JP3885741B2 - Lighting system, discharge lamp lighting device, lighting fixture - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a lighting system, a discharge lamp lighting device, and a lighting fixture.
[0002]
[Prior art]
In general, human visual characteristics cannot follow a rapid change in brightness.For example, if there is a sudden change in brightness near the entrance of a tunnel, the visibility decreases and the safety of the vehicle travels. There is a possibility that it cannot be secured. Therefore, in tunnel lighting, it is desired to increase the illuminance by a lighting fixture arranged in the vicinity of the entrance of the tunnel as much as possible to suppress a reduction in visibility. On the other hand, in order to increase the illuminance by the luminaire, it is necessary to use a high-intensity lamp or increase the number of lamps, and the power consumption increases, so the maintenance cost (running cost) increases. . Therefore, in order to reduce power consumption without reducing visibility, the illuminance of the tunnel illumination is adjusted according to the illuminance outside the tunnel. Techniques for reducing illuminance have been proposed.
[0003]
Since a plurality of lighting fixtures are arranged in the tunnel lighting, in order to control the brightness near the entrance of the tunnel according to the brightness outside the tunnel as described above, as shown in FIG. In addition to the power supply line Lp for supplying power to 1, it is necessary to connect a dimming signal line Lc for supplying a dimming signal to each lighting fixture 1. The illustrated lighting fixture 1 is 100% lit (rated lighting), 50% lit (light output is 50% of 100% lit), and 25% lit (light output is 25% of 100% lit) according to the dimming signal. It is assumed that the three-stage lighting state can be selected. A dimming signal output device 6 is connected to the dimming signal line Lc, and the dimming signal output device 6 has a function of detecting the illuminance outside the tunnel and generating a dimming signal.
[0004]
With the configuration shown in FIG. 16, during a period when the illuminance difference between the inside and outside of the tunnel is large as in the daytime, the illuminance 1 is turned on 100% to reduce the difference in illuminance inside and outside the tunnel. During the time period when the ambient illuminance outside the tunnel decreases, the lighting fixture 1 can be turned on by 50% in order to reduce the light output of the lighting fixture 1 inside the tunnel. In addition, during the period when the ambient illuminance outside the tunnel decreases and the traffic volume also decreases, such as at midnight, the possibility of an accident due to a decrease in visibility is reduced by increasing the inter-vehicle distance. It is possible to lower the lighting fixture 1 by 25%. In this way, the lighting fixture 1 is turned on 100% only during a period when the difference in illumination between the inside and outside of the tunnel is large, and the lighting fixture 1 is dimmed and turned on during other periods, so that it is consumed in comparison with the case where the lighting fixture 1 is always turned on. Electric power can be reduced.
[0005]
By the way, in the tunnel illumination, a discharge lamp (for example, a sodium lamp) is widely adopted as a lamp used in the lighting fixture 1. This is because when a discharge lamp is used, the power consumption and volume with respect to the light emission luminance are relatively small, and since the life is long, the frequency of lamp replacement can be relatively reduced. Here, it is known that the luminous efficiency of the discharge lamp varies depending on the vapor pressure of the encapsulated material, and the vapor pressure of the encapsulated material varies according to the tube wall temperature of the discharge lamp. Therefore, the discharge lamp is designed so that the vapor pressure of the encapsulated material becomes the optimum value at the tube wall temperature in use, and the tube wall temperature is low even if it is higher than the designed optimum temperature. However, the light emission efficiency is lowered. That is, as shown in FIG. 17, the luminous efficiency of the discharge lamp is maximized around room temperature. In other words, if the ambient temperature changes, the light output of the discharge lamp fluctuates, and there is a case where the light output as designed cannot be obtained from the lighting fixture 1 with respect to the illuminance change outside the tunnel.
[0006]
Therefore, it is considered to compensate for the change in the light output of the discharge lamp by adjusting the output of the discharge lamp lighting device for lighting the discharge lamp. As this type of technology, the discharge lamp lighting device employs a configuration in which the output of the inverter circuit is supplied to the discharge lamp, and the frequency at which the switching element provided in the inverter circuit is turned on and off (hereinafter referred to as the “operating frequency”) is determined. The thing which adjusts according to the tube wall temperature of this is proposed. An LC resonance circuit is provided at the output stage of the inverter circuit, and the power supplied to the discharge lamp through the LC resonance circuit can be changed by changing the operating frequency of the inverter circuit. Therefore, dimming of the discharge lamp becomes possible by changing the operating frequency. Therefore, a temperature detector that detects the temperature corresponding to the tube wall temperature of the discharge lamp is provided, and when the temperature detected by the temperature detector is not the temperature that maximizes the light emission efficiency of the discharge lamp, the discharge lamp lighting device changes to the discharge lamp. By increasing the power supplied, the light output of the discharge lamp is kept substantially constant. In other words, the operating frequency of the inverter circuit is changed according to the temperature detected by the temperature detector so as to keep the light output of the discharge lamp constant regardless of the temperature detected by the temperature detector.
[0007]
As a configuration for changing the operating frequency of the inverter circuit according to the temperature, a configuration for controlling the output frequency of an oscillation control circuit that generates a rectangular wave control signal for turning on and off the switching element is known. As this type of oscillation control circuit 13 ', a configuration shown in FIG. 18 has been proposed (see, for example, Patent Document 1).
[0008]
In the oscillation control circuit 13 'shown in the figure, the terminal voltage of the capacitor Ct that determines the cycle of the control signal is compared with a reference voltage set in two steps, high and low, using two comparators CP1 and CP2, and the outputs of the comparators CP1 and CP2 are output. Are used to reset and set the RS flip-flop circuit FF, respectively. The output of the RS flip-flop circuit FF is used as a control signal. The capacitor Ct is charged by a current source, and discharged through the resistor Rt and the transistor Qt during a period when the inverting output terminal of the RS flip-flop circuit FF is at the H level (that is, a period when the control signal is at the L level). . The comparator CP2 sets the RS flip-flop circuit FF when the capacitor Ct is discharged and the terminal voltage of the capacitor Ct becomes lower than the lower reference voltage. The comparator CP1 is charged with the capacitor Ct and the terminal voltage of the capacitor Ct is high. When the voltage becomes equal to or higher than the reference voltage, the RS flip-flop circuit FF is reset. The current source for charging the capacitor Ct includes two current mirror circuits 17 and 18, and each current mirror circuit 17 and 18 receives a negative temperature coefficient current source In and a positive temperature coefficient current source Ip, and inputs both currents. The output currents of the mirror circuits 17 and 18 are combined to charge the capacitor Ct. Furthermore, a variable resistor 19 for changing the contribution ratio of the negative temperature coefficient current source In and the positive temperature coefficient current source Ip to the charging current of the capacitor Ct is also provided.
