JP4058652B2 - Lighting device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an illumination device that lights a discharge lamp.
[0002]
[Prior art]
Japanese Patent Laid-Open No. 7-106088 discloses a technique for detecting the lamp lamp power by detecting the electrical characteristics when the discharge lamp is turned on in order to prevent erroneous mounting of the discharge lamp having different rated lamp voltages. ing.
[0003]
[Problems to be solved by the invention]
By the way, in recent years, the bases of different types of lamps have become common, and there is a possibility that different types of lamps may be erroneously mounted.
[0004]
However, in the above prior art, even if the difference in the rated lamp power of the same type of lamp can be detected, the type of the lamp is different although the difference in the rated lamp power is the same, such as a high pressure discharge lamp and an incandescent lamp. There is a problem that it cannot be handled when the differences are common.
[0005]
In the prior art, in order to detect that the mounted lamp is a compatible lamp in terms of the difference in lamp type and rated lamp power, the mounted lamp must be turned on. For this reason, for example, when a high pressure discharge lamp with a lower rated lamp power is turned on with a lighting device for the high pressure discharge lamp, there is a problem that the lamp becomes over input and there is a risk of explosion.
[0006]
An object of the present invention is to enable detection of whether or not the mounting lamp is a compatible lamp without lighting the mounting lamp.
[0007]
Another object of the present invention is to detect that the mounted lamp is a compatible lamp and automatically turn it on.
[0008]
Another object of the present invention is to automatically turn on a compatible lamp simply by mounting the compatible lamp.
[0009]
Another object of the present invention is to make it possible to make a determination including whether or not the compatible lamp is in a state where it can be turned on, for example, in the case of relighting after a short time after the light is turned off.
[0010]
Another object of the present invention is to detect a difference in rated lamp power and enable lighting driving according to the rated lamp power.
[0011]
Another object of the present invention is to make it possible to improve the accuracy of determination when determining whether or not the compatible lamp is in a state where it can be lit.
[0012]
Another object of the present invention is to prevent generation of useless start pulses.
[0013]
Another object of the present invention is to increase the safety during lamp mounting when the automatic lighting is performed only by mounting a compatible lamp.
[0014]
Another object of the present invention is to prevent an increase in power loss even if it is possible to detect whether or not the mounted lamp is a compatible lamp.
[0015]
Another object of the present invention is to provide a circuit for detecting whether or not the mounting lamp is a compatible lamp without lighting the mounting lamp, and a circuit for detecting an abnormality of the discharge lamp being lit. The purpose is to simplify the circuit configuration.
[0016]
Another object of the present invention is to prevent discharge from occurring in the gap formed between the base of the discharge lamp and the socket even when the discharge lamp is not completely mounted.
[0022]
[Means for Solving the Problems]
  Claim1The invention described inA discharge path is formed inside, and is electrically connected in parallel to the arc tube.Detection element having predetermined electrical characteristicsTogenamiDischarge lamps integrated in a row;A driving circuit for lighting and driving the discharge lamp by turning on and off the switching element; a bypass circuit for bypassing the switching element; and when the switching element is bypassed by the bypass circuit, the arc tube is not lit but the detection element By supplying current toA detection circuit for determining electrical characteristics of the detection element;A starting circuit for properly starting the discharge lamp by turning on the switching element based on a determination output indicating that the lamp is a compatible lamp; and stably lighting the discharge lamp by turning on the switching elementLighting circuit;It is characterized by having.
[0023]
Therefore, whether or not the mounting lamp is a compatible lamp can be determined based on whether or not the output of the detection circuit is within a predetermined range without lighting the mounting lamp.
[0024]
In addition, it is possible to automatically turn on the light by simply attaching a compatible lamp.
[0025]
Further, it is possible to perform lighting corresponding to the difference in rated lamp power of the same type of compatible lamp.
[0026]
In addition, using the fact that the electrical characteristics fluctuate depending on the temperature characteristics of the detection element, and appropriately setting the predetermined range of the output of the detection circuit, it is suitable for cases such as when the light is turned on again after a short time. It is possible to determine whether or not the mounted lamp, which is a lamp, is in a state that is not suitable for lighting.
[0027]
Note that the first determination circuit can be configured by, for example, a window comparator circuit.
[0028]
  Claim2The invention described inA discharge path is formed inside, and is electrically connected in parallel to the arc tube.Detection element having predetermined electrical characteristicsTogenamiDischarge lamps integrated in a row;A driving circuit for lighting and driving the discharge lamp by turning on and off the switching element; a bypass circuit for bypassing the switching element; and when the switching element is bypassed by the bypass circuit, the arc tube is not lit but the detection element By supplying current toA detection circuit for determining electrical characteristics of the detection element; and a first determination circuit for determining the discharge lamp as a compatible lamp when the output of the detection circuit is within a predetermined range;Based on the determination output that the detection circuit is a compatible lamp, the switching element is turned onDischarge lampStart properlyA starting circuit;By turning on the switching elementStable lighting of the discharge lampDoA lighting circuit; and a first control circuit that operates the starting circuit and the lighting circuit when the determination of the first determination circuit is a compatible lamp;It is characterized by having.
[0029]
Therefore, whether or not the mounting lamp is a compatible lamp can be determined based on whether or not the output of the detection circuit is within a predetermined range without lighting the mounting lamp.
[0030]
Further, since it is detected whether or not the mounting lamp is a compatible lamp, and the starting circuit and the lighting circuit are operated when the mounting lamp is a compatible lamp, it is possible to automatically turn on only by mounting the compatible lamp.
[0031]
Further, it is possible to perform lighting corresponding to the difference in rated lamp power of the same type of compatible lamp.
[0032]
In addition, using the fact that the electrical characteristics fluctuate depending on the temperature characteristics of the detection element, and appropriately setting the predetermined range of the output of the detection circuit, it is suitable for cases such as when the light is turned on again after a short time. It is possible to determine whether or not the mounted lamp, which is a lamp, is in a state that is not suitable for lighting.
