KR100336925B1 - Natrium Discharge Lamp - Google Patents

Abstract

The present invention relates to a sodium discharge lamp in which the lamp is started through the instantaneous heating of the discharge tube without the electronic ballast for the discharge lamp.

Disclosed is a discharge tube which is disposed in a vacuum bulb space and receives a voltage through two conductors and a tubular bushing from two electrodes, respectively, and is disposed at a distance from a discharge tube and a predetermined distance from one of the two conductors. A sodium discharge lamp having a support through which a conductor of the battery comprises: first and second driven contact members connected to two conductors and vertically disposed to face each other along an outer wall of the discharge tube from one end of the discharge tube to a predetermined length; One end is connected to the first driven contact member and one of the tubular bushings, and the other end is contacted to the second driven contact member to self-heat when the lamp is started, and to return to the first driven contact member when the ambient temperature of the discharge tube is above a predetermined temperature. Movable contact member to stop the heat generation by itself; A support member of a non-resistance component connected between the tubular bushing positioned at one of the two electrodes and the support rod for supplying voltage to the other tubular bushing side to support the discharge tube,

Accordingly, since the lamp can be started without the resonant circuit of the electronic ballast for the sodium discharge lamp, it is easy to replace the mercury lamp, and the cost of installing and replacing the sodium discharge lamp is reduced, and the lamp life is semi-permanent.

Description

Sodium Discharge Lamp

The present invention relates to a discharge lamp for injecting sodium gas, in particular in discharge lamps such as mercury, metal halides and sodium lamps, more specifically, it is inevitably used in sodium discharge lamps to start the discharge by a high-voltage voltage difference The present invention relates to a sodium discharge lamp that eliminates a dedicated ballast for the discharge lamp and starts the lamp by instantaneous heating of the discharge tube, thereby reducing energy waste and extending the life of the lamp and convenience of lamp replacement.

In general, mercury, metal halides, sodium discharge lamps, and the like can be cited as the discharge lamps that emit light and are installed in roadside trees, tunnels, and large factories.

The power consumption of the mercury discharge lamp and the metal halide discharge lamp depends on the type of each lamp. For example, there is a lamp having a power consumption of 175W to 1.5KW.

Such mercury discharge lamps and metal halide discharge lamps require electronic ballasts when they are turned on. In this case, the mercury discharge lamps and metal halide discharge lamps should select various types of electronic ballasts.

In particular, the electronic ballast applied to the mercury discharge lamp and the metal halide discharge lamp can be configured using a plurality of circuits, and has the advantage that the circuit is simple, while the mercury discharge lamp and the metal halide discharge lamp are consumed. It has the disadvantage of lower efficiency than the sodium discharge lamp compared to the power.

The electronic ballast applied to the sodium discharge lamp must generate electricity with a frequency higher than the frequency of the line voltage in order to start the sodium discharge lamp, while the circuit itself is complicated, but the mercury discharge lamp and It has considerably higher advantages than metal halide discharge lamps.

Due to the high efficiency of such sodium discharge lamps, the work of replacing the mercury discharge lamps and the metal halide discharge lamps already used in recent years with sodium discharge lamps is in progress.

However, in order to simply replace the mercury discharge lamp and the metal halide discharge lamp with the sodium discharge lamp, it is difficult to install and replace construction cost that must be replaced by the electronic ballast accordingly.

In particular, the sodium discharge lamp is classified into a high-pressure type and a low-pressure type, in general, the high-pressure sodium discharge lamp is one of the small size of the tube and the voltage difference between the starting voltage of the ballast and the on (ON) state, but low pressure sodium Discharge lamps have a larger tube size, higher starting voltage of ballast than high voltage type, and large voltage difference between starting voltage and on state.

Therefore, the electronic ballast must be selected according to the use of the high-pressure and low-pressure sodium discharge lamp, and all of the electronic ballasts for the high-pressure or low-pressure sodium discharge lamp convert the line voltage into a direct current voltage. The sodium discharge lamp is started by the difference in voltage obtained by resonating the voltage.

In addition, an important characteristic required for the electronic ballast for sodium discharge lamp is to improve the light efficiency of the lamp at a high frequency at the same time to reduce the quick start-up and power consumption, for example, according to Korean Patent Publication No. 89-574 Known.

Figure 1 shows one of the electronic ballast for such a low pressure sodium discharge lamp described in Korean Patent Publication No. 89-574.

