JPH05157400A - Adsorption type reactor - Google Patents
Adsorption type reactorInfo
- Publication number
- JPH05157400A JPH05157400A JP8336191A JP8336191A JPH05157400A JP H05157400 A JPH05157400 A JP H05157400A JP 8336191 A JP8336191 A JP 8336191A JP 8336191 A JP8336191 A JP 8336191A JP H05157400 A JPH05157400 A JP H05157400A
- Authority
- JP
- Japan
- Prior art keywords
- adsorbent
- passage
- passages
- hot water
- water
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
Links
Landscapes
- Sorption Type Refrigeration Machines (AREA)
Abstract
Description
【0001】[0001]
【産業上の利用分野】この発明は、利用されることが少
なかった比較的温度の低い温水を用い、吸着剤の水分の
吸脱着作用を利用して冷水を供給、あるいは冷凍機とし
て使用する吸着式反応器に係り、温水通路、吸着剤充填
層、蒸気通路、冷水通路の各通路を積層したプレートフ
ィン形熱交換器となし、簡単な構造で小型化、高効率化
を図った吸着式反応器に関する。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention uses hot water having a relatively low temperature, which has been rarely used, and supplies cold water by utilizing the water adsorption / desorption action of an adsorbent or an adsorption used as a refrigerator. This is a plate fin type heat exchanger in which hot water passages, adsorbent packed bed, steam passages, and cold water passages are laminated together, and the adsorption reaction has a simple structure to achieve downsizing and high efficiency. Regarding vessels.
【0002】[0002]
【従来の技術】現在多用されている吸収式冷凍機には、
冷媒と吸収剤に水と臭化リチウムの組合せを用いて、1
00kPa程度の低圧蒸気、または80〜150℃の高
温水、あるいは400℃未満の廃ガスを利用する単効用
吸収式冷凍機、800kPa程度の中圧蒸気、または1
90℃程度の高温水、あるいは400℃以上の廃ガスを
利用する二重効用吸収式冷凍機が知られている。いずれ
の吸収式冷凍機も、高真空下で作動する構成であり、所
謂真空ポンプが不可欠であり、発生器と凝縮器を巡る各
種配管が、多岐にわたり極めて複雑な構成からなる。2. Description of the Related Art Absorption refrigerators that are widely used at present include
Using a combination of water and lithium bromide as the refrigerant and absorbent, 1
Single-effect absorption refrigerator utilizing low-pressure steam of about 00 kPa, high-temperature water of 80 to 150 ° C, or waste gas of less than 400 ° C, medium-pressure steam of about 800 kPa, or 1
A double-effect absorption refrigerator utilizing high-temperature water of about 90 ° C. or waste gas of 400 ° C. or higher is known. Each of the absorption refrigerators is configured to operate under a high vacuum, a so-called vacuum pump is indispensable, and various pipes surrounding the generator and the condenser have a wide variety of extremely complicated configurations.
【0003】[0003]
【発明が解決しようとする課題】クリーンエネルギー化
や省エネルギーのため、太陽熱や廃熱利用した吸収式冷
凍機も、前記冷凍機と同様構成で、温水温度が低いため
満液型を散布型に変えた発生器となした構成が知られて
いるが、効率が悪く所要の冷水温度を得るのに、装置が
大型化する嫌いがあった。In order to make clean energy and save energy, an absorption refrigerator using solar heat or waste heat has the same structure as the refrigerator described above, and since the hot water temperature is low, the full liquid type is changed to a spray type. Although it is known that the generator is used as a generator, it is inefficient and there is a dislike that the device becomes large in size in order to obtain a required cold water temperature.
【0004】そこで、例えば、特開昭58−18446
7号、実開昭63−125758号、特開昭63−46
356号公報などに、シリカゲルなどの吸着剤の水分の
吸脱着作用を利用した冷凍機等が提案されている。上記
提案の吸着式冷凍機等は、真空容器内に所要の熱交換ユ
ニットを配設し、吸着剤を充填した構成が主であり、概
して構造が複雑で、小型化並びに高効率化が困難であっ
た。Therefore, for example, Japanese Patent Laid-Open No. 58-18446.
