CN111442413A - Integrated air conditioner - Google Patents

Abstract

The present invention provides an integrated air conditioner, comprising: the indoor air inlet and the indoor air outlet are formed in the shell on the indoor side, and the outdoor air inlet and the outdoor air outlet are formed in the shell on the outdoor side; the laminar flow fan is arranged in the indoor side and is provided with an air inlet channel; wherein the indoor air passes through indoor air intake reachs inlet air duct, laminar flow fan passes through fluid viscosity effect disturbance entering inlet air duct the indoor air forms laminar flow wind, laminar flow wind passes through indoor air outlet discharges the casing reachs indoorly. The integrated air conditioner has low noise and good user experience.

Description

Integrated air conditioner

Technical Field

The invention relates to the technical field of air conditioning, in particular to an integrated air conditioner.

Background

The traditional integrated air conditioner is generally a through-flow air supply system or a centrifugal air supply system, and the air outlet direction is in the front. Although the air deflector is used for guiding the air left and right and the louver is used for guiding the air up and down, the air deflector is limited by a volute structure, the left and right air supply angle is less than 80 degrees, the up and down air supply angle is less than 100 degrees, and only one air outlet is arranged, so the air supply range is very limited. Meanwhile, as the strip-shaped air outlet is used, the phenomenon that the air is directly blown to people is serious. In addition, in the current cross-flow fan air supply system and centrifugal air supply system, the periodic impact airflow of the blades can generate obvious rotation noise. The volute is matched with the fan to achieve the air supply effect, and the volute tongue can impact air flow to generate strong turbulence noise. Under the limit of performance indexes, the noise value is close to the limit, and the noise quality is difficult to obviously improve in the prior art.

Disclosure of Invention

One object of the present invention is to provide an integrated air conditioner with low noise, high air volume and high air pressure during air supply.

A further purpose of the present invention is to enable the indoor side of the integrated air conditioner to achieve 360 ° uniform air supply, thereby improving the user experience of the integrated air conditioner.

In particular, the present invention provides an integrated air conditioner including:

the indoor air inlet and the indoor air outlet are formed in the shell on the indoor side, and the outdoor air inlet and the outdoor air outlet are formed in the shell on the outdoor side; and

the laminar flow fan is arranged in the indoor side and is provided with an air inlet channel; the indoor air reaches the air inlet channel through the indoor air inlet, the laminar flow fan disturbs the indoor air entering the air inlet channel through the fluid viscosity effect to form laminar flow air, and the laminar flow air is discharged out of the shell through the indoor air outlet to reach the indoor.

Optionally, the casing on the indoor side is provided with an indoor air outlet around the laminar flow fan.

Optionally, the integrated air conditioner further comprises:

the first heat exchanger is arranged on the indoor side and used for exchanging heat with indoor air entering the indoor side through the indoor air inlet, and the indoor air after heat exchange through the first heat exchanger reaches the air inlet channel.

Optionally, the integrated air conditioner further comprises:

the air supply fan is arranged outside the room; and

the second heat exchanger is arranged at the outdoor side and is used for exchanging heat with outdoor air entering the outdoor side through the outdoor air inlet;

the air supply fan drives outdoor air to pass through the outdoor air inlet, exchange heat through the second heat exchanger and then be discharged out of the shell through the outdoor air outlet to the outdoor.

Optionally, the air supply fan is a centrifugal fan.

Optionally, the first heat exchanger is an evaporator, and the second heat exchanger is a condenser;

the integral type air conditioner still includes: a compressor for compressing a refrigerant;

the condenser is used for condensing the refrigerant from the compressor;

the evaporator is connected to the condenser for returning the refrigerant to the compressor.

Optionally, the laminar flow fan comprises:

the laminar flow fan comprises a plurality of annular discs, the annular discs are arranged in parallel at intervals, have the same central axis and have the centers which form an air inlet channel together, and indoor air enters the air inlet channel and reaches gaps among the annular discs; and

and the motor is configured to drive the plurality of annular discs to rotate, so that the air boundary layer close to the surfaces of the plurality of annular discs is driven by the plurality of rotating annular discs to rotate from inside to outside to form laminar wind.

Optionally, the laminar flow fan further comprises:

a driving disk arranged in parallel with the plurality of annular disks at intervals; and

a connecting member penetrating the drive disk and the plurality of annular disks to connect the plurality of annular disks to the drive disk;

the motor is configured to directly drive the drive disk to rotate, and the drive disk drives the plurality of annular disks to rotate.