The electronic ballast for the low pressure sodium discharge lamp, as shown in Figure 1, is connected to the AC power supply by the high frequency filter F, the peripheral current transformer M and the rectifier R. A high-frequency oscillator consisting of two transistors (1) and (2) in series connection between a positive (+) DC terminal and a lamp (8) constitutes a circuit. The two transistors 1, 2 are arranged to operate in an alternating phase. Diodes 12 and 13 are connected in series to the emitters of transistors 1 and 2. In the base drive transformer 3 of the transistors 1 and 2, one terminal of the primary winding 4 is connected between the transistors 1 and 2, and the other terminal is the inductor coil (choke) (7). It is connected to one terminal of the lamp (8) by.

The other electrode 8a of the lamp 8 is connected to the opposite polarity of the power supply by the resonant capacitors 10 and 11 and the voltage limiting diodes 23 and 24 parallel to them. The electrolytic capacitor C acts as a filter capacitor between the positive and negative power supply terminals. The parallel capacitor 9 of the lamp 8 also determines the starting frequency together with the lamp voltage just before the lamp 8 is turned on. However, during operation, the capacitors 10 and 11 additionally form the main resonance capacitance of the free oscillating series resonant circuit including an inductance in the form of a coil 7. In addition, the secondary windings 5 and 6 of the base drive transformer 3 are connected to the base terminals of the two transistors 1 and 2 so as to obtain a control voltage in the opposite phase. One of the two transistors then becomes conductive when the other transistor is not conducting or vice versa.

The protective diodes 14 and 15 connected between the winding 4 of the base drive transformer 3 and the (+) (-) power supply terminals are connected to each other when the transistors 1 and 2 are in the nonconductive state. It provides a passage for the current of the inductance 7.

The operation of the conventional electronic ballast for low pressure sodium discharge lamp made in this way will be described below.

The filter capacitor C is charged to the voltage forming the supply voltage of the circuit through the rectifier R. In the free oscillation resonant circuit, current flows to the electrodes 8a of the lamp 8 by both capacitors 10 and 11, from which the inductance and transformer 3 of the lamp 8 and the capacitor 9 are transferred. It flows through the side winding and flows to the conducting transistor 2 when the circuit is closed. In the oscillation circuit, the capacitors 10 and 11 are connected in parallel, and the capacitor 9 is connected in series to these parallel connections. In order to fix the capacitor 9 to the onset frequency of the lamp 8 higher than the operating frequency, the capacity of the capacitor 9 connected to the lamp 8 is equal to the capacity of the two capacitors 10 and 11 in parallel. It is good to set it as 1/2-1/4 with respect to a sum. When the current in the above-mentioned resonant circuit starts to decrease, the control voltage induced in the secondary windings 5, 6 of the transformer 3 at a sufficient rising reverse voltage of the capacitor 9 causes the transistor 2 to vision. Will cause the transistor 1 to be conductive at the same time. At this time, the current is again the winding (4) and coil (7), capacitor (9), and capacitor (10) of the transformer 3 until the reverse voltage formed in the capacitor (9) limits the flow of current for the change of direction It starts to flow in the opposite direction through the parallel connection of, (11). In this way, the current curve in the circuit forms a sine curve, and the current flowing through the transistor at the switching instant is close to zero. Under this situation, the conversion loss is minimal. The current flowing through the capacitor 9 turns on the lamp 8.

Of course, the cold cathode discharge lamp itself may be directly connected in parallel with the capacitor (9). The resistive impedance generated in the lamp 8 is connected in parallel with the capacitor 9. Since the resonant frequency mainly fixes the parallel connection of the capacitors 10 and 11, the operating frequency is reduced with respect to the onset start frequency. However, a current for heating the lamp 8 flows through the capacitor 9 until then. Due to the negative characteristics of the resistance by the lamp 8, the voltage of the electrode terminal 8a is not stabilized unless the diodes 23, 24 are connected in parallel with the capacitors 10, 11. Only one diode 23 or diode 24 is sufficient for the purpose of stabilization. If, for example, the voltage at the terminal 8a is to increase with the decreasing resistance of the lamp 8 or with the increase in the lamp current, the excess voltage is passed through the diode 23 or 24 for the return to the capacitor C. Leave the resonant circuit. In every half cycle, the voltage charged to capacitors 10 and 11 will be distributed so that the voltage at terminal 8a will stabilize.

