DE816001C - Ignition device for a gas discharge tube with an electromagnetic switch and an electromagnetic switch for such a device - Google Patents

Description

Ignition device for a gas discharge tube with electromagnetic Switch, as well as electromagnetic switch for such a device, gas discharge tubes are often fed by a current source, the voltage of which causes the tube to burn sufficient but insufficient to ignite the tube. Under gas discharge tubes In the present case, not only tubes are to be understood with one or more Gases are filled, but also tubes that are filled with steam or a gas-vapor mixture contain. An ignition switch is often used to put the tube into operation, which short-circuits the tube via at least one glow electrode. As a result of the short circuit current the glow electrode is preheated, while an additional one when opening the switch Voltage in a self-induction contained in the feed line of the tube is produced. Facilitate both preheating and extra tension the ignition of the tube. If the tube does not work when the switch is opened for the first time ignites, the switch repeats until the ignition conditions are met.

The most important representative of the aforementioned gas discharge tubes is the low-pressure mercury vapor discharge tube with a fluorescent wall. As an ignition switch a thermal bimetal switch is usually used as the heating element a glow discharge or resistor is used. The glow discharge switch is the most common. The resistance switch is only used in DC systems and in the case of difficult to ignite (very long or very low ambient temperatures used) Tubes application. Devices with thermal switches have the disadvantage that the ignition of the tube takes a few seconds. For AC systems, .the value of the additional voltage is not constant; when the switch z. B. straight interrupts in the zero crossing of the current. so is the additional tension created Zero. The switch must then repeat, which results in a further ignition delay.

Attempts have been made to remedy these disadvantages by using a switching device to eliminate, which has a much lower inertia and is in sync with the .frequency the supply voltage can work, e.g. B. an electromagnetic switch.

The invention relates to a device with a gas discharge tube in series with a self-induction bridged by an electromagnetic switch and provided with at least one glow electrode received in the bridging branch is, with the excitation winding of the switch parallel to the contacts of this switch lies. In the de-energized state, this is open, i. H. touch the contacts not each other. When the device is energized, the field winding becomes current flowing through it, which closes the switch and a stronger one Current the bypass current branch and the one connected in series with the discharge tube Self-induction flows through it. As a result of closing the switch, however, the Excitation winding short-circuited so that the switch opens again. Consequently a voltage surge is developed in the self-induction, which ignites the tube tries. If this ignition does not take place immediately, closing and are repeated opening the switch. It is ensured that the switching process occurs after ignition the discharge tube is not repeated any further. This can be achieved in that the Switch is designed such that the burning voltage of the discharge tube is not enough to close the switch.

These devices provided with an electromagnetic switch have had serious disadvantages so far. Often the discharge tubes do not ignite or only very sluggishly, if, on the other hand, they ignite quickly, this leads to a shortening the lifespan of the discharge tubes.

The invention aims to improve this device.

According to the invention, the switch is designed and the switch and device are adapted to one another in such a way that the switching period, ie the time between two successive closing operations of the switch, is less than 0.3 seconds, preferably even less than 0.1 seconds, and the sticking time of the switch, ie the duration of the mutual contact of the contacts, takes up such a large part of the switching period that the effective heating current of the glow electrode is more than 0.8 times, preferably more than one time, the operating current of the tube.

The basic idea of the invention consists in a relatively quickly repeating switch by adapting the sticking time of the Switch to achieve a very strong preheating current through the glow electrode (s). The relatively short switching period causes the switch seeks to ignite the tube at short intervals. Because of the relatively long Adhesive time flows through a strong one during a large part of the switching period Current the glow electrode, so that a rapid heating of the glow electrode is achieved will. One will of course strive for the mentioned effective current strength to increase as much as possible and to make it significantly larger than the operating current, to bring the glow electrode to emission temperature as quickly as possible.

In-depth studies have shown that in the known devices the switch opened so quickly that the preheating of the glow electrode was inadequate so that when the tube ignited it would operate with practically cold electrodes which explains the decrease in the life of the tube.

