Ultra-thin heat pump type air conditioner system
Technical field
The invention belongs to air conditioner technical fields, more particularly to a kind of ultra-thin heat pump type air conditioner system.
Background technique
Air-conditioning is divided into integral air conditioner and split-type air conditioner, wherein Domestic separating air-conditioning be most commonly that cabinet air-conditioner and
Wall-hanging air conditioner.Wherein wall-hanging air conditioner is compact-sized, is used widely unlike cabinet air-conditioner needs to occupy ground space.
Current air conditioner indoor unit is generally thicker, and bedroom or parlor space are limited, is placed in wall top, indoor unit is too thick to press to people
Compel sense, so slim-type air conditioner becomes inexorable trend.
The heat-exchange capacity of heat exchanger is a key factor for measuring air conditioning performance superiority and inferiority on air-conditioning, and in heat exchanger
Refrigerant side and wind side are then an important factor for influencing its heat-exchange capacity.Refrigerant is passed through in the cold-coal pipe of heat exchanger, it is cold
The cold coal amount of storage of coal pipeline directly affects the heat-exchange capacity of heat exchanger, and wind side is then by the hot superconductive plate in cold-coal pipe place and wing
The gap composition that piece is surrounded, fin play the role of increasing heat exchange area in air duct, and structure and shape directly affect air duct
The residence time of the track of interior fluid and fluid in air duct, and then influence heat-exchange capacity.Heat exchanger currently on the market
Mainly based on the structure of the swollen fin of S-shaped copper pipe, which is primarily present three problems: first is that heat-exchange capacity is insufficient;Second is that
The air duct of heat exchanger has some setbacks, and windage is larger;Third is that S-shaped copper pipe turning angle is more, Working fluid flow resistance is big.The present invention is using new
Type PCI heat exchanger, heat exchanger structure section gathers, thickness is smaller, heat exchange efficiency is high, can be very good the not high biography of substitution heat exchange efficiency
Fin heat exchanger under the overall leadership.
Summary of the invention
In view of the foregoing deficiencies of prior art, the purpose of the present invention is to provide a kind of ultra-thin heat pump type air conditioner systems
System, for solving the deficiency of heat-exchange capacity existing for air-conditioning in the prior art;The air duct of heat exchanger has some setbacks, windage compared with
Greatly;S-shaped copper pipe turning angle is more, and Working fluid flow resistance is larger, and heat exchange efficiency is lower;Air conditioner indoor unit is generally thicker, thicker
Air conditioner indoor unit can occupy biggish space, and the problems such as personal constriction.
In order to achieve the above objects and other related objects, the present invention provides a kind of based on ultra-thin heat pump type air conditioner system, institute
Stating ultra-thin heat pump type air conditioner system includes:
Air conditioner indoor unit, the air conditioner indoor unit include an at least Indoor Thermal superconductive heat exchanger, and the Indoor Thermal superconduction is changed
Hot device includes several the first hot superconduction heat exchange plates and several first radiating fins;In each first hot superconduction heat exchange plate
It is formed with the first sealing heat transfer path, the first refrigerant passage, the first refrigerant inlet and the first refrigerant exit;First sealing passes
Hot superconductive heat transfer working medium is filled in the passage of heat;First refrigerant inlet and first refrigerant exit are cold with described first
Matchmaker channel is connected;Several described first radiating fins are arranged alternately with the described in several first hot superconduction heat exchange plate, and are pasted
It is placed in the surface of the described first hot superconduction heat exchange plate;
Air-conditioner outdoor unit, the air-conditioner outdoor unit include outdoor refrigerant pipeline;
Coolant connecting tube road, between the air conditioner indoor unit and the outdoor machine of air-conditioner, with first refrigerant passage
And the outdoor refrigerant pipeline is connected, to form refrigerant circulation circuit.
Optionally, the air conditioner indoor unit further include:
Shell, the case inside are formed with accommodating chamber, are formed on the shell and the accommodating chamber is communicated with the outside
Logical air inlet and air outlet;
Water receiving tank is located in the holding tank, and is located at the lower section of the Indoor Thermal superconductive heat exchanger;The water receiving tank
End bottom is equipped with discharge outlet;
Drainpipe, one end are connected with the discharge outlet, and the other end extends to the outside of the shell.
Optionally, each first hot superconduction heat exchange plate includes: the first frame, the first cover board, the second cover board, first leads
Flowing plate, the second frame, the second deflector and third cover board;Wherein, first frame adheres on a table of first cover board
Face;Second cover board adheres on surface of first frame far from first cover board, in first cover board and institute
State formation first annular seal space room between the second cover board;First deflector is located in the first annular seal space room, in described
The first sealing heat transfer path is formed in first annular seal space body;Second frame adheres on second cover board far from described
The surface of first deflector;The third cover board adheres on surface of second frame far from second cover board, in institute
It states and forms the second sealed chamber between the second cover board and the third cover board;Second deflector is located at second seal chamber
Interior, in forming first refrigerant passage in the second chamber;First refrigerant inlet is located at second frame
On, and be connected with first refrigerant passage;First refrigerant exit is located on second frame, and with described first
Refrigerant passage is connected.
Optionally, first deflector includes several first flow guide bars along first direction parallel arrangement, and described
One flow guide bar includes the first protrusion that several are intervally arranged in a second direction, adjacent first protrusion in the second direction
Bottom integrally connected;The first direction and the second direction are perpendicular;
Second deflector includes the second flow guide bar that several arrange along the first direction parallel interval, and described
Two flow guide bars include several adjacent described second along the second protrusion that the second direction is intervally arranged, the second direction
The bottom integrally connected of protrusion.
Optionally, first protrusion on adjacent two rows first flow guide bar is arranged in a one-to-one correspondence or shifts to install,
Second protrusion on adjacent two rows second flow guide bar is arranged in a one-to-one correspondence or shifts to install.
Optionally, the described first hot superconduction heat exchange plate further includes the first vapor liquid equilibrium channel and the second vapor liquid equilibrium channel,
First vapor liquid equilibrium channel and second vapor liquid equilibrium channel are intervally arranged along the first direction leads in described first
The opposite two sides of flowing plate, and extend along the second direction, and first vapor liquid equilibrium channel and second vapor liquid equilibrium
Channel, which is located at, to be respectively positioned between second deflector and second frame.
Optionally, second sealed chamber includes the first cavity portion, the second cavity portion and third cavity portion;First cavity portion with
The third cavity portion is parallel, and second cavity portion and first cavity portion and the third cavity portion are perpendicular, and described second
Cavity portion is connected with first cavity portion and the third cavity portion;First refrigerant inlet is connected with first cavity portion,
First refrigerant exit is connected with the third cavity portion, and first refrigerant inlet is located at first cavity portion far from institute
The side of the second cavity portion is stated, the matchmaker outlet is located at side of the third cavity portion far from second cavity portion.
Optionally, it is additionally provided with liquid storage item in second frame, the liquid storage article is located at first cavity portion and described the
The junction of two cavity portions, and be located at first cavity portion and close on the inner wall of the third cavity portion.
Optionally, in the described first hot superconduction heat exchange plate, second frame, second cover board, second water conservancy diversion
The quantity of plate, first refrigerant inlet and first refrigerant exit be it is multiple, and second frame, it is described second lid
Plate, second deflector, the quantity of first refrigerant inlet and first refrigerant exit are identical;Multiple second sides
Frame is arranged in second cover board far from the surface parallel interval of first deflector;Multiple third cover board correspondences post
In each surface of second frame far from second cover board, to form multiple independent second sealed chambers;It is described
Deflector is located in each second sealed chamber;First refrigerant inlet and first refrigerant exit are set to each described
On second frame.
Optionally, the Indoor Thermal superconductive heat exchanger further include:
First balustrade deching adheres on several described first hot superconduction heat exchange plates and several described first radiating fins
The surface of laminated construction for being arranged alternately and being formed;
Second balustrade deching adheres on surface of the laminated construction far from first balustrade deching;
First through tube, the direction along the described in several first hot superconduction heat exchange plate arrangement extend, and by each described first
First refrigerant inlet in hot superconduction heat exchange plate is sequentially connected in series connection;
Second through tube, the direction along the described in several first hot superconduction heat exchange plate arrangement extend, and by each described first
First refrigerant exit in hot superconduction heat exchange plate is sequentially connected in series connection;
Refrigerant inlet pipe, one end are connected with the inside of first through tube;
Refrigerant outlet pipe, one end are connected with the inside of second through tube.
