JP4370478B2 - Refrigeration cycle equipment - Google Patents

Refrigeration cycle equipment Download PDF

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JP4370478B2
JP4370478B2 JP2007084909A JP2007084909A JP4370478B2 JP 4370478 B2 JP4370478 B2 JP 4370478B2 JP 2007084909 A JP2007084909 A JP 2007084909A JP 2007084909 A JP2007084909 A JP 2007084909A JP 4370478 B2 JP4370478 B2 JP 4370478B2
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filter
refrigerant
refrigeration cycle
compressor
receiver
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JP2008241196A (en
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宏明 坪江
憲一 中村
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Hitachi Appliances Inc
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    • 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
    • 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
    • F25B2400/00General features or devices for refrigeration machines, plants or systems, combined heating and refrigeration systems or heat-pump systems, i.e. not limited to a particular subgroup of F25B
    • F25B2400/18Refrigerant conversion
    • 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
    • F25B2500/00Problems to be solved
    • F25B2500/01Geometry problems, e.g. for reducing size

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  • Chemical & Material Sciences (AREA)
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  • Power Engineering (AREA)
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  • Mechanical Engineering (AREA)
  • Thermal Sciences (AREA)
  • General Engineering & Computer Science (AREA)
  • Compressor (AREA)
  • Applications Or Details Of Rotary Compressors (AREA)
  • Lubricants (AREA)
  • Heat-Exchange Devices With Radiators And Conduit Assemblies (AREA)

Description

本発明は、冷凍サイクル装置に係り、特に、固形異物及び液状不純物が残留した既設配管を再利用するのに好適な冷凍サイクル装置に関する。   The present invention relates to a refrigeration cycle apparatus, and more particularly to a refrigeration cycle apparatus suitable for reusing existing piping in which solid foreign matters and liquid impurities remain.

圧縮機と、熱源機側熱交換器と、膨張装置と、利用側熱交換器とを、液冷媒配管及びガス冷媒配管で接続して冷凍サイクルを形成する冷凍サイクル装置として、例えば空気調和機が知られている。   As a refrigeration cycle device that forms a refrigeration cycle by connecting a compressor, a heat source device side heat exchanger, an expansion device, and a use side heat exchanger with a liquid refrigerant pipe and a gas refrigerant pipe, for example, an air conditioner Are known.

空気調和機では、環境問題への対応などにより、冷媒としてCFC系冷媒又はHCFC系冷媒などを使用し、冷凍機油として鉱油などを使用する従来の空気調和機(以下、旧機という)から、鉱油などとは相溶性のないHFC系冷媒と、HFC系冷媒用の冷凍機油を使用する新しい空気調和機(以下、新機という)へ交換する需要が高まっている。この交換の際、旧機の室内機と室外機とを接続していた既設の冷媒配管を再利用することが行われている。   In air conditioners, in response to environmental problems, mineral oil is used from conventional air conditioners that use CFC refrigerant or HCFC refrigerant as refrigerant and mineral oil as refrigeration oil. There is an increasing demand for replacement with a new air conditioner (hereinafter referred to as a new machine) that uses a HFC refrigerant that is not compatible with the above and a refrigerating machine oil for the HFC refrigerant. At the time of this replacement, the existing refrigerant piping that connects the old indoor unit and the outdoor unit is reused.

ところが、再利用される接続配管の内部には、新機に使用したHFC系冷媒とは不溶、又は弱溶解成分である旧機に封入された冷凍機油(鉱油、アルキルベンゼンなど)、冷凍機油の酸化劣化反応物、塩素系化合物などの汚染物質(液状の不純物)が残留する場合がある。   However, inside the connection pipe to be reused, refrigerating machine oil (mineral oil, alkylbenzene, etc.) enclosed in the old machine that is insoluble or weakly soluble in the HFC refrigerant used in the new machine, oxidation of the refrigerating machine oil Contaminants (liquid impurities) such as degradation reactants and chlorine compounds may remain.

さらに、旧機に搭載された冷媒圧縮機の摺動部にて著しい摩耗が生じた場合、多量の摩耗粉起因の固形異物が発生し、ガス冷媒及び冷凍機油と共に冷媒圧縮機外に吐出され、再利用される接続配管内に残留する。   Furthermore, when significant wear occurs in the sliding part of the refrigerant compressor mounted on the old machine, a large amount of solid foreign matter due to wear powder is generated and discharged out of the refrigerant compressor together with gas refrigerant and refrigeration oil, It remains in the connection pipe that is reused.

このような不純物及び固形異物に対して何も対策を施さず既設配管を再利用すると、不純物による新機内の冷凍機油の劣化や、固形異物が新機に搭載した冷媒圧縮機に混入することによる冷媒圧縮機の摺動部の摩耗の促進などにより、空気調和機の信頼性を著しく損なうおそれがある。
このうち、新機内の冷凍機油の劣化に対しては、真空引き時に配管内に新機内と同じ冷凍機油を封入して、新機内の冷凍機油に対する接続配管内に残留した不純物の濃度を許容値以下に設定する施工方法が、例えば特許文献1に記載されている。また、接続配管を利用するに際して、接続配管内に残留した不純物を回収する洗浄運転を実施することが、例えば特許文献2に記載されている。
If existing pipes are reused without taking any countermeasures against such impurities and solid foreign matters, it may be caused by deterioration of refrigeration oil in the new machine due to impurities, or solid foreign matters mixed into the refrigerant compressor installed in the new machine. There is a risk that the reliability of the air conditioner may be significantly impaired due to the accelerated wear of the sliding portion of the refrigerant compressor.
Among these, for the deterioration of refrigerating machine oil in the new machine, the same refrigerating machine oil as in the new machine is enclosed in the pipe when evacuating, and the concentration of impurities remaining in the connection pipe for the refrigerating machine oil in the new machine is allowed. The construction method set below is described in Patent Document 1, for example. Further, for example, Patent Document 2 discloses that a cleaning operation for collecting impurities remaining in the connection pipe is performed when the connection pipe is used.

また、固形異物による新機の冷媒圧縮機の摺動部摩耗に対しては、多量の固形異物が冷媒圧縮機に流入しないようにストレーナなどを新機熱源側ユニットと接続配管との間に設置することが知られている。ここで使用するストレーナとしては、例えば特許文献3に記載されているものがある。   In addition, a strainer, etc. is installed between the new heat source unit and the connection piping so that a large amount of solid foreign matter does not flow into the refrigerant compressor when the sliding part of the new refrigerant compressor is worn by solid foreign matter. It is known to do. As a strainer used here, there is one described in Patent Document 3, for example.

特開2003−42603号公報JP 2003-42603 A 特開2000−9368号公報JP 2000-9368 A 特開2002−224513号公報JP 2002-224513 A

しかしながら、これらの従来技術では、効率よく既設配管を再利用することについて考慮がなされているとはいえない。   However, in these prior arts, it cannot be said that consideration is given to reusing existing piping efficiently.

すなわち、例えば不純物の濃度を許容値以下に設定するための冷凍機油封入作業の追加、あるいは洗浄運転の作業の追加などによってリニューアル工事の時間が長くなることが考えられる。   That is, for example, it may be possible to increase the time for renewal work by adding a refrigerating machine oil filling operation for setting the impurity concentration below an allowable value or by adding a cleaning operation.

そこで、本発明は、効率よく既設配管を再利用することのできる冷凍サイクル装置を提供すること課題とする。   Then, this invention makes it the subject to provide the refrigerating-cycle apparatus which can reuse existing piping efficiently.

