JP2006040671A - High pressure discharge lamp with built-in starter - Google Patents

Abstract

[PROBLEMS] A conventional high pressure discharge lamp with a built-in starter stops the operation of a switching element due to a malfunction of the starter when it takes several seconds or more until the lamp is lit. There was a drawback of becoming.
An arc tube 1 and a starter are housed in an envelope 9 having an outer tube and a base, and the arc tube 1 and the starter are connected in parallel. The starter includes a first parallel body in which a series body of a negative characteristic thermistor 7 and a resistor 6 for limiting a current flowing through the negative characteristic thermistor 7 is connected in parallel with the switching element 8.
[Selection] Figure 1

Description

  The present invention relates to a high pressure discharge lamp with a built-in starter in which a starter is built in an envelope including an outer tube and a base.

High-pressure sodium lamps that use translucent alumina ceramic for arc tubes, high-pressure mercury lamps that use transparent quartz tubes, or metal halide lamps are excellent in efficiency, so they are widely used in applications such as factory lighting and road lighting. Yes.

  By the way, a high-pressure mercury lamp does not require a high voltage pulse for starting the lamp, but a high-pressure sodium lamp or a metal halide lamp generally requires a high voltage pulse for starting the lamp. In particular, in a so-called ceramic metal halide lamp using a translucent alumina ceramic in a recently commercialized arc tube, it is difficult to provide a starting auxiliary electrode on the arc tube, and a high voltage pulse is required for starting. .

  As a method of applying a high voltage pulse to both ends of the arc tube at the time of starting the lamp, a method using a ballast with a built-in pulse generator, and a method using a built-in starter type lamp with a built-in starter in the lamp envelope, There is. The former requires an exclusive ballast with a built-in pulse generator, whereas the latter has the advantage that it can be lit with the most widely used inexpensive ballast for high-pressure mercury lamps. For this reason, a built-in starter type lamp is generally used as a high-pressure sodium lamp. Recently, a ceramic metal halide lamp having a built-in starter type is becoming common.

  By the way, as an example of the high pressure discharge lamp with a built-in starter, the one described in Patent Document 1 as shown in FIG. 4 is known. In FIG. 4, 1 is an arc tube, 12 is a resistor, 4 is a bimetal switch, 7 is a negative thermistor, 8 is a switching element such as a glow tube, and 9 is an envelope. The resistor 12 and the bimetal switch 4 are connected in series with a parallel circuit of the switching element 8 and the negative characteristic thermistor 7, and these four components form a starter. Here, the negative characteristic thermistor is an element whose resistance value decreases as the temperature rises. The bimetal switch 4 is closed when the lamp is not lit, and is attached to be opened by heat from the arc tube when the lamp is lit. The principle of operation when this lamp is normally lit and when it is not normally lit is as follows.

<When the lamp lights up normally>
When an AC voltage is applied to the base terminals a and b through the ballast, the switching element 8 operates, and the value of the current flowing through the starter repeatedly increases and decreases according to the opening and closing of the switching element contact. As a result, high voltage pulses are generated across a ballast (not shown) consisting of chokes. The high voltage pulse generated at both ends of the ballast is applied to the electrodes at both ends of the arc tube 1 through the cap terminals a and b, and the lamp is turned on. When the lamp is turned on, the bimetal switch 4 is opened by heat from the arc tube, and the operation of the starter is stopped.

<If the lamp does not light up normally>
In the case where the lamp does not light normally, for example, when the starting voltage of the arc tube rises and the lamp is in an astigmatic state, the operation principle is as follows. When an alternating voltage is applied to the base terminals a and b through the ballast, the switching element 8 operates, and the value of the current flowing through the starter repeatedly increases and decreases according to the opening and closing of the switching element contacts. As a result, a high voltage pulse is generated at both ends of a ballast (not shown) made of choke. The high voltage pulse generated at both ends of the ballast is applied to the electrodes at both ends of the arc tube 1, but the lamp is not lit because the starting voltage of the arc tube is high. Since the current continues to flow through the starter unless the lamp is lit, the temperature of the negative thermistor 7 rises due to self-heating due to the current, and the resistance value decreases. When the resistance value of the negative characteristic thermistor 7 decreases, the voltage value applied to the switching element 8 decreases. When the voltage applied to the switching element 8 falls below a certain value, the operation of the switching element stops. That is, if the arc tube becomes defective for some reason, the operation of the switching element is stopped after a certain period of time, and the generation of the high voltage pulse is automatically stopped.