[0033]
  Claim3The invention described inA discharge path is formed inside, and is electrically connected in parallel to the arc tube.Detection element having predetermined electrical characteristicsTogenamiDischarge lamps integrated in a row;A driving circuit for lighting and driving the discharge lamp by turning on and off the switching element; a bypass circuit for bypassing the switching element; and when the switching element is bypassed by the bypass circuit, the arc tube is not lit but the detection element By supplying current toA detection circuit for determining electrical characteristics of the detection element; and a first determination circuit for determining the discharge lamp as a compatible lamp when the output of the detection circuit is within a predetermined range;Based on the determination output that the detection circuit is a compatible lamp, the switching element is turned onDischarge lampStart properlyA starting circuit;By turning on the switching elementA lighting circuit that stably lights the discharge lamp; a first control circuit that operates the starting circuit and the lighting circuit when the determination of the first determination circuit is a compatible lamp; and based on an output of the detection circuit And a second control circuit for controlling outputs of the starting circuit and the lighting circuit.
[0034]
Therefore, whether or not the mounting lamp is a compatible lamp can be determined based on whether or not the output of the detection circuit is within a predetermined range without lighting the mounting lamp.
[0035]
Further, since it is detected whether or not the mounting lamp is a compatible lamp, and the starting circuit and the lighting circuit are operated when the mounting lamp is a compatible lamp, it is possible to automatically turn on only by mounting the compatible lamp.
[0036]
Further, it is possible to perform lighting corresponding to the difference in rated lamp power of the same type of compatible lamp.
[0037]
In addition, it is possible to determine whether or not the mounted lamp, which is a compatible lamp, is in a state that is not suitable for lighting, such as when the lamp is turned on again after a short time.
[0038]
Since the outputs of the starting circuit and the lighting circuit are controlled based on the output of the detection circuit, it is possible to determine the difference in the rated power of the same type of discharge lamp and to light it properly.
[0039]
  Claim4The invention described in 1 is characterized in that the first determination circuit includes a retaining means for retaining the discharge lamp during a preset period after the mounted lamp is determined to be a compatible lamp. is there.
[0040]
Therefore, since the discharge lamp is not turned on during the period, it is safe even if the lamp is automatically turned on immediately if a compatible lamp is attached.
[0041]
In order to reserve the lighting of the discharge lamp, the driving of the starting circuit may be reserved, or the power supply to the discharge lamp by the lighting circuit may be reserved.
[0042]
  Claim5In the first aspect of the invention, the first timer that counts a preset period after the first determination circuit determines that the mounted lamp is the compatible lamp, and the third control that stops the starting circuit during this period. And a circuit.
[0043]
Therefore, after determining that the mounting lamp is a conforming lamp, the preset period is counted, and during this period, the discharge lamp is turned on by stopping the starting circuit. It is safe even when automatically turned on.
[0044]
  Claim6The start circuit is configured to apply a start pulse to the discharge lamp; when the start circuit generates the start pulse, a second time is counted for the duration of the start pulse. A timer; and a fourth control circuit for stopping the starting circuit when the count time exceeds a preset time.
[0045]
Therefore, if it does not light even if a start pulse is given for a certain period of time due to a failure of the mounted lamp, etc., the start circuit is stopped and the base of the lamp is broken due to a useless start pulse or to other electrical or electronic equipment. Can prevent adverse effects.
[0047]
Accordingly, the detection circuit compares the detection output with the output value of the discharge lamp and the first numerical value range, and sends a signal to the first control circuit when it is within the first numerical value range. When the first control circuit is configured to drive the lighting circuit and the starting circuit when a predetermined signal is received and to stop when the predetermined signal is not received, The detection output is compared with the second numerical range, and when it is within the second numerical range, an abnormality of the discharge lamp that is lit is detected only by providing a circuit for outputting a signal to the first control circuit. be able to. That is, the first numerical value range may be set as a value when a compatible lamp is detected, and the second numerical value range may be set as a value when the discharge lamp is normally lit.
[0048]
Each of the first and second comparison circuits can be constituted by a window comparator circuit, for example.
[0049]
  Claim7The lighting circuit has a configuration in which the discharge lamp is dc-lit; and the lighting circuit is controlled so that a rest period for a time period in which the discharge lamp does not re-ignite to the lamp current of the discharge lamp is controlled. A sixth control circuit is provided.
[0050]
Therefore, there is a pause in the lamp current of the discharge lamp that is lit by direct current so that the discharge lamp does not re-ignite. As described above, it was confirmed that the discharge can be prevented from being generated in the gap between the lamp cap and the socket by making the rest period in the lamp current.
[0051]
It should be noted that the discharge that has occurred once is stopped if a pause interval is made once, but it is desirable to make this pause interval periodically because it can cope with a discharge phenomenon that does not occur when it occurs.
[0052]
  Claim8The discharge lamp is characterized in that the resistance or impedance of the detection element is larger than the equivalent resistance or impedance of the arc tube at the time of lighting.
[0053]
Therefore, power loss due to the detection element can be suppressed.
[0054]
  Claim9The invention described in 1 is characterized in that it is provided with a thermally responsive element such as a bimetal switch which is provided in the discharge lamp and operates by increasing the temperature of the discharge lamp to cut off the power to the detecting element. is there.
[0055]
Therefore, after the compatible lamp is turned on, when the lamp temperature has risen to some extent, the detection element can be de-energized to prevent power loss.
[0056]
  Claim 10In the invention described in item 1, the detection element has a resistance temperature coefficient of 500 ppm / ° C. or more.
[0057]
Therefore, even when detection is performed using the temperature characteristics of the detection element, a relatively large resistance with a temperature coefficient of resistance of 500 ppm / ° C. or higher is used as the detection element, so that electrical characteristics such as resistance or impedance corresponding to temperature fluctuations are used. The fluctuation of the value can be increased, and the detection accuracy can be improved.
[0058]
DETAILED DESCRIPTION OF THE INVENTION
First Embodiment of the Invention
FIG. 1 is a circuit diagram of an illuminating device 1 showing a first embodiment of the present invention, which is for a direct current.
[0059]
As shown in FIG. 1, in the lighting device 1, a lighting circuit 3, an igniter circuit 4, a lamp mounting detection circuit 5, and a high-pressure discharge lamp 6 are sequentially connected to a power supply line of a DC power supply 2.
[0060]
The lighting circuit 3 includes a drive circuit 11 that drives and drives the high-pressure discharge lamp 6 and a control circuit 12 that controls the drive circuit 11.
[0061]
The drive circuit 11 includes a switching element 13, a transformer 14 having a secondary winding connected to the base side of the switching element 13, a choke coil 15, a freewheeling diode 16, and the like. When the square wave is input, the switching element 13 is turned on and off to drive the high-pressure discharge lamp 6 to light.