上記課題を解決するため、本発明の冷凍サイクル装置は、圧縮機と、熱源機側熱交換器と、膨張装置と、利用側熱交換器とを、液冷媒配管及びガス冷媒配管で接続して冷凍サイクルを形成している。そして、ガス冷媒配管にストレーナを設けるとともに、液冷媒配管に容器を設ける。さらに、容器内には、液冷媒の上流側及び下流側の配管の各開口部を設けるとともに、各開口部に空間を画成し、かつ冷媒配管から吐出される異なる補捉対象物をそれぞれ捕捉する2つのフィルタを有するフィルタ装置を設けることを特徴とする。   In order to solve the above problems, a refrigeration cycle apparatus according to the present invention includes a compressor, a heat source device side heat exchanger, an expansion device, and a use side heat exchanger connected by a liquid refrigerant pipe and a gas refrigerant pipe. A refrigeration cycle is formed. And while providing a strainer in gas refrigerant piping, a container is provided in liquid refrigerant piping. Furthermore, the openings of the upstream and downstream pipes of the liquid refrigerant are provided in the container, and a space is defined in each opening, and different capture objects discharged from the refrigerant pipes are captured respectively. A filter device having two filters is provided.

この場合、冷媒配管から吐出される異なる補捉対象物は、冷媒とともに冷媒サイクルを循環する固形異物と、冷媒に対して不溶解あるいは弱溶解の少なくとも一方である液状不純物とすることができる。   In this case, the different trapping objects discharged from the refrigerant pipe can be solid foreign matters that circulate in the refrigerant cycle together with the refrigerant and liquid impurities that are at least one of insoluble or weakly soluble in the refrigerant.

これによれば、冷媒とともに流れる固形異物は、ガス冷媒の流路に設けられたストレーナ、及び液冷媒の流路に設けられた一方のフィルタによって捕捉されるので、冷暖房で冷媒の流れ方向が変わったとしても圧縮機に流入するのを抑制することができる。また、冷媒とは不溶、又は弱溶解成分である旧機に封入された冷凍機油などの液状不純物は、液冷媒の流路に設けられた他方のフィルタによって捕捉されるので、新機内の冷凍機油の劣化を抑制することができる。したがって、既設配管を再利用するに際して、冷凍機油封入作業の追加、あるいは洗浄運転の作業の追加などが不要であり、効率よく既設配管を再利用することができる。   According to this, the solid foreign matter flowing together with the refrigerant is captured by the strainer provided in the flow path of the gas refrigerant and the one filter provided in the flow path of the liquid refrigerant. Even if it is, it can suppress flowing into a compressor. In addition, since liquid impurities such as refrigerating machine oil sealed in the old machine that is insoluble or weakly soluble in the refrigerant are captured by the other filter provided in the flow path of the liquid refrigerant, the refrigerating machine oil in the new machine Can be prevented. Therefore, when reusing the existing piping, it is not necessary to add a refrigerating machine oil filling operation or an additional cleaning operation, and the existing piping can be reused efficiently.

また、膨張装置を、第1膨張装置と第2膨張装置で構成し、容器を、第1膨張装置と第2膨張装置との間に設けられ液冷媒を貯留するレシーバとすることができる。   Further, the expansion device can be constituted by a first expansion device and a second expansion device, and the container can be a receiver that is provided between the first expansion device and the second expansion device and stores liquid refrigerant.

さらに、2つのフィルタを、上段に液状不純物を捕捉するフィルタ、下段に固形異物を捕捉するフィルタという、上下二段で構成するとともに、冷媒配管の各開口部の空間を、固形異物を捕捉するフィルタで画成することが望ましい。   Further, the two filters are configured in two stages, an upper filter for capturing liquid impurities and a lower filter for capturing solid foreign substances, and a filter for capturing solid foreign substances in the space of each opening of the refrigerant pipe. It is desirable to define with.

鉱油などの液状不純物は、液冷媒に対してほとんど不溶であるので液冷媒と分離し、かつ液冷媒に対して比重が小さいため、より上方へ移動する。したがって、レシーバに貯留された液冷媒中で上段側に液状不純物を捕捉するフィルタを設けることで、効率よく液状不純物を捕捉することができる。また、下段側のフィルタによって冷媒配管の各開口部の空間が画成されているので、固形異物は、冷媒配管から吐出されると、すぐにこのフィルタに捕捉される。   Since liquid impurities such as mineral oil are almost insoluble in the liquid refrigerant, they are separated from the liquid refrigerant and move more upward because the specific gravity of the liquid refrigerant is small. Therefore, liquid impurities can be efficiently captured by providing a filter that captures liquid impurities on the upper side of the liquid refrigerant stored in the receiver. Moreover, since the space of each opening part of refrigerant | coolant piping is demarcated by the filter of the lower stage, when a solid foreign material is discharged from refrigerant | coolant piping, it will be capture | acquired by this filter immediately.

加えて、このような構成によれば、上段側のフィルタが設けられている箇所は、液冷媒の流速が比較的緩やかであるので、一旦捕捉された液状不純物が再び冷媒の流れに伴って流出するのを抑制することができる。   In addition, according to such a configuration, since the flow rate of the liquid refrigerant is relatively slow at the location where the upper filter is provided, once trapped liquid impurities flow out again with the flow of the refrigerant. Can be suppressed.

また、フィルタ装置は、レシーバ内に、レシーバの内壁面と所定間隔を有して設けることが望ましい。これは、レシーバ及びレシーバ内のフィルタ装置を製造する過程で、溶接などによりレシーバの壁面温度が高温になり、フィルタの耐久温度を超えてフィルタが溶融するなどの不具合の発生を抑制するためである。   Further, it is desirable that the filter device is provided in the receiver with a predetermined distance from the inner wall surface of the receiver. This is to suppress the occurrence of problems such as the wall surface temperature of the receiver becoming high due to welding or the like in the process of manufacturing the receiver and the filter device in the receiver, and the filter melting above the durable temperature of the filter. .

また、固形異物を捕捉するフィルタを、HFC冷凍機油が通過可能で、かつ数μm以上の固形異物を捕捉可能なメッシュ数を有する繊維性の材料で形成し、液状不純物を捕捉するフィルタを、HFC冷凍機油が通過可能で、かつ鉱油を捕捉可能なメッシュ数を有する繊維性の材料で形成することができる。   In addition, a filter that captures liquid impurities is formed of a fibrous material that has a mesh number that allows HFC refrigeration oil to pass through and that can capture solid foreign substances of several μm or more. It can be formed of a fibrous material having a mesh number through which refrigerating machine oil can pass and mineral oil can be captured.

また、液状不純物を捕捉するフィルタと固形異物を捕捉するフィルタを、ポリエステル製の繊維性材料で形成し、かつ液状不純物を捕捉するフィルタより固形異物を捕捉するフィルタの密度を大きく形成することができる。   Further, the filter for capturing liquid impurities and the filter for capturing solid foreign substances can be formed of a polyester fibrous material, and the density of the filter for capturing solid foreign substances can be formed larger than the filter for capturing liquid impurities. .

また、ストレーナを、利用側熱交換器と圧縮機との間に設け、ストレーナのスクリーンを、数μm以上の固形物を捕捉可能なSUSで形成することができる。   Moreover, a strainer is provided between the use side heat exchanger and the compressor, and the screen of the strainer can be formed of SUS capable of capturing a solid matter of several μm or more.