Optionally, the connecting piece is a blade, and the cross section of the blade is provided with a double-arc protruding towards the rotating direction of the annular disk, and the double-arc comprises an inner arc and a back arc which are sequentially arranged along the rotating direction of the annular disk; wherein the content of the first and second substances,

the inner arc and the back arc have different circle centers and both ends are crossed, or

The inner arc and the back arc have the same circle center and are arranged in parallel.

Optionally, the annular disc is arranged according to one or more of the following structures:

the distance between two adjacent annular disks is gradually increased along the flowing direction of the airflow in the air inlet channel;

the inner diameters of the plurality of annular disks are gradually reduced along the flowing direction of the airflow in the air inlet channel;

each annular disk is an arc-shaped disk which is gradually close to the driving disk from the inner side to the outer side.

According to the integrated air conditioner, the laminar flow fan is arranged in the indoor side shell, indoor air is disturbed by the laminar flow fan through the fluid viscosity effect to realize laminar flow air supply, the air supply process is low in noise, high in air volume and high in air pressure, and the use experience of a user of the integrated air conditioner is effectively improved.

Furthermore, the integrated air conditioner provided by the invention has the advantages that the indoor air outlet is arranged on the casing at the indoor side around the laminar flow fan for one circle, air is discharged from four sides, the air outlet range is enlarged, and 360-degree uniform air supply is realized.

The above and other objects, advantages and features of the present invention will become more apparent to those skilled in the art from the following detailed description of specific embodiments thereof, taken in conjunction with the accompanying drawings.

Drawings

Some specific embodiments of the invention will be described in detail hereinafter, by way of illustration and not limitation, with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar elements or components. Those skilled in the art will appreciate that the drawings are not necessarily drawn to scale. In the drawings:

fig. 1 is a schematic perspective view of an integrated air conditioner according to an embodiment of the present invention.

Fig. 2 is a schematic perspective view of another angle of the integrated air conditioner shown in fig. 1.

Fig. 3 is a schematic exploded view of the integrated air conditioner shown in fig. 1.

Fig. 4 is a schematic plan view of a part of components of the integrated type air conditioner shown in fig. 1.

Fig. 5 is a schematic perspective view of an integrated air conditioner according to another embodiment of the present invention.

Fig. 6 is a schematic perspective view of an integrated air conditioner according to still another embodiment of the present invention.

Fig. 7 is a schematic plan view of a part of components of the integrated type air conditioner shown in fig. 6.

Fig. 8 is a schematic perspective view of an evaporator and a water collector of an integrated air conditioner according to an embodiment of the present invention.

Fig. 9 is a schematic perspective view of a bottom cover and a water collector of an integrated air conditioner according to an embodiment of the present invention.

Fig. 10 is a schematic perspective view of a wind shield of the integrated type air conditioner according to one embodiment of the present invention.

Fig. 11 is a schematic perspective view of a fixing plate of an integrated type air conditioner according to an embodiment of the present invention.

Fig. 12 is a schematic perspective view of a laminar flow fan of an air conditioner according to an embodiment of the present invention.

Fig. 13 is a schematic diagram of the blowing principle of the laminar flow fan of the air conditioner shown in fig. 1.

Fig. 14 is a speed distribution and force distribution diagram of a laminar flow fan of the air conditioner shown in fig. 1.

Fig. 15 is a schematic cross-sectional view of the laminar flow fan shown in fig. 12.

Fig. 16 is a schematic perspective view of another perspective view of the laminar flow fan shown in fig. 12.

Fig. 17 is a schematic perspective view of still another perspective view of the laminar flow fan shown in fig. 12.

Fig. 18 is a schematic sectional view of a fixing mechanism, a motor and a laminar flow fan of an air conditioner according to an embodiment of the present invention in cooperation.

Fig. 19 is a schematic exploded view of a motor and a fixing mechanism of an air conditioner according to an embodiment of the present invention.

Fig. 20 is a schematic front view of a laminar flow fan of an air conditioner according to an embodiment of the present invention.

Fig. 21 is a schematic perspective view of another perspective of the laminar flow fan shown in fig. 20.

Fig. 22 is a schematic view of the air circulation of the laminar flow fan shown in fig. 20.

Fig. 23 is a schematic cross-sectional view of the laminar flow fan shown in fig. 20.

Fig. 24 is a schematic diagram of the relationship between the chord length of the blade of the laminar flow fan shown in fig. 20 and the air volume and the air pressure.