The device can be used for direct current operation: in this Case must be in series with the discharge tube not only a self-induction, but a resistor can also be connected. The switching period should then not be made so short that the preheating current during the gluing of the switch is not the possibility has to rise sufficiently. It has been shown that in practice excellent Results with bonding times between 3 and 25 m [sec. and with such a long switching period can be achieved that the sticking time is more than 35 0/0 or even more than 45 0/0 or 6o% of the switching period.

The invention can also be used with AC powered devices. The device and the switch are preferably dimensioned such that the switch 2 is closed f / n times per second, where f is the frequency of the alternating supply current, e.g. B. 50 Hz, and n represent an integer greater than zero. The switch then switches 2 f t, 2 f 2, 2 f 3 .... times per second. As an experiment it has been found that a switching period equal to 0.5 to 1.5 periods of the feeding alternating current (n = i to 3) gives excellent results; in this case the sticking time of the switch can advantageously be made equal to 0.2 to i periods of the alternating feed current. Preferably the switching period is made equal to one period of the alternating supply current @ (n = 2), in which case the sticking time of the switch can advantageously be made equal to 0.3 to 0.5 periods of the alternating supply current. With the gluing times and switching frequencies selected in this sense, the large inrush currents that occur in the self-induction heating circuit after the switch is closed are used with alternating current. By repeatedly generating an inrush current, a heating current which exceeds the static short-circuit current of the heating circuit, ie the current occurring when the switch is kept constantly closed, can be achieved. By appropriately saturating the magnetic circuit of the self-induction, these current surges can be increased to an even more favorable value. This self-induction can optionally consist of the leakage reactance of a leakage transformer or an alternating current generator.

The series impedance can be advantageous instead of a self-induction consist of the series connection of a capacitance and a self-induction, whereby the capacitance is greater than the inductance. Such combined ballast impedances have already been proposed for discharge tubes with a thermal Ignition switches are provided.

There is one in the current branch bridging the discharge tube additional self-induction added to remove the entire AC resistance when the tube is ignited and to increase the current preheating the glow electrode. It has now show that this additional self-induction known under the name compensator is unnecessary if the described, combined ballast impedance in one according to the invention trained device is used. The connections between the contacts the switch and the electrodes of the lZölire do not need any in this case to contain additional self-induction.

The sticking time of the switch is brought about by electromagnetic, mechanical and remanent magnetic causes. The excitation winding forms a circuit with the closed contacts, the self-induction of which can be designated with L and the resistance with R. After the contacts are closed, the energy accumulated in the self-induction causes a current through this circuit which, if it is sufficiently large, keeps the switch closed. The time during which the switch remains closed for this reason is called the electromagnetic sticking time. This electromagnetic sticking time in seconds is equal to LIR In p, where p is the ratio between the current intensity at which the switch is closed and the current intensity at which the switch opens again, and In p represents the natural logarithm of p. By letting I_, R and p be selected, the electromagnetic sticking time can be influenced.

The "mechanical cause of sticking lies in the inertia" of the switch. Changing the mass inertia is also a means to achieve the desired To achieve gluing time.

It has been found to be advantageous to substantially reduce the glue time to achieve electromagnetic causes and the electromagnetic sticking time at least 5o%, preferably more than 6o%, of the (@total adhesive time. To this Purpose can not only increase the electromagnetic bonding time, but also Reduction of the inertia of the switch can be applied. The setting the gluing time by means of mechanical. Size is usually critical. aside from that is a large number of switching operations per second with just one moving system with a high natural frequency, d. H. achievable with a small mass and a stiff spring, what difficult to combine with a long mechanical sticking time. For the one mentioned Purpose it is advantageous if the magnetic circuit of the switch has a constant air gap has in which the armature of the switch moves. Here the constant Air gap delimiting part of the yoke have an opening through which the Can move anchor in the direction of the core.