Optionally, the Indoor Thermal superconductive heat exchanger includes the first plate, the second plate and third plate, first plate
Material, second plate and the third plate are sequentially stacked and are combined with each other by rolling process;First sealing passes
The passage of heat and first refrigerant passage are formed by blowing-up technology;The first sealing heat transfer path is located at first plate
Between material and second plate, first refrigerant passage is between second plate and the third plate;It is described
It is formed with the first bulge-structure corresponding with the first sealing heat transfer path on first plate, is formed on the third plate
There is the second bulge-structure corresponding with first refrigerant passage.
Optionally, the air conditioner indoor unit includes multiple Indoor Thermal superconductive heat exchangers, multiple Indoor Thermal superconductions
First refrigerant passage of heat exchanger is connected.
Optionally, first radiating fin includes the fin protrusion of several horizontally spaced arrangements;Level side
The bottom integrally connected of the upward adjacent fin protrusion.
Optionally, first radiating fin includes several fin protrusions being intervally arranged along the vertical direction;Vertical side
The bottom integrally connected of the upward adjacent fin protrusion.
Optionally, the extending direction of the fin protrusion tilts default angle, the default angle compared to horizontal direction
Greater than 0 ° and less than 90 °.
Optionally, the air conditioner indoor unit further include:
An at least indoor fan, be located at the accommodating chamber in, and be located at least in the Indoor Thermal superconductive heat exchanger with it is described
Between air outlet;
Fan driving motor is located in the accommodating chamber, is electrically connected with the indoor fan, for driving the indoor wind
Machine work;
Filter screen is located in the accommodating chamber, and between the indoor fan and the air outlet;
First drive shaft is located in the accommodating chamber, and is located at the air outlet;
Several wind deflectors, be located at the accommodating chamber in, and along the axial direction of first drive shaft be intervally arranged in
In first drive shaft;
First driving motor is electrically connected with first drive shaft, is led described in the first drive shaft drive for driving
Aerofoil swings along the axial direction of first drive shaft;
Second drive shaft is located in the accommodating chamber, and is located at the air outlet;
Several louvre blades are located in second drive shaft, the length direction of the louvre blade and the air outlet
Length direction is identical;
Second driving motor, and second drive shaft, for driving second drive shaft to drive the louvre blade
Lower swing;
Display screen is located on the shell, for showing indoor actual temperature, indoor actual humidity, air conditioner indoor unit work
Operation mode, cleaning reminder and WIFI connection;
Electrical appliance kit is located in the accommodating chamber, with the fan driving motor, first driving motor, described second
Driving motor and display screen electrical connection.
Optionally, the shell includes:
Housing body, the housing body side are formed with holding tank, the housing body far from the holding tank one
Side is formed with decorative groove;The display location is in a side surface of the housing body far from the holding tank;
Cover board adheres on side of the housing body far from the decorative groove, is located at the cover board and the shell master
The holding tank between body is the accommodating chamber;
Transparent cover plate is buckled on the surface that the housing body is equipped with the decorative groove, the decorative groove is closed;
Decorative fresco is located in the decorative groove.
Optionally, the air-conditioner outdoor unit further includes finned coil formula heat exchanger, the finned coil formula heat exchanger
Including the outdoor refrigerant pipeline.
Optionally, the air-conditioner outdoor unit further include:
Outdoor hot superconductive heat exchanger, the hot superconductive heat exchanger in outdoor include several second hot superconduction heat exchange plates and several
A second radiating fin;Be each formed in each second hot superconduction heat exchange plate the second sealing heat transfer path, the second refrigerant passage,
Second refrigerant inlet and the second refrigerant exit;Hot superconductive heat transfer working medium is filled in the second sealing heat transfer path;Described
Two refrigerant inlets and second refrigerant exit are connected with second refrigerant passage;Several described second radiating fins
It is arranged alternately with the described in several second hot superconduction heat exchange plate, and adheres on the surface of the described second hot superconduction heat exchange plate;
Outdoor fan, positioned at the side of the hot superconductive heat exchanger in outdoor.
Optionally, the air-conditioning system further include: connection component, four-way reversing valve and compressor;Wherein,
The connection component is located at the coolant connecting tube road;
The four-way reversing valve is located at coolant connecting tube road, and with the coolant connecting tube road and the compressor
It is connected.
Optionally, the connection component include: the first shut-off valve, the second shut-off valve, the first silencer, the second silencer,
First filter, the second filter, check-valves, the first capillary and the second capillary;Wherein,
Second shut-off valve, first silencer, second silencer, the first filter, the non-return
Valve, first capillary and second filter are sequentially connected in series in the coolant connecting tube road, and second cut-off
The one end of valve far from first silencer is connected via the coolant connecting tube road with first refrigerant passage, and described
The one end of tow filtrator far from first capillary is connected via the coolant connecting tube road with the outdoor refrigerant pipeline;
First shut-off valve is between the four-way reversing valve and the air conditioner indoor unit;
Second capillary one end is connected between the first filter and the check-valves, and the other end is connected to institute
It states between check-valves and first capillary.
As described above, ultra-thin heat pump type air conditioner system of the invention has the advantages that ultra-thin heat pump of the invention
The first hot superconduction heat exchange plate in the Indoor Thermal superconductive heat exchanger of air conditioner indoor unit in type air-conditioning system uses hot superconductive heat transfer
Technology can make each regional temperature of entire plate face uniform, have the characteristics that heat conduction rate is fast, uniform temperature is good;Ultra-thin heat of the invention
The first hot superconduction heat exchange plate in the Indoor Thermal superconductive heat exchanger of air conditioner indoor unit in pump-type air-conditioning system is passed using hot superconduction
Thermal technology, the heat exchange efficiency of Indoor Thermal superconductive heat exchanger is high, thickness is smaller, compact-sized, the thickness of air conditioner indoor unit entirety compared with
It is small;In air conditioner indoor unit in ultra-thin heat pump type air conditioner system of the invention in Indoor Thermal superconductive heat exchanger the first radiating fin with
The air duct that first hot superconduction heat exchange plate is formed is smooth, windage is smaller.
Detailed description of the invention
Fig. 1 is shown as the structural schematic diagram of the air-conditioning system provided in the embodiment of the present invention one.
Fig. 2 is shown as the configuration schematic diagram of the air conditioner indoor unit provided in the embodiment of the present invention one.
Fig. 3 is shown as the sectional front view of the air conditioner indoor unit provided in the embodiment of the present invention one.
The stereochemical structure that fig. 4 to fig. 6 is shown as the exemplary air conditioner indoor unit of difference provided in the embodiment of the present invention one is shown
It is intended to.
The cross section structure that Fig. 7 to Figure 12 is shown as the exemplary air conditioner indoor unit of difference provided in the embodiment of the present invention one shows
It is intended to.
Figure 13 is shown as the explosion of the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention one
Structural schematic diagram.
Figure 14 is shown as first in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention one
The configuration schematic diagram of the first hot superconduction heat exchange plate of kind.
Figure 15 is shown as first in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention one
The structural schematic diagram of the first hot superconduction heat exchange plate of kind.
Figure 16 is shown as first in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention one
The first deflector in the first hot superconduction heat exchange plate of kind is placed in the overlooking structure diagram in the first frame.
Figure 17 is shown as first in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention one
The second frame in the first hot superconduction heat exchange plate of kind adheres on surface of second cover board far from the first deflector and the second deflector
The overlooking structure diagram being placed in the second frame.
Figure 18 is shown as second in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention one
The configuration schematic diagram of the first hot superconduction heat exchange plate of kind.
Figure 19 is shown as second in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention one
The structural schematic diagram of the first hot superconduction heat exchange plate of kind.
