1. A method of evaluating dye component suitability for optical recording media which comprises
a first step in which a temperature of a sample containing the dye component or a temperature of atmosphere surrounding said sample is set to two or more different prescribed temperatures, and an absorbance of said sample for light of a prescribed wavelength is measured at each of said prescribed temperatures, and
a second step in which suitability of including said dye component in a recording layer of the optical recording medium is evaluated based on one or more conditions which are set based on correlation between said prescribed temperatures and said absorbance.
2. A method of evaluating dye component suitability for optical recording media according to claim 1, wherein said prescribed wavelength is smaller than a wavelength of a laser light irradiated onto said optical recording medium during recording andor reading of said optical recording medium.
3. A method of evaluating dye component suitability for optical recording media according to claim 1, wherein said prescribed wavelength is in the range of 500-650 nm.
4. A method of evaluating dye component suitability for optical recording media according to claim 1, wherein said conditions are represented by the following inequalities (1) and (2).
200\u2266T1\u2266250\u2003\u2003(1)
wherein T1 represents a prescribed temperature which produces the absorbance satisfying the relationship represented by the following equality (3):
A1=A252\u2003\u2003(3)
(wherein A1 represents the absorbance at T1 and A25 represents the absorbance at 25\xb0 C.).
0.50\u2266{(A200\u2212A250)A200}\u22661.00\u2003\u2003(2)
(wherein A200 represents the absorbance at 200\xb0 C. and A250 represents the absorbance at 250\xb0 C.).
5. An optical recording material used for an optical recording medium capable of recording information by irradiation of light,
wherein a dye component contained in said optical recording material simultaneously satisfies the conditions represented by the following inequalities (1) and (2) when a temperature of a sample containing said dye component or a temperature of an atmosphere surrounding said sample is set to two or more different prescribed temperatures, and an absorbance of said sample for light of a prescribed wavelength is measured at each of said prescribed temperatures.
200\u2266T1\u2266250\u2003\u2003(1)
wherein T1 represents a prescribed temperature (units: \xb0 C.) which produces the absorbance satisfying the relationship represented by the following equality (3):
A1=A252\u2003\u2003(3)
(wherein A1 represents the absorbance at T1 and A25 represents the absorbance at 25\xb0 C.).
0.50\u2266{(A200\u2212A250)A200}\u22661.00\u2003\u2003(2)
(wherein A200 represents the absorbance at 200\xb0 C. and A250 represents the absorbance at 250\xb0 C.).
6. An optical recording medium capable of recording information by irradiation of light,
wherein a dye component contained in a recording layer provided in said optical recording medium simultaneously satisfies the conditions represented by the following inequalities (1) and (2) when a temperature of a sample containing said dye component or a temperature of an atmosphere surrounding said sample is set to two or more different prescribed temperatures, and an absorbance of said sample for light of a prescribed wavelength is measured at each of said prescribed temperatures.
200\u2266T1\u2266250\u2003\u2003(1)
wherein T1 represents a prescribed temperature (units: \xb0 C.) which produces the absorbance satisfying the relationship represented by the following equality (3):
A1=A252\u2003\u2003(3)
(wherein A1 represents the absorbance at T1 and A25 represents the absorbance at 25\xb0 C.).
0.50\u2266{(A200\u2212A250)A200}\u22661.00\u2003\u2003(2)
(wherein A200 represents the absorbance at 200\xb0 C. and A250 represents the absorbance at 250\xb0 C.).
