Grid controlled gas discharge lamp

Abstract

 A low pressure gas discharge lamp (such as a fluorescent lamp) which includes a wire mesh grid (32) disposed within the lamp envelope (10) so as to intercept the electrons flowing between the lamp electrodes. A lead wire (38) extends from the grid (32) to the outside of the lamp envelope (10), when the grid (32) is provided with a negative voltage with respect to the surrounding plasma the lamp may be switched off. The grid controlled lamp eliminates the need for a solid state power switch in the lamp driving circuitry. As such, the lamp current flows only through the lamp not through the electronic ballast/lamp driving circuitry. With the lamp current removed from the ballast circuitry, power dissipation problems in the driver circuitry are eliminated. The grid controlled lamp design greatly facilitates circuit design.

Description

[0001] The invention relates to a low pressure gas discharge lamp comprising an envelope, first and second electrodes disposed within said envelope, an ionizable gas filling said envelope, said gas becoming a changed plasma when a current flows between said first and second electrodes, and comprising a conductive grid disposed within said envelope, which lamp is provided with means for electrical connection to said grid.

[0002] A lamp according to the preamble is known from CA 685386.

[0003] Fluorescent lamps are in wide use because of their relatively high efficiency, low cost and long life. A fluorescent lamp is a low pressure mercury gas discharge lamp. As with all gas discharge lamps, fluorescent lamps have a negative resistance characteristic and require ballast circuitry to prevent current runaway. For many years the conventional ballast has been a copper/iron choke. However, in recent years, electronic ballasts for gas discharge lamps have become increasingly popular in the lighting industry. Apart from being more efficient than the conventional choke, the electronic ballast is lighter and offers the possibility of adding additional control features to the lamp such as dimming and lamp power stabilization. A disadvantage of electronic ballasts is their high price due in part to their requirement for the use of relatively expensive solid state power switches isn the control circuitry. A solid state power switch is relatively expensive and must carry large amounts of current. As such, the heat generated solid state power switch is not inconsequential and must be factored into the design of the ballast circuitry.

[0004] The present invention provides a lamp design in which the lamp itself functions as part of its own driver circuitry. The lamp itself operates as its own active high current component eliminating the need for high current devices in the electronic ballast/driving circuitry.

[0005] The present invention is directed to a low pressure gas discharge lamp (such as a fluorescent lamp) which includes a wire mesh grid disposed within the lamp envelope so as to intercept the plasma between the lamp electrodes. A lead wire extends from the grid to the outside of the lamp envelope. When the grid is provided with a negative voltage with respect to the surrounding plasma the lap may be switched off. The grid controlled lamp eliminates the need for a solid state power switch in the ballast circuitry. As such, the lamp current flows only through the lamp, not through the electronic ballast/lamp driving circuitry. With the lamp current removed from the ballast circuitry, power dissipation problems in the driver circuitry are eliminated. Only low current switches in the driving circuitry are required as the lamp current flows only through the lamp and not to the grid. The grid controlled lamp design greatly facilitates circuit design and integrated the lamp and its switching function.

[0006] For a better understanding of the invention reference is made to the following drawing which are to be taken in conjunction with the detailed specification to follow:

Fig. 1 is a sectional view of a first embodiment of a grid controlled gas discharge lamp;

Fig. 2 is another embodiment of a grid controlled discharge lamp;

Fig. 3a is a schematic diagram of the circuitry which may be utilized to test the operational parameters of grid controlled gaseous discharge lamps, Figs. 3b and 3c illustrate the lamp voltage and current in response to the driving pulses;

Fig. 4 is a chart of the minimum grid voltage required to interrupt the discharge lamp current of the lamp of Fig. 1 versus lamp currents; at differing mesh sizes;

Fig. 5 is a chart of minimum grid voltage required to interrupt the current of the gaseous discharge lamp of Fig. 2 versus lamp current for a variety of mesh sizes;

Fig. 6 is a chart of grid current as a function of lamp current for various mesh sizes; and

Fig. 7 is a circuit diagram utilizing a pair of grid lamps mounted in a "half-bridge" like configuration with the grid lamps operating as the control components in their own driver circuitry.

[0007] Fig. 1 illustrates a first embodiment of a grid controlled gas discharge lamp constructed in accordance with the invention. The lamp includes the usual glass envelope 10 and a metallic end cap 12 which includes the usual connectors (not shown) for connection to the source of lamp current. The inner surface of envelope 10 is coated with phosphors which fluoresce in the presence of a plasma. Conductive feed-throughs 18, 20 extend through a glass stem 22 and are connected to a cathode or electrode 24. This structure is a conventional fluorescent lamp. It should also be noted that the invention is also applicable to other low pressure discharge lamps such as a low pressure sodium vapor lamp.