Figure 20 is shown as second in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention one
The second frame in the first hot superconduction heat exchange plate of kind adheres on surface of second cover board far from the first deflector and the second deflector
The overlooking structure diagram being placed in the second frame.
Figure 21 is shown as third in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention one
The configuration schematic diagram of the first hot superconduction heat exchange plate of kind.
Figure 22 is shown as third in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention one
The structural schematic diagram of the first hot superconduction heat exchange plate of kind.
Figure 23 is shown as third in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention one
The second frame in the first hot superconduction heat exchange plate of kind adheres on surface of second cover board far from the first deflector and the second deflector
The overlooking structure diagram being placed in the second frame.
Figure 24 is shown as first in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention two
The configuration schematic diagram of hot superconduction heat exchange plate.
Figure 25 is shown as first in the Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention two
The schematic perspective view of radiating fin.
Figure 26 is shown as the first Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention three
Configuration schematic diagram.
Figure 27 is shown as the first Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention three
In the first hot superconduction heat exchange plate partial cross section's structural schematic diagram.
Figure 28 is shown as the first Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention three
In first hot the first plate of superconduction heat exchange plate side side view.
Figure 29 is shown as second of Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention three
Configuration schematic diagram.
Figure 30 is shown as second of Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention three
In first hot the first plate of superconduction heat exchange plate side side view.
Figure 31 is shown as second of Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention three
In the first hot superconduction heat exchange plate third plate side side view.
Figure 32 is shown as the third Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention three
Configuration schematic diagram.
Figure 33 is shown as the third Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention three
In first hot the first plate of superconduction heat exchange plate side side view.
Figure 34 is shown as the third Indoor Thermal superconductive heat exchanger in the air conditioner indoor unit provided in the embodiment of the present invention three
In the first hot superconduction heat exchange plate third plate side side view.
Component label instructions
1 ' air conditioner indoor unit
1 Indoor Thermal superconductive heat exchanger
11 first hot superconduction heat exchange plates
110 first cover boards
111 first frames
1111 filling exits
112 second cover boards
113 first annular seal space rooms
1131 first vapor liquid equilibrium channels
1132 second vapor liquid equilibrium channels
1133 first sealing heat transfer paths
1134 hot superconductive heat transfer working medium
114 first guide plates
1141 first flow guide bars
1142 first protrusions
115 second frames
1151 liquid storage items
1152 dividers
116 third cover boards
117 second sealed chambers
1171 first cavity portions
1172 second cavity portions
1173 third cavity portions
1174 first refrigerant passages
118 second deflectors
1181 second flow guide bars
1182 second protrusions
1191 first plates
11911 first bulge-structures
1192 second plates
1193 third plates
11931 second bulge-structures
12 first radiating fins
121 fin protrusions
13 first balustrade dechings
14 second balustrade dechings
15 first through tubes
16 second through tubes
171 refrigerant inlet pipes
172 refrigerant outlet pipes
18 backing plates
191 first refrigerant inlets
192 first refrigerant exits
2 shells
21 housing bodies
22 cover boards
23 decorative grooves
24 air inlets
25 air outlets
26 auxiliary air-outlets
3 water receiving tanks
31 drainpipes
41 indoor fans
42 indoor fan driving motors
43 filter screens
51 first drive shafts
52 wind deflectors
53 first driving motors
61 second drive shafts
62 louvre blades
63 second driving motors
7 display screens
81 electrical appliance kits
82 cable tray
91 transparent cover plates
92 decorative frescos
93 auxiliary heaters
2 ' air-conditioner outdoor units
21 ' outdoor hot superconductive heat exchangers
22 ' outdoor fans
3 ' connection components
31 ' first shut-off valves
32 ' second shut-off valves
33 ' first silencers
34 ' second silencers
35 ' first filters
36 ' second filters
37 ' check-valves
38 ' first capillaries
39 ' second capillaries
4 ' four-way reversing valves
5 ' compressors
6 ' coolant connecting tube roads
Specific embodiment
Illustrate embodiments of the present invention below by way of specific specific example, those skilled in the art can be by this specification
Other advantages and efficacy of the present invention can be easily understood for disclosed content.The present invention can also pass through in addition different specific realities
The mode of applying is embodied or practiced, the various details in this specification can also based on different viewpoints and application, without departing from
Various modifications or alterations are carried out under spirit of the invention.
Please refer to Fig.1 to Fig.3 4.It should be noted that diagram provided in the present embodiment only illustrates this in a schematic way
The basic conception of invention, though only show in diagram with related component in the present invention rather than package count when according to actual implementation
Mesh, shape and size are drawn, when actual implementation form, quantity and the ratio of each component can arbitrarily change for one kind, and its
Assembly layout form may also be increasingly complex.
Embodiment one
The present invention provides a kind of ultra-thin heat pump type air conditioner system, the ultra-thin heat pump type air conditioner system referring to FIG. 1 to FIG. 4,
System includes: air conditioner indoor unit 1 ', and the air conditioner indoor unit 1 ' includes an at least Indoor Thermal superconductive heat exchanger 1, and the Indoor Thermal is super
Leading heat exchanger 1 includes several the first hot superconduction heat exchange plates 11 and several first radiating fins 12;Each first hot superconduction
The first sealing heat transfer path (not indicating), the first refrigerant passage (not indicating), the first refrigerant are each formed in heat exchanger plates 11
Import 191 and the first refrigerant exit 192;Heat-transfer working medium (not indicating) is filled in the first sealing heat transfer path;It is described
First refrigerant inlet 191 and first refrigerant exit 192 are connected with first refrigerant passage;Several described first
Radiating fin 12 is arranged alternately with the described in several first hot superconduction heat exchange plate 11, and adheres on the described first hot superconduction heat exchange plate
11 surface;Air-conditioner outdoor unit 2 ', the air-conditioner outdoor unit 2 ' include outdoor refrigerant pipeline (not indicating);Matchmaker's connecting line
6 ', matchmaker's connecting line 6 ' between the air conditioner indoor unit 1 ' and the outdoor machine of air-conditioner 2 ', and with first refrigerant
Channel and the outdoor refrigerant pipeline are connected, to form refrigerant circulation circuit.
As an example, the air conditioner indoor unit 1 ' further include: shell 2 is formed with accommodating chamber on the inside of the shell 2 and (does not show
Out), the air inlet 24 and air outlet 25 that the accommodating chamber is communicated with the outside are formed on the shell 2;Water receiving tank 3, institute
It states water receiving tank 3 to be located in the holding tank, and the water receiving tank 3 is located at the lower section of the Indoor Thermal superconductive heat exchanger 1;It is described to connect
The end bottom of sink 3 is equipped with discharge outlet (not indicating);Drainpipe 31, described 31 one end of drainpipe are connected with the discharge outlet
It connects, the other end extends to the outside of the shell 2.The Indoor Thermal superconductive heat exchanger of the air conditioner indoor unit 1 ' of the invention
The described first hot superconduction heat exchange plate 11 in 1 uses hot super heat conduction, and each regional temperature of entire plate face can be made uniform, had
The feature that heat conduction rate is fast, uniform temperature is good;The heat exchange efficiency of the Indoor Thermal superconductive heat exchanger 1 is high, thickness is smaller, structure is tight
It gathers, the whole thickness of the air conditioner indoor unit 1 ' is smaller;Indoor Thermal superconduction described in the air conditioner indoor unit 1 ' of the invention is changed
First radiating fin 12 described in hot device 1 and the air duct that the described first hot superconduction heat exchange plate 11 is formed are smooth, windage is smaller;Work as institute
Air conditioner indoor unit 1 ' is stated for when freezing, the temperature of the Indoor Thermal superconductive heat exchanger 1 to be usually less than cooled room air
The upper surface of dew-point temperature, the Indoor Thermal superconductive heat exchanger 1 will form condensed water, by the Indoor Thermal superconductive heat exchanger
The water receiving tank 3 and the drainpipe 31 is arranged in 1 lower section, and the condensed water formed on the Indoor Thermal superconductive heat exchanger 1 can flow
It is discharged in the water receiving tank 3 and via the drainpipe 31.
