WO2018072314A1 - Unité de réfrigération par absorption et matrice de réfrigération par absorption - Google Patents

Unité de réfrigération par absorption et matrice de réfrigération par absorption Download PDF

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Publication number
WO2018072314A1
WO2018072314A1 PCT/CN2016/112148 CN2016112148W WO2018072314A1 WO 2018072314 A1 WO2018072314 A1 WO 2018072314A1 CN 2016112148 W CN2016112148 W CN 2016112148W WO 2018072314 A1 WO2018072314 A1 WO 2018072314A1
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WIPO (PCT)
Prior art keywords
absorption refrigeration
refrigeration unit
heat exchange
tube
unit according
Prior art date
Application number
PCT/CN2016/112148
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English (en)
Chinese (zh)
Inventor
邱伟
杨如民
武祥辉
武维建
刘彦武
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四川捷元科技有限公司
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Publication of WO2018072314A1 publication Critical patent/WO2018072314A1/fr

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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B15/00Sorption machines, plants or systems, operating continuously, e.g. absorption type
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28DHEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
    • F28D7/00Heat-exchange apparatus having stationary tubular conduit assemblies for both heat-exchange media, the media being in contact with different sides of a conduit wall
    • F28D7/16Heat-exchange apparatus having stationary tubular conduit assemblies for both heat-exchange media, the media being in contact with different sides of a conduit wall the conduits being arranged in parallel spaced relation
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28DHEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
    • F28D9/00Heat-exchange apparatus having stationary plate-like or laminated conduit assemblies for both heat-exchange media, the media being in contact with different sides of a conduit wall
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F21/00Constructions of heat-exchange apparatus characterised by the selection of particular materials
    • F28F21/06Constructions of heat-exchange apparatus characterised by the selection of particular materials of plastics material
    • F28F21/062Constructions of heat-exchange apparatus characterised by the selection of particular materials of plastics material the heat-exchange apparatus employing tubular conduits
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F9/00Casings; Header boxes; Auxiliary supports for elements; Auxiliary members within casings
    • F28F9/26Arrangements for connecting different sections of heat-exchange elements, e.g. of radiators
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02ATECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
    • Y02A30/00Adapting or protecting infrastructure or their operation
    • Y02A30/27Relating to heating, ventilation or air conditioning [HVAC] technologies
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B30/00Energy efficient heating, ventilation or air conditioning [HVAC]
    • Y02B30/62Absorption based systems

Definitions

  • the invention relates to the technical field of refrigeration equipment, in particular to an absorption refrigerator.
  • An absorption refrigerating machine which uses a binary solution as a working medium, wherein a low-boiling component is used as a refrigerant, that is, it is cooled by evaporation thereof; a high-boiling component is used as an absorbent, that is, an absorption effect of the refrigerant vapor is utilized.
  • a lithium bromide absorption refrigerating machine uses pure water as a refrigerant, that is, it relies on pure water to evaporate and absorb heat in a high vacuum environment to realize a cooling function.
  • the refrigerant vapor after the endothermic evaporation is absorbed, transported, heated and regenerated, condensed by the lithium bromide solution, and returned to the liquid state again, and then again absorbs heat and evaporates, and the source continuously performs the refrigeration cycle.
  • the evaporation temperature of the evaporator is generally set at about 5 ° C, and the saturation pressure is about 872 Pa.
  • This high vacuum environment requires high air tightness of the refrigerator.
  • a heat exchanger inside an absorption chiller uses a copper tube having a diameter of 16 mm or more as an array, and a copper plate is used as a heat exchange wall plate, thereby facing a complicated sealing problem with other components, and production efficiency is restricted. At the same time, this also results in a large overall weight of the absorption chiller, making it difficult to achieve weight reduction of the absorption chiller.
  • the metal is easily corroded by the solution and generates a non-condensable gas such as hydrogen to lower the working efficiency of the absorption refrigerating machine.
  • the object of the present invention is to overcome the deficiencies of the prior art and provide an absorption refrigeration unit in which a heat exchange tube and a heat exchange wall plate are made of plastic, so that the absorption refrigeration unit can be made under the premise of satisfying heat exchange performance. Lightweight and miniaturized. At the same time, the heat exchange tube and the heat exchange wall plate made of plastic are easy to seal and improve the production efficiency.
  • the plastic has strong anti-corrosion performance, can avoid non-condensable gas, and increases the working efficiency of the absorption refrigerating machine.
  • Such an absorption refrigeration unit is suitable for both high-power applications and suitable Used in homes and commercial applications where less power is required.
  • Plastics include general purpose plastics, engineering plastics and reinforced engineering plastics.
  • a second object of the present invention is to provide an absorption refrigeration matrix comprising a plurality of the above-described absorption refrigeration units.
  • the absorption refrigeration unit and the absorption refrigeration unit are an absorption refrigerator.
  • the regenerator, absorber, condenser and evaporator of the absorption refrigeration unit are shell-and-tube heat exchangers, including a shell side consisting of a shell-and-tube heat exchanger housing, and a shell-and-tube heat exchanger housing
  • the tube path formed by the heat exchange tubes; the heat exchange tubes are made of plastic.
  • the solution heat exchanger of the absorption refrigeration unit is a plate heat exchanger, the plate heat exchanger has a plate heat exchanger casing and a heat exchange wall plate; the heat exchange wall plate is fixed in the plate heat exchanger casing, and the heat exchange wall plate is Made of plastic.
  • the heat exchange tubes in the condenser, the evaporator, the absorber and the regenerator are made of a metal material having a relatively high heat transfer coefficient.
  • the heat exchange wall of the solution heat exchanger is also made of a metal material.
  • the density of the metal material is large, resulting in a large overall weight of the absorption refrigerator.
  • the metal heat exchange tube and the heat exchange wall plate also have the problems that the solution is corroded to generate non-condensable gas, which affects the working efficiency of the absorption refrigerating machine, and has high sealing process requirements and high sealing cost.
  • Plastics have a lower density than metal materials.
  • the weight of plastic in the same volume is much lower than that of metallic materials (such as brass).
  • metallic materials such as brass.
