The aspects of the present disclosure relate generally to ballasts for powering gas discharge lamps, and in particular to preheat circuits for electronic ballasts used to drive gas-discharge lamps.
A gas-discharge lamp belongs to a family of electric lighting or light generating devices that generate light by passing an electric current through a gas or vapor within the lamp. Atoms in the vapor absorb energy from the electric current and release the absorbed energy as light. One of the more widely used types of gas-discharge lamps is the fluorescent lamp which is commonly used in office buildings and homes. Fluorescent lamps contain mercury vapor whose atoms emit light in the non-visible low wavelength ultraviolet region. The ultraviolet radiation is absorbed by a phosphor disposed on the interior of the lamp tube causing the phosphor to luminesce, thereby producing visible light.
Current flow through a fluorescent lamp is generally achieved by placing cathodes at either end of the lamp tube to inject electrons into a vapor within the lamp. These cathodes are structured as filaments that are coated with an emissive material used to enhance electron injection. The emission mix typically comprises a mixture of barium, strontium, and calcium oxides. A small electric current is passed through the filaments to heat them to a temperature that overcomes the binding potential of the emissive material allowing thermionic emission of electrons to take place. When an electric potential is applied across the lamp, electrons are liberated from the emissive material coating on each filament causing a current to flow. While a lamp is in operation, and especially when a lamp is ignited, the emission mix is slowly sputtered off the filaments by bombardment with electrons and mercury ions. Over time, the emission mix is sputtered off of the cathodes in normal operation, but a larger amount is sputtered off when the lamp is ignited with cold cathodes. When the emission mix becomes depleted, a higher voltage is required for the cathodes to emit electrons, a condition sometimes referred to as end-of-life (“EOL”). The higher voltage results in an increase in temperature which may overheat the lamp and in some cases crack the glass if the lamp is not replaced.
Electronic ballasts for gas discharge lamps can be classified as preheat and instant start. In preheat ballasts, the lamp filaments are heated for a limited period of time before a lamp voltage is applied across the lamp to ignite the lamp. In instant start ballasts, the lamp filaments are not preheated, and a higher starting voltage is typically applied to ignite the lamps.
Fluorescent lamps, including compact fluorescent lamps (CFLs), include cathodes (filaments) which are preferably preheated before ignition to extend the operational life of the lamp. Conventional low cost CFL ballasts often use a positive temperature coefficient (PTC) thermistor to heat the lamp cathodes of the lamp prior to ignition (preheat). The PTC is coupled in parallel with a capacitor connected across the CFL, and initially conducts allowing preheating current to flow through the lamp cathodes. With continued conduction, the PTC device heats up and the PTC resistance increases, eventually triggering ignition of the gas in the lamp. The PTC, moreover, is typically situated in close proximity to the lamp to keep the PTC in the high-impedance condition during normal operation of the lamp. However, PTC devices are costly and occupy valuable space in the ballast. In addition, the PTC element never reaches infinite impedance and thus conducts some amount of current throughout operation of the ballast (even if some of the energy to keep the PTC device warm comes from lamp heating). Thus, the use of PTC devices for cathode preheating negatively impacts ballast efficiency. Furthermore, PTC preheating circuits need time to cool before reapplication of power to avoid cold-cathode ignition and the associated lamp degradation. Thus, a need remains for improved ballasts and techniques for preheating fluorescent lamp cathodes without using PTC components.
Accordingly, it would be desirable to provide a preheat circuit for an electronic ballast that resolves at least some of the problems identified above.
As described herein, embodiments of the present disclosure overcome one or more of the above or other disadvantages known in the art.
An embodiment of the present disclosure relates to a filament preheat module for preheating a filament of a lamp that is powered by a power circuit including an inverter having an inductively coupled conductor. In an embodiment, the filament preheat module includes a winding, the winding of the filament preheat module magnetically coupled to the inductively coupled conductor of the inductor to power the filament during preheating. A switching circuit is configured to electrically connect the power from the winding of the filament preheat module to the filament. The switching module is configured to cutoff the power to the filament from the filament preheat module after a predetermined time period during preheating.