As described above, the lamp 8 is discharged and turned on by generating a high start voltage through the electronic ballast and then the lamp 8 is continuously turned on with a stable start voltage that is much lower than the start voltage.

However, these electronic ballasts are economically lost at the end of the lamp life, when the lamps break out, or when the instantaneous overcurrent flows, the circuit elements of the electronic ballasts are destroyed and eventually the electronic ballasts and the lamps integrated therewith must be replaced. It will cause difficulty in replacement and replacement.

Therefore, as one method of avoiding the breakdown of the electronic ballast caused by the overcurrent and the detachment of the lamp and the resulting economic loss and the difficulty of replacing the lamp, for example, according to Korean Utility Model Publication No. 96-8112 Known.

According to Utility Model No. 96-8112, when the ballast is in normal operation, an overcurrent compensating circuit unit which operates only when an overcurrent flows due to an abnormality in the ballast is disposed so as to prevent damage to the switching element due to overcurrent. It is.

However, the overcurrent blocking method of the electronic ballast also cannot be an effective overcurrent blocking in the event of an abnormality or short circuit in the overcurrent compensating circuit. Therefore, the ballast itself and the lamp must be replaced as in the former.

FIG. 2 is a front view showing one conventional low pressure sodium discharge lamp that emits light by being started by the low pressure sodium discharge lamp ballast as described above or other kinds of electronic discharge ballasts for various types of sodium discharge.

The sodium discharge lamp 50 has a discharge tube 51 made of ceramic oxide. The discharge tube is longitudinally disposed at the center of the hemispherical bulb 52 made of hard glass, and the hard glass is sealed at the first end by the screw cap 53 and at the second end by the recess 59. do. Bulb 52 is emptied.

In the discharge tube 51, two first and second electrodes 54 and 54a having a predetermined electrode gap are arranged to face each other. The first electrode 54 away from the screw cap 53 is connected to the lead wire 57 along the discharge tube 51 via a tubular bushing 55 having an attachment 56. The lead wire 57 is guided toward the screw cap 53 along the outside of the discharge tube 51 and is connected to a supporting rod 58 of a conductor that supports the discharge tube 51. In addition, one end of the support rod 58 is fixed to the recess 59, and the other end is connected to the screw cap 53 to which power is input through the molding 63.

Similarly, the second electrode 54a is connected to the metal wire 60 via the tubular bushing 55a, and the metal wire 60 is contacted through the conductor 61 through the molding 63. Is connected to.

The discharge tube 51 contains a filler in which xenon and sodium gas are mixed at a predetermined ratio.

The conventional sodium discharge lamp 50 configured as described above has a high onset voltage of several tens of KHz to several hundred KHz generated from the above-mentioned Korean Patent Publication No. 89-574 or Utility Model Publication No. 96-8116 or other various kinds of electronic ballasts. Will be needed.

In other words, a high resonance voltage, for example, a voltage of 4 Kv, is applied to the screw cap 53 and the contact portion 62 of the sodium discharge lamp 50 from the above-described electronic ballast, respectively. The high frequency lighting start voltage applied to the screw cap 53 is applied to the first electrode of the discharge tube 51 through the support rod 58, the lead wire 57, the accessory 56, and the tubular bushing 55 of the conductor. 54 is supplied to the contact portion 62 and is supplied to the second electrode 54a in the discharge tube 51 through the conductor 61, the metal wire 60, and the tubular bushing 55a. .

When the lighting start voltage is applied to the first electrode 54 and the second electrode 54a in the discharge tube 51, the discharge tube 51 is disposed vertically in the bulb 52 and a mixed gas of xenon and sodium is sealed in the tube. This high discharge start voltage causes initial discharge and diffuses the light. After the discharge tube 51 is turned on, it is input from the above-described electronic ballast and continues to emit light by an operation start voltage lower than the start voltage.

The sodium discharge lamp according to the prior art requires the above-described electronic ballast for the sodium discharge lamp, when the circuit element of the electronic ballast is damaged by the above conditions, or when the electronic ballast is deteriorated to perform an unstable operation There is an economic loss and difficulty in replacing the ballast and the lamp integrated with it.

In addition, when the mercury lamp currently used to replace the sodium discharge lamp, it is impossible to replace only the sodium discharge lamp and there is a problem that the electronic ballast must also be replaced for sodium. In particular, the electronic ballast for sodium discharge lamp generates a high frequency of more than tens to hundreds of KHz to start the sodium discharge lamp, which has a fatal adverse effect on the controller of the precision machine around which the sodium discharge lamp is installed and the automatic cars running around. There is another problem.