  • the inventors made the heat exchange tubes and the heat exchange wall plates in the absorption chiller made of plastic.
  • the absorption refrigeration unit provided by the embodiment of the invention can greatly reduce the weight of the whole machine.
  • the heat exchange tubes and heat exchange panels made of plastic are easy to seal.
  • the plastic has stronger corrosion resistance, can avoid corrosion by solution and generate non-condensable gas, and increases the working efficiency of the absorption refrigerator.
  • Such an absorption refrigeration unit is suitable for use in homes and commercial applications where power is required.
  • the tube wall thickness of the heat exchange tubes is from 0.1 to 0.5 mm.
  • the tube wall thickness of the heat exchange tubes is 0.15 mm.
  • a plurality of rows of heat exchange tubes are arranged in an upper and lower layer; a plurality of support strips are disposed between the adjacent two rows of heat exchange tubes; and the support strips are used to support the adjacent two rows of heat exchange tubes.
  • the support strip is made of plastic.
  • the support strips and heat exchange tubes are made of the same plastic.
  • the plurality of rows of heat exchange tubes are arranged in an upper and lower layer; the outer diameter of the heat exchange tubes is from 3 mm to 5 mm.
  • the center distance of adjacent heat exchange tubes located in the same row is 4 mm to 6 mm.
  • the center distance between the upper and lower adjacent heat exchange tubes is 5 mm to 8 mm.
  • the heat exchange tube has an outer diameter of 3 mm. Adjacent heat exchange tubes located in the same row have a center-to-center distance of 4 mm. The center distance between the upper and lower adjacent heat exchange tubes is 7 mm.
  • the shell and tube heat exchanger housing is made of plastic.
  • the shell and tube heat exchanger housing and the heat exchange tubes are made of the same plastic.
  • the heat exchange wall panel has a thickness of from 0.1 mm to 0.5 mm.
  • the heat exchange wall panel has a thickness of 0.15 mm.
  • the heat exchange wall plate is provided with textured ridges for supporting the heat exchange wall and turbulent flow of the fluid flowing through the ridges to increase the heat transfer coefficient.
  • the ribs are made of plastic.
  • the ribs and the heat exchange wall are made of the same plastic.
  • the heat exchange panels are arranged in multiple layers.
  • the wall spacing of the adjacent two layers of the heat exchange wall plate is 0.5 mm to 3 mm.
  • the wall spacing of the adjacent two layers of heat exchange panels is 1 mm.
  • the plate heat exchanger housing is made of plastic.
  • the plate heat exchanger housing and the heat exchange wall are made of the same plastic.
  • the fuselage housing of the absorption refrigeration unit is made of plastic.
  • the absorption refrigeration unit has a plurality of water flow interfaces for introducing and discharging cold water, hot water and cooling water; the water flow interface is made of plastic.
  • the components of the absorption refrigeration unit are all made of plastic.
  • the absorption refrigeration unit is provided with at least two groups of water flow interface groups, each group of water flow interface groups including at least a water flow interface as an inlet and an outlet of the hot water, and a water flow interface as an inlet and an outlet of the cold water. , as a water flow interface for the inlet and outlet of the cooling water.
  • Adjacent absorption refrigeration units can be interconnected by a water flow interface such that any number of absorption refrigeration units can be plugged into each other through the water flow interface to form an absorption refrigeration matrix.
  • the absorption refrigeration unit is provided with at least two combined faces; each set of water flow interface groups is distributed on the combined face.
  • the body casing of the absorption refrigeration unit is a rectangular parallelepiped, and the combined surface is six surfaces of the fuselage casing.
  • a set of water flow interface groups is provided on each combination surface.
  • Adjacent absorption refrigeration units can be interconnected by a water flow interface such that any number of absorption refrigeration units can be plugged into each other through a water flow interface to form a matrix type absorption refrigeration matrix.
  • the combined surface of the absorption refrigeration unit is used to closely fit the combined surfaces of adjacent absorption refrigeration units to form a matrix type absorption refrigeration matrix.
  • the water flow interfaces on at least one of the opposing sets of faces are mirror symmetrical to one another.
  • the body casing of the absorption refrigeration unit is provided with a water flow pipe system, and the water flow pipe system connects the same function water flow interfaces in different water flow interface groups; the water flow pipe system is also connected with the pipe
  • the tube-connected connection of the shell-type heat exchanger enables the absorption refrigeration unit to simultaneously or separately introduce hot water, cold water and cooling water through any one of the water flow interface groups.
  • the water flow conduit system forms a unitary structure with the fuselage housing.
  • the water flow pipeline system comprises a hot water inlet pipe, a hot water outlet pipe, a cold water inlet pipe, a cold water outlet pipe, a cooling water inlet pipe, and a cooling water outlet pipe.
  • the hot water inlet pipe connects the hot water inlet to the inlet of the tube of the regenerator.
  • the hot water outlet pipe connects the hot water outlet and the outlet of the regenerator tube.
  • the cold water inlet pipe connects the cold water inlet to the inlet of the evaporator tube.
  • the cold water outlet pipe connects the cold water outlet and the outlet of the evaporator tube.
  • the cooling water inlet pipe connects the cooling water inlet to the inlet of the tube of the absorber and condenser.
  • the cooling water outlet pipe connects the cooling water outlet and the outlet of the tube of the absorber and condenser.
  • the regenerator and the condenser are located in an upper portion of the body casing of the absorption refrigeration unit, wherein
  • the regenerator is used to heat and evaporate the refrigerant water absorbed in the dilute solution to obtain the refrigerant vapor; the heat absorbed by the evaporation process is provided by the hot water of the regenerator tube.
  • the condenser is used to cool and condense the refrigerant vapor obtained in the regenerator into refrigerant water, and the refrigerant water passes through the section. After the flow, it flows to the shell side of the evaporator.
  • the evaporator and the absorber are located in a lower portion of the body casing of the absorption refrigeration unit, wherein
  • the evaporator is used for evaporating heat of the shell-side refrigerant water to cool the cold water of the tube;
  • the absorber is used to absorb the refrigerant vapor generated by the shell side of the evaporator into the concentrated solution, and the heat released during the absorption is carried away by the cooling water of the tube.