また、圧縮機の始動時及び停止時の少なくとも一方のときに、第1膨張装置及び第2膨張装置のいずれか一方を全閉あるいは微小開度とする制御を組み込むことにより、レシーバ内に液冷媒を回収して、より確実に液状不純物を捕捉することができる。   In addition, by incorporating a control in which at least one of the first expansion device and the second expansion device is fully closed or opened at least at one of the start time and the stop time of the compressor, the liquid refrigerant is provided in the receiver. Can be collected and liquid impurities can be captured more reliably.

本発明によれば、効率よく既設配管を再利用することのできる冷凍サイクル装置を提供することができる。   ADVANTAGE OF THE INVENTION According to this invention, the refrigerating-cycle apparatus which can reuse existing piping efficiently can be provided.

以下、本発明を適用してなる冷凍サイクル装置の実施形態を図1〜図5を用いて説明する。なお、以下の説明では空気調和機を一例として説明するが、これに限らず、本発明は、冷凍サイクルを形成しており、かつ既設配管を再利用する冷凍サイクル装置に適用可能である。また、実施形態は1台の室外機に複数台の室内機が接続されるマルチ型の空気調和機を例に説明するが、これに限らず1対1接続の空気調和機にも適用可能である。以下の説明では、同一機能部品については同一符号を付して重複説明を省略する。   Hereinafter, an embodiment of a refrigeration cycle apparatus to which the present invention is applied will be described with reference to FIGS. In the following description, an air conditioner will be described as an example. However, the present invention is not limited thereto, and the present invention is applicable to a refrigeration cycle apparatus that forms a refrigeration cycle and reuses existing piping. The embodiment will be described by taking a multi-type air conditioner in which a plurality of indoor units are connected to one outdoor unit as an example, but is not limited to this, and can be applied to a one-to-one connection air conditioner. is there. In the following description, the same functional parts are denoted by the same reference numerals, and redundant description is omitted.

図1は、本実施形態の空気調和機のサイクル系統図を示す図である。図に示すように、空気調和機は、室外機30と、室内機40a,40bと、これらを接続する液冷媒配管7及びガス冷媒配管12などで構成されている。   FIG. 1 is a diagram showing a cycle system diagram of the air conditioner of the present embodiment. As shown in the figure, the air conditioner includes an outdoor unit 30, indoor units 40a and 40b, and a liquid refrigerant pipe 7 and a gas refrigerant pipe 12 that connect them.

室外機30は、圧縮機1と、四方弁2と、熱源機側熱交換器3と、室外膨張弁4と、レシーバ5と、アキュムレータ15などを備えており、これらが冷媒配管で連結されて構成されている。そして、液冷媒配管7及びガス冷媒配管12との接続口には阻止弁6,13が設けられており、圧縮機1の吸入側の冷媒配管に固形物捕捉ストレーナ14aが設けられている。また、各室内機40a,40bは、室内膨張弁9a,9bと、利用側熱交換器10a,10bなどを備えており、これらが冷媒配管で連結されて構成されている。   The outdoor unit 30 includes a compressor 1, a four-way valve 2, a heat source unit side heat exchanger 3, an outdoor expansion valve 4, a receiver 5, an accumulator 15, and the like, which are connected by a refrigerant pipe. It is configured. In addition, blocking valves 6 and 13 are provided at the connection ports of the liquid refrigerant pipe 7 and the gas refrigerant pipe 12, and a solid matter trapping strainer 14 a is provided in the refrigerant pipe on the suction side of the compressor 1. Each of the indoor units 40a and 40b includes indoor expansion valves 9a and 9b, use side heat exchangers 10a and 10b, and the like, which are connected by a refrigerant pipe.

図2は、本実施形態の空気調和機の変形例を示す図である。図1との違いは、固形物捕捉ストレーナ14の配置位置の違いのみである。すなわち、図1では、室外機30内の圧縮機1の吸入側に固形物捕捉ストレーナ14aを設けているが、これに代えて図2のように、ガス冷媒配管12に固形物捕捉ストレーナ14bを設けてもよい。   FIG. 2 is a diagram illustrating a modification of the air conditioner of the present embodiment. The only difference from FIG. 1 is the difference in the arrangement position of the solid matter trapping strainer 14. That is, in FIG. 1, the solid matter trapping strainer 14a is provided on the suction side of the compressor 1 in the outdoor unit 30, but instead of this, the solid matter trapping strainer 14b is provided in the gas refrigerant pipe 12 as shown in FIG. It may be provided.

このような空気調和機において、室外機30及び室内機40a,40bをリニューアルする際に、液冷媒配管7,ガス冷媒配管12を再利用することが行われている。しかしながら、単にこれらの既設配管を再利用すると、配管内に残留した液状の不純物(旧機に封入された鉱油、アルキルベンゼンなどの冷凍機油、冷凍機油の酸化劣化反応物、塩素系化合物など)による新機内の冷凍機油の劣化や、固形異物が新機に搭載した冷媒圧縮機に混入することによる冷媒圧縮機の摺動部の摩耗の促進などにより、空気調和機の信頼性を著しく損なうおそれがある。   In such an air conditioner, when the outdoor unit 30 and the indoor units 40a and 40b are renewed, the liquid refrigerant pipe 7 and the gas refrigerant pipe 12 are reused. However, if these existing pipes are simply reused, the new liquid due to liquid impurities remaining in the pipes (mineral oil sealed in the old machine, refrigerating machine oil such as alkylbenzene, oxidation degradation reaction products of refrigerating machine oil, chlorine compounds, etc.) The reliability of the air conditioner may be significantly impaired due to deterioration of refrigeration oil in the machine and accelerated wear of the sliding part of the refrigerant compressor due to solid foreign substances mixed into the refrigerant compressor installed in the new machine. .

以下、既設配管内に残留した固形異物や不純物を回収する方法について説明する。なお、以下は既設配管内に残留した不純物の一例として鉱油を用いて説明する。
CFCやHCFCを使った空気調和装置が老朽化した場合、空気調和装置を交換する。まず、CFC又はHCFC冷媒を回収し、室外機30と室内機40a、40bを図1に示すものと交換する。液接続配管7とガス接続配管12は旧機のものを再利用する。室外機30には予めHFCが充填されているので、阻止弁6,13は閉じたまま室内機40a,40bと、液接続配管7と、ガス接続配管12とを接続状態で真空引きをし、その後HFCの追加充填と阻止弁6,13の開弁とを実施する。
Hereinafter, a method for recovering solid foreign matters and impurities remaining in the existing piping will be described. In the following description, mineral oil is used as an example of impurities remaining in the existing piping.
When the air conditioner using CFC or HCFC is aged, replace the air conditioner. First, the CFC or HCFC refrigerant is recovered, and the outdoor unit 30 and the indoor units 40a and 40b are replaced with those shown in FIG. The liquid connection pipe 7 and the gas connection pipe 12 are reused from the old machine. Since the outdoor unit 30 is preliminarily filled with HFC, the indoor units 40a and 40b, the liquid connection pipe 7 and the gas connection pipe 12 are evacuated in a connected state while the blocking valves 6 and 13 are closed, Thereafter, additional charging of HFC and opening of the stop valves 6 and 13 are performed.

空気調和機の基本的な動作としては、冷房運転の場合、圧縮機1で圧縮された高温高圧のガス冷媒は圧縮機1から吐出され、ガス冷媒が四方弁2を経て、熱源機側熱交換器3へと流入し、ここで熱交換器して凝縮液化する。凝縮液化した冷媒は全開とされた第1の膨張装置である室外膨張弁4を通り、余剰冷媒はレシーバ5に貯留され、残りが阻止弁6を通り、室内機40a,40bへ送られる。   As a basic operation of the air conditioner, in the case of cooling operation, the high-temperature and high-pressure gas refrigerant compressed by the compressor 1 is discharged from the compressor 1, and the gas refrigerant passes through the four-way valve 2 to exchange heat on the heat source side. It flows into the container 3, and it heat-exchanges here and condensates. The condensed and liquefied refrigerant passes through the outdoor expansion valve 4 that is the first expansion device that is fully opened, the excess refrigerant is stored in the receiver 5, and the remainder passes through the blocking valve 6 and is sent to the indoor units 40a and 40b.

