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JP5750592B2 - LIGHTING DEVICE AND LIGHTING APPARATUS USING THE LIGHTING DEVICE - Google Patents

LIGHTING DEVICE AND LIGHTING APPARATUS USING THE LIGHTING DEVICE Download PDF

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JP5750592B2
JP5750592B2 JP2011060117A JP2011060117A JP5750592B2 JP 5750592 B2 JP5750592 B2 JP 5750592B2 JP 2011060117 A JP2011060117 A JP 2011060117A JP 2011060117 A JP2011060117 A JP 2011060117A JP 5750592 B2 JP5750592 B2 JP 5750592B2
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lighting
light source
voltage
turn
intermittent
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JP2012195252A (en
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明 中城
明 中城
城戸 大志
大志 城戸
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Panasonic Intellectual Property Management Co Ltd
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B20/00Energy efficient lighting technologies, e.g. halogen lamps or gas discharge lamps
    • Y02B20/40Control techniques providing energy savings, e.g. smart controller or presence detection

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Description

本発明は、照明装置及び該照明装置を用いた照明器具に関するものである。   The present invention relates to a lighting device and a lighting fixture using the lighting device.

従来から、光源を間欠点灯させる際のオンデューティを変更することで光源の光出力(光束の時間平均値であり、単位時間当りの光量)を変更可能な照明装置が提供されている(例えば、特許文献1参照)。上記の間欠点灯の周波数は、光源の点滅が人の目に認識できない程度に充分に高い周波数とされる。   Conventionally, there has been provided an illumination device that can change the light output of the light source (the time average value of the luminous flux, the amount of light per unit time) by changing the on-duty when the light source is intermittently lit (for example, Patent Document 1). The frequency of the intermittent lighting is set to a sufficiently high frequency that the blinking of the light source cannot be recognized by human eyes.

上記のような照明装置において、光源として、例えば有機EL素子や発光ダイオード素子のように、直流電力によって点灯されるものが用いられる場合、光源に入力される電圧(以下、「負荷電圧」と呼ぶ。)Vxと光源に入力される電流(以下、「負荷電流」と呼ぶ。)電流Ixとはそれぞれ図13に示すような矩形波となる。   In the illumination device as described above, when a light source that is lit by DC power, such as an organic EL element or a light emitting diode element, is used as a light source, a voltage input to the light source (hereinafter referred to as a “load voltage”). .) Vx and the current (hereinafter referred to as “load current”) current Ix input to the light source are rectangular waves as shown in FIG.

従来は、上記の間欠点灯中、光源が点灯される期間(以下、「オン期間」と呼ぶ。)T2には負荷電圧Vxは光源が点灯する程度に高い一定値とされ、光源が消灯される期間(以下、「オフ期間」と呼ぶ。)T1には負荷電圧Vxは0Vにされていた。   Conventionally, during the intermittent lighting, the load voltage Vx is set to a constant value high enough to turn on the light source during a period (hereinafter referred to as “on period”) T2 during which the light source is turned on, and the light source is turned off. During the period (hereinafter referred to as “off period”) T1, the load voltage Vx was set to 0V.

特開2007−265805号公報JP 2007-265805 A

しかしながら、上記のようにオフ期間T1に負荷電圧Vxを0Vとする場合、オン期間T2の開始直後には突入電流により負荷電流Ixが比較的に大きくなることで、光源にかかる電気的なストレスが比較的に大きくなりやすい。上記の突入電流としては、例えば、光源の容量成分を充電する充電電流がある。   However, when the load voltage Vx is set to 0 V during the off period T1 as described above, the load current Ix becomes relatively large due to the inrush current immediately after the start of the on period T2, so that the electrical stress applied to the light source is reduced. It tends to be relatively large. Examples of the inrush current include a charging current for charging a capacitance component of the light source.

本発明は、上記事由に鑑みて為されたものであり、その目的は、間欠点灯時に光源にかかる電気的なストレスが抑えられる照明装置及び該照明装置を用いた照明器具を提供することにある。   The present invention has been made in view of the above-described reasons, and an object thereof is to provide an illuminating device that can suppress electrical stress applied to a light source during intermittent lighting and a luminaire using the illuminating device. .

