US20250377175A1 - Shell-and-plate heat exchanger and refrigeration apparatus - Google Patents

Shell-and-plate heat exchanger and refrigeration apparatus

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Publication number
US20250377175A1
US20250377175A1 US19/300,487 US202519300487A US2025377175A1 US 20250377175 A1 US20250377175 A1 US 20250377175A1 US 202519300487 A US202519300487 A US 202519300487A US 2025377175 A1 US2025377175 A1 US 2025377175A1
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US
United States
Prior art keywords
refrigerant
plate
partition plate
shell
channel
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
Application number
US19/300,487
Other languages
English (en)
Inventor
Daichi UTSUMI
Masaki Yamaguchi
Mitsuharu Numata
Shuhei ICHIMURA
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Daikin Industries Ltd
Original Assignee
Daikin Industries Ltd
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Daikin Industries Ltd filed Critical Daikin Industries Ltd
Publication of US20250377175A1 publication Critical patent/US20250377175A1/en
Pending legal-status Critical Current

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Classifications

    • 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
    • F28D9/0006Heat-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 the plate-like or laminated conduits being enclosed within a pressure vessel
    • 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
    • F28F9/02Header boxes; End plates
    • F28F9/0202Header boxes having their inner space divided by partitions
    • F28F9/0204Header boxes having their inner space divided by partitions for elongated header box, e.g. with transversal and longitudinal partitions
    • F28F9/0214Header boxes having their inner space divided by partitions for elongated header box, e.g. with transversal and longitudinal partitions having only longitudinal partitions
    • 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
    • F25B39/00Evaporators; Condensers
    • F25B39/02Evaporators
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F13/00Arrangements for modifying heat-transfer, e.g. increasing, decreasing
    • F28F13/06Arrangements for modifying heat-transfer, e.g. increasing, decreasing by affecting the pattern of flow of the heat-exchange media
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F3/00Plate-like or laminated elements; Assemblies of plate-like or laminated elements
    • F28F3/08Elements constructed for building-up into stacks, e.g. capable of being taken apart for cleaning
    • 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
    • F25B2339/00Details of evaporators; Details of condensers
    • F25B2339/02Details of evaporators
    • F25B2339/024Evaporators with refrigerant in a vessel in which is situated a heat exchanger
    • 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
    • F25B2339/00Details of evaporators; Details of condensers
    • F25B2339/02Details of evaporators
    • F25B2339/024Evaporators with refrigerant in a vessel in which is situated a heat exchanger
    • F25B2339/0241Evaporators with refrigerant in a vessel in which is situated a heat exchanger having plate-like elements
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F2210/00Heat exchange conduits
    • F28F2210/10Particular layout, e.g. for uniform temperature distribution

Definitions

  • the present disclosure relates to a shell-and-plate heat exchanger and a refrigeration apparatus.
  • Japanese Unexamined Patent Publication No. 2017-072343 discloses an evaporator including a pressure container into which a refrigerant flows, a plurality of heat transfer tube support plates spaced apart from one another along the longitudinal axis of the pressure container, and a group of heat transfer tubes installed to penetrate the plurality of heat transfer tube support plates.
  • a first aspect of the present disclosure is directed to a shell-and-plate heat exchanger, including: a shell having an internal space; and a plate stack housed in the internal space and including a plurality of heat transfer plates stacked and joined together, the shell-and-plate heat exchanger causing heat exchange between a refrigerant that has flowed into the internal space of the shell and a heating medium that has flowed into a heating medium channel of the plate stack, the shell-and-plate heat exchanger further including: a refrigerant inlet provided in a lower portion of the shell and allowing the refrigerant to flow into the internal space; and a partitioning member arranged between the plate stack and the refrigerant inlet, the partitioning member extending along a first direction that is a stacking direction of the plate stack, wherein if the plate stack is assumed to be equally divided into three sections in the first direction, a section in the middle in the first direction is referred to as a central heat exchange section, a section closer to one end in the first direction than
  • FIG. 1 is a refrigerant circuit diagram showing a configuration of a refrigeration apparatus according to a first embodiment.
  • FIG. 2 is a cross-sectional side view showing a configuration of a shell-and-plate heat exchanger.
  • FIG. 3 is a cross-sectional front view showing the configuration of the shell-and-plate heat exchanger.
  • FIG. 4 is a cross-sectional side view showing a configuration of a plate stack.
  • FIG. 5 is a plan view showing a configuration of a partitioning member.
  • FIG. 6 is a cross-sectional view taken along line A-A in FIG. 2 and viewed in the direction of arrows.
  • FIG. 7 is a cross-sectional side view showing a configuration of a shell-and-plate heat exchanger according to a second embodiment.
  • FIG. 8 is a cross-sectional front view showing the configuration of the shell-and-plate heat exchanger.
  • FIG. 9 is a cross-sectional view taken along line B 1 -B 1 shown in FIG. 7 and viewed in the direction of arrows.
  • FIG. 10 is a cross-sectional view taken along line B 2 -B 2 shown in FIG. 7 and viewed in the direction of arrows.
  • FIG. 11 is a diagram of a partitioning member according to a variation of the second embodiment, and corresponds to FIG. 9 .
  • FIG. 12 is a diagram of the partitioning member according to the variation of the second embodiment, and corresponds to FIG. 10 .
  • FIG. 13 is a cross-sectional side view showing a configuration of a shell-and-plate heat exchanger according to a third embodiment.
  • FIG. 14 is a cross-sectional front view showing the configuration of the shell-and-plate heat exchanger.
  • FIG. 15 is a cross-sectional view taken along line C 1 -C 1 shown in FIG. 13 and viewed in the direction of arrows.
  • FIG. 16 is a cross-sectional view taken along line C 2 -C 2 shown in FIG. 13 and viewed in the direction of arrows.
  • FIG. 17 is a cross-sectional view taken along line C 3 -C 3 shown in FIG. 13 and viewed in the direction of arrows.
  • FIG. 18 is a cross-sectional side view showing a configuration of a shell-and-plate heat exchanger according to a fourth embodiment.
  • FIG. 19 is a cross-sectional front view showing the configuration of the shell-and-plate heat exchanger.
  • FIG. 20 is a cross-sectional view taken along line D-D shown in FIG. 18 and viewed in the direction of arrows.
  • FIG. 21 is a plan view showing a configuration of a partitioning member according to a fifth embodiment.
  • FIG. 22 is a cross-sectional plan view showing the position of a refrigerant inlet.
  • FIG. 23 is a plan view showing a configuration of a partitioning member according to a sixth embodiment.
  • FIG. 24 is a cross-sectional plan view showing the position of a refrigerant inlet.
  • FIG. 25 is a plan view showing a configuration of a partitioning member according to a seventh embodiment.
  • FIG. 26 is a cross-sectional plan view showing the position of a refrigerant inlet.
  • FIG. 27 is a plan view showing a configuration of a partitioning member according to an eighth embodiment.
  • FIG. 28 is a cross-sectional plan view showing the position of a refrigerant inlet.
  • FIG. 29 is a plan view showing a configuration of a partitioning member according to a ninth embodiment.
  • a shell-and-plate heat exchanger ( 10 ) (will be hereinafter “referred to as a heat exchanger”) is provided in a refrigeration apparatus ( 1 ).
  • the refrigeration apparatus ( 1 ) includes a refrigerant circuit (la) filled with a refrigerant.
