filtering electric capacity, first diode, second diode and the 3rd diode; Described first diode, second diode and the series connection of the 3rd diode, the both positive and negative polarity of second diode is connected with the negative pole of first diode, the positive pole of second diode respectively, the both positive and negative polarity of the described first low frequency filtering electric capacity is connected with the negative pole of first diode, the positive pole of second diode respectively, and the both positive and negative polarity of the described second low frequency filtering electric capacity is connected with the negative pole of second diode, the positive pole of the 3rd diode respectively; The negative pole of the positive pole of the 3rd diode and first diode connects the output of described bridge rectifier respectively.

Further improvement as above-mentioned execution mode, described level pressure circuits for triggering comprise first divider resistance, second divider resistance, storage capacitor, bidirectional trigger diode and the 4th diode, described divider resistance is connected with divider resistance, first divider resistance and the second divider resistance common port are connected the positive pole of two-way trigger and the 4th diode respectively, described the 4th diode other end connects the self-oscillation high-frequency converter, the other end of the described two-way trigger other end and second divider resistance is the output of described level pressure circuits for triggering, described storage capacitor is in parallel with divider resistance, described first divider resistance, second divider resistance connects the output of passive filter circuit respectively.

Further improvement as above-mentioned execution mode, described self-oscillation high-frequency converter comprises first field-effect transistor, second field-effect transistor, coupling transformer, inductance coil, the loading coil and first electric capacity, second electric capacity, the 3rd electric capacity, the primary coil of described coupling transformer connects the output of described level pressure circuits for triggering, one end of described coupling transformer first secondary coil and second subprime coil connects the grid of first field-effect transistor and second field-effect transistor respectively, the source electrode of described first field-effect transistor is connected with the drain electrode of second field-effect transistor, the drain electrode of described first field-effect transistor is connected with the level pressure circuits for triggering, and the source electrode of described second field-effect transistor connects the other end of described coupling transformer second subprime coil; Described first parallel connection of secondary windings has first voltage stabilizing didoe and second voltage stabilizing didoe of mutual series connection, and the negative pole of described first voltage stabilizing didoe is connected with the negative pole of second voltage stabilizing didoe; Described second subprime coils from parallel connection of coils has the 3rd voltage stabilizing didoe and the 4th voltage stabilizing didoe of mutual series connection, and the negative pole of described the 3rd voltage stabilizing didoe is connected with the negative pole of the 4th voltage stabilizing didoe; Described coupling transformer first secondary coil is connected source electrode and second field-effect transistor drain electrode common port and the inductance coil of first field-effect transistor with the common port of second voltage stabilizing didoe, the described inductance coil other end connects first electric capacity respectively, second electric capacity and the 3rd electric capacity, described first electric capacity the other end connect an end of coupling transformer primary coil, the described second electric capacity other end connects loading coil, the other end of described loading coil connects the source electrode of second field-effect transistor, and the other end of described the 3rd electric capacity connects the source electrode of second field-effect transistor.

The beneficial effects of the utility model are: the utility model at first is converted to direct current to civil power, be transformed into high-frequency electrical energy again, high-frequency electrical energy produces high-intensity magnetic field by the induction coil in bulb centre, magnetic field energy is responded in the bulb, make gas avalanche ionization formation plasma in the bulb, the mercury atom of being excited in the plasma gives off the ultraviolet ray of 254nm in returning the ground state process, bulb inner wall fluorescent material is subjected to ultraviolet irradiation and converts visible light to, has high light efficiency, high-color rendering, no stroboscopic and long-life good characteristic.The special slow boost rectifying circuit of the utility model setting and level pressure circuits for triggering have effectively solved the clean boot problem of electrodeless lamp.This electron rectifier circuit structure is simple, with low cost, can produce in batches, substitutes existing incandescent lamp and electricity-saving lamp.

Description of drawings

The utility model is described in further detail below in conjunction with drawings and Examples:

Fig. 1 is a theory diagram of the present utility model;

Fig. 2 is circuit theory diagrams of the present utility model.