本発明の照明装置は、直流電圧を入力されて点灯される光源と、前記光源を間欠点灯させる間欠点灯動作が可能な点灯部とを備え、前記点灯部は、前記間欠点灯動作において前記光源を消灯させる期間中にも、前記光源を点灯させる際に出力される点灯用電圧と同じ向きの消灯用電圧であって前記光源に電流が流れない程度に低い消灯用電圧を出力し、前記点灯部は、前記間欠点灯動作において前記光源を点灯させる期間の継続時間を可変とするものであって、前記間欠点灯動作において前記光源を点灯させる期間の継続時間が短いほど、前記消灯用電圧を高くすることを特徴とする。
また、本発明の別の照明装置は、直流電圧を入力されて点灯される光源と、前記光源を間欠点灯させる間欠点灯動作が可能な点灯部とを備え、前記点灯部は、前記間欠点灯動作において前記光源を消灯させる期間中にも、前記光源を点灯させる際に出力される点灯用電圧と同じ向きの消灯用電圧であって前記光源に電流が流れない程度に低い消灯用電圧を出力し、前記点灯部は、前記間欠点灯動作において前記光源を点灯させる期間中に前記光源に出力する点灯用電圧を可変とするものであって、前記点灯用電圧が低いほど、前記消灯用電圧を低くすることを特徴とする。
また、本発明のさらに別の照明装置は、直流電圧を入力されて点灯される光源と、前記光源を間欠点灯させる間欠点灯動作が可能な点灯部とを備え、前記点灯部は、前記間欠点灯動作において前記光源を消灯させる期間中にも、前記光源を点灯させる際に出力される点灯用電圧と同じ向きの消灯用電圧であって前記光源に電流が流れない程度に低い消灯用電圧を出力し、前記点灯部は、前記間欠点灯の周期を可変とするものであって、前記間欠点灯の周期が長いほど、前記消灯用電圧を低くすることを特徴とする。
また、本発明の別の照明装置は、直流電圧を入力されて点灯される光源と、前記光源を間欠点灯させる間欠点灯動作が可能な点灯部とを備え、前記点灯部は、前記間欠点灯動作において前記光源を消灯させる期間中にも、前記光源を点灯させる際に出力される点灯用電圧と同じ向きの消灯用電圧であって前記光源に電流が流れない程度に低い消灯用電圧を出力し、前記光源は1個以上の発光素子からなり、前記光源を構成する発光素子の個数は可変であって、前記点灯部の出力端間に接続された発光素子の個数を検出する個数検出手段を備え、前記点灯部は、前記個数検出手段によって検出された発光素子の個数が少ないほど、前記消灯用電圧を低くすることを特徴とする。
また、本発明のさらに別の照明装置は、直流電圧を入力されて点灯される光源と、前記光源を間欠点灯させる間欠点灯動作が可能な点灯部とを備え、前記点灯部は、前記間欠点灯動作において前記光源を消灯させる期間中にも、前記光源を点灯させる際に出力される点灯用電圧と同じ向きの消灯用電圧であって前記光源に電流が流れない程度に低い消灯用電圧を出力し、前記光源の点灯開始直後における前記点灯部の出力電流の一時的な上昇幅を検出するサージ検出手段を備え、前記点灯部は、前記サージ検出手段によって検出された前記上昇幅を所定範囲内に収めるように、前記消灯用電圧を随時変更することを特徴とする。
The illumination device of the present invention includes a light source that is turned on when a DC voltage is input, and a lighting unit that is capable of intermittent lighting operation for intermittently lighting the light source, and the lighting unit turns the light source on in the intermittent lighting operation. also during the period to turn off, and outputs a low off voltage to the extent that no current flows to the light source a off voltage in the same direction as the lighting voltage which is output when turning on the light source, the lighting unit Is a variable duration of the period during which the light source is turned on in the intermittent lighting operation, and the turn-off voltage is increased as the duration of the period during which the light source is turned on in the intermittent lighting operation is shorter. It is characterized by that.
In addition, another lighting device of the present invention includes a light source that is turned on when a DC voltage is input, and a lighting unit that is capable of intermittent lighting operation for intermittently lighting the light source, and the lighting unit is configured to perform the intermittent lighting operation. In the period during which the light source is turned off, a turn-off voltage in the same direction as the turn-on voltage output when turning on the light source is output so as to prevent current from flowing through the light source. The lighting unit is configured to change a lighting voltage output to the light source during a period in which the light source is turned on in the intermittent lighting operation. The lower the lighting voltage, the lower the turn-off voltage. It is characterized by doing.
Furthermore, another illumination device of the present invention includes a light source that is turned on when a DC voltage is input, and a lighting unit that can perform an intermittent lighting operation of intermittently lighting the light source, and the lighting unit includes the intermittent lighting. Even during a period in which the light source is turned off during operation, a turn-off voltage in the same direction as the turn-on voltage output when turning on the light source, and a turn-off voltage that is low enough to prevent current from flowing through the light source is output. And the said lighting part makes the period of the said intermittent lighting variable, Comprising: The said voltage for light extinction is made low, so that the period of the said intermittent lighting is long.
In addition, another lighting device of the present invention includes a light source that is turned on when a DC voltage is input, and a lighting unit that is capable of intermittent lighting operation for intermittently lighting the light source, and the lighting unit is configured to perform the intermittent lighting operation. In the period during which the light source is turned off, a turn-off voltage in the same direction as the turn-on voltage output when turning on the light source is output so as to prevent current from flowing through the light source. The light source comprises one or more light emitting elements, the number of light emitting elements constituting the light source is variable, and a number detecting means for detecting the number of light emitting elements connected between the output terminals of the lighting unit. And the lighting unit lowers the turn-off voltage as the number of light emitting elements detected by the number detecting means is smaller.
Furthermore, another illumination device of the present invention includes a light source that is turned on when a DC voltage is input, and a lighting unit that can perform an intermittent lighting operation of intermittently lighting the light source, and the lighting unit includes the intermittent lighting. Even during a period in which the light source is turned off during operation, a turn-off voltage in the same direction as the turn-on voltage output when turning on the light source, and a turn-off voltage that is low enough to prevent current from flowing through the light source is output. And a surge detection means for detecting a temporary rise width of the output current of the lighting section immediately after the lighting of the light source is started, and the lighting section keeps the rise width detected by the surge detection means within a predetermined range. The turn-off voltage is changed at any time so as to fit in

また、上記の照明装置において、前記点灯部は、前記消灯用電圧を前記光源に対して連続的に出力する消灯時電源と、前記点灯用電圧を前記光源に対して間欠的に出力する点灯時電源とを有していてもよい。   Further, in the above illumination device, the lighting unit includes a power source during extinguishing that continuously outputs the voltage for extinguishing to the light source, and a lighting unit that intermittently outputs the voltage for lighting to the light source. You may have a power supply.

さらに、上記の照明装置において、前記点灯時電源は、前記間欠点灯動作において前記光源が点灯される期間中には出力電流を一定とするものであってもよい。   Furthermore, in the above-described lighting device, the lighting power source may make the output current constant during a period in which the light source is turned on in the intermittent lighting operation.

または、上記の照明装置において、前記点灯部は、出力電圧を切替え可能な1個のスイッチング電源からなるものであってもよい。   Alternatively, in the illumination device described above, the lighting unit may include a single switching power supply that can switch an output voltage.

さらに、上記の照明装置において、前記光源は1個以上の有機EL素子を有していてもよい。   Furthermore, in the above illumination device, the light source may include one or more organic EL elements.

本発明の照明器具は、上記いずれかの照明装置と、前記照明装置を保持する器具本体とを備えることを特徴とする。   The lighting fixture of the present invention includes any one of the lighting devices described above and a fixture main body that holds the lighting device.

本発明によれば、間欠点灯動作において光源が消灯される期間中に消灯用電圧によって光源の容量成分が予め充電されるので、光源が消灯される期間中に光源に電圧が出力されない場合に比べ、光源の点灯開始時の突入電流が抑えられ、光源にかかる電気的なストレスが抑えられる。   According to the present invention, since the capacitance component of the light source is charged in advance by the extinguishing voltage during the period when the light source is extinguished in the intermittent lighting operation, compared with a case where no voltage is output to the light source during the period when the light source is extinguished. Inrush current at the start of lighting of the light source is suppressed, and electrical stress applied to the light source is suppressed.

