JP4472197B2 - Refrigeration cycle equipment - Google Patents

Description

【００５９】
図５はこの実験に用いた活性炭の累積細孔分布である。活性炭Ａ、Ｂともに処理後の鉱油濃度は１％以下であった。活性炭Ｃでは処理後の鉱油濃度にほとんど変化は認められなかった。よって、１〜10nmに細孔分布を有する活性炭が鉱油吸着に適している。
【００６０】
活性炭は無極性の物質を選択的に吸着する性質を有しており、鉱油、エステル油の中で極性の低い（無極性に近い）鉱油を吸着しやすい。そして、活性炭への吸着は、極性、分子サイズと細孔径の関係により決まる。上記のように実験的に様々な細孔径を有する活性炭による鉱油吸着性を調べた結果、１〜１０nmの平均細孔径を有する活性炭が、効率良く鉱油を吸着することが判明した。
【００６１】
また、エステル油、エーテル油等のHFC冷媒とともに使用される潤滑油では、例えば、潤滑性を付加するために添加剤が添加されている。そのため、添加剤が活性炭により吸着除去された場合には、潤滑油としての性能が低下し、機器の信頼性が低下する。さらに、エステル油も吸着された場合にも、圧縮機内での潤滑油が減少し、機器の信頼性が低下する。そこで、図５中の活性炭Ａと同様の細孔直径を有する活性炭を用いて添加剤吸着特性を実験的に調べた。この実験では、鉱油10%、エステル油40%、Ｒ407C50%に混合した液を活性炭の中に入れ、吸着特性を調べた。
【００６２】
表２に活性炭による添加剤ａ，ｂ，ｃ，ｄの吸着特性の変化およびエステル油の吸着特性の変化を示す。各実験での条件は以下の通りである。
イ．活性炭の前処理なし。
ロ．活性炭の前処理として、添加剤ａ，ｂ，ｃ，ｄおよびエステル油を混合した油中に活性炭を浸し、活性炭内に添加剤ａ，ｂ，ｃ，ｄおよびエステル油を予め吸着させておいた。
【００６３】
【表２】

【００６４】
実験の結果、活性炭に予め添加剤およびエステル油を吸着させておくと、添加剤およびエステル油は吸着除去されないことが判明した。ここで、表２中の添加剤残存率とは、初期の添加剤量を１００％とした際の実験後の添加剤量を示している。また、前処理あり、なしで鉱油の吸着特性には変化がないことが判明した。したがって、活性炭を使用する場合には、吸着除去したくない例えば、添加剤、エステル油を予め活性炭に吸着させたものを用いることにより、使用中にこれらを吸着除去せず、機器の信頼性が向上する。活性炭による吸着では、活性炭の細孔内に分子が吸着される。そして、分子サイズ、構造により活性炭内に吸着する細孔位置が異なっている。そのため、吸着除去したくない例えば添加剤等と類似の分子サイズ、構造を有する第三の成分を予め吸着させておいても使用中に添加剤を吸着除去することはなく、同様の効果が得られる。
【００６５】
なお、本実施の形態では、添加剤とエステル油を予め活性炭に吸着させたが、吸着除去させたくない例えば、添加剤のみを予め活性炭内に吸着させておいても良く、もちろんエステル油のみでも同様の効果が得られるのは言うまでもない。
【００６６】
また、本実施の形態では、吸着剤として活性炭を用いたが、鉱油を選択的に吸着する他の吸着剤を用いてもよい。また、活性炭と他のモレキュラーシーブス等の吸着剤を組合せても活性炭により鉱油が選択的に吸着除去されることは言うまでもなく、成分として活性炭が含まれておれば同様の効果が得られる。
【００６７】
また、本実施の形態ではＨＦＣ冷媒用冷凍機油としてエステル油を用いたが、ＨＦＣ冷媒と相溶で、極性の大きいエーテル油を用いても同様の効果が得られることは言うまでもない。
【００６８】
実施の形態２．
図６は、本発明の実施の形態２による、油蓄積機構を搭載した冷凍サイクル装置の冷媒回路を示す。図６において、９は油蓄積機構、３１は油タンク、ｐ２１〜ｐ２３は冷媒回路、ｂ２１，ｂ２３は流量調整器を示す。その他の符号は、図１と同様または相当するものであるから説明を省略する。
【００６９】
図６において、弁ｂ２１、ｂ２３を閉じて、アキュムレータ６から鉱油および冷媒が油吸着器９に流入した後、流量調整器ｂ８、ｂ１０、ｂ１４を閉じる。このようにすると、活性炭による吸着時間が長くなり十分吸着できる。また、流量調節器ｂ８、ｂ１０、ｂ１４を開く、閉じる、をバッチ式で行うことにより、十分吸着できる。
また、配管ｐ３から液冷媒を配管ｐ１４を通して流量調整器ｂ１４により調整しながら油吸着器９に流入させることにより、鉱油の粘度が低下し、吸着効率が良くなる。このように、流量調整器ｂ１４を調節することにより、鉱油吸着効率が最適となるよう流入させる鉱油の粘度を調節する。
【００７０】
以上説明したように、この実施の形態では、鉱油蓄積機構としての油吸着器９に流入した鉱油を一定時間保持した後、流出させる。鉱油の流れのあるところに活性炭を用いると、吸着速度が低い場合、すなわち吸着効率が悪い場合には、十分に吸着されずに油が流出してしまう可能性もある。そこで、この実施の形態では、流入した鉱油を油吸着器９に保持しておき、十分吸着した後でメインの冷媒回路に戻すようにする。これにより鉱油の吸着をほぼ完全に行うことができる。
【００７１】
また、この実施の形態では、鉱油を液冷媒と混ぜて鉱油の濃度を下げ、また、鉱油の粘度を下げて油吸着器９に流入させる。粘度が低い鉱油は油吸着器９内での拡散速度が大きく、効率良く吸着できる。
【００７２】
さらに、流量調整器ｂ８、ｂ１０、ｂ１４を閉じた状態で弁ｂ２１、ｂ２３を開くことにより、高温ガスが油吸着器９内に流入し、活性炭から鉱油が脱着される。すなわち、活性炭は低温で吸着効率が良く、高温で悪くなるため、高温ガスを流すと吸着された活性炭が脱着する。脱着された鉱油は油タンク３１にためられる。この例では、脱着のために高温ガスを油吸着器９に流入させたが、油吸着器９の周囲にヒーターを設置しておき、ヒーター加熱等の方法でも鉱油の脱着をすることができる。
【００７３】
以上のように、この実施の形態では、油吸着器９を高温にすることにより、活性炭に蓄積した鉱油を高温脱着させる。脱着の手段は、高温のガス冷媒を通すとか、ヒーターによる熱源を用いる。脱着できるとトータルの活性炭量が少なくて済む。
【００７４】
また、この実施の形態では、油吸着器９から脱着された鉱油を油タンク３１など別容器に回収する。このように別容器に回収できればトータルの活性炭量が少なくて済み、以後、鉱油が流出することもなく安全である。
【００７５】
実施の形態３．
図７は、本発明の実施の形態３による、油蓄積機構を搭載した冷凍サイクル装置の冷媒回路を示す。図７において、９は油蓄積機構としての油吸着器、３２は圧縮機１の吐出側冷媒配管に設けられたオイルセパレータ、ｐ３２，ｐ３３，ｐ３４は冷媒回路、ｂ３２，ｂ３３，ｂ３４は流量調節器を示す。その他の符号は、図１と同様または相当するものであるから説明を省略する。
【００７６】
また、図８は図７における油吸着器９の構成を示す断面図である。図８において、１６は活性炭、１９，２２はクッション材、２６，２７は細孔部材を示す。
図７および図８において、オイルセパレータ３２からは高温の油が油吸着器９に流入する。オイルセパレータ３２からの流入する油は高温のため、粘度が低く、活性炭１６内を容易に流れる。しかしながら、高温では活性炭１６での吸着効率が悪いため、液配管ｐ３からの液冷媒を配管ｐ１４に通し流量調整器ｂ１４で調整しながら、活性炭１６の周りに流入させ油吸着器９内で熱交換させて活性炭１６の温度を下げる。
こうすることにより、活性炭での吸着効率が良くなる。つまり、高温状態の油を流すことにより油の粘度を下げ、これだけでは吸着効率が悪いため、冷媒で活性炭１６を冷やして効率良く吸着するようにする。
【００７７】
以上のように、この実施の形態では、油吸着器９をオイルセパレータ３２から圧縮機１への返油回路内に設置する。ここは油が多量にある部位のため、油の循環中に確実に吸着できる。
【００７８】
また、この実施の形態では、鉱油の吸着効率が最適となるように、活性炭の温度を下げる、あるいは流通している鉱油の温度を下げるように調整する。
【００７９】
また、この実施の形態では、油吸着器９に流入する鉱油が、上部より流入し下部に流出するように、油吸着器９や鉱油の流れ方向を工夫する。このようにすれば、重力の影響により鉱油が流れ易くなる。また、鉱油はエステル油、エーテル油より比重が低いため、活性炭１６の吸着効率が落ちた場合でも、油吸着器９内が混合油で満たされておれば鉱油が上になって浮かびやすく、流出しにくくなって良い。
【００８０】
なお、上記の実施の形態では、オイルセパレータ３２から圧縮機１へ戻す油と、アキュムレータ６から圧縮機１へ戻す油とは熱交換させるが混合はしていない。しかし、別の態様として、両方の油を油吸着器９で混合して鉱油を吸着させる方法もある。
【００８１】
実施の形態４．
図９はこの発明の実施の形態４による冷凍サイクル装置における冷媒回路の構成を示す図である。図９において、６はアキュムレータ、９は油蓄積機構としての油吸着器、３２はオイルセパレータ、ｐ３２およびｐ３５は冷媒配管、ｂ３２およびｂ３５は流量調整器を示す。その他の符号は、図１と同様または相当するものであるから説明を省略する。
【００８２】
この実施の形態では、アキュムレータ６から低温の鉱油を配管ｐ８と流量調整器ｂ８を通して油吸着器９に流入させる。その際、オイルセパレータ３２からも高温の油すなわち鉱油とエステル油との混合油を、配管ｐ３２の流量調整器ｂ３２で調節しながら流入させて混合することにより、油の粘度が低下し、活性炭内での拡散速度が上がり、吸着効率が良くなる。
また、液配管ｐ３から液冷媒を配管ｐ１４の流量調整器ｂ１４で調整しながら油吸着器９に流入させて混合することにより鉱油の粘度が低下し、活性炭内での拡散速度が上がり、吸着効率が良くなる。このように、流量調整器ｂ８，ｂ１４，ｂ３２を調節することにより、鉱油吸着効率が最適となるよう流入させる鉱油の粘度を調節する。鉱油を吸着した後の潤滑油は、配管ｐ３５と流量調整器ｂ３５を介して圧縮機１の吸入側へ戻す。
【００８３】
以上のように、この実施の形態では、アキュムレータ６から流出し圧縮機１に戻す油を油吸着器９に流入させるとともに、オイルセパレータ３２から圧縮機１へ戻す油も油吸着器９に流入させる。さらに、液配管ｐ３からの液冷媒を油吸着器９に流入させる。これらをそれぞれ流量調整器により調整して流入させて混合し、その混合比を制御する。また、油吸着器９に流入した鉱油を一定時間保持して十分に吸着をさせた後、流出させることもできる。
【００８４】
オイルセパレータ３２からの油は高温であるため、鉱油の温度を上げて鉱油の粘度を下げる作用をする。また、液配管ｐ３からの液冷媒と混ぜて全体の粘度を下げる、等の方法で粘度を下げて油吸着器に流入させる。鉱油は粘度が低いと拡散速度が高くなり、効率良く吸着できる。
【００８５】
したがって、この実施の形態では、活性炭への吸着効率が最適となるよう活性炭での液冷媒と油の圧力、温度を調整し、また、鉱油の粘度を調整する。
【００８６】
実施の形態５．
図１０はこの発明の実施の形態５による冷凍サイクル装置における冷媒回路の構成を示す図である。図１１はこの実施の形態で使用するオイルセパレータの構造を示す断面図、図１２はその活性炭パッケージの構造を示す断面図である。
図１０において、３３は圧縮機１の吐出側に設置されたオイルセパレータを示す。ｐ３２はオイルセパレータ３３から圧縮機１の吸入側への返油回路である。その他の符号は、図１と同様または相当するものであるから説明を省略する。また、図１１に示すオイルセパレータ３３において、１２３は流入管、１２４は流出管、１２５は油戻し管、１２６は中板、１２７は活性炭パッケージを示す。また、図１２に示す活性炭パッケージ１２７において、１２８は活性炭、１２９は活性炭１２８を被覆するフィルター、１３０は上下のフィルター１２９を接合する接着剤を示す。
【００８７】
この実施の形態では、図１０のような冷媒回路において、オイルセパレータ３３内に活性炭パッケージ１２７が入れられている。活性炭は一般的に粒状であるため、粒の流出を考慮する必要があるが、活性炭パッケージ１２７のようにしておけば流出もなく、使い勝手が良い。活性炭パッケージ１２７は、フィルター１２９内に包まれ、活性炭１２８が内部に入っている。そして、接着剤１３０により上下のフィルター１２９は接着されている。このように、活性炭１２８が流出しないようにしておけば、鉱油を吸着させたいところならどこでも入れられる。図１０では、オイルセパレータ３３内に入れたが、アキュムレータ６、液ダメ等の他の場所であっても良い。
【００８８】
以上のように、この実施の形態では、鉱油蓄積機構としての活性炭パッケージ１２７をオイルセパレータ３３内に内蔵した。このように冷凍サイクル装置に既にある機器ないし容器の中に活性炭パッケージを収容するため、特に設置場所を要しない点でメリットがある。また、オイルセパレータ３３などでは、油が多量にある部位のため、循環中に鉱油を確実に吸着できる。
【００８９】
また、活性炭パッケージは、アキュムレータ６内に内蔵することもできる。このようにすると、圧縮機の手前で鉱油を吸着除去するので、鉱油が圧縮機内の油（新油）と混ざることもなく良い。また、ここでは温度が低く、場合によっては冷媒もあるため、粘度が下がり、吸着効率が良い。
【００９０】
また、この実施の形態の活性炭パッケージは、活性炭をフィルター内に充填している。一般に活性炭は粒状であるため、または粉がでるため、回路に流出すると、回路がつまり不良となる。また、粒状の活性炭を現場で取り扱うには、粉も舞い作業性も悪い。そこで、フィルター内に充填されたものを用意すると、どこにでも容易に設置でき効果大である。
【００９１】
以上の各実施の形態では、冷媒から分離された潤滑油について、あるいは主冷媒回路から分離された潤滑油について、その潤滑油の中からさらに鉱油を吸着し蓄積あるいは分離する例を主として説明した。しかし、油吸着器９を冷媒回路の例えばガスラインに直接に設置して鉱油を吸着することも可能である。
【００９２】
実施の形態６．