Embodiment

With reference to Fig. 1, Fig. 2, a kind of electrodeless lamp comprises electrodeless lamp lamp body, is provided with nonpolar lamp circuit in it, and described nonpolar lamp circuit comprises:

(1) input filter: be made up of common mode inductance L5 and the filter capacitor C2, the C3 that are connected across its two ends, be used for filtering input noise and high-frequency interferencing signal, its input connects to exchange to be imported.

(2) slow boost rectifying circuit: described slow boost rectifying circuit comprises by the first rectifier diode D1, the second rectifier diode D2, the bridge rectifier that the 3rd rectifier diode D8 and the 4th rectifier diode D9 form, described the 3rd rectifier diode D8 is parallel with boost capacitor C7, the output of it and input filter circuit joins, be used to export direct-current working volts, boost capacitor C7 capacity is less, generally be passive filter circuit medium and low frequency filter capacitor C1,1/10～1/100 of C6 capacity, before electrodeless lamp starts, the output voltage of rectification circuit slowly rises, its peak approaches 2.2 times of input alternating voltage, after the electrodeless lamp startup work, the output voltage of slow boost rectifying circuit descends rapidly, its voltage peak maintains about 2.2 times of input alternating voltage, and this has just created condition for the clean boot of electrodeless lamp.

(3) passive filter circuit: comprise the first low frequency filtering capacitor C 1, the second low frequency filtering capacitor C 6, the first diode D4, the second diode D6 and the 3rd diode D10; The described first diode D4, the second diode D6 and the 3rd diode D10 series connection, the both positive and negative polarity of the second diode D6 is connected with the negative pole of the first diode D4, the positive pole of the second diode D6 respectively, the both positive and negative polarity of the described first low frequency filtering capacitor C 1 is connected with the negative pole of the first diode D4, the positive pole of the second diode D6 respectively, and the both positive and negative polarity of the described second low frequency filtering capacitor C 6 is connected with the negative pole of the second diode D6, the positive pole of the 3rd diode D10 respectively; The negative pole of the positive pole of the 3rd diode D10 and the first diode D4 connects the output of described bridge rectifier respectively, be used for filtering and power factor correction, interlocking is in DC power-supply circuit, and this circuit is to have pursuing of power adjustment functions to flow filter circuit, also can adopt other passive filter circuit.

(4) level pressure circuits for triggering: comprise the first divider resistance R1, the second divider resistance R2, storage capacitor C8, bidirectional trigger diode D11 and the 4th diode D3, described divider resistance R1 connects with divider resistance R2, the first divider resistance R1 and the second divider resistance R2 common port are connected the positive pole of two-way trigger D11 and the 4th diode D3 respectively, described the 4th diode (D3) other end connects the self-oscillation high-frequency converter, the other end of the described two-way trigger D11 other end and the second divider resistance R2 is the output of described level pressure circuits for triggering, described storage capacitor C8 is in parallel with divider resistance R2, the described first divider resistance R1, the second divider resistance R2 connects the output of passive filter circuit respectively.It is connected in the direct-flow input circuit, and its output is connected on the primary coil of coupling transformer T1; In order to protect bidirectional trigger diode; it is no longer produced for the second time after startup triggers; the mid point of divider resistance is connected to the path that is connected to field-effect transistor Q1, Q2 drain electrode, by the unidirectional conducting discharge of diode D3, does not allow it arrive the trigger voltage rated value again.The cooperation of slow boost rectifying circuit and level pressure circuits for triggering has solved the clean boot problem of electrodeless lamp electron rectifier.