[0062]
The control circuit 12 includes switching elements 21 and 22 that turn on and off the power supply to the primary winding of the transformer 14, a comparator 23 whose output side is connected to the gate side of the switching elements 21 and 22, and the comparison The comparator 23 is composed of an oscillator 24 whose output side is connected to the inverting input terminal of the comparator 23, and the triangular wave pulse output from the oscillator 24 is compared with a constant reference voltage by the comparator 23, and an output corresponding thereto is output from the comparator 23. Thus, an output corresponding to the duty ratio of the square wave applied to the transformer 14 is supplied from the drive circuit 11 to the high pressure discharge lamp 6.
[0063]
The igniter circuit 4 includes a charging capacitor 31 and a pulse transformer 32 connected between the power supply lines, one of which is connected to the negative side of the power supply line and the other of which is connected to the primary winding of the pulse transformer 32 and the anode side thereof. From a thyristor 34 connected to the primary winding of the pulse transformer 32 and having the cathode side connected to the negative side of the power supply line, a trigger element 35 connected to the charging side of the charging capacitor 31 and the gate side of the thyristor 34, and the like. Become. When electric energy of a certain level or more is accumulated in the charging capacitor 31, the trigger element 35 triggers the thyristor 34, and the operation that the charging current of the charging capacitor 33 flows through the primary winding of the pulse transformer 32 is repeated. A starting pulse is applied from the secondary winding of the pulse transformer 32 to the high-pressure discharge lamp 6.
[0064]
The high-pressure discharge lamp 6 is, for example, a metal halide lamp, and an arc tube 41 and a detection element 42 are connected in parallel. More specifically, as shown in FIG. 2, the detection element 42 is connected between the wires 45 and 46 that supply power to the arc tube 41 inside the high-pressure discharge lamp 6. In this example, the detection element 42 is a resistance for detecting a partial pressure. The detection element 42 has a temperature coefficient of resistance of 500 ppm / ° C. or higher. The resistance value of the detection element 42 is larger than the equivalent resistance value when the arc tube 41 is turned on.
[0065]
The lamp mounting detection circuit 5 uses a window comparator including comparators 51 and 52, and the non-inverting input terminal of the comparator 51 and the inverting input terminal of the comparator 52 are power supply lines to the high-pressure discharge lamp 6. It is connected to the positive side and is compared with the reference voltages respectively input to the inverting input terminal of the comparator 51 and the non-inverting input terminal of the comparator 52. The output terminal of the comparator 51 and the output terminal of the comparator 52 are connected to each other, and the combined output voltage of both comparators is input to the oscillator 24.
[0066]
In this example, the detection element 53 is a resistor for detecting a divided voltage, and is connected in series with the switch 54 between the emitter and the collector of the switching element 13, and bypasses the switching element 13 and allows a current to flow through the power supply line. be able to.
[0067]
Next, the operation of the lighting device 1 will be described.
[0068]
When the switch 54 is closed, a current flows through the high-pressure discharge lamp 6 bypassing the switching element 13. At this time, since neither the igniter circuit 4 nor the lighting circuit 3 is operating, the arc tube 41 is not lit, and a direct current flows through the detection elements 53 and 42 connected in series. As a result, a partial pressure corresponding to the magnitude of the resistance value of the high-pressure discharge lamp 6, that is, the detection element 42 is applied to the comparators 51 and 52. In the comparators 51 and 52, both the comparators 51 and 52 output a positive voltage only when the divided voltage is in a certain numerical value range according to the reference voltage input to each of the comparators.
[0069]
That is, when the resistance value of the high-pressure discharge lamp 6, that is, the resistance value of the detection element 42 falls within a certain numerical range, the mounted lamp of the lighting device 1 is determined as the compatible lamp of the lighting device 1, and the comparator at that time The combined voltage of the plus voltage output from both 51 and 52 can be used as the drive start signal of the lighting device 1.
[0070]
More specifically, when the lighting device 1 uses a 250 watt metal halide lamp as a compatible lamp, the resistance value of the 250 watt metal halide lamp is within the predetermined numerical range. When the detection element 42 is connected, such a metal halide lamp outputs the drive start signal as a compatible lamp. Conversely, if the mounting lamp of the lighting device 1 is a metal halide lamp with other rated lamp power (70 watts, 150 watts, etc.) or another type of lamp, such as an incandescent lamp, the resistance of the mounting lamp. Since the values are different (there is a filament in the incandescent bulb, the current flows, but the resistance value of the filament is small), so that erroneous mounting of the mounting lamp can be detected without turning on the mounting lamp.
[0071]
Further, by detecting whether or not the resistance value of the detection element 42 falls within the certain numerical value range, it is possible to determine whether or not the mounted lamp after being turned off is in a state where it can be turned on again. In other words, the resistance value of the detection element 42 increases as the temperature increases, and there is a possibility that the sensor element 42 cannot be relighted even when a start pulse is applied. Therefore, when a resistance value exceeding the certain numerical range is detected, it is determined that the lamp temperature is high for re-lighting, and the igniter circuit 4 is stopped until the lamp temperature is lowered to a re-lightable temperature. It is possible not to give a useless start pulse.
[0072]
In this case, as shown in FIG. 3, the upper limit value of the certain value range of the resistance value is set to a value b or less that is considered to be the upper limit value at which the high pressure discharge lamp 6 can be lit, and the resistance at normal temperature (about 25 ° C.) It is desirable to set the value a or more.
[0073]
Further, since the temperature coefficient of resistance is 500 ppm / ° C. or more, it is preferable that the slope of the resistance value with respect to the lamp temperature change can be sufficiently increased.
[0074]
As described above, when the mounting lamp is determined by the compatible lamp of the lighting device 1 and the lamp mounting detection circuit 5, and the drive start signal of the lighting device 1 is output to the oscillator 24 of the control circuit 12, as described above, The control circuit 12 drives the drive circuit 11, whereby the igniter circuit 4 is also driven to give a start pulse to the high-pressure discharge lamp 6 that is a compatible lamp, and the high-pressure discharge lamp 6 is lit.
[0075]
In addition, since the resistance value of the detection element 42 is set to be larger than the equivalent resistance value when the arc tube 41 is turned on, the power loss caused by energizing the detection element 42 can be made relatively small.