図１３は、本実施の形態6による、油蓄積機構を搭載した冷凍サイクル装置の冷媒回路図を示す。図１３において、９は油蓄積機構であり、熱源側熱交換器３の出口側の冷媒回路ｐ３に挿入されている。すなわち、メインの冷媒回路の液管に直列に挿入されている。その他の符号は、図１と同様または相当するものであるから説明を省略する。
【００９３】
図１３において、油蓄積機構９内には液冷媒または二相冷媒と混合した状態で、鉱油およびエステル油（またはエーテル油）が流入する。そのため、混合液の粘度が低く、油蓄積機構９内での拡散速度が高くなり、効率良く鉱油を吸着除去できる。
図１３では、油蓄積機構９は熱源機１００内に設置しているが、熱源機１００の外に設置しても良く、この場合、特別な回路が必要とならないばかりか、熱源機１００内のスペースに制限がある場合には、後付けで設置できる。このため、熱源機１００は新規の延長配管を使用するものと共通（同一）にでき、製造を簡略化できる。
また、油蓄積機構９は、例えば図２のような構造を有しており、フィルターにより冷媒回路内の固形異物を捕捉できる。
【００９４】
以上のように、この実施の形態では、油蓄積機構を液または二相ラインに設けた。そのため、鉱油が冷媒に混合した状態で油蓄積機構に流入するため、混合液の粘度が低下し、効率良く鉱油を吸着除去できる。また、油蓄積機構を熱源機の外に設置することもでき、熱源機を新規の延長配管を使用するものと共通（同一）にでき、製造を簡略化できる。
【００９５】
実施の形態７．
図１４は、本実施の形態７による、油蓄積機構を搭載した冷凍サイクル装置の冷媒回路図を示す。図１４において、９は油蓄積機構、ｐ４１は冷媒配管ｐ３からバイパスした冷媒配管で、他端が油蓄積機構９と接続されている。また、油蓄積機構９の他端は冷媒配管ｐ４２と接続され、冷媒回路の主回路である冷媒配管ｐ３に至っている。また、ｂ４１およびｂ４２は、それぞれの配管内に設置された弁である。また、ｂ３は配管３に油蓄積機構９と並列に設置された弁である。その他の符号は、図１と同様または相当するものであるから説明を省略する。
【００９６】
図１４において、油蓄積機構９内には液冷媒または二相冷媒と混合した状態で、鉱油およびエステル油（またはエーテル油）が流入する。そのため、混合液の粘度が低く、油蓄積機構９内での拡散速度が高くなり、効率良く鉱油を吸着除去できる。
また、油蓄積機構９は、冷媒回路の主回路である冷媒配管ｐ３からバイパスした位置に設置されており、異物等により油蓄積機構９内が詰まり、混合液が流れなくなった場合にでも、混合液は冷媒配管ｐ３を流れるため問題ない。また、弁ｂ３を閉じて弁ｂ４１、弁ｂ４２を開くことにより混合液の全量を油蓄積機構９内に流入させることもでき、この場合、バイパスとして流入させるよりも短時間で冷媒回路内の鉱油を油蓄積機構９内に蓄積することができる。
【００９７】
また、弁ｂ４１、弁ｂ４２を閉じて弁３を開くことにより、油蓄積機構９内に混合液を流入させないことも可能であり、油蓄積機構９内の吸着効率が落ちた場合には、このようにして油蓄積機構９を冷媒回路から切り離すこともできる。なお、これらの弁ｂ３，ｂ４１，ｂ４２をバッチ式に切替え、油蓄積機構９への流動を自由に制御することもできる。ここでは、弁ｂ３，ｂ４１，ｂ４２を設置したが、必要に応じてこれらは省略することもできる。
【００９８】
図１４では、油蓄積機構９は熱源機１００内に設置しているが、熱源機１００の外に設置しても良く、この場合、特別な回路が必要とならないばかりか、熱源機１００内のスペースに制限がある場合には、後付けで設置できるため、熱源機１００は新規の延長配管を使用するものと共通（同一）にでき、製造を簡略化できる。また、油蓄積機構９は、例えば図２のような構造を有しており、フィルターにより冷媒回路内の固形異物を捕捉できる。
【００９９】
実施の形態６及び７では、冷媒の液または二相ラインに油蓄積機構９のみを設けた例を示したが、実施の形態１で説明したように油抽出器と油吸着器とを二段に設けてもよい。
また、実施の形態６及び７では、液または二相ラインに直接に油吸着器を設けた例を示したが、液だめに油吸着器９を設けてもよい。この場合、液だめ容器内に油吸着剤を収納してもよく、また液だめ容器からバイパスさせてから吸着させてもよい。さらにまた、液だめの下流に油抽出器と油吸着器とを設けるようにしてもよい。
【０１００】
以上のように、この実施の形態では、油蓄積機構を液または二相ラインのバイパスに設けるとともに、必要に応じて弁を設けた。そのため、必要に応じて冷媒、油の混合液の流路を自由に制御できるとともに、油蓄積機構を回路内から切り離すこともでき、油蓄積機構内が詰まった場合にでも通常の冷凍・空調運転を継続することができる。
【０１０１】
その他の説明．
以上、実施の形態１〜７にわたって、この発明における油蓄積機構を搭載した冷凍サイクル装置の例について説明した。
油吸着器、あるいは油吸着器を含む油蓄積機構は、基本的には冷媒回路のどの位置に設置しても鉱油を吸着することができる。すなわち、冷媒回路のガスラインでも、液または二相ラインでも設置が可能である。また、そのバイパスラインにも設置できる。油吸着器の設置位置は、冷凍サイクル装置の特性、吸着の効率、機器への信頼性などを考慮して最適に選定しうる。設置位置の選定に当たっての主な考え方を以下に説明する。
（１）油吸着器の吸着効率は、液自体の粘度が低い方が拡散速度が増し、効率が良くなる。よって、液冷媒を混合させて粘度を下げる方法がとれる。
（２）油吸着器においては、活性炭の温度が低い方が吸着効率がよくなる。一方、液自体の温度は高い方が粘度が低くなるため、高温の液を流したとしても、活性炭自身を冷却しておくと、効率がよくなると考えられる。図８の例はその一例である。
（３）油吸着器により、冷媒が圧縮機に入る前に鉱油を吸着させてしまうと、圧縮機でスラッジが発生することもなく、安全である。例えばアキュムレータに活性炭を設置したり、また専用の吸着用の別容器を設けても良い。
（４）油吸着器を、バイパス回路に設置しておくと、主冷媒回路は影響をうけずに運転できる。また、バイパス回路に設置することにより、冷媒液、分離除去したい液（鉱油）量を自由に弁等で調整できるため、効率の良い吸着速度、粘度等で使用できる。
（５）油吸着器を、オイルセパレータ等の油が多量にあるところに用いた場合には、循環量が多く、比較的早く、鉱油濃度を低減できると考えられる。
（６）油吸着器を、既に冷媒回路内で容器として存在している部位に使用すると、設置スペースが必要ないというメリットが出る。例えば、アキュムレータ内、オイルセパレータ内、液ダメ内に設置する場合である。
（７）油吸着器を、液ラインあるいは気液二相ラインに使用すると、複雑な回路とならず、簡略的に使用できるメリットがある。
【０１０３】
【発明の効果】
この発明の冷凍サイクル装置では、請求項１に記載のように、旧潤滑油と新潤滑油との混合油から油吸着剤により旧潤滑油を吸着する機構を備えた。これにより、既設配管中に残留していた旧潤滑油を分離回収し、新潤滑油の劣化を抑えることができる。
【０１０４】
この発明の冷凍サイクル装置では、請求項２に記載のように、旧潤滑油と新潤滑油と新冷媒との混合液を二相分離させた状態から旧潤滑油に富む冷媒液を分離したうえ、油吸着剤により旧潤滑油を吸着する機構を備えた。これにより、既設配管中に残留していた旧潤滑油を分離回収し、新潤滑油の劣化を抑えることができるうえ、旧潤滑油の分離を二段に行うので、より十分に旧潤滑油を分離回収できる。
【０１０５】
この発明の冷凍サイクル装置では、請求項４〜６に記載のように、油蓄積機構を、アキュムレータで分離された潤滑油を圧縮機に戻す返油回路に設けた。これにより効率よく旧潤滑油を吸着・分離できる。
【０１０６】
この発明の冷凍サイクル装置では、請求項７〜９に記載のように、油蓄積機構を、オイルセパレータで分離された潤滑油を圧縮機に戻す返油回路に設けた。これにより、油が多量にある部位において油の循環中に旧潤滑油を確実に吸着できる。
【０１０７】
この発明の冷凍サイクル装置では、請求項１０，１１に記載のように、冷媒回路から液冷媒を分流させて油蓄積機構の油吸着剤と熱交換させる手段を設けた。これにより、吸着器の温度を下げるなどの温度調節ができ、吸着を効果的に行わせることができる。
【０１０８】
この発明の冷凍サイクル装置では、請求項１２〜１４に記載のように、アキュムレータで分離されて圧縮機に戻す潤滑油と、オイルセパレータで分離されて圧縮機に戻す潤滑油とを油蓄積機構で合流させた。また、流入量を調整できるようにした。これにより、旧潤滑油を効率よく吸着・分離できる。また、流入量、圧力、温度などを調整し、吸着効率が最適となるようにできる。また、潤滑油の流入を一時的に停止し吸着を十分に行ってから、次の潤滑油を流入させるようにすることもできる。
【０１０９】
この発明の冷凍サイクル装置では、請求項１５〜１７に記載のように、油蓄積機構に蓄積された油を脱着させる脱着機構を設けた。これにより活性炭を繰り返し利用でき活性炭量が少なくて済む。
【０１１０】
この発明の冷凍サイクル装置では、請求項１８に記載のように、油蓄積機構への潤滑油の流入・停止ならびに流入量を調整する手段と、冷媒回路から油蓄積機構への液冷媒の流入・停止ならびに流入量を調整する手段とを設け、各潤滑油と液冷媒の流入・停止ならびに混合比を調整できるようにした。これにより、油蓄積機構での液冷媒と油の圧力あるいは温度を調整したり、また、鉱油の粘度を調整したりでき、鉱油の吸着効率が最適となるように調整することができる。
【０１１１】
この発明の冷凍サイクル装置では、請求項１９に記載のように、油蓄積機構をアキュムレータ内部に設けた。これにより、油蓄積機構として特別な設置スペースが要らないうえ、潤滑油が圧縮機に入る手前で旧潤滑油を吸着し圧縮機内の新油と混ざることを防止できる。
【０１１２】
この発明の冷凍サイクル装置では、請求項２０に記載のように、油蓄積機構をオイルセパレータ内部に設けた。これにより、油蓄積機構として特別な設置スペースが要らないうえ、油が多量にある部位のため、旧潤滑油を循環中に確実に吸着できる。
【０１１３】
この発明の冷凍サイクル装置では、請求項２１に記載のように、油蓄積機構を、油が垂直方向の上方から下方に向かって流通するように配置した。これにより、重力の影響で流れ易くなり、吸着の効率が上がる。
【０１１４】
この発明の冷凍サイクル装置では、請求項２２に記載のように、油蓄積機構を、冷媒回路に対し着脱可能な着脱手段によって結合した。これにより、油蓄積機構が必要なくなれば取り外せるので、省スペースになる。
【０１１５】
この発明の冷凍サイクル装置では、請求項２３〜２５に記載のように、油蓄積機構の油吸着剤として活性炭を用いた。これにより旧潤滑油を効率よく吸着できる。
【０１１６】
この発明の冷凍サイクル装置では、請求項２６，２７に記載のように、油蓄積機構の油吸着剤である活性炭が流出するのを防止するようにした。これにより、回路が不良になるのを防止できる。
【０１１７】
この発明の冷凍サイクル装置では、請求項２８，２９に記載のように、油蓄積機構において活性炭を脱自在に支持した。これにより、活性炭の支持、取換えなどが便宜となる。
【０１１８】
この発明の冷凍サイクル装置では、請求項３０に記載のように、油吸着剤に第二の潤滑油及び／又はその添加剤を予め吸着させた。そのため、使用中に潤滑油として有効な成分を吸着しないため、機器の信頼性が向上する。
【０１１９】
この発明の冷凍サイクル装置では、請求項３１に記載のように、従来のクロロフルオロカーボン系冷媒またはハイドロクロロフルオロカーボン系冷媒に代えてハイドロフルオロカーボン系冷媒を用いる。これにより、環境対策を向上させることができる。
【図面の簡単な説明】
【図１】 本発明の実施の形態１による、油蓄積機構を搭載した冷凍サイクル装置の冷媒回路を示す。
【図２】 本発明の実施の形態１による、油蓄積機構としての油吸着器の構造例を示す。
【図３】 本発明の実施の形態１による、油吸着器の他の構造例を示す。
【図４】 冷媒中の油（鉱油＋エステル油等）濃度に対する、活性炭による吸着速度の関係を示す。
【図５】 本発明の実施の形態１における、実験に用いた活性炭の累積細孔分布である。
【図６】 本発明の実施の形態２による、油蓄積機構を搭載した冷凍サイクル装置の冷媒回路を示す。
【図７】 本発明の実施の形態３による、油蓄積機構を搭載した冷凍サイクル装置の冷媒回路を示す。
【図８】 本発明の実施の形態３による、油吸着器の構成を示す断面図である。
【図９】 本発明の実施の形態４による、冷凍サイクル装置における冷媒回路の構成を示す図である。
【図１０】 本発明の実施の形態５による、冷凍サイクル装置における冷媒回路の構成を示す図である。
【図１１】 本発明の実施の形態５で使用するオイルセパレータの構造を示す断面図である。
【図１２】 本発明の実施の形態５で使用する活性炭パッケージの構造を示す断面図である。
【図１３】 本発明の実施の形態６による、冷凍サイクル装置における冷媒回路の構成を示す図である。
【図１４】 本発明の実施の形態７による、冷凍サイクル装置における冷媒回路の構成を示す図である。
【符号の説明】
１００ 熱源機、 ２００ 利用側機、 １ 圧縮機、 ２ 四方弁、３ 熱源側熱交換器、 ４ 流量調整器、 ５ 利用側熱交換器、 ６ アキュムレータ、 ７ 抽出容器、 ８ 抽残液貯留容器、 ９ 油蓄積機構（油吸着器）、 １０ 冷媒熱交換器、 １１ 流量調整器、 ３１ 油タンク、 ３２ オイルセパレータ。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a refrigeration cycle apparatus or an air conditioning / refrigeration apparatus used by replacing an existing refrigerant with a new type of refrigerant.