  • the absorption refrigeration unit further includes a solution tank; the solution tank is for recovering the dilute solution produced in the absorber and providing the regenerator with the desired dilute solution.
  • the solution tank is made of plastic.
  • An absorption refrigeration matrix comprising any of the above-described absorption refrigeration units.
  • the absorption refrigeration unit provided by the embodiment of the invention has a heat exchange tube and a heat exchange wall plate made of plastic.
  • the weight of the whole machine can be greatly reduced.
  • the heat exchange tubes and heat exchange panels made of plastic are easy to seal.
  • the plastic has stronger corrosion resistance, can avoid corrosion by solution and generate non-condensable gas, and increases the working efficiency of the absorption refrigerator.
  • Such an absorption refrigeration unit is suitable for use in homes and commercial applications where power is required.
  • the absorption refrigeration matrix provided by the embodiment of the present invention has the above-mentioned absorption refrigeration unit, and therefore has the advantages of low weight, easy sealing, stronger corrosion resistance, and high work efficiency.
  • FIG. 1 is a schematic perspective view showing the structure of an absorption refrigeration unit according to an embodiment of the present invention
  • FIG. 2 is a schematic exploded view showing the assembly of the absorption refrigeration unit in the embodiment of the present invention.
  • 3A is a schematic perspective structural view of a condenser and a side regenerator in an embodiment of the present invention
  • 3B is a schematic cross-sectional structural view of a condenser and a side regenerator in an embodiment of the present invention
  • FIG. 4A is a schematic perspective view showing a three-dimensional installation structure of a solution heat exchanger according to an embodiment of the present invention
  • FIG. 4B is a schematic structural view of a bare heat exchange wall plate after a part of components are removed by a solution heat exchanger according to an embodiment of the present invention
  • FIG. 5 is a schematic diagram of direct splicing of six absorption refrigeration units to form an absorption refrigeration matrix in an embodiment of the present invention.
  • Absorption refrigeration unit 100 upper combined surface 110; lower combined surface 130; left combined surface 120; right combined surface 140; hot water inlets 111, 121; hot water outlets 112, 122; cold water inlets 113, 123; cold water outlets 114, 124; cooling water inlets 115, 125; cooling water outlets 116, 126; solution heat exchanger 135; regenerator 201; condenser 202; absorber 203; evaporator 204; hot water inlet pipes 211, 221; Pipes 212, 222; cold water inlet pipes 213, 223; cold water outlet pipes 214, 224; cooling water inlet pipes 215, 225; cooling water outlet pipes 216, 226; solution pump 231; solution tank 232; 300; support strip 301; heat exchange tube 310; solution distributor 321; shell-and-tube heat exchanger housing 322; drain hole 340; dilute solution inlet 401; concentrated solution outlet 402; concentrated solution to the absorber shell Channel 404; concentrated solution inlet 406; dilute solution outlet 408
  • orientation or positional relationship of the terms “upper”, “lower”, “left”, “right”, etc. is based on the orientation or positional relationship shown in the drawings, or The orientation or positional relationship that is conventionally placed when the product is used, or the orientation or positional relationship that is conventionally understood by those skilled in the art, is merely for the convenience of describing the present invention and simplifying the description, and does not indicate or imply the indicated device. Or the components must have a particular orientation, are constructed and operated in a particular orientation, and thus are not to be construed as limiting the invention.
  • the heat exchanger inside the conventional absorption chiller uses a copper tube having a diameter of 16 mm or more as an array, and thus faces complicated sealing problems with other components, and production efficiency is restricted. At the same time, this also results in a large overall weight of the absorption chiller, making it difficult to achieve weight reduction of the absorption chiller.
  • the metal is easily corroded by the solution and generates a non-condensable gas such as hydrogen to lower the working efficiency of the absorption refrigerating machine.
  • absorption chillers Due to the use of non-ferrous materials and mechanical processing methods, conventional absorption chillers are generally bulky, have poor corrosion resistance, and require professional maintenance. Generally, they cannot be used in homes and commercial applications where power is required.
  • the present embodiment provides an absorption refrigeration unit which is an absorption refrigerating machine whose heat exchange tubes and heat exchange wall plates are made of plastic.
  • the heat exchange tube is a thin-walled pipe member
  • the heat exchange wall plate is a thin-walled plate member, so that the absorption refrigeration unit can realize weight reduction and miniaturization under the premise of satisfying heat exchange performance.
  • the heat exchange tube and the heat exchange wall plate made of plastic are easy to seal, and can be integrated with other plastic parts by a precision injection molding process, thereby improving production efficiency.
  • the plastic has strong corrosion resistance, can avoid non-condensable gas, increases the working efficiency of the absorption refrigeration unit, and reduces the maintenance frequency.
  • Such an absorption refrigeration unit is suitable for use in a home and a commercial where power is required due to its weight reduction, miniaturization, and maintenance frequency.
  • the absorption refrigeration unit provided in this embodiment is also capable of forming a large absorption refrigeration matrix through a water flow interface group, which is highly expandable. Furthermore, it is only necessary to produce a standardized absorption refrigeration unit, and a plurality of absorption refrigeration units can be combined as needed during use, which greatly improves production efficiency and reduces manufacturing. Cost and production cycle.
  • plastic refers to engineering-plastics, such as polycarbonate (PC), polyamide (polyamide, PA), polyacetal (Polyoxy Methylene, POM), poly Polyphenylene Oxide (PPO), polyester (PET, PBT), polyphenylene sulfide (PPS), polyaryl ester, and the like.
  • an absorption refrigeration unit using a lithium bromide solution and a refrigerant water as a working medium will be described as an example.
  • the absorption refrigeration unit 100 is an absorption refrigerating machine having a rectangular parallelepiped shape.
  • the refrigeration power of the absorption refrigeration unit 100 is 3RT (about 11 kW)
  • the main body volume is only 840 ⁇ 400 ⁇ 200 (mm3), less than 0.1 cubic meter, and is processed by a precision injection molding process.
  • the inside is provided with heat exchange components such as a regenerator, an evaporator, an absorber, and a condenser.