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
1. An apparatus for detecting an arc fault occurring on a conductive wire between a power source and a load, comprising:
a voltage detector disposed between a phase conductive wire and a neutral wire, for detecting the amount of change in voltage per unit time with respect to the power source;
a first frequency band setting unit for setting a frequency band for a low load current with respect to the signal output from the voltage detector;
a first filter for detecting a high frequency signal out of the signal output from the first frequency band setting unit;
a first level limiter for limiting a level of a dimmer signal out of the signal output from the first filter so as to discriminate between the dimmer signal and an arc signal;
a second filter for detecting a high frequency signal out of the level-limited signal output from the first level limiter to detect only a frequency band of the arc signal;
a first frequency limit amplifier for limitedly amplifying the frequency band of the signal detected from the second filter;
a first level comparative oscillator for generating an oscillating signal with a pulse width determined according to the magnitude of current preset in a low load detecting route when the signal output from the first frequency limit amplifier is higher than a predetermined reference voltage;
a first comparator for accumulating signals oscillated from the first level comparative oscillator and a second level comparative oscillator and generating a signal when the accumulated signal is higher than a reference voltage;
a circuit breaker for breaking an electric connection between the power source and the load in response to the signal output from the first comparator;
a second frequency band setting unit for setting a frequency band for a high load current with respect to the signal output from the voltage detector;
a third filter for detecting a high frequency signal out of the signal output from the second frequency band setting unit;
a second frequency limit amplifier for limitedly amplifying a frequency band of the signal detected from the third filter; and
the second level comparative oscillator for generating an oscillating signal with a pulse width determined according to the magnitude of current preset in a high load detecting route when the signal output from the second frequency limit amplifier is higher than a predetermined reference voltage.
2. The apparatus of claim 1, further comprising:
a current detector for detecting the amount of change in current flowing onto the phase conductive wire or the neutral wire and generating a signal proportional to the amount of change;
a second comparator for setting the signal detected from the current detector as its reference voltage, receiving a setting reference voltage of one branch point of a load current detecting route as its input, and stopping generating an output signal when the signal output from the current detector is higher than the setting reference voltage of the branch point of the current detecting route; and
a first current branch switching unit for limiting an output oscillation by controlling the second level comparative oscillator when the second comparator generates the output signal, and limiting an output oscillation by controlling the first level comparator oscillator when the second comparator does not generate the output signal.
3. The apparatus of claim 1, wherein the voltage detector detects a voltage between the phase conductive wire and the neutral wire by a bridge diode which is a rectifier.
4. An apparatus for detecting an arc fault occurring on a conductive wire between a power source and a load, comprising:
a voltage detector disposed between a phase conductive wire and a neutral wire, for detecting the amount of change in voltage per unit time with respect to the power source;
a first frequency band setting unit for setting a frequency band for a low load current with respect to the signal output from the voltage detector;
a first filter for detecting a high frequency signal out of the signal output from the first frequency band setting unit;
a first level limiter for limiting a level of a dimmer signal out of the signal output from the first filter so as to discriminate between the dimmer signal and an arc signal;
a second filter for detecting a high frequency signal out of the level-limited signal output from the first level limiter to detect only a frequency band of the arc signal;
a first frequency limit amplifier for limitedly amplifying the frequency band of the signal detected from the second filter;
a first level comparative oscillator for generating an oscillating signal with a pulse width determined according to the magnitude of current preset in a low load detecting route when the signal output from the first frequency limit amplifier is higher than a predetermined reference voltage;
a first comparator for accumulating signals oscillated from the first level comparative oscillator and a second level comparative oscillator and generating a signal when the accumulated signal is higher than a reference voltage;
a circuit breaker for breaking an electric connection between the power source and the load in response to the signal output from the first comparator;
a second frequency band setting unit for setting a frequency band for a high load current with respect to the signal output from the voltage detector;
a third filter for detecting a high frequency signal out of the signal output from the second frequency band setting unit;
a second frequency limit amplifier for limitedly amplifying a frequency band of the signal detected from the third filter;
the second level comparative oscillator for generating an oscillating signal with a pulse width determined according to the magnitude of current preset in a high load detecting route when the signal output from the second frequency limit amplifier is higher than a predetermined reference voltage;
a current detector for detecting the amount of change in current flowing onto the phase conductive wire or the neutral wire and generating a signal proportional to the amount of change;
a second comparator for setting the signal detected from the current detector as its reference voltage, receiving a setting reference voltage of one branch point of a load current detecting route as its input, and stopping generating an output signal when the signal output from the current detector is higher than the setting reference voltage of the branch point of the current detecting route; and
a first current branch switching unit for limiting an output oscillation by controlling the second level comparative oscillator when the second comparator generates the output signal, and limiting an output oscillation by controlling the first level comparator oscillator when the second comparator does not generate the output signal.