As an example, the present invention relates to a refrigeration cycle apparatus that uses a chlorofluorocarbon (CFC) refrigerant or a hydrochlorofluorocarbon (HCFC) refrigerant by replacing it with a hydrofluorocarbon (HFC) refrigerant. In more detail, the heat source machine is updated to one using a new HFC refrigerant, and the existing extension pipe and / or use side machine used for the old refrigerant CFC refrigerant or HCFC refrigerant is used. While performing normal refrigeration and air-conditioning operation, it is possible to divert existing piping and / or use-side equipment by accumulating lubricating oil of old refrigerant remaining in existing piping and / or use-side equipment in a part of the refrigerant circuit. It relates to a refrigeration cycle apparatus.
[0002]
[Prior art]
As a technique for using existing piping in a conventional refrigeration cycle apparatus, for example, there is one disclosed in Japanese Patent Laid-Open No. 6-249551. This is intended to recover the mineral oil remaining in the existing pipes and to use the existing pipes by raytrofit, mainly for car air conditioners.
[0003]
[Problems to be solved by the invention]
However, in such a technique, when the existing piping such as a car air conditioner is short, the lubricating oil concentration for the old refrigerant in the system can be reduced by repeating the cleaning operation. In a refrigerator having a complicated refrigerant circuit using various loads such as a showcase on the use side, the lubricating oil concentration for the old refrigerant cannot be easily reduced in a short time operation.
The present invention has been made to solve such a conventional problem. For example, an HCFC-based refrigerant or a CFC-based refrigerant used as an old refrigerant is replaced with, for example, an HFC-based refrigerant as a new refrigerant. Even when ester oil or ether oil, which is lubricating oil, is mixed with mineral oil, which is lubricating oil of the old refrigerant that remains in the existing piping, the mineral oil remaining in the existing piping is removed while performing normal operation. The purpose is to improve the reliability of the refrigeration cycle by separating and recovering, suppressing the deterioration of new ester oil or ether oil, facilitating the construction of refrigeration / air conditioners using existing piping.
[0007]
[Means for Solving the Problems]
The refrigeration cycle apparatus of the present invention is Claim 1 As described in the above, the extension pipe and / or the use side machine used in the refrigeration cycle apparatus using the first refrigerant and the first lubricating oil, the second refrigerant and the second lubricating oil were used. In the refrigeration cycle apparatus used as an extension pipe and / or a use side machine of the refrigeration cycle apparatus, the oil that adsorbs the first lubricating oil from the mixed oil of the first lubricating oil and the second lubricating oil by an oil adsorbent. It has a storage mechanism.
[0008]
The refrigeration cycle apparatus of the present invention is Claim 2 As described in the above, the extension pipe and / or the use side machine used in the refrigeration cycle apparatus using the first refrigerant and the first lubricating oil, the second refrigerant and the second lubricating oil were used. In the refrigeration cycle apparatus used as an extension pipe of the refrigeration cycle apparatus and / or a use side machine, the second refrigerant is mixed with the mixed oil of the first lubricating oil and the second lubricating oil, and then two-phase separation is performed. An extractor for separating the second lubricating oil-rich refrigerant liquid from the state, and the first lubricating oil is adsorbed by an oil adsorbent from the second lubricating oil-rich refrigerant liquid separated from the extractor And an oil accumulation mechanism.
[0009]
The refrigeration cycle apparatus of the present invention is Claim 3 As described above, the oil accumulation mechanism is provided in the bypass circuit of the refrigerant circuit.
[0010]
The refrigeration cycle apparatus of the present invention is Claim 4 As described above, the oil accumulation mechanism is provided in the oil return circuit from the accumulator to the compressor.
[0011]
The refrigeration cycle apparatus of the present invention is Claim 5 As described above, a circuit is provided for allowing the liquid refrigerant from the refrigerant circuit to flow into the oil accumulation mechanism, and is mixed with the lubricating oil flowing from the accumulator.
[0012]
The refrigeration cycle apparatus of the present invention is Claim 6 The inflow / stop of the lubricating oil from the accumulator to the oil accumulation mechanism and the inflow amount are adjusted, and the inflow / stop and inflow amount of the liquid refrigerant from the refrigerant circuit to the oil accumulation mechanism are An adjusting means is provided so that the inflow / stop of the lubricating oil and the liquid refrigerant and the mixing ratio can be adjusted.
[0013]
The refrigeration cycle apparatus of the present invention is Claim 7 As described above, the oil accumulation mechanism is provided in the oil return circuit from the oil separator to the compressor.
[0014]
The refrigeration cycle apparatus of the present invention is Claim 8 As described above, a circuit for allowing liquid refrigerant from a refrigerant circuit to flow into the oil accumulation mechanism is provided and mixed with lubricating oil flowing from the oil separator.
[0015]
The refrigeration cycle apparatus of the present invention is Claim 9 The means for adjusting the inflow / stop of the lubricating oil and the inflow amount from the oil separator to the oil accumulation mechanism, and the inflow / stop of the liquid refrigerant and the inflow amount from the refrigerant circuit to the oil accumulation mechanism An adjusting means is provided so that the inflow / stop of the lubricating oil and the liquid refrigerant and the mixing ratio can be adjusted.
[0016]
The refrigeration cycle apparatus of the present invention is Claim 10 As described in the above, there is provided means for diverting the liquid refrigerant from the refrigerant circuit and exchanging heat with the oil adsorbent of the oil accumulation mechanism.