JP-A-8-250072

  Incidentally, the conventional high-pressure discharge lamp with a built-in starter shown in FIG. 4 has a drawback that even a normal lamp becomes inconspicuous due to a malfunction caused by the following starter.

<Malfunction 1>
Even when the lamp is normal, depending on the operation timing of the switching element 8, the resistance value of the negative characteristic thermistor 7 may decrease, and the switching element 8 may become inoperative. That is, the resistance value of the negative characteristic thermistor decreases in a short time within a few seconds after voltage application due to self-heating due to the flowing current. Therefore, when it takes several seconds or more for the lamp to light up, the operation of the switching element 8 without the lamp lighting up. Will stop. When the operation of the switching element 8 stops, the lamp cannot be lit and becomes in a state of astigmatism. As described above, there has been a problem that a normal lamp cannot be lit due to a malfunction caused by a starter built in the lamp envelope.

<Malfunction 2>
Even when the lamp is normal, the lamp starting voltage is high when the temperature of the arc tube 1 is not sufficiently lowered when the lamp is restarted. Therefore, when the bimetal switch 4 is closed, the lamp is not lit even when the switching element 8 is operated. As a result, the lamp is in an astigmatic state, the resistance value of the negative characteristic thermistor 7 decreases, and the operation of the switching element 8 stops. When the operation of the switching element 8 is stopped, the lamp cannot be turned on and it becomes a point. As described above, there is a problem that a normal lamp cannot be restarted due to a malfunction caused by a starter built in the lamp envelope.

  The present invention has been made to solve such problems, and provides a high pressure discharge lamp with a built-in starter that does not cause a malfunction due to the above-described starter.

  According to the first aspect of the present invention, a starter and an arc tube are accommodated in an envelope including an outer tube and a base, and the starter and the arc tube are connected in parallel. In the high-pressure discharge lamp, the starter includes a first parallel body in which a series body of a negative characteristic thermistor and a resistor is connected in parallel with the switching element.

  According to a second aspect of the present invention, a starter and an arc tube are housed in an envelope comprising an outer tube and a base, and the starter and the arc tube are connected in parallel. In the high-pressure discharge lamp, the starter includes a second parallel body in which a bimetal switch and a resistor are connected in parallel, and a third parallel body in which a negative characteristic thermistor and a switching element 8 are connected in parallel. In addition, the second parallel body and the third parallel body are connected in series.

  According to a third aspect of the present invention, a starter and an arc tube are housed in an envelope including an outer tube and a base, and the starter and the arc tube are connected in parallel. In the high-pressure discharge lamp, the starter includes a first parallel body in which a series body of a negative characteristic thermistor and a resistor is connected in parallel with the switching element, and a second parallel body in which a bimetal switch and a resistor are connected in parallel. And the first parallel body and the second parallel body are connected in series.

  According to the first aspect of the present invention, since the negative characteristic thermistor and the resistor are connected in series in the first parallel body constituting the starter, the magnitude of the current flowing through the negative characteristic thermistor can be controlled by the resistance. . As a result, the time until the resistance value of the negative-characteristics thermistor drops can be set freely, and switching has been a drawback of conventional high-pressure discharge lamps with a built-in starter. A malfunction that the operation of the element stops, that is, the malfunction 1 described above can be prevented.

  According to the invention of claim 2, the starter includes a second parallel body in which a resistor is connected in parallel with the bimetal switch, and a third parallel body in which the negative characteristic thermistor 7 is connected in parallel with the switching element 8. Since the two are connected in series, the bimetal can be heated using the heat generated by the resistor connected in parallel with the bimetal, and the return time of the bimetal when the lamp is restarted can be freely set. Thereby, the bimetal 4 is closed in a state where the temperature of the arc tube is not sufficiently lowered, which is a disadvantage of the conventional high pressure discharge lamp with a built-in starter, the resistance value of the negative characteristic thermistor 7 is lowered, and the operation of the switching element 8 is performed. Can be prevented from malfunctioning, that is, the malfunction 2 described above.