  • the refrigerant circuit (la) includes a compressor ( 2 ), a radiator ( 3 ), a decompression mechanism ( 4 ), and the heat exchanger ( 10 ) serving as an evaporator.
  • the decompression mechanism ( 4 ) is, for example, an expansion valve.
  • the refrigerant circuit (la) performs a vapor compression refrigeration cycle.
  • the refrigeration apparatus ( 1 ) is an air conditioner.
  • the air conditioner may be any of a cooling-only apparatus, a heating-only apparatus, or an air conditioner switchable between cooling and heating.
  • the air conditioner has a switching mechanism (e.g., a four-way switching valve) configured to switch the direction of circulation of the refrigerant.
  • the refrigeration apparatus ( 1 ) may be a water heater, a chiller unit, or a cooling apparatus configured to cool air in an internal space.
  • the cooling apparatus cools the air in an internal space of a refrigerator, a freezer, a container, or the like.
  • the heat exchanger ( 10 ) includes a shell ( 11 ) and a plate stack ( 30 ).
  • the plate stack ( 30 ) is housed in an internal space ( 15 ) of the shell ( 11 ).
  • the refrigerant flows into the internal space ( 15 ) of the shell ( 11 ).
  • the refrigerant includes a gas refrigerant and a liquid refrigerant.
  • the refrigerant exchanges heat with a heating medium flowing in the plate stack ( 30 ).
  • the heat exchanger ( 10 ) allows the refrigerant that has flowed into the internal space ( 15 ) of the shell ( 11 ) to evaporate, and thus, functions as an evaporator.
  • Examples of the heating medium used include water and brine.
  • the shell ( 11 ) includes a cylindrical body ( 12 ), a first closing member ( 13 ), and a second closing member ( 14 ).
  • the cylindrical body ( 12 ) is a circular cylindrical member extending in a horizontal direction and having openings on both axial ends.
  • the first closing member ( 13 ) is a disk-shaped member.
  • the first closing member ( 13 ) closes an opening on one end (the left end in FIG. 2 ) of the cylindrical body ( 12 ).
  • the first closing member ( 13 ) is attached to the cylindrical body ( 12 ) by welding.
  • the second closing member ( 14 ) is a disk-shaped member.
  • the second closing member ( 14 ) closes an opening on the other end (the right end in FIG. 2 ) of the cylindrical body ( 12 ).
  • the second closing member ( 14 ) is attached to the cylindrical body ( 12 ) by welding.
  • the shell ( 11 ) has the internal space ( 15 ) defined by the cylindrical body ( 12 ), the first closing member ( 13 ), and the second closing member ( 14 ).
  • the internal space ( 15 ) stores therein the liquid refrigerant.
  • the plate stack ( 30 ) is housed in the internal space ( 15 ).
  • the cylindrical body ( 12 ) is provided with a refrigerant inlet ( 21 ) and a refrigerant outlet ( 22 ).
  • the refrigerant inlet ( 21 ) is formed at the bottom of the cylindrical body ( 12 ).
  • the refrigerant is introduced into the internal space ( 15 ) through the refrigerant inlet ( 21 ).
  • the refrigerant inlet ( 21 ) is formed in a lower portion of the shell ( 11 ) at a central position in the stacking direction of the plate stack ( 30 ).
  • the refrigerant outlet ( 22 ) is formed at the top of the cylindrical body ( 12 ).
  • the refrigerant evaporated in the internal space ( 15 ) is emitted out of the shell ( 11 ) through the refrigerant outlet ( 22 ).
  • the refrigerant inlet ( 21 ) and the refrigerant outlet ( 22 ) are connected to the refrigerant circuit (la).
  • the first closing member ( 13 ) is provided with a heating medium inlet ( 23 ) and a heating medium outlet ( 24 ).
  • the heating medium inlet ( 23 ) and the heating medium outlet ( 24 ) are tubular members.
  • the heating medium inlet ( 23 ) penetrates the first closing member ( 13 ).
  • the heating medium inlet ( 23 ) is connected to a heating medium introduction path ( 33 ) of the plate stack ( 30 ).
  • the heating medium inlet ( 23 ) supplies the heating medium to the plate stack ( 30 ).
  • the refrigerant that has flowed into the internal space ( 15 ) of the shell ( 11 ) exchanges heat with the heating medium that has flowed into heating medium channels ( 32 ), which will be described later, of the plate stack ( 30 ).
  • the heating medium outlet ( 24 ) penetrates the first closing member ( 13 ) above the heating medium inlet ( 23 ).
  • the heating medium outlet ( 24 ) is connected to a heating medium emission path ( 34 ) of the plate stack ( 30 ).
  • the heating medium outlet ( 24 ) emits the heating medium out of the plate stack ( 30 ).
  • the plate stack ( 30 ) includes a plurality of heat transfer plates ( 40 ) stacked and joined together.
  • the plate stack ( 30 ) is housed in the internal space ( 15 ) of the shell ( 11 ) in a posture in which the stacking direction of the heat transfer plates ( 40 ) is the lateral direction.
  • the stacking direction of the plate stack ( 30 ) will be referred to as a “first direction.”
  • the heat transfer plates ( 40 ) include first plates ( 40 a ) and second plates ( 40 b ).
  • the first plates ( 40 a ) and the second plates ( 40 b ) are alternately stacked to form the plate stack ( 30 ).
  • a surface on the left side in FIG. 4 will be referred to as a “front surface,” and a surface on the right side in FIG. 5 will be referred to as a “back surface.”
  • Each of the first plates ( 40 a ) has an inlet protrusion ( 41 a ) and an outlet protrusion ( 43 a ).
  • the inlet protrusion ( 41 a ) and the outlet protrusion ( 43 a ) are portions of the first plate ( 40 a ) bulged toward the front surface.
  • the inlet protrusion ( 41 a ) is formed in a lower portion of the first plate ( 40 a ).
  • a first inlet hole ( 42 a ) is formed in a center portion of the inlet protrusion ( 41 a ).
  • the first inlet hole ( 42 a ) is a circular hole penetrating the first plate ( 40 a ) in a thickness direction.
  • the outlet protrusion ( 43 a ) is formed in an upper portion of the first plate ( 40 a ).
  • a first outlet hole ( 44 a ) is formed in a center portion of the outlet protrusion ( 43 a ).
  • the first outlet hole ( 44 a ) is a circular hole penetrating the first plate ( 40 a ) in the thickness direction.
  • Each of the second plates ( 40 b ) has an inlet recess ( 41 b ) and an outlet recess ( 43 b ).
  • the inlet recess ( 41 b ) and the outlet recess ( 43 b ) are portions of the second plate ( 40 b ) bulged toward the back surface.
  • the inlet recess ( 41 b ) is formed in a lower portion of the second plate ( 40 b ).
  • a second inlet hole ( 42 b ) is formed in a center portion of the inlet recess ( 41 b ).
  • the second inlet hole ( 42 b ) is a circular hole penetrating the second plate ( 40 b ) in the thickness direction.
  • the inlet recess ( 41 b ) is positioned to face the inlet protrusion ( 41 a ) of the first plate ( 40 a ).
  • the second inlet hole ( 42 b ) is positioned to face the first inlet hole ( 42 a ) of the first plate ( 40 a ).
  • the outlet recess ( 43 b ) is formed in an upper portion of the second plate ( 40 b ).
  • a second outlet hole ( 44 b ) is formed in a center portion of the outlet recess ( 43 b ).