[0017]
The refrigeration cycle apparatus of the present invention is Claim 11 And a means for adjusting the amount of lubricating oil flowing from the oil separator into the oil accumulation mechanism and a means for adjusting the amount of liquid refrigerant to be diverted from the refrigerant circuit, and the temperature of the oil adsorbent Can be adjusted.
[0018]
The refrigeration cycle apparatus of the present invention is Claim 12 As described above, the oil accumulation mechanism is provided in a merging circuit in which an oil return circuit from the accumulator to the compressor and an oil return circuit from the oil separator to the compressor are merged.
[0019]
The refrigeration cycle apparatus of the present invention is Claim 13 As described above, a circuit is provided for allowing liquid refrigerant from the refrigerant circuit to flow into the oil accumulation mechanism, and is mixed with the lubricating oil flowing from the accumulator and the oil separator.
[0020]
The refrigeration cycle apparatus of the present invention is Claim 14 The means for adjusting the inflow / stop of the lubricating oil from the accumulator to the oil accumulation mechanism and the amount of inflow, and the inflow / stop of the lubricating oil from the oil separator to the oil accumulation mechanism and the amount of inflow Means for adjusting and means for adjusting the amount of inflow / stop of the liquid refrigerant and the amount of inflow from the refrigerant circuit to the oil accumulation mechanism can be provided, and the inflow / stop of the respective lubricating oil and the liquid refrigerant and the mixing ratio can be adjusted It is what I did.
[0021]
The refrigeration cycle apparatus of the present invention is Claim 15 As described above, a desorption mechanism for desorbing the oil accumulated in the oil accumulation mechanism is provided.
[0022]
The refrigeration cycle apparatus of the present invention is Claim 16 As described above, the desorption mechanism has means for introducing the refrigerant gas of the refrigerant circuit into the oil accumulation mechanism and heating the adsorbent.
[0023]
The refrigeration cycle apparatus of the present invention is Claim 17 As described above, the desorption mechanism has means for heating the oil accumulation mechanism with an external heat source.
[0024]
The refrigeration cycle apparatus of the present invention is Claim 18 As described above, a collection container for collecting the desorbed oil is connected to the oil accumulation mechanism.
[0025]
The refrigeration cycle apparatus of the present invention is Claim 19 As described above, the oil accumulation mechanism is provided inside the accumulator.
[0026]
The refrigeration cycle apparatus of the present invention is Claim 20 As described above, the oil accumulation mechanism is provided inside the oil separator.
[0027]
The refrigeration cycle apparatus of the present invention is Claim 21 As described above, the oil accumulation mechanism is arranged so that oil flows from the upper side to the lower side in the vertical direction.
[0028]
The refrigeration cycle apparatus of the present invention is Claim 22 As described above, the oil accumulation mechanism is coupled to the refrigerant circuit by a detachable means that is detachable.
[0029]
The refrigeration cycle apparatus of the present invention is Claim 23 As described above, activated carbon is used as an oil adsorbent for the oil accumulation mechanism.
[0030]
The refrigeration cycle apparatus of the present invention is Claim 24 The average pore diameter of the activated carbon is 1 to 10 nm.
[0031]
The refrigeration cycle apparatus of the present invention is Claim 25 As described above, the activated carbon is bonded with a thermoplastic resin.
[0032]
The refrigeration cycle apparatus of the present invention is Claim 26 As described above, the oil accumulation mechanism is obtained by partitioning at least the downstream side of activated carbon as an oil adsorbent with a filter.
[0033]
The refrigeration cycle apparatus of the present invention is Claim 27 As described above, the oil accumulation mechanism is obtained by coating activated carbon as an oil adsorbent with a filter.
[0034]
The refrigeration cycle apparatus of the present invention is Claim 28 As described above, the oil accumulation mechanism supports activated carbon covered with a filter in a detachable manner in a container.
[0035]
The refrigeration cycle apparatus of the present invention is Claim 29 As described above, the oil accumulation mechanism is a structure in which activated carbon covered with a filter is elastically supported by an elastic member in a container.
[0036]
The refrigeration cycle apparatus of the present invention is Claim 30 As described above, the second lubricating oil and / or additive thereof is preliminarily adsorbed on the oil adsorbent.
[0037]
The refrigeration cycle apparatus of the present invention is Claim 31 The first refrigerant is a chlorofluorocarbon refrigerant or hydrochlorofluorocarbon refrigerant, the first lubricating oil is mineral oil, and the second refrigerant is a hydrofluorocarbon refrigerant, An ester oil or an ether oil is used as the second lubricating oil.
[0038]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and the description thereof may be simplified or omitted.
Embodiment 1 FIG.
FIG. 1 shows a refrigerant circuit of a refrigeration cycle apparatus equipped with an oil accumulation mechanism according to Embodiment 1 of the present invention. In FIG. 1, 100 indicates a heat source unit or outdoor unit, and 200 indicates a use side unit or indoor unit. 1 is a compressor, 2 is a four-way valve, 3 is a heat source side heat exchanger, 4 is a flow rate regulator, 5 is a use side heat exchanger, and 6 is an accumulator. In addition, 7 is an extraction container that separates new and old lubricating oil from a mixture of old and new lubricating oil, 8 is a residual liquid storage container, and 9 is an oil storage mechanism that adsorbs and accumulates old refrigerant lubricating oil. The oil adsorber, 10 is a refrigerant heat exchanger, and b14 is a flow rate regulator. In addition, p1 to p14 are refrigerant pipes connecting the above devices, and in particular, p4 is a liquid pipe (liquid extension pipe) as an extension pipe, p5 is a gas pipe (gas extension pipe) as an extension pipe, The heat source device 100 and the use side device 200 are connected to form a refrigerant circuit.
[0039]
An example of the extraction container 7 that can be used in the present invention has been described in detail in the previous application by the present inventors, Japanese Patent Application No. 2000-393582 (reference number 528719JP01).
The extraction container mixes the extraction mixture of the extract and the original solvent and the extract at a ratio for two-phase separation, extracts the extract in the extract into the extract, The density is lower than the density of the extraction liquid, and a mechanism for separating only the extraction residual liquid is provided.
In addition, as an example of the structure of the extraction container, the extract inflow pipe having a length in the vertical direction, the extract inflow pipe disposed at a position lower than the extract inflow pipe, the extract inflow pipe, and the above An extraction residual liquid outflow pipe arranged at a position higher than the extract inflow pipe, an extraction container for extracting a predetermined component from the extract by the extract, and an extract outflow pipe (extracted liquid outflow) having a length in the vertical direction A liquid level generating container having a pipe) in the lower part and the upper part in the vertical direction, respectively, and the extractant outflow pipe and the extraction residual liquid outflow pipe are more than the liquid level formed by the extractant outflow pipe. It arrange | positions so that the liquid level formed by extraction residual liquid outflow piping may become high.
[0040]
In FIG. 1, the extraction container 7 is connected to the lower part of the accumulator 6 through a drawing inflow pipe p8, and is connected to the heat source side heat exchanger 3 downstream of the heat source side heat exchanger 3 through an inflow pipe p14 and a valve b14. It is connected between the liquid pipe p4. Furthermore, it is connected to the extraction residual liquid storage container 8 through the extraction residual liquid outflow pipe p12. One end of the outflow pipe p <b> 9 is connected to the extraction container 7, and the other end is connected to the suction pipe p <b> 7 of the compressor 1 through the refrigerant heat exchanger 10 through the pipe p <b> 11, thereby forming the outdoor unit 100. In FIG. 1, only one system of the indoor unit 200 is shown, but there may be a plurality of systems in parallel.
[0041]
A new refrigerant replaces an existing refrigeration and air-conditioning system that used an old refrigerant, such as an HCFC or CFC refrigerant, and a first refrigeration oil (lubricating oil) such as mineral oil or hard alkylbenzene oil. Is replaced with a refrigeration / air-conditioning apparatus using a second refrigerant, for example, an HFC refrigerant, and a second refrigerating machine oil (lubricating oil), for example, ester oil or ether oil, to form the refrigerant circuit as described above.
That is, when constructing a refrigeration / air conditioner having the above-described configuration, the liquid pipe and gas pipe, or the liquid pipe / gas pipe and the indoor unit used in the unit filled with the HCFC or CFC refrigerant are installed. Mineral oil used as HCFC or CFC refrigerating machine oil in liquid pipes and gas pipes and indoor units when diverted and newly installed outdoor unit using HFC refrigerant and ester oil or ether oil as refrigerating machine oil Remains. An operation when the refrigeration / air conditioner is cooled in this state and a method for recovering mineral oil will be described.
[0042]
The high-temperature and high-pressure gas refrigerant discharged from the compressor 1 dissipates heat in the heat source side heat exchanger 3, condenses and liquefies, and flows through the liquid pipe p4. The liquid refrigerant flowing in the liquid pipe p4 cleans the mineral oil in the liquid pipe p4 while dragging the mineral oil remaining in the liquid pipe p4 by the interfacial shear force generated between the liquid refrigerant and the mineral oil. The liquid refrigerant that has flowed through the liquid pipe p4 enters the indoor unit 200, evaporates, flows through the gas pipe p5, and the mineral oil remaining in the gas pipe p5 is dragged by the shearing force generated between the gas refrigerant and the mineral oil. Wash the mineral oil in the tube. The gas refrigerant that has flowed through the gas pipe p5 returns to the outdoor unit 100, and returns to the compressor 1 via the four-way valve 2 and the accumulator 6. At this time, the ester oil taken out from the compressor 1 circulates in the existing refrigerant pipe together with the refrigerant, mixes with the mineral oil remaining in the existing pipe, and enters the accumulator 6 together with the refrigerant.
[0043]
When separating the recovered mineral oil from the existing pipe, the valve b14 is opened, the high-pressure liquid refrigerant is throttled to the low-pressure two-phase refrigerant by the flow rate regulator b14, and is led to the extraction container 7 through the inflow pipe p14. Further, from the accumulator 6, the mixed oil of the mineral oil and the ester oil recovered from the existing pipe flows into the extraction container 7 through the extract inflow pipe p8. In the extraction container 7, the ester oil in the mixed oil of mineral oil and ester oil is extracted into the refrigerant, and the oil rich in mineral oil, which is the extracted residual liquid, becomes the upper layer and is separated into two phases, and the amount of oil rich in mineral oil increases. The residual liquid storage container 8 stores the residual liquid through the extracted residual liquid outlet pipe p12. The mixed liquid of the lower layer refrigerant and the oil rich in ester oil (including slightly mineral oil) flows out from the outflow pipe p9 and is led to the oil adsorber 9, where the mineral oil is adsorbed and removed by activated carbon or the like in the oil adsorber 9. Is done. Since the mineral oil dissolved in the liquid refrigerant flows into the oil adsorber 9 as described above, the viscosity is lower than that of the mineral oil alone, and as a result, the diffusion rate is increased and the adsorption efficiency is good. The oil from which the mineral oil has been adsorbed and removed passes through the pipe p10 from the oil adsorber 9, and the liquid refrigerant evaporates and vaporizes in the refrigerant heat exchanger 10, and only the oil rich in ester oil flows into the suction pipe p7 of the compressor 1.
[0044]
As described above, it is used for a refrigeration / air-conditioning apparatus that is operated using a CFC-based or HCFC-based refrigerant, and uses an existing pipe in which mineral oil, which is a refrigerating machine oil for a CFC-based or HCFC-based refrigeration cycle, is used. Newly installed outdoor units and indoor units, and in refrigeration and air-conditioning systems that use HFC refrigerants as refrigerants, separate and collect existing pipes or existing oil and mineral oil remaining in indoor units as needed while performing normal operation. Or since it can adsorb and remove, it can prevent that ester oil deteriorates by mixing the deteriorated mineral oil and ester oil.