[0009]
Therefore, if the variable resistor 19 is adjusted, the ratio that the negative temperature coefficient current source In and the positive temperature coefficient current source Ip contribute to the charging current of the capacitor Ct changes, and temperature compensation of the charging current of the capacitor Ct becomes possible. Then, temperature compensation of the output frequency of the oscillation control circuit 13 'is performed. As a result, it is possible to control such that the output is kept constant regardless of the temperature detected by the negative temperature coefficient current source In and the positive temperature coefficient current source Ip.
[0010]
[Patent Document 1]
JP 2002-233151 A (page 4, FIG. 1)
[0011]
[Problems to be solved by the invention]
By the way, as described above, in the tunnel lighting, a dimming state of 25% lighting is required for 100% lighting, but when trying to realize 25% lighting with one lamp, the lamp current is greatly increased with respect to the rated current. It becomes difficult to raise the tube wall temperature. In particular, if the lamp is turned on at 25% at low temperatures, the tube wall temperature will be significantly lower than the temperature that maximizes the luminous efficiency. Therefore, the light output of the discharge lamp will be significantly higher than when it is turned on at 100% or 50%. Will be reduced. That is, if the technique described in Patent Document 1 is applied to tunnel illumination, it is required to increase the temperature coefficient of the current source in the oscillation control circuit 13 ′.
[0012]
However, if the temperature coefficient of the current source in the oscillation control circuit 13 'is increased, the output fluctuates due to the influence of the ambient temperature even during output adjustment and inspection before shipment. Therefore, temperature management during output adjustment and inspection is performed. As a result, there arises a problem that production efficiency is lowered. Further, in the above-described technique, the output of the inverter circuit is increased when the tube wall temperature is not the temperature that maximizes the light emission efficiency, and the light output must be greatly increased particularly when the lamp is turned on at 25% at a low temperature. Therefore, the control is performed against energy saving (see FIG. 6).
[0013]
The present invention has been made in view of the above reasons, and its purpose is to suppress the increase or decrease of the light output due to the change in the tube wall temperature, and the consumption accompanying the temperature compensation while taking a wide dimming range. An object of the present invention is to provide a lighting system, a discharge lamp lighting device, and a lighting fixture in which the increase / decrease width of power is relatively small.
[0014]
[Means for Solving the Problems]
  Claim 1And claim 2The invention relates to a lighting system.
[0015]
  The invention of claim 1 illuminates the same area.Two lightsDischarge lamp and2 lightsThis is a discharge lamp lighting device that constitutes a lighting fixture by being housed in a sealed lamp together with a discharge lamp of each type, and each discharge lamp is individually lit and dimmed according to a dimming signal from the outside. Possible2 piecesMultiple types of discharge lamp lighting devices and combinations of lighting and extinction of each discharge lamp and dimming amount by generating a dimming signal to be given to each discharge lamp lighting device and instructing to turn on and off each discharge lamp A dimming signal output device for selecting the lighting pattern ofThe dimming signal output device dims the lighting pattern for lighting both discharge lamps 100%, the lighting pattern for lighting one of the discharge lamps 100% and extinguishing the other discharge lamp, and either one of the discharge lamps. It is possible to select a lighting pattern that turns on and turns off the other discharge lamp.Discharge lamp lighting deviceIs freeDetect ambient temperature of electric lightNegative characteristic thermistorTemperature detectorThe other discharge lamp lighting device has a positive temperature coefficient thermistor that detects the ambient temperature of the discharge lamp as a temperature detector.And adjusting the dimming amount so as to suppress the change in the light output of the discharge lamp with respect to the change in temperature detected by the temperature detection unit. The ambient temperature of the discharge lamp means the temperature of a part that reflects the tube wall temperature of the discharge lamp, such as the tube wall temperature of the discharge lamp and the temperature in the lamp housing the discharge lamp.
[0019]
  Claim 2The invention ofClaim 1In the invention, an external temperature detection unit for detecting an ambient temperature is provided, and the dimming signal output device is configured to provide an external temperature detection unit in a lighting pattern in which one of the discharge lamps is dimmed and the other discharge lamp is extinguished. When the ambient temperature detected by the discharge lamp lighting device provided with a negative thermistor is less than or equal to the prescribed threshold, the ambient temperature detected by the external temperature detector is greater than or equal to the prescribed threshold. The discharge lamp is dimmed with a discharge lamp lighting device including a positive temperature coefficient thermistor.
[0020]
  Claims 3 to 11The present invention relates to a discharge lamp lighting device.
[0021]
  Claim 3The invention of claim 1Or claim 2A discharge lamp lighting device for use in the illumination system according to claim 1, wherein the power supplied from the dimming signal output device is converted into high frequency power by turning on and off a switching element, and a high frequency AC voltage is applied to the discharge lamp through an LC resonance circuit. Compensation circuit comprising an inverter circuit to be applied and an oscillation control circuit for controlling on / off of a switching element provided in the inverter circuit, the oscillation control circuit including the temperature detection unit and changing the output of the inverter circuit according to the detected temperature It is characterized by providing.
[0022]
  Claim 4The invention ofClaim 3According to the invention, a rectifying / smoothing circuit for rectifying and smoothing the power source is provided, and the temperature detection unit is disposed at a portion between the rectifying / smoothing circuit and the inverter circuit.
[0023]
  Claim 5The invention ofClaim 3 or claim 4In the invention, the temperature detection unit is connected to the case via a heat transfer member made of a material having a higher thermal conductivity than the atmosphere.
[0024]
  Claim 6The invention ofClaim 3In the invention, the oscillation control circuit includes a clocking means for measuring a cumulative lighting time, and a discharge lamp with the passage of the cumulative lighting time obtained by the clocking means so as to suppress a temporal change in the light output of the discharge lamp. Output correction means for increasing the light output.
[0025]
  Claim 7The invention ofClaim 3In the invention, the dimming by the dimming signal is multi-stage dimming. Note that step dimming means instantaneously changing the dimming amount so that a person can perceive a change in brightness.
[0026]
  Claim 8The invention ofClaim 3In the invention, the dimming by the dimming signal is continuous dimming. The continuous light control includes a case where the brightness is smoothly changed and a case where the brightness change per stage is set so that a person cannot perceive the brightness even if the brightness change is gradual. .
[0027]
  Claim 9The invention ofClaims 3 to 8In the invention, the compensation circuit operates when dimming is instructed by the dimming signal.
[0028]
  Claim 10The invention ofClaims 3 to 8The invention is characterized in that the compensation circuit is operated when a temperature detected by the temperature detector is not more than a prescribed threshold value.
[0029]
  Claim 11The invention ofClaims 3 to 8The invention is characterized in that the compensation circuit is operated when the temperature detected by the temperature detector is not more than a prescribed threshold value and the discharge lamp is dimmed.
[0030]
  Claims 12 to 16The present invention relates to a lighting apparatus.
[0033]
  Claim 12The invention of claim 1Or claim 2A lighting fixture for use in the lighting system according to claim 2, wherein the lamp is provided with two each of the discharge lamp lighting device and the discharge lamp, and the two discharge lamp lighting devices are arranged in a horizontal direction when the lamp is mounted on the construction surface. It is arranged on the straight line which becomes.