  • the second outlet hole ( 44 b ) is a circular hole penetrating the second plate ( 40 b ) in the thickness direction.
  • the outlet recess ( 43 b ) is positioned to face the outlet protrusion ( 43 a ) of the first plate ( 40 a ).
  • the second outlet hole ( 44 b ) is positioned to face the first outlet hole ( 44 a ) of the first plate ( 40 a ).
  • each first plate ( 40 a ) and an adjacent one of the second plates ( 40 b ) on the back side of the first plate ( 40 a ) are welded together at their peripheral portions along the entire perimeter. These plates may be brazed together.
  • the first inlet hole ( 42 a ) of each first plate ( 40 a ) overlaps the second inlet hole ( 42 b ) of an adjacent one of the second plates ( 40 b ) on the front side of the first plate ( 40 a ).
  • the rims of the overlapping first inlet hole ( 42 a ) and second inlet hole ( 42 b ) are welded together along the entire perimeter. These rims may be brazed together.
  • the first inlet hole ( 42 a ) and the second inlet hole ( 42 b ) communicate with the heating medium channels ( 32 ), which will be described later, to introduce the heating medium into the heating medium channels ( 32 ).
  • the first outlet hole ( 44 a ) of each first plate ( 40 a ) overlaps the second outlet hole ( 44 b ) of an adjacent one of the second plates ( 40 b ) on the front side of the first plate ( 40 a ).
  • the rims of the overlapping first outlet hole ( 44 a ) and second outlet hole ( 44 b ) are welded together along the entire perimeter. These rims may be brazed together.
  • the first outlet hole ( 44 a ) and the second outlet hole ( 44 b ) communicate with the heating medium channels ( 32 ), which will be described later, to emit the heating medium out of the heating medium channels ( 32 ).
  • the inlet protrusions ( 41 a ) and first inlet holes ( 42 a ) of the first plates ( 40 a ) and the inlet recesses ( 41 b ) and second inlet holes ( 42 b ) of the second plates ( 40 b ) form the heating medium introduction path ( 33 ).
  • the outlet protrusions ( 43 a ) and first outlet holes ( 44 a ) of the first plates ( 40 a ) and the outlet recesses ( 43 b ) and second outlet holes ( 44 b ) of the second plates ( 40 b ) form the heating medium emission path ( 34 ).
  • the heating medium introduction path ( 33 ) is a passage extending in the stacking direction of the heat transfer plates ( 40 ) in the plate stack ( 30 ).
  • the heating medium introduction path ( 33 ) is a passage blocked from the internal space ( 15 ) of the shell ( 11 ), and allows all the heating medium channels ( 32 ) to communicate with the heating medium inlet ( 23 ).
  • the heating medium emission path ( 34 ) is a passage extending in the stacking direction of the heat transfer plates ( 40 ) in the plate stack ( 30 ).
  • the heating medium emission path ( 34 ) is a passage blocked from the internal space ( 15 ) of the shell ( 11 ), and allows all the heating medium channels ( 32 ) to communicate with the heating medium outlet ( 24 ).
  • the plate stack ( 30 ) includes a refrigerant channel ( 31 ) and a heating medium channel ( 32 ).
  • the refrigerant channel ( 31 ) and the heating medium channel ( 32 ) are formed with a heat transfer plate ( 40 ) interposed therebetween, and include a plurality of refrigerant channels ( 31 ) and a plurality of heating medium channels ( 32 ).
  • the heat transfer plate ( 40 ) separates the refrigerant channel ( 31 ) and the heating medium channel ( 32 ) from each other.
  • Each of the first plate ( 40 a ) and the second plate ( 40 b ) includes repetition of long and narrow ridges and grooves.
  • Each first plate ( 40 a ) includes first front-side protrusions ( 45 a ) and first back-side protrusions ( 47 a ) alternately arranged.
  • the first front-side protrusions ( 45 a ) bulge toward the front side of the first plate ( 40 a ).
  • the first back-side protrusions ( 47 a ) bulge toward the back side of the first plate ( 40 a ).
  • Each second plate ( 40 b ) includes second front-side protrusions ( 47 b ) and second back-side protrusions ( 45 b ) alternately arranged.
  • the second front-side protrusions ( 47 b ) bulge toward the front side of the second plate ( 40 b ).
  • the second back-side protrusions ( 45 b ) bulge toward the back side of the second plate ( 40 b ).
  • Each of the refrigerant channels ( 31 ) is a channel sandwiched between the front surface of the first plate ( 40 a ) and the back surface of the second plate ( 40 b ).
  • the refrigerant channel ( 31 ) is a channel that communicates with the internal space ( 15 ) of the shell ( 11 ) and allows the refrigerant to flow therethrough.
  • each refrigerant channel ( 31 ) includes channels formed between the front surfaces of the first back-side protrusions ( 47 a ) and the back surfaces of the second front-side protrusions ( 47 b ), and spaces formed between the first front-side protrusions ( 45 a ) and the second back-side protrusions ( 45 b ).
  • Each of the heating medium channels ( 32 ) is a channel sandwiched between the back surface of the first plate ( 40 a ) and the front surface of the second plate ( 40 b ).
  • the heating medium channel ( 32 ) is a channel blocked from the internal space ( 15 ) of the shell ( 11 ) and allows the heating medium to flow therethrough.
  • each heating medium channel ( 32 ) includes channels formed between the back surfaces of the first front-side protrusions ( 45 a ) and the front surfaces of the second back-side protrusions ( 45 b ), and spaces formed between the first back-side protrusions ( 47 a ) and the second front-side protrusions ( 47 b ).
  • the heating medium flows from the heating medium inlet ( 23 ) into the heating medium introduction path ( 33 ).
  • the heating medium flowing through the heating medium introduction path ( 33 ) flows from the first inlet holes ( 42 a ) and the second inlet holes ( 42 b ) toward the first outlet holes ( 44 a ) and the second outlet holes ( 44 b ) through the heating medium channels ( 32 ).
  • the heating medium flowing through the heating medium introduction path ( 33 ) enters the heating medium channel ( 32 ).
  • the heating medium flows along the heating medium channel ( 32 ), passes through the space formed between the first back-side protrusion ( 47 a ) and the second front-side protrusion ( 47 b ), and enters an adjacent heating medium channel ( 32 ) above the heating medium channel ( 32 ). In this manner, the heating medium flows upward while flowing from one end to the other of the heat transfer plate ( 40 ).
  • the liquid refrigerant flows into the internal space ( 15 ) of the shell ( 11 ) through the refrigerant inlet ( 21 ).
  • the liquid refrigerant stored in the internal space ( 15 ) reaches close to the upper end of the plate stack ( 30 ).
  • the plate stack ( 30 ) is immersed in the liquid refrigerant.
  • the refrigerant stored in the internal space ( 15 ) has a relatively low pressure.
  • the low-pressure refrigerant exchanges heat with the heating medium flowing through the heating medium channels ( 32 ).
  • the refrigerant channel ( 31 ) and the heating medium channel ( 32 ) are adjacent to each other with the heat transfer plate ( 40 ) interposed therebetween.
  • the liquid refrigerant absorbs heat from the heating medium flowing through the heating medium channel ( 32 ) and evaporates.
  • the evaporated refrigerant moves from the refrigerant channel ( 31 ) further upward from the plate stack ( 30 ).