7, Japanese Utility Model Laid-Open No. 63-125758, Japanese Patent Laid-Open No. 63-46.
Japanese Patent No. 356, etc. propose a refrigerator or the like that utilizes the water adsorption / desorption action of an adsorbent such as silica gel. The adsorption refrigerating machine and the like proposed above are mainly configured by arranging a required heat exchange unit in a vacuum container and filling an adsorbent, and the structure is generally complicated, and it is difficult to reduce the size and increase the efficiency. there were.
【0005】この発明は、固体吸着剤を利用し、熱源に
比較的低温の温水を用いる、吸着式冷凍機、冷水器にお
ける上述の問題を解消でき、小型化、高効率化を図った
構造の簡単な構成からなり、冷凍機等に使用できる吸着
式反応器の提供を目的としている。According to the present invention, a solid adsorbent is used, and the above-mentioned problems in an adsorption type refrigerator and a water chiller that use hot water of a relatively low temperature as a heat source can be solved, and a structure in which the size and efficiency are improved. It is an object of the present invention to provide an adsorption reactor which has a simple structure and can be used in a refrigerator or the like.
【0006】[0006]
【課題を解決するための手段】この発明は、少なくとも
4層を積層したプレートフィン形熱交換器の構成からな
り、中央の2通路が孔あきプレートを介して減圧密閉室
を構成し、一方を吸着剤が充填された吸着剤層、他方を
吸着剤から発生した蒸気の蒸気通路となし、吸着剤層側
に熱源の温水が流入出する温水通路を隣接積層させ、蒸
気通路側に被冷却水の流入出する冷水通路の各通路を隣
接積層したことを特徴とする吸着式反応器である。SUMMARY OF THE INVENTION The present invention comprises a plate fin type heat exchanger in which at least four layers are laminated, and two central passages form a depressurized closed chamber through a perforated plate, one of which is formed. Adsorbent layer filled with adsorbent, the other is the steam passage of the steam generated from the adsorbent, the hot water passage for the hot water of the heat source to flow in and out adjacent to the adsorbent layer side, the cooling water on the steam passage side The adsorbing reactor is characterized in that the respective cold water passages that flow in and out of are laminated adjacent to each other.
【0007】また、この発明は、積層したプレートフィ
ン形熱交換器の構成からなり、蒸気通路の上部で孔あき
プレートを介して吸着剤が充填された吸着剤層を隣接積
層して減圧密閉室を構成し、吸着剤層側に熱源の温水が
流入出する温水通路を隣接積層させ、蒸気通路の下部で
被冷却媒体の流入出する冷水通路を隣接積層したことを
特徴とする吸着式反応器である。Further, the present invention comprises a laminated plate fin type heat exchanger, wherein adsorbent layers filled with an adsorbent are adjacently laminated via a perforated plate at the upper part of the vapor passage to form a decompression closed chamber. And an adsorbent reactor characterized in that a hot water passage through which hot water from a heat source flows in and out is adjoined on the adsorbent layer side, and a cold water passage through which a medium to be cooled flows in and out is adjoined under a vapor passage. Is.
【0008】また、この発明は、上記構成の吸着式反応
器の複数を並列配置し、各温水通路と冷水通路に温水と
被冷却水を交互に切替え供給可能に配管接続し、一方の
吸着式反応器で吸着剤を加熱し脱着作用させ、他方の吸
着式反応器で蒸気通路を加熱し、冷却する吸着剤に吸着
作用させ、相互に逆作用可能となして連続使用でき、例
えば吸着式冷凍機として使用できる。Further, according to the present invention, a plurality of the adsorption type reactors having the above-mentioned structure are arranged in parallel, and hot water and cooled water are alternately connected by piping so that hot water and cooled water can be alternately supplied. The adsorbent is heated in the reactor to cause desorption, and the vapor path is heated in the other adsorption reactor to adsorb to the adsorbent to be cooled so that they can interact with each other and can be used continuously. It can be used as a machine.