[0008] A cylindrical support tube 26 has an opening 28 at its lower portion which is sealed to stem 22. The upper portion of support tube 26 mounts a support ring 30 which is used to support a conductive grid 32 so as to enclose the upper opening of support tube 26. A spring clip 34 surrounds the upper portion of support tube 26 and assures that grid 32 and support ring 30 are held in close contact with support tube 26. Spring clip 34 is held in place by a circumferential indentation 36 disposed in tube 36. A lead wire 38 provides electrical connection through lamp stem 22 to grid 32. In this manner, the control voltage may be applied to grid 32.

[0009] As is discussed below, grid 32 is a square mesh tungsten grid of about 70% open area, with the fineness of the mesh being controlled by the desired circuit and operational parameters. The overall design of the support tube 26 is not critical. The only important characteristic is that the electrons flowing from electrode 24 must pass through grid 32. If there was a path around grid 32, the lamp would not function as grid 32 would be unable to interrupt the electron flow.

[0010] Fig. 2 shows an exploded view of a second embodiment of a grid controlled fluorescent lamp. In this drawing the same reference numerals are utilized to indicate like structure as in Fig. 1. Lamp envelope 10 includes an inwardly disposed indentation 40 which serves as the upper limit and seal for grid 32. The lower support for grid 32 is formed by the lead wires 38. Lead wires 38, connected to grid 32, run within hollow glass tubes 42, 44 for electrical isolation from the plasma.

[0011] In operation a grid disposed in an ionized gas plasma by virtue of its bombardment with charged ions and electrons will be placed at a positive voltage relative to the cathode which is at 0 volts. In this application this voltage on the grid is referred to as the floating voltage (V_f1). In order to interrupt the current the floating voltage must be overcome before driving the grid further negative. Figure 3a shows the circuit that was used for low frequency measurements of the grid controlled lamp. Figs. 3b and 3c show the voltages and current flowing in the grid controlled lamp in response to the grid driving pulses (GDRV). The lamp is operated from a voltage source, V_DC, ballasted with a resistor, R_DC. Because of the constant lamp current, the plasma is in a well defined state. DC operation is convenient but not necessary. S1 and S2 are high voltage, low power solid state switches (MOSFET), driven by a solid state level shifter LS. 'GDRV' is the control signal supplied by any suitable pulse generating circuitry. When the drive signal (GDRV) is high, S2 conducts and S1 is off. In this state, the lamp is on (I_1a>0). As a result, the grid is at the floating potential, V_f1, and A is at +ΔV_g. The voltage across the grid capacitor C_g, is (ΔV_g-V_f1). To prevent shoot-through, turn-on of S1 and S2 is softened a bit by putting a 330 Ω resistor in series with the gates.

[0012] When 'GDRV' goes low, S1 turns on and S2 turns off, node "A" is connected to ground and since the voltage across C_g is still (ΔV_g-V_f1), the grid is pulled down to -(ΔV_g-V_f1). If this is negative enough, the lamp current is interrupted (I_LA=0). During the negative pulse, the grid current I_g discharges C_g. Therefore, C_g must be large enough to maintain a sufficiently negative voltage on the grid. When 'GDRV' goes high again, A is connected to +△V_g and the grid has a voltage somewhat above V_f1. As a result, the grid functions as an anode, collecting electrons, until it is back at V_f1. Because this current is an electron current, it is much bigger than the grid current, I_g, which is a diffusion limited ion current.

[0013] Figure 4 shows V_g,min as a function of I_1a for lamps with 20, 32, 40 and 56 mesh per cm tungsten grids in the configuration shown in Fig. 1. Figure 5 is a similar graph for lamps constructed as shown in Fig. 2 with 40, 56 and 72 mesh/cm tungsten grids. The polarity of the lamp was chosen such that the grid is close to the cathode. The curves represent the averages of 2 to 5 lamps. As expected, V_g,min is more negative at higher I_1a. Also, the finer the grid, the easier the switching. The differences between the 40, 56 and 72 mesh/cm grids are relatively small. There are also small differences between the results in this case of the 40 and 56 mesh/cm grids of lamps of the two different configurations. It is apparent from the results, in particular those shown in fig. 4, that for a mesh value smaller than 20 mesh/cm the required value for V_g,min becomes impractically large. Thus the mesh of the grid should at least be 20 mesh/cm. The mesh used in the grids should be regular (i.e. all the wires in the mesh are uniformly spaced apart), if this is not the case the switching capability of the grid can be greatly deteriorated (V_g becomes too large). Figure 6 shows grid current (I_g) in milliamps as a function of lamp current (I_LA) for various mesh sizes. It is seen that the grid current is much lower than that of the current flowing through the lamp which permits the use of low current switches in the grid control circuitry.

