CS250206B2 - Cathode unit for fluorescent lamps - Google Patents

Abstract

Cathode unit intended for use in a fluorescent tube and designed in such a way that the service life of the tube is increased markedly as a result of a reduction in the loss of emmission material from the cathod (3). These material losses are caused by, inter alia, ion bombardment and by vaporization of the emission material. In order to achieve a marked increase in the reflection of released ions and molecules back to cathod surface, both ions and molecules which have been released through ion bombardment a ions and molecules which have been released vaporized from the cathod surface, the cathode (3) is surrounded by an electrically conductive cathode shield (6) in the form of a box-shaped casing which is, however, electrically insulated from the cathod. A opening (8) is made in the bottom of the shield for inserting the cathod (3). The open end of the shield (6) is sealed by means of a disc (9), preferably made of mica and provided with a centrally located hole (19). The hole diameter of the mica disc (9) should be selected so that it is as small as possible while bearing in mind the fact that the starting voltage for the tube should not exceed a predetermined value. The opening (8) in the bottom of the shield (6) should be of at least the same area as the hole in the mica disc (9).

Description

BACKGROUND OF THE INVENTION The present invention relates to a cathode fluorescent lamp unit comprising a cathode mounted on a cathode base in fixed relation to a fluorescent lamp wall and surrounded by a box-like surface of a cathode shield of electrically conductive material consisting of a wall and bottom. located in the discharge space in front of the cathode, a disk of electrically insulating material provided with a central opening.

The lifetime of the lamp, calculated in hours of burning time, is mainly determined by the lifetime of the cathode of the lamp. If the cathodes have lost some of their emission material, consisting of corrosive earth oxides, their electron emitting capacity will drop to the point that the lamp either fails to start or reaches a flashing stage that rapidly atomises the remaining emission material.

It is well known that excess barium, dissolved in mixed crystals of emission material, causes semiconductivity of the caustic oxides and reduces the work of electron release. This excess barium is formed by a chemical reaction between barium oxide and tungsten according to the following formula:

BaO + W - BasWOe + 3 Ba.

The barium tungsten thus formed remains as an intermediate layer between the tungsten and the emission substance itself for the life of the cathodes, while barium is continuously diffused as vapor by the emission substance.

The barium tungsten compound layer causes a damping reaction according to the above formula, i.e., reduced barium formation. As a result, the entire amount of barium will not evaporate after about 30,000 hours of continuous burning of a normal fluorescent lamp. However, the cathode stresses of the fluorescent lamp when starting are so great that the lifetime decreases by a factor of 2 to 3 under normal use of the fluorescent lamp, i.e. at an average bonding time of 2 to 3 hours each.

The loss of cathode material, which serves as the emission substance and the associated reduction in lamp life, are essentially triggered by three different events, namely: 1. removal of emission material due to ion bombardment, in particular in connection with insufficient cathode temperatures, 2. evaporation of emission material, and 3. chemical reactions between the emission material and the gaseous impurities in the lamp.

In the design of a fluorescent lamp which is intended to have an extremely long lifetime, during which the lamp is ignited and quenched very often, the cathodes of the fluorescent lamp must be designed in such a way that the three reasons for reduced lifetime (cathodes) are fully respected.

The prerequisite for the removal of emission material due to ion bombardment is basically the fact that any atom that leaves the cathode surface will never return to the cathode. However, this is only correct under vacuum. In fact, in a normal fluorescent lamp design, the cathode is surrounded by a noble metal atmosphere at a pressure of about 2.5 bar. as a result, the free average length of motion - for atoms and molecules released from the cathode surface, is considerably shorter than the distance between the cathode and the fluorescent wall. As a result, a large number of released atoms and molecules are reflected back and fall towards the cathode surface. This greatly reduces the loss of material. However, such a reduction is insufficient in the case of cathodes for long-life fluorescent lamps.

The evaporation of the emission substance is relatively constant in continuous operation, but proceeds faster after each start and in the minutes following the start, due to the increased cathode temperature. This means that the cathode for a long-life fluorescent lamp must be designed so that the evaporated atoms - and molecules - largely reflect off back to the cathode surface, and in addition that the temperature of the cathode remains relatively low during the actual start-up period.

The purpose of the invention is to solve the above problems and thus to create a cathode structure to be used in a fluorescent lamp which significantly increases the lifetime of the fluorescent lamp to be at least three times that of conventional fluorescent lamps.