送られた液冷媒は、第2の膨張装置である室内膨張弁9a,9bへ流入し、ここで低圧まで減圧されて低圧二相状態となり、利用側熱交換器10a,10bで空気などの利用側媒体と熱交換して蒸発・ガス化する。その後、ガス冷媒は、図2では固形物捕捉ストレーナ14bを経て、阻止弁13、四方弁2、図1では固形物捕捉ストレーナ14aを経て圧縮機1へ戻る。   The sent liquid refrigerant flows into the indoor expansion valves 9a and 9b, which are the second expansion devices, where the liquid refrigerant is decompressed to a low pressure to become a low-pressure two-phase state, and the utilization side heat exchangers 10a and 10b use air or the like. Evaporates and gasifies by exchanging heat with the side medium. Thereafter, the gas refrigerant returns to the compressor 1 via the solid matter trapping strainer 14b in FIG. 2, and through the blocking valve 13, the four-way valve 2, and in FIG. 1 via the solid matter trapping strainer 14a.

暖房運転の場合、圧縮機1で圧縮された高温高圧のガス冷媒は、HFC用冷凍機油と共に圧縮機1から吐出され、四方弁2、阻止弁13、図2では固形物捕捉ストレーナ14bを経て利用側熱交換器10a、10bへ流入し、ここで空気など利用側媒体と熱交換して凝縮液化する。凝縮液化した冷媒は、阻止弁6、レシーバ5へ流入し、室外膨張弁4で減圧され熱源機側熱交換器3で空気、水などの熱源媒体と熱交換して蒸発し、ガス化する。ガス化した冷媒は四方弁2、図1では固形物捕捉ストレーナ14aを経て圧縮機1へ戻る。   In the case of heating operation, the high-temperature and high-pressure gas refrigerant compressed by the compressor 1 is discharged from the compressor 1 together with the HFC refrigerating machine oil, and is used via the four-way valve 2, the blocking valve 13, and in FIG. It flows into the side heat exchangers 10a and 10b, and heat-exchanges with utilization side media, such as air, here, and is condensed and liquefied. The condensed and liquefied refrigerant flows into the blocking valve 6 and the receiver 5, is decompressed by the outdoor expansion valve 4, and is evaporated and gasified by exchanging heat with a heat source medium such as air and water in the heat source machine side heat exchanger 3. The gasified refrigerant returns to the compressor 1 through the four-way valve 2, in FIG.

図3は、HFC系冷媒とHFC用冷凍機油に対し、HFC系冷媒に不溶な成分である鉱油が約10%(=鉱油量/(HFC用冷凍機油量+鉱油量))混入した場合の鉱油の分離特性を示す図である。横軸は冷凍機油(HFC用冷凍機油+鉱油)への冷媒溶解度を示し、0%が冷凍機油(HFC用冷凍機油+鉱油)のみの場合を、100%が冷媒のみの場合を示す。縦軸は温度を示している。
この図に示すように、鉱油はHFC系冷媒にはほとんど溶解せず、一方HFC用冷凍機油には溶解する。そして、鉱油はHFC用冷凍機油が多く存在する圧縮機内では分離せず、液冷媒が多く存在する液接続配管7及びレシーバ5内で分離する。
続いて、本実施例の特徴部であるレシーバ5内に設置されたフィルタ装置について図4を用いて説明する。フィルタ装置は、レシーバ5内で上下二段に構成された異なるフィルタ53,54などで構成されている。フィルタ53はレシーバ5内の上段に設けられ、メッシュ数が比較的大きい繊維性の材料であり、その繊維の材質として、ポリエステル、ポリプロピレンの少なくとも1つで構成されている。
Fig. 3 shows mineral oil when about 10% (= mineral oil amount / (HFC refrigerator oil amount + mineral oil amount)) of mineral oil, which is an insoluble component in the HFC refrigerant, is mixed with the HFC refrigerant and HFC refrigerant oil. It is a figure which shows the isolation | separation characteristic. The horizontal axis indicates the solubility of the refrigerant in the refrigeration oil (HFC refrigeration oil + mineral oil), where 0% is only the refrigeration oil (HFC refrigeration oil + mineral oil) and 100% is the refrigerant only. The vertical axis represents temperature.
As shown in this figure, the mineral oil is hardly dissolved in the HFC refrigerant, whereas it is dissolved in the refrigeration oil for HFC. And mineral oil is not isolate | separated in the compressor in which many refrigeration oils for HFC exist, but isolate | separates in the liquid connection piping 7 and receiver 5 in which many liquid refrigerants exist.
Next, the filter device installed in the receiver 5 which is a characteristic part of the present embodiment will be described with reference to FIG. The filter device includes different filters 53 and 54 that are configured in two stages on the upper and lower sides in the receiver 5. The filter 53 is provided in the upper stage in the receiver 5 and is a fibrous material having a relatively large number of meshes. The material of the fiber is composed of at least one of polyester and polypropylene.

液冷媒及び液冷媒に溶解したHFC用冷凍機油は、粘度が著しく低い液体である。これに対して、鉱油は液冷媒及び液冷媒に溶解したHFC用冷凍機油に比べて粘度が著しく高い液体である。そのため、液冷媒及び液冷媒に溶解したHFC用冷凍機油はフィルタ53を通過するのに対して、鉱油はメッシュ数の大きいフィルタ53の繊維間に引っかかり、その後毛細管現象により繊維内部へ捕捉される。
したがって、フィルタ53をレシーバ5内に配置することで、圧縮機1内からHFC用冷凍機油とともに吐出された鉱油はレシーバ5内で分離し、その分離した鉱油のみをフィルタ53にて捕捉することが可能となる。
The liquid refrigerant and the refrigerating machine oil for HFC dissolved in the liquid refrigerant are liquids with extremely low viscosity. In contrast, mineral oil is a liquid that has a significantly higher viscosity than liquid refrigerant and refrigeration oil for HFC dissolved in liquid refrigerant. Therefore, the liquid refrigerant and the refrigeration oil for HFC dissolved in the liquid refrigerant pass through the filter 53, whereas the mineral oil is caught between the fibers of the filter 53 having a large mesh number, and is then trapped inside the fibers by a capillary phenomenon.
Therefore, by disposing the filter 53 in the receiver 5, the mineral oil discharged together with the HFC refrigerating machine oil from the compressor 1 is separated in the receiver 5, and only the separated mineral oil can be captured by the filter 53. It becomes possible.