[0034]
  Claim 13The invention ofClaim 12In the invention, the discharge lamp lighting device is housed in a single cylindrical case.
[0035]
  Claim 14The invention ofClaim 13In the invention, the cylindrical case is hermetically sealed.
[0036]
  Claim 15The invention ofClaim 14In the invention, the discharge lamp lighting device is fixed in a thermally coupled form to a pedestal made of a highly heat conductive material.
[0037]
  Claim 16The invention of claim 1Or claim 2It is a lighting fixture used for the illumination system as described above, wherein the discharge lamp and the discharge lamp lighting device for lighting the discharge lamp are arranged close to each other.
[0038]
DETAILED DESCRIPTION OF THE INVENTION
  (Basic configuration)
  This exampleThen, as shown in FIG. 1, a case where two lighting lamps 3 are provided in one lighting fixture 1.Show.
[0039]
  This exampleAs shown in FIG. 1, the lighting system shown in FIG. 1 includes a lighting fixture 1 in which a discharge lamp lighting device 4 is housed in a lamp 5 together with a discharge lamp 3, and a dimming signal for the discharge lamp lighting device 4 provided in the lighting fixture 1. Is provided with a dimming signal output device 6 for dimming the discharge lamp 3. The lighting fixture 1 contains two discharge lamps 3, and each discharge lamp 3 is lit by a separate discharge lamp lighting device 4. That is, two discharge lamp lighting devices 4 are accommodated in the lighting fixture 1. When the lighting fixture 1 is used for tunnel lighting, a lamp 5 having a sealed structure is used for the purpose of drip-proof and dust-proof. A dimming signal output device 6 having a brightness sensor (not shown) for detecting ambient illuminance outside the tunnel is connected to the lighting fixture 1, and the dimming signal output device 6 corresponds to the brightness outside the tunnel. A dimming signal is generated to control the light output of the discharge lamp 3. Power is supplied to the dimming signal output device 6 from the commercial power supply AC, and each discharge lamp lighting device 4 is supplied with power separately from the dimming signal output device 6. That is, between the dimming signal output device 6 and the lighting fixture 1, two sets of power supply lines Lp1 and Lp2 for supplying power from the dimming signal output device 6 to each discharge lamp lighting device 4, and dimming signal output A set of dimming signal lines Lc for providing a dimming signal from the device 6 to the discharge lamp lighting device 4 is provided. Power supply from the dimming signal output device 6 to each discharge lamp lighting device 4 is individually controlled, and the discharge lamp 3 that is turned on by each discharge lamp lighting device 4 is selected to be turned on or off. That is, in the dimming signal output device 6, it is possible to select a plurality of types of lighting patterns depending on the combination of whether or not both the discharge lamps 3 are turned on or off and the dimming amount of each discharge lamp 3. ing.
[0040]
Incidentally, as shown in FIG. 2, the discharge lamp lighting device 4 includes a rectifying / smoothing circuit 11 that rectifies and smoothes the AC power supplied from the commercial power supply AC via the power lines Lc1 and Lc2 (see FIG. 1). A configuration in which a DC voltage obtained by the smoothing circuit 11 is converted into a high frequency voltage by the inverter circuit 12 and a high frequency AC voltage is applied to the discharge lamp 3 through an LC resonance circuit (not shown) provided at the output stage of the inverter circuit 12. Is adopted. The rectifying / smoothing circuit 11 includes a chopper circuit for the purpose of power factor improvement and reduction of input current distortion, and includes a filter for removing high-frequency components and a full-wave rectifying circuit between the commercial power supply AC and the chopper circuit. As the inverter circuit 12, various known configurations can be used. The inverter circuit 12 includes a switching element, and the power supplied to the discharge lamp 3 through the LC resonance circuit can be changed by changing the ON / OFF frequency (that is, the operating frequency) of the switching element. . In other words, the light output of the discharge lamp 3 can be changed by changing the operating frequency, and the light output of the discharge lamp 3 is designed to decrease if the operating frequency is increased. In the illustrated example, the rectifying / smoothing circuit 11 and the inverter circuit 12 are described separately, but a configuration in which a part of the switching elements of the chopper circuit and the inverter circuit 12 used in the rectifying / smoothing circuit 11 is shared is adopted. May be.
[0041]
  A control signal for controlling the operating frequency of the inverter circuit 12 is generated by the oscillation control circuit 13 and given to the switching element of the inverter circuit 12 through the drive circuit 14. The drive circuit 14 performs level conversion for driving the switching element on the control signal generated by the oscillation control circuit 13. The control signal output from the oscillation control circuit 13 is a rectangular wave, and the frequency of the control signal is variable in the oscillation control circuit 13. by the way,This exampleThe dimming signal output circuit 6 is configured to output a binary dimming signal, and the discharge lamp lighting device 4 is provided with a switch element SW that is turned on / off by the dimming signal. The switch element SW is connected to the dimming switching circuit 15, and the dimming switching circuit 15 switches the frequency of the control signal output from the oscillation control circuit 13 in two steps depending on whether the switch element SW is on or off. .This exampleThen, the frequency of the control signal is set so as to be switched between a frequency at which the discharge lamp 3 is lit 100% (100% lighting) and a frequency at which the discharge lamp 3 is lit 50%. Further, the oscillation control circuit 13 is provided with a temperature detection unit Th that detects the ambient temperature of the discharge lamp 3, and the ambient temperature at which the frequency of the control signal output from the oscillation control circuit 13 is detected by the temperature detection unit Th. It is corrected according to. That is, the frequency of the control signal is adjusted so that the light output of the discharge lamp 3 does not change even if the ambient temperature detected by the temperature detector Th changes.
[0042]
The configuration of the oscillation control circuit 13 used in the discharge lamp lighting device 3 will be described in more detail. As shown in FIG. 3, the oscillation control circuit 13 outputs a rectangular wave control signal from the comparator CP by charging and discharging the capacitor Co and comparing the terminal voltage of the capacitor Co with a reference voltage set in the comparator CP. The configuration is adopted. The comparator CP is provided with hysteresis by adopting a configuration in which the reference voltage is lowered when the output becomes H level and the reference voltage is raised when the output becomes L level, and the capacitor Co is provided by providing hysteresis to the comparator CP. Chattering due to minute fluctuations in the terminal voltage is prevented.
[0043]
The charge / discharge current Io of the capacitor Co is controlled by the charge / discharge circuit CD. Thus, by controlling the charging / discharging current Io of the capacitor Co by the charge / discharge circuit CD, the change speed of the terminal voltage of the capacitor Co can be changed, and as a result, the frequency of the control signal output from the comparator CP is changed. Can be made. That is, if the charging / discharging current Io is increased, the changing speed of the terminal voltage of the capacitor Co is increased, and the frequency of the control signal is increased.