An embodiment of the present disclosure is directed to a circuit for preheating a filament of a lamp. In an embodiment, the circuit includes a filament preheating circuit electrically coupled to the filament, an inverter including a inductively coupled conductor configured to be magnetically coupled to the filament preheating circuit to provide electrical power to the filament, and a switching device configured to enable power to flow from filament preheating circuit to the filament in a preheating stage.
An embodiment of the present disclosure is directed to a ballast for driving a gas discharge lamp. In an embodiment, the ballast includes an inverter configured to generate a lamp supply voltage signal and a filament preheat circuit electrically coupled to an inductively coupled conductor of the inverter and the gas discharge lamp. The filament preheat circuit is configured to preheat a filament of the gas discharge lamp. In an embodiment, the filament preheat circuit includes a winding magnetically coupled to inductively coupled conductor of the inverter, the winding configured to provide electrical power to the filament during preheating. A switching circuit is configured to electrically connect the power from the winding of the filament preheat module to the filament, wherein the switching module is configured to enable power to the filament during preheating and cutoff the power to the filament from the filament preheat module after a predetermined time period during preheating.
These and other embodiments and advantages of embodiments of the present disclosure will become apparent from the following detailed description considered in conjunction with the accompanying drawings. It is to be understood, however, that the drawings are designed solely for purposes of illustration and not as a definition of the limits of the invention, for which reference should be made to the appended claims. Additional aspects and advantages of the invention will be set forth in the description that follows, and in part will be obvious from the description, or may be learned by practice of the invention. Moreover, the aspects and advantages of the invention may be realized and obtained by means of the instrumentalities and combinations particularly pointed out in the appended claims.
These and other features, aspects, and advantages of the present disclosure will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein;
Referring to
The filament preheating circuit 200 of the disclosed embodiments does not require a high voltage cutoff switch. Rather, the filament preheating circuit 200 of the disclosed embodiments is powered from a winding of the resonant inductor or transformer of the inverter circuitry of the electronic ballast 10, referred to as the preheat winding, and is cutoff from the inverter power section 14 automatically by a switch signal. The filament preheating circuit 200 of the disclosed embodiments does not need to have a common “reference ground” as does the inverter power section 14, which means it can be equipped with the isolation from the inverter power section 14. The voltage of the preheating winding remains low, typically 5V˜10V, thus enabling the use of low voltage, and low cost switching and other components, and also the use of a preheating inductor or transformer in the filament preheat circuit that is built with less copper and smaller core size, such as for example, a ring core transformer .
In the exemplary embodiments described herein, the lamp load module 30 includes one or more gas discharge lamps as well as ballasting components and filament heating circuitry. An inverter power section 14 receives switch gating signals 13, 15, also referred to as gate drive signals, from a gate drive circuit 12 which operates the inverter 10 and adjusts or regulates the frequency of the inverter 10. The preheat circuit module 200 is generally configured to preheat the lamp filaments in the lamp load module 30 by drawing energy from an inductively coupled conductor of the preheat circuit module 220, such as a winding, coupled with an inductively coupled conductor of the inverter power circuit 14, such as for example, an inductor or transformer. The preheat module 200 of the disclosed embodiments eliminates the need for a high voltage cutoff switch and can also be used to provide the preheating energy to multiple lamp filaments.
