Heat-pump water heater

The invention claimed is: 1 . A heat-pump water heater comprising: a refrigerant circuit in which refrigerant circulates through refrigerant pipes; a water circuit in which water circulates through water pipes; and a controller configured to control components provided in the refrigerant circuit and components provided in the water circuit, wherein the refrigerant circuit includes a main circuit and a bypass circuit, wherein the main circuit is formed such that components in the main circuit are sequentially connected, and includes a compressor configured to compress the refrigerant sucked in to the compressor, and discharge the refrigerant which is compressed, a water heat exchanger configured to cause heat exchange to be performed between the refrigerant which flows in the refrigerant circuit and the water which flows in the water circuit, a first pressure-reducing device configured to reduce a pressure of the refrigerant, and an air heat exchanger including heat exchange circuitry and a fan, the heat exchange circuitry being configured to cause heat exchange to be performed between air and the refrigerant, the fan being configured to send to the heat exchange circuitry, the air which is subjected to the heat exchange with the refrigerant, wherein the refrigerant pipes include a first refrigerant pipe between the compressor and the water heat exchanger and a second refrigerant pipe between the air heat exchanger and the compressor, wherein the bypass circuit forms a flow passage that connects the first refrigerant pipe between the compressor and the water heat exchanger and the second refrigerant pipe between the air heat exchanger and the compressor, the bypass circuit including a second pressure-reducing device configured to adjust a flow rate of the refrigerant which flows in the bypass circuit, wherein the water circuit includes a hot water tank configured to store water supplied from the outside and heated water, a water pump configured to supply water that flows out from the hot water tank to the water heat exchanger and supply water that flows out from the water heat exchanger to the hot water tank, and the water heat exchanger, wherein the controller is configured to perform controls in a night-time hot-water supply mode different from controls in a normal hot-water supply mode, in the night-time hot-water supply mode which is during night-time, the water is heated by the heat exchange between the water and the refrigerant in the water heat exchanger, and the water which is heated is stored in the hot water tank, one of the controls in the night-time hot-water supply mode being performed to cause the water pump to operate with a lowest frequency set in advance, an other one of the controls in the night-time hot-water supply mode being performed to cause the compressor to operate with a lowest frequency set in advance, the other one of the controls being performed to stop the fan. 2 . The heat-pump water heater of claim 1 , further comprising: a discharge temperature sensor configured to detect a pipe temperature of the first refrigerant pipe which is connected with a discharge port of the compressor; a suction temperature sensor configured to detect a pipe temperature of the second refrigerant pipe which is connected with a suction port of the compressor; a compressor temperature sensor configured to detect a temperature of lower part of a shell container that forms an outer shell of the compressor; a water temperature sensor configured to detect a temperature of the water stored in the hot water tank; a high pressure sensor configured to detect a pressure of the refrigerant discharged from the compressor; and a low pressure sensor configured to detect a pressure of the refrigerant which is sucked into the compressor, wherein the controller is configured to, in the night-time hot-water supply mode, calculate a discharge superheat degree from a difference between a discharge pipe temperature of the compressor that is detected by the discharge temperature sensor and a saturated gas temperature of the refrigerant that is calculated from the pressure detected by the high pressure sensor, calculate a suction superheat degree from a difference between a suction pipe temperature of the compressor that is detected by the suction temperature sensor and a saturated gas temperature of the refrigerant that is calculated from the pressure detected by the low pressure sensor, calculate a compressor-shell lower-part superheat degree from a difference between the temperature of the lower part of the shell container that is detected by the compressor temperature sensor and a saturated gas temperature of the refrigerant that is calculated from the pressure detected by the low pressure sensor, control, when the discharge superheat degree is less than a first threshold set in advance, an opening degree of the first pressure-reducing device and an opening degree of the second pressure-reducing device, to set the opening degree of the first pressure-reducing device to an opening degree set in advance, such that the opening degree of the first pressure-reducing device is decreased from a current opening degree thereof, and to set the opening degree of the second pressure-reducing device to an opening degree set in advance, such that the opening degree of the second pressure-reducing device is increased from a current opening degree thereof, control, when the suction superheat degree is less than a second threshold set in advance, the opening degree of the first pressure-reducing device and the opening degree of the second pressure-reducing device, to set the opening degree of the first pressure-reducing device to an opening degree set in advance, such that the opening degree of the first pressure-reducing device is decreased from the current opening degree thereof, and to set the opening degree of the second pressure-reducing device to an opening degree set in advance, such that the opening degree of the second pressure-reducing device is increased from the current opening degree thereof, and control, when the compressor-shell lower-part superheat degree is less than a third threshold set in advance, the opening degree of the first pressure-reducing device and the opening degree of the second pressure-reducing device, to set the opening degree of the first pressure-reducing device to an opening degree set in advance, such that the opening degree of the first pressure-reducing device is decreased from the current opening degree thereof, and to set the opening degree of the second pressure-reducing device to an opening degree set in advance, such that the opening degree of the second pressure-reducing device is increased from the current opening degree thereof. 3 . The heat-pump water heater of claim 2 , wherein the refrigerant pipes include a third refrigerant pipe between the water heat exchanger and the first pressure-reducing device, the refrigerant circuit further includes a second bypass circuit that forms a flow passage connecting the third refrigerant pipe between the water heat exchanger and the first pressure-reducing device and the second refrigerant pipe between the air heat exchanger and the compressor, wherein the second bypass circuit includes a third pressure-reducing device configured to adjust a flow rate of the refrigerant that flows in the second bypass circuit. 4 . The heat-pump water heater of claim 3 , wherein the controller is configured to: control, when the discharge superheat degree is less than the first threshold set in advance, an opening degree of the third pressure-reducing device to set the opening degree of the third pressure-reducing device to an opening degree set in advance, such that the opening degree of the third pressure-reducing device is increased from a current openin