RU2319251C1 - Method for improving power and light characteristics of gas-discharge lamps - Google Patents

Abstract

FIELD: lighting engineering; high-power and high-frequency gas-discharge lamps.

SUBSTANCE: proposed method is characterized in that gas-discharge lamp is disposed in magnetic field whose direction is perpendicular to discharge current of lamp followed by voltage application across lamp electrodes, excitation of gas discharge, end initiation of discharge current; magnetic field flux density is constant in magnitude and amounts to 90-110 mT or periodically varies between 0 and this value in space along lamp axis; discharge current amounts to more than 0.5 A at its variation frequency over 1 kHz. Additional magnetic field of same flux density as that of mentioned magnetic field can be applied to lamp at angle of 80 to 100 deg. to lamp.

EFFECT: enhanced capacity of luminous flux, lamp power, efficiency of electrical-to-luminous energy conversion, reduced loss of utilized luminous flux.

2 cl 7 dwg, 2 ex

Description

The invention relates to the field of lighting, in particular to gas-discharge high-frequency (HF) lamps of high power.

Power of a light stream, electric power, efficiency the conversion of consumed electric energy into light, as well as a decrease in the loss of useful light flux, are the most significant characteristics in the development and especially in the operation of gas discharge lamps (bactericidal, fluorescent, etc.)

In the art, technical solutions are known in which a constant magnetic field is used to optimize some emission characteristics of gas discharge lamps.

A known method of suppressing the effect of flickering radiation of a discharge lamp, which is observed when igniting fluorescent lamps at low temperatures and significantly increases the heating time of the lamp. The technical effect of this method is to reduce the lamp warm-up time and is achieved by applying a constant magnetic field along the entire length of the gap between the lamp electrodes in the direction perpendicular to the lamp electric field (US Patent No. 441772, H01J 61/10, 1983). A magnetic field is created by one or more permanent magnets located on the outer surface of the bulb. The disadvantage of this method is its narrow application and limitation indicated by the effect.

The closest technical solution, selected as a prototype, is a method of increasing the intensity of radiation intensity and efficiency of a lamp by applying a constant magnetic field, implemented in the description of the design of a discharge lamp (Japanese Patent JP 58115745, H01J 61/70, 1983).

In the known method, increasing the radiation power of the gas discharge lamp and / or reducing the aging rate of the lamp bulb during its operation is achieved by reducing the discharge current while maintaining the lamp radiation level by applying a constant magnetic field in a direction perpendicular to the direction of the discharge current of the lamp. The magnetic field is created by several permanent magnets, which are located at some distance from the outer surface of the lamp bulb opposite each other. The magnitude of the magnetic field induction is at least 200 mT. The effect of increasing the radiation power of the discharge lamp from such a field is equal to the effect of increasing the discharge current from 0.6 A to 1.0 A, which is about 10%.

In the prototype, it is assumed that the discharge lamp is powered by an electromagnetic ballast (EMPR) with a frequency of change of the discharge current of 50-60 Hz.

However, the increase in radiation power achieved by this method is not effective enough, and the efficiency is small, despite the significant magnitude of the applied magnetic field, which makes it inapplicable to high-power lamps, especially those working with electronic ballasts (electronic ballasts).

The basis of the proposed invention is the task of developing a method to improve the electrical and light characteristics of discharge lamps and make their use the most efficient.

The technical result obtained by the implementation of the invention is to increase the power of the light flux, the electric power of the lamp, efficiency conversion of spent electrical energy into light, as well as reducing the loss of useful light flux due to the possibility of its redistribution.

The specified technical result is achieved due to the fact that in the method of improving the electrical and light characteristics of gas discharge lamps, which includes placing the lamp in a magnetic field whose direction is perpendicular to the direction of the discharge current of the lamp, applying voltage to the lamp electrodes, exciting the gas discharge and providing a constant discharge current , according to the invention, the magnetic field induction is constant in magnitude and is 90-110 mT, and the magnitude of the discharge current is more than 0.5 A When a frequency above 1 kHz.

The technical result is also achieved by the fact that the magnetic field induction can periodically vary in space along the axis of the lamp from 0 to a specified value of 90-110 mT.

It is also advisable to apply an additional constant magnetic field to the lamp with the same induction as the original, the direction of which is from 80 to 100 degrees with the direction of the original magnetic field.

As a means to create the specified magnetic field using a continuous permanent magnet located near the outer surface of the lamp tube, the length of which is comparable to the length of the discharge gap.

As a means to create a magnetic field with periodically changing induction and polarity, use a system of several bipolar magnets located near the outer surface of the lamp bulb along the longitudinal axis of the lamp along the entire length of the discharge gap, the total length of which is comparable to its length.

As a means to create an additional magnetic field with constant induction, a solid magnet is used, located at an angle of 80 to 100 degrees to the solid magnet that creates the initial magnetic field. An additional magnetic field with induction periodically changing in space is created by placing a system of several bipolar magnets in a plane that makes an angle of 80 to 100 degrees with the original magnet system.

Figure 1 shows the location of the solid magnet along the length of the lamp.

Figure 2 presents a variant of the location of the solid magnets when applying an additional magnetic field.

Figure 3 presents the location of the system, consisting of several magnets along the length of the lamp to create a magnetic field, with periodically changing in space along the axis of the lamp induction and polarity.

Figure 4 presents a variant of the arrangement of systems of several magnets along the axis of the lamp when creating an additional magnetic field with periodically changing induction and polarity.