  • the evaporated refrigerant flows out through the refrigerant outlet ( 22 ) into the refrigerant circuit.
  • the shell-and-plate heat exchanger ( 10 ) of this embodiment includes the plate stack ( 30 ) that includes the plurality of heat transfer plates ( 40 ) stacked and joined together. Thus, the refrigerant flowing between the plurality of heat transfer plates ( 40 ) cannot flow in the stacking direction.
  • the heat exchange efficiency of the plate stack ( 30 ) as a whole can be increased.
  • a section in the middle in the stacking direction is referred to as a “central heat exchange section ( 35 )”; a section closer to one end (the left end in FIG. 2 ) in the stacking direction than the central heat exchange section ( 35 ) is referred to as a “first heat exchange section ( 36 )”; and a section closer to the other end (the right end in FIG. 2 ) in the stacking direction than the central heat exchange section ( 35 ) is referred to as a “second heat exchange section ( 37 ).”
  • the heat exchanger ( 10 ) includes a partitioning member ( 5 ).
  • the partitioning member ( 5 ) reduces a variation between the ratio between the liquid refrigerant and the gas refrigerant contained in the refrigerant made to exchange heat in the central heat exchange section ( 35 ) and the ratio between the liquid refrigerant and the gas refrigerant contained in the refrigerant made to exchange heat in each of the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ).
  • the partitioning member ( 5 ) is disposed below the plate stack ( 30 ).
  • the partitioning member ( 5 ) includes a first partition plate ( 61 ), a pair of guide plates ( 52 ), and first sidewall portions ( 63 ).
  • the first partition plate ( 61 ) serves as a partition between the plate stack ( 30 ) and the refrigerant inlet ( 21 ).
  • the first partition plate ( 61 ) extends along the stacking direction of the plate stack ( 30 ) between the first closing member ( 13 ) and the second closing member ( 14 ) in the internal space ( 15 ) of the shell ( 11 ).
  • the stacking direction of the plate stack ( 30 ) is hereinafter referred to as a “first direction” (the lateral direction in FIG. 2 ), and the width direction of the first partition plate ( 61 ) orthogonal to the first direction is hereinafter referred to as a “second direction” (the lateral direction in FIG. 3 ).
  • the first sidewall portions ( 63 ) are edge portions of the first partition plate ( 61 ) in the second direction which are bent to incline downward. Both ends of the first sidewall portions ( 63 ) in the second direction are in contact with the inner peripheral surface of the cylindrical body ( 12 ) of the shell ( 11 ).
  • the partitioning member ( 5 ) forms an internal channel ( 55 ).
  • the internal channel ( 55 ) extends along the stacking direction of the plate stack ( 30 ).
  • the refrigerant that has flowed into the internal channel ( 55 ) from the refrigerant inlet ( 21 ) flows through the internal channel ( 55 ).
  • the internal channel ( 55 ) is formed in a space surrounded by the first partition plate ( 61 ), the first sidewall portions ( 63 ), the cylindrical body ( 12 ), the first closing member ( 13 ), and the second closing member ( 14 ).
  • the pair of guide plates ( 52 ) are provided on a lower portion of the first partition plate ( 61 ).
  • the pair of guide plates ( 52 ) are spaced apart from each other in the second direction and extend along the stacking direction of the plate stack ( 30 ). Both ends of each of the pair of guide plates ( 52 ) in the first direction are located inward of both ends of the first partition plate ( 61 ) in the first direction (see FIG. 5 ). Thus, a gap is formed between the left end portion of the guide plate ( 52 ) and the first closing member ( 13 ), and between the right end portion of the guide plate ( 52 ) and the second closing member ( 14 ).
  • the pair of guide plates ( 52 ) are inclined such that the closer to the downside, the closer to the outside of the first partition plate ( 61 ) in the second direction to be away from each other.
  • the pair of guide plates ( 52 ) each have a lower end in contact with the inner peripheral surface of the cylindrical body ( 12 ) of the shell ( 11 ).
  • the internal channel ( 55 ) includes a first channel ( 56 ) and second channels ( 57 ).
  • the first channel ( 56 ) is a space formed between the pair of guide plates ( 52 ).
  • the first channel ( 56 ) guides the refrigerant that has flowed therein from the refrigerant inlet ( 21 ) to spaces under the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ).
  • the second channels ( 57 ) are spaces each formed between the guide plate ( 52 ) and the associated first sidewall portion ( 63 ), which is a bent portion of the first partition plate ( 61 ) on each end in the second direction.
  • the second channels ( 57 ) guide the refrigerant that has turned back at ends of the first channel ( 56 ) in the first direction and passed through the first channel ( 56 ) to a space under the central heat exchange section ( 35 ).
  • the partitioning member ( 5 ) has first communication holes ( 58 ) and second communication holes ( 59 ).
  • the first communication holes ( 58 ) and the second communication holes ( 59 ) are formed in the first partition plate ( 61 ).
  • the first communication holes ( 58 ) communicate with the first channel ( 56 ) and are open toward the plate stack ( 30 ).
  • the plurality of first communication holes ( 58 ) are spaced apart from one another in the first direction and in the second direction in the first partition plate ( 61 ).
  • the first communication holes ( 58 ) discharge the gas refrigerant contained in the refrigerant flowing through the first channel ( 56 ).
  • the second communication holes ( 59 ) communicate with the second channels ( 57 ) and are open toward the plate stack ( 30 ).
  • the plurality of second communication holes ( 59 ) are spaced apart from one another in the first direction in the first partition plate ( 61 ).
  • the second communication holes ( 59 ) discharge the liquid refrigerant contained in the refrigerant flowing through the second channels ( 57 ).
  • the refrigerant that has flowed into the internal space ( 15 ) of the shell ( 11 ) through the refrigerant inlet ( 21 ) passes through the first channel ( 56 ) in the partitioning member ( 5 ) and flows along the first direction. It is thus possible to distribute the refrigerant among the central heat exchange section ( 35 ), the first heat exchange section ( 36 ), and the second heat exchange section ( 37 ) in the plate stack ( 30 ).
  • the variation between the degree of dryness of the refrigerant made to exchange heat in the central heat exchange section ( 35 ) and the degree of dryness of the refrigerant made to exchange heat in each of the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ) is 70% or less, particularly 40% or less.
  • the variation between the mass flow rate of the liquid refrigerant made to exchange heat in the central heat exchange section ( 35 ) and the mass flow rate of the liquid refrigerant made to exchange heat in each of the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ) is 30% or less, particularly 20% or less.
  • the partitioning member ( 5 ) reduces variations in the amount of the refrigerant flowing in the stacking direction of the plate stack ( 30 ), thereby making it possible to increase the heat exchange efficiency of the plate stack ( 30 ) as a whole.
  • the first channel ( 56 ) guides the refrigerant that has flowed in through the refrigerant inlet ( 21 ) to the spaces under the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ), and the refrigerant that has passed through the first channel ( 56 ) is guided to the space under the central heat exchange section ( 35 ). It is thus possible to reduce variations in the amount of the refrigerant flowing in the stacking direction of the plate stack ( 30 ).
  • appropriately setting the degree of dryness of the refrigerant and the mass flow rate of the liquid refrigerant in the stacking direction of the plate stack ( 30 ) can increase the heat exchange efficiency of the plate stack ( 30 ) as a whole.
  • providing the refrigerant inlet ( 21 ) at a central position in the first direction makes it possible to distribute the refrigerant that has flowed into the internal space ( 15 ) through the refrigerant inlet ( 21 ) uniformly toward both ends in the first direction.