  • the absorption refrigeration unit 100 uses lithium bromide solution + refrigerant water as a working medium, and relies on refrigerant water to evaporate and absorb heat in a high vacuum environment to achieve refrigeration.
  • the refrigerant water absorbs heat and evaporates into a refrigerant vapor.
  • the refrigerant vapor no longer has a phase change endothermic capacity. Therefore, it is absorbed by the lithium bromide solution and then regenerated by heating with the lithium bromide solution to generate a refrigerant vapor.
  • the refrigerant vapor is condensed and returned to the liquid refrigerant water to be again absorbed by heat.
  • the refrigerant water absorbs heat and absorbs - absorption - regeneration - condensation - and then absorbs heat and evaporates, so that the source continuously performs the refrigeration cycle.
  • the cold water, hot water and cooling water exchange heat between the evaporator, the regenerator, the absorber and the various components of the condenser to complete the refrigeration process.
  • the absorption refrigeration unit 100 obtains energy from the outside through hot water, cooling water, and cold water pipes, respectively, and releases heat to the outside and supplies cold to the outside.
  • the absorption refrigeration unit 100 shown in Fig. 1 also has a water flow piping system, a solution heat exchange and a circulation system to constitute an independent and complete refrigerator. When installed separately, its cooling power is called unit power.
  • the plurality of absorption refrigeration units 100 have the capability of forming a large absorption refrigeration matrix by combination, so that the total power becomes the sum of the powers of the plurality of absorption refrigeration units 100.
  • the present embodiment provides a set of water flow interface groups on the four combined faces of the absorption refrigeration unit 100: the upper combined face 110, the left combined face 120, the lower combined face 130, and the right combined face 140, respectively.
  • Each group of water flow interface groups includes a hot water inlet, a hot water outlet, a cold water inlet, a cold water outlet, a cooling water outlet, and a cooling water inlet.
  • the upper combined surface 110 is respectively provided with a hot water inlet 111, a hot water outlet 112, a cold water inlet 113, a cold water outlet 114, a cooling water inlet 115 and a cooling water outlet 116;
  • the right side surface 140 is respectively provided with a hot water inlet 121 and hot water.
  • the lower combined surface 130 opposite the upper combined surface 110 is provided with six identical water flow interfaces that are mirror symmetrical with the upper combined surface 110
  • the left combined surface 120 (back) opposite the right combined surface is provided with
  • the right combination face 140 is six identical water flow interfaces that are mirror symmetrical.
  • the symmetrical design of the upper and lower sides makes the corresponding water flow interfaces align and connect together when the two absorption refrigeration units 100 are combined up and down or left and right.
  • At least two of the six faces of the rectangular parallelepiped absorption refrigeration unit 100 may be arranged as a combined face, each of which is provided with a set of water flow interface groups for use with adjacent absorption refrigeration units (or external The energy medium is connected.
  • Each group of water flow interface groups includes six water flow interfaces. In actual use, according to the actual situation, it is also possible to use four water flow interfaces or other number of water flow interfaces as one water flow interface group on one combined surface.
  • the rectangular parallelepiped absorption refrigeration unit enables adjacent absorption refrigeration units to closely fit each other through the combined faces to form an absorption refrigeration matrix, thereby obtaining a more compact structure. It can be understood that in other embodiments, the absorption refrigeration unit may not adopt a rectangular parallelepiped structure.
  • FIG. 2 is a schematic exploded view of the assembly of the absorption refrigeration unit 100 in the embodiment of the present invention.
  • the regenerator 201 and the condenser 202 are located at an upper portion in the body casing of the absorption refrigeration unit 100.
  • the regenerator 201 is for heating and evaporating the refrigerant water absorbed in the dilute solution to obtain the refrigerant vapor, and the heat absorbed by the evaporation process is supplied by the hot water of the tube of the regenerator 201.
  • the condenser 202 is used to cool and condense the refrigerant vapor obtained in the regenerator 201 into refrigerant water, and the refrigerant water flows to the shell side of the evaporator 204 after throttling.
  • the evaporator 204 and the absorber 203 are located at a lower portion in the body casing of the absorption refrigeration unit 100.
  • the evaporator 204 is used to cool the cold water of the tube by the endothermic heat of evaporation of the shell-side refrigerant water.
  • the absorber 203 is used to absorb the refrigerant vapor generated by the shell side of the evaporator 204 into the concentrated solution, and the heat released during the absorption is carried away by the cooling water of the tube.
  • the upper combined surface 110 of the absorption refrigeration unit is provided with a plurality of water flow pipes formed by the mutual cooperation of the housing wall plates; respectively, the hot water inlet pipe 211, the hot water outlet pipe 212, and the cold water inlet pipe. 213, a cold water outlet pipe 214, a cooling water inlet pipe 215, and a cooling water outlet pipe 216, and It is not connected to the hot water inlet 111, the hot water outlet 112, the cold water inlet 113, the cold water outlet 114, the cooling water inlet 115, and the cooling water outlet 116.
  • the right combination surface 140 of the absorption refrigeration unit is provided with a plurality of water flow pipes formed by the mutual matching of the wall plates of the fuselage casing; respectively, the hot water inlet pipe 221 and the hot water outlet pipe. 222.
  • Each of the above-described pipes is connected to the hot water inlet 121, the hot water outlet 122, the cold water inlet 123, the cold water outlet 124, the cooling water inlet 125, and the cooling water outlet 126, respectively.
  • the water outflow inlets on the respective combination faces are communicated with each other through the water flow pipe, so that the absorption refrigeration unit 100 can simultaneously or separately introduce the hot water, the cold water and the cooling water from any one of the combined faces.
  • the absorption refrigeration unit 100 communicates with the external heat source, the cold source, the cooling water source or the adjacent absorption refrigeration unit 100 through the water flow interface on the four combined surfaces, and supplies or withdraws the water flow, and the hot water and the cold water are
  • the cooling water is connected to the tube paths of the respective shell-and-tube heat exchangers (regenerator 201, condenser 202, evaporator 204, and absorber 203) inside the absorption refrigeration unit 100.