In one example, as shown in figure 4, the air inlet 24 is located at the top of the shell 2, the air outlet 25 is located at
The lower part of the shell 2, i.e., the described air conditioner indoor unit 1 ' can be the form of top return air lower part air-supply, relatively be suitble to heating mould
Formula can achieve the air-supply effect for making the blanket type heating of hot-air from bottom to top when heating using lower part air-supply.
In another example, as shown in figure 5, on the basis of Fig. 4 structure, auxiliary air-outlet is additionally provided on the shell 2
26, the auxiliary air-outlet 26 is located at the opposite two sides of the air outlet 25, by adding the auxiliary air-outlet 26, Ke Yishi
Existing low wind speed air-supply, human sense of comfort are more preferable.
In another example, as shown in fig. 6, the air inlet 24 is located at the lower part of the shell 2, the air outlet 25
In the top of the shell 2, and the top of the shell 2 and the opposite two sides of the shell 2 are equipped with auxiliary air-outlet 26, i.e.,
The air conditioner indoor unit 1 ' can be the form of at the top of the return air of lower part and top air-supply, relatively be suitble to refrigeration mode, the air-conditioning
When indoor unit 1 ' freezes, the air outlet 25 on top and top can allow cold air to send from top to bottom as waterfall
Out.It certainly, in other examples, can also be without the auxiliary air-outlet 26 on the shell 2.
As an example, the air conditioner indoor unit 1 ' can also include: an at least indoor fan please continue to refer to Fig. 2 and Fig. 3
41, the indoor fan 41 is located in the accommodating chamber, and is located at least in the Indoor Thermal superconductive heat exchanger 1 and the air inlet
Between 24;Indoor fan driving motor 42, the indoor fan driving motor 42 are located in the accommodating chamber, the indoor fan
Driving motor 42 is electrically connected with the indoor fan 41, for driving the indoor fan 41 to work;Filter screen 43, the filtering
Net 43 is located in the accommodating chamber, and between the indoor fan 41 and the air inlet 24;First drive shaft 51, it is described
First drive shaft 51 is located in the accommodating chamber, and is located at the air outlet 25;Several wind deflectors 52 are led described in several
Aerofoil 52 is located in the accommodating chamber, and is intervally arranged along the axial direction of first drive shaft 51 in first drive shaft
On 51;First driving motor 53, first driving motor 53 are electrically connected with first drive shaft 51, for driving described
One drive shaft 51 drives the wind deflector 52 to swing along the axial direction of first drive shaft 51;Second drive shaft 61, it is described
Second drive shaft 61 is located in the accommodating chamber, and is located at the air outlet 25;Several louvre blades 62, several described hundred
Blade 62 is located in second drive shaft 61, the length direction phase of the length direction of the louvre blade 62 and the air outlet 25
Together;Second driving motor 63, second driving motor 63 is electrically connected with second drive shaft 61, for driving described second
Drive shaft 61 drives the louvre blade 62 to swing up and down;Display screen 7, the display screen 7 is located on the shell 2, for showing
Indoor actual temperature, indoor actual humidity, 1 ' operating mode of air conditioner indoor unit (heating, refrigeration, humidification or dehumidifying etc.), cleaning mention
The parameters such as awake and WIFI connection;Electrical appliance kit 81, the electrical appliance kit 81 is located in the accommodating chamber, and the electrical appliance kit 81 can position
In in the region being individually isolated in the accommodating chamber, the electrical appliance kit 81 and the indoor fan driving motor 42, described first
Driving motor 53, second driving motor 63 and the display screen 7 are electrically connected, with for the indoor fan driving motor 42,
First driving motor 53, second driving motor 63 and the display screen 7 provide electric power.It should be noted that working as institute
When stating electrical appliance kit 81 and being located at independent space, it is additionally provided with cable tray 82 in the accommodating chamber, in order to use conducting wire described
Electrical appliance kit 81 is drawn out of independent space.
In one example, as shown in Fig. 2, Fig. 8, Fig. 9, Figure 11 and Figure 12, wherein Fig. 8 is the air-supply of top return air lower part, figure
9 and Figure 11 is that (the i.e. described air inlet 24 is located at the left side of the shell 2, and the air outlet 25 is located at for air-supply on the right side of the return air of left side
The right side of the shell 2), Figure 12 blows simultaneously on the right side of the return air of left side and upper and lower two sides, and (the i.e. described air inlet 24 is described in
The left side of shell 2, the air outlet 25 are located at the right side of the shell 2, and the two sides up and down of the shell 2 be equipped with it is described auxiliary
Help air outlet 26);The quantity of the indoor fan 41 can be one, and the indoor fan 41 is located at the Indoor Thermal superconduction and changes
Between hot device 1 and the air inlet 24.
In another example, as shown in Fig. 7 and Figure 10, wherein Fig. 7 is the air-supply of top return air lower part, and Figure 10 returns for left side
(the i.e. described air inlet 24 is located at the left side of the shell 2, and the air outlet 25 is located at the right side of the shell 2 for air-supply on the right side of wind
Side);The air conditioner indoor unit 1 ' may include two indoor fans 41, one of them described indoor fan 41 is located at described
Between Indoor Thermal superconductive heat exchanger 1 and the air inlet 24, another described indoor fan 41 is located at the Indoor Thermal superconduction and changes
Between hot device 1 and the air outlet 25, to enhance heat exchange.
In one example, shown in as shown in Figure 1, Figure 2, Fig. 7, Fig. 9, Figure 10 and Figure 12, the air conditioner indoor unit 1 ' may include
One Indoor Thermal superconductive heat exchanger 1;In another example, as shown in Fig. 8 and Figure 11, the air conditioner indoor unit 1 ' be can wrap
Multiple Indoor Thermal superconductive heat exchangers 1 are included, first refrigerant passage of multiple Indoor Thermal superconductive heat exchangers 1 is connected
It is logical;Wherein, Fig. 8 and Figure 11 only with the air conditioner indoor unit 1 ' include two Indoor Thermal superconductive heat exchangers 1 as an example,
In actual example, the quantity of the Indoor Thermal superconductive heat exchanger 1 is not limited thereto.
As an example, the indoor fan 41 may include through-flow indoor fan, wind in axis flow chamber inner blower or centrifugal chamber
Machine etc.;When the indoor fan 41 is through-flow indoor fan, the indoor fan may include a through-flow fan blade, can be with
Including two through-flow fan blades.
As an example, Indoor Thermal superconductive heat exchanger described in this implementation 1 may include soldering formula Indoor Thermal superconductive heat exchanger,
The first hot superconduction heat exchange plate 11 can be the hot superconduction heat exchange plate of soldering formula first, and as shown in figure 13, each first heat is super
Leading heat exchanger plates 11 includes: the first frame 111, the first cover board 110, the second cover board 112, the first deflector 114, the second frame
115, the second deflector 118, third cover board 116, the first refrigerant inlet 191 and the first refrigerant exit 192;Wherein, described first
Frame 111 adheres on a surface of first cover board 110;It is separate that second cover board 112 adheres on first frame 111
The surface of first cover board 110, to form first annular seal space between first cover board 110 and second cover board 112
Room 113;First deflector 114 is located in the first annular seal space room 113, in shape in the first annular seal space room 113
At the first sealing heat transfer path (not indicating), (do not show in the first sealing heat transfer path filled with hot superconductive heat transfer working medium
Out);Second frame 115 adheres on surface of second cover board 112 far from first deflector 114;The third
Cover board 116 adheres on surface of second frame 115 far from second cover board 112, in second cover board 112 and institute
It states and forms the second sealed chamber 117 between third cover board 116;Second deflector 118 is located at second sealed chamber 117
It is interior, in forming the first refrigerant passage (not indicating) in the second chamber 17;First refrigerant inlet 191 is located at described
On second frame 115, and first refrigerant inlet 191 is connected with first refrigerant passage;First refrigerant exit
192 are located on second frame 115, and first refrigerant exit 192 is connected with first refrigerant passage;Several
First radiating fin 12, several described first radiating fins 12 replace row with the described in several first hot superconduction heat exchange plate 11
Cloth, and first radiating fin 12 adheres on the surface of the described first hot superconduction heat exchange plate 11.