[0045]
Further, after the mineral oil is captured in a pressure vessel such as the accumulator 6, for example, the amount of mineral oil flowing into the extraction vessel 7 and the oil adsorber 9 can be controlled by allowing the mineral oil to flow into the extraction vessel 7 and the oil adsorber 9. The extraction in the extraction container 7 and the mineral oil adsorption in the oil adsorber 9 can be performed well. Further, by capturing the mineral oil flowing from the existing piping just before flowing into the compressor 1 like the accumulator 6, the lubricity in the compressor is not hindered by the mineral oil, and the reliability of the refrigeration cycle apparatus is improved. To do.
[0046]
Further, the extraction container 7 and the adsorption container 9 are installed at positions bypassing the main circuit connecting the compressor 1, the four-way valve 2, the heat source side heat exchanger 3, the flow rate regulator 4, the use side heat exchanger 5, and the accumulator 6. Thus, extraction and adsorption of mineral oil are not hindered by the rapid flow rate of the main circuit, and even if the extraction container 7 and the adsorber 9 do not operate due to failure, there is no hindrance to normal air conditioning operation. The reliability of the equipment is improved.
[0047]
As described above, in this embodiment, the refrigerant circuit for returning the ester oil flowing out from the accumulator 6 to the suction pipe p7 of the compressor 1 includes the extraction container 7 and the oil adsorber 9, and the extraction container 7 separates the mineral oil. The ester oil was extracted and recovered, and a slight amount of mineral oil contained in the extracted ester oil was removed by adsorption using the oil adsorber 9. That is, extraction of ester oil and adsorption of mineral oil were combined in series. Therefore, the removal rate of mineral oil is improved, and high purity ester oil can be recovered and utilized.
It is also possible to remove all mineral oil remaining in the refrigerant circuit by adsorption using an adsorbent such as activated carbon. In this case, a large amount of activated carbon is required, but in this embodiment, the mineral oil is first removed roughly by extraction, and the mineral oil that cannot be removed is removed by adsorption, so that a small amount of activated carbon is required. There is a merit.
[0048]
Next, FIG. 2 shows a structural example of an oil adsorber as an oil accumulation mechanism according to this embodiment. In FIG. 2, 16 is a cylindrical activated carbon, 17 and 18 are filters (resins) covering the inner and outer cylindrical surfaces of the activated carbon, 19 is a cushion material on one end surface, 20 and 21 are plate materials, and 22 is a cushion on the other end surface. The material 23 is a fixing spring.
The activated carbon 16 is hardened with a thermoplastic resin such as PP (polypropylene) or PE (polyethylene). Therefore, even when the activated carbon 16 is incorporated in the container, the activated carbon powder does not fly, and the workability at the site is good. Further, since the sides are covered with the filters 17 and 18 made of PP, PE, etc., there is no possibility that broken powder flows out into the circuit. Further, the cushioning materials 19 and 22 and the spring 23 provide cushioning properties, and the container can be sealed by welding or the like while being pressed down during manufacturing. The direction of oil flow is indicated by the arrow, but there is no problem in the reverse direction.
[0049]
As described above, in this embodiment, activated carbon is used as a material for adsorbing mineral oil by the oil adsorber 9. Activated carbon has the property of selectively adsorbing non-polar substances, and can selectively adsorb mineral oils that are less polar than ester oils or ether oils.
[0050]
In this oil adsorber, activated carbon was bound with a binder. Incorporation of normal activated carbon into the refrigerant circuit is inferior in workability, such as powder flying during assembly. Therefore, it is possible to prevent powder from fluttering on site by solidifying with a thermoplastic resin (PP, PE, etc.) and molding it into a cartridge type and then incorporating it.
[0051]
In this oil adsorber, a filter was provided on the end face of the activated carbon. Ordinary activated carbon has a small particle size and may be crushed during use to close the refrigerant circuit, so a filter is provided on the downstream side in the oil flow direction to prevent outflow.
[0052]
Moreover, in this oil adsorber, since the activated carbon is fixed by providing a spring in the container, the activated carbon can be prevented from shaking.
[0053]
In this oil adsorber, the entire periphery of the activated carbon was covered with a filter. In other words, the filter is filled with activated carbon. Since activated carbon is generally granular or powdered, if it flows out into the refrigerant circuit, the circuit becomes defective. Also, when handling granular activated carbon on-site, powder is also poor and workability is poor. Therefore, by preparing a filter filled in the filter, it is possible to prevent the powder from flowing out, and it can be easily installed anywhere and the workability is improved. Moreover, the solid foreign substance in a refrigerant circuit can also be removed with a filter.
[0054]
Next, FIG. 3 shows another structural example of the oil adsorber according to this embodiment. In this oil adsorber, the container has a flange structure or the like, and a flange 24 is attached. The activated carbon 16 sealed with an internal filter can be easily taken out and replaced. There is a merit that the concentration of the mineral oil flowing out from the oil adsorber 9 is periodically measured, and the activated carbon can be replaced when the concentration is not lowered. Moreover, it can also be made a new state by processing the taken-out activated carbon, and also leads to recycling of activated carbon.
In addition, the oil adsorber 9 is equipped with screws 25 at both ends, and can be easily attached to and detached from the refrigerant pipe.
[0055]
In this way, if the oil adsorber 9 is made removable, it can be removed if the oil adsorber 9 is no longer needed, so the advantage is great when the space is limited.
[0056]
Next, FIG. 4 shows the relationship between the adsorption rate by activated carbon and the concentration of oil (mineral oil + ester oil, etc.) in the refrigerant. At the point where the oil concentration in the refrigerant is low, the viscosity of the liquid is low and the adsorption speed is fast, but the total amount of mineral oil contained in the liquid is small, and the adsorption speed of the activated carbon is not fully utilized (can still be adsorbed within a unit time) Afford). On the other hand, when the oil concentration is 100%, the adsorption rate is slow because the viscosity is high. There seems to be an optimum point around the middle where the viscosity of the liquid is low and the adsorption rate of the activated carbon can be utilized.
[0057]
Table 1 shows the results of the mineral oil adsorption test when three types of activated carbon A, B, and C are used. In this experiment, a mixture of 10% mineral oil, 40% ester oil, and R407C50% was put into activated carbon, and the adsorption characteristics of mineral oil due to the difference in activated carbon were examined.
[0058]
[Table 1]

[0059]
FIG. 5 shows the cumulative pore distribution of the activated carbon used in this experiment. Both the activated carbons A and B had a mineral oil concentration of 1% or less after the treatment. In activated carbon C, the mineral oil concentration after the treatment hardly changed. Therefore, activated carbon having a pore distribution of 1 to 10 nm is suitable for mineral oil adsorption.
[0060]
Activated carbon has a property of selectively adsorbing nonpolar substances, and easily adsorbs mineral oil having low polarity (close to nonpolarity) among mineral oils and ester oils. And adsorption to activated carbon is determined by the relationship between polarity, molecular size and pore size. As described above, as a result of examining the mineral oil adsorptivity by activated carbon having various pore diameters experimentally as described above, it was found that activated carbon having an average pore diameter of 1 to 10 nm adsorbs mineral oil efficiently.
[0061]
Moreover, in lubricating oil used with HFC refrigerants, such as ester oil and ether oil, the additive is added, for example, in order to add lubricity. Therefore, when the additive is adsorbed and removed by activated carbon, the performance as a lubricating oil is lowered, and the reliability of the equipment is lowered. Further, when the ester oil is also adsorbed, the lubricating oil in the compressor is reduced and the reliability of the equipment is lowered. Therefore, the additive adsorption characteristics were experimentally investigated using activated carbon having the same pore diameter as activated carbon A in FIG. In this experiment, a mixture of 10% mineral oil, 40% ester oil, and R407C50% was placed in activated carbon and the adsorption characteristics were examined.
[0062]
Table 2 shows changes in the adsorption characteristics of the additives a, b, c, and d by activated carbon and changes in the adsorption characteristics of the ester oil. Conditions in each experiment are as follows.
I. No pretreatment of activated carbon.
B. As a pretreatment of activated carbon, activated carbon was immersed in oil mixed with additives a, b, c, d and ester oil, and additives a, b, c, d and ester oil were adsorbed in advance in the activated carbon. .
[0063]
[Table 2]

[0064]
As a result of the experiment, it was found that if the additive and ester oil were adsorbed in advance on activated carbon, the additive and ester oil were not adsorbed and removed. Here, the additive residual ratio in Table 2 indicates the amount of additive after the experiment when the initial additive amount is 100%. It was also found that the mineral oil adsorption characteristics were unchanged with and without pretreatment. Therefore, when using activated carbon, you do not want to remove it by adsorption.For example, by using an additive or ester oil that has been previously adsorbed on activated carbon, these are not removed by adsorption during use, and the reliability of the equipment is reduced. improves. In the adsorption by activated carbon, molecules are adsorbed in the pores of the activated carbon. And the position of the pore which adsorb | sucks in activated carbon changes with molecular sizes and structures. Therefore, even if a third component having a molecular size and structure similar to that of an additive or the like that is not to be removed by adsorption is adsorbed in advance, the additive is not adsorbed and removed during use, and the same effect is obtained. It is done.
[0065]
In this embodiment, the additive and the ester oil are preliminarily adsorbed on the activated carbon, but it is not desired to adsorb and remove.For example, only the additive may be preliminarily adsorbed in the activated carbon. Needless to say, the same effect can be obtained.
[0066]
In the present embodiment, activated carbon is used as the adsorbent, but other adsorbents that selectively adsorb mineral oil may be used. Further, even if activated carbon is combined with other adsorbents such as molecular sieves, mineral oil is selectively adsorbed and removed by activated carbon, and the same effect can be obtained if activated carbon is included as a component.
[0067]
In this embodiment, ester oil is used as the refrigerating machine oil for the HFC refrigerant. However, it goes without saying that the same effect can be obtained even when ether oil that is compatible with the HFC refrigerant and has a large polarity is used.
[0068]
Embodiment 2. FIG.
FIG. 6 shows a refrigerant circuit of a refrigeration cycle apparatus equipped with an oil accumulation mechanism according to Embodiment 2 of the present invention. In FIG. 6, 9 is an oil accumulation mechanism, 31 is an oil tank, p21 to p23 are refrigerant circuits, and b21 and b23 are flow rate regulators. The other symbols are the same as or equivalent to those in FIG.
[0069]
In FIG. 6, the valves b21 and b23 are closed, and after mineral oil and refrigerant flow from the accumulator 6 into the oil adsorber 9, the flow regulators b8, b10 and b14 are closed. If it does in this way, the adsorption time by activated carbon will become long and can fully adsorb | suck. Moreover, it can fully adsorb | suck by performing the flow controller b8, b10, b14 by batch type.
Further, by allowing the liquid refrigerant from the pipe p3 to flow into the oil adsorber 9 while being adjusted by the flow rate regulator b14 through the pipe p14, the viscosity of the mineral oil is lowered and the adsorption efficiency is improved. Thus, by adjusting the flow rate regulator b14, the viscosity of the mineral oil to be introduced is adjusted so that the mineral oil adsorption efficiency is optimized.
[0070]
As described above, in this embodiment, the mineral oil that has flowed into the oil adsorber 9 as the mineral oil accumulation mechanism is held for a certain period of time and then discharged. If activated carbon is used where mineral oil flows, if the adsorption rate is low, that is, if the adsorption efficiency is poor, there is a possibility that the oil will flow out without being sufficiently adsorbed. Therefore, in this embodiment, the mineral oil that has flowed in is retained in the oil adsorber 9 and is sufficiently adsorbed and then returned to the main refrigerant circuit. As a result, the mineral oil can be almost completely adsorbed.