  According to the invention of claim 3, the starter comprises a first parallel body in which a series body of a negative characteristic thermistor and a resistor is connected in parallel with the switching element, and a bimetal switch and a resistor connected in parallel. Since the two parallel bodies are connected in series, the bimetal can be heated using the heat generated by the resistor connected in parallel with the bimetal, and the return time of the bimetal can be freely set when the lamp is restarted. The magnitude of current flowing through the thermistor can be controlled by resistance. Thereby, the bimetal 4 is closed in a state where the temperature of the arc tube is not sufficiently lowered, which is a disadvantage of the conventional high pressure discharge lamp with a built-in starter, the resistance value of the negative characteristic thermistor 7 is lowered, and the operation of the switching element is performed. It is possible to prevent both of the malfunction 2 that stops, that is, the malfunction 2 and the malfunction that the operation of the switching element stops, that is, the malfunction 1 described above, when it takes several seconds or more for the lamp to turn on.

  The present invention will be described with reference to the drawings. FIG. 1 is a circuit configuration diagram showing a first embodiment of a high-pressure discharge lamp with a built-in starter according to the present invention. In FIG. 1, reference numeral 9 denotes an envelope including an outer tube and a base, and an arc tube 1 having electrodes at both ends thereof is connected to and fixed to the electric lead wires a and b. . Further, a starter is connected in parallel with the arc tube 1 between the electric lead-ins a and b.

  The starter includes a first parallel body in which a series body of a negative characteristic thermistor 7 and a resistor 6 is connected in parallel with the switching element 8, a resistor 5 connected in series with the first parallel body, and the resistance 5 includes a bimetal switch 4 connected in series with the filament 5 and a filament resistor 10 connected in series with the bimetal switch 4. Here, the negative characteristic thermistor is an element whose resistance value decreases as the temperature rises. For example, a negative thermistor having a characteristic of about 10 KΩ at room temperature of 25 ° C. but about 55Ω at 250 ° C. can be used.

  In the starter, the resistor 6 is for adjusting the current flowing in the negative characteristic thermistor 7. The resistance 6 controls the amount of current flowing through the negative characteristic thermistor 7 and adjusts the time until the resistance value of the negative characteristic thermistor 7 decreases due to self-heating. As a result, the lamp can be reliably started even when it takes several seconds or more to light the lamp. Further, the resistor 5 is for adjusting the current flowing through the switching element 8. By this resistor 5, the current flowing through the switching element 8 at the time of starting the lamp is limited, and the height of the high voltage pulse can be adjusted. The bimetal switch 4 is closed when the lamp is not lit, and is attached to be opened by heat from the arc tube after the lamp is lit. Thereby, since the starter does not operate while the lamp is lit, generation of an extra high voltage pulse can be prevented.

  FIG. 2 is a circuit configuration diagram showing a second embodiment of the starter built-in type high-pressure discharge lamp of the present invention. In FIG. 2, reference numeral 9 denotes an envelope including an outer tube and a base, and an arc tube 1 having electrodes at both ends thereof is connected to and fixed to the electric lead wires a and b. . Further, a starter is connected in parallel with the arc tube 1 between the electric lead-ins a and b.

  The starter includes a third parallel body in which a negative characteristic thermistor 7 is connected in parallel with the switching element 8, a resistor 5 connected in series with the third parallel body, and a bimetal connected in series with the resistor 5. A switch 4 and a resistor 3 are connected in parallel to each other, and a second parallel body and a filament resistor 10 connected in series with the second parallel body. Here, the negative characteristic thermistor is an element whose resistance value decreases as the temperature rises. For example, a negative thermistor having a characteristic of about 10 KΩ at room temperature of 25 ° C. but about 55Ω at 250 ° C. can be used.

  In the starter, the resistor 3 connected in parallel with the bimetal switch 4 is for heating the bimetal switch 4 during lamp operation. Due to the action of the resistor 3, the arc tube is sufficiently cooled when the lamp is restarted, and the bimetal switch 4 is restored in a state where the lamp can be started, so that the lamp can be reliably restarted. Further, the resistor 5 is for adjusting the current flowing through the switching element 8. By this resistor 5, the current flowing through the switching element 8 at the time of starting the lamp is limited, and the height of the high voltage pulse can be adjusted. The bimetal switch 4 is closed when the lamp is not lit, and is attached to be opened by heat from the arc tube after the lamp is lit.

  FIG. 3 is a circuit configuration diagram showing a third embodiment of the high-pressure discharge lamp with a built-in starter of the present invention. In FIG. 3, reference numeral 9 denotes an envelope including an outer tube and a base, and an arc tube 1 having electrodes at both ends thereof is connected to and fixed to the electric lead-ins a and b. . Further, a starter is connected in parallel with the arc tube 1 between the electric lead-ins a and b.