It should be noted that due on the inside of first frame 111 be hollow area, first cover board 110 with it is described
It, can be in first cover board 110, second lid after second cover board, 112 note is placed in two opposite surfaces of first frame 111
The first annular seal space room 113 is formed on the inside of plate 112 and first frame 111;Similarly, due in second frame 115
Side is hollow area, and second cover board 112 and the third cover board 116 adhere on two opposite tables of second frame 115
Behind face, second sealing can be formed on the inside of second cover board 112, the third cover board 116 and second frame 115
Chamber 117.
It should be noted that hot super heat conduction includes filling work in closed interconnected micro-channel system
Medium realizes the hot pipe technique of hot superconductive heat transfer by the evaporation of working media with condensation phase transformation;And pass through control enclosed system
Middle working media micro-architectural state, i.e., in diabatic process, the boiling (or condensation of gaseous medium) of liquid medium is suppressed, and
Reach the consistency of working medium micro-structure on this basis, and realizes the phase transformation of efficient heat transfer and inhibit (PCI) heat transfer technology.This implementation
In example, the hot superconductive heat transfer working medium can inhibit heat-transfer working medium for phase transformation, at this point, the hot superconductive heat transfer working medium is in heat transfer
It boils or condenses in the process and be suppressed, and reach the consistency of working medium micro-structure on this basis and realize heat transfer.The present embodiment
In, the hot superconductive heat transfer working medium can also be carried out continuously evaporation endothermic and condense exothermic phase transformation circulation to come in diabatic process
Realize flash heat transfer.
As an example, the hot superconductive heat transfer working medium is fluid, it is preferable that the hot superconductive heat transfer working medium can be gas
Or the mixture of liquid or gas and liquid, it is further preferable that the hot superconductive heat transfer working medium is liquid and gas in the present embodiment
The mixture of body.
As an example, the height of first deflector 114 is identical as the thickness of first frame 111, described second
The height of deflector 118 is identical as the thickness of second frame 115.By the height of first deflector 114 be set as with
The height of first frame 111 is identical, and sets the height of second deflector 118 to and second frame 115
Thickness it is identical, it can be ensured that the bonding area of first deflector 114 and second deflector 118 and solder layer reaches
Maximum, to increase weld strength.
As an example, be formed with filling exit 1111 on first frame 111, the filling exit 1111 and the sealing the
One sealed chamber 113 is connected, and the hot superconductive heat transfer working medium is filled in first sealing via the filling exit 1111 and passes
In the passage of heat.It should be noted that the filling exit 1111 needs to close after the hot superconductive heat transfer working medium filling.
In one example, as shown in figure 14, first frame 111 may include but be not limited only to annular peripheral frame.It is described
The side of first frame 111 is equipped with the filling exit 1111 through side wall.First cover board 110, second cover board 112 and institute
The first frame 111 is stated and after first deflector 114 welds together, described in one end insertion by a filling tube (not shown)
Filling exit 1111 can fill the hot superconductive heat transfer working medium into the first sealing heat transfer path.The populated hot superconduction
After heat-transfer working medium, the filling exit 1111 should being enclosed so as to, the first sealing heat transfer path realizes sealing.Described second
Cover board 112, second deflector 118 and the third cover board 116 weld together also by welding procedure;Described first dissipates
Hot fin 12 is welded in the surface of the described first hot superconduction heat exchange plate 11 by welding procedure.
As an example, first deflector 114 includes several along first direction parallel as shown in Figure 14 and Figure 16
First flow guide bar 1141 of cloth, first flow guide bar 1141 include the first protrusion that several are intervally arranged in a second direction
1142, the bottom integrally connected of adjacent first protrusion 1142 in the second direction;The first direction and described second
Direction is perpendicular.First protrusion 1142 can extend along the second direction in square-wave-shaped, wave-shaped can also extend.
It is concave between adjacent first protrusion 1142 along the second direction.First cover board 110, second cover board 112
After welding together with first frame 111 and first deflector 114, described the first of first deflector 114
Gap between protrusion 1142 and first cover board 110, between adjacent first protrusion 1142 of the second direction
The gap between gap and adjacent first flow guide bar 1141 between recess and second cover board 112 collectively forms institute
State the first sealing heat transfer path.
As an example, several described first flow guide bars 1141 can be with integrally connected, specifically, several described first are led
The one end for flowing item 1141 can be equipped with connection strap (not shown), and the connection strap is arranged along the first flow guide bar 1141 described in several
Direction extend, and several described first flow guide bars 1141 are sequentially connected in series.
As an example, first protrusion 1142 on adjacent two rows first flow guide bar 1141 can correspond and set
It sets, i.e., along the first direction (i.e. first flow guide bar 1141 arrange direction), on the first flow guide bar 1141 described in each item
First protrusion 1142 be arranged in a one-to-one correspondence.Certainly, in other examples, on adjacent two rows first flow guide bar 1141
First protrusion 1142 can also shift to install, described first on so-called adjacent two rows first flow guide bar 1141 is convex
Portion 1142, which shifts to install, to be referred to, the side of first protrusion 1142 on adjacent two rows first flow guide bar 1141 is staggered;
The distance of first protrusion 1142 dislocation of adjacent two rows first flow guide bar 1141 can be less than first protrusion
The distance of 1142 width, first protrusion 1142 dislocation of adjacent two rows first flow guide bar 1141 can also be equal to institute
State the width of the first protrusion 1142, at this point, first protrusion 1142 of the first flow guide bar 1141 described in a row with it is adjacent thereto
A row described in the first flow guide bar 1141 first protrusion 1142 between recess alignment.It should be noted that adjacent
When first protrusion 1142 on two rows of first flow guide bars 1141 shifts to install, every on row's first flow guide bar 1141
First protrusion 1142 be arranged in a one-to-one correspondence, i.e. first protrusion 1142 on the first flow guide bar 1141 described in odd row
It is shifted to install with first protrusion 1142 on the first flow guide bar 1141 described in even rows, and the first water conservancy diversion described in each odd row
First protrusion 1142 on item 1141 is arranged in a one-to-one correspondence, described second on the first flow guide bar 1141 described in each even rows
Protrusion 142 is also arranged in a one-to-one correspondence.
As an example, please referring to Figure 16, the first hot superconduction heat exchange plate 11 further includes the first vapor liquid equilibrium channel 1131
And the second vapor liquid equilibrium channel 1132, first vapor liquid equilibrium channel 1131 and second vapor liquid equilibrium channel 1132 are along institute
First direction is stated to be intervally arranged the two sides opposite in first deflector 114, and first vapor liquid equilibrium channel 1131 and
Second vapor liquid equilibrium channel 1132 extends along the second direction, and first vapor liquid equilibrium channel 1131 and described the
Two vapor liquid equilibrium channels 1132, which are located at, to be respectively positioned between second deflector 14 and second frame 115.Pass through setting institute
The first vapor liquid equilibrium channel 1131 and second vapor liquid equilibrium channel 1132 are stated, the hot superconductive heat transfer working medium edge can be reduced
The flow resistance of the second direction, can the hot superconductive heat transfer working medium in the first sealing heat transfer path described in active balance,
So that the first hot superconduction heat exchange plate 11 is generally in equal temperature state.
As an example, second deflector 118 include several arrange along the first direction parallel interval second
Flow guide bar 1181, second flow guide bar 1181 include several along the second protrusion 1182 that the second direction is intervally arranged,
The bottom integrally connected of adjacent second protrusion 1182 in the second direction.Second protrusion 1182 is along the second party
To that can be in that square wave is extending, wave-shaped can also extend.Along the second direction, between adjacent second protrusion 1182
It is concave.Second cover board 112, the third cover board 116, second frame 115 and second deflector 118 welding
After together, gap between second protrusion 1182 and second cover board 112 of second flow guide bar 18, along described
Gap between recess and the third cover board 116 between adjacent second protrusion 1182 of second direction and adjacent described
Gap between second flow guide bar 1181 collectively forms first refrigerant passage.
As an example, several described second flow guide bars 1181 can be with integrally connected, specifically, several described second are led
The one end for flowing item 1181 can be equipped with connection strap (not shown), and the connection strap is arranged along the second flow guide bar 1181 described in several
Direction extend, and several described second flow guide bars 1181 are sequentially connected in series.