  • a refrigeration apparatus includes: the shell-and-plate heat exchanger ( 10 ); and the refrigerant circuit (la) through which the refrigerant to exchange heat in the shell-and-plate heat exchanger ( 10 ) flows. It is thus possible to provide a refrigeration apparatus including the shell-and-plate heat exchanger ( 10 ).
  • a heat exchanger ( 10 ) includes a partitioning member ( 5 ).
  • the partitioning member ( 5 ) reduces a variation between the ratio between the liquid refrigerant and the gas refrigerant contained in the refrigerant made to exchange heat in the central heat exchange section ( 35 ) and the ratio between the liquid refrigerant and the gas refrigerant contained in the refrigerant made to exchange heat in each of the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ).
  • the partitioning member ( 5 ) is disposed below the plate stack ( 30 ).
  • the partitioning member ( 5 ) includes a first partition plate ( 61 ), a second partition plate ( 62 ), and a first sidewall portion ( 63 ).
  • the first partition plate ( 61 ) extends along the first direction.
  • the second partition plate ( 62 ) is disposed below the first partition plate ( 61 ) and extends along the first direction.
  • the first sidewall portion ( 63 ) extends along peripheral portions of the first partition plate ( 61 ) and the second partition plate ( 62 ), and couples the first partition plate ( 61 ) and the second partition plate ( 62 ) together.
  • the partitioning member ( 5 ) is a box-shaped member with an internal channel ( 55 ).
  • the partitioning member ( 5 ) extends along the first direction between the first closing member ( 13 ) and the second closing member ( 14 ) in the internal space ( 15 ) of the shell ( 11 ).
  • a downstream end of the refrigerant inlet ( 21 ) is connected to the second partition plate ( 62 ).
  • the refrigerant inlet ( 21 ) is disposed below the central heat exchange section ( 35 ) of the plate stack ( 30 ).
  • the internal channel ( 55 ) guides the refrigerant that has flowed into a space under the central heat exchange section ( 35 ) from the refrigerant inlet ( 21 ) to a space under each of the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ).
  • the partitioning member ( 5 ) has first communication holes ( 68 ) and second communication holes ( 69 ).
  • the first communication holes ( 68 ) are formed in the first partition plate ( 61 ).
  • the second communication holes ( 69 ) are formed in the second partition plate ( 62 ).
  • the first communication holes ( 68 ) communicate with the internal channel ( 55 ) and are open toward the plate stack ( 30 ).
  • the plurality of first communication holes ( 68 ) are spaced apart from one another in the first direction and in the second direction in the first partition plate ( 61 ) (see FIG. 9 ).
  • the first communication holes ( 68 ) discharge the gas refrigerant contained in the refrigerant flowing through the internal channel ( 55 ).
  • the pitch of the first communication holes ( 68 ) arranged in the first direction is changed as appropriate. Specifically, the pitch (P1) between the first communication holes ( 68 ) adjacent to each other near the refrigerant inlet ( 21 ) is set to be greater than the pitch (P2) between the first communication holes ( 68 ) adjacent to each other at end portions in the first direction.
  • Such a configuration makes it easier for the refrigerant to be discharged from end portions of the internal channel ( 55 ) in the first direction. It is thus possible to reduce the likelihood that most of the gas refrigerant that has flowed into the internal channel ( 55 ) from the refrigerant inlet ( 21 ) is discharged toward the central heat exchange section ( 35 ), and it becomes easier to distribute the refrigerant to the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ) as well.
  • the second communication holes ( 69 ) communicate with the internal channel ( 55 ) and are open in a direction opposite to the plate stack ( 30 ).
  • the plurality of second communication holes ( 69 ) are spaced apart from one another in the first direction and in the second direction in the second partition plate ( 62 ) (see FIG. 10 ).
  • the second communication holes ( 69 ) discharge the liquid refrigerant contained in the refrigerant flowing through the internal channel ( 55 ).
  • the pitch of the second communication holes ( 69 ) arranged in the first direction is changed as appropriate. Specifically, the pitch (P1) between the second communication holes ( 69 ) adjacent to each other near the refrigerant inlet ( 21 ) is set to be greater than the pitch (P2) between the second communication holes ( 69 ) adjacent to each other at end portions in the first direction.
  • Such a configuration makes it easier for the refrigerant to be discharged from end portions of the internal channel ( 55 ) in the first direction. It is thus possible to reduce the likelihood that most of the liquid refrigerant that has flowed into the internal channel ( 55 ) from the refrigerant inlet ( 21 ) is discharged toward the central heat exchange section ( 35 ), and it becomes easier to distribute the refrigerant to the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ) as well.
  • the refrigerant heading toward the partitioning member ( 5 ) from the refrigerant inlet ( 21 ) passes through the internal channel ( 55 ) in the partitioning member ( 5 ) and flows along the first direction. It is thus possible to distribute the refrigerant among the central heat exchange section ( 35 ), the first heat exchange section ( 36 ), and the second heat exchange section ( 37 ) in the plate stack ( 30 ).
  • the internal channel ( 55 ) guides the refrigerant that has flowed in from the refrigerant inlet ( 21 ) to the spaces under the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ) and causes the gas refrigerant to flow out through the first communication holes ( 68 ) and the liquid refrigerant to flow out through the second communication holes ( 69 ). It is thus possible to reduce variations in the amount of the refrigerant flowing in the stacking direction of the plate stack ( 30 ).
  • the first communication holes ( 68 ) are arranged at equal pitches in the first direction. Specifically, the pitch (P1) between the first communication holes ( 68 ) adjacent to each other near the refrigerant inlet ( 21 ) is set to be equal to the pitch (P2) between the first communication holes ( 68 ) adjacent to each other at end portions in the first direction.
  • the diameters of the first communication holes ( 68 ) arranged in the first direction are changed as appropriate. Specifically, the first communication holes ( 68 ) at the end portions in the first direction each have a diameter d2 that is greater than the diameter d1 of the first communication hole ( 68 ) near the refrigerant inlet ( 21 ).
  • the diameter d1 of the communication holes ( 50 ) at positions closest to the refrigerant inlet ( 21 ) and the diameter d2 of the communication holes ( 50 ) at positions farthest from the refrigerant inlet ( 21 ) are set to satisfy the condition “d1 ⁇ d2.”
  • Such a configuration makes it easier for the refrigerant to be discharged from end portions of the internal channel ( 55 ) in the first direction. It is thus possible to reduce the likelihood that most of the gas refrigerant that has flowed into the internal channel ( 55 ) from the refrigerant inlet ( 21 ) is discharged toward the central heat exchange section ( 35 ), and it becomes easier to distribute the refrigerant to the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ) as well.
  • the second communication holes ( 69 ) are arranged at equal pitches in the first direction. Specifically, the pitch (P1) between the second communication holes ( 69 ) adjacent to each other near the refrigerant inlet ( 21 ) is set to be equal to the pitch (P2) between the second communication holes ( 69 ) adjacent to each other at end portions in the first direction.
  • the diameters of the second communication holes ( 69 ) arranged in the first direction are changed as appropriate. Specifically, the second communication holes ( 69 ) at the end portions in the first direction each have a diameter d2 that is greater than the diameter d1 of the second communication holes ( 69 ) near the refrigerant inlet ( 21 ).