[0071]
Further, in this embodiment, the mineral oil is mixed with the liquid refrigerant to lower the concentration of the mineral oil, and the viscosity of the mineral oil is lowered to flow into the oil adsorber 9. Mineral oil having a low viscosity has a high diffusion rate in the oil adsorber 9 and can be adsorbed efficiently.
[0072]
Further, by opening the valves b21 and b23 with the flow rate regulators b8, b10 and b14 closed, the high temperature gas flows into the oil adsorber 9, and the mineral oil is desorbed from the activated carbon. That is, activated carbon has good adsorption efficiency at low temperatures and deteriorates at high temperatures. Therefore, when activated gas is flowed, the adsorbed activated carbon is desorbed. The desorbed mineral oil is stored in the oil tank 31. In this example, the hot gas is allowed to flow into the oil adsorber 9 for desorption, but a heater is installed around the oil adsorber 9, and the mineral oil can be desorbed by a method such as heater heating.
[0073]
As described above, in this embodiment, the oil adsorber 9 is heated to desorb the mineral oil accumulated in the activated carbon at a high temperature. As the desorption means, a high-temperature gas refrigerant is passed, or a heat source using a heater is used. If it can be desorbed, the total amount of activated carbon can be reduced.
[0074]
In this embodiment, the mineral oil desorbed from the oil adsorber 9 is collected in another container such as the oil tank 31. Thus, if it can be recovered in a separate container, the total amount of activated carbon can be reduced, and thereafter, it is safe without the mineral oil flowing out.
[0075]
Embodiment 3 FIG.
FIG. 7 shows a refrigerant circuit of a refrigeration cycle apparatus equipped with an oil accumulation mechanism according to Embodiment 3 of the present invention. In FIG. 7, 9 is an oil adsorber as an oil storage mechanism, 32 is an oil separator provided in the discharge side refrigerant piping of the compressor 1, p32, p33, and p34 are refrigerant circuits, and b32, b33, and b34 are flow rate regulators. Indicates. The other symbols are the same as or equivalent to those in FIG.
[0076]
FIG. 8 is a cross-sectional view showing the configuration of the oil adsorber 9 in FIG. In FIG. 8, 16 is activated carbon, 19 and 22 are cushion materials, and 26 and 27 are pore members.
7 and 8, high-temperature oil flows from the oil separator 32 into the oil adsorber 9. Since the oil flowing in from the oil separator 32 has a high temperature, the viscosity is low, and the oil flows easily in the activated carbon 16. However, since the adsorption efficiency at the activated carbon 16 is poor at high temperature, the liquid refrigerant from the liquid pipe p3 is passed through the pipe p14 and adjusted by the flow rate regulator b14, and flows around the activated carbon 16 to exchange heat in the oil adsorber 9. To lower the temperature of the activated carbon 16.
By doing so, the adsorption efficiency with activated carbon is improved. In other words, the viscosity of the oil is lowered by flowing high-temperature oil, and the adsorption efficiency is poor only by this, so that the activated carbon 16 is cooled with the refrigerant so as to be adsorbed efficiently.
[0077]
As described above, in this embodiment, the oil adsorber 9 is installed in the oil return circuit from the oil separator 32 to the compressor 1. Since this is a site with a large amount of oil, it can be reliably adsorbed during the circulation of the oil.
[0078]
Further, in this embodiment, the temperature of the activated carbon is adjusted or the temperature of the circulating mineral oil is adjusted so as to optimize the adsorption efficiency of the mineral oil.
[0079]
In this embodiment, the oil adsorber 9 and the flow direction of the mineral oil are devised so that the mineral oil flowing into the oil adsorber 9 flows from the upper part and flows out to the lower part. If it does in this way, mineral oil will flow easily under the influence of gravity. In addition, since mineral oil has a lower specific gravity than ester oil and ether oil, even if the adsorption efficiency of activated carbon 16 is reduced, if the oil adsorber 9 is filled with mixed oil, the mineral oil tends to float up and flow out. It may be difficult to do.
[0080]
In the above embodiment, the oil returned from the oil separator 32 to the compressor 1 and the oil returned from the accumulator 6 to the compressor 1 are heat-exchanged, but are not mixed. However, as another aspect, there is a method in which both oils are mixed by the oil adsorber 9 to adsorb mineral oil.
[0081]
Embodiment 4 FIG.
FIG. 9 is a diagram showing the configuration of the refrigerant circuit in the refrigeration cycle apparatus according to Embodiment 4 of the present invention. In FIG. 9, 6 is an accumulator, 9 is an oil adsorber as an oil accumulation mechanism, 32 is an oil separator, p32 and p35 are refrigerant pipes, and b32 and b35 are flow regulators. The other symbols are the same as or equivalent to those in FIG.
[0082]
In this embodiment, low temperature mineral oil is allowed to flow from the accumulator 6 to the oil adsorber 9 through the pipe p8 and the flow rate regulator b8. At that time, a high temperature oil, that is, a mixed oil of mineral oil and ester oil is also introduced from the oil separator 32 while being adjusted by the flow rate regulator b32 of the pipe p32, so that the viscosity of the oil decreases, Increases the diffusion rate and improves the adsorption efficiency.
Also, by adjusting the liquid refrigerant from the liquid pipe p3 to the oil adsorber 9 while adjusting with the flow rate regulator b14 of the pipe p14, the viscosity of the mineral oil is lowered, the diffusion rate in the activated carbon is increased, and the adsorption efficiency is increased. Will be better. Thus, by adjusting the flow rate regulators b8, b14, b32, the viscosity of the mineral oil to be introduced is adjusted so that the mineral oil adsorption efficiency is optimized. The lubricating oil after adsorbing the mineral oil is returned to the suction side of the compressor 1 through the pipe p35 and the flow rate regulator b35.
[0083]
As described above, in this embodiment, the oil that flows out from the accumulator 6 and returns to the compressor 1 flows into the oil adsorber 9, and the oil that returns from the oil separator 32 to the compressor 1 also flows into the oil adsorber 9. . Further, the liquid refrigerant from the liquid pipe p3 is caused to flow into the oil adsorber 9. These are respectively adjusted by a flow rate regulator and mixed in by mixing them, and the mixing ratio is controlled. Further, the mineral oil that has flowed into the oil adsorber 9 can be held for a certain period of time to be sufficiently adsorbed and then discharged.
[0084]
Since the oil from the oil separator 32 is high temperature, it acts to raise the temperature of the mineral oil and lower the viscosity of the mineral oil. Further, the viscosity is lowered by a method such as mixing with the liquid refrigerant from the liquid pipe p3 to lower the entire viscosity, and the liquid is then flowed into the oil adsorber. Mineral oil has a low viscosity and a high diffusion rate, and can be adsorbed efficiently.
[0085]
Therefore, in this embodiment, the pressure and temperature of the liquid refrigerant and oil in the activated carbon are adjusted so that the adsorption efficiency to the activated carbon is optimized, and the viscosity of the mineral oil is adjusted.
[0086]
Embodiment 5 FIG.
FIG. 10 is a diagram showing the configuration of the refrigerant circuit in the refrigeration cycle apparatus according to Embodiment 5 of the present invention. FIG. 11 is a cross-sectional view showing the structure of the oil separator used in this embodiment, and FIG. 12 is a cross-sectional view showing the structure of the activated carbon package.
In FIG. 10, 33 denotes an oil separator installed on the discharge side of the compressor 1. p32 is an oil return circuit from the oil separator 33 to the suction side of the compressor 1. The other symbols are the same as or equivalent to those in FIG. In the oil separator 33 shown in FIG. 11, 123 is an inflow pipe, 124 is an outflow pipe, 125 is an oil return pipe, 126 is an intermediate plate, and 127 is an activated carbon package. In the activated carbon package 127 shown in FIG. 12, 128 is activated carbon, 129 is a filter that covers the activated carbon 128, and 130 is an adhesive that joins the upper and lower filters 129.
[0087]
In this embodiment, an activated carbon package 127 is placed in the oil separator 33 in the refrigerant circuit as shown in FIG. Since activated carbon is generally granular, it is necessary to consider the outflow of particles. However, if activated carbon package 127 is used, there is no outflow and it is easy to use. The activated carbon package 127 is wrapped in a filter 129, and activated carbon 128 is contained inside. The upper and lower filters 129 are bonded by the adhesive 130. In this way, as long as the activated carbon 128 is prevented from flowing out, it can be put anywhere where mineral oil is to be adsorbed. In FIG. 10, although it put in the oil separator 33, other places, such as the accumulator 6 and a liquid use, may be sufficient.
[0088]
As described above, in this embodiment, the activated carbon package 127 as a mineral oil accumulation mechanism is built in the oil separator 33. As described above, since the activated carbon package is accommodated in the equipment or container that is already in the refrigeration cycle apparatus, there is an advantage in that an installation place is not particularly required. In addition, since the oil separator 33 and the like have a large amount of oil, the mineral oil can be reliably adsorbed during circulation.
[0089]
The activated carbon package can also be built in the accumulator 6. If it does in this way, since mineral oil is adsorbed and removed before a compressor, mineral oil may not be mixed with oil (new oil) in a compressor. Further, here, the temperature is low, and in some cases, there is a refrigerant, so that the viscosity is lowered and the adsorption efficiency is good.
[0090]
In the activated carbon package of this embodiment, activated carbon is filled in the filter. Since activated carbon is generally granular or powdered, if it flows out into the circuit, the circuit becomes defective. Also, when handling granular activated carbon on-site, powder is also poor and workability is poor. Therefore, if a filter filled in the filter is prepared, it can be easily installed anywhere and has a great effect.
[0091]
In each of the above embodiments, the example in which the mineral oil is further adsorbed and accumulated or separated from the lubricating oil separated from the refrigerant or the lubricating oil separated from the main refrigerant circuit has been mainly described. However, it is also possible to install the oil adsorber 9 directly in, for example, a gas line of the refrigerant circuit to adsorb mineral oil.
[0092]
Embodiment 6 FIG.
FIG. 13 shows a refrigerant circuit diagram of a refrigeration cycle apparatus equipped with an oil storage mechanism according to the sixth embodiment. In FIG. 13, 9 is an oil accumulation mechanism, which is inserted into the refrigerant circuit p <b> 3 on the outlet side of the heat source side heat exchanger 3. That is, it is inserted in series in the liquid pipe of the main refrigerant circuit. The other symbols are the same as or equivalent to those in FIG.
[0093]
In FIG. 13, mineral oil and ester oil (or ether oil) flow into the oil accumulation mechanism 9 in a state of being mixed with a liquid refrigerant or a two-phase refrigerant. Therefore, the viscosity of the liquid mixture is low, the diffusion rate in the oil accumulation mechanism 9 is increased, and the mineral oil can be adsorbed and removed efficiently.
In FIG. 13, the oil accumulation mechanism 9 is installed in the heat source apparatus 100, but it may be installed outside the heat source apparatus 100, and in this case, a special circuit is not required, If space is limited, it can be installed later. For this reason, the heat source device 100 can be made common (same) as that using a new extension pipe, and the manufacturing can be simplified.
The oil accumulation mechanism 9 has a structure as shown in FIG. 2, for example, and can capture solid foreign matters in the refrigerant circuit with a filter.
[0094]
As described above, in this embodiment, the oil accumulation mechanism is provided in the liquid or the two-phase line. Therefore, since the mineral oil flows into the oil accumulation mechanism in a state of being mixed with the refrigerant, the viscosity of the mixed solution is reduced, and the mineral oil can be efficiently adsorbed and removed. In addition, the oil storage mechanism can be installed outside the heat source unit, and the heat source unit can be made common (same) as that using a new extension pipe, and the manufacturing can be simplified.
