EP0816779B1 - Air conditioner and moisture removing device for use with the air conditioner - Google Patents

Air conditioner and moisture removing device for use with the air conditioner Download PDF

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Publication number
EP0816779B1
EP0816779B1 EP95912460A EP95912460A EP0816779B1 EP 0816779 B1 EP0816779 B1 EP 0816779B1 EP 95912460 A EP95912460 A EP 95912460A EP 95912460 A EP95912460 A EP 95912460A EP 0816779 B1 EP0816779 B1 EP 0816779B1
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EP
European Patent Office
Prior art keywords
coolant
air conditioner
moisture
liquid
removing device
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
EP95912460A
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German (de)
English (en)
French (fr)
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EP0816779A4 (en
EP0816779A1 (en
Inventor
Takeshi Endo
Hirokiyo Terada
Naoto Katsumata
Kousaku Yagi
Kenichi Kawashima
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Hitachi Ltd
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Hitachi Ltd
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Filing date
Publication date
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Publication of EP0816779A4 publication Critical patent/EP0816779A4/en
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Publication of EP0816779B1 publication Critical patent/EP0816779B1/en
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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B13/00Compression machines, plants or systems, with reversible cycle
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B43/00Arrangements for separating or purifying gases or liquids; Arrangements for vaporising the residuum of liquid refrigerant, e.g. by heat
    • F25B43/003Filters