[0044]
Two sets of current mirror circuits are used for the charge / discharge circuit CD. One current mirror circuit includes one transistor Q1 on the input side and two transistors Q2 and Q3 on the output side. Transistors Q2 and Q3 are connected to be an active load of the other current mirror circuit. The other current mirror circuit includes an input-side transistor Q4 through which a current passing through the transistor Q2 passes, and an output-side transistor Q5 through which a current passing through the transistor Q3 passes. One end of the capacitor Co is connected to a connection point between the collector of the transistor Q3 and the collector of the transistor Q5, and the other end of the capacitor Co is connected to the emitter of the transistor Q5. Therefore, if no current flows through the transistor Q5, the current passing through the transistor Q3 becomes the charging current for the capacitor Co. Since the transistor Q5 has a collector-emitter connected across the capacitor Co, and the transistor Q5 forms a current mirror circuit together with the transistor Q4, the discharge current of the capacitor Co is determined by the current flowing through the transistor Q4. . The collector-emitter of the transistor Q6 for switching is connected in parallel to the collector-emitter of the transistor Q4, and the transistor Q6 is turned on / off by a signal obtained by inverting the output of the comparator CP by the inverting circuit NT. Therefore, when the output of the comparator CP is at H level, that is, during a period when the terminal voltage of the capacitor Co is relatively high, the transistor Q6 is off and a current flows through the transistor Q5, so that the capacitor Co is discharged and the capacitor Co is discharged. The terminal voltage decreases. When the terminal voltage of the capacitor Co decreases and the output of the comparator CP becomes L level, the transistor Q6 is turned on, the transistor Q5 is turned off, and a charging current flows through the transistor Q3 through the transistor Q3. That is, the terminal voltage of the capacitor Co increases, and the output of the comparator CP is inverted to the H level over time. By repeating the above operation, the output of the comparator CP alternately repeats the L level and the H level, and a control signal that is a rectangular wave is output from the comparator CP.
[0045]
  By the way, in order to determine the charging / discharging current Io, the charging / discharging circuit CD is provided with a current regulator Rf composed of a variable resistor capable of adjusting the collector current of the transistor Q1. Therefore, the charge / discharge current Io can be appropriately set by adjusting the current regulator Rf. Further, between both ends of the current regulator Rf, a compensation circuit CL composed of a series circuit of a transistor Q7 as a switching element and a temperature detection unit Th is connected.This exampleThe resistance value of the temperature detector Th used in FIG. 4 changes depending on the detected temperature. For example, as shown in FIG. 4, a fixed resistor Rs and a variable resistor Rv are connected in series to a temperature sensor Rt composed of a thermistor. Adopt the configuration. As the temperature sensor Rt, either a negative characteristic thermistor or a positive characteristic thermistor is used.
[0046]
In this configuration, when the transistor Q7 is off, the current flowing through the transistor Q1 constituting the current mirror circuit is the current If flowing through the current regulator Rf, so the charge / discharge current Io is changed to the current If flowing through the current regulator Rf. Match. When the transistor Q7 is on, the current flowing through the transistor Q1 constituting the current mirror circuit is the sum of the current If flowing through the current regulator Rf and the current Id flowing through the temperature detection unit Th. The charge / discharge current Io increases as compared to when it is off. That is, the frequency of the control signal is higher when the transistor Q7 is on than when it is off.
[0047]
The above-described dimming switching circuit 15 is connected to the transistor Q7. When the switch element SW connected to the dimming switching circuit 15 is on, the transistor Q7 is also on, so that the temperature detection unit Th is connected to the current regulator Rf. Connected in parallel. When the temperature detector Th is connected in parallel to the current regulator Rf, the current flowing through the transistor Q1 constituting the current mirror circuit increases, so the charge / discharge current Io of the capacitor Co increases to increase the frequency of the control signal. The light output of the discharge lamp 3 is reduced. Therefore, when the dimming signal is not input and the transistor Q7 is off, the discharge lamp 3 is turned on 100%. When the dimming signal is input and the transistor Q7 is turned on, the discharge lamp 3 is turned on 50%. Furthermore, if the relationship between the current regulator Rf and the temperature detector Th is designed, 100% lighting or 50% lighting can be selected by the dimming signal. Moreover, when the transistor Q7 is turned on and is 50% lit (that is, when dimming), the current flowing through the transistor Q1 changes according to the temperature detected by the temperature detector Th. Thus, by appropriately setting the characteristics of the temperature detector Th, it is possible to reduce the change in the light output of the discharge lamp 3 with respect to the change in the ambient temperature as compared with the case where the temperature detector Th is not used. become.
[0048]
By the way, in the above-described configuration example, each discharge lamp 3 can be selected between 100% lighting, 50% lighting and extinguishing, and the lighting fixture 1 as a whole when both of the two discharge lamps 3 are turned on 100%. If the light output is 100%, the light output as a whole of the lighting fixture 1 when only one of them is turned on 100% and the other is turned off is 50%. Furthermore, when only one of them is turned on by 50% and the other is turned off, the light output of the lighting fixture 1 as a whole is 25%. That is, for each discharge lamp 3, by selecting a state in which only one of the two discharge lamps 3 is lit while maintaining the light output at 50% or more, the overall light output of the luminaire 1 is obtained. Can achieve 25% smaller than 50%. Note that which of the two discharge lamps 3 is turned off is appropriately selected.
[0049]
  With the above-described configuration, the lower limit of dimming per lamp of the discharge lamp 3 is 50%, and the lamp current of the discharge lamp 3 is large and the tube wall temperature of the discharge lamp 3 is higher than when dimming to 25%. Also gets higher. In other words, the light can be adjusted relatively easily regardless of the specification of the discharge lamp 3, and the possibility of occurrence of problems such as flickering at the time of low luminous flux is reduced. Moreover, since it is technically easy to adjust the light to 50% as described above, the circuit configuration is not complicated, resulting in a reduction in cost. here,This exampleIn this case, temperature compensation is not performed at 100% lighting, and temperature compensation is performed only when the light output is dimmed to 50%. Therefore, the circuit configuration is also simple in this respect. This is because, when a sealed lamp 5 is used like the lighting fixture 1 used for tunnel lighting, if the lamp 5 is designed so as to use heat generated from the discharge lamp 3 when 100% is lit, 100% lit. This is because sometimes it is possible to design such that the light output hardly changes depending on the temperature (a design that suppresses the decrease in light output at low temperatures is possible), and temperature compensation is performed only when 50% of the light is generated with little heat generation. DoThis exampleEven in this configuration, it is possible to expect a sufficient effect of suppressing a change in light output accompanying a change in ambient temperature.
