Abstract: In a casing (11) of a humidity controller (10), a first heat exchanger chamber (37) which accommodates a first adsorption heat exchanger (51), and a second heat exchanger chamber (38) which accommodates a second adsorption heat exchanger (52) are arranged next to each other in the left-to-right direction. An indoor air side passage (32) and an outdoor air side passage (34) are provided on the rear panel portion (13) side of the heat exchanger chambers (37, 38), and a supply side passage (31) and exhaust side passage (33) are provided on the front panel portion (12) side of the heat exchanger chambers (37, 38). The rear panel portion (13) is provided with an outdoor air intake opening (24) and an indoor air intake opening (23) at locations close to a center of the rear panel portion (13) in the left-to-right direction.

Abstract: A refrigerant circuit (40) is provided with two adsorption heat exchangers (56, 57) in addition to an outdoor heat exchanger (54) and an indoor heat exchanger (55). The indoor heat exchanger (55) and the two adsorption heat exchangers (56, 57) are disposed in an indoor unit (11), while the outdoor heat exchanger (54) is disposed in an outdoor unit (12). In the adsorption heat exchanger (56, 57) serving as an evaporator, moisture in the air is adsorbed by the adsorbent. In the adsorption heat exchanger (56, 57) serving as a condenser, moisture is desorbed from the adsorbent and then applied to the air. Then, the air dehumidified or humidified by the adsorption heat exchanger (56, 57) is supplied to a room to cope with latent heat load in the room. On the other hand, in the indoor heat exchanger (55), air is cooled or heated. Then, the air cooled or heated by the indoor heat exchanger (55) is supplied to the room to cope with sensible heat load in the room.

Abstract: An optical disk drive includes a spindle motor for rotating an optical disk, and an optical pickup head. On a base plate, a pickup moving motor moves the optical pickup head in a disk radial direction. A motor plate supports the spindle motor. A spacer holder has a small thickness, and is secured to the base plate. A spacer boss is disposed to project from the spacer holder toward the motor plate. A first hole is formed through the spacer boss. A retaining screw has first and second shaft portions. A screw hole is formed in the base plate, for engagement with the first shaft portion inserted through the first hole, to retain the retaining screw. A great diameter peripheral surface is positioned at the second shaft portion, for applying pressure to fit the spacer boss tightly on the motor plate. Further, the spacer is formed from plastic material.

Abstract: A humidity controller apparatus (20) contains an adsorption rotor (24) and a heater (25). A first passage (21) along which a first air stream flows and a second passage (22) along which a second air stream flows are formed in the humidity controller apparatus (20). The amount of heat exchange between the first and second air streams and the amount of moisture exchange between the first and second air streams vary by adjustment to the rotating speed of the adsorption rotor (24), and the humidity controller apparatus (20) is switched between a dehumidification operation and a humidification/heating operation. During the dehumidification operation, the rotating speed of the adsorption rotor (24) is set low. The first air stream is dehumidified by the adsorption rotor (24) and then supplied to the inside of a room. The second air stream is used for regeneration of the adsorption rotor (24) and then discharged to the outside of the room.

Abstract: A humidity control system (10) includes a refrigerant circuit (50) in which an adsorption heat exchanger (51, 52) carrying an adsorbent thereon is connected. During a regeneration action of a humidification operation of the humidity control system (10), outdoor air passes through the adsorption heat exchanger (51, 52) from upstream towards downstream in the flow of refrigerant. Therefore, the air can be effectively increased in temperature at the air inflow end of the adsorption heat exchanger (51, 52), thereby preventing freezing of dew condensation water.

Abstract: A cell body receiving fuel supply to generate power, an inverter receiving output power of the cell body to convert it into ac power, and a vapor-compression refrigerating machine receiving the ac power output from the inverter as operating power and using a motor as its driving source are provided. An intermediate part of a connection line connecting the aforementioned inverter and vapor-compression refrigerating machine is connected to a refrigeration air-conditioning power board to make effective use of a fuel cell and to prevent the footprint and construction costs from increasing.