本発明における負過電圧Vxと負荷電流Ixとの波形の例を示す説明図である。It is explanatory drawing which shows the example of the waveform of the negative overvoltage Vx and the load current Ix in this invention. 同上を示す回路ブロック図である。It is a circuit block diagram which shows the same as the above. 同上における負過電圧Vxと負荷電流Ixとの関係の一例を示す説明図である。It is explanatory drawing which shows an example of the relationship between the negative overvoltage Vx and load current Ix in the same as the above. 同上における消灯時電源の出力電圧Vaと点灯時電源の出力電圧Vbと負過電圧Vxとの波形の例を示す説明図である。It is explanatory drawing which shows the example of the waveform of the output voltage Va of the light source at the time of light extinction, the output voltage Vb of the power source at the time of lighting, and the negative overvoltage Vx in the above. 同上の変更例を示す回路ブロック図である。It is a circuit block diagram which shows the example of a change same as the above. 同上の別の変更例の要部を示す回路ブロック図である。It is a circuit block diagram which shows the principal part of another example of a change same as the above. 同上の更に別の変更例を示す回路ブロック図である。It is a circuit block diagram which shows another example of a change same as the above. (a)(b)はそれぞれ同上の別の変更例の光源を示す回路ブロック図であり、(a)は発光素子が4個接続された状態を示し、(b)は発光素子が3個接続された状態を示す。(A) (b) is a circuit block diagram which shows the light source of another modified example same as the above, (a) shows the state where four light emitting elements are connected, (b) shows the connection of three light emitting elements. Indicates the state that has been performed. 同上の更に別の変更例の光源を示す回路ブロック図である。It is a circuit block diagram which shows the light source of another modified example same as the above. (a)(b)はそれぞれ同上の別の変更例における負過電圧Vxと負荷電流Ixとの波形の例を示し、(b)は(a)よりもオン期間T2の継続時間がより長くされた状態での波形を示す。(A) (b) shows the example of the waveform of the negative overvoltage Vx and the load current Ix in another modification example same as the above, respectively, (b), the duration of the ON period T2 is made longer than (a). The waveform in the state is shown. (a)(b)はそれぞれ同上の更に別の変更例における負過電圧Vxと負荷電流Ixとの波形の例を示し、(b)は(a)よりも消灯用電圧V1がより低くされた状態での波形を示す。(A) (b) shows the example of the waveform of the negative overvoltage Vx and the load current Ix in another modification example same as the above, respectively, (b) is a state in which the turn-off voltage V1 is made lower than (a) The waveform at is shown. 同上を用いた照明器具の一例を示す分解斜視図である。It is a disassembled perspective view which shows an example of the lighting fixture using the same as the above. 従来例における負過電圧Vxと負荷電流Ixとの波形の例を示す説明図である。It is explanatory drawing which shows the example of the waveform of the negative overvoltage Vx and the load current Ix in a prior art example.

以下、本発明を実施するための最良の形態について、図面を参照しながら説明する。   The best mode for carrying out the present invention will be described below with reference to the drawings.

本実施形態の照明装置は、図2に示すように、直流電力によって点灯される光源1を点灯させるものである。このような光源1としては、例えば発光ダイオード素子や有機EL素子などの発光素子、又は、このような発光素子が複数個接続された発光ダイオードアレイや有機ELアレイを用いることができる。   As shown in FIG. 2, the illumination device of the present embodiment lights a light source 1 that is turned on by DC power. As such a light source 1, for example, a light emitting element such as a light emitting diode element or an organic EL element, or a light emitting diode array or an organic EL array in which a plurality of such light emitting elements are connected can be used.

ここで、光源1に入力される負荷電圧Vxと光源1に流れる負荷電流Ixとの関係を図3に示す。図3を見てもわかるように、光源1は、負荷電圧Vxが所定の電圧(いわゆるターンオン電圧)Von未満であれば負荷電流Ixが流れず点灯しない。   Here, the relationship between the load voltage Vx input to the light source 1 and the load current Ix flowing through the light source 1 is shown in FIG. As can be seen from FIG. 3, if the load voltage Vx is less than a predetermined voltage (so-called turn-on voltage) Von, the load current Ix does not flow and does not light up.

そして、本実施形態は、光源1が点灯しない程度の電圧(以下、「消灯用電圧」と呼ぶ。)V1を連続的に光源1に出力する消灯時電源21と、光源1が点灯する程度の電圧(以下、「点灯用電圧」と呼ぶ。)V2を間欠的に光源1に出力する間欠点灯動作が可能な点灯時電源22とを備える。すなわち、本実施形態における点灯部2は、消灯時電源21と点灯時電源22とを備える。消灯用電圧V1はすなわちターンオン電圧Vonよりも低い正の(つまり光源1を点灯する電圧と同じ向きの)電圧であり、点灯用電圧V2はすなわちターンオン電圧Vonよりも高い電圧(例えば光源1の定格電圧)である。消灯時電源21と点灯時電源22とはそれぞれ逆流防止用のダイオードD1,D2を介して光源1に接続されている。つまり、消灯時電源21の出力電圧Vaと点灯時電源22の出力電圧Vbとのうち、より高い一方が光源1に入力されて負荷電圧Vxとなる。消灯時電源21の出力電圧Vaと点灯時電源22の出力電圧Vbと負過電圧Vxとの波形の例を図4に示す。 In the present embodiment, the power source 21 at the time of turn-off that continuously outputs a voltage V1 at which the light source 1 is not turned on (hereinafter referred to as “light-off voltage”) V1 to the light source 1 and the light source 1 are turned on. A lighting power source 22 capable of intermittent lighting operation for intermittently outputting a voltage (hereinafter referred to as “lighting voltage”) V2 to the light source 1 is provided. In other words, the lighting unit 2 in the present embodiment includes a power supply 21 when turned off and a power supply 22 when turned on. The turn-off voltage V1 is a positive voltage that is lower than the turn-on voltage Von (that is, the same direction as the voltage that turns on the light source 1), and the turn-on voltage V2 is a voltage that is higher than the turn-on voltage Von (for example, the rating of the light source 1). Voltage). The off-time power supply 21 and the on-time power supply 22 are connected to the light source 1 via backflow prevention diodes D1 and D2, respectively. In other words, the higher one of the output voltage Va of the power supply 21 when turned off and the output voltage Vb of the power supply 22 when turned on is input to the light source 1 and becomes the load voltage Vx. FIG. 4 shows an example of waveforms of the output voltage Va of the power supply 21 when turned off, the output voltage Vb of the power supply 22 when turned on, and the negative overvoltage Vx.

さらに、本実施形態は、外部の交流電源3から入力された交流電力を全波整流するダイオードブリッジ4と、このダイオードブリッジ4の直流出力を平滑化するコンデンサC0とを有する。   Furthermore, the present embodiment includes a diode bridge 4 that full-wave rectifies AC power input from an external AC power supply 3 and a capacitor C0 that smoothes the DC output of the diode bridge 4.

点灯時電源22は、ダイオードブリッジ4の直流出力がコンデンサC0によって平滑化された直流電力の電圧値を変換する電圧変換回路23と、電圧変換回路23から光源1への給電をオンオフするスイッチQ1と、スイッチQ1を駆動する駆動回路24とを有する。スイッチQ1としては周知の半導体スイッチを用いることができる。また、電圧変換回路23としては例えばバックコンバータ(降圧チョッパ回路)のような周知のスイッチング電源を用いることができる。   The lighting power source 22 includes a voltage conversion circuit 23 that converts the voltage value of DC power obtained by smoothing the DC output of the diode bridge 4 by the capacitor C0, and a switch Q1 that turns on and off the power supply from the voltage conversion circuit 23 to the light source 1. And a drive circuit 24 for driving the switch Q1. A known semiconductor switch can be used as the switch Q1. As the voltage conversion circuit 23, for example, a known switching power supply such as a buck converter (step-down chopper circuit) can be used.