As an example, second protrusion 1182 on adjacent two rows second flow guide bar 1181 can correspond and set
It sets, i.e., along the first direction, second protrusion 1182 on the second flow guide bar 1181 described in each item is arranged in a one-to-one correspondence.When
So, in other examples, second protrusion 1182 on adjacent two rows second flow guide bar 1181 can also shift to install,
Second protrusion 1182 on so-called adjacent two rows second flow guide bar 1181, which shifts to install, to be referred to, adjacent two rows described
The side of second protrusion 1182 on two flow guide bars 1181 is staggered;Described the of adjacent two rows second flow guide bar 1181
The distance of two protrusions 1182 dislocation can be less than the width of second protrusion 1182, adjacent two rows second flow guide bar 1181
The distance of second protrusion 1182 dislocation can also be equal to the width of second protrusion 1182, at this point, the described in a row
Described the second of second protrusion 1182 of two flow guide bars 1181 and the second flow guide bar 1181 described in a row adjacent thereto is convex
Recess alignment between portion 1182.It should be noted that described second on adjacent two rows second flow guide bar 1181 is convex
When portion 1182 shifts to install, second protrusion 1182 respectively arranged on second flow guide bar 1181 is arranged in a one-to-one correspondence, i.e., odd
Number arrange second protrusions 1182 on second flow guide bars 1181 with it is described on the second flow guide bar 1181 described in even rows
Second protrusion 1182 shifts to install, and second protrusion 1182 on the second flow guide bar 1181 described in each odd row corresponds
It is arranged, second protrusion 1182 on the second flow guide bar 1181 described in each even rows is also arranged in a one-to-one correspondence.
As an example, please referring to Figure 14 and Figure 17, second sealed chamber 117 includes the first cavity portion 1171, the second chamber
Portion 1172 and third cavity portion 1173;First cavity portion 1171 is parallel with the third cavity portion 1173, second cavity portion
1172 is perpendicular with first cavity portion 1171 and the third cavity portion 1173, and second cavity portion 1172 and first chamber
Portion 1171 and the third cavity portion 1173 are connected;First refrigerant inlet 191 is connected with first cavity portion 1171, institute
It states the first refrigerant exit 192 to be connected with the third cavity portion 1173, and first refrigerant inlet 191 is located at first chamber
Side of the portion 1171 far from second cavity portion 1172, it is separate that first refrigerant exit 192 is located at the third cavity portion 1173
The side of second cavity portion 1172, i.e., described first refrigerant inlet 191 and first refrigerant exit 192 are located at described second
The same side of sealed chamber 117.
As an example, second frame 115 may include but be not limited only to U-shaped frame, second sealed chamber 117
It may include but be not limited only to U-shaped cavity portion.
As an example, the third cover board 116 may include U-shaped cover board.The third cover board 116 adheres on described second
Behind side of the frame 115 far from second cover board 112, second frame 115 is completely covered in the third cover board 116.Tool
Body, in the first hot superconduction heat exchange plate 11, each side of the third cover board 116 is corresponding with second frame 115
Each side and corresponding each side of second cover board 112 align.
As an example, please referring to Figure 14 and Figure 17, liquid storage item 1151, the liquid storage are additionally provided in second frame 115
Item 1151 is located at the junction of first cavity portion 1171 and second cavity portion 1172, and is located at first cavity portion 1171 and faces
On the inner wall of the nearly third cavity portion 1173.The liquid storage item 1151 can extend in a first direction.The liquid storage item 1151 can
To play the role of to the refrigerant water conservancy diversion.
In another example, Figure 18 to Figure 20 is please referred to, second frame 115 can also be annular peripheral frame, described the
Divider 1152, the fixed company of the inner wall of described 1152 one end of divider and second frame 115 are additionally provided in two frames 115
It connects, the length of the divider 1152 is less than second sealed chamber 17 along the ruler of the length direction of the divider 1152
It is very little;First cavity portion 1171 and the third cavity portion 1173 are located at the opposite two sides of the divider 1152, and described
Two cavity portions 1172 are located between the free end and second frame 115 of the divider 1152;When the described first hot superconduction is changed
When hot plate 11 is equipped with the liquid storage item 1151, the liquid storage item 1151 is located at the free end of the divider 1152, and the storage
Liquid item 1151 and the divider 1152 are perpendicular.The other structures and reality of first hot superconduction heat exchange plate described in the present embodiment
The other structures for applying the first hot superconduction heat exchange plate described in example one are identical, referring specifically to embodiment one, herein no longer
It is tired to state.
As an example, second frame 115, the third cover board 116, second deflector 118, described first
Refrigerant inlet 191 and the quantity of first refrigerant exit 192 are one.
As an example, three sides of second frame 115, three sides corresponding with second deflector 118 and
Second cover board, 112 corresponding three sides correspond alignment, for example, the bottom edge of second frame 115 and described the
The bottom edge of two deflectors 118 and the alignment of the bottom edge of second cover board 112, second frame 115 two sides adjacent with bottom edge
Two sides adjacent with second deflector 118 and bottom edge are aligned one by one respectively on side, and with second cover board 112 and bottom edge
Adjacent two sides are aligned one by one.
In another example, Figure 21 to Figure 23 is please referred to, in the first hot superconduction heat exchange plate 11, second frame
115, the third cover board 116, second deflector 118, first refrigerant inlet 191 and first refrigerant exit
192 quantity is multiple, and second frame 115, the third cover board 116, second deflector 118, described
One refrigerant inlet 191 and the quantity of first refrigerant exit 192 are identical;Multiple second frames 115 are in second lid
Plate 112 is arranged far from the surface parallel interval of first deflector 114;Multiple third cover boards 116 are corresponding to adhere on respectively
Surface of second frame 115 far from second cover board 112, to form multiple independent second sealed chambers 117;
Second deflector 118 is located in each second sealed chamber 117;First refrigerant inlet 191 and described first cold
Matchmaker outlet 192 is set on each second frame 115.
As an example, please continue to refer to Figure 13, the Indoor Thermal superconductive heat exchanger 1 further include: the first balustrade deching 13, institute
It states the first balustrade deching 13 and adheres on several first hot superconduction heat exchange plates 11 and several described first radiating fins 12
The surface of laminated construction for being arranged alternately and being formed;Second balustrade deching 14, second balustrade deching 14 adhere on described
Surface of the laminated construction far from first balustrade deching 13.
As an example, between the adjacent first hot superconduction heat exchange plate 11, the first hot superconduction heat exchange plate 11 with it is described
Described first dissipates between first balustrade deching 13 and between the first hot superconduction heat exchange plate 11 and second balustrade deching 14
The quantity of hot fin 12 can be one, or it is multiple, as shown in figure 13.
As an example, please continue to refer to Figure 13, the Indoor Thermal superconductive heat exchanger further include: the first through tube 15, it is described
First through tube 15 extends along the direction that the described in several first hot superconduction heat exchange plate 11 is arranged, and first through tube 15 will
First refrigerant inlet 191 in each first hot superconduction heat exchange plate 11 is sequentially connected in series connection;Second through tube 16, it is described
Second through tube 16 extends along the direction that the described in several first hot superconduction heat exchange plate 11 is arranged, and second through tube 16 will
First refrigerant exit 192 in each first hot superconduction heat exchange plate 11 is sequentially connected in series connection;Refrigerant inlet pipe 171, it is described
171 one end of refrigerant inlet pipe is connected with the inside of first through tube 6;Refrigerant outlet pipe 172, described 172 one end of refrigerant outlet pipe
It is connected with the inside of second through tube 16.
In one example, please continue to refer to Figure 13, first radiating fin 12 may include several in the horizontal direction
The fin protrusion 121 being intervally arranged;The bottom integrally connected of the adjacent fin protrusion 121 in horizontal direction;I.e. described first
Several described fin protrusions 121 in radiating fin 12 can extend along the vertical direction, at this point, adjacent institute in the horizontal direction
Stating has the recessed portion (not indicating) extended along the vertical direction between fin protrusion 121.First radiating fin 12 with it is each
The recessed portion between the first hot superconduction heat exchange plate 11, first balustrade deching 13 and second balustrade deching 14
Form air duct.