Accordingly, it is desirable to provide a low-cost sodium discharge lamp in terms of cost, and a more efficient and stable sodium discharge lamp in terms of reliability while alleviating the above problems.

Accordingly, an object of the present invention is to provide a sodium discharge lamp which starts a lamp even at low voltage, without an electronic ballast which starts the lamp by a high voltage difference using a resonant circuit, and the lamp has a simple structure. .

Another object of the present invention is to provide a sodium discharge lamp that can be used in common in the ballast for mercury lamps, this lamp is to replace the efficient sodium lamps from mercury lamps and to facilitate the replacement work and minimize energy waste It is characterized by.

It is yet another object of the present invention to provide a sodium discharge lamp which starts the lamp as the release of hot electrons due to instantaneous heating without the occurrence of high frequency at the start of the lamp, which generates instantaneous high heat in the discharge tube and then switches Characterized in that the heating start unit is arranged.

Another object of the present invention is to protect the lamp itself from high heat and instantaneous overvoltage to further extend its life.

1 is a circuit diagram for explaining an electronic ballast for a sodium discharge lamp according to the prior art,

2 is a front view showing a sodium discharge lamp according to the prior art,

3 is a front view showing an embodiment provided in the description of the sodium discharge lamp according to the present invention,

4 is a cross-sectional view taken along line IV-IV of FIG. 3,

FIG. 5 is an enlarged view illustrating a heating start unit arranged around the discharge tube of FIG. 3 to generate high heat.

<Description of the symbols for the main parts of the drawings>

51: discharge tube 52: bulb

54, 54a: first second electrode 55, 55a: tubular bushing

110: heat generating start portion 110a, 110b: first, second driven contact member

110c: movable contact member 120: support

130: flexible wire 150: support member

The sodium discharge lamp according to an aspect of the present invention for achieving the above object is disposed in the vacuum space bulb space and discharged to receive a voltage through two conductors and two tubular bushings from two electrodes, respectively, and the A sodium discharge lamp having a support disposed at an electrode side of one of the two electrodes of a discharge tube and spaced apart from the discharge tube by a predetermined distance, and having one of the two conductors penetrated therein: (1) A conductor passing through the support and the First and second driven contact members connected to a conductor which does not penetrate the support, and each having contact pieces vertically disposed to face each other along the outer wall of the discharge tube from one end of the discharge tube to a predetermined length; (2) One end is connected to the first driven contact member and the one tubular bushing, and the other end is contacted with the contact piece of the second driven contact member to self-heat when the lamp is started, and the ambient temperature of the discharge tube is increased. A movable contact member having a contact piece that returns to the contact piece of the first driven contact member when the temperature reaches a predetermined temperature and stops heat generation thereof; And (3) a support member of a non-resistance component connected between the tubular bushing positioned at one of the two electrodes and the support rod for supplying voltage to the other tubular bushing to support the discharge tube.

Optionally, the contact piece of the movable contact member and the tubular bushing are connected by a flexible wire.

In this way, when the lamp is started, hot electrons are emitted while the surroundings of the discharge tube are heated to a high temperature by a momentary short-circuit of the movable contact member and the second driven contact member, and thus a low voltage inputted by the hot electrons to the two electrodes, for example, It can be seen that even at 220V, the lamp easily turns on and the lamp is turned on, and the movable contact member moves to the first driven contact member at the moment when the ambient temperature of the discharge tube is higher than the predetermined temperature, that is, the discharge occurs, thereby preventing the power short.

As a result, since the lamp can be started without the resonant circuit of the electronic ballast for the sodium discharge lamp, it is easy to replace the mercury lamp, and the cost of the installation and replacement of the sodium discharge lamp as well as the life of the lamp has a semi-permanent advantage.

And, there may be a plurality of embodiments of the present invention, the following will be described in detail with respect to the most preferred embodiment.

Through this preferred embodiment, it is possible to better understand the objects, features and advantages of the present invention.

Hereinafter, preferred embodiments of the sodium discharge lamp according to the present invention with reference to the accompanying drawings will be described in detail.

In addition, the technique of the present invention can be applied to various types of discharge lamps that cause discharge by using a resonance circuit.

Thus, FIGS. 3 to 5 used in the description focus on various types of discharge lamps using a high voltage difference rather than a specific discharge lamp.