Fig. 25 is a schematic cross-sectional view of a laminar flow fan of an air conditioner having a double arc blade according to an embodiment of the present invention.

Fig. 26 is a schematic view showing the relationship between the installation angle of the double circular arc blade and the air volume and the wind pressure.

Fig. 27 is a schematic cross-sectional view of a laminar flow fan of an air conditioner having an aviation blade according to one embodiment of the present invention.

FIG. 28 is a schematic view showing the relationship between the installation angle of the aviation blade and the air volume and the air pressure.

Fig. 29 is a schematic front view of a laminar flow fan in which a pitch of ring disks of a laminar flow fan of an air conditioner is gradually changed according to an embodiment of the present invention.

Fig. 30 is a schematic perspective view of the laminar flow fan shown in fig. 29.

Fig. 31 is a schematic diagram of the relationship between the gradual pitch change of the multiple annular disks and the air volume and the air pressure of the laminar flow fan shown in fig. 29.

Fig. 32 is a schematic cross-sectional view of a laminar flow fan having a gradually changing inner diameter of an annular disk of a laminar flow fan of an air conditioner according to an embodiment of the present invention.

Fig. 33 is a schematic diagram of the relationship between the inner diameter gradient of a plurality of annular disks and the air volume and the air pressure of the laminar flow fan shown in fig. 32.

Fig. 34 is a schematic central angle view of an inner and outer diameter connecting line of a plurality of annular disks of a laminar flow fan of which the annular disks of a laminar flow fan of an air conditioner are arc-shaped disks on the same longitudinal section passing through a central axis according to an embodiment of the present invention.

Fig. 35 is a schematic diagram showing the relationship between the central angle of the laminar flow fan shown in fig. 34 and the air volume and the air pressure.

Detailed Description

Fig. 1 is a schematic perspective view of an integrated air conditioner 100 according to one embodiment of the present invention. Fig. 2 is a schematic perspective view of another angle of the integrated air conditioner 100 shown in fig. 1. Fig. 3 is a schematic exploded view of the integrated air conditioner 100 shown in fig. 1. Fig. 4 is a schematic plan view of part of the components of the integrated air conditioner 100 shown in fig. 1. The integrated air conditioner 100 according to the embodiment of the present invention is a window type air conditioner, and may generally include a housing 200 and a laminar flow fan 110. The interior of the casing 200 is divided into an indoor side 210 and an outdoor side 220, the casing 200 of the indoor side 210 is provided with an indoor air inlet 211 and an indoor air outlet 212, and the casing 200 of the outdoor side 220 is provided with an outdoor air inlet 221 and an outdoor air outlet 222. The laminar flow fan 110 is disposed in the indoor side 210, and an air inlet channel is formed at the center thereof; the indoor air reaches the air inlet channel through the indoor air inlet 211, the laminar flow fan 110 disturbs the indoor air entering the air inlet channel through a fluid viscosity effect to form laminar flow air, and the laminar flow air is discharged out of the casing 200 through the indoor air outlet 212 to reach the indoor. The integrated air conditioner 100 of the embodiment of the invention has the advantages that the laminar flow fan 110 is arranged in the shell 200 of the indoor side 210, the laminar flow fan 110 is used for disturbing indoor air through the fluid viscosity effect to realize laminar flow air supply, the air supply process is low in noise, high in air quantity and air pressure, novel in appearance and good in function, and the user experience can be obviously improved.

In some embodiments, the casing 200 of the indoor side 210 of the integrated air conditioner 100 of the embodiment of the present invention is provided with an indoor air outlet 212 around the laminar flow fan 110. The integrated air conditioner 100 of the embodiment of the invention has the indoor air outlet 212 arranged around the laminar flow fan 110 by the casing 200 at the indoor side 210, so that air is exhausted from four sides, the air outlet range is enlarged, the air is prevented from blowing directly to users, and 360-degree uniform air supply is realized. When the air guide plate 213 is used for guiding air, the air can be prevented from blowing out directly, and a good air supply effect is achieved.

In some embodiments, the integrated air conditioner 100 of the embodiment of the present invention further includes: the first heat exchanger is arranged on the indoor side 210 and used for exchanging heat with indoor air entering the indoor side 210 through the indoor air inlet 211, and the indoor air after heat exchange through the first heat exchanger reaches the air inlet channel. Indoor air enters from the indoor air inlet 211, is subjected to heat exchange by the first heat exchanger, and is turned by 90 degrees in the laminar flow fan 110 and then is discharged from the circumferential direction of the laminar flow fan 110.

