NL8105509A - STARTING TOOL FOR DISCHARGE LAMPS. - Google Patents

Description

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Starting aid for discharge lamps.

The invention relates to discharge lamps and in particular to internal starting aids for such lamps.

Discharge lamp starting aids can be divided into two general classes, namely active means such as impulse generators of some form and passive techniques such as ground planes or probes.

Active assets have the disadvantage of being expensive. They also contribute to the size and weight of the ballast. The active agents are also often complex, and this is a negative factor since the reliability is adversely affected. Passive starting aids can also be divided into two separate classes. First, there is the exterior type, which includes 15 ground planes, adjacent to or in contact with the exterior lamp wall. Examples of this type of starting aid include external conductive lamp wall coverings or stripes and grounded luminaires. The second class of passive starting aids includes internal conductive stripes or linings and 20 starting probes.

The relative merit of a particular type of passive starting aid depends on the lamp type and the intended market application. For example, the standard F40WT12 lamp generally relies on a grounded luminaire to provide the necessary start function. Energy-saving and krypton-filled F34WR12 lamps rely on an internally conductive film placed between the glass and the phosphor. External stripes and coatings are preferred in Europe.

However, while the use of start-up aids has been recognized as a desirable property, it has hitherto not been possible to form lamps with an effective and economical internal start-up aid that does not affect the amount of light exiting.

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It is thus an object of the invention to avoid the drawbacks of the known art.

Another object of the invention is to provide a simple and economical starting aid.

Yet another object of the invention is to provide an internal starting aid, which is practically invisible in a finished lamp.

Yet another object of the invention is to provide a method for making such lamps.

These objects are achieved according to an aspect of the invention by forming a discharge lamp which is provided with a tubular glass envelope with a phosphor layer on the inner surface thereof. Sealing closers seal the ends of the sheath and each include first and second lead-in wires fused therein. These lead-in wires support electrodes within the envelope. One of the sealing closers includes a third lead-in wire, and a wire starting aid is electrically connected to its internal end. The filamentary starting aid has a major portion of its length adjacent to the phosphor coating. An arc-generating and entertaining medium, which includes mercury, fills the sealed envelope.

The lamp is constructed by placing a pre-phosphor coated linear envelope in a position to receive the mounts. A first mounting member is inserted into the casing and fused to it. The second mounting member, which includes the third guide and to which the filamentous starting aid is attached, is then inserted into the other end of the envelope and fused to it. The lamp is then evacuated, filled and melted down.

The lamps thus constructed and shaped are simple and economical. The solid filament starting aid has no tendency to break or separate as is the case with previously used internal stripes.

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The invention will be explained in more detail below with reference to the drawing.

Figure 1 shows a longitudinal section of a lamp provided with an internal thread-like starting aid.

Figures 2 and 3 are sectional views of alternative mounting members.

Figure 4 schematically shows a non-linear lamp using the invention in conjunction with its circuitry.

Figure 5 is a diagram for the progress of the lamp making process.

Figure 1 shows a discharge lamp 10 provided with a tubular glass envelope 12 with a layer of phosphorus 14 on the inner surface thereof. Sealing closure members 16 and 18 close the ends of the casing 12. An arc generating and entertaining medium comprising mercury fills the sealed casing 12, which may have been evacuated and filled by any known technique.

The sealing closure members 16 and 8 have 20 lead-in wires 20 and 22 and 21 and 23, respectively, which are fused therein and electrodes 24 and 26 are electrically connected thereto and are carried thereby. Usually, one or both sealing closures are provided with a suction tube, which is not shown in the drawing.

One of the sealing closure members, for example 18, has a third lead-in wire 28 fused therein and extending inwardly and outwardly from the sheath 12. A filamentary starting aid 30 is electrically connected to the inner end of the lead-in wire 28 and the major portion of its length is adjacent to the phosphor coating 14. The starting aid 30 has a length x which is substantially equal to the arc length of the lamp 10. Preferably, the aid 30 ends with its free end 32 near the opposite electrode, in this case the electrode 24. The starting aid 30 is constructed of a material which is practically inert with respect to the mercury atmosphere.

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- 4 - in the lamp, such as nickel or nickel plated steel.

The sealing closers 16 and 18, which are preferably identical except for the third lead-in wire 28, can be of any desired shape. In FIG. 2, a sealing closure member 18 is shown in a circular, disc-shaped configuration, while FIG. 3 shows a conventional run-out and press form. In any case, the member 18 includes the lead-in wires 21 and 23, which carry the electrode 26, and the lead-in wire 28, which is connected to and carries the filamentary starting aid 30.

The filamentous starting aid 30 has additional advantages when used in non-linear lamps such as the circular embodiment, shown in part in Figure 15 4. Here, the lamp 10 is formed such that the filamentous starting aid 30 is located along the outer diameter of the envelope 12 when it is held in place by the tension supplied to it by the rolling process.

Lamps 10 are constructed by placing the envelope 12 with the phosphor coating 14 on the inner surface thereof in such a manner that the sealing closers or mountings can be received. If the total length of the lamp 10 is small, for example 30 cm or less, the envelope 12 can be placed horizontally. However, the preferred orientation is vertical, especially at great lengths.