Abstract: An air conditioning system (1) includes a first humidity controller (10), a second humidity controller (20), a first air conditioner (30), a second air conditioner (40), and a interlock control means (3). The first humidity controller (10) humidifies an indoor perimeter zone while the second humidity controller (20) humidifies an indoor interior zone. The first air conditioner (30) heats/cools the indoor perimeter zone while the second air conditioner (40) heats/cools the indoor interior zone. Upon input of dew condensation occurrence information, the first humidity controller (10) performs a dew removal operation while the first humidity controller (20), the first air conditioner (30), and the second air conditioner (40) continue respective operations at input of the dew condensation occurrence information.

Abstract: A humidity control system (10) includes a refrigerant circuit (50) including a compressor (53), a first adsorption heat exchanger (51) carrying an adsorbent thereon, an expansion valve (55) adjustable in opening and a second adsorption heat exchanger (52) carrying an adsorbent thereon, supplies humidity-controlled air to a room by operating alternately in a first batch mode in which the second adsorption heat exchanger (52) adsorbs moisture in air and the first adsorption heat exchanger (51) releases moisture to air and a second batch mode in which the first adsorption heat exchanger (51) adsorbs moisture in air and the second adsorption heat exchanger (52) releases moisture to air, controls the opening of the expansion valve (55), sets, upon start of the first batch mode, the opening of the expansion valve (55) to that at the end of the preceding first batch mode and sets, upon start of the second batch mode, the opening of the expansion valve (55) to that at the end of the preceding second batch mode.

Abstract: In the air conditioning system (1), switching is selectively made between a normal operation where air is dehumidified by the humidity controller (10) alone according to operating conditions and a simultaneous dehumidifying operation where air is dehumidified by the humidity controller (10), while at the same time air is dehumidified by the air conditioner (20) by condensing moisture in the air.

Abstract: A humidity controller includes a differential pressure detection means (93, 97) for detecting a difference between high voltage and low voltage in a refrigeration cycle of a refrigerant circuit (50) and a control means (30) for controlling the capacity of the compressor (53). The control means (30) reduces the capacity of the compressor (53) when a detected value of the differential pressure detection means (93, 97) exceeds a reduction threshold. Further, the control means (30) stops the compressor (53) when the detected value of the differential pressure detection means (93, 97) exceeds a stop threshold higher than the reduction threshold.

Abstract: The control means (41 and 42) cause the air conditioner to start air temperature control when temperature To of the outdoor air is in a pre-set range at the time of starting the air conditioning system (1), after the lapse of a pre-set time since the humidity controller (10) started adjusting air humidity. The room temperature nears the humidity set value Rs during the time air temperature control is started in the air conditioner (20).

Abstract: A humidity control system (10) includes a refrigerant circuit (50) to which two adsorption heat exchangers (51, 52) are connected. In the humidity control system (10), air is humidified in the adsorption heat exchanger (51, 52) working as the condenser while air is dehumidified in the adsorption heat exchanger (51, 52) working as the evaporator. If during the dehumidification operation the actually measured value of the room temperature is lower than the selected value of the room temperature or if during the humidification operation the actually measured value of the room temperature is higher than the selected value of the room temperature, the performance of a compressor (53) is controlled such that the actually measured value of the room temperature equals the selected value of the room temperature.

Abstract: A humidity control system (10) includes a refrigerant circuit (50) including a compressor (53), a first adsorption heat exchanger (51) carrying an adsorbent thereon, an expansion valve (55) adjustable in opening and a second adsorption heat exchanger (52) carrying an adsorbent thereon, supplies humidity-controlled air to a room by operating alternately in a first batch mode in which the second adsorption heat exchanger (52) adsorbs moisture in air and the first adsorption heat exchanger (51) releases moisture to air and a second batch mode in which the first adsorption heat exchanger (51) adsorbs moisture in air and the second adsorption heat exchanger (52) releases moisture to air, and controls the opening of the expansion valve (55), when a valve control start time has come a predetermined time after the start of each batch mode, so that the degree of superheat of refrigerant in the refrigerant circuit (50) reaches a predetermined value.