すなわち、駆動回路24がスイッチQ1を繰り返しオンオフ駆動することで、光源1が間欠点灯する。さらに、本実施形態は、光源1に直列に接続された抵抗Rdと抵抗Rdの両端電圧を増幅した電圧(つまり負荷電流Ixに応じた電圧)駆動回路24に入力する増幅回路とからなる電流検出部25を有する。駆動回路24は、電流検出部25から入力された電圧に応じて、負荷電流Ixの時間平均値を所定の目標値とするようなオンデューティでスイッチQ1をオンオフ駆動する。上記のような駆動回路24は例えばマイコンを用いて周知技術で実現可能であるので、詳細な図示並びに説明は省略する。 That is, the light source 1 is intermittently lit by the drive circuit 24 repeatedly driving the switch Q1 on and off. Further, in the present embodiment, a current composed of a resistor Rd connected in series to the light source 1 and an amplification circuit that inputs a voltage obtained by amplifying the voltage across the resistor Rd (that is, a voltage corresponding to the load current Ix) to the drive circuit 24. A detection unit 25 is included. The drive circuit 24 drives the switch Q1 on and off with an on-duty such that the time average value of the load current Ix is set to a predetermined target value in accordance with the voltage input from the current detection unit 25. Since the drive circuit 24 as described above can be realized by a well-known technique using, for example, a microcomputer, detailed illustration and description thereof are omitted.

消灯時電源21としては、電池を用いてもよいし、周知のスイッチング電源を用いてもよい。消灯時電源21としてスイッチング電源が用いられる場合、消灯用電圧V1の変更が可能となる。また、消灯時電源21としてスイッチング電源が用いられる場合、点灯時電源22と消灯時電源21とで電源を共用としてもよいし、消灯時電源21用の電源は点灯時電源22の電源とは別途としてもよい。   As the light source 21 at the time of extinguishing, a battery or a known switching power source may be used. When a switching power supply is used as the power supply 21 at the time of extinguishing, it is possible to change the extinguishing voltage V1. Further, when a switching power supply is used as the off-time power supply 21, the lighting power supply 22 and the unlit power supply 21 may share power, and the power supply for the unlit power supply 21 is separate from the power supply of the lighting power supply 22. It is good.

上記構成によれば、図1に示すように、光源1が消灯されるオフ期間T1中にも消灯用電圧V1だけの負過電圧Vxが確保され、これによって光源1の容量成分は予め充電されるので、オフ期間T1中に負過電圧Vxが0Vとされる場合に比べ、オン期間T2の開始時の突入電流が抑えられ、従って光源1にかかる電気的なストレスが抑えられる。特に、光源1が有機EL素子を有する場合、光源1の容量成分が比較的に大きくなるので、上記の効果も比較的に大きくなる。   According to the above configuration, as shown in FIG. 1, the negative overvoltage Vx corresponding to the extinguishing voltage V1 is ensured even during the off period T1 when the light source 1 is extinguished, whereby the capacitance component of the light source 1 is charged in advance. Therefore, compared with the case where the negative overvoltage Vx is set to 0 V during the off period T1, the inrush current at the start of the on period T2 is suppressed, and thus the electrical stress applied to the light source 1 is suppressed. In particular, when the light source 1 includes an organic EL element, the above-mentioned effect is also relatively large because the capacitance component of the light source 1 is relatively large.

ところで、オン期間T2の開始時の突入電流を抑える方法としては、光源1への給電路に限流抵抗やインダクタを挿入するという方法もある。しかしながら、光源1への給電路に限流抵抗を挿入した場合、光源1の点灯中には、限流抵抗による電力損失が継続して発生してしまう。また、光源1への給電路にインダクタを挿入した場合、そのインダクタの時定数により、負過電圧Vxの立上がりや立下りが鈍くなり、これによって、間欠点灯のオンデューティT2/(T1+T2)と光源1の光出力との間の比例関係が損なわれ、光源1の光出力の厳密な制御が困難となる可能性がある。本実施形態では、光源1への給電路に限流抵抗を挿入する場合に比べて電力損失を低減することができ、また、光源1への給電路にインダクタを挿入する場合に比べて光源1の光出力の厳密な制御を容易とすることができる。   By the way, as a method of suppressing the inrush current at the start of the ON period T2, there is a method of inserting a current limiting resistor or an inductor in the power supply path to the light source 1. However, when a current limiting resistor is inserted into the power supply path to the light source 1, power loss due to the current limiting resistor continuously occurs while the light source 1 is turned on. In addition, when an inductor is inserted into the power supply path to the light source 1, the rise and fall of the negative overvoltage Vx becomes dull due to the time constant of the inductor. There is a possibility that the proportional relationship between the light output of the light source 1 and the light output of the light source 1 may be impaired, and it becomes difficult to strictly control the light output of the light source 1. In the present embodiment, the power loss can be reduced as compared with the case where a current limiting resistor is inserted in the power supply path to the light source 1, and the light source 1 is compared with the case where an inductor is inserted in the power supply path to the light source 1. Strict control of the light output can be facilitated.

なお、駆動回路24は上記のようなものに限られず、例えば図5に示すように、外部から入力される矩形波状の調光信号に連動してスイッチQ1をオンオフ駆動するものであってもよい。上記の調光信号は光源1の光出力を指示するものであって、指示する光出力が高いほどオンデューティを高くされている。図5の駆動回路24は、フォトカプラPCにより入出力間の絶縁を達成するとともに、Hレベルの電圧値が所定の電圧Vccとされた矩形波状の駆動信号VgでスイッチQ1を駆動するものである。   The drive circuit 24 is not limited to the above, and for example, as shown in FIG. 5, the switch Q1 may be driven to turn on / off in conjunction with a rectangular-wave dimming signal input from the outside. . The dimming signal indicates the light output of the light source 1, and the higher the indicated light output, the higher the on-duty. The drive circuit 24 shown in FIG. 5 achieves insulation between input and output by the photocoupler PC, and drives the switch Q1 with a rectangular-wave drive signal Vg having an H level voltage value set to a predetermined voltage Vcc. .

また、図5の例では、電流検出部25の出力は電圧変換回路23に入力されており、電圧変換回路23は、オン期間T2中には、電流検出部25の出力を用い、負荷電流Ixを一定に維持するようにフィードバック動作する。つまり、点灯部2は、光源1が点灯される期間であるオン期間T2中には、負荷電流(すなわち光源1への出力電流)Ixを一定とする。   In the example of FIG. 5, the output of the current detection unit 25 is input to the voltage conversion circuit 23. The voltage conversion circuit 23 uses the output of the current detection unit 25 during the ON period T2, and the load current Ix The feedback operation is performed so as to keep the constant. That is, the lighting unit 2 keeps the load current (that is, the output current to the light source 1) Ix constant during the on period T2, which is a period during which the light source 1 is lit.

さらに、図5の例では、光源1は、4個の発光素子11の直列回路からなる。各発光素子11としてはそれぞれ例えば有機EL素子を用いることができる。   Further, in the example of FIG. 5, the light source 1 includes a series circuit of four light emitting elements 11. As each light emitting element 11, for example, an organic EL element can be used.