  • Such a configuration makes it easier for the refrigerant to be discharged from end portions of the internal channel ( 55 ) in the first direction. It is thus possible to reduce the likelihood that most of the liquid refrigerant that has flowed into the internal channel ( 55 ) from the refrigerant inlet ( 21 ) is discharged toward the central heat exchange section ( 35 ), and it becomes easier to distribute the refrigerant to the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ) as well.
  • a heat exchanger ( 10 ) includes a partitioning member ( 5 ).
  • the partitioning member ( 5 ) reduces a variation between the ratio between the liquid refrigerant and the gas refrigerant contained in the refrigerant made to exchange heat in the central heat exchange section ( 35 ) and the ratio between the liquid refrigerant and the gas refrigerant contained in the refrigerant made to exchange heat in each of the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ).
  • the partitioning member ( 5 ) is disposed below the plate stack ( 30 ).
  • the partitioning member ( 5 ) has an internal channel ( 55 ) through which the refrigerant that has flowed in from the refrigerant inlet ( 21 ) flows.
  • the partitioning member ( 5 ) includes a first partition plate ( 61 ), a second partition plate ( 62 ), a first sidewall portion ( 63 ), and a second sidewall portion ( 64 ).
  • the internal channel ( 55 ) includes an upper channel ( 76 ) and a lower channel ( 77 ).
  • the first partition plate ( 61 ) extends along the first direction.
  • the second partition plate ( 62 ) is disposed below the first partition plate ( 61 ) and extends along the first direction.
  • the first sidewall portion ( 63 ) extends along peripheral portions of the first partition plate ( 61 ) and the second partition plate ( 62 ), and couples the first partition plate ( 61 ) and the second partition plate ( 62 ) together.
  • the second sidewall portion ( 64 ) extends downward from the peripheral portions of the second partition plate ( 62 ). A lower end portion of the second sidewall portion ( 64 ) is in contact with the inner peripheral surface of the cylindrical body ( 12 ) of the shell ( 11 ).
  • the upper channel ( 76 ) is formed by the first partition plate ( 61 ), the second partition plate ( 62 ), and the first sidewall portion ( 63 ).
  • the lower channel ( 77 ) is formed by the second partition plate ( 62 ), the second sidewall portion ( 64 ), and the cylindrical body ( 12 ).
  • the refrigerant inlet ( 21 ) communicates with the lower channel ( 77 ).
  • the refrigerant that has flowed into the lower channel ( 77 ) from the refrigerant inlet ( 21 ) flows through the lower channel ( 77 ).
  • the refrigerant inlet ( 21 ) is formed in a lower portion of the shell ( 11 ) at a central position in the stacking direction of the plate stack ( 30 ).
  • the partitioning member ( 5 ) has upper communication holes ( 78 ) and lower communication holes ( 79 ).
  • the upper communication holes ( 78 ) are formed in the first partition plate ( 61 ).
  • the lower communication holes ( 79 ) are formed in the second partition plate ( 62 ).
  • the upper communication holes ( 78 ) communicate with the upper channel ( 76 ) and are open toward the plate stack ( 30 ).
  • the plurality of upper communication holes ( 78 ) are spaced apart from one another in the first direction and in the second direction in the first partition plate ( 61 ) (see FIG. 15 ).
  • the upper communication holes ( 78 ) discharge the refrigerant flowing through the upper channel ( 76 ).
  • the lower communication holes ( 79 ) allow the lower channel ( 77 ) and the upper channel ( 76 ) to communicate with each other.
  • the plurality of lower communication holes ( 79 ) are spaced apart from one another in the first direction and in the second direction in the second partition plate ( 62 ) (see FIG. 16 ).
  • the number of lower communication holes ( 79 ) is less than the number of the upper communication holes ( 78 ).
  • the lower communication holes ( 79 ) are open at positions away from the refrigerant inlet ( 21 ).
  • the lower communication holes ( 79 ) discharge the refrigerant flowing through the lower channel ( 77 ) to the upper channel ( 76 ).
  • the refrigerant that has flowed into the lower channel ( 77 ) from the refrigerant inlet ( 21 ) flows through the lower channel ( 77 ).
  • the lower channel ( 77 ) guides the refrigerant that has flowed into a space under the central heat exchange section ( 35 ) from the refrigerant inlet ( 21 ) to a space under each of the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ).
  • the refrigerant that has flowed into the lower channel ( 77 ) flows toward the upper channel ( 76 ) from the lower communication holes ( 79 ).
  • the upper channel ( 76 ) guides the refrigerant that has flowed into spaces under the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ) from the lower communication holes ( 79 ) to spaces under the central heat exchange section ( 35 ), the first heat exchange section ( 36 ), and the second heat exchange section ( 37 ).
  • the refrigerant flowing through the upper channel ( 76 ) is discharged from the upper communication holes ( 78 ) toward the plate stack ( 30 ).
  • the refrigerant that has flowed in from the refrigerant inlet ( 21 ) is made to flow through the lower channel ( 77 ) in the stacking direction of the plate stack ( 30 ), and is then guided by the upper channel ( 76 ) to the spaces under the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ). It is thus possible to stir the liquid refrigerant and the gas refrigerant contained in the refrigerant and reduce variations in the amount of the refrigerant flowing in the stacking direction of the plate stack ( 30 ).
  • a heat exchanger ( 10 ) includes a partitioning member ( 5 ).
  • the partitioning member ( 5 ) reduces a variation between the ratio between the liquid refrigerant and the gas refrigerant contained in the refrigerant made to exchange heat in the central heat exchange section ( 35 ) and the ratio between the liquid refrigerant and the gas refrigerant contained in the refrigerant made to exchange heat in each of the first heat exchange section ( 36 ) and the second heat exchange section ( 37 ).
  • the partitioning member ( 5 ) is disposed below the plate stack ( 30 ).
  • the partitioning member ( 5 ) includes a first partition plate ( 61 ), a stirring member ( 82 ), and first sidewall portions ( 63 ).
  • the first partition plate ( 61 ) serves as a partition between the plate stack ( 30 ) and the refrigerant inlet ( 21 ).
  • the first partition plate ( 61 ) extends along the first direction between the first closing member ( 13 ) and the second closing member ( 14 ) in the internal space ( 15 ) of the shell ( 11 ).
  • the first sidewall portions ( 63 ) are edge portions of the first partition plate ( 61 ) in the second direction which are bent to incline downward. Both ends of the first sidewall portions ( 63 ) in the second direction are in contact with the inner peripheral surface of the cylindrical body ( 12 ) of the shell ( 11 ).
  • the partitioning member ( 5 ) has an internal channel ( 55 ).
  • the internal channel ( 55 ) extends along the stacking direction of the plate stack ( 30 ).
  • the refrigerant that has flowed into the internal channel ( 55 ) from the refrigerant inlet ( 21 ) flows through the internal channel ( 55 ).
  • the internal channel ( 55 ) is formed in a space surrounded by the first partition plate ( 61 ), the first sidewall portions ( 63 ), the cylindrical body ( 12 ), the first closing member ( 13 ), and the second closing member ( 14 ).
  • the stirring member ( 82 ) is disposed in the internal channel ( 55 ).
  • the stirring member ( 82 ) is made of a porous material, such as a mesh material. The gas refrigerant and the liquid refrigerant contained in the refrigerant flowing through the internal channel ( 55 ) are stirred while passing through the stirring member ( 82 ).
  • the partitioning member ( 5 ) has communication holes ( 50 ).