圧縮機1の形態として圧縮機1内の冷凍機油貯留部の圧力が高い高圧チャンバー方式、あるいは圧縮機1の吐出部にオイルセパレータを配置している場合には、圧縮機1内あるいはオイルセパレータ内に貯留した冷凍機油の温度は高温となる。一方、レシーバ5の温度はその温度よりも低くなる。そして、冷凍機油の劣化は、温度が上昇するほど促進し、さらにHFC用冷凍機油の劣化は既設配管内に残留した鉱油(劣化油)の混入量が多いほど劣化は促進するので、圧縮機1内あるいはオイルセパレータ内よりも低温のレシーバ5で鉱油を捕捉することにより、HFC用冷凍機油の劣化を抑制することができる。   When the compressor 1 is in the form of a high-pressure chamber system in which the pressure of the refrigerating machine oil reservoir in the compressor 1 is high, or when an oil separator is disposed in the discharge part of the compressor 1, the compressor 1 or the oil separator The temperature of the refrigerating machine oil stored in the tank becomes high. On the other hand, the temperature of the receiver 5 is lower than that temperature. The deterioration of the refrigerating machine oil is accelerated as the temperature rises, and the deterioration of the HFC refrigerating machine oil is further promoted as the mixing amount of the mineral oil (deteriorating oil) remaining in the existing pipe increases. By capturing the mineral oil with the receiver 5 having a lower temperature than the inside or the oil separator, the deterioration of the refrigeration oil for HFC can be suppressed.

また、鉱油をフィルタ53に捕捉するためには、フィルタ53と鉱油とが接触する必要がある。そこで、圧縮機1の起動時及び圧縮機の停止時に、レシーバ5の後流側の膨張装置(冷房運転時であれば室内膨張弁9a、9b、暖房運転時であれば室外膨張弁4)を全閉あるいは全閉に近い小開度に設定して運転することで、レシーバ5内に冷媒を回収する。   Further, in order to capture the mineral oil in the filter 53, the filter 53 and the mineral oil need to contact each other. Therefore, when the compressor 1 is started and when the compressor is stopped, the expansion device on the downstream side of the receiver 5 (the indoor expansion valves 9a and 9b during the cooling operation and the outdoor expansion valve 4 during the heating operation) is installed. The refrigerant is recovered in the receiver 5 by setting the valve to a fully closed position or a small opening degree close to the fully closed state.

これにより、フィルタ53にHFC系冷媒とHFC用冷凍機油と鉱油との混合液とを接触することができるので、レシーバ5内においては鉱油のみが分離することから、鉱油のみを捕捉することができる。   As a result, the filter 53 can be brought into contact with the mixed liquid of the HFC refrigerant, the HFC refrigerating machine oil, and the mineral oil, so that only the mineral oil is separated in the receiver 5, so that only the mineral oil can be captured. .

さらに、フィルタ53に対する流速が大きいほどフィルタ53の鉱油捕捉量は減少する。これは、一度フィルタ53に捕捉された鉱油が、冷媒の流体力によりフィルタ53の外に押し出されるからである。そして、レシーバ5内にHFC系冷媒とHFC用冷凍機油と鉱油の混合液を導入する冷媒導入出管51、52の管先端部の近傍であるほど、混合液の流入速度は大きいので、管先端部を下方に向けて、レシーバ5内に導入したHFC系冷媒とHFC用冷凍機油と鉱油の混合液がフィルタ53を通過した後に、レシーバ5から導出するようにする。これにより、レシーバ5内に導入した鉱油がフィルタ53を通過することなく、導出することを抑制することができる。   Furthermore, the amount of mineral oil captured by the filter 53 decreases as the flow velocity with respect to the filter 53 increases. This is because the mineral oil once captured by the filter 53 is pushed out of the filter 53 by the fluid force of the refrigerant. And since the inflow speed of a liquid mixture is so large that it is near the pipe | tube front-end | tip part of the refrigerant | coolant inlet / outlet pipes 51 and 52 which introduce | transduce the liquid mixture of HFC type | system | group refrigerant | coolant, HFC refrigerating machine oil, and mineral oil in the receiver 5, The liquid mixture of the HFC refrigerant, the HFC refrigerating machine oil, and the mineral oil introduced into the receiver 5 is led out from the receiver 5 after passing through the filter 53 with the portion facing downward. Thereby, it can suppress that the mineral oil introduce | transduced in the receiver 5 leads out, without passing the filter 53. FIG.

以上のような構成により、従来技術のように、不純物の濃度を許容値以下に設定するに際して、冷凍機油メーカから缶容器にて提供された冷凍機油を、専用のホースを用いてコンタミの混入防止に注意しながら封入するといった作業が必要なく、リニューアル工事の時間を抑制することができる。また、追加する冷凍機油を予め新機内に封入する従来の方法のように、接続配管の長いビル用マルチエアコンでのリニューアルの際に、接続配管内に残留する多量の不純物に対応した多量の冷凍機油を新機内に封入することによって新機の容積が大きくなり、新機を設置できなくなるといった問題を抑制することができる。   With the above configuration, when the impurity concentration is set below the allowable value as in the prior art, the contamination of the refrigeration oil provided by the refrigeration oil manufacturer in a can container is prevented using a dedicated hose. It is not necessary to enclose the product while paying attention to it, and the time for renewal work can be reduced. In addition, as in the conventional method in which additional refrigeration oil is sealed in the new machine in advance, a large amount of refrigeration corresponding to the large amount of impurities remaining in the connection pipes when renewing with a multi air conditioning system for buildings with long connection pipes. By enclosing the machine oil in the new machine, the volume of the new machine becomes large and the problem that the new machine cannot be installed can be suppressed.

また、接続配管を再利用するに際して、接続配管内に残留した不純物を回収する洗浄運転を実施する必要もないため、リニューアル工事の作業時間を抑制して、効率的に既設配管の再利用をすることができる。   In addition, when reusing connection pipes, it is not necessary to carry out cleaning operations to collect impurities remaining in the connection pipes, so the time required for renewal work can be reduced and existing pipes can be reused efficiently. be able to.

さらに、フィルタ53よりも下段に配置されたフィルタ54は、レシーバ5内の冷媒導入出管51,52の管先端部の近傍に設けられている。言い換えればフィルタ54によって冷媒導入出管51,52の先端部の空間62が画成されている。フィルタ54は、フィルタ53よりも大きい繊維性の材料であり数μmの固形異物を除去可能なメッシュ数である。つまりフィルタ53よりも繊維が密に重なり合った、繊維間の空隙が小さい、密度の大きい繊維性の材料であり、その繊維の性質として、ポリエステル、ポリプロピレン、SUSの少なくとも1つで構成されている。   Further, the filter 54 disposed below the filter 53 is provided in the vicinity of the pipe leading ends of the refrigerant introduction / extraction pipes 51 and 52 in the receiver 5. In other words, the filter 54 defines a space 62 at the tip of the refrigerant introduction / extraction pipes 51 and 52. The filter 54 is a fibrous material larger than the filter 53, and has a mesh number that can remove solid foreign matters of several μm. That is, it is a fibrous material with dense fibers overlapping with each other more densely than the filter 53 and having a small gap between the fibers and a high density. The fiber is composed of at least one of polyester, polypropylene, and SUS.

鉱油を捕捉するフィルタ53としては、鉱油が毛細管現象により繊維内部へと捕捉されることから、フィルタ53の繊維間の空隙をできるだけ大きくとり、捕捉可能な鉱油の量を多く設定するために、フィルタ54とは異なる密度に設定することが望ましい。なお、フィルタ54は冷媒導入出管51,52から導入した固形異物をレシーバ5内から導出しないように、冷媒導入出管51,52の管先端部の近傍を囲うように配置する。   As the filter 53 for capturing the mineral oil, the mineral oil is trapped inside the fibers by capillary action. Therefore, in order to set the gap between the fibers of the filter 53 as large as possible and to set a large amount of mineral oil that can be captured, It is desirable to set the density different from 54. The filter 54 is disposed so as to surround the vicinity of the pipe leading ends of the refrigerant introduction / extraction pipes 51, 52 so that solid foreign substances introduced from the refrigerant introduction / extraction pipes 51, 52 are not led out from the receiver 5.