[0050]
  (Embodiment 1)
  In the present embodiment, the configuration of the compensation circuit CL in the configuration of the oscillation control circuit 13 shown in FIG. 3 is changed to the configuration shown in FIG. That is,Basic configurationIn the present embodiment, one of the negative characteristic thermistor and the positive characteristic thermistor is used as the temperature sensor Rt used in the temperature detection unit Th. In the present embodiment, the temperature sensor Rt1 including the negative characteristic thermistor and the temperature sensor including the positive characteristic thermistor. A configuration in which Rt2 is used in combination is adopted. That is, fixed resistors Rs1, Rs2 and variable resistors Rv1, Rv2 are connected in series to the temperature sensors Rt1, Rt2, respectively, a series circuit of the temperature sensor Rt1, the fixed resistor Rs1, and the variable resistor Rv1, and the temperature sensor Rt2 and the fixed resistor. A configuration is adopted in which the current flowing through the series circuit of Rs2 and the variable resistor Rv2 is combined with the current flowing through the current regulator Rf and flows through the transistor Q1. The current flowing through the temperature sensor Rt1 increases at a low temperature, and the current flowing through the temperature sensor Rt2 increases at a high temperature. Therefore, by adjusting the temperature characteristics of the two temperature sensors Rt1 and Rt2 with the variable resistors Rv1 and Rv2, it is possible to obtain a temperature characteristic that minimizes or maximizes the current flowing through the transistor Q1 at a specific temperature.
[0051]
For example, the same configuration as in FIG. 3 is adopted for one discharge lamp 3, and a negative characteristic thermistor is used for the temperature sensor Rt, and the frequency of the control signal is 100% lit, 50% lit, and 25% lit, respectively. Is assumed to be temperature compensated. FIG. 6 shows the relationship between ambient temperature and light output ratio (ratio of light output when rated lighting at 25 ° C. is 100). A is 100% lit, B is 50% lit, and C is 25% lit. Each case is shown. In addition, D is a reference example in which 25% lighting is performed and temperature compensation is not performed. According to FIG. 6, in the practical temperature range (assuming −10 to 40 ° C.) of the environment in which the discharge lamp 3 is lit, in any of 100% lighting, 50% lighting, and 25% lighting. However, when the ambient temperature is lower than 25 ° C., the light output is larger than that at 25 ° C., but at a temperature higher than 25 ° C., the light output is smaller than that at 25 ° C. This is because, when a negative temperature coefficient thermistor whose resistance value decreases as the detected temperature increases in the configuration of FIG. 3 is used for the temperature sensor Rt, the charge / discharge current Io of the capacitor Co increases as the detected temperature increases, and the frequency of the control signal increases. In order to increase the light output on the higher temperature side than 25 ° C. compared to the case of 25 ° C., it is necessary to use a positive temperature coefficient thermistor for the temperature sensor Rt.
[0052]
  Therefore, this embodiment uses both a negative temperature coefficient thermistor and a positive temperature coefficient thermistor. By combining and using the temperature characteristics of both, the low temperature side and the high temperature side with respect to 25 ° C., which is normal temperature, are used. In any case, it is possible to set the characteristic to increase the light output. Other configurations and operations areBasic configurationIt is the same.
[0053]
  (Embodiment 2)
  Mentioned aboveIn an embodiment,Each discharge lamp 3 is dimmed in two stages of 100% lighting and 50% lighting, and the temperature compensation is performed at the time of 50% lighting. However, in this embodiment, each discharge lamp 3 is Dimming continuously. That is, the dimming signal output device 6 is configured to output an analog dimming signal or a multilevel dimming signal instead of a binary dimming signal. The format of the dimming signal output from the dimming signal output device 6 does not matter, but as shown in FIG. 7, the lighting fixture 1 uses a dimming signal corresponding to the dimming amount instead of the dimming switching circuit 15. A dimming signal conversion circuit 16 for converting to a voltage signal is provided.
[0054]
The output of the dimming signal conversion circuit 16 is input to a voltage follower including the operational amplifier OP1 and the transistor Q8, and the current Id flowing through the transistor Q8 is supplied to the transistor Q1 together with the current If flowing through the current regulator Rf. . One end of the temperature detection unit Th is connected to the emitter of the transistor Q8, and the output end of a voltage follower constituted by the operational amplifier OP2 is connected to the other end of the temperature detection unit Th. A DC power supply VB is connected to the input terminal of the voltage follower using the operational amplifier OP2.
[0055]
  In this configuration, if the output voltage of the dimming signal conversion circuit 16 is VA, the voltage across the temperature detection unit Th will be (VA-VB), and both ends of the temperature detection unit Th according to the dimming signal. The voltage will change. That is, the current flowing through the temperature detection unit Th according to the dimming signal, in other words, the current Id flowing through the transistor Q8 changes, and a current according to the dimming amount instructed by the dimming signal is supplied to the transistor Q1. It becomes possible. For example, if the dimming signal is set so that VA = VB, the current Id does not flow through the temperature detection unit Th, and therefore the frequency of the control signal is determined only by the current If flowing through the current regulator Rf. The discharge lamp 3 is turned on 100%. Further, the current Id flowing through the transistor Q8 can be continuously changed by continuously changing the output voltage of the dimming signal conversion circuit 16, and as a result, the light output of the discharge lamp 3 is continuously changed. It becomes possible. As is clear from the above description, VA ≧ VB, and the higher the voltage VA, the lower the light output of the discharge lamp 3. Therefore, the dimming signal and voltage VA in the dimming signal conversion circuit 16 are reduced. The conversion characteristics are as shown in FIG. Other configurations and operations areBasic configurationIt is the same.
[0056]
  (Embodiment 3)
  In each embodiment mentioned above, although the example using the thing of the same specification was shown for the two discharge lamp lighting devices 4 which comprise the lighting fixture 1, in this embodiment, the temperature detection part in one discharge lamp lighting device 4 An example in which a negative characteristic thermistor is used as the temperature sensor Rt in Th and a positive characteristic thermistor is used as the temperature sensor Rt in the temperature detection unit Th in the other discharge lamp lighting device 4 is shown. Further, the dimming signal output device 6 is provided with an external temperature detection unit 10 that detects the ambient temperature of the place where the lighting fixture 1 is installed.
[0057]
  Embodiment 1As described above, if a negative temperature coefficient thermistor is used as the temperature sensor Rt, the light output can be increased on the low temperature side in the temperature range of the environment where the lighting fixture 1 is used, and if a positive temperature coefficient thermistor is used as the temperature sensor Rt, The light output can be increased on the side. Therefore, in the present embodiment, the operation of the dimming signal output device 6 is a state where one of the two lamps is turned off and the other discharge lamp 3 is turned on by 50% (that is, as the lighting fixture 1). Is selected, the power supply is supplied to the discharge lamp lighting device 4 using the negative characteristic thermistor if the temperature detected by the external temperature detector 10 is equal to or less than a prescribed threshold value, and the external temperature detector When the detected temperature by 10 is equal to or higher than a prescribed threshold value, power is supplied to the discharge lamp lighting device 4 using a positive temperature coefficient thermistor. Here, the threshold for the detected temperature is set to 25 ° C., for example.
[0058]
  If the configuration of the present embodiment is adopted, the change in the light output of the discharge lamp 3 with respect to the change in the ambient temperature can be suppressed, and the light output on both the high temperature side and the low temperature side with respect to a specific temperature. By controlling in the direction of increasing the illuminance, it is possible to maintain the illuminance more than the desired illuminance regardless of the ambient temperature. Other configurations and operations areBasic configurationIt is the same.