As an example, first radiating fin 12 may include flat type fin, rippled fin, serrated fin,
Porous fin or combined type fin etc..
As an example, the shell 2 may include: housing body 21 and cover board 22, the shell please continue to refer to Fig. 1
21 side of main body is formed with holding tank (not indicating), and the housing body 21 is formed with decoration far from the side of the holding tank
Slot 23;The display screen 7 can be located at a side surface of the housing body 21 far from the holding tank;The cover board 22 posts
Institute in side of the housing body 21 far from the decorative groove 23, between the cover board 22 and the housing body 21
Stating holding tank is the accommodating chamber;The air conditioner indoor unit 1 ' further include: transparent cover plate 91 and decorative fresco 92 are described transparent
Cover board 91 is buckled on the surface that the housing body 21 is equipped with the decorative groove 23, and the decorative groove 23 is closed;The dress
Decorations mural painting 92 is located in the decorative groove 23.
As an example, the air conditioner indoor unit 1 ' further includes auxiliary heater 93, the auxiliary heater 93 adheres on institute
State the surface of Indoor Thermal superconductive heat exchanger 1.
In one example, the air-conditioner outdoor unit 2 ' further includes finned coil formula heat exchanger (not shown), the fin
Tube coil type heat exchanger includes the outdoor refrigerant pipeline.
In another example, please continue to refer to Fig. 1, the air-conditioner outdoor unit 2 ' further include: outdoor hot superconductive heat exchanger
21 ', the hot superconductive heat exchanger 21 ' in outdoor include several second hot superconduction heat exchange plates (not indicating) and several second dissipate
Hot fin (not indicating);Be each formed in each second hot superconduction heat exchange plate the second sealing heat transfer path (not indicating),
Second refrigerant passage (not indicating), the second refrigerant inlet (not indicating) and the second refrigerant exit (not indicating);Described
Hot superconductive heat transfer working medium (not shown) is filled in two sealing heat transfer paths;Second refrigerant inlet and second refrigerant go out
Mouth is connected with second refrigerant passage;Several described second radiating fins and several described second hot superconduction heat exchanges
Plate is arranged alternately, and adheres on the surface of the described second hot superconduction heat exchange plate;Outdoor fan 22 ', the outdoor fan 22 ' are located at
The side of the hot superconductive heat exchanger 21 ' in outdoor.Specifically, the knot of the structure of the air-conditioner outdoor unit 2 ' and air conditioner indoor unit 1 '
Structure can be identical.
As an example, please continue to refer to Fig. 1, the ultra-thin heat pump type air conditioner system further include: the air-conditioning system is also wrapped
It includes: connection component 3 ', four-way reversing valve 4 ' and compressor 5 ';Wherein, the connection component 3 ' is located at the coolant connecting tube road
On 6 ';The four-way reversing valve 4 ' is located on the coolant connecting tube road 6 ', and the four-way reversing valve 4 ' and the refrigerant connect
Adapter tube road 6 ' and the compressor 5 ' are connected.
As an example, the connection component 3 ' includes: the first shut-off valve 31 ', the second shut-off valve 32 ', the first silencer
33 ', second silencer 34 ', first filter 35 ', the second filter 36 ', check-valves 37 ', the first capillary 38 ' and second mao
Tubule 39 ';Wherein, second shut-off valve 32 ', first silencer 33 ', second silencer 34 ', first mistake
Filter 35 ', the check-valves 37 ', first capillary 38 ' and second filter 36 ' are sequentially connected in series in the refrigerant
On connecting line 6 ', and the one end of second shut-off valve 32 ' far from first silencer 33 ' is via the coolant connecting tube
Road 6 ' is connected with first refrigerant passage, the one end of second filter 36 ' far from first capillary 38 ' via
The coolant connecting tube road 6 ' is connected with the outdoor refrigerant pipeline;First shut-off valve 31 ' is located at four-way commutation
Between valve 4 ' and the air conditioner indoor unit 1 ';Described second capillary, 39 ' one end be connected to the first filter 35 ' with it is described
Between check-valves 37 ', the other end is connected between the check-valves 37 ' and first capillary 38 '.
The working principle of ultra-thin heat pump type air conditioner system of the invention are as follows:
When the ultra-thin heat pump type air conditioner system refrigerating operaton, refrigerant (generally liquid refrigeration from the outside into the room
Agent) enter the Indoor Thermal superconductive heat exchanger 1 in in room air carry out heat exchange;The refrigerant is empty due to absorbing room
Heat in gas becomes gaseous state by liquid, and temperature and pressure do not change, the air in the room since heat is pulled away,
Temperature decline, cold air blow out via the air outlet 25 of the air conditioner indoor unit 1 ' and are sent into the room.The refrigerant
Through being entered in the compressor 5 ' by first shut-off valve 31 ' and the four-way reversing valve 4 ' after the interior is gasified,
By the compressor 5 ' be compressed into high temperature, high pressure gas after be drained into the outdoor heat exchanger of the outdoor air-conditioner 2 ' with
Outdoor air carries out heat exchange, and the refrigerant is cooled into the liquid of medium temperature high pressure.After outdoor air absorbs heat, temperature is increased
It is discharged in external environment by the outdoor fan 22 '.It is first passed through by the medium temperature highly pressurised liquid that the outdoor heat exchanger comes out described
Second filter 36 ' makes its temperature, pressure drop to original by the decompression cooling of the first capillary 38 ' described in throttling set
The low temperature come, using the check-valves 37 ', the first filter 35 ', second silencer 34 ', described
First silencer 33 ' and second shut-off valve 32 ' return in the Indoor Thermal superconductive heat exchanger 1.
When the ultra-thin heat pump type air conditioner system heating operation, change the stream of the refrigerant by the four-way reversing valve 4 '
To the function of air conditioner indoor unit 1 ' described in conversion two season of summer in winter and the air-conditioner outdoor unit 2 '.When winter heating, from the outdoor
The high-temperature high-pressure refrigerant gas that heat exchanger comes out is arranged to the Indoor Thermal superconductive heat exchanger 1, through by described the after condensation
One capillary 38 ' and second capillary 39 ' arrange the refrigerant of low-temp low-pressure to the outdoor heat exchanger, by absorption chamber outside
The refrigerant evaporation of liquid at other, is entered back into the compressor 5 ' and carries out next circulation by the heat of environment.It needs to illustrate
, when refrigerating capacity deficiency, need to open the auxiliary heater 93 and generate heat, the heat that the auxiliary heater 93 generates
Air after heating is discharged into interior via the air outlet 25 by the indoor fan 41 by amount.
The described first hot superconduction in the Indoor Thermal superconductive heat exchanger 1 in the air conditioner indoor unit 1 ' of the invention is changed
Hot plate 11 uses hot super heat conduction, and each regional temperature of entire plate face can be made uniform, has that heat conduction rate is fast, uniform temperature is good
Feature;The described first hot superconduction heat exchange plate in the Indoor Thermal superconductive heat exchanger 1 of the air conditioner indoor unit 1 ' of the invention
11 use hot super heat conduction, and the heat exchange efficiency of the Indoor Thermal superconductive heat exchanger 1 is high, thickness is smaller, compact-sized, air-conditioning
The whole thickness of indoor unit 1 ' is smaller;Described in Indoor Thermal superconductive heat exchanger 1 described in the air conditioner indoor unit 1 ' of the invention
First radiating fin 12 and the air duct that the described first hot superconduction heat exchange plate 11 is formed are smooth, windage is smaller;The room of the invention
Refrigerant heat exchange area is big in interior hot superconductive heat exchanger 1, efficiency with higher;In Indoor Thermal superconductive heat exchanger 1 of the invention
It is the first annular seal space room 113 and second sealed chamber 117 inside the first hot superconduction heat exchange plate 11, and described
First deflector 114 and second water conservancy diversion are respectively set in first annular seal space room 113 and second sealed chamber 117
Plate 118, first deflector 114 and second deflector 118 play booster action, make first cover board 110, institute
The thickness for stating the second cover board 112 and the third cover board 116 can be thinned, and bearing capacity increases, and intensity improves, and mitigate the sky
The weight and thickness of indoor unit 1 ', and the heat exchange area inside increase are adjusted, hot superconductive radiating ability is enhanced;The sky of the invention
Adjust the fin protrusion 121 in first radiating fin 12 in the Indoor Thermal superconductive heat exchanger 1 in indoor unit 1 '
Horizontally spaced arrangement, the surface temperature of the Indoor Thermal superconductive heat exchanger 1 generate cold when being lower than air dew point temperature
Condensate can be smoothly discharged.