ここで、調光信号が、上記のような矩形波状ではなく、指示する光出力に応じた電圧値の電圧信号である場合、駆動回路24においては、図6に示すように、入力された電圧値に応じたオンデューティの矩形波を生成する適宜の矩形波生成回路241を用いればよい。このような矩形波生成回路241は集積回路として市販されている。   Here, when the dimming signal is not a rectangular wave as described above but a voltage signal having a voltage value corresponding to the instructed optical output, the drive circuit 24 receives the input voltage as shown in FIG. An appropriate rectangular wave generation circuit 241 that generates an on-duty rectangular wave corresponding to the value may be used. Such a rectangular wave generation circuit 241 is commercially available as an integrated circuit.

さらに、消灯時電源21と点灯時電源22とを別途に設ける代わりに、図7に示すように点灯部2が1個のスイッチング電源で構成されていてもよい。図7の点灯部2は、交流電源3からの入力電力を全波整流するダイオードブリッジ4の直流出力端間に接続された周知のバックコンバータからなる。すなわち、図7の点灯部2は、ダイオードブリッジ4の直流出力端間に接続されたスイッチング素子Q2とインダクタL1とコンデンサC1との直列回路と、カソードがスイッチング素子Q2とインダクタL1との接続点に接続されるとともにアノードがダイオードブリッジ4の低電圧側の直流出力端に接続されたダイオードD3と、スイッチング素子Q2を繰り返しオンオフ駆動する駆動回路26とを有し、コンデンサC1の両端を出力端としている。駆動回路26は、出力電圧(すなわちコンデンサC1の両端電圧であり、負荷電圧Vx)を所定の目標電圧とするようにスイッチング素子Q2のオンデューティを随時変更するというフィードバック動作を行う。上記の目標電圧は、オフ期間T1中には消灯用電圧V1とされ、オン期間T2中には点灯用電圧V2とされる。さらに、駆動回路26は、光源1の光出力を指示する調光信号を入力され、調光信号によって指示された光出力が高いほど、間欠点灯のオンデューティT2/(T1+T2)を高くする。   Further, instead of separately providing the light source 21 for turning off and the power source 22 for turning on, the lighting unit 2 may be composed of one switching power source as shown in FIG. The lighting unit 2 in FIG. 7 includes a known buck converter connected between the DC output terminals of the diode bridge 4 that performs full-wave rectification on the input power from the AC power supply 3. That is, the lighting unit 2 in FIG. 7 includes a series circuit of a switching element Q2, an inductor L1, and a capacitor C1 connected between the DC output terminals of the diode bridge 4, and a cathode at a connection point between the switching element Q2 and the inductor L1. A diode D3 having an anode connected to a DC output terminal on the low voltage side of the diode bridge 4 and a drive circuit 26 for repeatedly turning on and off the switching element Q2 are connected, and both ends of the capacitor C1 are output terminals. . The drive circuit 26 performs a feedback operation in which the on-duty of the switching element Q2 is changed as needed so that the output voltage (that is, the voltage across the capacitor C1 and the load voltage Vx) is a predetermined target voltage. The target voltage is the turn-off voltage V1 during the off period T1, and the turn-on voltage V2 during the on period T2. Further, the drive circuit 26 receives a dimming signal that instructs the light output of the light source 1, and increases the on-duty T2 / (T1 + T2) of intermittent lighting as the light output instructed by the dimming signal is higher.

図7のように点灯部2を1個のスイッチング電源で構成した場合、図2や図5のように消灯時電源21と点灯時電源22とを別途に設ける場合に比べ、部品点数の削減による製造コストの低減が可能となる。ただし、図7の例では、コンデンサC1等の時定数により、消灯用電圧V1と点灯用電圧V2との間での切替に一定の時間を要するから、間欠点灯のオンデューティT2/(T1+T2)と光源1の光出力との間の比例関係が損なわれる可能性がある。これに対し、図2や図5のように消灯時電源21と点灯時電源22とを別途に設ける場合には、図7の例に比べ、消灯用電圧V1と点灯用電圧V2との間での切替にかかる時間が短縮されるから、間欠点灯のオンデューティT2/(T1+T2)と光源1の光出力との間の比例関係が損なわれにくいという利点がある。   When the lighting unit 2 is configured by a single switching power supply as shown in FIG. 7, the number of parts is reduced as compared with the case where the light-off power source 21 and the light-up power source 22 are separately provided as shown in FIGS. Manufacturing cost can be reduced. However, in the example of FIG. 7, since a certain time is required for switching between the turn-off voltage V1 and the turn-on voltage V2 due to the time constant of the capacitor C1 or the like, the intermittent turn-on duty T2 / (T1 + T2) The proportional relationship between the light output of the light source 1 may be impaired. On the other hand, when the light-off power source 21 and the light-on power source 22 are separately provided as shown in FIG. 2 and FIG. 5, compared with the example of FIG. Therefore, there is an advantage that the proportional relationship between the on-duty T2 / (T1 + T2) of intermittent lighting and the light output of the light source 1 is not easily lost.

また、接続される発光素子11の個数を変更可能としてもよい。具体的には例えば、周知のコネクタを用いて各発光素子11を個別に着脱自在とする。図5や図7の例のように各発光素子11が互いに直列に接続される場合、上記のように発光素子11の個数を可変とするならば、図8(a)(b)に示すように、取り外された発光素子11に代わって他の発光素子11への給電路を構成する適宜のスイッチ12を、各発光素子11にそれぞれ並列に設ける必要がある。上記の場合、適切な点灯用電圧V2は、接続される発光素子11の個数に応じて変化するので、少なくとも点灯用電圧V2については変更可能とされる必要がある。具体的には発光素子11の個数を検出する個数検出回路(図示せず)を設け、この個数検出回路によって検出された個数が多いほど電圧変換回路23や駆動回路26が点灯用電圧V2を高くする。個数検出回路は、光源1の両端のインピーダンスに基いて発光素子11の個数を検出するものであってもよいし、オフされているスイッチ12の個数を発光素子11の個数として検出するものであってもよく、いずれの場合にも周知技術で実現可能であるので詳細な図示並びに説明は省略する。
Further, the number of connected light emitting elements 11 may be changeable. Specifically, for example, each light emitting element 11 is individually detachable using a known connector. When the light emitting elements 11 are connected in series as in the examples of FIGS. 5 and 7, if the number of the light emitting elements 11 is variable as described above, as shown in FIGS. In addition, instead of the removed light emitting element 11, it is necessary to provide each light emitting element 11 with an appropriate switch 12 that constitutes a feeding path to another light emitting element 11. In the above case, the appropriate lighting voltage V2 varies depending on the number of the light emitting elements 11 to be connected. Therefore, at least the lighting voltage V2 needs to be changeable. Specifically, a number detection circuit (not shown) for detecting the number of the light emitting elements 11 is provided, and the voltage conversion circuit 23 and the drive circuit 26 increase the lighting voltage V2 as the number detected by the number detection circuit increases. To do. The number detection circuit may detect the number of light emitting elements 11 based on the impedances of both ends of the light source 1 or detect the number of switches 12 that are turned off as the number of light emitting elements 11. In any case, since it can be realized by a well-known technique, detailed illustration and description are omitted.