Definitions

  • the invention relates to a heat pump type air conditioner comprising an outdoor unit including a coolant compressor, a four-way valve, an outdoor heat exchanger and an expansion means connected in this order by pipes, at least one indoor unit including an indoor heat exchanger, which units are connected through a gas line and a liquid line to form a refrigerating cycle which is selectively operable in a cooling mode and a heating mode by changing over the four-way valve, and a moisture removing device disposed in said refrigerating cycle between said indoor heat exchanger and said expansion means or between said expansion means and said outdoor heat exchanger.
  • Such a heat pump type air conditioner of the generic kind is disclosed by EP 0 502 609 A1.
  • CFC chlorofluorocarbon
  • HCFC hydrochlorofluorocarbon
  • coolants made of one type or a mixture of plural types of HFC (hydrofluorocarbon) that contains in the molecular structure no chlorine atoms, which are causes for destruction of the ozone layer have been developed as alternative materials and studied aiming at practical use.
  • HFC materials have high intensity of polarization and exhibit almost no solubility with mineral oil and alkyl benzene-based lubricants which have been used conventionally. It is essential for a coolant to have solubility with a lubricant from the viewpoint of recirculating a lubricant in a refrigerating cycle, supplying a sufficient amount of lubricant to a mechanism section of a compressor, and ensuring reliability of the apparatus.
  • refrigerator oils containing ether-, ester- or carbonate-based materials which, when oxygen atoms are introduced thereto, exhibit solubility due to a dipole interactive action with the oxygen molecules.
  • Any type of those refrigerator oils has a high affinity with water molecules and a high degree of moisture absorption.
  • JP 63-69961 discloses a refrigerating apparatus which can be used as an air conditioner comprising a compressor, a condenser, expansion means, an evaporator and a moisture removing device, which are connected in this order.
  • the moisture removing device comprises a cylindrical container having an inlet at one end and an outlet at the opposit end and which is filled with a large number of spherical desiccants.
  • the inlet for the conventional coolant is smaller than the outlet.
  • the desiccants of the moisture removing device come into contact with the coolant exiting from the evaporator in the gas-phase.
  • JP 5-66075 corresponding to JP 3-226254 discloses a refrigerating cycle for an air conditioner for automotive vehicles comprising in this order a compressor, a condenser, an expansion device, an evaporator and a moisture removing device.
  • a fluorohydrocarbon is used as coolant.
  • the moisture removing device can be a container, in which a throughgoing perforated pipe is centrally arranged. Between the outside of this central pipe and the inner wall of the container desiccants are provided.
  • a container can be used, in the lower part of which the desiccants are held by means of a perforated plate, above which an inlet pipe and an outlet pipe empty into a free flow space in the container.
  • the moisture removing device is disposed in the low pressure line between the evaporator and the compressor so that the refrigerant at this location is in the state that the superheated gas is in saturation to have a high degree of dryness, and the contact of the refrigerant with the dryer makes the refrigerant a gaseous phase and deteriorate an ability of water absoption.
  • moisture removing devices are arranged in the gas line which means that the desiccants are contacted with coolant in its gas-phase which means high pressure loss and low efficiency with regard to reducing the moisture content.
  • Synthetic zeolite has been long known as a desiccant for removing moisture in a refrigerating cycle. Because of forming a cage-like molecular structure, synthetic zeolite has a characteristic of selectively taking in and retaining the substances, which have specific molecular diameters, within the cavities of cages as the result of a sieving effect developed by the cage-like molecular structure. Therefore, even when synthetic zeolite is employed with a fluorine-based coolant, it can adsorb only moisture without adsorbing the coolant. Then, under a condition where the density of ambient moisture is high and the velocity of motion of water molecules is low, the probability of moisture being adsorbed through the cages is increased and synthetic zeolite has a higher adsorption ability.
  • the adsorption ability of synthetic zeolite is increased by bringing the adsorbent and the coolant into contact with each other in a state of liquid phase where the density is higher, the flow speed is smaller, and the velocity of molecular motion is lower than in a state of gas phase.
  • an air conditioner which is gentle to the global environment can be provided with no need of greatly modifying a conventional apparatus.
  • HFC materials have a high global worming factor and hence it is required to reduce an absolute amount of HFC materials enclosed in a refrigerating apparatus.
  • a heat pump type air conditioner of the generic kind uses a coolant made of at least one type of fluorohydrocarbon containing no chlorine atoms, in that a partition means is included in said moisture removing means for partition into a flow passage for the coolant and a moisture absorber holding portion, and in that a control means is provided for controlling the expansion means so as to make the coolant after condensation in the indoor heat exchanger or in the outdoor heat exchanger to become a two-phase flow of gas and liquid.
  • the flow in the liquid coolant line as part of the refrigerant cycle is usually a two-phase flow during operation of the refrigerating cycle, in which two-phase flow the moisture removing or absorbing means is disposed.
  • the moisture absorbing means can develop separate functions such that moisture is absorbed in liquid phase and the gas coolant flows fast.
  • the heat pump type air conditioner produces a low pressure loss and has a high reliability using a HFC-based coolant that is fit for protection of the global environment, and as a working oil for instance an ester-based lubricant.
  • a further expansion means can be associated with said indoor unit wherein said moisture removing means is disposed between the two expansion means.