In addition, in each figure used for description, the same component may be attached | subjected, and may show the same number, and the overlapping description may be abbreviate | omitted.

In addition, in the following description, the example which used sodium as a discharge type lamp is considered.

3 is a front view showing an embodiment provided in the description of the sodium discharge lamp according to the invention, Figure 4 is a cross-sectional view taken along the line IV-IV of Figure 3, Figure 5 is disposed around the discharge tube of Figure 3 Figure shows an enlarged heat generating starter that generates high heat.

The sodium discharge lamp 100 according to the present embodiment is made of ceramic oxide and has a discharge tube 51 containing a filler in which mercury, xenon, and sodium are mixed at a predetermined ratio.

The discharge tube 51 is longitudinally disposed at the center of the substantially hemispherical bulb 52 made of hard glass, and the bulb 52 of the hard glass is screwed at the first end and recessed by the screw cap 53. Is sealed at the second end. The bulb 52 is in a vacuum state.

In the discharge tube 51, two first and second electrodes 54 and 54a having a predetermined electrode gap are arranged to face each other. The first electrode 54 away from the screw cap 53 is connected to the lead wire 57 along the discharge tube 51 via a tubular bushing 55 having an attachment 56. A lead wire 57 for supporting the discharge tube 51 and for supplying power is connected to the support rod 58 of the conductor guided to the screw cap 53 along the outside of the discharge tube 51. In addition, one end of the support bar 58 is fixed to the recess 59, and the other end is connected to the screw cap 53 through the molding 63.

In the general sodium discharge lamp configured as described above, in particular, in the present invention, one of the two electrodes 54 and 54a of the discharge tube 51, preferably, the discharge tube 51 and the predetermined electrode on the side of the second electrode 54a. Place the support 120 of the insulator at a distance of.

In addition, two conductor pins 140 and 140a penetrate the support 120 and are connected to the conductors 160 and 160a respectively connected to the screw cap 53 and the contact portion 62 through the molding 63. When the lamp starts, the voltages of the two conductors 160 and 160a are shorted to generate high heat around the discharge tube 51 so as to discharge them, and when the temperature around the discharge tube 51 rises above a certain temperature, it switches instantly. A heating start unit 110 for stopping heat generation is installed between the discharge tube 51 and the support 120. Moreover, the support member 150 of the resistivity component for supporting the discharge tube 51 is connected between the tubular bushing 55a and the support rod 58 connected with the 2nd electrode 54a.

In the above, the heating start unit 110 is connected to the two conductor pins (140, 140a) passing through the support 120, each other along the outer wall of the discharge tube 51 to the predetermined length from the lower end of the discharge tube 51 The first and second driven contact members 110a and 110b having contact pieces 110d and 110e formed on the upper end portions which are vertically spaced apart from each other, and one end thereof are connected to the lower end of the first driven contact member 110a and the other end portion thereof. Touches the contact piece 110e of the second driven contact member 110b and generates heat, and when the ambient temperature of the discharge tube 51 reaches a predetermined temperature or more, the contact piece 110d of the first driven contact member 110a is heated. The second electrode is connected to the movable contact member 110c having the contact piece 110f which moves and contacts therewith, the contact piece 110f of the movable contact member 110c, and the tubular bushing 55a of the second electrode 54a. It consists of the flexible wire 130 which supplies a voltage to 54a.

In the drawings, reference numerals 170 and 180 are jitters connected to the two conductors 160 and 160a to increase the degree of vacuum in the bulb 52 and to remove impurities.

Sodium discharge lamp of the present invention made as described above will be described in more detail with reference to FIGS.

First, a line voltage, for example, 220V, is input through the two conductors 160 and 160a from the screw cap 53 and the contact portion 62 of the sodium discharge lamp 100. The line voltage of 220 V through the screw cap 53 and the conductor 160a is the first of the discharge tube 51 through the support rod 58, the lead wire 57, the attachment 56, and the tubular bushing 55 of the conductor. The electrode 54 is supplied to the second driven contact member 110b through the conductor pin 140a of the heat generating starter 110 connected to the conductor 160a.