[0076]
Further, as described above, since the detection element 42 is connected to the wires 45 and 46, the connection of the detection element 42 also contributes to an improvement in the mounting strength of the arc tube 41.
[0077]
[Second Embodiment of the Invention]
FIG. 4 is a circuit diagram of a lighting device 60 showing a second embodiment of the present invention, which is for AC use.
[0078]
In the figure, circuit elements having the same reference numerals as those in FIGS. 1 and 2 are the same as those in the first embodiment of the present invention, and detailed description thereof will be omitted.
[0079]
As shown in FIG. 4, the lighting device 60 includes a lighting circuit 63 including a DC-DC converter 61 and an inverter circuit 62.
[0080]
The DC-DC converter 61 includes a switching element 64, a choke coil 65, a freewheeling diode 66, and the like, and a signal voltage is applied from the control circuit 75 to the gate of the switching element 64.
[0081]
The inverter circuit 62 is a full bridge circuit of four switching elements 71, 72, 73, 74, and the high pressure discharge lamp 6 is AC driven by turning on / off the switching elements 71, 72, 73, 74.
[0082]
The control circuit 75 outputs signals having different duty ratios to drive the switching element 64 on and off.
[0083]
The lighting device 60 includes a plurality of lamp mounting detection circuits 5, in this example, three stages. In each lamp mounting detection circuit 5, various reference voltages for the comparators 51 and 52 are set.
[0084]
Next, the operation of the lighting device 60 will be described.
[0085]
The lighting device 60 includes a plurality of lamp mounting detection circuits 5, in this example, three stages. In each lamp mounting detection circuit 5, the reference voltages of the comparators 51 and 52 are set variously. The partial pressure corresponding to the magnitude of the resistance value of the high-pressure discharge lamp 6 that can be detected by the mounting detection circuit 5, that is, the detection element 42 can be set to different constant numerical ranges.
[0086]
If each different fixed numerical range corresponds to a plurality of types of rated lamp power (for example, 70 watts, 150 watts, 250 watts) of the high-pressure discharge lamp 6, a signal from any lamp mounting detection circuit 5 is output. Depending on whether or not any lamp mounting detection circuit 5 outputs a signal, it is determined whether the lamp type is not a compatible lamp, or whether the lamp type is a compatible lamp and its rated lamp power. Can do.
[0087]
When no signal is input from any of the lamp mounting detection circuits 5 to the control circuit 75, the switching element 64 is not turned on / off, and the lighting circuit 63 is not driven. Do not light up (such as an incandescent bulb).
[0088]
When a signal is input from one of the lamp mounting detection circuits 5 to the control circuit 75, the ratio of the on-time of the switching element 64 is changed depending on which of the lamp mounting detection circuits 5 to which the signal is input. The type determines the rated lamp power of the mounted lamp, which is a compatible lamp, and an output corresponding to the rated lamp power is output from the DC-DC converter 61.
[0089]
[Third Embodiment of the Invention]
FIG. 5 is a circuit diagram of an illuminating device 80 showing a third embodiment of the present invention. In FIG. 5, circuit elements having the same reference numerals as those in FIGS. 1 and 2 are the same as those in the first embodiment of the present invention. The detailed description is omitted.
[0090]
The illumination device 80 is obtained by adding a pulse stop circuit 81 to the illumination device 1.
[0091]
The pulse stop circuit 81 includes a switching element 82 having an emitter and a collector connected to both sides of the charging capacitor 31, a timer 83 connected to the gate side of the switching element 82 to turn on and off the switching element 82, A DC power source 84 that is a power source of the timer 83 is configured. The DC power supply 84 is driven by supplying power to the timer 83 when the igniter circuit 4 operates.
[0092]
Next, the operation of the lighting device 80 will be described.
[0093]
When the switch 54 is closed, as in the first embodiment, it is determined whether or not the mounted lamp is a compatible lamp. If it is determined that the mounted lamp is a compatible lamp, the igniter circuit 4 generates a start pulse, Look at starting the mounted lamp.
[0094]
The timer 83 starts driving and starts counting for a predetermined time. When this fixed time has elapsed, a voltage is output from the timer 83 to the gate side of the switching element 82, and the switching element 82 is turned on, thereby short-circuiting between the charging capacitors 31 and preventing charging of the charging capacitor 31. The igniter circuit 4 stops operating thereafter.
[0095]
When the high pressure discharge lamp 6 is turned off and then turned on again when the high pressure discharge lamp 6 is not sufficiently cooled, the lamp mounting detection circuit 5 adapts the mounted lamp for a while due to the temperature characteristics of the detecting element 42. May not be determined. When the mounting lamp is sufficiently cooled and the lamp mounting detection circuit 5 determines that the mounting lamp is a compatible lamp, generation of the start pulse by the igniter circuit 4 starts as described above. In conjunction with the start of the igniter circuit 4, the timer 83 is energized, and the timer 83 starts counting for a certain time. Even if the high-pressure discharge lamp 6 is pulled out or breaks down during this time, the igniter circuit 4 is stopped after trying to start the lamp for a fixed time counted by the timer 83. There will be no dielectric breakdown in the base of this product and no adverse effects on other electrical and electronic equipment.
[0096]
[Fourth Embodiment of the Invention]
FIG. 6 is a circuit diagram of an illuminating device 90 showing a fourth embodiment of the present invention, in which circuit elements having the same reference numerals as those in FIGS. 1 and 2 are the same as those in the first embodiment of the present invention. The detailed description is omitted.
[0097]
The lighting device 90 includes a lighting circuit 93 including a DC-DC converter 91 and a drive circuit 92. The DC-DC converter 91 includes a switching element 94, a choke coil 95, a return diode 96, a smoothing capacitor 97, and the like.
[0098]
The drive circuit 92 is connected to the gate of the switching element 94 and turns on and off the switching element 94 at a constant on-time ratio.
[0099]
The detection element 53 is connected to the negative output line of the DC-DC converter 91, and the switch 54 is connected to bypass the switching element 94 without passing through the detection element 53.
[0100]
The lamp lighting detection circuit 101 is connected in parallel with the mounting lamp, and detects whether or not the mounting lamp is lit based on a variation in partial pressure of the mounting lamp.
