Abstract: A processing method according to the present embodiment is a processing method of a fiber containing resin in which fibers are contained in a matrix resin. The processing method includes: a step of thermal decomposition of the matrix resin in the fiber containing resin; and a step of stirring a resulting fibers bundle in solvent after the thermal decomposition. At the time of the thermal decomposition, the matrix resin may be carbonized in a dry distillation-carbonization furnace, for example.

Abstract: A constant current circuit includes a first transistor, a second transistor having the gate and the source connected to the gate and the source of the first transistor, and having the drain connected to a load, a voltage adjustment circuit section that controls the drain voltage of the first transistor, a constant current generation circuit section that supplies a constant current to the first transistor, and a detection circuit section that determines whether at least one of the first transistor and the second transistor is unable to output a current proportional to the first constant current while at least one of the first transistor and the second transistor operates in the linear region, by performing a voltage comparison between a voltage at a connecting section between the voltage adjustment circuit section and the constant current generation circuit section and a predetermined reference voltage.

Abstract: A processing method according to the present embodiment is a processing method of a fiber containing resin in which fibers are contained in a matrix resin. The processing method includes: a step of thermal decomposition of the matrix resin in the fiber containing resin; and a step of stirring a resulting fibers bundle in solvent after the thermal decomposition. At the time of the thermal decomposition, the matrix resin may be carbonized in a dry distillation-carbonization furnace, for example.

Abstract: A switching regulator switch between an input terminal and an output terminal; a second switch between the output terminal and ground; a switching-time control circuit to generate a first signal when a first period corresponding to a ratio of ON-period of the first switch to a sum of those of the switches has elapsed from a reset-release timing and a reset signal when a second period longer than the first period has elapsed from the rest-release timing; a comparator to generate a second signal when a feedback voltage is smaller than a reference voltage; and a switch control circuit to control the switches so that the first switch is turned off and the second switch is turned on in response to the first signal, and the second switch is turned off and the first switch is fumed on in response to the second signal.

Abstract: A DC-DC converter converts an input voltage input from an input terminal to a predetermined voltage and outputs the converted voltage from an output terminal, the DC-DC converter including an output control transistor and an operation control circuit that has an error amplifying circuit, whereby the error amplifying circuit includes an output circuit configured to output an error voltage and include an output transistor of a source follower connection, a series circuit configured to include a resistor for phase compensation and a capacitor for phase compensation and be connected between a control electrode of the output circuit and a grounding voltage terminal, and an amplifying circuit configured to be positioned on a side more distant from a side outputting the error voltage relative to the output circuit in the error amplifying circuit, and include a voltage generating element as a load of the amplifying circuit.

Abstract: A switching regulator includes a first switching element connected between an input terminal and an output terminal; a second switching element connected between the output terminal and a ground; a switching-time control circuit to generate a first switching-time control signal indicating finish timing of an ON-period of the first switching element, based on a ratio of a length of the ON-period of the first switching element to a sum of lengths of ON-periods of the first and second switching elements; a comparator generate a second switching-time control signal indicating finish timing of the ON-period of the second switching element when a feedback voltage is smaller than a reference voltage; and a switching-element control circuit to control switching of the first and second switching elements so that the first and second switching elements are turned on complementarily based on the first and second switching-time control signals.

Abstract: A method is presented for producing polyolefin microporous membranes which are superior in thermal stability and are particularly useful as a separator for a lithium ion battery. A process including a first step of melting polyolefin resin and mixing together at least melted polyolefin resin, organosiloxane particles including a polysiloxane cross-linked structure and having a spherical or golfball shape with an average particle diameter of 0.01-10 ?m and a plasticizer to obtain a melted mixture, a second step of molding this mixture and biaxially stretching molded product to obtain a stretched film and a third step of extracting and removing the plasticizer from the stretched film is carried out, if a membrane having a single film layer is to be produced, to obtain this single film layer and, if a membrane having two or more laminated film layer is to be produced, to obtain the film layers on both outsides.