  The starter includes a first parallel body in which a series body of a negative characteristic thermistor 7 and a resistor 6 is connected in parallel with the switching element 8, a resistor 5 connected in series with the first parallel body, and the resistance 5 comprises a second parallel body formed by connecting a bimetal switch 4 connected in series with a resistor 5 and a resistor 3 in parallel, and a filament resistor 10 connected in series with the second parallel body. Here, the negative characteristic thermistor is an element whose resistance value decreases as the temperature rises. For example, a negative thermistor having a characteristic of about 10 KΩ at room temperature of 25 ° C. but about 55Ω at 250 ° C. can be used.

  In the starter, the resistor 6 is for adjusting the current flowing in the negative characteristic thermistor 7. The resistance 6 controls the amount of current flowing through the negative characteristic thermistor 7 and adjusts the time until the resistance value of the negative characteristic thermistor 7 decreases due to self-heating. As a result, the lamp can be reliably started even when it takes several seconds or more to light the lamp.

  In the starter, the resistor 3 connected in parallel with the bimetal switch 4 is for heating the bimetal switch 4 during lamp operation. By the action of the resistor 3, the arc tube is sufficiently cooled when the lamp is restarted, and the bimetal switch 4 is restored in a state where it can be started, so that the lamp can be reliably restarted. Further, the resistor 5 is for adjusting the current flowing through the switching element 8. The resistor 5 limits the current flowing through the switching element 8 at the time of starting the lamp and can adjust the height of the high voltage pulse. The bimetal switch 4 is closed when the lamp is not lit, and is attached to be opened by heat from the arc tube after the lamp is lit.

  In each of the first, second, and third embodiments, a glow tube, a non-linear ceramic capacitor, a bimetal switch, a semiconductor switch, or the like can be used as the switching element. Moreover, you may arrange | position some components which comprise a starter in a nozzle | cap | die. Furthermore, in order to improve the startability of the arc tube, a start auxiliary conductor may be provided in the vicinity of the arc tube. In the starter, the filament resistor 10 is for preventing an overcurrent load on the ballast that may occur when the arc tube has a slow leak. The operating principle of the filament resistor 10 for preventing overcurrent load on the ballast is described in detail in Japanese Patent Application Laid-Open No. 55-124941. The filament resistor 10 is not necessarily used. Furthermore, although heat loss from the arc tube is suppressed by evacuating the outer tube, an inert gas such as nitrogen gas or argon gas can be enclosed.

Next, examples will be described. In the embodiment, since the glow tube is used as the switching element 8, the switching element 8 will be described as the glow tube 8 in the following description.

<Example 1>
An embodiment of a ceramic metal halide lamp having a lamp size of 360 W will be described.
In FIG. 1, an arc tube 1 is made of a translucent alumina tube, and mercury, a starting rare gas, and a metal halide are enclosed inside. An envelope 9 including an outer tube and a base (not shown) includes a first parallel body, a resistor 5, a bimetal switch 4, and a filament resistor 10 in parallel with the arc tube 1. Is connected to the starter. In the first parallel body, a series body of a resistor 6 and a negative characteristic thermistor 7 is connected in parallel with the glow tube 8. The inside of the outer tube is kept at a high vacuum. This lamp can be lit in combination with a choke ballast for high pressure mercury lamps.

  The bimetal switch 4 is attached so that it is closed when the lamp is not lit and opened when the lamp is lit. The resistor 5 is for controlling the current flowing through the glow tube 8 and has a resistance value of about 300Ω. The resistor 6 constituting the first parallel body is for controlling the current flowing in the negative characteristic thermistor 7 and has a resistance value of about 700Ω. The negative characteristic thermistor 7 has a characteristic that the resistance value decreases as the temperature rises. For example, the resistance value is about 10 KΩ at a room temperature of 25 ° C., but the resistance value decreases to about 55Ω at 250 ° C. Next, the operating principle of the starter will be described for the case where the lamp is normally lit and not lit when the lamp is lit in combination with a choke ballast for a 400 W high-pressure mercury lamp.

<When the lamp lights up normally>
When an AC voltage is applied to the cap terminals a and b via a ballast (not shown), the switching element 8 operates, and the value of the current flowing through the starter increases according to the switching of the switching element contacts. The decrease is repeated, resulting in a high voltage pulse across a choke ballast (not shown). The high voltage pulse generated by the ballast is applied between the electrodes at both ends of the arc tube via the current introduction lines a and b. When the power is turned on, the resistance value of the negative characteristic thermistor 7 is several tens of kΩ, and the lamp is lit by this high voltage pulse when the lamp is in a normal state. When the lamp is turned on, the bimetal switch 4 is opened by heat from the arc tube, the starter is disconnected from the power supply, and the generation of pulses is stopped.