In some embodiments, the integrated air conditioner 100 of the embodiment of the present invention further includes: a supply air fan 600 and a second heat exchanger. The blower fan 600 is provided on the outdoor side 220. The second heat exchanger is disposed at the outdoor side 220 for exchanging heat with outdoor air entering the outdoor side 220 through an outdoor air inlet 221. The blower fan 600 drives the outdoor air to pass through the outdoor air inlet 221, exchange heat with the second heat exchanger, and then be discharged out of the casing 200 through the outdoor air outlet 222 to the outdoor. Preferably, the supply fan 600 is a centrifugal fan 610.

In some embodiments, the first heat exchanger of the integrated air conditioner 100 of the embodiment of the present invention is the evaporator 120, and the second heat exchanger is the condenser 700. The integrated air conditioner 100 of the embodiment of the present invention further includes: a compressor 140 for compressing a refrigerant; the condenser 700 serves to condense the refrigerant from the compressor 140; the evaporator 120 is connected to the condenser 700 to return the refrigerant to the compressor 140.

Fig. 1 is a schematic perspective view of an integrated air conditioner 100 according to one embodiment of the present invention. Fig. 5 is a schematic perspective view of an integrated air conditioner 100 according to another embodiment of the present invention. In one embodiment, an integrated air conditioner 100 of an embodiment of the present invention includes: the double-suction centrifugal fan comprises a shell 200, a partition plate 160, an evaporator 120, a water receiving tray 130, a purification mechanism 800, a laminar flow fan 110, a fixing mechanism 401, a wind shield 500, a wind deflector 213, a compressor 140, an electric appliance box 150, a double-suction centrifugal fan 610, a volute 611 and two condensers 700.

The housing 200 includes a left cover plate 203 and a right cover plate 204. The housing body is a split structure, and includes an upper housing 201 and a bottom housing 202, having a front side, an upper side, a rear side and a lower side, and having openings at left and right sides thereof, respectively. The left cover plate 203 closes the opening on the left side, and the right cover plate 204 closes the opening on the right side. The partition 160 is longitudinally disposed within the housing body, and an indoor side 210 is defined between the left cover plate 203, the left portions of the upper and lower cases 201 and 202, and the partition 160, and an outdoor side 220 is defined between the partition 160, the right portions of the upper and lower cases 201 and 202, and the right cover plate 204.

The evaporator 120, the purification mechanism 800, the laminar flow fan 110, and the fixing mechanism are provided in this order from left to right on the indoor side 210.

The evaporator 120 evaporates the refrigerant in a low-temperature and low-pressure state to exchange heat with indoor air, thereby generating condensed water. The mating evaporator 120 is provided with a drip tray 130. The water pan 130 is disposed on the bottom shell 202 and located at the bottom of the evaporator 120 for receiving the condensed water. The evaporator 120 may be a straight plate type evaporator 121, a V-type evaporator 122, or other type of evaporator. In some embodiments, the evaporator 120 is a straight plate type evaporator 121 having a square cross section; the drip tray 130 has a square groove matching the cross section of the straight plate type evaporator 121. In other embodiments, evaporator 120 is a V-shaped evaporator 122 having a V-shaped cross-section; the V-shaped evaporator 122 has two sides and a tip formed by the intersection of the two sides, and the distance from the tip to the laminar flow fan 110 is greater than the distance from the two sides to the laminar flow fan 110; the drip tray 130 has a V-shaped groove that matches the cross-section of the V-shaped evaporator 122. Fig. 8 is a schematic perspective view of an evaporator 120 and a water tray 130 of the integrated air conditioner 100 according to an embodiment of the present invention. Fig. 9 is a schematic perspective view of a bottom cover and a water tray 130 of the integrated air conditioner 100 according to an embodiment of the present invention. The water receiving tray 130 can be fixed on the bottom case 202 by arranging the positioning column 131 on the bottom case 202. The heat exchange area can be maximized in a limited space by using the V-shaped evaporator 122, the heat exchange area is increased, and the overall efficiency is improved, wherein the V-shaped angle can be 90-175 degrees, such as 90-120 degrees, 120-150 degrees, and further such as 110 degrees, 140 degrees, and 115 degrees.