ここで、従来技術における固形異物を捕捉するストレーナは、粒径20μm以上の固形異物が捕捉可能である。しかしながら、冷媒圧縮機の摺動部摩耗により生じた固形異物を実機から回収した固形異物の粒径分布を測定した結果、粒径20μm以下のものが半数以上含まれることがわかっており、粒径20μm以上の固形異物が捕捉可能なストレーナでは、粒径20μm以下の固形異物は冷媒圧縮機に流入することになる。   Here, the strainer for capturing solid foreign matters in the prior art can capture solid foreign matters having a particle diameter of 20 μm or more. However, as a result of measuring the particle size distribution of the solid foreign material collected from the actual machine due to the sliding part wear of the refrigerant compressor, it is known that more than half of the particles have a particle size of 20 μm or less. In a strainer capable of capturing solid foreign matters of 20 μm or more, solid foreign matters having a particle size of 20 μm or less flow into the refrigerant compressor.

また、文献「“潤滑”、第17巻、第11号(1972)741〜746」には、冷媒圧縮機にも採用しているすべり軸受での最小隙間は1〜20μmであり、文献「“トライボロジーと環境”、新樹社、53ページ、図2・2・3・7(b)」には固形異物の粒径と軸受の最小隙間とが等しくなる条件にて、最も摺動部の摩耗が促進されるとの記載がある。   Further, in the document “" Lubrication ”, Vol. 17, No. 11 (1972) 741-746, the minimum clearance in the sliding bearing employed in the refrigerant compressor is 1-20 μm. "Tribology and the environment", Shinkisha, page 53, Fig. 2, 2, 3 and 7 (b) "shows that the wear of the sliding part is the most under the condition that the particle size of the solid foreign material is equal to the minimum clearance of the bearing. There is a statement that it will be promoted.

この点、本実施形態では、上述のような構成により、冷媒導入出管51,52から吐出された固形異物はフィルタ54の冷媒導入出管51,52側の面に付着する。その結果、固形異物が新機に搭載した圧縮機に混入して圧縮機の摺動部の摩耗が促進され、空気調和機の信頼性が損なわれることを抑制することができる。   In this regard, in the present embodiment, the solid foreign matter discharged from the refrigerant introduction / extraction pipes 51 and 52 adheres to the surface of the filter 54 on the refrigerant introduction / extraction pipes 51 and 52 side in the above-described configuration. As a result, it is possible to suppress the solid foreign matter from being mixed into the compressor mounted on the new machine, promoting wear of the sliding portion of the compressor, and impairing the reliability of the air conditioner.

なお、固形異物によりフィルタ54が閉塞することを抑制するために、フィルタ54の冷媒導入出管51,52側の面積を十分確保することが望ましい。   In order to prevent the filter 54 from being blocked by solid foreign matters, it is desirable to secure a sufficient area on the side of the refrigerant inlet / outlet pipes 51 and 52 of the filter 54.

次に、レシーバ5に内蔵する上段の冷媒不溶成分を除去するフィルタ53、下段の固形異物を除去するフィルタ54の設置方法について説明する。
製造時においてフィルタ53,54をパンチングメタル55、56で挟んだ後、キャップ58,59とボディ60とを溶接する。その際にボディ60の内壁面の温度がフィルタ53,54の最高使用温度を超える。よって、フィルタ53,54がボディ60の内壁面に接する構造であれば、フィルタ53,54が熱で溶融し、冷媒不溶成分を捕捉できなくなる。さらにはレシーバ5内に導入した液冷媒及び液冷媒に溶解したHFC用冷凍機油が、レシーバ5内での流路を遮断されることから、レシーバ5内から導出されず、圧縮機1の吐出温度の過昇による機器の停止、あるいは圧縮機1内の冷凍機油不足による摺動部の摩耗を生じる。
Next, the installation method of the filter 53 for removing the upper-stage refrigerant insoluble component built in the receiver 5 and the filter 54 for removing the lower solid foreign matter will be described.
After the filters 53 and 54 are sandwiched between the punching metals 55 and 56 at the time of manufacture, the caps 58 and 59 and the body 60 are welded. At that time, the temperature of the inner wall surface of the body 60 exceeds the maximum operating temperature of the filters 53 and 54. Therefore, if the filters 53 and 54 are in contact with the inner wall surface of the body 60, the filters 53 and 54 are melted by heat, and the refrigerant insoluble component cannot be captured. Further, the liquid refrigerant introduced into the receiver 5 and the refrigeration oil for HFC dissolved in the liquid refrigerant are blocked from the flow path in the receiver 5, so that they are not led out from the receiver 5 and discharged from the compressor 1. The apparatus stops due to excessive rise in temperature, or the sliding portion wears due to insufficient refrigeration oil in the compressor 1.

そのため、本実施例ではフィルタ53,54の温度が最高使用温度以下となるようにボディ60とフィルタ53,54の間に所定の間隔Δdを設け、ボディ60内壁面の温度がフィルタに伝わるのを抑制するようにしている。   Therefore, in this embodiment, a predetermined interval Δd is provided between the body 60 and the filters 53 and 54 so that the temperature of the filters 53 and 54 is equal to or lower than the maximum use temperature, and the temperature of the inner wall surface of the body 60 is transmitted to the filter. I try to suppress it.

固形物捕捉ストレーナ14a,14bは、図5に示すように、一方を中央部が開口した導入キャップ71を接続し、もう一方の底面にはスクリーンを配置した固形異物を捕捉する円筒状のスクリーン70を耐圧容器74の内部に封入した構造である。導入キャップ71とスクリーン70との接続は、円周方向を全て溶接することにより、導入キャップ71とスクリーン70との接続部からの固形異物の流入出を防止する。   As shown in FIG. 5, the solid matter trapping strainers 14 a and 14 b are connected to an introduction cap 71 having an opening at the center, and a cylindrical screen 70 for catching solid foreign matters having a screen disposed on the other bottom surface. Is sealed in the pressure vessel 74. The connection between the introduction cap 71 and the screen 70 prevents the inflow and outflow of solid foreign substances from the connection portion between the introduction cap 71 and the screen 70 by welding all the circumferential directions.

さらに、耐圧容器74の内面と導入キャップ71との接続についても、円周方向を全周かしめる、あるいは円周方向を全て溶接することで、固形異物の流入出を防止する。   Further, with respect to the connection between the inner surface of the pressure vessel 74 and the introduction cap 71, the inflow and outflow of solid foreign matter is prevented by caulking the entire circumference direction or welding all the circumference direction.

固形物捕捉ストレーナ14a,14b内部の冷媒、冷凍機油及び固形異物の流れは、まず配管72側から冷媒、冷凍機油及び固形異物が流入する際は、実線の矢印のように流れる。冷媒及び冷凍機油はスクリーンの開孔部を通り、配管73側から流出する。スクリーン70の開孔部よりも粒径が大きい固形異物は、スクリーン70を通過することができないので、スクリーン70の内面に捕捉される。   The flow of the refrigerant, the refrigerating machine oil, and the solid foreign matter inside the solid matter trapping strainers 14a and 14b flows as indicated by solid arrows when the refrigerant, the refrigerating machine oil, and the solid foreign matter first flow in from the pipe 72 side. The refrigerant and the refrigerating machine oil flow out from the piping 73 side through the opening of the screen. A solid foreign substance having a particle size larger than the aperture of the screen 70 cannot pass through the screen 70 and is thus captured on the inner surface of the screen 70.