  Next, Table 1 shows an example of experimental data. The lamp used in the experiment was a light emitting tube of a 360 W ceramic metal halide lamp which started after about 6000 hours and had a slightly worse startability. The lamp used in the experiment was the same as that of Example 1 and the conventional example, except that the configuration of the starter was different. A 200V choke ballast for a 400 W high pressure mercury lamp was used as a ballast for lighting the lamp.

  Table 1 shows the number of lamps whether or not the lamps are normally lit after the power is turned on. As can be seen from Table 1, in the lamp of Example 1, all of the 20 lamps tested turned on normally. On the other hand, in the conventional lamp configured with the starter shown in FIG. 4, the operation of the glow tube 8 was stopped by the time the lamp was turned on and nine of the 20 lamps tested were not turned on normally. . In other words, the lamp of Example 1 has a rate of astigmatism due to a malfunction of the starter of 0%, whereas the lamp of the conventional example has a rate of 45%.

  After the lamp is lit, the voltage applied to both ends of the starter becomes the voltage applied to both ends of the arc tube 1, that is, the lamp voltage, so that the voltage applied to the glow tube 8 is lowered and the operation stops. When the operation of the glow tube 8 is stopped, no high voltage pulse is generated. As described above, the lamp of Example 1 is a lamp that takes several seconds or more to start after lighting for about 6000 hours until the resistance value of the negative characteristic thermistor 7 decreases by adjusting the current flowing through the negative characteristic thermistor 7 with the resistor 6. The lamp can be started with certainty because the time is delayed.

<When the lamp does not light>
When the lamp is not lit, the voltage is continuously applied to the glow tube 8 through the ballast after the power is turned on. As a result, in the negative characteristic thermistor 7 connected in parallel to the glow tube 8, a current flows through the resistor 6 for current adjustment, and the resistance value decreases due to self-heating. When the resistance value of the negative characteristic thermistor 7 decreases, the voltage applied to the glow tube 8 decreases. After a certain time elapses after the power is turned on, the voltage necessary for maintaining the glow discharge is not applied to the glow tube 8, and the operation of the glow tube 8 stops. When the operation of the glow tube 8 is stopped, no high voltage pulse is generated.

  When the lamp is not lit, the bimetal switch 4 is kept closed. Therefore, the filament resistor 10, the current limiting resistor 5 to the glow tube 8, and the current adjusting resistor 6 to the negative characteristic thermistor 7 are used. The current continues to flow through the starter composed of the negative characteristic thermistor 7 and the glow tube 8. However, since a current flows through the resistor 5, the resistor 6, and the negative characteristic thermistor 7, the current value is regulated to a value of about 0.1A. Thereby, useless power consumption is suppressed.

  As described above, in the case of the high pressure discharge lamp with a built-in starter of Example 1, the high voltage pulse is automatically stopped within a certain time after the power is turned on when the lamp is not lit normally. When replacing the lamp, there is no risk of electric shock and the lamp is highly safe.

<Example 2>
An embodiment of a ceramic metal halide lamp having a lamp size of 360 W will be described. In FIG. 2, the arc tube 1 is made of a translucent alumina tube, and mercury, a starting rare gas, and a metal halide are enclosed inside. In an envelope 9 including an outer tube and a base (not shown), a second parallel body in which a bimetal switch 4 and a resistor 3 are connected in parallel with the arc tube 1, and a glow tube 8 A starter comprising a third parallel body in which the negative characteristic thermistor 7 is connected in parallel and a resistor 5 is connected. The inside of the outer tube is kept at a high vacuum. This lamp can be lit in combination with a choke ballast for high pressure mercury lamps.

  The bimetal switch 4 is attached so that it is closed when the lamp is not lit and opened when the lamp is lit. The resistor 3 is for heating the bimetal switch 4 and has a resistance value of about 10 KΩ. The resistor 5 is for controlling the current flowing through the glow tube 8 and has a resistance value of about 300Ω. The negative characteristic thermistor 7 has a characteristic that the resistance value decreases as the temperature rises. For example, the resistance value is about 10 KΩ at a room temperature of 25 ° C., but the resistance value decreases to about 55Ω at 250 ° C. Next, the operating principle of the starter will be described for the case where the lamp is normally lit and not lit when the lamp is lit in combination with a choke ballast for a 400 W high-pressure mercury lamp.