It has also proven to be advantageous to use remanent magnetic bonding Limit causes. For this purpose, between the existing magnetic material Parts of the armature and the core of a non-magnetic, solid material are attached. The strength of this substance affects the strength of the current at which the armature drops and can e.g. B: be smaller than ioop.

A spark may be between the opening contacts of the switch appear. The spark apparently extends the glue time as the spark current is over the open contacts flows and thus contributes to the heating current. The spark is however, it is detrimental to the contact material and thus to the service life of the switch. In order to avoid this disadvantage, it has proven advantageous to use the contacts of the switch by connecting a capacitance and a resistor in series bridge. This resistance can be achieved by at least one glow electrode in the tube are formed. The capacity can have a value from iooo to iooooo, e.g. B. from 30 have ooo pF.

The value of the preheating current depends on the short-circuit amperage of the Ballast from the tube. Due to the design of this ballast, it can influence can also be exerted on the preheating current.

The invention further relates to an electromagnetic switch, which is suitable for use in the device designed according to the invention.

According to the invention, this switch has the feature that its switching period, measured with direct current, is shorter than 0.3 seconds, preferably even shorter than 0.1 seconds, and that its sticking time is more than 35%, preferably more than .45 % Or even 60% of this switching period.

According to a further feature of the invention, the electromagnetic Sticking time of the switch at least 50%, preferably more than 60% of the total sticking time be.

The magnetic circuit of the switch can have a constant air gap, in which the armature of the switch moves. The constant air gap can be used delimiting part of the yoke have an opening through which the armature extends in the direction of the core can move.

Preferably, between the parts made of magnetic material the armature and the core attached a non-magnetic material, the strength of which is preferred is less than ioo, et. In an advantageous embodiment of the switch are its contacts through the series connection of a capacitance and bridged by a resistance.

The switch can further have the feature that the armature or at least the support member of the armature in the non-excited state of the switch against an adjustable stop, preferably resting against a flexible wire.

The invention is explained in more detail with reference to the drawing, for example. Here, FIGS. I and 2 are two side views of an embodiment of the new switch, while FIGS. 3 to 5 circuit diagrams designed according to the invention Represent devices.

The magnetic circuit of the switch shown in Fig. I and 2 exists from a core i, a yoke consisting of two parts 2 and 3 and the armature 4. An air gap of constant width is between the yoke part 3 and the core i intended. The armature 4 is attached to a leaf spring 5, which is between the overlapping yoke parts 2 and 3 is clamped. The anchor 4 is in an opening of the part 3 attached and extends through this in the direction of the core. the At its free end, spring 5 has a contact 6 which touches a mating contact 7 can. This mating contact is on an extension of the yoke part 2 with interposition a spacer 8 made of insulating material attached. On the yoke part 3 is a right angle bent wire 9 attached. The spring 5 lies against the horizontal part of this Wire on. The core i is surrounded by a magnetic coil io which is parallel to the Contacts 6 and 7 is switched. These contacts do not touch each other in an unexcited manner "Status of the relay. The connection contacts of the relay are labeled i i and 12.