[0095]
Embodiment 7 FIG.
FIG. 14 shows a refrigerant circuit diagram of a refrigeration cycle apparatus equipped with an oil storage mechanism according to the seventh embodiment. In FIG. 14, 9 is an oil accumulation mechanism, p41 is a refrigerant pipe bypassed from the refrigerant pipe p3, and the other end is connected to the oil accumulation mechanism 9. The other end of the oil storage mechanism 9 is connected to the refrigerant pipe p42 and reaches the refrigerant pipe p3 which is the main circuit of the refrigerant circuit. Further, b41 and b42 are valves installed in the respective pipes. Further, b3 is a valve installed in the pipe 3 in parallel with the oil accumulation mechanism 9. The other symbols are the same as or equivalent to those in FIG.
[0096]
In FIG. 14, mineral oil and ester oil (or ether oil) flow into the oil accumulation mechanism 9 in a state of being mixed with a liquid refrigerant or a two-phase refrigerant. Therefore, the viscosity of the liquid mixture is low, the diffusion rate in the oil accumulation mechanism 9 is increased, and the mineral oil can be adsorbed and removed efficiently.
Further, the oil accumulation mechanism 9 is installed at a position bypassed from the refrigerant pipe p3 which is the main circuit of the refrigerant circuit. Even when the oil accumulation mechanism 9 is clogged with foreign matter or the like and the mixed liquid does not flow, the oil accumulation mechanism 9 is mixed. There is no problem because the liquid flows through the refrigerant pipe p3. Further, by closing the valve b3 and opening the valve b41 and the valve b42, the entire amount of the mixed liquid can be allowed to flow into the oil accumulation mechanism 9, and in this case, the mineral oil in the refrigerant circuit can be obtained in a shorter time than flowing as a bypass. Can be stored in the oil storage mechanism 9.
[0097]
Further, by closing the valve b41 and the valve b42 and opening the valve 3, it is possible to prevent the mixed liquid from flowing into the oil accumulation mechanism 9, and when the adsorption efficiency in the oil accumulation mechanism 9 decreases, In this way, the oil accumulation mechanism 9 can be separated from the refrigerant circuit. Note that these valves b3, b41, and b42 can be switched to a batch type to freely control the flow to the oil accumulation mechanism 9. Here, the valves b3, b41, and b42 are provided, but these may be omitted if necessary.
[0098]
In FIG. 14, the oil accumulation mechanism 9 is installed in the heat source apparatus 100, but it may be installed outside the heat source apparatus 100, and in this case, a special circuit is not required, When the space is limited, the heat source device 100 can be installed later, so that the heat source device 100 can be made common (same as) using a new extension pipe, and the manufacturing can be simplified. The oil accumulation mechanism 9 has a structure as shown in FIG. 2, for example, and can capture solid foreign matters in the refrigerant circuit with a filter.
[0099]
In the sixth and seventh embodiments, an example in which only the oil accumulation mechanism 9 is provided in the refrigerant liquid or the two-phase line has been described. However, as described in the first embodiment, the oil extractor and the oil adsorber are arranged in two stages. May be provided.
In the sixth and seventh embodiments, the oil adsorber is provided directly in the liquid or the two-phase line. However, the oil adsorber 9 may be provided in the liquid reservoir. In this case, the oil adsorbent may be stored in the liquid reservoir, or may be adsorbed after being bypassed from the liquid reservoir. Furthermore, an oil extractor and an oil adsorber may be provided downstream of the liquid reservoir.
[0100]
As described above, in this embodiment, the oil accumulation mechanism is provided in the bypass of the liquid or the two-phase line, and a valve is provided as necessary. Therefore, the flow path of the refrigerant and oil mixture can be freely controlled as necessary, and the oil accumulation mechanism can be disconnected from the circuit, so that even when the oil accumulation mechanism is clogged, normal refrigeration / air conditioning operation is possible. Can continue.
[0101]
Other explanation.
As mentioned above, the example of the refrigerating cycle apparatus carrying the oil storage mechanism in this invention was demonstrated over Embodiment 1-7.
An oil adsorber or an oil storage mechanism including an oil adsorber can basically adsorb mineral oil at any position in the refrigerant circuit. That is, it can be installed in a gas line of a refrigerant circuit, a liquid or a two-phase line. It can also be installed in the bypass line. The installation position of the oil adsorber can be optimally selected in consideration of the characteristics of the refrigeration cycle apparatus, the efficiency of adsorption, and the reliability of the equipment. The main concept for selecting the installation position is described below.
(1) As for the adsorption efficiency of the oil adsorber, the lower the viscosity of the liquid itself, the higher the diffusion rate and the better the efficiency. Therefore, a method can be used in which the liquid refrigerant is mixed to lower the viscosity.
(2) In the oil adsorber, the lower the temperature of the activated carbon, the better the adsorption efficiency. On the other hand, the higher the temperature of the liquid itself, the lower the viscosity. Therefore, even if a high temperature liquid is flowed, it is considered that the efficiency is improved if the activated carbon itself is cooled. The example of FIG. 8 is an example.
(3) If mineral oil is adsorbed by the oil adsorber before the refrigerant enters the compressor, the compressor does not generate sludge and is safe. For example, activated carbon may be installed in the accumulator, or a separate container for adsorption may be provided.
(4) If the oil adsorber is installed in the bypass circuit, the main refrigerant circuit can be operated without being affected. Moreover, by installing in the bypass circuit, the amount of the refrigerant liquid and the liquid (mineral oil) to be separated and removed can be freely adjusted with a valve or the like, so that it can be used with an efficient adsorption speed, viscosity, and the like.
(5) When the oil adsorber is used in a place where there is a large amount of oil such as an oil separator, it is considered that the amount of mineral oil can be reduced relatively quickly and relatively quickly.
(6) When the oil adsorber is used in a site that already exists as a container in the refrigerant circuit, there is an advantage that an installation space is not necessary. For example, it is a case where it installs in an accumulator, an oil separator, or a liquid waste.
(7) When the oil adsorber is used in a liquid line or a gas-liquid two-phase line, there is an advantage that it is not complicated and can be used simply.
[0103]
【The invention's effect】
In the refrigeration cycle apparatus of the present invention, Claim 1 As described in (1), a mechanism for adsorbing the old lubricating oil from the mixed oil of the old lubricating oil and the new lubricating oil by the oil adsorbent is provided. Thereby, the old lubricating oil remaining in the existing piping can be separated and recovered, and deterioration of the new lubricating oil can be suppressed.
[0104]
In the refrigeration cycle apparatus of the present invention, Claim 2 As described in, after the two-phase separation of the mixed liquid of the old lubricating oil, the new lubricating oil and the new refrigerant, the refrigerant liquid rich in the old lubricating oil is separated and the old lubricating oil is adsorbed by the oil adsorbent. Equipped with mechanism. As a result, the old lubricant remaining in the existing piping can be separated and recovered, the deterioration of the new lubricant can be suppressed, and the old lubricant can be separated in two stages. Can be separated and recovered.
[0105]
In the refrigeration cycle apparatus of the present invention, Claims 4-6 As described above, the oil accumulation mechanism is provided in the oil return circuit that returns the lubricating oil separated by the accumulator to the compressor. Thereby, old lubricating oil can be adsorbed and separated efficiently.
[0106]
In the refrigeration cycle apparatus of the present invention, Claims 7-9 As described above, the oil accumulation mechanism is provided in the oil return circuit that returns the lubricating oil separated by the oil separator to the compressor. As a result, the old lubricating oil can be reliably adsorbed during the circulation of the oil in a portion where the oil is large.
[0107]
In the refrigeration cycle apparatus of the present invention, Claims 10 and 11 As described in the above, there is provided means for diverting the liquid refrigerant from the refrigerant circuit to exchange heat with the oil adsorbent of the oil accumulation mechanism. Thereby, temperature control, such as lowering | hanging the temperature of an adsorption device, can be performed and adsorption | suction can be performed effectively.
[0108]
In the refrigeration cycle apparatus of the present invention, Claims 12-14 The lubricating oil separated by the accumulator and returned to the compressor was merged with the lubricating oil separated by the oil separator and returned to the compressor by the oil accumulation mechanism. In addition, the inflow volume can be adjusted. Thereby, old lubricating oil can be adsorbed and separated efficiently. In addition, the amount of inflow, pressure, temperature, etc. can be adjusted to optimize the adsorption efficiency. It is also possible to temporarily stop the inflow of the lubricating oil and sufficiently adsorb it before the next lubricating oil is allowed to flow.
[0109]
In the refrigeration cycle apparatus of the present invention, Claims 15-17 As described above, a desorption mechanism for desorbing the oil accumulated in the oil accumulation mechanism was provided. As a result, the activated carbon can be used repeatedly, and the amount of activated carbon can be reduced.
[0110]
In the refrigeration cycle apparatus of the present invention, Claim 18 Means for adjusting the inflow / stop of the lubricating oil to the oil accumulation mechanism and the inflow amount, and means for adjusting the inflow / stop of the liquid refrigerant from the refrigerant circuit to the oil accumulation mechanism and the inflow amount. The inflow / stop and mixing ratio of each lubricant and liquid refrigerant can be adjusted. Thereby, the pressure or temperature of the liquid refrigerant and oil in the oil accumulation mechanism can be adjusted, the viscosity of the mineral oil can be adjusted, and the mineral oil adsorption efficiency can be adjusted to be optimum.
[0111]
In the refrigeration cycle apparatus of the present invention, Claim 19 As described above, an oil accumulation mechanism was provided inside the accumulator. Thereby, a special installation space is not required as an oil accumulation mechanism, and it is possible to prevent the old lubricating oil from being adsorbed and mixed with the new oil in the compressor before the lubricating oil enters the compressor.
[0112]
In the refrigeration cycle apparatus of the present invention, Claim 20 As described above, an oil accumulation mechanism was provided inside the oil separator. This eliminates the need for a special installation space as an oil storage mechanism, and can reliably adsorb old lubricating oil during circulation because of the large amount of oil.
[0113]
In the refrigeration cycle apparatus of the present invention, Claim 21 As described above, the oil accumulation mechanism was arranged so that the oil circulated from the upper side to the lower side in the vertical direction. Thereby, it becomes easy to flow under the influence of gravity, and the efficiency of adsorption increases.
[0114]
In the refrigeration cycle apparatus of the present invention, Claim 22 As described above, the oil accumulation mechanism was coupled to the refrigerant circuit by means of detachable means. This saves space because the oil storage mechanism can be removed if it is no longer needed.
[0115]
In the refrigeration cycle apparatus of the present invention, Claims 23 to 25 Activated carbon was used as the oil adsorbent for the oil accumulation mechanism. Thereby, old lubricating oil can be adsorbed efficiently.
[0116]
In the refrigeration cycle apparatus of the present invention, Claims 26 and 27 As described above, the activated carbon which is the oil adsorbent of the oil accumulation mechanism is prevented from flowing out. This can prevent the circuit from becoming defective.
[0117]
In the refrigeration cycle apparatus of the present invention, Claims 28 and 29 As described in, the activated carbon was removably supported in the oil accumulation mechanism. This makes it convenient to support and replace the activated carbon.
[0118]
In the refrigeration cycle apparatus of the present invention, Claim 30 The second lubricating oil and / or its additive was previously adsorbed to the oil adsorbent as described in. Therefore, since the component effective as the lubricating oil is not adsorbed during use, the reliability of the device is improved.
[0119]
In the refrigeration cycle apparatus of the present invention, Claim 31 As described above, a hydrofluorocarbon refrigerant is used instead of the conventional chlorofluorocarbon refrigerant or hydrochlorofluorocarbon refrigerant. Thereby, environmental measures can be improved.
