Abstract: A heat storage system includes a compressor that compresses refrigerant; a heat storage tank that stores a heating medium; heat exchange means provided outside the heat storage tank for heating the heating medium using heat of the refrigerant compressed by the compressor; a heat accumulating circuit including a feed path that feeds the heating medium flowing out of the heat storage tank to the heat exchange means, a return path that returns the heating medium heated by the heat exchange means into the heat storage tank, and a pump that circulates the heating medium; and control means capable of executing an initial operation that controls an operating frequency of the compressor at the beginning of a heat accumulating operation in which the heating medium heated by the heat exchange means is accumulated in the heat storage tank.

Abstract: Provided is a heat pump hot water supply apparatus configured to directly supply water heated by a gas cooler to a utilization side. The heat pump hot water supply apparatus is configured to execute operation modes including a first operation mode and a second operation mode. The first operation mode includes causing the water heated by the gas cooler to return to a water tank as intermediate-temperature water. The second operation mode is an operation mode to be performed after the first operation mode, and includes mixing the water heated by the gas cooler and the intermediate-temperature water in the water tank, and directly supplying the mixed water to the utilization side.

Abstract: A heat pump device includes a compressor, a motor, a shell, a muffler, a heat exchanger, a housing, a blower, a first insulating material, and a second insulating material. The compressor compresses refrigerant. The motor drives the compressor. The shell houses the motor and the compressor. The compressor is connected to the muffler, which is further connected to heat exchanger. The housing has first and second spaces. The shell, the heat exchanger, and the muffler are disposed in the first space. The blower is disposed in the second space. The muffler is entirely located within a space between the shell and the first heat exchanger. The first insulating material at least partially cover the discharge muffler and the first heat exchanger. The second insulating material at least partially cover the shell. The first insulating material has a higher thermal resistance than the second insulating material.

Abstract: A heat pump device includes a compression mechanism for compressing refrigerant, a motor for driving the compression mechanism, a shell housing the compression mechanism and the motor, a discharge muffler located outside the shell, a first pipe connecting the compression mechanism to the discharge muffler, and a thermal insulator (a first thermal insulating material and a second thermal insulating material). The shell and the discharge muffler are spatially located next to each other without being in contact with each other. The thermal insulator is at least partially located in a space where a distance between an outer surface of the shell and an outer surface of the discharge muffler is minimum.

Abstract: Provided is a heat pump hot water supply apparatus configured to directly supply water heated by a gas cooler to a utilization side. The heat pump hot water supply apparatus is configured to execute operation modes including a first operation mode and a second operation mode. The first operation mode includes causing the water heated by the gas cooler to return to a water tank as intermediate-temperature water. The second operation mode is an operation mode to be performed after the first operation mode, and includes mixing the water heated by the gas cooler and the intermediate-temperature water in the water tank, and directly supplying the mixed water to the utilization side.

Abstract: A heat pump device includes a compression mechanism for compressing refrigerant, a motor for driving the compression mechanism, a shell housing the compression mechanism and the motor, a discharge muffler located outside the shell, a first pipe connecting the compression mechanism to the discharge muffler, and a thermal insulator (a first thermal insulating material and a second thermal insulating material). The shell and the discharge muffler are spatially located next to each other without being in contact with each other. The thermal insulator is at least partially located in a space where a distance between an outer surface of the shell and an outer surface of the discharge muffler is minimum.

Abstract: A heat pump device includes: a compression mechanism for compressing refrigerant; a motor for driving the compression mechanism; a shell housing the compression mechanism and the motor; a discharge muffler located outside the shell, a first pipe which connects the compression mechanism to the discharge muffler; a first heat exchanger which includes a refrigerant inlet and which exchanges heat between the refrigerant and a heating medium; and a second pipe which connects the discharge muffler to the refrigerant inlet of the first heat exchanger. The shell and the discharge muffler are spatially located next to each other. The discharge muffler and the first heat exchanger are spatially located next to each other. The discharge muffler is at least partially located in a space between the shell and the first heat exchanger.

Abstract: This invention provides a method and an apparatus for direct formation of a stripe pattern on a textile substrate such as sliver. The object of the invention is to dispense with a gill which would interfere with a high-speed feed of said textile substrate and thereby improve the efficiency of coloration. In accordance with this invention, a color supply hollow drum (2) and a color suction hollow drum (3) are vetically juxtaposed and a continuous length of fibrous material is continuously fed between said two drums (2), (3) by rotation thereof. As the substrate material is thus fed, a color composition is supplied from color supply grooves (8) of the color supply hollow drum (2) while it is drawn by a suction force acting in color suction grooves (13) of the color suction hollow drum (3) to cause the color composition to strike through the fibrous substrate material to thereby form color stripes of substantially the same configuration as that of the above-mentioned grooves on the fibrous substrate material.

Abstract: This invention provides a method and an apparatus for direct formation of a stripe pattern on a textile substrate such as sliver. The object of the invention is to dispense with a gill which would interfere with a high-speed feed of said textile substrate and thereby improve the efficiency of coloration. In accordance with this invention, a color supply hollow drum 2 and a color suction hollow drum 3 are vertically juxtaposed and a continuous length of fibrous material is continuously fed between said two drums 2, 3 by rotation thereof. As the substrate material is thus fed, a color composition is supplied from color supply grooves 8 of the color supply hollow drum 2 while it is drawn by a suction force acting in color suction grooves 13 of the color suction hollow drum 3 to cause the color composition to strike through the fibrous substrate material to thereby form color stripes of substantially the same configuration as that of the above-mentioned grooves on the fibrous substrate material.