<When the lamp lights up normally>
When an AC voltage is applied to the cap terminals a and b via a ballast (not shown), the switching element 8 operates, and the value of the current flowing through the starter increases according to the switching of the switching element contacts. The decrease is repeated, resulting in a high voltage pulse across a choke ballast (not shown). The high voltage pulse generated by the ballast is applied between the electrodes at both ends of the arc tube via the current introduction lines a and b. When the power is turned on, the resistance value of the negative characteristic thermistor 7 is several tens of kΩ, and the lamp is lit by this high voltage pulse when the lamp is in a normal state.

  When the lamp is lit, the bimetal switch 4 is opened by heat from the arc tube, and current continues to flow to the starter via the resistor 3. However, the resistor 3 limits the current flowing through the starter to a very small value of about 20 mA. Therefore, the power consumed by the starter while the lamp is lit is 2 to 3 W, which hardly affects the efficiency. After the lamp is lit, the voltage applied between the electrodes at both ends of the lamp, that is, the lamp voltage is applied to the starter, so that the glow tube 8 no longer operates and the high voltage pulse stops.

  While the lamp is on, the bimetal switch 4 receives radiant heat from both the arc tube 1 and the resistor 3 that have become hot. Therefore, the cooling rate of the bimetal switch 4 when the lamp is turned off is slower than that of a conventional lamp that does not have the resistor 3. When the lamp is turned off and then turned on, that is, in the conventional lamp having no resistor 3 at the time of restarting the lamp, the starter operates when the temperature of the bimetal switch 4 is lowered and the contact is closed. There is a possibility that the temperature is not sufficiently lowered. If the temperature of the arc tube is not sufficiently lowered, the starting voltage of the arc tube is high and the lamp does not restart reliably.

  Since the voltage remains applied to the starter unless the lamp is restarted, the temperature of the negative temperature coefficient thermistor increases due to self-heating, and the resistance value decreases. When the resistance value of the negative characteristic thermistor decreases, the voltage drop at that portion decreases, and the voltage applied to the glow tube 8 also decreases. When the voltage applied to the glow tube 8 decreases, the glow tube 8 stops operating and the generation of high voltage pulses stops. When the high voltage pulse stops, the lamp will not turn on.

  On the other hand, in the lamp of Example 2 of the present invention, the cooling rate of the bimetal switch 4 when the lamp is turned off is slow as described above, so when the temperature of the bimetal switch 4 falls and the contact is closed, the arc tube Since the temperature is sufficiently low and the starting voltage is low, the lamp can be reliably restarted.

  Next, Table 2 shows an example of experimental data. The lamp used in the experiment was an arc tube taken out from the lamp that was lit for about 6000 hours. That is, the lamp used in the experiment was the same as that of Example 2 and the conventional example, except that the configuration of the starter was different, and the same arc tube was used. A 200V choke ballast for a 400 W high pressure mercury lamp was used as a ballast for lighting the lamp. Table 2 shows the number of lamps indicating whether or not the lamp is restarted after the power is turned off and the lamp is turned off immediately after the lamp is stably lit.

  In Table 2, the lamps of Example 2 indicate that all the 20 test lamps were successfully restarted. On the other hand, in the conventional lamp that does not include the resistor 3, four of the twenty test pieces did not restart. That is, the lamp of Example 2 has a rate of astigmatism at the time of restart due to a malfunction of the starter of 0%, whereas that of the conventional lamp is 20%. As described above, the built-in starter-type high-pressure discharge lamp of Example 2 can reliably restart the lamp.

<If the lamp does not light up normally>
When the lamp does not light normally, the voltage is continuously applied to the glow tube 8 through the ballast after the power is turned on. As a result, a current flows through the negative characteristic thermistor 7 connected in parallel to the glow tube 8, and the resistance value of the negative characteristic thermistor 7 decreases due to self-heating. When the resistance value of the negative characteristic thermistor decreases, the voltage applied to the glow tube 8 also decreases. After a certain time elapses after the power is turned on, the voltage necessary for maintaining the glow discharge is not applied to the glow tube 8, and the operation of the glow tube 8 stops. When the operation of the glow tube 8 is stopped, no high voltage pulse is generated.