In British Pat. No. 1,133,840 discloses a fluorescent lamp with a heated cathode surrounded by a cathode screen. The cathode shield consists of a metal sheet and is therefore electrically conductive and is electrically separated from the cathode and spaced apart from the proximal end of the lamp and is covered by an electrically insulating disc having a central opening.

It is a low-pressure mercury lamp which, in order to reduce the wavelength of the emitted electromagnetic radiation, interferes with, for example, radio signals. The main purpose of this lamp is therefore completely different from the purpose of the invention. The shade according to this specification will in fact have little effect on the life of the lamp, since it has no bottom. The absence of such a bottom substantially reduces the reflection of the emission material back to the cathode.

Furthermore, U.S. Pat. No. 2,917,650 describes a lamp with a cathode shield, which is electrically insulated from the cathode and has no bottom at the end facing the lamp base, because the purpose of the lamp is to prevent formation stains on the wall of the lamp and therefore no protection at the end of the lamp is required.

On the contrary, the purpose of the invention is, as mentioned above, to provide a cathode unit for a fluorescent lamp having a lifetime of at least three times that of conventional fluorescent lamps. This lifetime is mainly determined by the durability of its cathodes and the lifetime of these cathodes

again depends on how long they hold their ability to transmit electrons.

SUMMARY OF THE INVENTION The diameter of the aperture in the disc is between 25% and 35% of the diameter of the fluorescent lamp, the bottom of the box-shaped cathode sheath being positioned opposite the cathode base formed by the foot and having a passageway at least as large as the area of the hole in the disc.

According to a preferred embodiment of the invention, the opening area is less than 110 mm 2.

According to another embodiment of the invention, the passage in the bottom of the box-like housing is elongated.

According to yet another embodiment of the invention, the box-like housing has a generally circular cylindrical shape extending in the axial direction of the lamp.

The aperture in the disc is preferably round.

In this case, it is expedient if the disc consists of mica and has a thickness in the range of about 0.1 to 0.15 mm.

The box-like cathode shield will preferably consist of iron or nickel.

According to yet another embodiment of the invention, a strut is disposed between the cathode shield and the shoe to support the cathode shield with respect to the fluorescent tube.

According to an advantageous embodiment of the invention, the lamp tube has a diameter of 38 mm.

The properties of the fluorescent lamp according to the invention have been achieved by improving the electron emission conditions for the cathodes. This improvement was due to the following measures:

1. The consumption of emission material at start-up is limited by the reflection of the evaporated atoms and molecules on the cathode surface during the start-up period.

2. A cathode shield that has no electrical connection reduces the rate of evaporation of emission material during normal operation.

3. Gaseous impurities in the lamp are removed by particularly efficient pumping during its manufacture.

Experience has shown that the most efficient pumping is achieved in a self-pumping unit where a vacuum pumping at high temperature is combined with an internal pumping which is carried out by introducing mercury droplets into a hot lamp. When a drop of mercury hits the wall of a fluorescent lamp, it evaporates explosively and leads to the effect of a diffusion pump in the lamp. This leads to an extremely efficient removal of impurities. However, if this is to be done to a sufficient extent, it is important that the cathode does not have a detrimental effect on the efficiency of the above pumping process. For this purpose, the opening in the bottom of the cathode shield will preferably have an area at least equal to the area of the opening in the disc.

The invention will now be described by way of example with reference to the drawings.

Giant. 1 shows one end of a fluorescent lamp provided with a cathode unit constructed in accordance with the invention.

Giant. 2a-2b show, in a vertical cross-section or a bottom view, respectively, the cathode screen used for the cathode unit.

Giant. 3 is a plan view of a mica disc intended to cover the open end of the cathode shield shown in FIGS. 2a and 2b.

Giant. 4 is a graph showing the starting voltage and pumping rate dependence on the diameter of the hole in the mica disc.

Giant. 1 shows in cross-section one end of a fluorescent lamp designed and constructed according to the invention. The glass wall 1 of the lamp is sealed at the end by a foot 2 in a conventional manner. This foot 2 also serves as a base for the cathode supports 4 which carry the fluorescent cathode formed by the spiral 3. These cathode supports 4, which are electrically conductive, are connected to lead wires 5 which are sealed to the foot 2 and through which current can pass spiral 3 and heat the spiral. The spiral cathode 3 is surrounded by a cathode screen 6, which is preferably made of iron or nickel. The screen 6 is supported by a strut 7, which is sealed into the foot 2 and is electrically insulated from the spiral 2.