[0059]
It should be noted that a negative characteristic thermistor is used for both the temperature detectors Th of both discharge lamp lighting devices 4 and temperature compensation by the temperature detector Th is performed only when the temperature detected by the external temperature detector 10 is equal to or less than a prescribed threshold. It is also possible to configure. Alternatively, a configuration in which the compensation circuit is operated when the temperature detected by the temperature detection unit Th provided in the discharge lamp lighting device 4 is equal to or lower than a specified threshold, or the detected temperature is equal to or lower than the specified threshold and compensated only when the light is adjusted. A configuration for operating the circuit may be employed.
[0060]
Below, the temperature detection technique for applying to each embodiment mentioned above is demonstrated. As shown in FIG. 10, the discharge lamp lighting device 4 includes a circuit board 7 that is a printed wiring board on which the rectifying and smoothing circuit 11 and the inverter circuit 12 are mounted, and the temperature detection unit Th is also mounted on the circuit board 7. . Here, a desirable position of the temperature detection unit Th on the circuit board 7 is a part between the rectifying and smoothing circuit 11 and the inverter circuit 12, and by arranging the temperature detection part Th in this part, The influence of the temperature due to the heat generating component (mainly switching element) of the rectifying / smoothing circuit 11 or the inverter circuit 12 is reduced, and the temperature detecting unit detects the change in the ambient temperature while mounting the temperature detecting unit Th on the same circuit board 7 as the heat generating component. It becomes possible to detect accurately by Th. That is, the light output of the discharge lamp 3 can be controlled by accurately reflecting the change in the ambient temperature of the discharge lamp 3.
[0061]
Incidentally, as shown in FIG. 11, the circuit board 7 is generally housed in a case 8 made of metal or synthetic resin. In this case, since the circuit board 7 is disposed away from the inner side surface of the case 8, the temperature detection unit Th does not contact the peripheral wall of the case 8, and the ambient temperature is difficult to be transmitted to the temperature detection unit Th. Therefore, a heat transfer member 9 made of a material having a higher heat tradition rate than the atmosphere (preferably metal) is interposed between the temperature detection unit Th and the inner side surface of the case 8, and the case 8 to the temperature detection unit Th. It is desirable to facilitate heat transfer. If this configuration is adopted, the temperature detector Th is less susceptible to the heat generated inside the case 8 such as the heat generated from the heat generating components of the rectifying and smoothing circuit 11 and the inverter circuit 12, and the ambient temperature of the discharge lamp 3 is reduced. It is possible to control the light output accurately reflecting the above.
[0062]
When two discharge lamps 3 are provided in one lamp 5 as shown in FIG. 12, two discharge lamp lighting devices 4 provided for lighting each discharge lamp 3 are connected to the lamp 5. It is desirable to arrange them on a straight line that is horizontal when attached to the construction surface. In particular, when a straight tubular discharge lamp 3 is used as in the illustrated example, the longitudinal direction of both discharge lamps 3 is the horizontal direction, and two discharge lamp lighting devices 4 are disposed between the discharge lamps 3. It is desirable to arrange along the longitudinal direction. Here, when the lamp 5 is used for illumination in the tunnel, it is arranged so that the direction of the arrow shown on the right side of FIG. Such an arrangement is particularly effective when the lamp 5 has a sealed structure. That is, since air flows in the vertical direction inside the lamp 5, a temperature distribution is generated in the vertical direction in the lamp 5, but there is little temperature distribution in the horizontal direction. Under the same temperature condition, it becomes possible to correct the light output of both discharge lamps 3 under substantially the same temperature condition.
[0063]
In order to further equalize the temperature conditions of the two discharge lamp lighting devices 4, as shown in FIG. 13, the two discharge lamp lighting devices 4 are stored side by side in one cylindrical case 8a, or as shown in FIG. Thus, what is necessary is just to fix both the discharge lamp lighting devices 4 to the one base 8b which consists of a good heat conductive material in the form couple | bonded thermally. Moreover, if the cylindrical case 8a is made into a sealed structure, the temperature conditions of the both discharge lamp lighting devices 4 can be further equalized.
[0064]
In the above-described configuration example, the temperature conditions in the two discharge lamp lighting devices 4 are equalized. However, when a plurality of discharge lamps 3 are provided in the lamp 5, the ambient temperature for each discharge lamp 3 is set. Accordingly, when the light output of each discharge lamp 3 is to be controlled, as shown in FIG. 15, each discharge lamp 3 and each discharge lamp lighting device 4 for lighting this discharge lamp 3 are arranged close to each other. Is desirable. With such an arrangement, it becomes possible to control the light output according to the ambient temperature of each discharge lamp 3.
[0065]
By the way, in general, since the light output of the discharge lamp 3 decreases as the accumulated lighting time becomes longer, if not only the light output fluctuation of the discharge lamp 3 due to the change of the ambient temperature but also the temporal change of the light output is suppressed. The oscillation control circuit 13 may be provided with timing means for measuring the cumulative lighting time and output correction means for increasing the light output of the discharge lamp as the cumulative lighting time obtained by the timing means elapses. In this configuration, for example, 70% lighting is performed while the cumulative lighting time is short, and control is performed such that the light output of the discharge lamp 3 gradually approaches 100% lighting as the cumulative lighting time elapses. Further, in each of the above-described embodiments, the power supplied to the discharge lamp 3 is controlled by controlling the on / off frequency of the switching element included in the inverter circuit 12, but by controlling the on / off duty of the switching element. The power supplied to the discharge lamp 3 may be controlled. Furthermore, the value of the light output in each of the above-described embodiments is an example, and is not limited to the combination of 100% lighting, 50% lighting, and 25% lighting, and the light output may be appropriately set according to the purpose.
[0066]
【The invention's effect】
  According to the configuration of the first aspect of the invention, the lamp is housed in a sealed structure together with the discharge lamp lighting device to constitute a lighting fixture and illuminate the same range.2 lightsSince it is possible to select multiple types of lighting patterns by combining lighting and extinction and dimming amount for each of the discharge lamps, lighting to turn on all discharge lamps when adjusting the illuminance of the range illuminated by these discharge lamps If the light output in the pattern is 100%,OneTurn off the discharge lampThe otherBy selecting the lighting pattern to dim the discharge lamp, the illuminance in the illumination area can be reduced while supplying relatively large power to the dimming discharge lamp, and the discharge lamp can be lit stably. However, low illumination is possible. As a result, even when illuminating at low illuminance, the power supplied to the discharge lamp can be made relatively large, and the change in the discharge lamp tube wall temperature is suppressed regardless of the environmental temperature of the place where the discharge lamp is installed. It is possible to make the power consumption increase / decrease accompanying temperature compensation relatively small while widening the dimming range. Also,2 lightsDimming each discharge lamp and each discharge lamp2 piecesSince the discharge lamp lighting device is housed in a lighting fixture, a desired illuminance can be obtained by selecting a lighting pattern of the discharge lamp in units of the lighting fixture, and the lamp has a sealed structure. The tube wall temperature can be kept relatively high when the lamp is lit, and temperature compensation only needs to be performed during dimming. That is, in a sealed lamp such as a lighting fixture used for tunnel lighting, if the lamp structure is designed so as to use heat generated from a discharge lamp when 100% is lit, the light output is almost dependent on temperature when 100% is lit. A design that does not change is possible.