This relay had the following properties in one particular case: Core dimensions: 8 X 8 X 21 mm; Anchor dimensioning: diameter 2.5, height 4 mm; Yoke part 3: thickness i mm, width 20 mm with an opening of 3 mm diameter for the anchor to pass through. The tombak spring 5 had a thickness of 0.2 mm and a width of 3 mm. In the horizontal part, the armature was arranged at a distance of 16 mm and the contact 6 at a distance of 25 mm from the vertical part of the spring. The magnet winding had 17,000 turns made of enamelled copper wire with a diameter of 40 u. The distance between contacts 6 and 7 in the de-energized state was 1 mm. The size of the fixed air gap between the yoke part 3 and the core i was 1.15 mm, that between the armature 4 and the core was 0.9 mm. At the free end of the core a brass foil 13 with a thickness of 50 µ was attached. Under these circumstances the relay had a self induction of 22 H and a resistance of 12,000 ohms. The pull-in current for direct current at the moment the contacts close was 8 mA. The closed relay opened when the current through the winding was reduced to i mA. The magnetic energy of the self-induction causes a current through the winding when the contacts are closed and tries to keep the armature in the attracted state for a time called the electromagnetic sticking time and L / R In p = 22 / i2 000 hl 8/1 sec . = 4 m / sec. is, where p represents the ratio between the aforementioned attraction flow and waste flow. The total bonding time was 6 m / sec., So that the .. mass effect of the anchor a mechanical bonding time of 2 m / sec. can be attributed. The relay switched 82 times per second at a DC voltage of 220 V. The switching period in this case was 12.2 m / sec., I.e. less than 0.1 seconds, and the total bonding time was 49% of this switching period.

Fig.3 represents the circuit of the switch described with a through Alternating current to be fed gas discharge tube dat. In this figure are the self-induction the solenoid and any other self-inductions that are present in that of the solenoid and the contacts 6 and 7 connected in parallel to this are present are denoted by 14. 15 represents the resistance of the solenoid and any others Represent resistances that occur in the circle mentioned. The spring that makes the contacts Tried to keep open is denoted by 16 and schematically shows the mode of operation the leaf spring 5 in FIGS. 1 and 2. The switch is on the glow electrodes 17 and 18 of the gas discharge tube i9 connected via a choke coil 20 of 1.2 H or via a switch 21 to an alternating current source 22 of 22o V and 5o Hz could be connected. The tube had a length of 120 cm, an inside diameter of 35 mm and was filled with Ar under a pressure of 2 mm. The burning voltage This tube was 10 5 V, the operating current 420 mA with an energy consumption of 40 W.

This tube ignited after 0.1 seconds; During this time, a heating current of 790 mA, which is significantly more than the operating current, flows through the glow electrodes 17 and 18. The resistance of the heating circuit was about 90 ohms. The switch switched at a frequency of 50 per second. The switching period was therefore 20 m / sec. and the sticking time 0.3 periods of the alternating supply current. This means that when the contact is closed, an effective current of 1.45 A passed through heating circuit 20-17-7-6-18. This remarkable fact is due to the favorable adaptation of the sticking time of the switch to the switch-on processes occurring in the heating circuit. It should be noted that the static heating current with constantly closed contacts 6 and 7, that is to say without interruptions, was only 0.66 A. If the switch was replaced by the usual glow light bimetallic relay, the tube ignited on average after 5 seconds, whereby the voltage of the power source had to be increased from 22o to 275 V.

The factors L, R and p, which determine the electromagnetic sticking time of the switch, can easily be changed. By omitting the light 13 on the core and changing the air gap between but and core in 1.5 mm, the self-induction of the circle of the additional current (adhesive circle) was 6, 7, 14, 15 to 25 H, the attraction current to io mA and the release current brought to o, i m.'1. The electromagnetic bonding time was 10 m / sec., The total bonding time 12 m / sec., The heating current 0.72 A, and the relay switched at a frequency of 331 / smal per second, which corresponds to a switching period of 30 m / sec. and means a sticking time of 40% of this switching period. In this case, the tube ignited after 0.4 to 0.8 seconds, i.e. on average after 0.6 seconds. It should be noted that this switch had a switching period of 13.5 m / Sel with direct current. exhibited.

When the resistance 15 was changed to 28 50 ohms, the air gap between yoke and core to 2.5 mm and the layer 13 was arranged from 50 t, on the core, a self-induction 14 of 17 H, a target current of 6.25 mA, a release current of 5.75 mA, an electromagnetic sticking time of practically zero and a total sticking time of 2 m / sec. achieved. The switch switched ioom times per second; the heating current was only 300 mA, with the tube after 180 m / sec. had not yet ignited. The switching period of this switch was 11.1 m / sec for direct current.