The indoor air inlet 211 of the integrated air conditioner 100 according to the embodiment of the present invention may include: a first air inlet 231 formed on the left cover plate 203, and a second air inlet 232 formed on the upper case 201 and/or the bottom case 202 between the left cover plate 203 and the evaporator 120. Also, the first intake vent 231 is preferably a micro-hole intake vent, and the second intake vent 232 is preferably an elongated hole. The second air inlet 232 is preferably provided with a plurality of air deflectors 213. The wind deflector 213 guides the wind to prevent the wind from blowing directly to the user. In order to increase the intake air volume and improve the air supply efficiency, it is preferable that the left cover plate 203 and the upper case 201 and the bottom case 202 between the left cover plate 203 and the evaporator 120 are provided with indoor air inlets 211.

The purification mechanism 800 is used for filtering air flowing through to output clean and healthy air to the indoor, and comprises a flexible purification block 801 and a purification bracket 802. The flexible purifying block 801 is used for filtering indoor air and is made of compressible soft materials. The purification bracket 802 is longitudinally arranged in the shell body, and the flexible purification block 801 is filled and fixed in the bracket. The flexible purification block 801 is plugged in the purification bracket 802 in an extrusion mode, which is very convenient.

The laminar flow fan 110 is formed at the center thereof with an air intake channel 302 configured to disturb the indoor air entering the air intake channel 302 by a fluid viscosity effect to form laminar flow wind. The laminar flow fan 110 includes a laminar flow fan 300 and a motor 400. Fig. 12 is a schematic perspective view of the laminar flow fan 300. The laminar flow fan 300 includes a plurality of annular disks 301, the plurality of annular disks 301 are spaced apart from each other and arranged in parallel, have the same central axis, and have centers that collectively form an air intake passage 302, and indoor air enters the air intake passage 302 to gaps between the plurality of annular disks 301. The motor 400 is connected to the laminar flow fan 300 and configured to drive the plurality of annular disks 301 to rotate, so that the air boundary layer 304 near the surfaces of the plurality of annular disks 301 is driven by the plurality of annular disks 301 to rotate from inside to outside to form laminar flow wind. Where air boundary layer 304 is a very thin layer of air adjacent to the surface of each disk.

Fig. 13 is a schematic diagram of the air supply principle of the laminar flow fan 110. The motor 400 drives the plurality of annular disks 301 to rotate at a high speed, and air in the intervals of the annular disks 301 contacts and moves mutually, so that the air boundary layer 304 close to the surfaces of the annular disks 301 is driven by the rotating annular disks 301 to rotate from inside to outside to form laminar air under the action of viscous shear force tau. Fig. 14 is a velocity distribution and force distribution diagram of the laminar flow fan 110 of the integrated air conditioner 100 according to the embodiment of the present invention, and is a schematic diagram of a viscous shear force distribution τ (y) and a velocity distribution u (y) to which the air boundary layer 304 is subjected. The viscous shear experienced by air boundary layer 304 is actually the resistance that the individual disks create to air boundary layer 304. The axis of abscissa in fig. 14 refers to the distance in the moving direction of air boundary layer 304, and the axis of ordinate refers to the height of air boundary layer 304 in the direction perpendicular to the moving direction. v. of_eThe velocity of the air flow at each point within air boundary layer 304, the thickness of air boundary layer 304, τ_wThe variables y in τ (y) and u (y) refer to the height of the cross-section of air boundary layer 304 in the direction perpendicular to the direction of travel, L the distance between a point on the inner circumference of annular disc 301 and a point on the surface of annular disc 301, then τ (y) is the distribution of viscous shear forces experienced at the height of the cross-section of air boundary layer 304 at distance L of y, and u (y) is the velocity distribution at the height of the cross-section of air boundary layer 304 at distance L of y.