Abstract: The invention provides dispersing agents for inorganic fillers capable of uniformly dispersing inorganic fillers in a substrate such as made of a rubber or resin material such that molded products with improved mechanical strength and abrasion resistance can be produced from such a substrate material and more specifically that rubber compositions with improved abrasion resistance and workability can be obtained and that automobile tires with improved low fuel consumption and handling stability can be produced from such rubber compositions, as well as a method of producing such dispersing agents characterized as using a modified conjugated diene polymer obtained by introducing specified structural units with improved mutual reaction with inorganic fillers into a conjugated diene polymer having affinity with rubber and resin materials.

Abstract: A method is presented for producing polyolefin microporous membranes which are superior in thermal stability and are particularly useful as a separator for a lithium ion battery. A process including a first step of melting polyolefini resin and mixing together at least melted polyolefin resin, organosiloxane particles including a polysiloxane cross-linked structure and having a spherical or golfball shape with an average particle diameter of 0.01-10 ?m and a plasticizer to obtain a melted mixture, a second step of molding this mixture and biaxially stretching molded product to obtain a stretched film and a third step of extracting and removing the plasticizer from the stretched film is carried out, if a membrane having a single film layer is to be produced, to obtain this single film layer and, if a membrane having two or more laminated film layer is to be produced, to obtain the film layers on both outsides.

Abstract: A switching regulator includes a ripple generating circuit that generates a ripple voltage signal having a voltage that increases when a first switch element is on and decreases when a second switch element is on, or a voltage that decreases when the first switch element is on and increases when the second switch element is on, a comparator that compares the ripple voltage signal to a reference voltage, and generates a comparison signal indicating the comparison result, and a switch element control circuit that generates, according to the comparison signal, a control signal to switch on and off of the first switch element and a control signal to switch on and off of the second switch element, and applies the control signals to the first and second switch elements, respectively, wherein the ripple generating circuit generates the ripple voltage signal based on the control signals.

Abstract: A power source device includes a main power source circuit, a sub power source circuit whose output voltage is changed when the output voltage of the main power source circuit is changed, a voltage difference detecting circuit which detects whether a voltage difference between the output voltages of the main and sub power source circuits is within a predetermined voltage difference, and a voltage control circuit which controls the output voltages of the main and sub power source circuits based on a voltage changing signal and an output from the voltage difference detecting circuit. The voltage control circuit controls so that the voltage difference between the output voltages of the main and sub power source circuits is within the predetermined voltage difference by controlling output voltage changing speed when the voltage difference between the output voltages of the main and sub power source circuits is over the predetermined voltage difference.

Abstract: A switching regulator circuit for achieving stepping-up or stepping-down, including a basic circuit and an inductor connected to the basic circuit. The basic circuit includes a switching circuit to perform switching, a control circuit to control the switching circuit, a first terminal connected to one end of the inductor and the switching circuit, and second and third terminals connected to the switching circuit. When the input voltage is stepped up, the control circuit causes the switching circuit to charge the inductor via the first terminal and the third terminal and to discharge the inductor via the first terminal and the second terminal. When the input voltage is stepped down, the control circuit causes the switching circuit to charge the inductor via the first terminal and the second terminal and to discharge the inductor via the first terminal and the third terminal.

Abstract: A DC-DC converter configured to vary an output voltage includes an oscillator circuit configured to output a first clock signal; a digital-to-analog converter controlled based on the first clock signal input thereto and configured to output a voltage according to a voltage setting signal; a delay circuit configured to output a second clock signal delayed by a predetermined delay time with respect to the first clock signal input thereto; an error amplifier circuit having the output voltage of the digital-to-analog converter input thereto as a reference voltage; a pulse width modulation comparator provided with an output of the error amplifier circuit and a voltage into which a current flowing through an inductor is converted; and a control part configured to control a switching transistor of the DC-DC converter based on the second clock signal output by the delay circuit and an output of the pulse width modulation comparator.