[0101]
  Timer105As in the case of the third embodiment, a certain time starts counting, and when the lamp lighting detection circuit 101 detects the lighting of the matching lamp, the matching lamp is not turned on until the counting time elapses. If a signal is received, a signal is output to the control circuit 103. The control circuit 103 receives this signal and outputs a drive stop signal to the drive circuit 92 and the igniter circuit 4.
[0102]
When the lamp mounting detection circuit 5 determines that the mounting lamp is a compatible lamp, the lamp 104 starts counting for a predetermined time by the timer 104. When this count ends, the control circuit 103 sends a signal to the drive circuit 92, and the drive circuit 92 drives the DC-DC converter 91.
[0103]
  In the high-pressure discharge lamp 6, the thermally responsive element 10 such as a bimetal switch that cuts off the power to the detecting element 42 due to a rise in temperature.2Is connected. This thermally responsive element 102Is disposed in the vicinity of the arc tube 41 as shown in FIG. 7 so that the heat of the arc tube 41 can be sufficiently sensed.
[0104]
Next, the operation of the lighting device 90 will be described.
[0105]
When the high pressure discharge lamp 6 which is a compatible lamp is mounted with the switch 54 closed and the lighting device 90 having no mounted lamp, the lamp mounting detection circuit 5 is replaced with the compatible lamp by the partial pressure of the detection element 42. The control circuit 103 outputs a control signal so that the lighting circuit 93 is driven, and the igniter circuit 4 is driven to light the high-pressure discharge lamp 6. Therefore, it is possible to automatically turn on the lamp simply by mounting the compatible lamp.
[0106]
In this case, the lamp mounting detection circuit 5 detects the compatible lamp and does not immediately turn on the lamp, but waits until the set time of the timer 104 has passed. You can wait to improve safety.
[0107]
Further, when the igniter circuit 4 is operated and the timer 105 starts counting, the lamp lighting detection circuit 101 detects the lighting of the compatible lamp, and when the compatible lamp is not lit until the count time elapses, A signal is output to the control circuit 103 and a drive stop signal is output to the igniter circuit 4. Therefore, even when the lamp cannot be lit due to a failure of a compatible lamp, the useless start pulse is prevented from being output, so that the breakdown of the cap of the mounted lamp does not occur and other electrical and electronic devices are not adversely affected.
[0108]
When the lamp is not lit within the count time by the timer 105 and the mounted lamp is subsequently replaced, the lamp mounting detection circuit 5 determines again whether or not the replacement lamp is a compatible lamp. After the waiting time according to 104, the control circuit 103 outputs a signal to the drive circuit 92, and automatic lighting is performed in the same manner as described above.
[0109]
Further, when a time passes after the compatible lamp 6 is turned on and the lamp temperature rises, the heat-responsive element 106 cuts off the power to the detection element 42, so that power loss due to the detection element 42 is prevented.
[0110]
[Fifth Embodiment of the Invention]
FIG. 8 is a circuit diagram of an illuminating device 110 showing a fifth embodiment of the present invention, which is for a direct current. In the figure, circuit elements having the same reference numerals as those in FIGS. 1, 2, and 6 are the same as those in the first and fourth embodiments of the present invention, and detailed description thereof is omitted.
[0111]
The illumination device 110 includes a lamp state detection circuit 111 as shown in FIG. The lamp state detection circuit 111 is a window comparator circuit including comparators 112 and 113, and determines whether or not the lamp voltage of the high-pressure discharge lamp 6 is within a predetermined numerical range. This predetermined numerical range is a numerical range of the magnitude of the lamp voltage when the high-pressure discharge lamp 6 is normally lit, and the reference voltages of the comparators 51 and 52 are set so as to be such a numerical range. ing. The output of the lamp state detection circuit 111 is input to the oscillator 24 similarly to the lamp mounting detection circuit 5. The voltage detection circuit 114 outputs a voltage proportional to the partial pressure of the high-pressure discharge lamp 6 to the lamp mounting detection circuit 5 and the lamp state detection circuit 111.
[0112]
With the above circuit configuration, when the lamp voltage of the high-pressure discharge lamp 6 is within a predetermined numerical range after detecting the compatible lamp by the lamp mounting detection circuit 5, the lighting circuit 93 is operated as it is. Thus, the high pressure discharge lamp 6 is kept on. However, the high pressure discharge lamp 6 does not light up even though the igniter circuit 4 is applying the start pulse, or when the high voltage discharge lamp 6 leaks and the lamp voltage is extremely lowered or increased, the high pressure discharge lamp When the magnitude of the lamp voltage 6 deviates from the predetermined numerical range and the high-pressure discharge lamp 6 is found not to be normally lit, the oscillator 24 can be turned off and the lighting device 110 can be stopped.
[0113]
With such a circuit configuration, a conventionally known circuit that detects the lamp voltage and stops the lighting of the high-pressure discharge lamp 6 when the lighting of the high-pressure discharge lamp 6 is abnormal is compatible with the mounted lamp. When detecting whether or not the lamp is a compatible lamp and using a circuit that automatically turns on when the lamp is a compatible lamp, the control circuit 12 and the voltage detection circuit 114 can be shared in both circuits. It can be simple.
[0114]
[Sixth Embodiment of the Invention]
FIG. 9 is a circuit diagram of an illuminating device 120 showing a sixth embodiment of the present invention, which is for a direct current. In the figure, circuit elements having the same reference numerals as those in FIG. 5 are the same as those in the third embodiment of the present invention, and detailed description thereof is omitted.
[0115]
The illuminating device 120 is the illuminating device 80 according to the third embodiment of the invention shown in FIG. 5, and is provided with a pulse generating circuit 121 instead of the pulse stop circuit 81. The pulse generation circuit 121 is an RC circuit composed of a resistor 122 and a charging capacitor 123. The timer circuit 124 to which the output signal of the lamp mounting detection circuit 5 is input and the charging side of the charging capacitor 123 of the timer circuit 124 are based on And a switching element 125 having an emitter and a collector connected to both sides of the charging capacitor 31.
[0116]
That is, the lighting device 120 is provided with a timer circuit 124 instead of the timer 83 in the lighting device 80 (the switching element 125 corresponds to the switching element 82), and the lamp mounting detection circuit 5 detects the mounting of the compatible lamp. After that, a predetermined time delay determined by the RC time constant of the timer circuit 124 is created until the switching element 125 is turned on.