  • the communication holes ( 50 ) are formed in the first partition plate ( 61 ).
  • the communication holes ( 50 ) communicate with the internal channel ( 55 ) and are open toward the plate stack ( 30 ).
  • the plurality of communication holes ( 50 ) are spaced apart from one another in the first direction and in the second direction in the first partition plate ( 61 ).
  • the communication holes ( 50 ) discharge the refrigerant flowing through the internal channel ( 55 ).
  • the liquid refrigerant and the gas refrigerant contained in the refrigerant that has flowed in from the refrigerant inlet ( 21 ) are stirred by the stirring member ( 82 ) while flowing in the stacking direction of the plate stack ( 30 ). It is thus possible to reduce variations in the ratio between the liquid refrigerant and the gas refrigerant in the stacking direction of the plate stack ( 30 ).
  • a partitioning member ( 5 ) includes a first partition plate ( 61 ), a pair of guide plates ( 52 ), and first sidewall portions ( 63 ).
  • the partitioning member ( 5 ) has an internal channel ( 55 ).
  • the internal channel ( 55 ) extends along the first direction.
  • the internal channel ( 55 ) includes a first channel ( 56 ) and second channels ( 57 ).
  • the partitioning member ( 5 ) has a plurality of communication holes ( 50 ).
  • the communication holes ( 50 ) include first communication holes ( 58 ) and second communication holes ( 59 ).
  • the first communication holes ( 58 ) and the second communication holes ( 59 ) are formed in the first partition plate ( 61 ).
  • the first communication holes ( 58 ) communicate with the first channel ( 56 ).
  • the plurality of first communication holes ( 58 ) are spaced apart from one another in the first direction and in the second direction in the first partition plate ( 61 ).
  • the second communication holes ( 59 ) communicate with the second channels ( 57 ).
  • the plurality of second communication holes ( 59 ) are spaced apart from one another in the first direction in the first partition plate ( 61 ).
  • the refrigerant inlet ( 21 ) is formed in a lower portion of the shell ( 11 ) at a position shifted in the first direction from a central position in the first direction.
  • One end of the first partition plate ( 61 ) in the first direction is referred to as a “first end ( 91 ),” and the other end is referred to as a “second end ( 92 ).”
  • the distance from the refrigerant inlet ( 21 ) to the first end ( 91 ) is longer than the distance from the refrigerant inlet ( 21 ) to the second end ( 92 ).
  • first region a region of the first partition plate ( 61 ) closer to the first end ( 91 ) than the refrigerant inlet ( 21 ) is referred to as a “first region,” and a region of the first partition plate ( 61 ) closer to the second end ( 92 ) than the refrigerant inlet ( 21 ) is referred to as a “second region.”
  • the first region and the second region are a left region and a right region, respectively, separated from each other by the centerline passing through the center of the refrigerant inlet ( 21 ).
  • the diameter d3 of the communication holes ( 50 ) formed in the first region and the diameter d4 of the communication holes ( 50 ) formed in the second region are set to satisfy the condition “d3>d4.”
  • the diameters of the communication holes ( 50 ) are set so that the refrigerant can flow to the communication holes ( 50 ) far from the refrigerant inlet ( 21 ) easily. It is thus possible to reduce variations in the distribution amount of the refrigerant.
  • a partitioning member ( 5 ) includes a first partition plate ( 61 ), a pair of guide plates ( 52 ), and first sidewall portions ( 63 ).
  • the partitioning member ( 5 ) has an internal channel ( 55 ).
  • the internal channel ( 55 ) extends along the first direction.
  • the internal channel ( 55 ) includes a first channel ( 56 ) and second channels ( 57 ).
  • the partitioning member ( 5 ) has a plurality of communication holes ( 50 ).
  • the communication holes ( 50 ) include first communication holes ( 58 ) and second communication holes ( 59 ).
  • the first communication holes ( 58 ) and the second communication holes ( 59 ) are formed in the first partition plate ( 61 ).
  • the first communication holes ( 58 ) communicate with the first channel ( 56 ).
  • the plurality of first communication holes ( 58 ) are spaced apart from one another in the first direction and in the second direction in the first partition plate ( 61 ).
  • the second communication holes ( 59 ) communicate with the second channels ( 57 ).
  • the plurality of second communication holes ( 59 ) are spaced apart from one another in the first direction in the first partition plate ( 61 ).
  • the refrigerant inlet ( 21 ) is formed in a lower portion of the shell ( 11 ) at a position shifted in the first direction from a central position in the first direction.
  • One end of the first partition plate ( 61 ) in the first direction is referred to as a “first end ( 91 ),” and the other end is referred to as a “second end ( 92 ).”
  • the distance from the refrigerant inlet ( 21 ) to the first end ( 91 ) is longer than the distance from the refrigerant inlet ( 21 ) to the second end ( 92 ).
  • first region a region of the first partition plate ( 61 ) closer to the first end ( 91 ) than the refrigerant inlet ( 21 ) is referred to as a “first region,” and a region of the first partition plate ( 61 ) closer to the second end ( 92 ) than the refrigerant inlet ( 21 ) is referred to as a “second region.”
  • the channel width L1 of the first channel ( 56 ) in the first region and the channel width L2 of the first channel ( 56 ) in the second region are set to satisfy the condition “L1>L2.”
  • the channel width of the first channel ( 56 ) in the first region is constant.
  • the channel width of the first channel ( 56 ) in the second region is narrowest at the end portion near the second end ( 92 ).
  • the channel width of the first channel ( 56 ) gradually becomes narrower from the first region toward the second region. In other words, in the first channel ( 56 ), the refrigerant flows more easily in the first region where the channel width is wider, than in the second region where the channel width is narrower.
  • the channel widths of the first channel ( 56 ) in the first region and the second region are set so that the refrigerant can flow to the first channel ( 56 ) in the first region distant from the refrigerant inlet ( 21 ) easily. It is thus possible to reduce variations in the distribution amount of the refrigerant.
  • a partitioning member ( 5 ) includes a first partition plate ( 61 ), a second partition plate ( 62 ), and a first sidewall portion ( 63 ).
  • the partitioning member ( 5 ) has an internal channel ( 55 ).
  • the internal channel ( 55 ) extends along the first direction.
  • a downstream end of the refrigerant inlet ( 21 ) is connected to the second partition plate ( 62 ).
  • the refrigerant inlet ( 21 ) is formed in a lower portion of the shell ( 11 ) at a position shifted in the first direction from a central position in the first direction.
  • the partitioning member ( 5 ) has a plurality of communication holes ( 50 ).
  • the communication holes ( 50 ) include first communication holes ( 68 ) and second communication holes ( 69 ).
  • the first communication holes ( 68 ) are spaced apart from one another in the first direction and in the second direction in the first partition plate ( 61 ).
  • the plurality of second communication holes ( 69 ) are spaced apart from one another in the first direction and in the second direction in the second partition plate ( 62 ).
  • first end ( 91 ) One end of the first partition plate ( 61 ) in the first direction is referred to as a “first end ( 91 ),” and the other end is referred to as a “second end ( 92 ).”
  • first end ( 91 ) One end of the first partition plate ( 61 ) in the first direction is referred to as a “first end ( 91 ),” and the other end is referred to as a “second end ( 92 ).”
  • the distance from the refrigerant inlet ( 21 ) to the first end ( 91 ) is longer than the distance from the refrigerant inlet ( 21 ) to the second end ( 92 ).