  • the four hot water inlets 111, 121 and the like of the hot water are connected to the tube inlet of the regenerator 201 through the hot water inlet pipes 211, 221 built in the four walls to supply the heat to the absorption refrigeration unit 100.
  • the four cooling water inlets 115, 125 and the like of the cooling water are connected to the condenser 202 and the tube inlet of the absorber 203 through the cooling water inlet pipes 215, 225 and the like.
  • the four hot water outlets 112, 122 of the hot water are connected to the tube outlet of the regenerator 201 through the hot water outlet pipes 212, 222 and the like built in the four wall plates.
  • the four cold water outlets 114, 124 and the like of the cold water are connected to the tube outlet of the evaporator 204 through the cold water outlet pipes 214, 224 and the like built in the four wall plates.
  • the four cooling water outlets 116, 126 and the like of the cooling water are connected to the condenser outlets of the condenser 202 and the absorber 203 through the cooling water outlet pipes 216, 226 and the like built in the four wall plates. In this way, a complete water flow duct system is formed, which forms an integral structure with the fuselage casing of the absorption refrigeration unit 100.
  • the water flow pipe system interconnects the same function water flow interfaces in different water flow interface groups; so that the absorption refrigeration unit 100 can simultaneously introduce hot water, cold water and cooling water through any one of the water flow interface groups.
  • the water flow duct system allows the absorption refrigeration unit 100 to simultaneously or separately introduce hot water, cold water, and cooling water from any one of the combined surfaces.
  • 4A is a schematic perspective view showing the three-dimensional installation structure of the solution heat exchanger 135 in the embodiment of the present invention.
  • the solution heat exchanger 135 is a plate heat exchanger. As shown in FIG. 1, the solution heat exchanger 135 is disposed in the recessed region of the side wall of the body casing of the absorption refrigeration unit 100, and is integrally formed with the refrigeration unit. As shown in FIG. 2, the solution tank 232 is substantially square, and cooperates with the internal structure of the lower portion of the fuselage casing of the absorption refrigeration unit 100, so that the entire solution tank 232 is perfectly matched and embedded in the fuselage casing of the absorption refrigeration unit 100. Internally, the volume of the absorption refrigeration unit 100 is made more compact. Solution tank 232 is used to recover the dilute lithium bromide solution produced in absorber 203 and to provide regenerator 201 with the desired dilute lithium bromide solution.
  • 4B is a schematic view showing the structure of the exposed heat exchange wall 420 after the solution heat exchanger 135 has removed some components in the embodiment of the present invention.
  • a plurality of heat exchange walls 420 are arranged in a plurality of layers, wherein the interior of the plate heat exchanger casing 424 is evenly spaced by a plurality of heat exchange walls 420 to form a passage for the hot and cold solution to flow:
  • the dilute solution channel 412 and the concentrated solution channel 414 are separated.
  • the low temperature lithium bromide solution and the high temperature lithium bromide concentrated solution are simultaneously in contact with the heat exchange wall plate 420, and the heat exchange wall plate 420 becomes a medium for heat exchange between the low temperature lithium bromide solution and the high temperature lithium bromide concentrated solution.
  • the four corners of the solution heat exchanger 135 are respectively provided with inlets and outlets for the solution channels, respectively: a concentrated solution inlet 406 in the upper left corner, a concentrated solution outlet 402 in the lower left corner, a dilute solution inlet 401 in the lower right corner, and a thin upper left corner.
  • Solution outlet 408 a concentrated solution inlet 406 in the upper left corner, a concentrated solution outlet 402 in the lower left corner, a dilute solution inlet 401 in the lower right corner, and a thin upper left corner.
  • a solution pump 231 a concentrated solution to the channel 404 of the shell side of the absorber 203, and a dilute solution to the channel 409 of the regenerator 201.
  • the solution pump 231 is used to power the dilute solution flowing in the solution heat exchanger 135, pump it from the dilute solution inlet 401 in the lower right corner to the dilute solution outlet 408 in the upper left corner, and transport it to the regenerator 201 through the connecting pipe.
  • the solution dispenser (not shown).
  • a surface of the heat exchange wall 420 is stamped with a densely distributed, longitudinally and transversely woven strip 422 for supporting the heat exchange wall 420 to withstand
  • the pressure generated by the vacuum causes turbulence in the fluid flowing through the ribs 422 to increase the heat transfer coefficient.
  • the heat exchange wall 420 is made of plastic, and the heat exchange wall 420 has a thickness of 0.1 mm to 0.5 mm.
  • the heat exchange wall panel 420 has a thickness of 0.15 mm.
  • such an extremely thin thickness compensates for the problem of insufficient heat transfer performance of the plastic, so that the heat transfer performance of the heat exchange wall plate 420 can meet the requirements of the absorption refrigerator.
  • the heat exchange wall 420 is made of plastic, the phase With the metal heat exchange wall plate, the weight of the solution heat exchanger 135 can be greatly reduced, thereby achieving weight reduction.
  • the plastic Since the plastic has excellent corrosion resistance, it can also avoid the generation of non-condensable gas due to corrosion of the heat exchange wall 420, which increases the working efficiency of the absorption refrigerator. At the same time, the heat exchange wall 420 made of plastic is easier to seal than the metal heat exchange wall.
  • the inventors have found through research that the traditional solution heat exchanger using metal heat exchanger wall plate is difficult to seal due to metal.
  • the shell In order to ensure the sealing performance of the solution heat exchanger, the shell can only be made of thick steel plate or casting. In order to further increase the weight of the solution heat exchanger and the corrosion resistance is poor.
  • the plate heat exchanger housing 424 of the solution heat exchanger 400 is also made of plastic, so that the seal between the plate heat exchanger housing 424 and the heat exchange wall 420 can be easily realized.
  • the thickness of the plate heat exchanger housing 424 can be reduced.
  • the weight of the solution heat exchanger 135 is further alleviated, and the corrosion resistance of the solution heat exchanger 135 is also enhanced.
  • the plate heat exchanger housing 424 and the heat exchange wall 420 may be made of the same kind of plastic and integrally molded by an injection molding process to provide excellent sealing performance.
  • the ribs 422 are made of plastic to ensure weight reduction.