As best seen in Figures 2a and 2b, the cathode shield 6 is in the form of a box-shaped housing, in the bottom of which is an elongate passage 8 for introducing the cathode 3 and portions of the cathode supports 4. The open end of the box-shaped cathode shield 6 is closed by mica The disc 9 preferably has a thickness in the range of 0.10 to 1.15 mm. As can be seen from FIG. 3, the mica disk 9 is provided with a centrally located opening 10, which is preferably round in shape. The opening 10 has a diameter of 10-12 mm for a normal fluorescent lamp with a tube diameter of 38 mm. A smaller diameter than indicated would reduce the pumping of the inside of the fluorescent wall, but at the same time would increase the starting voltage to unacceptable values as shown in Figure 4, which shows the starting voltage U in volts as well as the relative pumping rate S in a function of the diameter D 10 in mm for aperture 10. A larger aperture diameter 10 would reduce the starting voltage only insignificantly, but would greatly increase the blackening of the lamp wall.

It is important that the disc 9 is made of mica or some other electrically non-conductive material that does not emit gas, since ion bombardment would, if the disc 9, for example, be made of iron, create additional atomized material and thus intensify the blackening of the fluorescent wall.

The described construction according to the invention gives still further advantages, namely in half-periods, when the spiral 3 acts as an anode. Because .discharge

2SC20S

it must pass through the mica disk 9 provided with the aperture 10, a noticeable increase in the electron density adjacent to the spiral 3, which acts as an anode, is obtained. This reduces the anode loss. This, in turn, causes the cathode temperature to decrease, thereby reducing the evaporation rate.

As mentioned above, it is desirable that the tube be evacuated by a pumping process in which vacuum pumping is combined with an "internal pumping" achieved by allowing mercury droplets to strike the hot tube of the fluorescent lamp. A drop of this type is shown schematically in FIG. 1 under reference numeral 11. The tips 12 and 13 schematically indicate the most important flow paths through which the steam is taken. The mercury vapor that follows the path indicated by the arrow 13 must not be obstructed by a structure consisting of a cathode shield 6 and a mica disk 9 if the carbon dioxide that exists on the emission layer and is formed by converting carbonates to oxides is effectively removed. should be effective. To this end, the diameter of the opening 10 in the mica disc 9 should exceed 10 mm (for a fluorescent tube with a tube diameter of 38 mm) and the bottom passage 8 in the cathode shield 6 must have an area at least as large as the opening 10 of the mica disc 9 preferably larger.

The above-described cathode design of the present invention allows, even if a normal burning time of three hours per bond is maintained, to achieve a lifetime that is three to four times longer than that of conventional fluorescent lamps.

Claims (9)

SUBJECT OF THE INVENTION A cathode fluorescent lamp unit comprising a cathode mounted on a cathode base in fixed relation to a fluorescent lamp wall and surrounded by a box-shaped cathodic screen housing of an electrically conductive wall and bottom material, said housing being electrically unconnected to the cathode and sealed from the open end side; disposed in the discharge space in front of the cathode, a disk of electrically insulating material having a central aperture, characterized in that the diameter of the aperture (10) in the disc (9) is between 25% and 35% of the fluorescent lamp diameter; (6) is located opposite the cathode base formed by the shoe (2) and is provided with a passage (8) the surface of which is at least as large as that of the opening (10) in the disc (9). The cathode unit according to claim 1, characterized in that the area of the opening (10) is less than 110 mm ² . Cathode unit according to Claims 1 and 2, characterized in that the passage (8) in the bottom of the box-shaped housing is elongated. 4. The cathode unit of claim 1, wherein the box-like housing has a generally circular cylindrical shape extending in the axial direction of the lamp. The cathode unit according to claims 1 and 2, characterized in that the opening (10) in the disc (9) is round. The cathode unit according to claim 5, characterized in that the disc (9) consists of mica and has a thickness in the range of about 0.1 to 0.15 mm. The cathode unit according to claim 1, characterized in that the box-like housing of the cathode shield (6) consists of iron or nickel. The cathode unit according to claim 1, characterized in that a strut (7) is arranged between the cathode shield (6) and the shoe (2) to support the cathode shield (6) relative to the lamp tube. 9. The cathode unit of claim 1 wherein the lamp tube has a diameter of 38 mm.