  • the moisture removing device comprises an enclosed container connected with an inlet pipe and an outlet pipe for the coolant, an inner pipe disposed in the container defining the flow passage in communication with the pipes for the coolant and having a diameter which is equal to that of the connected pipes for the coolant or more than that, and desiccants held between the inner pipe and the container.
  • the moisture removing device is a gas/liquid separator having in a lower portion desiccants held by the partition means.
  • the desiccants consist of synthetic zeolite with absorbing molecules having a mean diameter of 0,31 nm (3,1 ⁇ ) or less.
  • the moisture removing device may include indicator means for indicating its moisture content.
  • the heat pump type air conditioner of the present invention is gentle to the global environment because the coolant that does not destroy the ozone layer is employed and the amount of coolant enclosed in the refrigerating cycle is cut down. Even though the coolant flow is a two-phase flow, the moisture removing device is disposed in a low-pressure flow area where it produces a small pressure loss, and the moisture removing means comprises a moisture retaining portion and a main passage portion. Therefore, a pressure loss caused by the coolant flow can be reduced and moisture can be removed from the working coolant with high efficiency. Additionally, since fluid force acting on the desiccant held by the moisture retaining portion can be reduced without using a complicated structure, it is possible to prevent the desiccant from being pulverized into powder due to abrasion caused by fluid friction, vibration, etc.
  • the air conditioner does not require the expansion means to be changed over depending on whether the operation is in the mode of cooling or heating, and requires just one expansion means.
  • the flow in the line where the moisture removing device is disposed can be either a liquid one-phase flow or a gas and liquid two-phase flow.
  • the moisture removing device develops small fluid resistance for any of those flows, the desiccant is prevented from being pulverized into powder. Also, the moisture removing device does not reduce its ability of removing moisture in any of those flow states.
  • the provision of the gas/liquid separator enables the desiccant to be placed in a passage where only the liquid coolant flows, or in a liquid pool. Therefore, moisture in the working coolant can be effectively removed under a condition of low pressure loss.
  • the coolant can be surely discriminated from water molecules and the amount of coolant molecules adsorbed by the desiccant can be made sufficiently small. Further, the action and motion of the desiccant can be confirmed.
  • the construction enabling the desiccant to be easily replaced also contributes to improving reliability of the liquid refrigerating cycle and the moisture absorbing means.
  • synthetic zeolite used as desiccants is desirably selected such that absorbing molecules have a mean diameter of 0,31 nm (3.1 angstroms) or less, when the coolant is provided by a coolant containing HPC32, e.g., any of coolants having such numbers defined by ASHRAE as a series of R407 (mixture of three types of HFC32/HFC125/HFC134a) and a series of R410 (mixture of two types of HFC32/HFC125).
  • ASHRAE any of coolants having such numbers defined by ASHRAE as a series of R407 (mixture of three types of HFC32/HFC125/HFC134a) and a series of R410 (mixture of two types of HFC32/HFC125).
  • HFC32 has a minimum mean diameter of molecules as small as 0,33 nm (3.3 angstroms); and water molecules have a diameter of 0,28 nm (2.8 angstroms). Then, an intermediate value between those two diameters is selected here.
  • an intermediate value between those two diameters is selected here.
  • water molecules are surely adsorbed, but the HFC coolant will never be adsorbed by zeolite in theory. This means that even the coolant containing HFC32 is hardly adsorbed by synthetic zeolite, the moisture absorbing ability of desiccants is not lowered, and the coolant is not decomposed. Consequently, the moisture removing device and the air conditioner using the moisture removing device are improved in reliability.
  • the coolant that does not destroy the ozone layer is employed, the amount of that coolant to be enclosed in the refrigerating cycle can be cut down, and moisture present in the refrigerating cycle can be reduced. Then, an air conditioner which minimizes an effect upon the global environment, is less expensive and has high reliability can be realized.
  • a combination of the gas/liquid separator and the moisture removing device enables moisture to be removed without needing a special structure for reducing a pressure loss, while preventing the desiccants being pulverized into powder and deteriorating. Therefore, conventional drier manufacturing equipment can be employed without any modifications, which is effective in manufacturing the air conditioner less expensively.
  • the amount of coolant adsorbed by the desiccants can be made sufficiently small, it is possible to prevent the coolant from decomposing and producing acids, to suppress not only chemical wear of the mechanism sections of both the air conditioner and the water removing device, but also decomposition of the desiccants, and to realize a highly reliable air conditioner.
  • the air conditioner and the water removing device can be surely and easily improved in reliability.
  • Fig. 1 is a typical view of a refrigerating cycle of a heat pump type air conditioner.
  • An outdoor unit 11 is made up of a four-way valve 3, an accumulator 2, a coolant compressing apparatus 1 represented by an inverter driven scroll compressor, an outdoor heat exchanger 4, an outdoor expansion device 6 represented by an electromagnetic expansion valve, and a drier 7 which are connected in order through piping lines.
  • an indoor unit 12 is made up of an indoor expansion device 8 and an indoor heat exchanger 9 which are connected through piping lines. The outdoor unit and the indoor unit are connected each other through a gas line 13 and a liquid line 14, thereby making up a refrigerating cycle.
  • an outdoor blower 5 is provided to blow air to the outdoor heat exchanger of the outdoor unit
  • an indoor blower 10 is provided to blow air to the indoor heat exchanger of the indoor unit.
  • the indoor and outdoor units also include sensors for control of their constituent devices, controllers for controlling the constituent devices based on outputs of the sensors, and remote control switches.