  • the ribs 422 and the heat exchange wall 420 are made of the same plastic to facilitate manufacturing.
  • the wall spacing of the adjacent two layers of the heat exchange wall 420 is 0.5 mm to 3 mm. In the present embodiment, the spacing between the walls of the adjacent two layers of the heat exchange wall 420 is 1 mm. At the same time, since the thickness of the heat exchange wall plate 420 is 0.15 mm, the structure of the solution heat exchanger 135 is made more compact, and a larger heat exchange area is provided per unit volume, which is advantageous for miniaturization of the solution heat exchanger 135.
  • the regenerator 201, the condenser 202, the evaporator 204, and the absorber 203 are all shell-and-tube heat exchangers having similar structures.
  • the regenerator 201 and the condenser 202 will be described as an example.
  • 3A is a schematic perspective view showing a condenser 202 and a side regenerator 201 in the embodiment of the present invention
  • FIG. 3B is a schematic cross-sectional structural view of the condenser 202 and the side regenerator 201 in the embodiment of the present invention.
  • shell-and-tube heat exchangers 300 there are two shell-and-tube heat exchangers 300, the shell-and-tube heat exchanger 300 on the left side constitutes the condenser 202, the shell-and-tube heat exchanger 300 on the right side and the solution distributor in the figure. 321 constitutes a regenerator 201.
  • the shell-and-tube heat exchanger 300 includes a heat exchange tube 310 and a shell-and-tube heat exchanger housing 322.
  • a plurality of rows of heat exchange tubes 310 are arranged in upper and lower layers (only a part of the heat exchange tubes 310 are shown in the figure), and the heat exchange tubes 310 are fixed on the tubes In the heat exchanger housing 322.
  • the shell-and-tube heat exchanger housing 322 constitutes the tube path of the shell-and-tube heat exchanger 300, and the heat exchange tube 310 constitutes the shell side of the shell-and-tube heat exchanger 300.
  • the heat exchange tube 310 is made of plastic, and the tube wall thickness of the heat exchange tube 310 is from 0.1 mm to 0.5 mm. In the present embodiment, the tube wall thickness of the heat exchange tube 310 is 0.15 mm. Compared with the metal heat exchange tube, the extremely thin thickness increases the heat exchange area by more than ten times in the same volume, which makes up for the problem that the heat transfer performance of the plastic is insufficient, so that the heat transfer performance of the heat exchange tube 310 can reach the absorption type. Refrigerator requirements.
  • the heat exchange tube 310 is made of plastic, the weight of the shell-and-tube heat exchanger 300 can be greatly reduced as compared with the use of the metal heat-dissipating tube, thereby achieving weight reduction. Since the plastic has excellent corrosion resistance, it can also avoid the generation of non-condensable gas due to corrosion of the heat exchange tube 310, thereby increasing the working efficiency of the absorption refrigerator. At the same time, the heat exchange tube 310 made of plastic is easier to seal than the metal heat exchange tube.
  • the inventor discovered through research that the traditional shell-and-tube heat exchanger using metal heat exchange tube is difficult to seal due to metal.
  • the shell can only be thick steel plate. Or the casting is made, thereby further increasing the weight of the shell-and-tube heat exchanger and having poor corrosion resistance.
  • the shell-and-tube heat exchanger housing 322 of the shell-and-tube heat exchanger 300 is also made of plastic, such that between the shell-and-tube heat exchanger housing 322 and the heat exchange tube 310 The sealing can be easily achieved, and the thickness of the shell-and-tube heat exchanger housing 322 can be reduced. Thus, the weight of the shell-and-tube heat exchanger 300 is further alleviated, and the corrosion resistance of the shell-and-tube heat exchanger 300 is also enhanced.
  • the shell-and-tube heat exchanger housing 322 and the heat exchange tube 310 may be made of the same kind of plastic and integrally molded by an injection molding process to provide excellent sealing performance.
  • a plurality of support bars 301 are disposed at equal intervals, and the support bars 301 are disposed to intersect with the heat exchange tubes 310 and perpendicular to the heat exchange tubes 310.
  • the support bar 301 is used to support the two rows of heat exchange tubes 310 adjacent to each other and to withstand the structural stress caused by the high vacuum in the shell-and-tube heat exchanger housing 322.
  • the support bar 301 is made of plastic to ensure weight reduction.
  • the support bar 301 and the heat exchange tube 310 are made of the same plastic to facilitate manufacturing.
  • the solution dispenser 321 is a rectangular parallelepiped having a cavity inside for the flow of a dilute lithium bromide solution.
  • the solution distributor 321 is disposed at the upper portion of the shell-and-tube heat exchanger 300 on the right side to collectively form the regenerator 201.
  • a plurality of drain holes 340 are uniformly disposed on the solution distributor 321 .
  • the drain hole 340 In the case of the elongated holes, three rows are formed extending in the width direction of the solution distributor 321 and equally spaced apart to form a row. In the longitudinal direction of the solution distributor 321, a plurality of rows of drain holes 205 are provided at equal intervals.
  • the bleed hole 205 is used to uniformly spray the dilute lithium bromide solution in the cavity to the lower heat exchange tube 310.
  • the solution dispenser 321 can also be made of plastic for further weight reduction.
  • the solution dispenser 321 and the shell-and-tube heat exchanger housing 322 can be made of the same type of plastic to facilitate manufacturing, assembly, and sealing.
  • the inventors In addition to achieving weight reduction of the shell-and-tube heat exchanger 300, the inventors also desire to achieve miniaturization of the shell-and-tube heat exchanger 300.
  • the miniaturized shell-and-tube heat exchanger 300 can make the absorption refrigerator 100 as small as a whole, and can be applied to a home or other place where the cooling power is not high.
  • the heat exchange efficiency of the condenser 202 is not high because the refrigerant vapor enters the condenser 202 and undergoes heat exchange and heat exchange liquefaction with the heat exchange tube 310 to form water droplets on the surface of the heat exchange tube 310, and Collecting and freely dropping under the action of gravity, the condensed water is continuously dropped into the lower rows of heat exchange tubes 310 during the dropping process, and a descending water film is formed on the surface of the heat exchange tubes 310, especially at the lower arc of the heat exchange tubes 310.