また、冷房暖房兼用機など逆サイクル運転を実施したときの冷媒、冷凍機油及び固形異物の流れを、点線の矢印で示す。   In addition, the flow of the refrigerant, the refrigerating machine oil, and the solid foreign matter when the reverse cycle operation such as the cooling and heating combined machine is performed is indicated by dotted arrows.

図2のように、固形物捕捉ストレーナ14bをガス接続配管12とガス阻止弁13の間に配置した場合、スクリーン70内面に捕捉された固形異物は、冷媒及び冷凍機油の流体力により固形物捕捉ストレーナ14bの外に流出する可能性がある。しかし、固形異物は固形物捕捉ストレーナ14bとレシーバ5内に配置したフィルタ54により、液冷媒配管7,ガス冷媒配管12内に閉じ込めて、冷媒圧縮機1内への流入を防止することができる。   As shown in FIG. 2, when the solid substance capture strainer 14 b is disposed between the gas connection pipe 12 and the gas blocking valve 13, the solid foreign matter captured on the inner surface of the screen 70 is captured by the fluid force of the refrigerant and the refrigerating machine oil. There is a possibility of flowing out of the strainer 14b. However, the solid foreign matter can be confined in the liquid refrigerant pipe 7 and the gas refrigerant pipe 12 by the solid substance capturing strainer 14b and the filter 54 disposed in the receiver 5, and can be prevented from flowing into the refrigerant compressor 1.

固形物捕捉ストレーナ14a、14bに採用するスクリーン70の材質としては、粒径数μm以上の固形異物の捕捉し、使用する冷媒、冷凍機油を劣化させない、スクリーン70自体も劣化しない材料であるSUS製とすることが望ましい。
また、文献「“トライボロジーと環境”、新樹社、53ページ、図2・2・3・7(c)」の記載によれば、軸受摺動部に供給する異物量が増加するほど、軸受部の摩耗量は増加する。このことから冷媒圧縮機1の仕様として固形異物混入量の許容値が設定されており、前記固形異物混入量の許容値以下であれば、液冷媒配管7、ガス冷媒配管12内に残留する固形異物の一部はスクリーン70を通過し、冷媒圧縮機1に流入しても問題ない。
The material of the screen 70 employed in the solid matter trapping strainers 14a and 14b is made of SUS, which is a material that catches solid foreign matters having a particle size of several μm or more, does not deteriorate the refrigerant and refrigerator oil used, and does not deteriorate the screen 70 itself. Is desirable.
According to the document “Tribology and the Environment”, Shinkisha, p. 53, FIGS. 2, 2, 3 and 7 (c), the bearing part increases as the amount of foreign matter supplied to the bearing sliding part increases. The amount of wear increases. Therefore, an allowable value for the amount of solid foreign matter is set as a specification of the refrigerant compressor 1 and the solid remaining in the liquid refrigerant pipe 7 and the gas refrigerant pipe 12 is less than the allowable value for the amount of solid foreign matter mixed in. Even if a part of the foreign matter passes through the screen 70 and flows into the refrigerant compressor 1, there is no problem.

つまり、固形物捕捉ストレーナ14a、14bに採用するスクリーン70は、粒径数μm以上の固形異物を捕捉するが、捕捉率は100%以下でも問題はない。
また、冷媒及び冷凍機油からの流体力に耐えるべく、スクリーン70の内周及び外周をパンチングメタルなどの強度の高い部材で補強しても良い。
That is, the screen 70 employed in the solid matter trapping strainers 14a and 14b catches solid foreign matters having a particle size of several μm or more, but there is no problem even if the catching rate is 100% or less.
Further, the inner periphery and outer periphery of the screen 70 may be reinforced with a high-strength member such as a punching metal in order to withstand the fluid force from the refrigerant and the refrigerating machine oil.

このとき、図1のように圧縮機1の吸入側に固形物捕捉ストレーナ14aを配置した場合は、冷凍サイクル中の固形異物である、液冷媒配管7、ガス冷媒配管12内に残留する固形異物、及び圧縮機1の経年劣化により発生する摩耗粉が全て固形物捕捉ストレーナ14aに集まる。そのため、固形物捕捉ストレーナ14aが固形異物により閉塞しないよう、固形物捕捉ストレーナ14aのスクリーン70の面積を十分に確保することが重要である。   At this time, when the solid matter trapping strainer 14a is arranged on the suction side of the compressor 1 as shown in FIG. 1, the solid foreign matters remaining in the liquid refrigerant pipe 7 and the gas refrigerant pipe 12 which are solid foreign substances in the refrigeration cycle. , And all the abrasion powder generated by the aging deterioration of the compressor 1 is collected in the solid matter capturing strainer 14a. Therefore, it is important to ensure a sufficient area of the screen 70 of the solid matter trapping strainer 14a so that the solid matter trapping strainer 14a is not blocked by the solid foreign matter.

図2のように、固形物捕捉ストレーナ14bをガス接続配管12とガス阻止弁13の間に配置した場合、固形物捕捉ストレーナ14bでは、冷房運転時は液冷媒配管7、ガス冷媒配管12内に残留する固形異物のみが流入する。一方、暖房運転時は、圧縮機1の経年劣化により発生する摩耗粉のみが固形物捕捉ストレーナ14bに流入する。このことから、固形物捕捉ストレーナ14bに流入する固形異物の量が、固形物捕捉ストレーナ14aよりも少なく、固形物捕捉ストレーナ14bのスクリーン70の面積を小さく設定することができ、小型化が可能である。   As shown in FIG. 2, when the solid matter trapping strainer 14 b is disposed between the gas connection pipe 12 and the gas blocking valve 13, the solid matter trapping strainer 14 b is placed in the liquid refrigerant pipe 7 and the gas refrigerant pipe 12 during the cooling operation. Only the remaining solid foreign material flows in. On the other hand, at the time of heating operation, only the abrasion powder generated by the aging deterioration of the compressor 1 flows into the solid matter capturing strainer 14b. From this, the amount of solid foreign matter flowing into the solid matter trapping strainer 14b is smaller than that of the solid matter trapping strainer 14a, the area of the screen 70 of the solid matter trapping strainer 14b can be set small, and downsizing is possible. is there.

本発明の空気調和機の冷凍サイクル系統図を示す図である。It is a figure which shows the refrigerating cycle system diagram of the air conditioner of this invention. 本発明による他の実施形態を示すサイクル系統図。The cycle system diagram which shows other embodiment by this invention. HFC系冷媒とHFC用冷凍機油と鉱油共存下での鉱油分離特性を示すグラフである。It is a graph which shows the mineral oil separation characteristic in the presence of HFC refrigerant, HFC refrigerating machine oil, and mineral oil. レシーバ及びレシーバ内に設置するフィルタ装置の縦断面を示す図である。It is a figure which shows the longitudinal cross-section of the filter apparatus installed in a receiver and a receiver. 固形物捕捉ストレーナの断面を示す図である。It is a figure which shows the cross section of a solid substance capture strainer.