[0067]
  And bothA lighting pattern that turns on one of the discharge lamps, a lighting pattern that lights one of the discharge lamps 100% and turns off the other discharge lamp, and dimming one of the discharge lamps and turning off the other discharge lamp The lighting pattern to be turned on can be selected. Therefore, the lighting pattern to turn on both discharge lamps at 100% is set to 100% light output, and the lighting pattern to turn on one discharge lamp at 100% and turn off the other discharge lamp is 50%. In the lighting pattern in which one discharge lamp is dimmed and the other discharge lamp is extinguished, the light output can be further reduced. That is, a configuration suitable for tunnel illumination can be provided.
[0069]
  One moreThe negative temperature thermistor is used for the temperature detector in one discharge lamp lighting device, and the positive temperature coefficient thermistor is used for the temperature detector in the other discharge lamp lighting device, combining discharge lamp lighting devices with different temperature characteristics. Thus, temperature compensation is possible in a wide temperature range.
[0070]
  Claim 2The invention ofClaim 1The dimming signal output device includes an external temperature detection unit that detects the ambient temperature, and the dimming signal output device uses a dimming pattern in which one of the discharge lamps is dimmed and the other discharge lamp is extinguished by the external temperature detection unit. If the detected ambient temperature is less than or equal to the specified threshold, the discharge lamp is dimmed with a discharge lamp lighting device equipped with a negative characteristic thermistor, and if the ambient temperature detected by the external temperature detector is greater than or equal to the specified threshold, it is positive. The discharge lamp is dimmed by a discharge lamp lighting device equipped with a characteristic thermistor. When the discharge lamp is dimmed, the tube wall temperature is lower than when 100% is lit. Compensate the optical output over a wide temperature range by compensating the optical output and changing the temperature compensation characteristics on the high temperature side and low temperature side with respect to the specified temperature. Possible to become.
[0071]
  Claim 3The invention of claim 1Or claim 2A discharge lamp lighting device used in the illumination system according to claim 1, wherein the power supplied from the dimming signal output device is converted into high frequency power by turning on and off the switching element, and a high frequency AC voltage is applied to the discharge lamp through an LC resonance circuit And an oscillation control circuit for controlling on / off of a switching element provided in the inverter circuit. The oscillation control circuit includes a temperature detection unit and a compensation circuit that changes the output of the inverter circuit according to the detected temperature. In this configuration, the on / off frequency of the switching element by the oscillation control circuit is changed in accordance with the ambient temperature of the discharge lamp, so that temperature compensation is possible with a simple configuration.
[0072]
  Claim 4The invention ofClaim 3In this invention, a rectifying / smoothing circuit for rectifying and smoothing the power source is provided, and a temperature detection unit is disposed at a portion between the rectifying / smoothing circuit and the inverter circuit. The influence of heat on the detector can be relatively reduced, and the light output of the discharge lamp can be controlled by accurately reflecting the change in the ambient temperature of the discharge lamp.
[0073]
  Claim 5The invention ofClaim 3 or claim 4In this invention, the temperature detection unit is connected to the case via a heat transfer member made of a material having a higher thermal conductivity than the atmosphere, and the temperature detection unit is affected by the heat generated inside the case. This makes it possible to control the light output that accurately reflects the ambient temperature of the discharge lamp.
[0074]
  Claim 6The invention ofClaim 3In the invention, the oscillation control circuit includes a clocking means for timing the cumulative lighting time, and a light output of the discharge lamp as the cumulative lighting time obtained by the clocking means suppresses a temporal change in the light output of the discharge lamp. Output correction means for increasing the discharge lamp, and not only fluctuations in the light output of the discharge lamp due to changes in the ambient temperature, but also temporal changes in the light output of the discharge lamp can be suppressed, resulting in an illumination space. The change in brightness can be reduced.
[0075]
  Claim 7The invention ofClaim 3In this invention, since dimming by the dimming signal is multi-stage dimming, dimming control is simple.
[0076]
  Claim 8The invention ofClaim 3In this invention, since the dimming by the dimming signal is continuous dimming, the light output can be finely adjusted.
[0077]
  Claim 9The invention ofClaims 3 to 8In this invention, the compensation circuit operates when dimming is instructed by the dimming signal, and when 100% is lit and the tube wall temperature is relatively high, the influence of the environmental temperature is small, so temperature compensation By performing temperature compensation only when the light is lit and the tube wall temperature is relatively low, an increase in power consumption accompanying temperature compensation is suppressed.
[0078]
  Claim 10The invention ofClaims 3 to 8In the present invention, since the compensation circuit is operated when the temperature detected by the temperature detection unit is equal to or lower than the prescribed threshold, the power consumption accompanying the temperature compensation is increased by performing the temperature compensation only when the tube wall temperature is relatively low. Will be suppressed.
[0079]
  Claim 11The invention ofClaims 3 to 8In the invention, since the compensation circuit is operated when the temperature detected by the temperature detection unit is equal to or lower than the specified threshold and the discharge lamp is dimmed, temperature compensation is performed only when the tube wall temperature is relatively low by dimming. An increase in power consumption accompanying temperature compensation is suppressed.
[0082]
  Claim 12The invention of claim 1Or claim 2A lighting fixture for use in the lighting system according to claim 1, wherein the lamp is provided with two discharge lamp lighting devices and two discharge lamps, and both discharge lamp lighting devices are in a horizontal direction when the lamp is mounted on the construction surface. Because it is arranged on the line, both discharge lamp lighting devices can be kept under almost the same temperature conditions without being affected by the temperature distribution in the lamp, and as a result, both discharge lamps can be controlled under the same temperature conditions. Can do.
[0083]
  Claim 13The invention ofClaim 12In this invention, since both discharge lamp lighting devices are housed in one cylindrical case, the temperature difference between both discharge lamp lighting devices is small, and the temperature conditions of both discharge lamp lighting devices can be made closer.
[0084]
  The invention of claim 14Claim 13In the invention, since the cylindrical case is sealed, the internal temperature of the cylindrical case becomes uniform, the temperature difference between the two discharge lamp lighting devices is further reduced, and the temperature conditions of the two discharge lamp lighting devices are made closer. be able to.
[0085]
  Claim 15The invention ofClaim 14In this invention, since both the discharge lamp lighting devices are fixed in a thermally coupled form to a pedestal made of a highly heat conductive material, both the discharge lamp lighting devices are thermally coupled via the pedestal, The temperature difference between the discharge lamp lighting devices is reduced, and the temperature conditions of both discharge lamp lighting devices can be made closer.