(5) self-oscillation high-frequency converter: comprise the first field-effect transistor Q1, the second field-effect transistor Q2, coupling transformer T1, inductance coil L1, the loading coil L2 and first capacitor C 4, second capacitor C 5, the 3rd capacitor C 9, the primary coil of described coupling transformer T1 connects the output of described level pressure circuits for triggering, the end of described coupling transformer first secondary coil L3 and second subprime coil L4 connects the grid of the first field-effect transistor Q1 and the second field-effect transistor Q2 respectively, the source electrode of the described first field-effect transistor Q1 is connected with the drain electrode of the second field-effect transistor Q2, the drain electrode of the described first field-effect transistor Q1 is connected with the level pressure circuits for triggering, and the source electrode of the described second field-effect transistor Q2 connects the other end of described coupling transformer second subprime coil L4; The described first secondary coil L3 is parallel with the first voltage stabilizing didoe D5 and the second voltage stabilizing didoe D7 of mutual series connection, and the negative pole of the described first voltage stabilizing didoe D5 is connected with the negative pole of the second voltage stabilizing didoe D7; Described second subprime coil L3 is parallel with the 3rd voltage stabilizing didoe D12 and the 4th voltage stabilizing didoe D13 of mutual series connection, and the negative pole of described the 3rd voltage stabilizing didoe D12 is connected with the negative pole of the 4th voltage stabilizing didoe D13, makes the usefulness of bi-directional voltage stabilizing; The described coupling transformer first secondary coil L3 is connected the source electrode of the first field-effect transistor Q1 and the common port and the inductance coil L1 of second field-effect transistor Q2 drain electrode with the common port of the second voltage stabilizing didoe D7, the described inductance coil L1 other end connects first capacitor C 4 respectively, second capacitor C 5 and the 3rd capacitor C 9, described first capacitor C 4 the other end connect an end of the primary coil of coupling transformer, described second capacitor C, 5 other ends connect loading coil L2, the other end of described loading coil L2 connects the source electrode of the second field-effect transistor Q2, and the other end of described the 3rd capacitor C 9 connects the source electrode of the second field-effect transistor Q2.

The main feature of the utility model circuit has been to use special slow boost rectifying circuit and level pressure circuits for triggering to finish the clean boot of electrodeless lamp jointly.Because electrodeless lamp when starting, needs bigger starting power, and it is less to start the required holding power in back.This novel electron rectifier circuit energy clean boot work, its thinking is: before lamp starts, no matter whether public AC power is on the low side, DC power supply voltage after its rectification can both reach the higher voltage scope, and a certain design point triggering startup in the higher voltage scope, so that enough big starting power to be provided; And after lamp started, the voltage of the DC power supply after its rectification returned to the normal condition behind the common bridge rectifier, can provide normal design power to guarantee the operate as normal of electrodeless lamp.When electric network source was the 220V alternating current, the voltage after the slow boost rectifying circuit II of process carries out bridge rectifier and boosts was in the higher voltage value, and this magnitude of voltage is positioned between 220V and the 2 * 220V; In level pressure circuits for triggering IV, this DC input voitage to storage capacitor C8 charging, reaches the trigger voltage V of bidirectional trigger diode D11 when the voltage at storage capacitor C8 two ends after divider resistance R1, R2 dividing potential drop _STThe time, trigger tube triggering work.Can change the ratio of R1, R2, when designing trigger tube triggering work, DC input voitage is in a higher voltage value (this value is positioned between 220V and the 2 * 220V), just can provide sufficiently high input power like this when starting, thereby guarantees that circuit safety starts; But after the clean boot, because the capacity of the Capacity Ratio low frequency filtering capacitor C 1 of boost capacitor C7, C6 is much smaller, DC input voitage returns to lower value (this value is less than 220V) behind the common bridge rectifier.In fact, even when public AC supply voltage is very low (such as 160V), at this moment its DC input voitage that triggers when starting still is in a higher voltage design load (this value is positioned between 220V and the 2 * 220V), thereby guarantees its clean boot.

The invention is not limited to above-mentioned execution mode, as long as it reaches technique effect of the present utility model with essentially identical means, all should belong to protection range of the present utility model.

Claims

1, a kind of electrodeless lamp is characterized in that: comprise electrodeless lamp lamp body, be provided with nonpolar lamp circuit in it, described nonpolar lamp circuit comprises:

The level pressure circuits for triggering, it links to each other with the output that has no chance filter circuit, can guarantee the electron rectifier clean boot;

2, electrodeless lamp according to claim 1 is characterized in that: described passive filter circuit is for pursuing the stream filter circuit.

3, electrodeless lamp according to claim 1 is characterized in that: described input filter comprises common mode inductance (L5) and is connected across the filter capacitor (C2, C3) at its two ends.