It has emerged from these and other measurements that the Embodiments of the invention described, the maximum heating current at a Frequency of 50 Hz of the AC supply voltage, with a gluing time of approx. 8 m / sec. occurs that the heating current decreases only slowly with longer gluing times, with shorter ones Gluing times, however, are relatively quick.

In order to counteract spark formation, a capacitor is according to the invention connected directly in parallel to contacts 6 and 7. It turned out that the contact organs often welded together. This was remedied by the fact that between a resistor was placed across the capacitor and contacts. It turned out that for this purpose the resistance of one or, unfortunately, glow electrodes was sufficient, so that the capacitor can be arranged at the point indicated by 23 in FIG could. Its capacity was 100 to 100,000, preferably about 30,000 pF.

It was found that the additional tension generated upon opening the contacts were 100 to 150 volts.

Of course, the switch must not close after the tube has been ignited. This means that the closing voltage of the switch the burning voltage of the tube must exceed or at least higher than that of burning Tube at the switch must be voltage. The operating voltage increases somewhat during the lifetime of the tube, and the supply voltage can also drop. Therefore, the tightening voltage is 6o to () o%, preferably about 75 0/0 of the supply voltage selected when the operating voltage of the tube is about 5o "/ a of the supply voltage. In the case of a circuit according to FIG. 3, the effective voltage is under supply voltage of the current source 22, when fed by means of a leakage transformer, the no-load voltage to understand its secondary winding.

When the switch was tested, special means were used to control the Contact distance, the distance between armature and core and the mechanical preload to change the spring. This is far too cumbersome for practice. For serial production of the switch, the flexible wire 9 is sufficient as a setting means. The setting is done by carefully moving the free end of the wire up and down will. This end can be cut shorter after the setting has been reached.

4 shows the circuit of a direct current system according to the invention. In the circuit of FIG. 3 the following is replaced: the choke coil 2o by a resistor 24 and a smaller choke coil 25 in series and the alternating current source 22 by a direct current source 26 of 220V. Furthermore, the ends of the glow electrode 17, which now works as an anode, are connected to one another. The resistance of the heating circuit 24-25-7-6-18 was 300 ohms, its self-induction 7o mH. The gluing time had to be at least 3 m / sec. and at least 35 0/0, preferably more than 45 or even 60 0/0 of the switching period. For practical reasons, a gluing time of more than 25 m / sec: is no longer an option. It was found that the heating current was approximately proportional to the square root of the glue time / switching period ratio, which ratio is naturally always less than 1. Since the switch always interrupts at full current strength in the case of direct current, the use of a capacitor parallel to the contacts of the switch, preferably at the point indicated by 23, is desirable. The switches which gave good results in the AC circuit according to FIG. 3 could also be used with the same success in this DC system.

Fig. 5 shows an alternating current system according to the invention at the choke coil 2o according to FIG. 3 by a capacitor 27 and the choke coil 28 is replaced in series. When the capacitance of the capacitor is the reactance of the reactor exceeds, the tube takes a leading current. This has the advantage that when combined with a device according to FIG. 3, a favorable work factor and a significantly quieter light can be achieved. The plant with a tube with leading Discharge current required, in combination with the previously common bimetal relay, the use of an additional choke coil 29 to provide a sufficiently high heating current to reach. It has now been found that when using one according to the invention trained electromagnetic ignition switch the additional choke coil itself superfluous and that nevertheless the tube ignites even more easily than in the circuit according to FIG. 3. The capacitance of the capacitor 27 was 3.5 yF, the self-induction the inductor 1.2 H, the resistance this choke coil and of the glow electrodes together around 90 ohms.

It should be noted that the tube filled only with Ar is a difficult one to ignite Represents tube. At room temperature it is about a normal low pressure mercury vapor discharge tube Equivalent with 2 mm ar-esse filling at an ambient temperature of ° C.