ところで、オン期間T2の開始直後における負荷電流Ixの一時的な上昇幅(以下、「サージ電流値」と呼ぶ。)Isを小さく抑える観点では、消灯用電圧V1は光源1が点灯しない範囲内でなるべく高い電圧とされることが望ましい。   By the way, from the viewpoint of suppressing the temporary increase width (hereinafter referred to as “surge current value”) Is of the load current Ix immediately after the start of the ON period T2, the turn-off voltage V1 is within a range where the light source 1 is not turned on. It is desirable that the voltage be as high as possible.

一方、点灯部2の回路部品にかかる電気的なストレスを抑える観点や、点灯部2における消費電力を抑える観点では、消灯用電圧V1はなるべく低くされることが望ましい。このとき、最低限どの程度の消灯用電圧V1を確保すべきかは、考え方や、種々の条件によって変化する。そこで、消灯用電圧V1が自動的に変更される構成を採用してもよい。消灯用電圧V1の変更は、図7の例においては駆動回路26における目標電圧の変更により達成される。また、図2の例や図5の例のように消灯時電源21と点灯時電源22とが別途に設けられる場合であっても、消灯時電源21として出力電圧Vaを変更可能な直流電源回路(例えば周知のスイッチング電源)を用いれば、消灯用電圧V1は変更可能である。   On the other hand, from the viewpoint of suppressing electrical stress applied to the circuit components of the lighting unit 2 and from the viewpoint of suppressing power consumption in the lighting unit 2, it is desirable that the turn-off voltage V1 be as low as possible. At this time, the minimum amount of the turn-off voltage V1 to be secured varies depending on the way of thinking and various conditions. Therefore, a configuration in which the extinguishing voltage V1 is automatically changed may be employed. The change of the turn-off voltage V1 is achieved by changing the target voltage in the drive circuit 26 in the example of FIG. Further, even when the light-off power source 21 and the light-on power source 22 are separately provided as in the example of FIG. 2 and the example of FIG. 5, the direct-current power supply circuit that can change the output voltage Va as the light-off power source 21. If (for example, a well-known switching power supply) is used, the turn-off voltage V1 can be changed.

以下、消灯用電圧V1の変更の具体的な態様について説明する。   Hereinafter, a specific mode of changing the turn-off voltage V1 will be described.

例えば、光源1として図8(a)(b)のように複数個の発光素子11が互いに直列に接続されたものを用いる場合、上記の個数検出回路によって検出された発光素子11の個数が少ないほど、光源1全体としてのターンオン電圧Vonの低下に合わせて、消灯用電圧V1が低くされることが望ましい。   For example, when a light source 1 having a plurality of light emitting elements 11 connected in series as shown in FIGS. 8A and 8B is used, the number of light emitting elements 11 detected by the number detection circuit is small. It is desirable that the turn-off voltage V1 be lowered in accordance with the decrease in the turn-on voltage Von of the light source 1 as a whole.

また、光源1として図9に示すように複数個の発光素子11が互いに並列に接続されたものを用いる場合、光源1全体としてのターンオン電圧Vonは発光素子11の個数では変化しないから、発光素子11の個数が変更されても点灯用電圧V2を変更する必要はない。しかしながら、発光素子11の個数が少なくなると、個々の発光素子11に流れる電流に変化がなくとも、サージ電流値Isは小さくなる。従って、点灯部2の回路部品にかかる電気的ストレスを抑えるためにサージ電流値Isを一定以下に抑えた上で、消灯用電圧V1をなるべく低くしたいのであれば、図9のように複数個の発光素子11が互いに並列に接続される場合にも、発光素子11の個数が少ないほど消灯用電圧V1が低くされることが望ましい。   Further, when a light source 1 having a plurality of light emitting elements 11 connected in parallel as shown in FIG. 9 is used, the turn-on voltage Von of the light source 1 as a whole does not change depending on the number of light emitting elements 11. Even if the number of eleven is changed, it is not necessary to change the lighting voltage V2. However, when the number of light emitting elements 11 decreases, the surge current value Is decreases even if the current flowing through each light emitting element 11 does not change. Therefore, if it is desired to reduce the surge current value Is to a certain level or less in order to suppress electrical stress applied to the circuit components of the lighting unit 2, it is desirable to reduce the turn-off voltage V1 as much as possible as shown in FIG. Even when the light emitting elements 11 are connected in parallel to each other, it is desirable that the turn-off voltage V1 be lowered as the number of the light emitting elements 11 decreases.

ここで、直流電力で点灯される光源1は、一般に、負荷電流Ixが多いほど光出力(光束)が高くなる。従って、サージ電流値Isが多いほど、光源1の実際の光出力と、意図された光出力との差が大きくなってしまう。そして、サージ電流値Isを一定とすると、個々のオン期間(つまり、間欠点灯における光源1の点灯状態の継続時間)T2が短いほど、意図された光出力に対する光源1の実際の光出力の比が大きくなってしまう。従って、個々のオン期間T2が短いほど、上記の比を一定以下に抑えるために最低限必要な消灯用電圧V1は高くなる。そこで、図10(a)(b)に示すように、個々のオン期間T2が短いときほど、点灯部2が消灯用電圧V1を高くするという構成を採用してもよい。図10(a)(b)の例では、個々のオフ期間T1の長さは一定とされており、オン期間T2の長さの変更のみによって光源1の光出力を変更している。つまり、図10の例では、間欠点灯の周期T1+T2が長いほど、消灯用電圧V1が低くされていることになる。   Here, in general, the light source 1 that is turned on by DC power has a higher light output (light flux) as the load current Ix increases. Therefore, the greater the surge current value Is, the greater the difference between the actual light output of the light source 1 and the intended light output. If the surge current value Is is constant, the ratio of the actual light output of the light source 1 to the intended light output becomes shorter as the individual on-period (that is, the duration of the lighting state of the light source 1 in intermittent lighting) T2 is shorter. Will become bigger. Therefore, the shorter the individual on-period T2, the higher the minimum turn-off voltage V1 required to keep the above ratio below a certain level. Therefore, as shown in FIGS. 10A and 10B, a configuration in which the lighting unit 2 increases the turn-off voltage V1 as the individual on-period T2 is shorter may be employed. In the example of FIGS. 10A and 10B, the length of each off period T1 is constant, and the light output of the light source 1 is changed only by changing the length of the on period T2. That is, in the example of FIG. 10, the longer the intermittent lighting cycle T1 + T2, the lower the turn-off voltage V1.