[0117]
By the way, when the high-pressure discharge lamp 6 is mounted, even after the base comes into contact with the terminal in the socket, it cannot be completely mounted unless the base is further inserted into the socket. Nevertheless, when the cap contacts the terminal in the socket, the lamp mounting detection circuit 5 detects the compatible lamp and automatically lights up. There is a possibility of leaving the state incomplete. Based on this, when the base is loosened and the high-pressure discharge lamp 6 is DC-driven, there is a possibility that discharge occurs between the socket and the base. In addition, an operator may receive an unpleasant electric shock during the lamp mounting operation.
[0118]
On the other hand, in the lighting device 120, even when the compatible lamp is detected by the lamp mounting detection circuit 5, lighting of the high-pressure discharge lamp 6, that is, application of the start pulse is not started immediately, and the timer circuit 124 Since the operation start time of the igniter circuit 4 is delayed, the lamp can be automatically turned on only after the mounting operation of the high-pressure discharge lamp 6 is completed, and the above problem can be solved.
[0119]
[Seventh Embodiment of the Invention]
FIG. 10 is a circuit diagram of a lighting device 130 showing a seventh embodiment of the present invention, which is for a direct current. In the figure, circuit elements having the same reference numerals as those in FIG. 8 are the same as those in the fifth embodiment of the present invention, and detailed description thereof is omitted.
[0120]
The lighting device 130 includes a control circuit 131. The control circuit 131 includes a non-inverting amplifier circuit 132 that amplifies the lamp voltage detected by the voltage detection circuit 114, and an intermittent pulse generation circuit that generates an intermittent pulse voltage having a differential waveform superimposed on the output voltage of the non-inverting amplifier circuit 132. 133. Further, an oscillator 134 is provided that outputs a triangular pulse voltage in which the superimposed voltage is input to the inverting input terminal according to the output voltage of the lamp mounting detection circuit 5. Further, a comparator 135 is provided that compares the voltage obtained by superimposing the intermittent pulse on the output voltage of the non-inverting amplifier circuit 132 with the triangular wave pulse voltage output from the oscillator 134 and outputs an output corresponding to the voltage to the drive circuit 92. ing.
[0121]
With the circuit configuration as described above, the oscillator 134 corresponds to the oscillator 24 and the comparator 135 corresponds to the comparator 23, and controls the drive circuit 92. In the case of this lighting device 130, the detected lamp voltage The voltage obtained by superimposing the intermittent pulse of the differential waveform on the non-inverting input terminal of the comparator 135 is input. Therefore, if only the triangular wave pulse voltage and the ramp voltage of the oscillator 134 are compared with each other by the comparator 135, the switching element 94 is only in a short time corresponding to the generation of the intermittent pulse even during the period when the switching element 94 is on. Is turned off, and as shown in FIG. 11, a rest period h in which the lamp current decreases to substantially zero occurs. The rest period h is set to an extremely short time such that the high-pressure discharge lamp 6 does not disappear and does not substantially re-ignite, for example, about several hundred μm.
[0122]
By the way, when the high pressure discharge lamp 6 is DC-driven, if the high pressure discharge lamp 6 is not completely installed and there is a gap between the base and the socket, a discharge occurs in the gap and a metal part such as a socket is formed. May cause adverse effects such as deformation.
[0123]
However, the present inventor has verified that when such a discharge is generated, it can be extinguished by providing the pause interval h. It was also verified that the discharge can be eliminated if the pause interval h is provided once. Moreover, in this illuminating device 130, since the idle period h is periodically provided in the generation period of an intermittent pulse, it can prepare for the discharge between a nozzle | cap | die and a socket whose generation | occurrence | production time cannot be estimated.
[0124]
[Eighth Embodiment of the Invention]
FIG. 12 is a circuit diagram of a lighting device 140 showing an eighth embodiment of the present invention, which is for a direct current. In the figure, circuit elements having the same reference numerals as those in FIG. 10 are the same as those in the seventh embodiment of the present invention, and detailed description thereof is omitted.
[0125]
The lighting device 140 includes a control circuit 141. The control circuit 141 is different from the control circuit 131 in that the intermittent pulse generation circuit 133 is not provided, and the intermittent pulse is not superimposed on the output voltage of the non-inverting amplifier circuit 132.
[0126]
The lighting device 140 includes a pause interval generation circuit 142, and the intermittent pulse derivation circuit 133 is provided in the pause interval generation circuit 142. The pause period generation circuit 142 receives a switching element 143 that bypasses the gate voltage output from the drive circuit 92 to the switching element 94 to the power supply line, and an intermittent pulse generated by the intermittent pulse derivation circuit 133 is input to the light emitting element. The photocoupler 144 is connected to the output side of the light receiving element and the gate side of the switching element 143.
[0127]
That is, the lighting device 140 bypasses the ON signal of the switching element 94 output from the drive circuit 92, thereby turning off the switching element 94 for an extremely short time and creating a rest period h. Thereby, similarly to the lighting device 130, it is possible to prevent the electric discharge generated in the gap between the base and the socket.
[0129]
【The invention's effect】
  Claim1The invention described inA discharge path is formed inside, and is electrically connected in parallel to the arc tube.Detection element having predetermined electrical characteristicsTogenamiDischarge lamps integrated in a row;A driving circuit for lighting and driving the discharge lamp by turning on and off the switching element; a bypass circuit for bypassing the switching element; and when the switching element is bypassed by the bypass circuit, the arc tube is not lit but the detection element By supplying current toA detection circuit for determining electrical characteristics of the detection element;A starting circuit for properly starting the discharge lamp by turning on the switching element based on a determination output indicating that the lamp is a compatible lamp; and stably lighting the discharge lamp by turning on the switching elementLighting circuit;Therefore, it is possible to determine whether or not the mounting lamp is a conforming lamp without lighting the mounting lamp, based on whether or not the output of the detection circuit is within a predetermined range. can do. In addition, it is possible to automatically turn on the light by simply attaching a compatible lamp. Further, it is possible to perform lighting corresponding to the difference in rated lamp power of the same type of compatible lamp. In addition, using the fact that the electrical characteristics fluctuate depending on the temperature characteristics of the detection element, and appropriately setting the predetermined range of the output of the detection circuit, it is suitable for cases such as when the light is turned on again after a short time. It is possible to determine whether or not the mounted lamp, which is a lamp, is in a state that is not suitable for lighting.