  When the lamp does not light up normally, the bimetal switch 4 is kept closed, and therefore comprises a filament resistor 10, a current limiting resistor 5 to the glow tube 8, a negative characteristic thermistor 7, and a glow tube 8. Current continues to flow to the starter. However, since a current flows through the resistor 5 and the negative characteristic thermistor 7, the current value is regulated to a value of about 0.3A to 0.4A. Thereby, useless power consumption is suppressed.

  As described above, in the case of the high pressure discharge lamp with a built-in starter of Example 2, the high voltage pulse is automatically stopped within a certain time after the power is turned on when the lamp is not lit normally. When replacing the lamp, there is no risk of electric shock and the lamp is highly safe.

<Example 3>
An embodiment of a ceramic metal halide lamp having a lamp size of 360 W will be described. In FIG. 3, the arc tube 1 is made of a translucent alumina tube, and mercury, a starting rare gas, and a metal halide are enclosed inside. In an envelope 9 including an outer tube and a base (not shown), a first parallel body and a resistor in which a series body of a negative characteristic thermistor 7 and a resistor 6 is connected in parallel with the switching element 8. 5, a starter comprising a second parallel body in which a bimetal switch 4 and a resistor 3 are connected in parallel and a filament resistor 10 is connected. The inside of the outer tube is kept at a high vacuum. This lamp can be lit in combination with a choke ballast for high pressure mercury lamps.

  The bimetal switch 4 is attached so that it is closed when the lamp is not lit and opened when the lamp is lit. The resistor 3 is for heating the bimetal switch 4 and has a resistance value of about 10 KΩ. The resistor 5 is for controlling the current flowing through the glow tube 8 and has a resistance value of about 300Ω. The resistor 6 is for controlling the current flowing in the negative characteristic thermistor 7 and has a resistance value of about 700Ω. The negative characteristic thermistor 7 has a characteristic that the resistance value decreases as the temperature rises. For example, the resistance value is about 10 KΩ at a room temperature of 25 ° C., but the resistance value decreases to about 55Ω at 250 ° C. Next, the operating principle of the starter will be described for the case where the lamp is normally lit and not lit when the lamp is lit in combination with a choke ballast for a 400 W high-pressure mercury lamp.

<When the lamp lights up normally>
When an AC voltage is applied to the cap terminals a and b via a ballast (not shown), the switching element 8 operates, and the value of the current flowing through the starter increases according to the switching of the switching element contacts. The decrease is repeated, resulting in a high voltage pulse across a choke ballast (not shown). The high voltage pulse generated by the ballast is applied between the electrodes at both ends of the arc tube via the current introduction lines a and b. When the power is turned on, the resistance value of the negative characteristic thermistor 7 is several tens of kΩ, and the lamp is lit by this high voltage pulse when the lamp is in a normal state.

  When the lamp is lit, the bimetal switch 4 is opened by heat from the arc tube, and current continues to flow to the starter via the resistor 3. However, the resistor 3 limits the current flowing through the starter to a very small value of about 20 mA. Therefore, the power consumed by the starter while the lamp is lit is 2 to 3 W, which hardly affects the efficiency. After the lamp is lit, the voltage applied to both ends of the starter becomes the voltage applied to both ends of the arc tube 1, that is, the lamp voltage, so that the voltage applied to the glow tube is lowered and the operation is stopped. When the operation of the glow tube 8 is stopped, no high voltage pulse is generated.

  The lamp of Example 3 is lit for about 6000 hours, and even in a lamp that takes several seconds or more to start, the current flowing through the negative characteristic thermistor 7 is adjusted by the current adjusting resistor 6 to reduce the resistance value of the negative characteristic thermistor 7. Since the time until is delayed, the lamp can be started reliably. Further, in the lamp of Example 3, the cooling rate of the bimetal switch 4 when the lamp is extinguished is slow as described above. Therefore, when the temperature of the bimetal switch 4 decreases and the contact is closed when the lamp is restarted, the temperature of the arc tube Since the starting voltage is sufficiently low, the lamp can be reliably restarted.

  Next, examples of experimental data are shown in Tables 3 and 4. The lamp used in the experiment was an arc tube removed from the lamp that was lit for about 6000 hours. The lamp of Example 3 and the lamp of the conventional example differ from each other only in the configuration of the starter, and the same arc tube is used. This arc tube has a slightly worse startability because it takes 1 to 4 seconds to start after lighting for about 6000 hours. A 200V choke ballast for a 400 W high pressure mercury lamp was used as a ballast for lighting the lamp.