  • the thickness of the water film tends to be very thick, increasing the heat transfer resistance between the refrigerant vapor and the heat exchange tube 310, which is disadvantageous for the contact of the refrigerant vapor with the heat exchange tube 310, resulting in inefficient heat exchange.
  • the shell-and-tube heat exchanger 300 When the shell-and-tube heat exchanger 300 is used as a part of the regenerator 201 and the absorber 203, as the cooling power is reduced, the required circulation amount of the working fluid is also reduced, and accordingly, the outer surface of the heat exchange tube 310 cannot be formed.
  • the lithium bromide solution is sufficiently wetted to cause an unfavorable phenomenon of "dry spots".
  • the inventors tried to increase the flow rate of the circulation pump, and continuously sprayed the working fluid far more than the actual required circulation amount from the effluent pool at the bottom of the regenerator 201 and the absorber 203 to On top of the heat exchange tube 310. However, this increases the flow rate of the circulation pump, increasing parasitic energy consumption and operating costs. The trend is toward the development of miniaturization and home-based absorption chillers.
  • the shell-and-tube heat exchanger 300 When the shell-and-tube heat exchanger 300 is used as the evaporator 204, since the specific heat capacity of the refrigerant water is large, the flow rate of the refrigerant water required to complete the rated cooling capacity is relatively small, and a complicated refrigerant distributor is required to accurately fix the refrigerant water. Distributed to each heat exchange tube 310, so that the refrigerant water fully wets the heat exchange tube 310 and along A water film (referred to as a falling film) having a uniform thickness reduction is formed on the surface of the heat exchange tube 310.
  • a water film referred to as a falling film
  • the refrigerant water evaporates, the refrigerant water is continuously reduced, so that the heat exchange tube 310 cannot be sufficiently wetted to cause a "dry spot" on the outer surface of the heat exchange tube 310.
  • the appearance of dry spots greatly reduces the heat transfer coefficient of the evaporator 204. Therefore, in order to ensure sufficient wetting, it is necessary to dispose a dedicated refrigerant pump, and use a refrigerant water far more than the actual evaporation amount, and continuously pump the refrigerant water which has not evaporated from the bottom of the evaporator 204 under the pumping of the refrigerant pump.
  • the top of the evaporator 204 The existence of the refrigerant pump increases the volume and weight of the refrigerator on the one hand, making it difficult to miniaturize the evaporator 204, and on the other hand, increases the running cost.
  • the inventors optimized the outer diameter of the heat exchange tubes 310 and the center distance between adjacent heat exchange tubes 310.
  • the outer diameter of the heat exchange tube 310 is set to 3 mm to 5 mm
  • the center distance of the adjacent heat exchange tubes 310 in the same row is set to 4 mm to 6 mm
  • the center distance of the upper and lower adjacent heat exchange tubes 310 is set to 5 mm. ⁇ 8mm.
  • the outer diameter of the heat exchange tube 310 is 3 mm
  • the center distance of the adjacent heat exchange tubes 310 in the same row is 4 mm
  • the center distance of the upper and lower adjacent heat exchange tubes 310 is 7 mm.
  • the gap between the adjacent heat exchange tubes 310 of the same row is only 1 mm, so that the small gap can exert the beneficial effect of the surface tension of the refrigerant water, so that The refrigerant water condensed on the surface of the heat pipe 310 is collected at the gap and dropped.
  • the first condensed refrigerant water does not drip onto the surface of the lower heat exchange tube 310 to form a water film, so that the thickness of the water film suspended on the lower surface of the heat transfer tube 310 is reduced, thereby improving the overall working efficiency of the condenser 202. In this way, the condenser 202 is miniaturized.
  • the gap between adjacent heat exchange tubes 310 of the same row is only 1 mm, at which the surface tension and gravity of the lithium bromide solution
  • the combined action enables the lithium bromide solution to have both a downward flow and a diffusion and accumulation at the gap, thereby ensuring that the refrigerant water is always immersed in the heat exchange tube 310.
  • the lithium bromide solution and the heat exchange tube 310 are subjected to immersion and falling film combined heat exchange.
  • the lithium bromide solution does not need to fill the entire casing 201, and only the lithium bromide solution is required to finally immerse the heat exchange tube 310. Therefore, the deposition height of the lithium bromide solution at the gap can be adjusted according to the flow rate of the lithium bromide solution, so that the lithium bromide solution can uniformly immerse the heat exchange tube 310 even when the refrigeration load is small and the flow rate of the lithium bromide solution is small.
  • the contact of the lithium bromide solution with the heat exchange tube 310 can be ensured without multiple pumping, the dry spot phenomenon is effectively eliminated, the parasitic energy consumption and the running cost are reduced, and the regenerator 201 and the absorber 203 are miniaturized.
  • the outer diameter of the heat exchange tube 310 is only 3 mm, and the gap between the adjacent heat exchange tubes 310 of the same row is only 1 mm, so that the small gap can exert the refrigerant water.
  • the beneficial effect of surface tension Under the combined action of the surface tension of the refrigerant water and the gravity, a part of the refrigerant water forms a pile at the gap, diffuses and wets the heat exchange tube 310, and another portion drops through the gap to the heat exchange tube 310 of the lower layer.
  • the refrigerant water flows through the heat exchange tubes 310 of each layer in sequence.
  • the refrigerant water flows through the layer heat exchange tubes 310, all of which are completed by gravity.
  • the refrigerant water passes through the uppermost heat exchange tube 310, and when it reaches the lowermost heat exchange tube 310, it is completely evaporated, and it is not necessary to use a refrigerant pump.
  • the gap can automatically adjust the accumulation height of the refrigerant water at the gap according to the flow rate of the refrigerant water.
  • the flow rate of the refrigerant water is large, the height of the liquid accumulated at the gap will flood the heat transfer tube 310, and the flow rate flowing through the gap is also large.