Claims (19)

PATENT POCKET PRICE: i. Ignition device for a gas discharge tube, which is connected in series with a self-induction, bridged by an electromagnetic switch and provided with at least one glow electrode which is located in the bridging current branch, the excitation winding being connected in parallel to the contacts of this switch, characterized in that the switch is such Is constructed and the switch and the device are adapted to one another in such a way that the switching period is shorter than 0.3 seconds, preferably even shorter than 0.1 seconds, and the sticking time is so large a part of the switching period that .the effective heating current the glow electrode is greater than 0.8, preferably greater than the simple operating current of the tube. 2. Ignition device according to claim i for direct current operation, thereby characterized in that the bonding time is 3 to 25 m / sec. and more than 35%, preferably is more than 45 or even 60 0/0 of the switching period. 3. Ignition device according to claim i for alternating current operation, characterized in that the switching period is 0.5 to 1.5 periods and the sticking time is 0.2 to i period of the alternating feed current. 4. Ignition device according to claim 3, characterized in that the switching period is one period and the sticking time is preferably 0.3 to 0.5 periods of the alternating feed current. 5. Ignition device according to claim i, characterized in that the series impedance consists of the series connection of capacitance and self-induction, the capacitance is greater than the inductance, and that the connections between the contacts of the Switch and the electrodes of the tube do not contain any additional self-induction. 6. Ignition device according to claims 3, 4 or 5, characterized in that the heating current is greater than the static short-circuit current of the heating circuit. - '7. Ignition device according to one of the preceding claims, characterized in that the electromagnetic sticking time t = L / R In p is at least 50%, preferably more than 6o 0/0 of the total sticking time, L being the self-induction and R being the resistance of the circuit contains the excitation winding and the contacts of the switch, where p is the ratio between the current intensity at which the switch is closed and the current intensity at which the switch opens again, and ln p represents the natural logarithm of p. B. Ignition device according to claim 7, characterized in that the magnetic circuit of the Switch has a constant air gap in which the armature of the switch emotional. G. Ignition device according to claim 8, characterized in that the constant air gap delimiting part of the yoke has an opening through which the anchor can move in the direction of the core. ok Ignition device according to claim 7, characterized in that between the armature parts made of magnetic material and a non-magnetic, solid substance is attached to the core, its strength is preferably less than i oo lc. i i. Ignition device according to one of the preceding Claims, characterized in that the contacts of the switch are connected in series of capacitance and resistance are bridged, the resistance preferably is formed by at least one glow electrode of the tube. 12. Ignition device according to one of the preceding claims, characterized in that the anchor or at least the support element of the armature in the de-energized state of the switch against one adjustable stop, preferably a flexible wire, is applied. 13. Electromagnetic switch for use in a device according to one of the preceding claims, characterized in that the switching period of the switch, measured with direct current, is shorter than 0.3 seconds, preferably even shorter than 0.1 seconds, and the sticking time is more than 35 0/0, preferably more than 45 or even 6o% of this switching period. 14. Electromagnetic switch according to claim 13, characterized in that that the electromagnetic sticking time is at least 50 0/0, preferably more than 6o % of the total glue time. 15. Electromagnetic switch according to claim 14, characterized characterized in that .the magnetic circuit of the switch has a constant air gap, in which the armature of the switch moves. 16. Electromagnetic switch after Claim 15, characterized in that the one delimiting the constant air gap Part of the yoke has an opening through which the armature extends in the direction of the Kernes can move. 17. Electromagnetic switch according to claim 14, characterized characterized in that between the parts made of magnetic material of the Anchor and the core a non-magnetic, solid material is attached, the strength of which is preferably less than ioo, u. 18. Electromagnetic switch according to claim 13 or one of the following, characterized that the contacts of the switch bridged by the series connection of a capacitance and a resistor are. 19. Electromagnetic switch according to claim 13 or one of the following, characterized in that the armature or at least the support member of the armature in the de-energized state of the switch against an adjustable stop, preferably against a flexible wire, rests.