Abstract: A power supply circuit includes an output driver transistor, a buffer circuit, and an error amplification circuit. The buffer circuit includes a first transistor connected to an output terminal and a second transistor functioning as a load for the first transistor. The error amplification circuit includes a differential pair including a first pair of transistors, a current mirror circuit including a second pair of transistors, a constant current source supplying a current and driving the differential pair and the current mirror circuit, a third transistor connected between one of the differential pair and the current mirror circuit. The first and second transistor have the same polarity as the transistors constituting the current mirror circuit, and control terminals of the first and third transistors are connected at a first junction node that is connected to a second junction node between the one of the differential pair and the third transistor.

Abstract: A switching regulator switch between an input terminal and an output terminal; a second switch between the output terminal and ground; a switching-time control circuit to generate a first signal when a first period corresponding to a ratio of ON-period of the first switch to a sum of those of the switches has elapsed from a reset-release timing and a reset signal when a second period longer than the first period has elapsed from the rest-release timing; a comparator to generate a second signal when a feedback voltage is smaller than a reference voltage; and a switch control circuit to control the switches so that the first switch is turned off and the second switch is turned on in response to the first signal, and the second switch is turned off and the first switch is fumed on in response to the second signal.

Abstract: A constant current circuit includes a first transistor, a second transistor having the gate and the source connected to the gate and the source of the first transistor, and having the drain connected to a load, a voltage adjustment circuit section that controls the drain voltage of the first transistor, a constant current generation circuit section that supplies a constant current to the first transistor, and a detection circuit section that determines whether at least one of the first transistor and the second transistor is unable to output a current proportional to the first constant current while at least one of the first transistor and the second transistor operates in the linear region, by performing a voltage comparison between a voltage at a connecting section between the voltage adjustment circuit section and the constant current generation circuit section and a predetermined reference voltage.

Abstract: A current-mode control type DC-DC converter includes a switching transistor turned on with a clock signal output in predetermined cycles, an inductor supplied with electric current when the switching transistor is turned on, an error amplifier circuit to output an error voltage that is an amplified difference between a predetermined reference voltage and a divided output voltage of the DC-DC converter, a slope voltage generation circuit to generate a slope voltage by performing slope compensation on an inductor current, a PWM comparator to compare the slope voltage with the error voltage and generate a reset pulse to turn off the switching transistor when the slope voltage reaches the error voltage, and a slope voltage maintenance mechanism to keep the slope voltage at the ground voltage from when the reset pulse is generated to when a subsequent clock signal is generated.

Abstract: A switching regulator includes a first switching element connected between an input terminal and an output terminal; a second switching element connected between the output terminal and a ground; a switching-time control circuit to generate a first switching-time control signal indicating finish timing of an ON-period of the first switching element, based on a ratio of a length of the ON-period of the first switching element to a sum of lengths of ON-periods of the first and second switching elements; a comparator generate a second switching-time control signal indicating finish timing of the ON-period of the second switching element when a feedback voltage is smaller than a reference voltage; and a switching-element control circuit to control switching of the first and second switching elements so that the first and second switching elements are turned on complementarily based on the first and second switching-time control signals.

Abstract: A switching regulator includes a switching element that switches between on and off according to a control signal, an inductor that is charged with the input voltage by switching of the switching element, a rectification element that discharges the inductor when the switching element is off and charging the inductor is stopped, a differential amplifier that amplifies a difference between a voltage proportional to the output voltage and a predetermined reference voltage, a voltage change detection circuit that detects changes in the output voltage, and a control circuit that causes the switching element to switch between on and off in a predetermined cycle depending on a voltage output from the differential amplifier. The control circuit turns on the switching element regardless of the predetermined cycle when the voltage change detection circuit detects that a decrease in the output voltage exceeds a predetermined first reference value.

Abstract: A power supply circuit electrically connectable to a load, including a reference voltage circuit, having a ground voltage detection element to detect a ground terminal voltage at the ground terminal of the load, to generate a reference voltage based on the detected ground terminal voltage; an error amplifier to generate a difference voltage between and the reference voltage and a load voltage detection circuit generated based on a voltage at a power supply terminal of the load; and a control circuit to control an output voltage of the power supply circuit such that the output voltage is set to a constant voltage based on the difference voltage from the error amplifier to cause a voltage between the power supply terminal and the ground terminal of the load to set to a predetermined voltage.