Abstract: A remote control device of a heat pump system is useable to switch an operating state of the heat pump system. The remote control device includes a touch screen and physical keys provided separately from the touch screen. The touch screen is configured and arranged to display a plurality of touch keys displayed by words, graphics, or symbols associated separately with any of a plurality of set items. The physical keys include at least two function keys. A number of the function keys is fewer than a number of the set items and a number of the touch keys. The function keys are assigned a common function utilized when the operating state is switched. Same functions as when the touch keys are inputted are enacted by inputting the function keys.

Abstract: The current-sensing circuit (1) includes a shunt resistor (R1) connected in series with a path of current from an inverter (106), an operational amplifier (12) amplifying voltage across both ends of this shunt resistor (R1) with a predetermined gain, a low-pass filter (18) averaging output voltage of this operational amplifier (12), and an arithmetic unit (50) calculating the current flowing through the path based on output voltage of the low-pass filter (18). The supply voltage of the operational amplifier (12) is set higher than the supply voltage of the arithmetic unit (50). The output voltage of the operational amplifier (12) is averaged at the low-pass filter (18) to a lower value than the supply voltage of the arithmetic unit (50).

Abstract: First and third current paths are connected at mutual one end, and second and fourth current paths are connected at mutual one end. A transmitter sends signals utilizing the change of a current by changing the current flowing between other ends of the first and second current paths. A switching part brings about a non-conductive state between the other end of the third current path and the other end of the fourth current path by being applied with a control signal from a controller. By contrast with this, the switching part brings about a conductive state between the other end of the third current path and the other end of the fourth current path by not being applied the control signal.

Abstract: The current-sensing circuit 1 includes a shunt resistor R1 connected in series with a path of current from an inverter 106, an operational amplifier 12 amplifying voltage across both ends of this shunt resistor R1 with a predetermined gain, a low-pass filter 18 averaging output voltage of this operational amplifier 12, and an arithmetic unit 50 calculating the current flowing through the path based on output voltage of the low-pass filter 18. The supply voltage of the operational amplifier 12 is set higher than the supply voltage of the arithmetic unit 50. The output voltage of the operational amplifier 12 is averaged at the low-pass filter 18 to a lower value than the supply voltage of the arithmetic unit 50.

Abstract: First and third current paths are connected at mutual one end, and second and fourth current paths are connected at mutual one end. A transmitter sends signals utilizing the change of a current by changing the current flowing between other ends of the first and second current paths. A switching part brings about a non-conductive state between the other end of the third current path and the other end of the fourth current path by being applied with a control signal from a controller. By contrast with this, the switching part brings about a conductive state between the other end of the third current path and the other end of the fourth current path by not being applied the control signal.

Abstract: A refrigerator stated is characterized in that it includes a machine room (14) formed on a lower part of a rear of a main body of the refrigerator; a refrigerant compressor (12) installed offset to one side in the machine room (14) in a width direction; and a cooler (9) for receiving a refrigerant from the refrigerant compressor (12) and cooling an inside of a storage chamber; wherein the cooler (9) is arranged inside the refrigerator via a heat insulating wall (3a) of the main body above the refrigerant compressor (12) arranged on one side of the machine room (14) and at a position on an opposite side of the refrigerant compressor (12) in a width direction; and control and power source boards (21) of the refrigerator are arranged in another wide space of the refrigerant compressor (12) in the machine room (14) in a width direction.

Abstract: A refrigerator-freezer is described, in which refrigerant leakage from the refrigeration cycle can be safely detected. The refrigerator-freezer comprises: a refrigeration cycle formed by a compressor, a capillary, an evaporator and an accumulator connected in series, and filled with a flammable refrigerant; a cooling fan configured to blow the cold air cooled by the evaporator in the refrigerator-freezer; and a refrigerant leakage detection system configured to detect leakage of the flammable refrigerant, wherein the refrigerant leakage detection system is provided with a temperature sensor configured to measure the temperature of a refrigerant conduit of the evaporator and judges that the flammable refrigerant is leaking in the low pressure side of the refrigeration cycle when the temperature is detected by the temperature sensor with the compressor being halted is no lower than a predetermined temperature.