また、光源1の光出力を変更する方法としては、間欠点灯のオンデューティT2/(T1+T2)を変更するという方法の他に、点灯用電圧V2を変更するという方法も考えられる。また、例えば、光出力の大まかな変更をオンデューティT2/(T1+T2)の変更によって達成し、光出力の微調整を点灯用電圧V2の変更によって達成するといったように、上記2通りの方法を組み合わせることも考えられる。上記のように点灯用電圧V2が変更される場合、点灯用電圧V2が低いほどサージ電流値Isは少なくなるので、点灯用電圧V2が低いほど、サージ電流値Isを一定以下に抑えるために最低限必要な消灯用電圧V1は低くなる。そこで、図11(a)(b)に示すように、点灯用電圧V2が低いほど、点灯部2が消灯用電圧V1を低くするものとしてもよい。   As a method of changing the light output of the light source 1, a method of changing the lighting voltage V2 in addition to a method of changing the on-duty T2 / (T1 + T2) of intermittent lighting is also conceivable. Further, for example, the above two methods are combined such that a rough change of the light output is achieved by changing the on-duty T2 / (T1 + T2) and a fine adjustment of the light output is achieved by changing the lighting voltage V2. It is also possible. When the lighting voltage V2 is changed as described above, the lower the lighting voltage V2, the smaller the surge current value Is. Therefore, the lower the lighting voltage V2, the lower the minimum in order to keep the surge current value Is below a certain level. The necessary turn-off voltage V1 becomes low. Therefore, as shown in FIGS. 11A and 11B, the lighting unit 2 may lower the turn-off voltage V1 as the turn-on voltage V2 is lower.

さらに、サージ電流値Isを検出するサージ検出手段(図示せず)を設け、このサージ検出手段によって検出されたサージ電流値Isを所定範囲内に収めるように、点灯部2が消灯用電圧V1を随時変更するものとしてもよい。例えば、点灯部2は、サージ電流値Isが上記所定範囲の上限値を上回っていれば消灯用電圧V1を高くし、サージ電流値Isが上記所定範囲の下限値を下回っていれば消灯用電圧V1を低くする。上記のようなサージ検出手段は周知技術で実現可能であるので、詳細な図示並びに説明は省略する。   Further, a surge detection means (not shown) for detecting the surge current value Is is provided, and the lighting unit 2 sets the turn-off voltage V1 so that the surge current value Is detected by the surge detection means falls within a predetermined range. It may be changed at any time. For example, the lighting unit 2 increases the turn-off voltage V1 if the surge current value Is exceeds the upper limit value of the predetermined range, and turns off the voltage if the surge current value Is is lower than the lower limit value of the predetermined range. Lower V1. Since the surge detecting means as described above can be realized by a well-known technique, detailed illustration and description are omitted.

上記のような消灯用電圧V1の各種の変更は、条件が少しでも異なれば必ず消灯用電圧V1が変更されるといった連続的な変更であってもよいし、ある程度の幅を持った条件に対して消灯用電圧V1が一定とされるといったような段階的な変更であってもよい。また、上記各種の変更を組み合わせてもよい。例えば、複数通りの決定方法で決定される点灯用電圧V2のうち最も低いものを点灯部2が採用するといった構成を採用してもよい。さらに、例えば点灯用電圧V2がある程度低くされる場合などに、消灯用電圧V1が一時的に0にされてもよい。当然ながら、上記いずれの場合にも、消灯用電圧V1の上限値は、光源1に電流が流れない程度に低い(つまり光源1のターンオン電圧Vonよりも低い)値とされる。   The various changes of the turn-off voltage V1 as described above may be continuous changes in which the turn-off voltage V1 is always changed if the conditions are slightly different, or for a condition having a certain range. The step-by-step change may be such that the extinguishing voltage V1 is constant. Moreover, you may combine the said various changes. For example, a configuration may be employed in which the lighting unit 2 employs the lowest one of the lighting voltages V2 determined by a plurality of determination methods. Further, for example, when the lighting voltage V2 is lowered to some extent, the extinguishing voltage V1 may be temporarily set to zero. Of course, in any of the above cases, the upper limit value of the turn-off voltage V1 is set to a value that is low enough that no current flows through the light source 1 (that is, lower than the turn-on voltage Von of the light source 1).

また、点灯部2は、入力された調光信号等に応じて、間欠点灯動作だけでなく、光源1に対して点灯用電圧V2を連続的に出力する(つまりオンデューティを100%とする)連続点灯動作を行う可能性があってもよい。   The lighting unit 2 continuously outputs the lighting voltage V2 to the light source 1 in addition to the intermittent lighting operation according to the input dimming signal or the like (that is, the on-duty is set to 100%). There may be a possibility of performing a continuous lighting operation.

上記各種の照明装置は、図12に示すような照明器具5に使用することができる。図12の照明器具5は、点灯部2やダイオードブリッジ4を収納及び保持するケース51と、ケース51と光源1を構成する4個の発光素子11とをそれぞれ保持する器具本体50とを有する。上記のような照明器具5は周知技術で実現可能であるので、詳細な図示並びに説明は省略する。   The various lighting devices described above can be used in a lighting fixture 5 as shown in FIG. The lighting fixture 5 of FIG. 12 includes a case 51 that houses and holds the lighting unit 2 and the diode bridge 4, and a fixture body 50 that holds the case 51 and the four light emitting elements 11 that constitute the light source 1. Since the lighting fixture 5 as described above can be realized by a well-known technique, detailed illustration and description thereof are omitted.

1 光源
2 点灯部
5 照明器具
11 発光素子
21 消灯時電源
22 点灯時電源
50 器具本体
V1 消灯用電圧
V2 点灯用電圧
DESCRIPTION OF SYMBOLS 1 Light source 2 Lighting part 5 Lighting fixture 11 Light emitting element 21 Power supply at the time of extinction 22 Power supply at the time of lighting 50 Appliance main body V1 Voltage for extinguishing V2 Voltage for lighting

Claims (10)

