DE923020C - High pressure mercury lamp for direct current operation - Google Patents

Description

High-pressure mercury lamp for direct current operation The invention relates to a high-pressure mercury lamp for direct current operation with a noble gas base filling and a solid, non-activated or only weakly activated glow electrode, heated by the discharge, and an activated auxiliary cathode located at a greater distance from the anode. It is very difficult to operate discharge tubes of this type with low voltages, for example of 30 V and less. These difficulties are particularly great when it is necessary to achieve high luminance, the electrode spacing small, z. B. smaller than q. mm to choose. Since a substantial part of the energy converted in the discharge path is supplied to the anode as a result of the anode falling, it takes on a high temperature during operation, which leads to its rapid disintegration. The atomization makes the tube unusable in a short time.

These disadvantages are avoided in the invention in that the anode surface is chosen so large that the anode, which is made of high-melting metal, for example tungsten, is heated to a temperature of at most aioo °, preferably of only 180 °, due to the anode losses. leads. According to the invention, the anode is in a thermally conductive connection with the vessel wall only via its power supply line. The diameter of the anode and its length is equal to a multiple of the length of the discharge path. Since the energy supplied to the anode is related to the discharge current. m, it is advantageous to choose the quotient of the anode surface: S trorus strength greater than% 10 mm2 / A, preferably greater than 30 mm2 / A. If the high-pressure mercury lamp is to be used in conjunction with optical systems, it is desirable, especially when the discharge path is very small, to use the. Always keep the arc in the same place. For this purpose, it is advisable to attach a tip to the anode in the arrangement according to the invention which is arranged opposite the cathode, which is also advantageously pointed, for example the end of the cathode wire forming the hot cathode. If the anode consists of a solid body, for example a sphere or a cylinder, the tip can be formed by a wire protruding somewhat from the surface of this body.

To achieve a very high luminance, it is desirable to to choose the discharge path as short as possible and with a high mercury vapor pressure, preferably from more than 10 atm. to work. To get a Achieving sufficiently rapid heating of the discharge vessel is advantageous the anode of the high-pressure mercury lamp according to the invention is cylindrical and arranged so that the discharge in normal operating condition at the free end of the cylinder begins, while .the other end leads to the meltdown. By this measure it is achieved that a part of the heat supplied to the anode to the melting point which otherwise experience shows that because of their large mass only proportionally would heat up slowly. This acceleration of the heating process is special of great importance for frequently interrupted operation, as the waiting times are considerable be shortened.

This arrangement also has a spherical anode in front of it the advantage that the cylindrical anode has a smaller surface with the same surface area Has shadow effect. This advantage is particularly effective when the Arc starts near one end or at the end of the cylinder. It has proved to be advantageous, at least one of the dimensions .the large area formed anode larger than five times, preferably even larger than that Ten times the electrode spacing. to choose.

The drawings show, in a partially schematic representation, exemplary embodiments of the high-pressure mercury lamp according to the invention. The spherical anode i sits on the seal 2 in the arrangement according to FIG. The cathode consists of two parts, namely the activated auxiliary electrode 3, which is attached in the vicinity of the seal, and the preferably non-activated cathode wire 4, which is led to the vicinity of the tip 5 of the anode serving for the arc attachment. That. Discharge vessel contains a mercury supply, which is expediently completely evaporating during operation, and a basic inert gas filling, e.g. B. argon. When the voltage is applied, an arc discharge initially goes from the activated auxiliary electrode 3 to the anode tip 5. As a result of the activation, the ignition takes place at voltages of less than 30 V, e.g. B. 24 V without the cathode needing to be preheated for this purpose. The auxiliary cathode 4, on which the arc attaches during continuous operation, heats up from. even to the required temperature. As the temperature of the discharge vessel rises, so does the vapor density and causes an increase in the arc drop. This in turn has the consequence that the discharge path is shortened, although the work function on the activated electrode 3 is noticeably smaller than on the non-activated cathode wire 4. Cathode wire 4.

To make this process occur with certainty, it is expedient to design or arrange the cathode wire 4 and the auxiliary electrode 3 in such a way that that the distance of each point of the cathode surface is the closer to the anode, the smaller its distance from the tip of the cathode wire 4, or with others Words .: to lead the cathode wire so that the distance between the cathode and the anode steadily decreases in the direction from the auxiliary cathode to the tip of the cathode.

In some cases it has advantages to use the cathode wire itself that way to choose thin, that it is heated up to the temperature everywhere as a result of the discharge which is necessary to maintain the cathode spot. In this The case is namely the transition of the arc starting point from the auxiliary electrode 3 to the tip of the cathode wire 4 facilitated without the risk that the arc extinguishes on its wandering. The thin cathode wire works here as a self-heating hot cathode.

In order to also determine the anodic starting point, there is a protruding tip attached, for example from a thin or pointed Wire 5 can exist. The size of the anode results from the amperage that the high-pressure mercury lamp is supposed to carry. Recommended for a current of 2.5 A. it is advisable to choose the diameter approximately equal to 5 to 6 mm.

As a ball from the specified exhaust measurements already a significant portion shields the emission angle of the arc, it is convenient for some purposes to use in its place a cylinder as the anode. Such an anode is shown in FIG. Their application proves to be particularly optical when used. Systems with a large opening ratio of the arrangement with a spherical anode as superior The cylinder is provided with a slot into which a thin tungsten wire is clamped. In normal operating conditions, the discharge does not start at part 6, but only at the tip 7. With this arrangement of the anodic attachment point, a much larger radiation angle is available 1. With a diameter of the anode of 3 mm and a total length of 9 mm, the surface area of the anode is approximately 90 mm 2 of, for example, io, u thickness. Thin lead wires io are connected to these foils as power connections n, while as a lead to the. Electrodes that are used with: the wires connected to the foils ii. In the drawing, the two foils are shown as lying in one plane. In practice, it is usually more advantageous to arrange them parallel to one another. At the inner end of the melt-down foot, the latter forks into two individual tubes 12. This ensures that the atomization products cannot bring about any contact between the two power supply lines ii. So that the arc has its optical center of gravity exactly in the axis of symmetry of the tube, it may be useful to incline the anode cylinder 6 a little against the axis of symmetry, as FIG. 2 shows.