Embodiment two
Incorporated by reference to Figure 13 to Figure 23 refering to Figure 24 to Figure 25, the present embodiment also provides a kind of air conditioner indoor unit 1 ', this implementation
The structure of air conditioner indoor unit 1 ' described in example is roughly the same with the structure of air conditioner indoor unit 1 ' described in embodiment one, the two
Difference be that the structure of first radiating fin 12 is different;Specifically, the first radiating fin 12 described in embodiment one wraps
The fin protrusion 121 of several horizontally spaced arrangements is included, the bottom one of the adjacent fin protrusion 121 in horizontal direction
Body connects, i.e., several described fin protrusions 121 in described first radiating fin 12 extend along the vertical direction;And the present embodiment
Described in the first radiating fin 12 include several fin protrusions 121 for being intervally arranged along the vertical direction;It is adjacent on vertical direction
The bottom integrally connected of the fin protrusion 121, i.e., several described 121 edges of fin protrusion in described first radiating fin 12
Horizontal (or level of approximation) direction extends.
As an example, the extending direction of the fin protrusion 121 tilts default folder compared to horizontal direction in the present embodiment
Angle, the default angle are greater than 0 ° and less than 90 °.In first radiating fin 12 in air conditioner indoor unit 1 ' of the invention
The fin protrusion 121 is intervally arranged along the vertical direction and the extending direction of the fin protrusion 121 inclines compared to horizontal direction
Tiltedly default angle, the surface temperature of the Indoor Thermal superconductive heat exchanger 1 is lower than the condensed water that generates when air dew point temperature can be with
It is smoothly discharged.
Embodiment three
Incorporated by reference to Fig. 1 to Figure 23 refering to Figure 26 to Figure 34, the present embodiment also provides a kind of air conditioner indoor unit 1 ', in this implementation
The structure of the air conditioner indoor unit 1 ' is roughly the same with the structure of air conditioner indoor unit 1 ' described in embodiment one kind, the area of the two
Be not: the described first hot superconduction heat exchange plate 11 in Indoor Thermal superconductive heat exchanger 1 described in embodiment one is soldering formula the
One hot superconduction heat exchange plate, and the hot first hot superconduction heat exchange plate 11 of institute in Indoor Thermal superconductive heat exchanger 1 described in the present embodiment
For the hot superconduction heat exchange plate 11 of inflation type first.
As an example, please referring to Figure 27, the Indoor Thermal superconductive heat exchanger 1 includes the first plate 1191, the second plate
1192 and third plate 1193, first plate 1191, second plate 1192 and the third plate 1193 successively fold
It sets and is combined with each other by rolling process;The first sealing heat transfer path 1133 and first refrigerant passage 1174 are logical
Blowing-up technology is crossed to be formed;The first sealing heat transfer path 1133 is located at first plate 1191 and second plate 1192
Between, first refrigerant passage 1174 is between second plate 1192 and the third plate 1193;The heat is super
Conduction heat transfer working medium 1134 is filled in the first sealing heat transfer between first plate 1191 and second plate 1192
In channel 1133;First protrusion corresponding with the first sealing heat transfer path 1133 is formed on first plate 1191
Structure 11911 is formed with second bulge-structure corresponding with first refrigerant passage 1174 on the third plate 1193
11931。
As an example, the shape of the first sealing heat transfer path 1133 may include hexagonal honeycomb shape, round honeycomb
Shape, quadrangle honeycomb, at least one of multiple U-shapeds, diamond shape, triangle and circular ring shape of head and the tail concatenation or at least two
Any combination.
As an example, the shape of first refrigerant passage 1174 can be with the shape of the first sealing heat transfer path 1133
Shape is identical, and the shape of first refrigerant passage 1174 can also be different from the first sealing shape of heat transfer path 1133.
In one example, the first sealing heat transfer path 1133 and first refrigerant passage 1174 as described in Figure 26 and Figure 28
Shape can be identical, and be hexagonal honeycomb shape, and first sealing 1133 overlay area of heat transfer path and described the
The area of one refrigerant passage, 1174 overlay area is identical.
In another example, as shown in Figure 29 to Figure 31, the shape and described the of the first sealing heat transfer path 1133
The shape of one refrigerant passage 1174 may each comprise hexagonal honeycomb shape, and the shape of 1174 overlay area of the first refrigerant passage
Shape can be U-shaped.
In another example, such as Figure 32 to Figure 34, the shape of the first sealing heat transfer path 1133 and described first cold
The shape in matchmaker channel 1174 may each comprise hexagonal honeycomb shape, and the area of 1174 overlay area of the first refrigerant passage is less than
The area of first sealing, 1133 overlay area of heat transfer path.
Certainly, in other examples, first refrigerant passage 1174 can also return loop structure into single channel including single channel,
Or multichannel returns loop structure into multichannel, can also be parallel loop structure.
As an example, the Indoor Thermal superconductive heat exchanger 1 further includes several backing plates 18, the backing plate 18 is located at the room
Between interior hot superconductive heat exchanger 11 and first radiating fin 12.
In conclusion the present invention provides a kind of ultra-thin heat pump type air conditioner system, the ultra-thin heat pump type air conditioner system includes:
Air conditioner indoor unit, the air conditioner indoor unit include an at least Indoor Thermal superconductive heat exchanger, and the Indoor Thermal superconductive heat exchanger includes
Several the first hot superconduction heat exchange plates and several first radiating fins;Is each formed in each first hot superconduction heat exchange plate
One sealing heat transfer path, the first refrigerant passage, the first refrigerant inlet and the first refrigerant exit;In the first sealing heat transfer path
Filled with hot superconductive heat transfer working medium;First refrigerant inlet and first refrigerant exit with the first refrigerant passage phase
Connection;Several described first radiating fins are arranged alternately with the described in several first hot superconduction heat exchange plate, and are adhered on described
The surface of first hot superconduction heat exchange plate;Air-conditioner outdoor unit, the air-conditioner outdoor unit include outdoor refrigerant pipeline;Coolant connecting tube
Road, between the air conditioner indoor unit and the outdoor machine of air-conditioner, with first refrigerant passage and the outdoor refrigerant pipeline
It is connected, to form refrigerant circulation circuit.The Indoor Thermal of air conditioner indoor unit in ultra-thin heat pump type air conditioner system of the invention is super
The first hot superconduction heat exchange plate in heat exchanger is led using hot super heat conduction, each regional temperature of entire plate face can be made uniform, had
Have the characteristics that heat conduction rate is fast, uniform temperature is good;The Indoor Thermal of air conditioner indoor unit in ultra-thin heat pump type air conditioner system of the invention
The first hot superconduction heat exchange plate in superconductive heat exchanger uses hot super heat conduction, the heat exchange efficiency of Indoor Thermal superconductive heat exchanger
Height, thickness are smaller, compact-sized, and the thickness of air conditioner indoor unit entirety is smaller;In ultra-thin heat pump type air conditioner system of the invention
The air duct that the first radiating fin and the first hot superconduction heat exchange plate are formed in Indoor Thermal superconductive heat exchanger in air conditioner indoor unit is smooth, wind
It hinders smaller.
The above-described embodiments merely illustrate the principles and effects of the present invention, and is not intended to limit the present invention.It is any ripe
The personage for knowing this technology all without departing from the spirit and scope of the present invention, carries out modifications and changes to above-described embodiment.Cause
This, institute is complete without departing from the spirit and technical ideas disclosed in the present invention by those of ordinary skill in the art such as
At all equivalent modifications or change, should be covered by the claims of the present invention.