直流電圧を入力されて点灯される光源と、
前記光源を間欠点灯させる間欠点灯動作が可能な点灯部とを備え、
前記点灯部は、前記間欠点灯動作において前記光源を消灯させる期間中にも、前記光源を点灯させる際に出力される点灯用電圧と同じ向きの消灯用電圧であって前記光源に電流が流れない程度に低い消灯用電圧を出力し、
前記点灯部は、前記間欠点灯動作において前記光源を点灯させる期間の継続時間を可変とするものであって、
前記間欠点灯動作において前記光源を点灯させる期間の継続時間が短いほど、前記消灯用電圧を高くすることを特徴とする照明装置。
A light source that is turned on when a DC voltage is input;
A lighting unit capable of intermittent lighting operation for intermittently lighting the light source,
The lighting unit is a turn-off voltage in the same direction as a turn-on voltage output when turning on the light source even during a period in which the light source is turned off in the intermittent lighting operation, and no current flows through the light source. Outputs a low turn-off voltage ,
The lighting unit is configured to change a duration of a period for lighting the light source in the intermittent lighting operation,
In the intermittent lighting operation, the lighting voltage is increased as the duration of the period during which the light source is turned on is shorter .
直流電圧を入力されて点灯される光源と、
前記光源を間欠点灯させる間欠点灯動作が可能な点灯部とを備え、
前記点灯部は、前記間欠点灯動作において前記光源を消灯させる期間中にも、前記光源を点灯させる際に出力される点灯用電圧と同じ向きの消灯用電圧であって前記光源に電流が流れない程度に低い消灯用電圧を出力し、
前記点灯部は、前記間欠点灯動作において前記光源を点灯させる期間中に前記光源に出力する点灯用電圧を可変とするものであって、
前記点灯用電圧が低いほど、前記消灯用電圧を低くすることを特徴とする照明装置。
A light source that is turned on when a DC voltage is input;
A lighting unit capable of intermittent lighting operation for intermittently lighting the light source,
The lighting unit is a turn-off voltage in the same direction as a turn-on voltage output when turning on the light source even during a period in which the light source is turned off in the intermittent lighting operation, and no current flows through the light source. Outputs a low turn-off voltage,
The lighting unit is configured to change a lighting voltage output to the light source during a period of lighting the light source in the intermittent lighting operation,
The lighting device , wherein the lighting voltage is lowered as the lighting voltage is lower .
直流電圧を入力されて点灯される光源と、
前記光源を間欠点灯させる間欠点灯動作が可能な点灯部とを備え、
前記点灯部は、前記間欠点灯動作において前記光源を消灯させる期間中にも、前記光源を点灯させる際に出力される点灯用電圧と同じ向きの消灯用電圧であって前記光源に電流が流れない程度に低い消灯用電圧を出力し、
前記点灯部は、前記間欠点灯の周期を可変とするものであって、
前記間欠点灯の周期が長いほど、前記消灯用電圧を低くすることを特徴とする照明装置。
A light source that is turned on when a DC voltage is input;
A lighting unit capable of intermittent lighting operation for intermittently lighting the light source,
The lighting unit is a turn-off voltage in the same direction as a turn-on voltage output when turning on the light source even during a period in which the light source is turned off in the intermittent lighting operation, and no current flows through the light source. Outputs a low turn-off voltage,
The lighting unit is configured to change a cycle of the intermittent lighting,
The lighting device characterized in that the longer the intermittent lighting cycle, the lower the turn-off voltage .
直流電圧を入力されて点灯される光源と、
前記光源を間欠点灯させる間欠点灯動作が可能な点灯部とを備え、
前記点灯部は、前記間欠点灯動作において前記光源を消灯させる期間中にも、前記光源を点灯させる際に出力される点灯用電圧と同じ向きの消灯用電圧であって前記光源に電流が流れない程度に低い消灯用電圧を出力し、
前記光源は1個以上の発光素子からなり、
前記光源を構成する発光素子の個数は可変であって、
前記点灯部の出力端間に接続された発光素子の個数を検出する個数検出手段を備え、
前記点灯部は、前記個数検出手段によって検出された発光素子の個数が少ないほど、前記消灯用電圧を低くすることを特徴とする照明装置。
A light source that is turned on when a DC voltage is input;
A lighting unit capable of intermittent lighting operation for intermittently lighting the light source,
The lighting unit is a turn-off voltage in the same direction as a turn-on voltage output when turning on the light source even during a period in which the light source is turned off in the intermittent lighting operation, and no current flows through the light source. Outputs a low turn-off voltage,
The light source comprises one or more light emitting elements,
The number of light emitting elements constituting the light source is variable,
Comprising a number detecting means for detecting the number of light emitting elements connected between the output ends of the lighting unit;
The lighting device is characterized in that the lighting unit lowers the turn-off voltage as the number of light emitting elements detected by the number detecting means is smaller .
直流電圧を入力されて点灯される光源と、
前記光源を間欠点灯させる間欠点灯動作が可能な点灯部とを備え、
前記点灯部は、前記間欠点灯動作において前記光源を消灯させる期間中にも、前記光源を点灯させる際に出力される点灯用電圧と同じ向きの消灯用電圧であって前記光源に電流が流れない程度に低い消灯用電圧を出力し、
前記光源の点灯開始直後における前記点灯部の出力電流の一時的な上昇幅を検出するサージ検出手段を備え、
前記点灯部は、前記サージ検出手段によって検出された前記上昇幅を所定範囲内に収めるように、前記消灯用電圧を随時変更することを特徴とする照明装置。
A light source that is turned on when a DC voltage is input;
A lighting unit capable of intermittent lighting operation for intermittently lighting the light source,
The lighting unit is a turn-off voltage in the same direction as a turn-on voltage output when turning on the light source even during a period in which the light source is turned off in the intermittent lighting operation, and no current flows through the light source. Outputs a low turn-off voltage,
Surge detecting means for detecting a temporary rise width of the output current of the lighting unit immediately after the lighting of the light source is started,
The lighting device is characterized in that the turn-off voltage is changed as needed so that the rising width detected by the surge detecting means falls within a predetermined range .
前記点灯部は、前記消灯用電圧を前記光源に対して連続的に出力する消灯時電源と、前記点灯用電圧を前記光源に対して間欠的に出力する点灯時電源とを有することを特徴とする請求項1〜5のいずれか1項に記載の照明装置。 The lighting unit includes: a power supply for extinguishing that continuously outputs the voltage for extinguishing to the light source; and a power source for lighting that intermittently outputs the voltage for lighting to the light source. The lighting device according to any one of claims 1 to 5 . 前記点灯時電源は、前記間欠点灯動作において前記光源が点灯される期間中には出力電流を一定とすることを特徴とする請求項記載の照明装置。 The lighting device according to claim 6 , wherein the lighting power source makes an output current constant during a period in which the light source is turned on in the intermittent lighting operation . 前記点灯部は、出力電圧を切替え可能な1個のスイッチング電源からなることを特徴とする請求項1〜5のいずれか1項に記載の照明装置。 The lighting unit, the lighting device according to any one of claims 1-5, characterized in that it consists of one switching power supply capable of switching the output voltage. 前記光源は1個以上の有機EL素子を有することを特徴とする請求項1〜8のいずれか1項に記載の照明装置。 Wherein the light source lighting device according to any one of claims 1-8, characterized in that it comprises one or more organic EL elements. 請求項1〜9のいずれか1項に記載の照明装置と、前記照明装置を保持する器具本体とを備えることを特徴とする照明器具。A lighting fixture comprising: the lighting device according to any one of claims 1 to 9; and a fixture main body that holds the lighting device.
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