The bell 13 delimiting the discharge space, which preferably consists of Oarzglas is made almost in the shape of a sphere with an outer diameter from about 10 to 15 mm. It is with the end of the fusible foot near the electrode 8 merged.

The power converted in the tube is relatively small. she therefore heats up because their dimensions are usually ten times the arc length will be hard to beat. It is therefore necessary to achieve a high pressure The discharge vessel is usually advantageous at normal room temperatures to surround with a jacket 1.4 and to vent the space between the two parts or to fill with a gas of low thermal conductivity and low pressure. at The arrangement shown results in extremely rapid heating of the discharge vessel instead, because a relatively large part of the anode heat is generated by conduction of the Melting point is supplied. This point of the discharge vessel therefore heats up faster than without this supply of heat, so that the lamp according to the invention already after a short time the operating temperature even at the coldest parts of the vessel accepts.

The discharge lamp according to the invention requires an electrode spacing at i mm and 2.5 A load a terminal voltage of about 20 V, so that the entire power consumption is only around 50 W. About half of this power is in the anode or implemented in their immediate vicinity. From this it is explained that the heat dissipation of the anode is of considerable importance. In the inventive. large area Forming the anode, the major part of this anodic heat is due to radiation submitted.

Fig. 3 shows a further embodiment of the cathode for Mercury vapor lamp according to the invention. The main cathode is at your der Auxiliary cathode adjacent end of two ibis three wires twisted together, while its end near the anode q. consists only of a simple thin wire. These Arrangement has the advantage that the cathode wire is significant due to the twist is stiffer. One could also use the main cathode q. along the entire length by twisting stiffen by two or more wires. In this case, however, it is a matter of concern to wear that in the vicinity of the anode only one tip for attaching the cathodic Discharge is present. Otherwise the arc would be inclined, perpetual to jump from one cathode tip to the other.

When activating the platelets that make up the auxiliary cathode 3 is can also on the cathode wire q. self activating agent applied will. However, due to the high temperature, they do not remain on the cathode wire for long. The evaporation results, if only an extremely thin layer on the cathode wire q. is applied, does not significantly affect the transparency of the discharge vessel disturbing pollution.

Also with the arrangement according to FIG. 3 the arc goes in the direction the axis over. This arrangement has the advantage that the tube goes in almost all directions shines evenly. The shadow effect of the cathode wire 4 can because of its small diameter are disregarded.

The auxiliary cathode 3 exists in the illustrated embodiments from a pen on which several platelets a few millimeters in diameter are made are pushed onto hard-to-melt metal. The space between the platelets and its surface is used to accommodate the activation compound. The cathode wire q. can be attached to the auxiliary cathode, for example, in such a way that it is around the The pin that carries the platelets is looped and, as FIGS. 1 and 3 show, is surrounded on both sides by the platelets.

For a current of 2.5 A it is recommended to use the cathode wire about 0.2 mm thick and the length, measured from the auxiliary cathode, about the same io mm to choose.

At a current of 2.5 A, the anode heats up at most bright red heat when its surface, as in the example given, is around 90 mm2 amounts to.

The surface brightness of the lamp is with the specified operating data and around 15,000 stilb for an arc length of about 1 mm. It can be reduced to a multiple Increase the specified value by reducing the distance from the main cathode and anode to 0.5 mm and less while increasing the Hg pressure and in order to the specific voltage drop in the arc. The increase in steam pressure is to be dimensioned in such a way that the total burning voltage of the pipe is consistent with the one in the example above; then the same proportion of the total radiation is omitted on the arc. Headlights equipped with it therefore stand out despite the small power of the lamp by a very long range. Because the high pressure mercury discharge can also be modulated with low frequency, the lamp can also be used for light telephony be used.

Claims (6)

PATENT CLAIMS: i. High-pressure mercury lamp for direct current operation with a noble gas base filling with a fixed, heated by the discharge; non-activated or only weakly activated main cathode made of refractory metal and activated auxiliary cathode, attached at a greater distance from the anode, for mains voltages below 30 volts and with a distance between the main electrodes smaller than q. mm, characterized in that the anode is in a thermally conductive connection with the vessel wall only via its current feed line and that its diameter and length are equal to a multiple of the length of the discharge path. 2. High pressure mercury lamp according to claim i, characterized in that the quotient of the anode surface: current intensity is greater than io mni2 / A, preferably greater than 30 mm2 / A. 3. High pressure mercury lamp according to claims i and a, characterized in that opposite the tip of the cathode wire a tip, preferably an approximately protruding wire, is attached to the anode is. q :. High-pressure mercury lamp according to Claims 1 to 3, characterized in that that the anode has the shape of a cylinder, on which the fused-down side is facing away At the end of the discharge in the normal operating state, so that the heating in Direction is discharged to the meltdown. 5. High pressure mercury lamp according to claim q., characterized in that the cylinder has a slot at its tip is provided, in which a thin tungsten wire is attached, which a little, preferably protrudes less than 1 mm from the cylinder surface. 6. High pressure mercury lamp according to one of the preceding claims, characterized in that the power supplies for anode and cathode are brought out on one and the same side.