Figure 5 presents the polar distribution of the radiation intensity around the tube lamp when applying a magnetic field from one side.

Figure 6 shows the dependence of the magnetic field along the axis of the lamp when using a system of several differently oriented magnets.

Figure 7 shows the polar distribution of the radiation intensity around the tube lamp when applying additional and initial magnetic fields from two sides.

The magnet is placed in the immediate vicinity of the surface of the bulb of the discharge lamp (FIG. 1) along its longitudinal axis. The length of the magnet should be comparable with the interelectrode distance of the lamp. At the same time, a constant magnetic field of the order of 90-110 mT is created on the surface of the lamp bulb, the direction of which is perpendicular to the direction of the discharge current of the lamp.

As a result, the radiation power of the discharge lamp is increased by up to 35%, and the efficiency of converting electric energy into radiation is increased by up to 8%, which is several times more compared to the prototype.

To create a magnetic field with induction periodically varying in space along the axis of the lamp, it is allowed to use a system of several short magnets stacked along the length of the lamp (Fig. 3). The total length of the magnets is comparable with the interelectrode distance of the lamp. With this approach, the magnetic field varies substantially along the length of the lamp, for example as in FIG. 6. In this case, an increase in the radiation power of the lamp by up to 60% is achieved with an increase in the efficiency of the lamp by up to 15%.

In addition, by reducing the period of change of the magnetic field along the coordinate and providing a sharp change in the orientation of the magnetic field, it is possible to achieve an even greater effect of increasing the lamp power.

By placing the permanent magnets in a certain way, it is possible to adjust the priority radiation directions of the tube discharge lamp. For example, in many fixtures, half of the lamp's radiation goes to the ceiling or wall, and not to the usable area intended for lighting. This effect can be smoothed out using permanent magnets. For example, when two magnets are located along the entire length of the lamp in perpendicular planes (Fig. 2) or in planes arranged at an angle of 80 to 100 ° to each other, we achieve redistribution of the radiation flux to the useful illumination area (Fig. 7) simultaneously with its increase. In this case, the lamp efficiency, taking into account the redistribution of radiation, also increases.

To redistribute the radiation around the lamp, the magnet system shown in FIG. 3 is also used. When two such systems are placed in planes arranged at an angle of 80 to 100 ° to each other, for example in perpendicular planes, as shown in FIG. 4, it is possible to increase the radiation power of the lamp with increasing discharge efficiency.

The invention is implemented as follows

Example 1. When using a quartz amalgam bactericidal lamp with a tube diameter of ⌀19 and an interelectrode distance of 144 cm, filled with a neonargon gas mixture, with a power of 250 W, with a discharge current of 2.0 A, at a frequency of 45 kHz, a UV radiation power of 95 W was obtained .

When applying a magnetic field of 105 ± 5 mT, created by a continuous permanent magnet located on one side of the bulb along the entire length of the lamp along its longitudinal axis, the average UV radiation power of the lamp increased to 128 W, and the electric power of the lamp when stabilizing the discharge current increased to 310 Tue Accordingly, the lamp efficiency increased from 38.0% to 41.3%.

In addition to the effect of increasing the radiation power of the lamp, a redistribution of the radiation intensity around the lamp is shown, shown in Fig.5.

Example 2. A magnetic field with a periodically changing induction and orientation created by a system of magnets is applied to the lamp considered above. The magnetic field induction was 95 ± 5 mT with a period of field change along the coordinate of 700 mm, and the field orientation with the same period sharply changed to the opposite. In this case, the average power of UV radiation increased to 155 W, the electric power of the lamp increases to 350 W, and the efficiency to 43.7%.

Thus, for high-power gas-discharge lamps operating with electronic ballasts, providing a frequency of change in the discharge current of more than 1 kHz, with a power of more than 250 W and a discharge current of more than 0.5 A, using fields of permanent magnets with induction of the order of 100 mT, an increase in the intensity of light radiation is achieved lamps by 30-35%, a significant increase in the electric power of the lamp, and the overall efficiency of converting electricity to radiation increases by 5-8% compared with the efficiency in the absence of a magnetic field.

When a magnetic field is applied, which varies sharply in space with respect to induction and orientation along the longitudinal axis of the lamp, the effect of an increase in the radiation intensity reaches 60%, with an increase in the source efficiency by up to 15%.

At discharge lamp currents, the magnitude of which is less than 0.5 A and change frequencies of less than 1 kHz, the effect is very weakly expressed and has no practical application. Creating fields with an induction of more than 110 mT requires large energy costs and is not effective for this method.

By placing the permanent magnets in different planes relative to each other, it is possible to redistribute the light flux around the lamp (FIGS. 5, 7) with an increase in efficiency due to the reduction of lighting losses of unnecessary area.

Claims (2)

1. A method for improving the electrical and light characteristics of a gas discharge lamp, which consists in increasing the radiation power and efficiency of the lamp by placing the gas discharge lamp in a magnetic field whose direction is perpendicular to the direction of the discharge current of the lamp, followed by applying voltage to the lamp electrodes, exciting the gas discharge and providing the occurrence of a discharge current, characterized in that the magnetic field induction is constant in magnitude, the value of which is 90-110 mT or periodically from enyaetsya from 0 to this value in the space along the axis of the lamp, and the quantity of the discharge lamp current is more than 0.5 A at a frequency of change of more than 1 kHz. 2. The method according to claim 1, characterized in that in addition to the lamp a magnetic field is applied with the same induction as that of the original magnetic field, and directed at an angle of 80-100 ° to it.

Images