【0009】[0009]
【作用】この発明において、吸着剤には、ゼオライト、
シリカゲル、活性炭等、蒸発媒体には、水、メタノー
ル、アンモニアその他が利用できる。In the present invention, the adsorbent is zeolite,
Water, methanol, ammonia or the like can be used as an evaporation medium such as silica gel or activated carbon.
【0010】図面に基づく発明の開示 構成1 図1はこの発明による吸着式反応器の構成を示す一部破
断斜視説明図である。この発明による吸着式反応器は、
プレート1間にコルゲートフィン2を挟み、周囲にスペ
ーサーバー3を配置して形成する4通路を積層したプレ
ートフィン形熱交換器の構成からなり、図1の手前側の
通路から、温水通路10、吸着剤層11、蒸気通路1
2、冷水通路13が設けてある。Disclosure of the Invention Based on the Drawing Structure 1 FIG. 1 is a partially broken perspective view showing the structure of an adsorption reactor according to the present invention. The adsorption reactor according to the present invention is
The corrugated fins 2 are sandwiched between the plates 1, and the spacer fins 3 are arranged around the plate fins to form a plate fin type heat exchanger in which four passages are stacked. The passages on the front side of FIG. Adsorbent layer 11, vapor passage 1
2. A cold water passage 13 is provided.
【0011】積層した4通路のうち中央の2通路は、孔
あきプレート4を介して連通しているが密閉室を構成し
ており、所要値まで減圧され、一方を孔あきコルゲート
フィン7を介して吸着剤5が充填された吸着剤層11、
他方を加熱された吸着剤5から発生した蒸気の蒸気通路
12を構成している。蒸気通路12内のスペーサー6は
蒸気の流路を確保するために用いている。なお、蒸気通
路12内のコルゲートフィン2は孔あきあるいはスリッ
ト付きフィンを用いると、蒸気または水が両壁面に接触
して熱交換効率が良くなるので好ましい。従って、吸着
剤層11側に熱源たる温水の流入出口を設けた温水通路
10を隣接積層させ、蒸気通路12側に被冷却水の流入
出口を設けた冷水通路13の各通路を隣接積層してあ
る。The central two passages of the four laminated passages communicate with each other through the perforated plate 4, but constitute a closed chamber, and the pressure is reduced to a required value, and one of them is passed through the perforated corrugated fin 7. An adsorbent layer 11 filled with the adsorbent 5,
The other side constitutes a vapor passage 12 for the vapor generated from the heated adsorbent 5. The spacer 6 in the steam passage 12 is used to secure a flow path for steam. It is preferable that the corrugated fins 2 in the steam passage 12 are perforated or have slits, because steam or water comes into contact with both wall surfaces to improve heat exchange efficiency. Therefore, the hot water passage 10 having the inlet / outlet of the hot water as a heat source is adjacently laminated on the adsorbent layer 11 side, and the respective passages of the cold water passage 13 having the inflow / outlet of the cooled water on the steam passage 12 side are adjacently laminated. is there.
【0012】まず、再生行程では温水通路10に所要の
温水を送給すると、隣接する吸着剤層11の吸着剤5が
加熱されて、例えば、吸着剤に含まれていた水が蒸発し
て、孔あきプレート4を通過して、蒸気通路12に入
る。水蒸気が充満した蒸気通路12に隣接する冷水通路
13では、冷却水が水蒸気の蒸発潜熱を奪い蒸気を凝縮
させて水にする。First, when the required hot water is fed to the hot water passage 10 in the regeneration process, the adsorbent 5 in the adsorbent layer 11 adjacent to the adsorbent 5 is heated, and, for example, water contained in the adsorbent evaporates, It passes through the perforated plate 4 and enters the steam passage 12. In the cold water passage 13 adjacent to the steam passage 12 filled with steam, the cooling water removes the latent heat of vaporization of the steam to condense the steam into water.
【0013】また逆に、吸着行程では温水通路10に冷
却水や他冷水などを供給して、吸着剤5を冷却し、冷水
通路13に被冷却水を送給すると、先に蒸発潜熱を奪わ
れて水になった蒸気通路12の水が加熱されて蒸発し
て、被冷却水を冷却する。また蒸発した蒸気は吸着剤5
に吸着される。On the contrary, in the adsorption process, if cooling water or other cold water is supplied to the hot water passage 10 to cool the adsorbent 5 and the water to be cooled is sent to the cold water passage 13, the latent heat of vaporization is taken away first. The water in the steam passage 12 which has been broken into water is heated and evaporated to cool the water to be cooled. Also, the vaporized vapor is adsorbent 5
Is adsorbed on.