The DC input voltage 20 is received onto the positive and ground rails 212, 214 and is selectively switched by switching devices Q1 and Q2 connected in series between the positive rail 212 and ground rail 214. The selective switching of switching devices Q1 and Q2 generally operates to generate a square wave at an inverter output node 218, which in turn excites the resonant tank circuit 216 to thereby drive the lamp supply voltage 17. In an embodiment, the square wave has an amplitude of approximately one-half the DC input voltage 20 at the inverter output node 218. The frequency of the square wave generated at node 218 can be referred to as the frequency of the inverter or as the inverter frequency. In an embodiment, the inverter frequency is approximately 70 kilohertz, although any suitable or desired inverter frequency may be used. The resonant tank 216 includes an inductively coupled conductor L1-1, referred to as resonant inductor L1-1, as well as an equivalent capacitance, generally comprising the equivalent of capacitors C1 and C2 connected in series between the positive rail 212 and the ground rail 214 with a center node 220 coupled to the lamp supply voltage by capacitor C3. A clamping circuit is formed by diodes D1 and D2 individually connected in parallel with the capacitances C1 and C2, respectively. The lamp supply voltage 17 is used to drive the lamp load 30, which in the embodiment of
The preheat circuit 200 shown in
In the embodiment shown in
In this embodiment, the filament preheating circuit 200 is energized by an inductively coupled conductor or winding L1-2 of the resonant inverter power section 14. The winding L1-2 can be taken from a resonant inductor or transformer of the resonant inverter power section 14, such as for example transformer winding L1-1 shown in
As is illustrated in
In the embodiment shown in
In an embodiment, a first delay circuit 210 is used to control the switching ON of the switch Q201. The first delay, controlled by the RC timing of the first delay circuit, causes the first switch Q201 to switch ON after a pre-determined time period. For example, once the resonant inverter 10 starts to resonate, and the winding L1-2 of the filament preheat module 200 absorbs the energy coupled from winding L1-1 of the inverter power section 14. The switch Q201 switches ON after a short delay, which is a result of the RC combination of the first delay circuit.
In the example of
A second delay circuit 220 is used to control the switching of device Q202 to the ON state. The second delay, controlled by the RC timing of the second delay circuit 220, causes the switch Q202 to switch to the ON state, which causes switch Q201 to switch OFF. In the example of
When Q201 is ON, Q202 is OFF, and the preheat circuit 200 starts energizing the filaments of lamps 201, 203. Thus, current passes from the preheating circuit 200 through terminals J1, J2 and through the filament of the lamps 201, 203 shown in
During the preheating stage, the voltage across capacitor C203 starts to increase until the voltage at circuit node or point A reaches the break down voltage of zener diode D201. When the voltage across C203 reached the threshold voltage of Q202, the switch Q202 will be in the ON state. When Q202 is ON, switching device Q201 is switched to a non-conducting or OFF state. In the OFF state of Q201, the preheating current to the filaments of lamps 201, 203 through terminals J1, J2 is cut-off. This is the end of the preheating stage.
In the examples of
As is shown in
The aspects of the disclosed embodiments provide preheating energy from a winding of the preheat circuit that is magnetically coupled to a winding of the resonant inductor or transformer. Since the preheat circuit draws power from the resonant inductor or transformer and can be configured with isolating from the resonant inverter, a high voltage switch is not required The preheating transformer could be equipped with less copper and smaller core size, using for example a low cost ring core transformer. The preheat energy can be cutoff automatically from the resonant inverter by the switch signal. The preheating current to the lamp filaments generally approximates a standard sine (or cosine) wave signal, which produces less electromagnetic interference, than a pulse wave signal used to ignite ballasts. The preheat circuit uses less components, is low cost and can be used for example, in a programmed start electronic ballast.
Thus, while there have been shown, described and pointed out, fundamental novel features of the invention as applied to the exemplary embodiments thereof, it will be understood that various omissions and substitutions and changes in the form and details of devices and methods illustrated, and in their operation, may be made by those skilled in the art without departing from the spirit and scope of the invention. Moreover, it is expressly intended that all combinations of those elements and/or method steps, which perform substantially the same function in substantially the same way to achieve the same results, are within the scope of the invention. Moreover, it should be recognized that structures and/or elements and/or method steps shown and/or described in connection with any disclosed form or embodiment of the invention may be incorporated in any other disclosed or described or suggested form or embodiment as a general matter of design choice. It is the intention, therefore, to be limited only as indicated by the scope of the claims appended hereto.
Number | Date | Country | Kind |
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201210502418.3 | Nov 2012 | CN | national |