[0130]
  Claim2The invention described inA discharge path is formed inside, and is electrically connected in parallel to the arc tube.Detection element having predetermined electrical characteristicsTogenamiDischarge lamps integrated in a row;A driving circuit for lighting and driving the discharge lamp by turning on and off the switching element; a bypass circuit for bypassing the switching element; and when the switching element is bypassed by the bypass circuit, the arc tube is not lit but the detection element By supplying current toA detection circuit for determining electrical characteristics of the detection element; and a first determination circuit for determining the discharge lamp as a compatible lamp when the output of the detection circuit is within a predetermined range;Based on the determination output that the detection circuit is a compatible lamp, the switching element is turned onDischarge lampStart properlyA starting circuit;By turning on the switching elementStable lighting of the discharge lampDoA detection circuit, comprising: a lighting circuit; and a first control circuit that operates the starting circuit and the lighting circuit when the determination of the first determination circuit is a compatible lamp. Whether or not the mounting lamp is a compatible lamp can be determined without lighting the mounting lamp. Further, since it is detected whether or not the mounting lamp is a compatible lamp, and the starting circuit and the lighting circuit are operated when the mounting lamp is a compatible lamp, it is possible to automatically turn on only by mounting the compatible lamp. Further, it is possible to perform lighting corresponding to the difference in rated lamp power of the same type of compatible lamp. In addition, using the fact that the electrical characteristics fluctuate depending on the temperature characteristics of the detection element, and appropriately setting the predetermined range of the output of the detection circuit, it is suitable for cases such as when the light is turned on again after a short time. It is possible to determine whether or not the mounted lamp, which is a lamp, is in a state that is not suitable for lighting.
[0131]
  Claim3The invention described inA discharge path is formed inside, and is electrically connected in parallel to the arc tube.Detection element having predetermined electrical characteristicsTogenamiDischarge lamps integrated in a row;A driving circuit for lighting and driving the discharge lamp by turning on and off the switching element; a bypass circuit for bypassing the switching element; and when the switching element is bypassed by the bypass circuit, the arc tube is not lit but the detection element By supplying current toA detection circuit for determining electrical characteristics of the detection element; and a first determination circuit for determining the discharge lamp as a compatible lamp when the output of the detection circuit is within a predetermined range;Based on the determination output that the detection circuit is a compatible lamp, the switching element is turned onDischarge lampStart properlyA starting circuit;By turning on the switching elementA lighting circuit that stably lights the discharge lamp; a first control circuit that operates the starting circuit and the lighting circuit when the determination of the first determination circuit is a compatible lamp; and based on an output of the detection circuit And a second control circuit for controlling the output of the starting circuit and the lighting circuit, so that the mounting lamp is determined depending on whether or not the output of the detection circuit is within a predetermined range. It is possible to determine whether the lamp is a compatible lamp without turning on the mounting lamp. Further, since it is detected whether or not the mounting lamp is a compatible lamp, and the starting circuit and the lighting circuit are operated when the mounting lamp is a compatible lamp, it is possible to automatically turn on only by mounting the compatible lamp. Further, it is possible to perform lighting corresponding to the difference in rated lamp power of the same type of compatible lamp. In addition, it is possible to determine whether or not the mounted lamp, which is a compatible lamp, is in a state that is not suitable for lighting, such as when the lamp is turned on again after a short time. Since the outputs of the starting circuit and the lighting circuit are controlled based on the output of the detection circuit, it is possible to determine the difference in the rated power of the same type of discharge lamp and to light it properly.
[0132]
  Claim4The invention described in claim2Or3In the invention described in item 1, the first determination circuit includes a retaining unit that retains lighting of the discharge lamp during a preset period after the mounted lamp is determined to be a compatible lamp. Therefore, since the discharge lamp is not lit during the period, it is safe even if the lamp is automatically turned on immediately if a compatible lamp is attached.
[0133]
  Claim5The invention described in claim4In the first aspect of the invention, a first timer that counts a preset period after the first determination circuit determines that the mounted lamp is a compatible lamp, and a third control that stops the starter circuit during this period. A discharge lamp by counting a preset period after determining that the mounted lamp is a compatible lamp, and stopping the starting circuit during this period. Since the lighting of the lamp is reserved, it is safe even if the lamp is automatically turned on immediately if a compatible lamp is attached.
[0134]
  Claim6The invention described in claim 1, 2, 3, 4,Of 5In any one of the inventions, the starting circuit is configured to apply a starting pulse to the discharge lamp; when the starting circuit generates the starting pulse, the duration of the starting pulse is counted. And a fourth control circuit for stopping the starting circuit when the count time exceeds a preset time, so that a failure of a mounted lamp or the like is provided. If it does not light even if a start pulse is given for a certain period of time, the start circuit is stopped, and the useless start pulse can prevent dielectric breakdown of the lamp cap and adverse effects on other electrical and electronic equipment. it can.
[0136]
  Claim7The invention described in claim 1, 2, 3, 4, 5,6'sIn the invention according to any one of the above, the lighting circuit is configured to direct-discharge the discharge lamp; the lighting circuit is controlled so that the discharge lamp does not re-ignite the lamp current of the discharge lamp. Since the sixth control circuit for providing the rest period is provided, the lamp current of the discharge lamp that is lit by direct current has a rest period that is long enough for the discharge lamp not to re-ignite. . As described above, it was confirmed that the discharge can be prevented from being generated in the gap between the lamp cap and the socket by making the rest period in the lamp current.
[0137]
  Claim8The invention described in claim 1, 2, 3, 4, 5, 6,7'sIn the invention described in any one of the above, the discharge lamp is characterized in that the resistance or impedance of the detection element is larger than the equivalent resistance or impedance of the arc tube at the time of lighting. Power loss due to the element can be suppressed.
[0138]
  Claim9The invention described in claim 1, 2, 3, 4, 5, 6, 7,8'sThe invention according to any one of the above, characterized by comprising a thermally responsive element such as a bimetal switch which is provided in the discharge lamp and operates by increasing the temperature of the discharge lamp to cut off the power to the detecting element. Therefore, after the compatible lamp is turned on, when the lamp temperature rises to some extent, the detection element is de-energized to prevent power loss.