【0014】従って、上述した構成の吸着式反応器の2
機を並列配置し、各温水通路10と冷水通路13に温水
/冷却水と冷却水/被冷却水を交互に切替え供給可能に
配管接続し、一方の吸着式反応器で吸着剤5を加熱し脱
着作用させ、他方の吸着式反応器で冷水通路13に被冷
却水を送給して蒸気通路12を加熱し、温水通路10に
被冷却水や他冷水などを供給して冷却する吸着剤5に吸
着作用させ、相互に逆作用可能となして、一方の吸着式
反応器を再生に、他方の吸着式反応器を冷水製造に供し
て、これを繰り返すことにより連続使用することができ
る。Therefore, the adsorption reactor having the above-mentioned structure
The machines are arranged in parallel, and hot water / cooling water and cooling water / cooled water are alternately connected to each hot water passage 10 and the cold water passage 13 by pipe connection so that the adsorbent 5 is heated by one of the adsorption reactors. An adsorbent 5 that is desorbed, feeds water to be cooled to the cold water passage 13 in the other adsorption reactor to heat the steam passage 12, and supplies water to be cooled or other cold water to the hot water passage 10 to cool it. Can be adsorbed to each other so that they can interact with each other, one adsorption reactor is used for regeneration, the other adsorption reactor is used for cold water production, and this can be repeated for continuous use.
【0015】構成2 図2はこの発明による吸着式反応器の他の構成を示す一
部破断斜視説明図である。図2の吸着式反応器は、図1
の例と同様に積層したプレートフィン形熱交換器の構成
からなるが、上部と下部に分かれ、上部は吸着剤層11
を挟み蒸気通路12と温水通路10の3層構造であり、
下部は蒸気通路12と冷水通路13の2層構造からな
り、このうち蒸気通路12が上部と下部で同層連通した
構成からなり、反応器全体からみれば4層構造からな
る。Structure 2 FIG. 2 is a partially broken perspective view showing another structure of the adsorption reactor according to the present invention. The adsorption reactor of FIG.
The plate fin type heat exchanger has the same structure as in the above example, but is divided into an upper part and a lower part, and the upper part is the adsorbent layer 11
It has a three-layer structure of a steam passage 12 and a hot water passage 10 sandwiching
The lower part has a two-layer structure of a steam passage 12 and a cold water passage 13, and the steam passage 12 has a structure in which the upper part and the lower part communicate with each other in the same layer, and has a four-layer structure when viewed from the whole reactor.
【0016】積層した通路のうち上部の蒸気通路12と
吸着剤層11間は孔あきプレート4を介して連通してい
るが密閉室を構成しており、所要値まで減圧され、吸着
剤層11には吸着剤5が充填されている。従って、反応
器上部では吸着剤層11側に熱源たる温水の流入出口を
設けた温水通路10を隣接積層させ、反応器下部では蒸
気通路12側に被冷却水の流入出口を設けた冷水通路1
3の各通路を隣接積層してある。かかる構成の図2の吸
着式反応器は、先の図1の構成と全く同様の作用効果を
奏するが、蒸気通路12の下部が媒体液(凝縮水)溜と
して機能するため、保水性能にすぐれている。The upper vapor passage 12 and the adsorbent layer 11 among the laminated passages communicate with each other through the perforated plate 4 but form a closed chamber, and the adsorbent layer 11 is depressurized to a required value. Is filled with an adsorbent 5. Therefore, in the upper part of the reactor, the hot water passage 10 having the inlet / outlet of hot water as a heat source on the adsorbent layer 11 side is adjacently stacked, and in the lower part of the reactor, the cold water passage 1 having the inlet / outlet of water to be cooled on the steam passage 12 side.