  • the drier 7 comprises a container 21, a coolant passage 23 formed in a central portion of the container 21 and allowing a coolant to pass through it, and desiccants 22 stored in a space defined between the container 21 and the coolant passage 23. Then, pipes of the adjacent lines are connected to both ends of the container 21 opposite to each other in the direction of passage of the coolant.
  • the heat pump type air conditioner utilizes a vapor pressure refrigerating cycle and is operated selectively in one mode of cooling and heating by changing over the four-way valve 3.
  • the air conditioner employs, as a working coolant, HFC (fluorohydrocarbon) that does not destroy the ozone layer.
  • the HFC coolant is given by one type or a mixture of plural types selected from among HFC32 (difluoromethane), HFC125 (pentafluoroethane), HFC134a (1, 1, 1, 2 - totrafluoroethane) and HFC143a (1, 1, 2 - trifluoroethane).
  • the air conditioner employs, as refrigerator oil, any of ester-, ether- or carbonate-based refrigerator oils which, when oxygen atoms are introduced to molecular structures thereof, exhibit solubility with the HFC-based coolant.
  • the air conditioner constructed as described above operates as follows. First, in the mode of cooling operation, a high-temperature, high-pressure gas coolant delivered from the coolant compressing apparatus 1 is introduced to the outdoor heat exchanger 4 serving as a condenser where the gas coolant is converted into a liquid coolant through processes of heat radiation, condensation and supercooling.
  • the liquid coolant is subject to a pressure reduction in the outdoor expansion device 6 under control of the controller for coming into a gas and liquid two-phase flow.
  • the coolant in this state passes through the drier 7, flows through the liquid line 14, and then reaches the indoor unit 12.
  • the coolant is subject to a further pressure reduction in the indoor expansion device 8 to have a lower pressure and a lower temperature.
  • the resultant coolant is introduced to the indoor heat exchanger 9 serving as an evaporator where the coolant is evaporated while absorbing heat, and undergoes heat exchange with indoor air for cooling an indoor space. Further, the coolant enters the outdoor unit 11 through the gas line 13, passes through the four-way valve 3 and the accumulator 2 successively, and is sucked by the coolant compressing apparatus 1, thus completing one round of a refrigerating cycle. In the mode of heating operation, the four-way valve 3 is changed over so that a high-temperature, high-pressure gas coolant delivered from the coolant compressing apparatus 1 is introduced to the indoor unit 12 through the gas line 13.
  • the coolant undergoes heat exchange with indoor air to radiate heat to the indoor space for heating.
  • the liquid coolant having been condensed and supercooled in the indoor heat exchanger 9 is subject to a pressure reduction in the indoor expansion device 8 under control of the controller for coming into a gas and liquid two-phase flow.
  • the coolant in this state flows through the liquid line 14 and passes through the drier 7.
  • the coolant is subject to a further pressure reduction in the outdoor expansion device 6 to have a lower pressure and a lower temperature.
  • the resultant coolant is introduced to the outdoor heat exchanger 4 serving now as an evaporator where it is evaporated while absorbing heat. After that, the coolant passes through the four-way valve 3 and the accumulator 2 successively, and is sucked by the coolant compressing apparatus 1, thus completing one round of a refrigerating cycle.
  • the amount of coolant to be passed through the liquid line 14 extending over a relatively long distance for interconnection between the outdoor unit 11 and the indoor unit 12 can be reduced corresponding to mixing of the gas coolant having low density in the liquid coolant as compared with the case of the coolant being passed through the liquid line 14 in one phase of supercooled liquid. Accordingly, the amount of coolant enclosed in the refrigerating cycle can be made smaller than that required for a full-liquid system in which the liquid line is fully filled with the liquid coolant.
  • Synthetic zeolite capable of selectively adsorbing only moisture in the refrigerating cycle is sintered with a binder and formed into a cylindrical core which serves as a moisture retaining portion 22.
  • the drier 7 is formed by enclosing the moisture retaining portion 22 in the container 21 and then coupling the opposite ends of the container 21 to the pipes of the adjacent lines.
  • the inner diameter of the moisture retaining portion 22 corresponding to the coolant passage 23 is selected to be equal to or more than that of the pipes upstream and downstream of the drier 7.
  • the moisture retaining portion 22 made of porous zeolite is adsorbed by the moisture retaining portion 22 made of porous zeolite. Therefore, the moisture content in the refrigerating cycle is gradually reduced.
  • the inner diameter of the coolant passage 23 of the drier 7 is equal to or more than that of the pipes upstream and downstream of the drier 7, a pressure loss is not increased remarkably even though the coolant in the gas and liquid two-phase state passes through the drier 7.
  • the moisture retaining portion 22 is not subject to large fluid force otherwise caused by flow of the coolant, the desiccants can be prevented from being pulverized into powder due to friction, vibration, etc.
  • the amount of enclosed coolant is reduced, the amount of coolant that may affect destruction of the ozone layer or global warming can be cut down. Further, since the amount of moisture in the refrigerating cycle that is a factor of lowering the reliability can be reduced, it is possible to provide an air conditioner which is effective for protection of the global environment and is highly reliable.
  • the modification of Fig. 3 differs from the embodiment of Fig. 1 in that the drier 7 is disposed between the outdoor heat exchanger 4 and the outdoor expansion device 6, and the indoor expansion device 8 is omitted. Also in this modification, the drier 7 has the same structure adapted for a low pressure loss as in the embodiment of Fig. 2. Therefore, the desiccants can be prevented from being pulverized into powder even when the coolant flows through the drier 7 as a gas and liquid two-phase flow.
  • Fig. 4 shows a first modification wherein the drier 7 comprises a container 31 having both ends to which connecting pipes are jointed, a moisture retaining portion 32 storing desiccants therein, a fixed plate 33 for dividing an inner space of the container 31 into a main flow passage and the moisture retaining portion 32, and a spring 34 for positioning the fixed plate in place.