[0139]
  Claim 10The invention described in claim 1, 2, 3, 4, 5, 6, 7, 8,9In the invention according to any one of the above, the detection element is characterized by a resistance having a temperature coefficient of resistance of 500 ppm / ° C. or higher, so that even when detection is performed using the temperature characteristics of the detection element. Because the resistance temperature coefficient is 500 ppm / ° C or higher and a relatively large resistance is used as the detection element, the fluctuation of the electrical characteristic value such as resistance or impedance corresponding to the temperature fluctuation can be increased, and the detection accuracy can be increased. Can be improved.
[Brief description of the drawings]
FIG. 1 is a circuit diagram of an illumination device showing a first embodiment of the present invention.
FIG. 2 is a plan view of a high-pressure discharge lamp that is a compatible lamp of the illumination device.
FIG. 3 is a graph illustrating the operation of the lighting device.
FIG. 4 is a circuit diagram of a lighting device showing a second embodiment of the present invention.
FIG. 5 is a circuit diagram of an illumination device showing a third embodiment of the present invention.
FIG. 6 is a circuit diagram of an illumination device showing a fourth embodiment of the present invention.
FIG. 7 is a plan view of a high-pressure discharge lamp that is a compatible lamp of the illumination device.
FIG. 8 is a circuit diagram of an illumination device showing a fifth embodiment of the present invention.
FIG. 9 is a circuit diagram of an illumination device showing a sixth embodiment of the present invention.
FIG. 10 is a circuit diagram of an illumination device showing a seventh embodiment of the present invention.
FIG. 11 is a graph showing a temporal change in lamp current of the lighting device.
FIG. 12 is a circuit diagram of an illumination device showing an eighth embodiment of the present invention.
[Explanation of symbols]
1 Lighting device
3 lighting circuit
4 Start circuit
5 detection circuit, first determination circuit, first comparison circuit
6 Discharge lamp
12 1st, 2nd, 4th control circuit
41 Discharge path
42 Detection element
60 Lighting equipment
63 Lighting circuit
75 First and second control circuits
80 Lighting equipment
81 Third control circuit
83 Second timer
90 Lighting equipment
93 Lighting circuit
103 1st, 2nd, 4th control circuit
104 First timer
105 Second timer
106 Thermally responsive element
110 Illumination device
111 Second comparison circuit
114 Output detection circuit
120 lighting device
121 Reservation means
124 1st timer, 3rd control circuit
125 third control circuit
130 Illumination device
131 sixth control circuit
140 Illuminator
141 Sixth control circuit
142 sixth control circuit

Claims (10)

A discharge lamp having a discharge path formed therein and a detection element connected in parallel to the arc tube and having a predetermined electrical characteristic; ;
A driving circuit for lighting and driving the discharge lamp by turning on and off the switching element;
A bypass circuit for bypassing the switching element;
A detection circuit for determining electrical characteristics of the detection element by supplying current to the detection element when the switching element is bypassed by the bypass circuit;
A starting circuit for properly starting the discharge lamp by turning on the switching element based on a discrimination output of the detection circuit as a compatible lamp;
A lighting circuit for stably lighting the discharge lamp by turning on the switching element;
And a lighting device. A discharge lamp having a discharge path formed therein and a detection element connected in parallel to the arc tube and having a predetermined electrical characteristic; ;
A driving circuit for lighting and driving the discharge lamp by turning on and off the switching element;
A bypass circuit for bypassing the switching element;
A detection circuit for determining electrical characteristics of the detection element by supplying current to the detection element when the switching element is bypassed by the bypass circuit;
A first determination circuit that determines that the discharge lamp is a compatible lamp when the output of the detection circuit is within a predetermined range;
A starting circuit for properly starting the discharge lamp by turning on the switching element based on a discrimination output of the detection circuit as a compatible lamp;
A lighting circuit for stably lighting the discharge lamp by turning on the switching element;
A first control circuit that operates the starting circuit and the lighting circuit when the determination of the first determination circuit is a compatible lamp;
And a lighting device. A discharge lamp having a discharge path formed therein and a detection element connected in parallel to the arc tube and having a predetermined electrical characteristic; ;
A driving circuit for lighting and driving the discharge lamp by turning on and off the switching element;
A bypass circuit for bypassing the switching element;
A detection circuit for determining electrical characteristics of the detection element by supplying current to the detection element when the switching element is bypassed by the bypass circuit;
A first determination circuit that determines that the discharge lamp is a compatible lamp when the output of the detection circuit is within a predetermined range;
A starting circuit for properly starting the discharge lamp by turning on the switching element based on a discrimination output of the detection circuit as a compatible lamp;
A lighting circuit for stably lighting the discharge lamp by turning on the switching element;
A first control circuit that operates the starting circuit and the lighting circuit when the determination of the first determination circuit is a compatible lamp;
A second control circuit for controlling the outputs of the starting circuit and the lighting circuit based on the output of the detection circuit;
A lighting device comprising:   The holding means for holding on the discharge lamp during a preset period after the first determination circuit determines that the mounted lamp is a compatible lamp. Lighting device. Reservation means:
A first timer for counting a preset period after the first determination circuit determines that the mounted lamp is a compatible lamp;
The lighting device according to claim 4, further comprising a third control circuit that stops the starting circuit during the period. The starting circuit is;
Configured to apply a starting pulse to the discharge lamp;
A second timer that counts the duration of the start pulse when the start circuit generates a start pulse;
4. A fourth control circuit that stops the start circuit when the count time exceeds a preset time. 6. The lighting device described. The lighting circuit is configured to direct-discharge the discharge lamp;
The control circuit according to claim 1, further comprising a sixth control circuit for controlling the lighting circuit so as to provide a rest period for a time that the discharge lamp does not re-ignite in the lamp current of the discharge lamp. The illumination device according to any one of 3, 4, 5, and 6 . Discharge lamps;
Claim 1,2,3,4,5,6, characterized in that those resistance or impedance of the detection element than the equivalent resistance or impedance of the arc tube during lighting is larger, in any one of 7 The lighting device described. A heat responsive element provided in the discharge lamp, which operates by increasing the temperature of the discharge lamp and cuts off the power to the detection element, is provided. The lighting device according to any one of 6, 7, and 8 . The detection element is:
The lighting device according to any one of claims 1, 2, 3, 4, 5, 6, 7, 8, and 9, wherein the resistance temperature coefficient is a resistance of 500 ppm / ° C or more.

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