The three passages are laminated adjacent to each other. The adsorption type reactor of FIG. 2 having such a structure has the same effect as that of the structure of FIG. 1, but the lower part of the vapor passage 12 functions as a medium liquid (condensed water) reservoir, and therefore has excellent water retention performance. ing.
【0017】[0017]
【実施例】ちなみに、吸着剤にシリカゲル、蒸発媒体に
水を用いた場合、再生時には温水通路に80℃の温水を
送給すると、隣接する吸着剤層の吸着剤が加熱されて、
孔あきプレートを通過して、蒸気通路に入り、これに隣
接する冷水通路の31℃の冷却水で冷却され凝縮する。
また、吸着時には冷水通路の14℃の被冷却水が水の蒸
発により7℃に冷却される。この蒸気は隣接する吸着剤
層で吸着されるが、このとき温水通路に31℃の冷却水
を流して吸着剤を冷却する。Example By the way, when silica gel is used as the adsorbent and water is used as the evaporation medium, when hot water of 80 ° C. is fed to the hot water passage during regeneration, the adsorbent in the adjacent adsorbent layer is heated,
After passing through the perforated plate, it enters the steam passage and is cooled and condensed by the cooling water at 31 ° C. in the cold water passage adjacent thereto.
Further, at the time of adsorption, the water to be cooled at 14 ° C in the cold water passage is cooled to 7 ° C by evaporation of water. The vapor is adsorbed by the adsorbent layer adjacent to the adsorbent layer. At this time, cooling water at 31 ° C. is flowed through the hot water passage to cool the adsorbent.
【0018】[0018]
【発明の効果】この発明による吸着式反応器は、温水通
路、吸着剤充填層、蒸気通路、冷水通路の各通路を積層
したプレートフィン形熱交換器の構成からなり、簡単な
構造で小型化、高効率化を達成できる。The adsorption reactor according to the present invention comprises a plate fin type heat exchanger in which hot water passages, adsorbent-packed beds, steam passages, and cold water passages are laminated, and has a simple structure and is miniaturized. High efficiency can be achieved.
【図1】この発明による吸着式反応器の構成を示す一部
破断斜視説明図である。FIG. 1 is a partially cutaway perspective view showing the structure of an adsorption reactor according to the present invention.
【図2】この発明による吸着式反応器の他の構成を示す
一部破断斜視説明図である。FIG. 2 is a partially cutaway perspective view showing another configuration of the adsorption reactor according to the present invention.
1 プレート 2 コルゲートフィン 3 スペーサーバー 4 孔あきプレート 5 吸着剤 6 スペーサー 7 孔あきコルゲートフィン 10 温水通路 11 吸着剤層 12 蒸気通路 13 冷水通路 1 Plate 2 Corrugated Fin 3 Spacer 4 Perforated Plate 5 Adsorbent 6 Spacer 7 Perforated Corrugated Fin 10 Hot Water Passage 11 Adsorbent Layer 12 Steam Passage 13 Cold Water Passage
───────────────────────────────────────────────────── フロントページの続き (72)発明者 柳 秀治 茨城県勝田市中根3600−80 (72)発明者 真田 勝 茨城県稲敷郡茎崎町高見原3−3−18 (72)発明者 笠原 敬介 東京都中野区白鷺3−6−11 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Shuji Yanagi 3600-80 Nakane, Katsuta-shi, Ibaraki Prefecture (72) Inventor Masaru Sanada 3-3-18 Takamihara, Kukizaki-cho, Inashiki-gun, Ibaraki Prefecture (72) Inventor Keisuke Kasahara Tokyo 3-6-11 Shirasagi, Nakano-ku, Tokyo
Claims (2)
ン形熱交換器の構成からなり、中央の2通路が孔あきプ
レートを介して減圧密閉室を構成し、一方を吸着剤が充
填された吸着剤層、他方を吸着剤から発生した蒸気の蒸
気通路となし、吸着剤層側に熱源の温水が流入出する温
水通路を隣接積層させ、蒸気通路側に被冷却媒体の流入
出する冷水通路の各通路を隣接積層したことを特徴とす
る吸着式反応器。1. An adsorbent having a structure of a plate fin type heat exchanger in which at least four layers are laminated, two central passages constitute a decompression closed chamber through a perforated plate, and one of which is filled with an adsorbent. Layer, the other is a steam passage for the steam generated from the adsorbent, hot water passages where hot water of the heat source flows in and out are adjoined on the adsorbent layer side, and cold water passages where the cooling medium flows in and out on the steam passage side. An adsorption-type reactor characterized in that passages are laminated adjacent to each other.