Meanwhile, the line voltage of 220V through the contact portion 62 and the conductor 160 is supplied to the first driven contact member 110a and the movable contact member 110c through the conductor pin 140 of the heating starter 110. In addition, it is simultaneously supplied to the tubular bushing 55a connected to the first electrode 54a via the flexible wire 130. In this case, as shown in FIG. 5, since the contact piece 110e of the movable contact member 110c such as bimetal is in contact with the second driven contact member 110b before the lamp is started, the two conductors 160 and 160a and the conductor pins. The line voltage inputted to 140 and 140a is in a short state. Accordingly, the contact portion of the movable contact member 110c and the second driven contact member 110b is heated to generate instantaneous high heat. The high heat generated at the contact portion instantly heats the bulb 52 in the vacuum state and the discharge tube 51 as the cold cathode, thereby releasing a large amount of hot electrons in the discharge tube 51.

When the temperature of the two contact portions is greater than or equal to a predetermined temperature, the movable contact member 110c is momentarily moved toward the first driven contact member 110a to be in contact with the contact piece 110d, thereby preventing short of two voltages. . Here, the contact between the movable contact member 110c and the second driven contact member 110b is instantaneous and the tubular toward the second electrode 54a side even if the movable contact member 110c is separated from the second driven contact member 110b. The line voltage is continuously supplied to the bushing 55a by the flexible wire 130.

Subsequently, the cold cathode discharge tube 51 is instantaneously heated to emit a large amount of hot electrons, and at the same time, a low line voltage 220V is continuously input to the first and second electrodes 54 and 54a, thereby discharging the discharge tube. Discharge of 51 is made smoothly, and it lights.

Since the temperature in the bulb 52 is considerably high in the state where the sodium discharge lamp 100 is continuously lit, the movable contact member 110c is kept in the first passive contact until the lamp is turned off and the temperature is lowered to some extent. The contact piece 110d of the member 110a is contacted.

When the sodium discharge lamp is turned off and the temperature of the bulb 52 falls below a predetermined temperature, the movable contact member 110c returns to an initial state, that is, moves to the contact piece 110e of the second driven contact member 110b to make contact. do.

On the other hand, as a comparative example, unlike the conventional technique, that is, the sodium discharge lamp is discharged by using a resonant circuit of a sodium-only electronic ballast, and after the discharge is turned on by using a line voltage, the present invention provides a The lamp is started by heating the discharge tube as heat obtained by momentarily shorting the line voltage input to the power supply. It turns out that it turns on.

As a result, according to the present invention, an electronic ballast for sodium is not required when the sodium lamp is turned on, the replacement of the mercury lamp is facilitated, and the life of the product can be extended and the product can be stabilized.

In addition, while specific embodiments of the present invention have been described and illustrated above, it is obvious that the present invention may be variously modified and implemented by those skilled in the art.

Such modified embodiments should not be individually understood from the technical spirit or the prospect of the present invention, and such modified embodiments should fall within the appended claims of the present invention.

According to the sodium discharge lamp of the present invention, which is clear from the above description, the sodium discharge lamp can be started without the resonant circuit of the exclusive electronic ballast for sodium, and it is easy to replace and replace the mercury lamp with an efficient sodium discharge lamp. Cost reduction and energy waste are minimized.

In addition, since the lamp itself is protected from high temperature and instantaneous overvoltage, the lifetime is semi-permanent and the installation of the sodium discharge lamp has a simple effect.

Claims (4)

A discharge tube disposed in a vacuum bulb space and receiving a voltage through two conductors and two tubular bushings from two electrodes, respectively, and spaced apart from the discharge tube by a predetermined distance on one of the two electrodes of the discharge tube; In a sodium discharge lamp with a support through which one of the two conductors is perforated: (1) a first connecting member connected to a conductor penetrating said support member and a conductor not penetrating said support member, each having a contact piece vertically disposed opposite to each other along an outer wall of said discharge tube from one end of said discharge tube to a predetermined length; A second driven contact member; (2) One end is connected to the first driven contact member and the one tubular bushing, and the other end is contacted with the contact piece of the second driven contact member to self-heat when the lamp is started, and the ambient temperature of the discharge tube is increased. A movable contact member having a contact piece that returns to the contact piece of the first driven contact member when the temperature reaches a predetermined temperature and stops heat generation thereof; And (3) Sodium comprising a support member of a non-resistance component connected between the tubular bushing located on either electrode side of the two electrodes and the support rod for supplying voltage to the other tubular bushing side to support the discharge tube. Discharge lamp. (delete) (delete) The method of claim 1, A sodium discharge lamp, characterized in that the contact piece of the movable contact member and the tubular bushing are connected by a flexible wire.