[Brief description of the drawings]
FIG. 1 shows a refrigerant circuit of a refrigeration cycle apparatus equipped with an oil accumulation mechanism according to Embodiment 1 of the present invention.
FIG. 2 shows an example of the structure of an oil adsorber as an oil storage mechanism according to Embodiment 1 of the present invention.
FIG. 3 shows another structure example of the oil adsorber according to the first embodiment of the present invention.
FIG. 4 shows the relationship between the adsorption rate of activated carbon and the concentration of oil (mineral oil + ester oil, etc.) in the refrigerant.
FIG. 5 is a cumulative pore distribution of activated carbon used in the experiment in Embodiment 1 of the present invention.
FIG. 6 shows a refrigerant circuit of a refrigeration cycle apparatus equipped with an oil accumulation mechanism according to Embodiment 2 of the present invention.
FIG. 7 shows a refrigerant circuit of a refrigeration cycle apparatus equipped with an oil accumulation mechanism according to Embodiment 3 of the present invention.
FIG. 8 is a cross-sectional view showing a configuration of an oil adsorber according to a third embodiment of the present invention.
FIG. 9 is a diagram showing a configuration of a refrigerant circuit in a refrigeration cycle apparatus according to Embodiment 4 of the present invention.
FIG. 10 is a diagram showing a configuration of a refrigerant circuit in a refrigeration cycle apparatus according to Embodiment 5 of the present invention.
FIG. 11 is a cross-sectional view showing the structure of an oil separator used in Embodiment 5 of the present invention.
FIG. 12 is a sectional view showing the structure of an activated carbon package used in Embodiment 5 of the present invention.
FIG. 13 is a diagram showing a configuration of a refrigerant circuit in a refrigeration cycle apparatus according to Embodiment 6 of the present invention.
FIG. 14 is a diagram showing a configuration of a refrigerant circuit in a refrigeration cycle apparatus according to Embodiment 7 of the present invention.
[Explanation of symbols]
100 heat source machine, 200 use side machine, 1 compressor, 2 four-way valve, 3 heat source side heat exchanger, 4 flow rate regulator, 5 use side heat exchanger, 6 accumulator, 7 extraction container, 8 extraction residual liquid storage container, 9 Oil storage mechanism (oil adsorber), 10 Refrigerant heat exchanger, 11 Flow rate regulator, 31 Oil tank, 32 Oil separator.

Claims (34)

  The extension pipe and / or the use side machine used in the refrigeration cycle apparatus using the first refrigerant and the first lubricating oil is replaced with the extension pipe of the refrigeration cycle apparatus using the second refrigerant and the second lubricating oil. And / or a refrigeration cycle apparatus used as a use side machine, comprising an oil accumulation mechanism for adsorbing the first lubricating oil from the mixed oil of the first lubricating oil and the second lubricating oil by an oil adsorbent. A refrigeration cycle apparatus characterized by.   The extension pipe and / or the use side machine used in the refrigeration cycle apparatus using the first refrigerant and the first lubricating oil is replaced with the extension pipe of the refrigeration cycle apparatus using the second refrigerant and the second lubricating oil. And / or, in the refrigeration cycle apparatus used as a use side machine, the second refrigerant is mixed from the state in which the second refrigerant is mixed with the mixed oil of the first lubricating oil and the second lubricating oil and then separated from the second phase. An extractor for separating the lubricant liquid rich in lubricating oil, and an oil storage mechanism for adsorbing the first lubricating oil from the refrigerant liquid rich in the second lubricating oil separated from the extractor by an oil adsorbent. A refrigeration cycle apparatus characterized by that. The refrigeration cycle apparatus according to claim 1 or 2 , wherein the oil accumulation mechanism is provided in a bypass circuit of a refrigerant circuit. The refrigeration cycle apparatus according to claim 1 or 2 , wherein the oil accumulation mechanism is provided in an oil return circuit from an accumulator to a compressor. 4. The refrigeration cycle apparatus according to claim 3 , wherein a circuit that allows liquid refrigerant from a refrigerant circuit to flow into the oil accumulation mechanism is provided and mixed with lubricating oil that flows from an accumulator. 6. The refrigeration cycle apparatus according to claim 5 , wherein means for adjusting the inflow / stop and inflow amount of lubricating oil from the accumulator to the oil accumulation mechanism, inflow of liquid refrigerant from the refrigerant circuit to the oil accumulation mechanism, A refrigeration cycle apparatus comprising a means for stopping and adjusting an inflow amount so that the inflow / stop and mixing ratio of the lubricating oil and the liquid refrigerant can be adjusted. The refrigeration cycle apparatus according to claim 1 or 2 , wherein the oil accumulation mechanism is provided in an oil return circuit from an oil separator to a compressor. 8. The refrigeration cycle apparatus according to claim 7 , wherein a circuit that allows liquid refrigerant from a refrigerant circuit to flow into the oil accumulation mechanism is provided and mixed with lubricating oil that flows from the oil separator. 9. The refrigeration cycle apparatus according to claim 8 , wherein means for adjusting the inflow / stop and inflow amount of lubricating oil from an oil separator to the oil accumulation mechanism, and inflow / liquid refrigerant flow from the refrigerant circuit to the oil accumulation mechanism. A refrigeration cycle apparatus characterized by comprising means for stopping and adjusting an inflow amount so that the inflow / stop and mixing ratio of the lubricating oil and the liquid refrigerant can be adjusted. 8. The refrigeration cycle apparatus according to claim 7 , further comprising means for diverting a liquid refrigerant from the refrigerant circuit to exchange heat with the oil adsorbent of the oil accumulation mechanism. The refrigeration cycle apparatus according to claim 10 , further comprising means for adjusting the amount of lubricating oil flowing from the oil separator into the oil accumulation mechanism, and means for adjusting the amount of liquid refrigerant to be diverted from the refrigerant circuit, A refrigeration cycle apparatus characterized in that the temperature of the oil adsorbent can be adjusted. The refrigeration cycle apparatus according to claim 1 or 2 , wherein the oil accumulation mechanism is provided in a merging circuit in which an oil return circuit from the accumulator to the compressor and an oil return circuit from the oil separator to the compressor are merged. A refrigeration cycle apparatus characterized by that. The refrigeration cycle apparatus according to claim 12 , further comprising a circuit for allowing liquid refrigerant from a refrigerant circuit to flow into the oil accumulation mechanism, and mixing with the lubricating oil flowing from the accumulator and the oil separator. apparatus. The refrigeration cycle apparatus according to claim 13 , wherein means for adjusting inflow and stoppage of the lubricating oil from the accumulator to the oil accumulation mechanism, and means for adjusting the amount of inflow of lubricating oil from the oil separator to the oil accumulation mechanism Means for stopping and adjusting the amount of inflow, and means for adjusting the amount of inflow / stop of the liquid refrigerant and the amount of inflow from the refrigerant circuit to the oil storage mechanism, and inflow / stop of each of the lubricating oil and the liquid refrigerant, and A refrigeration cycle apparatus characterized in that the mixing ratio can be adjusted. The refrigeration cycle apparatus according to any one of claims 1 to 14 , further comprising a desorption mechanism for desorbing the oil accumulated in the oil accumulation mechanism. 16. The refrigeration cycle apparatus according to claim 15 , wherein the desorption mechanism has means for introducing the refrigerant gas of the refrigerant circuit into the oil accumulation mechanism and heating the adsorbent. The refrigeration cycle apparatus according to claim 15 , wherein the desorption mechanism includes means for heating the oil accumulation mechanism with an external heat source. The refrigeration cycle apparatus according to any one of claims 15 to 17 , wherein a recovery container for recovering the desorbed oil is connected to the oil accumulation mechanism. 2. The refrigeration cycle apparatus according to claim 1 , wherein the oil accumulation mechanism is provided inside an accumulator. The refrigeration cycle apparatus according to claim 1 , wherein the oil accumulation mechanism is provided inside an oil separator. 21. The refrigeration cycle apparatus according to any one of claims 1 to 20 , wherein the oil accumulation mechanism is arranged so that oil circulates downward from above in the vertical direction. The refrigeration cycle apparatus according to any one of claims 1 to 21 , wherein the oil accumulation mechanism is coupled to the refrigerant circuit by means of detachable means. The refrigeration cycle apparatus according to any one of claims 1 to 21 , wherein activated carbon is used as an oil adsorbent for the oil accumulation mechanism. The refrigeration cycle apparatus according to claim 23 , wherein the activated carbon has an average pore diameter of 1 to 10 nm. 25. The refrigeration cycle apparatus according to claim 23 or 24 , wherein the activated carbon is bonded with a thermoplastic resin. 26. The refrigeration cycle apparatus according to any one of claims 23 to 25 , wherein the oil accumulation mechanism partitions at least a downstream side of activated carbon as an oil adsorbent with a filter. The refrigeration cycle apparatus according to any one of claims 23 to 25 , wherein the oil accumulation mechanism is obtained by coating activated carbon as an oil adsorbent with a filter. 28. The refrigeration cycle apparatus according to claim 27 , wherein the oil accumulation mechanism detachably supports activated carbon covered with a filter in a container. 28. The refrigeration cycle apparatus according to claim 27 , wherein the oil accumulation mechanism elastically supports activated carbon covered with a filter by an elastic member in a container. 30. The refrigeration cycle apparatus according to any one of claims 1 to 29 , wherein the second lubricant and / or additive thereof are adsorbed in advance on the oil adsorbent. 31. The refrigeration cycle apparatus according to claim 1 , wherein the first refrigerant is a chlorofluorocarbon refrigerant or a hydrochlorofluorocarbon refrigerant, the first lubricating oil is mineral oil, and the second refrigerant. A refrigeration cycle apparatus using a hydrofluorocarbon refrigerant as the second lubricating oil and an ester oil or an ether oil as the second lubricating oil. The extension pipe and / or the use side machine used in the refrigeration cycle apparatus using the first refrigerant and the first lubricating oil is replaced with the extension pipe of the refrigeration cycle apparatus using the second refrigerant and the second lubricating oil. And in the refrigeration cycle apparatus used as a utilization side machine, in the refrigeration cycle apparatus provided with an oil accumulation mechanism for adsorbing the first lubricating oil with an oil adsorbent in the refrigerant circuit,
A refrigeration cycle apparatus, wherein the second lubricant and / or additive thereof are adsorbed in advance on the oil adsorbent . The extension pipe and / or the use side machine used in the refrigeration cycle apparatus using the first refrigerant and the first lubricating oil is replaced with the extension pipe of the refrigeration cycle apparatus using the second refrigerant and the second lubricating oil. And in the refrigeration cycle apparatus used as a utilization side machine, in the refrigeration cycle apparatus provided with an oil accumulation mechanism for adsorbing the first lubricating oil with an oil adsorbent in the refrigerant circuit,
A refrigeration cycle apparatus, wherein the oil accumulation mechanism is provided in a bypass circuit of a main refrigerant circuit, and the second lubricant and / or additive thereof is adsorbed in advance on the oil adsorbent . The extension pipe and / or the use side machine used in the refrigeration cycle apparatus using the first refrigerant and the first lubricating oil is replaced with the extension pipe of the refrigeration cycle apparatus using the second refrigerant and the second lubricating oil. And in the refrigeration cycle apparatus used as a utilization side machine, in the refrigeration cycle apparatus provided with an oil accumulation mechanism for adsorbing the first lubricating oil with an oil adsorbent in the refrigerant circuit,
A refrigeration cycle apparatus comprising the oil accumulation mechanism in a refrigerant liquid line or a two-phase line, wherein the second lubricating oil and / or additive thereof is adsorbed in advance on the oil adsorbent .

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