  • the installation position of the drier in the refrigerating cycle and the operation of the refrigerating cycle are the same as in the embodiment of Fig. 1.
  • a large number of desiccants obtained by forming synthetic zeolite into bead-like granules are enclosed in a lower portion of the container 31 to serve as the moisture retaining portion 32.
  • the fixed plate 33 is held down by the spring 34.
  • the fixed plate 33 has a large number of holes formed therein and being smaller than the diameter of the desiccant beads, allowing the coolant to flow through the holes. Therefore, only a liquid phase portion of the coolant in the state of a two-phase flow passing an upper portion of the container 31 resides in the container 31 and comes into contact with the moisture retaining portion 32.
  • the inner space of the container 31 is thus divided into an upper area where the coolant flows and a lower area where the desiccants are present, a pressure loss is small and the desiccants are not exposed to the coolant flow at a high speed. As a result, the desiccants are prevented from being pulverized into powder. Further, the desiccants and the coolant are contacted with each other in a liquid state providing good adsorption efficiency, and the coolant residing in the container is replaced by new one successively under an action of the coolant flow. Accordingly, the desiccants can effectively develop an ability of adsorbing moisture and can quickly reduce the moisture content in the refrigerating cycle.
  • Fig. 5 shows another modification of the drier wherein dryness of the coolant can be visually confirmed and the moisture retaining portion can be easily replaced.
  • This modification differs from the modification of Fig. 4 in additionally comprising a sight glass 36, a moisture content sensor 37, a joint portion 38, and a shield sheet 39.
  • the moisture content sensor 37 is formed by making a substance of which color changes depending on the moisture content, e.g., cobalt chloride, fixedly impregnated in a sheet, and is arranged so that a drying state of the refrigerating cycle can be visually confirmed through the sight glass 36.
  • the joint portion 38 has a screw fastening structure enabling a lower portion of the container to be removed optionally.
  • the drier having the above construction it is possible to confirm that moisture is surely removed, and to easily replace the desiccants when the coolant is replaced or added at the time of repair of troubles or maintenance. As a result, the moisture adsorbing ability can be restored and the reliability can be ensured.
  • an inner pipe 46 having substantially the same diameter as the connecting pipes is disposed in a container 41 and coupled to the connecting pipes.
  • bead-like desiccants are stored to serve as a moisture retaining member 42.
  • a fixed plate 43 secured by caulking at one end of the space in the direction of coolant flow
  • a movable plate 44 on the side nearer to the other end of the space in the direction of coolant flow
  • a spring 45 interposed between the movable plate 44 and an inner wall of the container 41.
  • the desiccants are stored in a space defined between the fixed plate 43 and the movable plate 44.
  • the moisture retaining member 42 is fast held in that space by resilient force of the spring 45.
  • Each of the fixed plate 43, the movable plate 44 and the inner tube 46 has a large number of holes formed therein and being smaller than the diameter of the desiccant beads, allowing the coolant to freely pass through the holes.
  • FIG. 7 shows an example employing a gas/liquid separator.
  • a coolant inlet pipe 54 for introducing the coolant into the container 51
  • a coolant outlet pipe 55 for introducing the coolant from the interior of the container 51 to the exterior thereof. Distal ends of these two pipes reach a position near the bottom surface of the container 51.
  • the coolant in liquid phase is filled in the container up to a level intermediate the container and the coolant in gas phase is filled in a space of the container above the liquid coolant.
  • Gas coolant mixing holes 56 and 57 are formed respectively in the coolant inlet pipe 54 and the coolant outlet pipe 55 so that the liquid coolant extracted from the lower portion of the container 51 is added with the gas coolant present in the upper portion of the container 51 to keep a certain degree of dryness in the coolant.
  • Bead-like desiccants 52 are held by a desiccant retaining member in the lower portion of the container 51 where the coolant in liquid phase is filled, while the liquid coolant is allowed to freely pass among the bead-like desiccants 52.
  • the desiccants 52 are held in place by a desiccant retaining member 53 in the form of a net cage, for example.
  • the desiccants 52 are placed in the liquid coolant flowing into the container 51 and dispersing at a low speed, they are prevented from being pulverized into powder and can be used in a liquid contact state providing good adsorption efficiency.
  • the gas/liquid separator also has a function of adjusting the amount of coolant when it is installed in the liquid line of the refrigerating cycle operated utilizing a gas and liquid two-phase flow.
  • the drier of this modification operates exactly in the same manner as described above regardless of which one of the two pipes 54, 55 inserted in the container 51 serves as the coolant introducing pipe.
  • Fig. 8 shows a modification of the gas/liquid separator shown in Fig. 7. This modification is suitable for use in the refrigerating cycle where the coolant flows only in one direction.
  • the coolant in liquid phase is filled in a lower portion of the container 61 and the coolant in gas phase is filled in a space of the container above the liquid coolant.
  • the coolant in the gas and liquid two-phase state flowing through an introducing pipe 63 inserted into an upper portion of the container 61 is separated into a liquid and gas in the container 61.
  • a drier 62 which may be conventional one is installed in a liquid outlet pipe 64 which is inserted into the lower portion of the container filled with the liquid coolant and permits only the liquid coolant to pass through it, thereby removing moisture contained in the coolant.
  • a pipe portion above the drier 62 and the upper portion of the container 61 are communicated with each other by a gas outlet pipe 65 to prevent the gas coolant from building up excessively in the gas/liquid separator.