  • first region a region of the first partition plate ( 61 ) closer to the first end ( 91 ) than the refrigerant inlet ( 21 ) is referred to as a “first region,” and a region of the first partition plate ( 61 ) closer to the second end ( 92 ) than the refrigerant inlet ( 21 ) is referred to as a “second region.”
  • the diameter d3 of the first communication holes ( 68 ) formed in the first region and the diameter d4 of the first communication holes ( 68 ) formed in the second region are set to satisfy the condition “d3>d4.”
  • the diameter d5 of the second communication holes ( 69 ) formed in the first region and the diameter d6 of the second communication holes ( 69 ) formed in the second region are set to satisfy the condition “d5>d6.”
  • the diameters of the communication holes ( 50 ) in the first region and the second region are set so that the refrigerant can flow to the communication holes ( 50 ) of the first partition plate ( 61 ) and the second partition plate ( 62 ) in the first region distant from the refrigerant inlet ( 21 ) easily. It is thus possible to reduce variations in the distribution amount of the refrigerant.
  • a partitioning member ( 5 ) includes a first partition plate ( 61 ), a second partition plate ( 62 ), a first sidewall portion ( 63 ), and a second sidewall portion ( 64 ).
  • the partitioning member ( 5 ) has an internal channel ( 55 ).
  • the internal channel ( 55 ) extends along the first direction.
  • the internal channel ( 55 ) includes an upper channel ( 76 ) and a lower channel ( 77 ).
  • the refrigerant inlet ( 21 ) communicates with the lower channel ( 77 ).
  • the refrigerant inlet ( 21 ) is formed in a lower portion of the shell ( 11 ) at a position shifted from a central position in the first direction.
  • the partitioning member ( 5 ) has a plurality of communication holes ( 50 ).
  • the communication holes ( 50 ) include upper communication holes ( 78 ) and lower communication holes ( 79 ).
  • the plurality of upper communication holes ( 78 ) are spaced apart from one another in the first direction and in the second direction in the first partition plate ( 61 ).
  • the upper communication holes ( 78 ) communicate with the upper channel ( 76 ).
  • the plurality of lower communication holes ( 79 ) are spaced apart from one another in the first direction and in the second direction in the second partition plate ( 62 ).
  • the lower communication holes ( 79 ) communicate with the upper channel ( 76 ) and the lower channel ( 77 ).
  • first end ( 91 ) One end of the second partition plate ( 62 ) in the first direction is referred to as a “first end ( 91 ),” and the other end is referred to as a “second end ( 92 ).”
  • first end ( 91 ) One end of the second partition plate ( 62 ) in the first direction is referred to as a “first end ( 91 ),” and the other end is referred to as a “second end ( 92 ).”
  • the distance from the refrigerant inlet ( 21 ) to the first end ( 91 ) is longer than the distance from the refrigerant inlet ( 21 ) to the second end ( 92 ).
  • first region a region of the second partition plate ( 62 ) closer to the first end ( 91 ) than the refrigerant inlet ( 21 ) is referred to as a “first region,” and a region of the second partition plate ( 62 ) closer to the second end ( 92 ) than the refrigerant inlet ( 21 ) is referred to as a “second region.”
  • the diameter d5 of the lower communication holes ( 79 ) formed in the first region and the diameter d6 of the lower communication holes ( 79 ) formed in the second region are set to satisfy the condition “d5>d6.”
  • the diameters of the lower communication holes ( 79 ) in the first region and the second region are set so that the refrigerant can flow to the lower communication holes ( 79 ) of the second partition plate ( 62 ) in the first region distant from the refrigerant inlet ( 21 ) easily. It is thus possible to reduce variations in the distribution amount of the refrigerant.
  • a partitioning member ( 5 ) includes a first partition plate ( 61 ), a stirring member ( 82 ), and first sidewall portions ( 63 ).
  • the partitioning member ( 5 ) has an internal channel ( 55 ).
  • the internal channel ( 55 ) extends along the first direction.
  • the refrigerant inlet ( 21 ) communicates with the internal channel ( 55 ).
  • the refrigerant inlet ( 21 ) is formed in a lower portion of the shell ( 11 ) at a position shifted from a central position in the first direction.
  • the partitioning member ( 5 ) has a plurality of communication holes ( 50 ).
  • the plurality of communication holes ( 50 ) are spaced apart from one another in the first direction and in the second direction in the first partition plate ( 61 ).
  • the communication holes ( 50 ) communicate with the internal channel ( 55 ).
  • first end ( 91 ) One end of the first partition plate ( 61 ) in the first direction is referred to as a “first end ( 91 ),” and the other end is referred to as a “second end ( 92 ).”
  • first end ( 91 ) One end of the first partition plate ( 61 ) in the first direction is referred to as a “first end ( 91 ),” and the other end is referred to as a “second end ( 92 ).”
  • the distance from the refrigerant inlet ( 21 ) to the first end ( 91 ) is longer than the distance from the refrigerant inlet ( 21 ) to the second end ( 92 ).
  • first region a region of the first partition plate ( 61 ) closer to the first end ( 91 ) than the refrigerant inlet ( 21 ) is referred to as a “first region,” and a region of the first partition plate ( 61 ) closer to the second end ( 92 ) than the refrigerant inlet ( 21 ) is referred to as a “second region.”
  • the diameter d3 of the communication holes ( 50 ) formed in the first region and the diameter d4 of the communication holes ( 50 ) formed in the second region are set to satisfy the condition “d3>d4.”
  • the diameters of the communication holes ( 50 ) in the first region and the second region are set so that the refrigerant can flow to the communication holes ( 50 ) of the first partition plate ( 61 ) in the first region distant from the refrigerant inlet ( 21 ) easily. It is thus possible to reduce variations in the distribution amount of the refrigerant.
  • the present disclosure is useful for a shell-and-plate heat exchanger and a refrigeration apparatus.

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Thermal Sciences (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Heat-Exchange Devices With Radiators And Conduit Assemblies (AREA)
  • Details Of Heat-Exchange And Heat-Transfer (AREA)
US19/300,487 2023-03-29 2025-08-14 Shell-and-plate heat exchanger and refrigeration apparatus Pending US20250377175A1 (en)

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PCT/JP2024/011788 WO2024204114A1 (ja) 2023-03-29 2024-03-25 シェルアンドプレート式熱交換器及び冷凍装置

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FI114738B (fi) * 2000-08-23 2004-12-15 Vahterus Oy Levyrakenteinen lämmönvaihdin
JP4192413B2 (ja) * 2000-09-06 2008-12-10 株式会社Ihi 氷蓄熱装置の過冷却器
JP4451998B2 (ja) * 2001-05-22 2010-04-14 三菱重工業株式会社 蒸発器及びこれを有する冷凍機
JP6716227B2 (ja) * 2015-10-09 2020-07-01 三菱重工サーマルシステムズ株式会社 蒸発器、これを備えたターボ冷凍装置
CN205156444U (zh) * 2015-11-26 2016-04-13 珠海格力电器股份有限公司 满液式蒸发器的均液板和满液式蒸发器
JP6860095B1 (ja) * 2020-01-14 2021-04-14 ダイキン工業株式会社 シェルアンドプレート式熱交換器
JP7518332B2 (ja) * 2020-01-14 2024-07-18 ダイキン工業株式会社 シェルアンドプレート式熱交換器

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