  • the flow rate of the refrigerant water is small, the liquid accumulated in the gap is low in height, but due to the wettability of the surface of the heat exchange tube 310, the refrigerant liquid will infiltrate the heat exchange tube 310, reducing the chance of "dry spots" on the surface of the heat exchange tube 310. Increase the heat transfer coefficient. In this way, it is not necessary to provide a dedicated refrigerant pump and a refrigerant distributor, which reduces the running cost and also facilitates miniaturization of the evaporator 204.
  • the body casing, the water flow port, and the solution tank 232 of the absorption refrigeration unit 100 may be made of plastic. Even the components of the absorption refrigeration unit 100 are all made of plastic.
  • FIG. 5 is a schematic diagram of direct splicing of six absorption refrigeration units to form an absorption refrigeration matrix 500 in an embodiment of the present invention.
  • the six absorption refrigeration units have the same structure as the absorption refrigeration unit 100.
  • the six absorption refrigeration units are numbered 501, 502, and 503, respectively. 504, 505, 506.
  • the six absorption refrigeration units 501, 502, 503, 504, 505, 506 are superimposed and combined in a 3 ⁇ 2 manner to form an absorption refrigeration matrix 500.
  • Six refrigeration units 501, 502, 503, 504, The water flow interfaces on the adjacent combination faces of 505 and 506 are connected together, for example, the hot water inlets of the respective absorption refrigeration units are connected with the hot water inlets of the adjacent refrigeration units; from the hot water source (for example, boilers, solar water heaters)
  • the supplied hot water is supplied through the hot water inlet 511 of the absorption refrigeration unit 501, and then the hot water is supplied to the regenerator of the respective absorption refrigeration unit through the hot water inlet pipe in each absorption refrigeration unit, and the hot water
  • the hot water outlet pipes of the respective absorption refrigeration units flow out, and finally the hot water of the absorption refrigeration matrix 500 returns from the hot water outlet 512 of the absorption refrigeration unit 503 to the heat.
  • the cold water from the cold load is input to the evaporator of the absorption refrigeration matrix 500 through the cold water inlet 513 of the absorption refrigeration unit 501, and is cooled by the refrigerant water in the evaporator, and then cooled from the absorption refrigeration unit 503.
  • Exit 514 returns to a cold load.
  • the cooling water from the cooling tower is supplied to the condenser and the absorber of the absorption refrigeration matrix 500 through the cooling water inlet 515 of the absorption refrigeration unit 501, and the heat discharged from the condenser/absorber is absorbed, and the cooling water is taken from the absorption refrigeration unit.
  • the cooling water outlet 516 of 503 is returned to the cooling tower.
  • the combined faces of adjacent absorption refrigeration units are in close contact.
  • the six absorption refrigeration units are combined to form a single working unit, and the combined cooling system has a cooling power of 6 ⁇ 3RT (about 66 kW), which is six times the power of the single absorption refrigeration unit, and is passed through a matrix. Combined to achieve a cooling power multiplier expansion.
  • the heat exchange tube is made of plastic, and the wall thickness of the heat exchange tube is 0.1 mm to 0.5 mm.
  • the thickness of the tube wall of such a heat exchange tube is much lower than that of the metal heat exchange tube, and the heat exchange area is increased by more than ten times under the same volume, thereby making up for the problem of insufficient heat transfer performance of the plastic, so that the heat transfer tube is transmitted.
  • the thermal performance can meet the requirements of absorption chillers, and the absorption refrigeration unit can achieve weight reduction and miniaturization.
  • the heat exchange tube made of plastic is easy to seal, and can be integrally molded with other plastic parts by a precision injection molding process, thereby improving production efficiency.
  • the plastic has strong corrosion resistance, can avoid non-condensable gas, increases the working efficiency of the absorption refrigeration unit, and reduces the maintenance frequency.
  • Such an absorption refrigeration unit is suitable for use in a home and a commercial where power is required due to its weight reduction, miniaturization, and maintenance frequency.
  • the absorption refrigeration unit is also capable of forming a large absorption refrigeration matrix through a water flow interface group, which is highly expandable. Furthermore, it is only necessary to produce a standardized absorption refrigeration unit, and a plurality of absorption refrigeration units can be combined as needed during use, which greatly improves production efficiency, reduces manufacturing cost and production cycle.

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Thermal Sciences (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Sorption Type Refrigeration Machines (AREA)
  • Heat-Exchange Devices With Radiators And Conduit Assemblies (AREA)

Abstract

L'invention concerne une unité de réfrigération par absorption (100, 501, 502, 503 504, 505, 506) et une matrice de réfrigération par absorption (500). Un régénérateur (201), un absorbeur (203), un condenseur (202) et un évaporateur (204) de l'unité de réfrigération par absorption (100, 501, 502, 503, 504, 505, 506) sont tous des échangeurs de chaleur à enveloppe et faisceau de tubes (300), comprenant un côté enveloppe qui est constitué de boitiers d'échangeur de chaleur à enveloppe et faisceau de tubes (322), et un côté de tube qui est constitué de tubes d'échange de chaleur (310) dans les boîtiers d'échangeur de chaleur à enveloppe et faisceau de tubes (322); les tubes d'échange de chaleur (310) sont en plastique. Un échangeur de chaleur à solution (135) de l'unité de réfrigération par absorption (100, 501, 50 50 504, 505, 506) est un échangeur de chaleur à plaques, comprenant un boîtier d'échangeur de chaleur à plaques (424) et un panneau mural d'échange de chaleur (420); le panneau mural d'échange de chaleur (420) est fixé dans le boîtier d'échangeur de chaleur à plaques (424) et est en plastique. Le poids total de l'unité de réfrigération par absorption est réduit, et l'unité de réfrigération par absorption est capable d'empêcher la génération de gaz non condensable et d'améliorer les performances d'étanchéité.
PCT/CN2016/112148 2016-10-18 2016-12-26 Unité de réfrigération par absorption et matrice de réfrigération par absorption WO2018072314A1 (fr)

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JP2012141101A (ja) * 2010-12-29 2012-07-26 Makoto Izumi 吸収式冷凍機
CN105849476A (zh) * 2013-10-21 2016-08-10 索拉尔弗罗斯特实验室有限公司 呈板设计的调节吸收式制冷机
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