When the sheath 12 is placed vertically, the mounting member 16 is inserted into the lower end of the sheath and fused therein. The mounting member 18 with the long thread-like starting aid attached thereto is then inserted into the top end of the casing 12 and fused to it. If the final lamp is to remain a linear type, the final operation such as evacuation and filling can now be performed. If the lamp is to be of a non-linear type, for example circular, the bent parts are formed according to conventional techniques. However, the 8105509 * 5 lamp orientation during the molding process must ensure that the filamentary starting aid 30 is located against the outer inner wall. After forming, the non-linear lamp is evacuated and filled according to known techniques.

In operation, this lamp is particularly suitable for applications where no starting aid is formed by the ballast, such as the upstream resistor according to figure 4. There, a supply voltage V, preferably an alternating voltage of 120 V and 60 Hz, is supplied to the terminals 34 and 36 of the starter 38, which is a conventional glow light starter, operating in a conventional manner when a switch 40 is closed. When the starter 38 is conductive, the lamp electrodes 24 and 26 will reach the thermionic emission temperature and a substantial space charge will surround them. When the starter 38 opens the preheat circuit and when the instantaneous polarity of the supply voltage is positive on a terminal 42, the capacitor 44 will be positively charged at the terminal 46. The charge path includes the filamentary device 30, the ballast resistor 48 and 20. supply voltage V. The starting aid 30 is coupled to the electrode 24 by the electron-space charge formed during the preheating phase. The voltage generated across capacitor 44 will depend on the value of the capacitor, the space charge at the electrode 24 and the proximity of the electrode 24 to the starting auxiliary wire 30. When the supply voltage V reverses polarity at the subsequent half period such that the supply voltage is positive at the terminal 50 and before the starter 30 closes again, the voltage of the capacitor 44 will add to the supply voltage in a voltage increase mode. This combined voltage will occur across the gap between the electrode 24 and the filamentary starting aid 30. The polarity of this voltage is such that the electrode 24 will be positive with respect to the starting aid 30. Without the added voltage of the capacitor 44, the available voltage is not sufficient to initiate the cold cathode discharge from the starter 8105509 * RV-6 means 30. This discharge is necessary for the wire 30 to act as a lamp starting aid.

The cold cathode discharge from the starting aid 30 to the electrode 24 will form a free charge 5 consisting of electrons and positive mercury ions. The current explanation of the starting assist mechanism is that ambipolar preferred diffusion of this charge is performed by the presence of the negatively charged wire 30. In the region close to the wire 30, the sheath wall will acquire a positive charge 10 due to the electrostatic attraction of the wire 30. The dipole field formed by this charge is considerably larger than that which could be generated by an external wire or stripe, since the dipole distance in the latter case is considerably greater, resulting in a smaller field strength.

The effect of this dipole field is that additional ionization occurs near the sheath wall, which in turn extends the dipole field further along the wire 30. This is analogous to the process which takes place between the negatively charged sheath inner wall and the positively charged outer wall with an external lamp starting aid. In this manner, a conductive layer is formed along the lamp wall to a point where the axial lamp field is sufficient to start the lamp. In this regard, the value of capacitor 44 is critical with respect to a minimum threshold value. This value must be greater than 0.1 yuF. Otherwise, a significant voltage drop will occur during the polarity reversal of the supply voltage V. Laboratory measurements have shown that this effect is likely to be caused by a capacitor discharge current, resulting from space charge absorption at the electrode 24, when the polarity of the supply voltage reverses and is positive. at the electrode 24.

The filamentary starting aid 30 as described above is superior to all previous 35 designs. Compared to internal conductive coatings or stripes, the filamentary starting aid is superior due to ease of manufacture and lower cost. In addition, it is easy to adapt to non-linear lamps.

In linear or straight lamps, the filamentary starting aid provides improved operation tgp-5 due to better optical transmission as well as superior lumen maintenance.

Compared to external starting aids, superior operation is obtained because of the increased electric field strength associated with the internal wire. It is also better from a cost and manufacturing standpoint, since additional steps would be required when applying an external starting aid to a finished lamp. From an aesthetic point of view, the present invention offers an additional advantage in that external starting aids require some form of electrical insulation in situations where electrical connection is required at some point in the chain. The present invention is practically invisible with the finished lamp.

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Claims (4)

1. Fluorescent lamp with a tubular glass body having first and second ends and a phosphor coating on the inner surface thereof, first and second sealing members each with two lead-in wires fused therein and for sealing said ends of the body, while first and second electrodes are respectively attached to the interior parts of these lead-in wires, in the first and second sealing members and an arc generating and entertaining medium 10 within the body, characterized in that a third lead-in wire is fused into the first sealing member this third lead-in wire terminates within the body near the first electrode, and a solid filament starting aid is attached to the inner end portion of this third electrode 15 and extends along the length of the body to a position close to the second electrode. 2. A lamp according to claim 1, characterized in that the arc-generating and sustaining medium comprises mercury vapor and the solid filamentary starting aid is formed from material which is practically inert to this mercury vapor. Lamp according to claim 2, characterized in that the solid wire material is selected from the group of nickel and nickel plated steel. 25 4. Device substantially as described in the description and / or shown in the drawing. 8105509