  Table 3 shows the number of lamps whether or not the lamps are normally lit after the power is turned on. As can be seen from Table 3, in the lamp of Example 3, all of the 20 lamps tested turned on normally. On the other hand, in the conventional lamp composed of the starter shown in FIG. 4, nine of the 20 lamps tested stopped the glow tube operation until the lamp was turned on, and did not light normally.

  Next, using the same lamp, the power was turned off from the state in which the lamp was stably lit, the lamp was turned off, the power was turned on immediately, and a restart test was performed to see if the lamp restarted. Table 4 shows the results of the restart test.

  In Table 4, the lamps of Example 3 indicate that all of the 20 test lamps were successfully restarted. On the other hand, in the conventional lamp not provided with the resistor 3, four of the twenty test pieces did not restart. In other words, the lamp of Example 3 has a rate of astigmatism at the time of restart due to a malfunction of the starter of 0%, whereas that of the conventional lamp is 20%.

  As described above, the high pressure discharge lamp with a built-in starter according to the third embodiment can reliably start the lamp and reliably restart the lamp even in a lamp that requires several seconds or more for starting. That is, both malfunction 1 and malfunction 2 due to the above-described starter can be prevented.

<When the lamp does not light>
When the lamp is not lit, the voltage is continuously applied to the glow tube 8 through the ballast after the power is turned on. As a result, in the negative characteristic thermistor 7 connected in parallel to the glow tube 8, a current flows through the resistor 6 for current adjustment, and the resistance value decreases due to self-heating. When the resistance value of the negative characteristic thermistor 7 decreases, the voltage applied to the glow tube 8 also decreases. After a certain time elapses after the power is turned on, the voltage necessary for maintaining the glow discharge is not applied to the glow tube 8, and the operation of the glow tube 8 stops. When the operation of the glow tube 8 is stopped, no high voltage pulse is generated.

  When the lamp is not lit, the bimetal switch 4 is kept closed. Therefore, the filament resistor 10, the current limiting resistor 5 to the glow tube 8, and the current adjusting resistor 6 to the negative characteristic thermistor 7 are used. The current continues to flow through the starter composed of the negative characteristic thermistor 7 and the glow tube 8. However, since a current flows through the resistor 5, the resistor 6, and the negative characteristic thermistor 7, the current value is regulated to a value of about 0.1A. Thereby, useless power consumption is suppressed.

  As described above, in the case of the high pressure discharge lamp with a built-in starter of Example 3, when the lamp does not light, the high voltage pulse automatically stops within a certain time after the power is turned on. When replacing the lamp, there is no risk of electric shock and the lamp is highly safe.

1 is a circuit configuration diagram showing a starter built-in type high-pressure discharge lamp according to a first embodiment of the present invention; It is a circuit block diagram which shows the starter built-in type high pressure discharge lamp concerning the 2nd Embodiment of this invention. It is a circuit block diagram which shows the starter built-in type high pressure discharge lamp concerning the 3rd Embodiment of this invention. It is a circuit block diagram which shows an example of the conventional high pressure discharge lamp with a built-in starter.

Explanation of symbols

1 Arc tube 3 Resistance 4 Bimetal switch 5 Resistance 6 Resistance 7 Negative characteristic thermistor 8 Switching element 9 Envelope

Claims (3)

In a high-pressure discharge lamp with a built-in starter, a starter and an arc tube are housed in an envelope including an outer tube and a base, and the starter and the arc tube are connected in parallel. Is a high-pressure discharge lamp with a built-in starter, comprising a first parallel body in which a series body of a negative characteristic thermistor and a resistor is connected in parallel with the switching element. In a high-pressure discharge lamp with a built-in starter, a starter and an arc tube are housed in an envelope including an outer tube and a base, and the starter and the arc tube are connected in parallel. Comprises a second parallel body in which a bimetal switch and a resistor are connected in parallel, and a third parallel body in which a negative characteristic thermistor and a switching element are connected in parallel, and the second parallel body A starter built-in type high-pressure discharge lamp, wherein the third parallel body and the third parallel body are connected in series. In a high-pressure discharge lamp with a built-in starter, a starter and an arc tube are housed in an envelope including an outer tube and a base, and the starter and the arc tube are connected in parallel. Includes a first parallel body in which a series body of a negative characteristic thermistor and a resistor is connected in parallel to the switching element, and a second parallel body in which a bimetal switch and a resistor are connected in parallel. The parallel generator of 1 and the said 2nd parallel body are connected in series, The high pressure discharge lamp with a built-in starter characterized by the above-mentioned.

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