成からなり、蒸気通路の上部で孔あきプレートを介して
吸着剤が充填された吸着剤層を隣接積層して減圧密閉室
を構成し、吸着剤層側に熱源の温水が流入出する温水通
路を隣接積層させ、蒸気通路の下部で被冷却媒体の流入
出する冷水通路を隣接積層したことを特徴とする吸着式
反応器。2. A decompression closed chamber is constructed by adjoining adsorbent layers filled with an adsorbent through a perforated plate at the upper part of a steam passage, which comprises a laminated plate fin type heat exchanger. An adsorption reactor characterized in that hot water passages through which hot water of a heat source flows in and out are adjoined on the adsorbent layer side, and cold water passages through which a medium to be cooled flows in and out under a vapor passage.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP8336191A JPH05157400A (en) | 1991-03-23 | 1991-03-23 | Adsorption type reactor |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP8336191A JPH05157400A (en) | 1991-03-23 | 1991-03-23 | Adsorption type reactor |
Publications (1)
Publication Number | Publication Date |
---|---|
JPH05157400A true JPH05157400A (en) | 1993-06-22 |
Family
ID=13800293
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP8336191A Pending JPH05157400A (en) | 1991-03-23 | 1991-03-23 | Adsorption type reactor |
Country Status (1)
Country | Link |
---|---|
JP (1) | JPH05157400A (en) |
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2002107003A (en) * | 2000-07-24 | 2002-04-10 | Mayekawa Mfg Co Ltd | Panel-shaped adsorption type refrigerator |
JP2005300129A (en) * | 2004-03-19 | 2005-10-27 | Denso Corp | Adsorber for adsorption type refrigerating machine |
US7065981B2 (en) | 1997-07-14 | 2006-06-27 | Dometic Ag | Sorption unit for an air conditioning apparatus |
WO2008029185A2 (en) * | 2006-09-08 | 2008-03-13 | University Of Warwick | Heat exchanger |
JP2015094026A (en) * | 2013-11-14 | 2015-05-18 | 株式会社東芝 | Oxygen reducing apparatus and refrigerator |
JP2017125649A (en) * | 2016-01-14 | 2017-07-20 | 株式会社あい・あいエナジーアソシエイツ | Heat exchange unit and adsorption type refrigerator |
-
1991
- 1991-03-23 JP JP8336191A patent/JPH05157400A/en active Pending
Cited By (9)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US7065981B2 (en) | 1997-07-14 | 2006-06-27 | Dometic Ag | Sorption unit for an air conditioning apparatus |
JP2002107003A (en) * | 2000-07-24 | 2002-04-10 | Mayekawa Mfg Co Ltd | Panel-shaped adsorption type refrigerator |
JP2005300129A (en) * | 2004-03-19 | 2005-10-27 | Denso Corp | Adsorber for adsorption type refrigerating machine |
WO2008029185A2 (en) * | 2006-09-08 | 2008-03-13 | University Of Warwick | Heat exchanger |
WO2008029185A3 (en) * | 2006-09-08 | 2008-04-24 | Univ Warwick | Heat exchanger |
JP2010502931A (en) * | 2006-09-08 | 2010-01-28 | ユニヴァーシティ・オヴ・ウォーリック | Heat exchanger |
US8276393B2 (en) | 2006-09-08 | 2012-10-02 | University Of Warwick | Heat exchanger |
JP2015094026A (en) * | 2013-11-14 | 2015-05-18 | 株式会社東芝 | Oxygen reducing apparatus and refrigerator |
JP2017125649A (en) * | 2016-01-14 | 2017-07-20 | 株式会社あい・あいエナジーアソシエイツ | Heat exchange unit and adsorption type refrigerator |
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