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Mechanical Engineering (AREA)
  • Thermal Sciences (AREA)
  • General Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Analytical Chemistry (AREA)
  • Power Engineering (AREA)
  • Drying Of Gases (AREA)
  • Central Air Conditioning (AREA)
  • Compression-Type Refrigeration Machines With Reversible Cycles (AREA)
EP95912460A 1995-03-17 1995-03-17 Air conditioner and moisture removing device for use with the air conditioner Expired - Lifetime EP0816779B1 (en)

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
PCT/JP1995/000481 WO1996029554A1 (fr) 1995-03-17 1995-03-17 Conditionneur d'air a absorbeur d'humidite integre

Publications (3)

Publication Number Publication Date
EP0816779A1 EP0816779A1 (en) 1998-01-07
EP0816779A4 EP0816779A4 (en) 1998-08-05
EP0816779B1 true EP0816779B1 (en) 2003-08-27

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EP95912460A Expired - Lifetime EP0816779B1 (en) 1995-03-17 1995-03-17 Air conditioner and moisture removing device for use with the air conditioner

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Country Link
EP (1) EP0816779B1 (ja)
JP (1) JP3435164B2 (ja)
DE (1) DE69531631T2 (ja)
ES (1) ES2202353T3 (ja)
WO (1) WO1996029554A1 (ja)

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MY125381A (en) 2000-03-10 2006-07-31 Sanyo Electric Co Refrigerating device utilizing carbon dioxide as a refrigerant.
EP1363088B1 (en) * 2002-05-08 2006-07-26 Finber S.p.A Receiver drier
DE10338526A1 (de) 2002-08-31 2004-03-11 Behr Gmbh & Co. Kg Sammler für ein Kältemittel, Wärmetauscher, Kältemittelkreislauf und Verfahren zur Herstellung eines Sammlers
KR20130092492A (ko) * 2012-02-09 2013-08-20 매니토웍 푸드서비스 컴퍼니즈, 엘엘씨 저비용 고효율 제빙기
US10151522B2 (en) 2016-01-27 2018-12-11 Haier Us Appliance Solutions, Inc. Microchannel condenser and dual evaporator refrigeration system
US11619405B1 (en) 2022-01-27 2023-04-04 Greg Drenik Airflow moisture reduction system

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Publication number Publication date
WO1996029554A1 (fr) 1996-09-26
DE69531631D1 (de) 2003-10-02
DE69531631T2 (de) 2004-06-17
JP3435164B2 (ja) 2003-08-11
EP0816779A4 (en) 1998-08-05
EP0816779A1 (en) 1998-01-07
ES2202353T3 (es) 2004-04-01

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