符号の説明Explanation of symbols

1 圧縮機
2 四方弁
3 熱源機側熱交換器
4 室外膨張弁
5 レシーバ
6,13 阻止弁
7 液冷媒配管
9a,9b 室内膨張弁
10a,10b 利用側熱交換器
12 ガス冷媒配管
14a,14b 固形物捕捉ストレーナ
15 アキュムレータ
30 室外機
40a,40b 室内機
51,52 冷媒導入出管
53,54 フィルタ
55,56 パンチングメタル
58,59 キャップ
60 ボディ
70 スクリーン
71 導入キャップ
74 耐圧容器
DESCRIPTION OF SYMBOLS 1 Compressor 2 Four-way valve 3 Heat source machine side heat exchanger 4 Outdoor expansion valve 5 Receiver 6, 13 Stop valve 7 Liquid refrigerant piping 9a, 9b Indoor expansion valve 10a, 10b Usage side heat exchanger 12 Gas refrigerant piping 14a, 14b Solid Object capture strainer 15 Accumulator 30 Outdoor unit 40a, 40b Indoor unit 51, 52 Refrigerant introduction / extraction pipe 53, 54 Filter 55, 56 Punching metal 58, 59 Cap 60 Body 70 Screen 71 Introduction cap 74 Pressure-resistant container

Claims (7)

圧縮機と、熱源機側熱交換器と、膨張装置と、利用側熱交換器とを、液冷媒配管及びガス冷媒配管で接続して冷凍サイクルを形成してなる冷凍サイクル装置であって、
前記ガス冷媒配管にストレーナが設けられるとともに、前記液冷媒配管に容器が設けられ、
該容器内には、前記液冷媒の上流側及び下流側の配管の各開口部が設けられるとともに、該各開口部に空間を画成し、かつ冷媒配管から吐出される異なる補捉対象物をそれぞれ捕捉する2つのフィルタが設けられてなり、
前記2つのフィルタは、上下二段に構成されてなり、上段にHFC冷凍機油が通過可能で、かつ鉱油を捕捉可能なメッシュ数を有する繊維性の材料で形成されたフィルタが、下段にHFC冷凍機油が通過可能で、かつ圧縮機摺動部より発生し前記冷媒配管から吐出される数μm以上の摩耗粉を捕捉可能なメッシュ数を有する繊維性の材料で形成されたフィルタが設けられ、前記各開口部の空間は、前記摩耗粉を捕捉するフィルタに画成されてなることを特徴とする冷凍サイクル装置。
A refrigeration cycle device formed by connecting a compressor, a heat source device side heat exchanger, an expansion device, and a use side heat exchanger with a liquid refrigerant pipe and a gas refrigerant pipe to form a refrigeration cycle,
A strainer is provided in the gas refrigerant pipe, and a container is provided in the liquid refrigerant pipe.
In the container, openings of the upstream and downstream pipes of the liquid refrigerant are provided, a space is defined in each of the openings, and different capturing objects discharged from the refrigerant pipes are provided. Ri Na and two filters to capture each provided,
The two filters are configured in two upper and lower stages, and a filter formed of a fibrous material having a mesh number that allows passage of HFC refrigerating machine oil and captures mineral oil in the upper stage is HFC refrigeration in the lower stage. A filter formed of a fibrous material having a mesh number capable of passing machine oil and having a mesh number capable of capturing wear powder of several μm or more generated from the compressor sliding portion and discharged from the refrigerant pipe, A space in each opening is defined by a filter that captures the wear powder.
前記膨張装置は、第1膨張装置と第2膨張装置からなり、前記容器は、前記第1膨張装置と第2膨張装置との間に設けられ液冷媒を貯留するレシーバであることを特徴とする請求項1に記載の冷凍サイクル装置。   The expansion device includes a first expansion device and a second expansion device, and the container is a receiver that is provided between the first expansion device and the second expansion device and stores liquid refrigerant. The refrigeration cycle apparatus according to claim 1. 前記2つのフィルタは、前記レシーバ内に、前記レシーバの内壁面と所定間隔を有して設けられてなることを特徴とする請求項に記載の冷凍サイクル装置。 The refrigeration cycle apparatus according to claim 2 , wherein the two filters are provided in the receiver with a predetermined distance from an inner wall surface of the receiver. 前記鉱油を捕捉するフィルタと前記摩耗粉を捕捉するフィルタは、ポリエステル製の繊維性材料で形成され、かつ前記鉱油を捕捉するフィルタより前記摩耗粉を捕捉するフィルタの密度が大きく形成されてなることを特徴とする請求項1乃至3のいずれか1項に記載の冷凍サイクル装置。 The filter that captures the mineral oil and the filter that captures the wear powder are formed of a polyester fibrous material, and the density of the filter that captures the wear powder is larger than the filter that captures the mineral oil. The refrigeration cycle apparatus according to any one of claims 1 to 3 . 前記ストレーナは、前記利用側熱交換器と圧縮機との間に設けられ、該ストレーナのスクリーンは、数μm以上の固形物を捕捉可能なSUSで形成されてなることを特徴とする請求項1乃至4のいずれか1項に記載の冷凍サイクル装置。 The strainer is provided between the utilization-side heat exchanger and the compressor, the screen of the strainer claim 1, characterized by being formed of several μm or more solids can be captured SUS The refrigeration cycle apparatus according to any one of 1 to 4 . 前記圧縮機の始動時及び停止時の少なくとも一方のときに、前記第1膨張装置及び第2膨張装置のうち、前記レシーバの後流側の膨張装置を全閉あるいは微小開度とすることを特徴とする請求項2乃至5のいずれか1項に記載の冷凍サイクル装置。 The at least one of the first expansion device and the second expansion device at the time of starting and stopping the compressor, the expansion device on the downstream side of the receiver is fully closed or has a minute opening. The refrigeration cycle apparatus according to any one of claims 2 to 5 . 圧縮機と、四方弁と、熱源機側熱交換器と、第1膨張装置と、レシーバと、第2膨張装置と、利用側熱交換器とを冷媒配管で連結して冷凍サイクルを形成してなる冷凍サイクル装置であって、
前記利用側熱交換器と前記圧縮機との間に、冷媒と共に前記冷凍サイクルを循環する固形異物を捕捉するストレーナが設けられるとともに、前記レシーバ内に、圧縮機摺動部より発生する数μm以上の摩耗粉と、鉱油とを捕捉するフィルタ装置が設けられ、
前記フィルタ装置は、上段にHFC冷凍機油が通過可能で、かつ鉱油を捕捉可能なメッシュ数を有する繊維性の材料で形成されたフィルタを、下段にHFC冷凍機油が通過可能で、かつ圧縮機摺動部より発生し前記冷媒配管から吐出される数μm以上の摩耗粉を捕捉可能なメッシュ数を有する繊維性の材料で形成されたフィルタを配置して構成され、前記摩耗粉を捕捉するフィルタによって前記レシーバ内に挿入された冷媒配管の上流側及び下流側のそれぞれの開口部に空間が画成されてなることを特徴とする冷凍サイクル装置。
A compressor, a four-way valve, a heat source machine side heat exchanger, a first expansion device, a receiver, a second expansion device, and a use side heat exchanger are connected by a refrigerant pipe to form a refrigeration cycle. A refrigeration cycle apparatus comprising:
Between the use side heat exchanger and the compressor, a strainer that captures solid foreign matters circulating in the refrigeration cycle together with the refrigerant is provided, and several μm or more generated from the compressor sliding portion in the receiver A filter device that captures the wear powder and mineral oil of
The filter device has a filter formed of a fibrous material having a mesh number that allows HFC refrigerator oil to pass through and captures mineral oil in the upper stage , and allows HFC refrigerator oil to pass through in the lower stage. A filter formed of a fibrous material having a mesh number that can capture wear powder of several μm or more generated from a moving portion and discharged from the refrigerant pipe is arranged, and the filter that captures the wear powder A refrigeration cycle apparatus characterized in that a space is defined in each of the upstream and downstream openings of the refrigerant pipe inserted into the receiver.
JP2007084909A 2007-03-28 2007-03-28 Refrigeration cycle equipment Expired - Fee Related JP4370478B2 (en)

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