[0086]
  Claim 16The invention of claim 1Or claim 2The discharge lamp and the discharge lamp lighting device for lighting the discharge lamp are arranged close to each other, so that the light output reflecting the ambient temperature for each discharge lamp is provided. Control becomes possible.
[Brief description of the drawings]
[Figure 1]Basic configurationFIG.
FIG. 2 is a block diagram showing a discharge lamp lighting device used in the above.
FIG. 3 is a circuit diagram showing an oscillation control circuit used in the above.
FIG. 4 is a circuit diagram showing a temperature detection unit used in the above.
FIG. 5 shows the present invention.Embodiment 1It is a circuit diagram which shows the temperature detection part used for.
FIG. 6 is an operation explanatory view of the above.
[Fig. 7] of the present invention.Embodiment 2It is a circuit diagram which shows the principal part of the oscillation control circuit used for FIG.
FIG. 8 is an operation explanatory view of the above.
FIG. 9 shows the present invention.Embodiment 3FIG.
FIG. 10 is a schematic configuration diagram showing an arrangement example of a temperature detection unit in the present invention.
FIG. 11 is a schematic configuration diagram showing another arrangement example of the temperature detection unit in the present invention.
FIG. 12 is a schematic configuration diagram showing an arrangement example of a discharge lamp lighting device according to the present invention.
FIG. 13 is a schematic configuration diagram showing another arrangement example of the discharge lamp lighting device according to the present invention.
FIG. 14 is a schematic configuration diagram showing another arrangement example of the discharge lamp lighting device according to the present invention.
FIG. 15 is a schematic configuration diagram showing still another arrangement example of the discharge lamp lighting device according to the present invention.
FIG. 16 is a block diagram showing a conventional example.
FIG. 17 is an operation explanatory view of the above.
FIG. 18 is a circuit diagram of an oscillation control circuit used in a conventional example.
[Explanation of symbols]
  1 lighting equipment
  3 discharge lamp
  4 discharge lamp lighting device
  6 Dimming signal output device
  7 Circuit board
  8 cases
  8a Tubular case
  8b pedestal
  9 Heat transfer member
  10 External temperature detector
  12 Inverter circuit
  13 Oscillation control circuit
  CL compensation circuit
  Rt temperature sensor
  Rt1 Temperature sensor (Negative thermistor)
  Rt2 temperature sensor (positive temperature coefficient thermistor)
  Th temperature detector

Claims (16)

Two discharge lamps that illuminate the same area, and a discharge lamp lighting device that constitutes a lighting fixture by being housed in a hermetically sealed lamp together with the two discharge lamps. Two discharge lamp lighting devices capable of dimming each discharge lamp in accordance with the dimming signal from the light source, and a dimming signal to be given to each discharge lamp lighting device, and instructing lighting and extinguishing of each discharge lamp And a dimming signal output device that selects a plurality of types of lighting patterns based on a combination of lighting and extinction of each discharge lamp and dimming amount, and the dimming signal output device is lit to turn on both discharge lamps 100%. Select a pattern, a lighting pattern in which one of the discharge lamps is turned on 100% and the other discharge lamp is turned off, and a lighting pattern in which one of the discharge lamps is dimmed and the other discharge lamp is turned off. An ability with a negative temperature coefficient thermistor One of the discharge lamp lighting device for detecting the ambient temperature of the lamp discharge as a temperature detection unit, and the other discharge lamp lighting device temperature detecting the positive characteristic thermistor to detect the ambient temperature of the discharge lamp The illumination system is characterized in that the dimming amount is corrected so as to suppress a change in the light output of the discharge lamp with respect to a change in temperature detected by the temperature detection unit. An external temperature detection unit for detecting an ambient temperature is provided, and the dimming signal output device is detected by the external temperature detection unit in a lighting pattern in which one of the discharge lamps is dimmed and the other discharge lamp is extinguished. If the ambient temperature is below a specified threshold, the discharge lamp lighting device is equipped with a negative characteristic thermistor to dimm the discharge lamp, and if the ambient temperature detected by the external temperature detector is above the specified threshold, the positive thermistor The illumination system according to claim 1, wherein the discharge lamp is dimmed by a discharge lamp lighting device provided . The discharge lamp lighting device used in the illumination system according to claim 1 or 2, wherein the power supplied from the dimming signal output device is converted into high frequency power by turning on and off a switching element, and the power is supplied through an LC resonance circuit. An inverter circuit for applying a high-frequency AC voltage to the discharge lamp and an oscillation control circuit for controlling on / off of a switching element provided in the inverter circuit, the oscillation control circuit including the temperature detection unit and detecting the output of the inverter circuit A discharge lamp lighting device comprising: a compensation circuit that changes in accordance with the above. The discharge lamp lighting device according to claim 3, further comprising a rectifying / smoothing circuit that rectifies and smoothes the power supply, wherein the temperature detection unit is disposed at a portion between the rectifying / smoothing circuit and the inverter circuit. The discharge lamp lighting device according to claim 3 or 4, wherein the temperature detection unit is connected to the case via a heat transfer member made of a material having a higher thermal conductivity than the atmosphere. The oscillation control circuit measures the cumulative lighting time, and increases the light output of the discharge lamp with the lapse of the cumulative lighting time obtained by the timing means so as to suppress the temporal change of the light output of the discharge lamp. The discharge lamp lighting device according to claim 3, further comprising: an output correction unit that causes the output to be corrected . 4. The discharge lamp lighting device according to claim 3, wherein dimming by the dimming signal is multi-stage dimming . 4. The discharge lamp lighting device according to claim 3, wherein dimming by the dimming signal is continuous dimming . 9. The discharge lamp lighting device according to claim 3, wherein the compensation circuit operates when dimming is instructed by the dimming signal . The discharge lamp lighting device according to any one of claims 3 to 8, wherein the compensation circuit is operated when a temperature detected by the temperature detection unit is equal to or lower than a prescribed threshold value . The discharge according to any one of claims 3 to 8, wherein the compensation circuit is operated when a temperature detected by the temperature detection unit is equal to or less than a prescribed threshold value and the discharge lamp is dimmed. Electric light lighting device. It is a lighting fixture used for the lighting system of Claim 1 or Claim 2, Comprising: The said discharge lamp lighting device and the said two discharge lamps are each provided in the said lamp, and both discharge lamp lighting A lighting apparatus, wherein the apparatus is arranged on a straight line that is horizontal when the lamp is mounted on the construction surface. The lighting apparatus according to claim 12, wherein the both discharge lamp lighting devices are accommodated in a single cylindrical case. The lighting apparatus according to claim 13, wherein the cylindrical case is hermetically sealed. The lighting apparatus according to claim 14, wherein the both discharge lamp lighting devices are fixed in a form thermally coupled to a pedestal made of a highly heat conductive material . It is a lighting fixture used for the illumination system of Claim 1 or Claim 2, Comprising: The said discharge lamp and the said discharge lamp lighting device which lights the said discharge lamp are arrange | positioned mutually close, The illumination characterized by the above-mentioned. vessel equipment.

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