Abstract: An air conditioning system (1) including a demand control device (10) that controls the total amount of the working power of a plurality of air conditioning loads is provided with, in order to improve comfortableness under demand control, an air conditioner (20) including a refrigerant circuit and dominantly processes an indoor sensible heat load and a humidity controller (30) which includes adsorption members (32, 33) and dominantly processes a latent heat load. According to a set level of a plurality of demand control levels, the evaporation temperature of the refrigerant circuit composing the air conditioner (20) is controlled while the indoor humidity is adjusted by the humidity controller (30).

Abstract: Heat exchangers of a refrigerant circuit 50 are constructed of a first adsorption heat exchanger 51 and a second adsorption heat exchanger 52, both of which have an adsorbent supported thereon, and are constructed so as to be switched into an evaporator and a condenser. An air passage 60 is constructed so as to be switched into states in which air flowing from the outside of a room to the inside of the room and air flowing from the inside of the room to the outside of the room flow through either of the first adsorption heat exchanger 51 and the second adsorption heat exchanger 52.

Abstract: In an input section (30), a set temperature Ts which becomes a control target temperature of a humidity controller (10), and a set relative humidity Rs which becomes a control target humidity of the humidity controller (10) are set. An air conditioning control section (42) adjusts the temperature adjusting capacity of the humidity controller (10) such that the room temperature may come very close to the set temperature Ts. Further, an arithmetic section (33) calculates, as the target absolute humidity As, the absolute humidity which becomes the relative humidity set value Rs at the set temperature Ts. A humidity adjustment section (41) adjusts the humidity adjusting capacity of the humidity controller (10) such that the absolute humidity of the room may come very close to the target absolute humidity As.

Abstract: A refrigerant circuit (40) is provided with an outdoor heat exchanger (54), an indoor heat exchanger (55) and two adsorption heat exchangers (56, 57). The indoor heat exchanger (55) is disposed in an indoor unit (11), while the outdoor heat exchanger (54) and the two adsorption heat exchangers (56, 57) are disposed in an outdoor unit (12). Moisture in outdoor air taken in the outdoor unit (12) is adsorbed by the adsorbent in the adsorption heat exchanger (56, 57) serving as an evaporator and the air is dehumidified. The dehumidified air is cooled by the indoor heat exchanger (55) serving as an evaporator and the air is supplied to the room space.

Abstract: An air conditioning device has a heat source unit and a utilization unit connected via a refrigerant connection pipe to form a refrigerant circuit, and has a cooler, a secondary receiver, and a separation membrane device. The cooler cools at least a portion of the refrigerant that flows through the liquid-side refrigerant circuit as the compressor is operated and the refrigerant in the refrigerant circuit is recirculated. The secondary receiver separates the refrigerant cooled by the cooler into a liquid refrigerant and a gas refrigerant that includes non-condensable gas. The separation membrane device has a separation membrane for separating the non-condensable gas from the gas refrigerant obtained by gas-liquid separation, and discharges the non-condensable gas thus separated to the outside of the refrigerant circuit.

Abstract: To properly control a flow rate of fluid through a flow path for heat recovery to the overall flow rate, a branch flow rate regulating part is provided that branches air between an air supply source and a heat exchanger to lead the branched air to a heat recovery path, and regulates the amount of branched air.

Abstract: An optical disk drive includes a spindle motor for rotating an optical disk, and an optical pickup head. On a base plate, a pickup moving motor moves the optical pickup head in a disk radial direction. A motor plate supports the spindle motor. A spacer holder has a small thickness, and is secured to the base plate. A spacer boss is disposed to project from the spacer holder toward the motor plate. A first hole is formed through the spacer boss. A retaining screw has first and second shaft portions. A screw hole is formed in the base plate, for engagement with the first shaft portion inserted through the first hole, to retain the retaining screw. A great diameter peripheral surface is positioned at the second shaft portion, for applying pressure to fit the spacer boss tightly on the motor plate. Further, the spacer is formed from plastic material.