[0014] If the grid is close to the anode instead of the cathode, V_g,min stays approximately the same. ΔV_g (the difference between V_f1 and V_g,min), however, is much higher as V_f1 is higher. This is not trivial, because the thickness of the space charge layer is a function of the voltage drop across it (V_f1-V_g). However, when the current is interrupted, the potential of the plasma around the grid changes. Thus the grid must be made negative with respect to the cathode to obtain switching. V_g,min does not change very much with the position of the grid in the lamp. With the grid closer to the cathode ΔV_g can be kept smaller and this is desirable. However, the grid must not be too close to the cathode since the plasma is different in close proximity and switching becomes very different. Distances of 6 mm to 13 mm from grid to cathode give satisfactory results. Grids 32 were constructed from square mesh tungsten round wire usually used for chemical sieving. The grids have about 70% open area and tungsten is relatively sputtering resistant. However other materials may also be used (such as nickel or molybendum).

[0015] Figure 7 illustrates a practical grid lamp circuit. As can be seen the grids are driven, by signals GDRV₁ and GDRV₂ in a manner similar to that of Fig. 3. The two grid lamps are connected in a "half-bridge" like configuration with the grid lamps forming one-side of the bridge and the other side of the bridge being formed by capacitors C₁ and C₂. As lamps L₁ and L₂ need not be switched on and off simultaneously, diodes D₁ and D₂ which are connected in parallel therewith provide alternate paths for current flow when one or both of the lamps are turned off. Bridging the lamps are resonant elements C_s and L_s which form a tuned circuit. As is seen, each of the lamps replaces a solid state power device. The grid driver elements (S₁, S₂, S₃, S₄) consist only pf high-voltage, low-power devices.

[0016] The circuit of Fig. 7, depending upon the operating frequency and the values of resonant elements C_s and L_s may be operated in either the so-called capacitive or inductive modes. In these modes lamps L₁ and L₂ may be turned off either by the action of the grids or by the action of the resonant circuitry. Operation in either of these modes may at various frequencies prevent deleterious so-called "constriction". Constriction occurs when the electrons of the plasma try to force their way through one of the openings of the grid. When this occurs the wires of the grid at the point where constriction occurs can burn out, which causes failure of the controlling grid. Such constriction may be avoided by controlling the parameters of the circuit elements of the circuit of Fig. 7 and by controlling the speed of changes in lamp current and grid voltage. Other possible circuit elements, such as described in the copending application referred to at page 1 may also be used in conjunction with the grid controlled lamp of the present invention.

[0017] In the schematic of Fig. 7 the lamps are shown being driven with V_DC. However, as is known to those skilled in the art, V_DC may be any DC source such as rectified power line voltage. The circuit may be operated at frequencies of at least 20 KHz which is a standard operating frequency for solid state lamp driver circuits. Accordingly, Fig. 7 illustrates that the grid controlled gas discharge lamps constructed in accordance with the present invention form an integral part of their own driving circuitry without the need for high current switching devices. This provides meaningful cost and heat dissipation savings.

[0018] Although the present invention has been described in conjunction with preferred embodiments, it is to be understood that modifications and variations may be resorted to without departing from the spirit and scope of the invention, as those skilled in the art will readily understand. Such modification and variations are considered to be within the purview and scope of the invention and the appended claims.

Claims

1. A low pressure gas discharge lamp comprising:
   an envelope, first and second electrodes disposed within said envelope, an ionizable gas filling said envelope, said gas becoming a charged plasma when a current flows between said first and second electrodes,
   and comprising a conductive grid disposed within said envelope, which lamp is provided with means for electrical connection to said grid, characterized in that said grid comprises a mesh of 20 to 72 mesh/cm.

2. A lamp as claimed in Claim 1, characterized in that said first and second electrodes comprise an anode and a cathode, said grid being disposed closer to said cathode than said anode.

3. A lamp as claimed in Claim 1 or 2, characterized in that said envelope includes an inwardly disposed indentation, said grid being disposed in contact with said indentation.

4. A lamp as claimed in claim 1, 2 and 3, wherein the lamp is a fluorescent lamp.

Drawing