4, electrodeless lamp according to claim 1, it is characterized in that: described slow boost rectifying circuit comprises the bridge rectifier of being made up of first rectifier diode (D1), second rectifier diode (D2), the 3rd rectifier diode (D8) and the 4th rectifier diode (D9), and described the 3rd rectifier diode D8 is parallel with boost capacitor (C7).

5, electrodeless lamp according to claim 1 and 2 is characterized in that: described passive filter circuit comprises the first low frequency filtering electric capacity (C1), the second low frequency filtering electric capacity (C6), first diode (D4), second diode (D6) and the 3rd diode (D10); Described first diode (D4), second diode (D6) and the 3rd diode (D10) series connection, the both positive and negative polarity of second diode (D6) is connected with negative pole, second diode (D6) positive pole (D6) of first diode (D4) respectively, the both positive and negative polarity of the described first low frequency filtering electric capacity (C1) is connected with the negative pole of first diode (D4), the positive pole of second diode (D6) respectively, and the both positive and negative polarity of the described second low frequency filtering electric capacity (C6) is connected with the negative pole of second diode (D6), the positive pole of the 3rd diode (D10) respectively; The negative pole of the positive pole of the 3rd diode (D10) and first diode (D4) connects the output of described bridge rectifier respectively.

6, electrodeless lamp according to claim 1, it is characterized in that: described level pressure circuits for triggering comprise first divider resistance (R1), second divider resistance (R2), storage capacitor (C8), bidirectional trigger diode (D11) and the 4th diode (D3), described divider resistance (R1) is connected with divider resistance (R2), first divider resistance (R1) and second divider resistance (R2) common port are connected the positive pole of two-way trigger (D11) and the 4th diode (D3) respectively, described the 4th diode (D3) other end connects the self-oscillation high-frequency converter, the other end of described two-way trigger (D11) other end and second divider resistance (R2) is the output of described level pressure circuits for triggering, described storage capacitor (C8) is in parallel with divider resistance (R2), described first divider resistance (R1), second divider resistance (R2) connects the output of described passive filter circuit respectively.

7, electrodeless lamp according to claim 1, it is characterized in that: described self-oscillation high-frequency converter comprises first field-effect transistor (Q1), second field-effect transistor (Q2), coupling transformer (T1), inductance coil (L1), loading coil (L2) and first electric capacity (C4), second electric capacity (C5), the 3rd electric capacity (C9), the primary coil of described coupling transformer (T1) connects the output of described level pressure circuits for triggering, one end of described coupling transformer first secondary coil (L3) and second subprime coil (L4) connects the grid of first field-effect transistor (Q1) and second field-effect transistor (Q2) respectively, the source electrode of described first field-effect transistor (Q1) is connected with the drain electrode of second field-effect transistor (Q2), the drain electrode of described first field-effect transistor (Q1) is connected with the level pressure circuits for triggering, and the source electrode of described second field-effect transistor (Q2) connects the other end of described coupling transformer second subprime coil (L4); Described first secondary coil (L3) is parallel with first voltage stabilizing didoe (D5) and second voltage stabilizing didoe (D7) of mutual series connection, and the negative pole of described first voltage stabilizing didoe (D5) is connected with the negative pole of second voltage stabilizing didoe (D7); Described second subprime coil (L3) is parallel with the 3rd voltage stabilizing didoe (D12) and the 4th voltage stabilizing didoe (D13) of mutual series connection, and the negative pole of described the 3rd voltage stabilizing didoe (D12) is connected with the negative pole of the 4th voltage stabilizing didoe (D13); Described coupling transformer first secondary coil (L3) is connected the source electrode of first field-effect transistor (Q1) and the common port and the inductance coil (L1) of second field-effect transistor (Q2) drain electrode with the common port of second voltage stabilizing didoe (D7), described inductance coil (L1) other end connects first electric capacity (C4) respectively, second electric capacity (C5) and the 3rd electric capacity (C9), the other end of described first electric capacity (C4) connects an end of coupling transformer (T1) primary coil, described second electric capacity. (C5) other end connects loading coil (L2), the other end of described loading coil (L2) connects the source electrode of second field-effect transistor (Q2), and the other end of described the 3rd electric capacity (C9) connects the source electrode of second field-effect transistor (Q2).