The indoor air outlet 212 of the integrated air conditioner 100 according to the embodiment of the present invention is formed on one or more sides of the upper casing 201 and/or the bottom casing 202 of the circumference of the laminar flow fan 300. In some embodiments, the housing body is provided with indoor air outlets 212 on four sides thereof to form 360-degree air outlet. In some embodiments, a wind shield 500 is provided between the laminar flow fan 300 and the housing body. The wind shielding member 500 has a notch 501, and laminar air flows out of the housing 200 through the notch 501 and the indoor air outlet 212 to reach the indoor space. Preferably, in order to blow as much wind as possible out of the indoor outlet 212, the casing body is provided with the indoor outlet 212 only at a position thereof corresponding to the notch 501. The wind deflector 500 may define the gap 501 by using one and/or more than one wind deflector in combination. Fig. 10 is a schematic perspective view of a wind shielding member 500 of the unitary air conditioner 100 according to an embodiment of the present invention, the housing body having a front side, an upper side, a rear side and a lower side, on which an indoor wind outlet 212 is opened; the wind deflector 500 has an upper side, a rear side and a lower side, the front side of which is missing to define a notch 501. Fig. 6 is a schematic perspective view of an integrated air conditioner 100 according to still another embodiment of the present invention. Fig. 7 is a schematic plan view of part of the components of the integrated air conditioner 100 shown in fig. 6. Taking the V-shaped evaporator 122 as an example, the casing body may be provided with indoor air outlets 212 on the front side and the rear side, and wind shields are respectively disposed between the upper side and the lower side of the casing body and the laminar flow fan 300.

The laminar flow fan 300 further includes: drive disk 305 and link 306. The driver disks 305 are arranged in parallel with a plurality of annular disks 301 at a spacing. A connector 306 extends through the drive disk 305 and the plurality of ring disks 301 to connect the plurality of ring disks 301 to the drive disk 305. The motor 400 is configured to directly drive the drive disk 305 to rotate, and the drive disk 305 rotates the plurality of annular disks 301.

In some embodiments, the driving disk 305 of the laminar flow fan 300 is formed at the center thereof with a recess 351 toward the plurality of ring disks 301, and the motor 400 is fixedly disposed in the recess 351. Fig. 12 is a schematic perspective view of the laminar flow fan 300. Fig. 15 is a schematic cross-sectional view of the laminar flow fan 300 shown in fig. 12. Fig. 16 is a schematic perspective view of another view of the laminar flow fan 300 shown in fig. 12. Fig. 17 is a schematic perspective view of still another view angle of the laminar flow fan 300 shown in fig. 12.

A fixing mechanism 401 is disposed in the housing 200 for fixing the motor 400. Fig. 18 is a schematic cross-sectional view of the engagement of the fixing mechanism 401, the motor 400, and the laminar flow fan 300. Fig. 19 is a schematic exploded view of the motor 400 and the fixing mechanism 401. The fixing mechanism 401 includes a fixing plate 411 and a fixing frame 412, and the motor 400 is disposed between the fixing plate 411 and the fixing frame 412. The fixing plate 411 is longitudinally disposed between the upper case 201 and the bottom case 202. The fixing frame 412 has a main body 421 and a claw 422 extending from the main body 421 toward the fixing plate 411. The body 421 has a through hole 423, and an output shaft of the motor 400 extends out of the fixing frame 412 from the through hole 423 and is connected to the laminar flow fan 300. The claw 422 is fixed to the fixing plate 411 and is disposed to match the recess 351. A connection hole 352 is formed at the center of the recess 351, and an output shaft of the motor 400 is inserted into the connection hole 352 and fixed to the driving disk 305. The fixing plate 411 is provided with a plate attachment hole 414, the claw portion 422 is provided with a claw attachment hole 424, and the claw portion 422 and the fixing plate 411 are fixed by using a bolt or the like. Further, the fixing plate 411 is provided with a reinforcing rib 415. Fig. 11 is a schematic perspective view of a fixing plate 411 of the integrated air conditioner 100 according to an embodiment of the present invention.

An accommodation chamber is formed between the fixed plate 411 and the partition plate 160. A compressor 140 and an appliance case 150 are disposed in the receiving chamber. The compressor 140 serves to compress a refrigerant. A main control board is arranged in the electrical appliance box body 150.

An outdoor air inlet 221 is formed on the housing body between the partition 160 and the right cover plate 204, and the outdoor air inlet 221 forms two opposite air inlet sides on the housing body. The right cover plate 204 is provided with an outdoor air outlet 222.

The volute 611 is disposed between the two opposite air inlet sides, and has an inlet opposite to the outdoor air inlet 221 and an outlet facing the outdoor air outlet 222. The double-suction centrifugal fan 610 is disposed in the volute 611, and drives the outdoor air to enter the outdoor side 220 through the outdoor air inlet 221, and then the outdoor air is discharged from the outdoor air outlet 222 after turning around in the volute 611. The double-suction centrifugal fan 610 is adopted to suck air from the double air inlet sides, so that the efficiency is high.

Between the housing body and both sides of the scroll 611 are respectively provided a first plate condenser 710 and a second plate condenser 720 for condensing the compressed refrigerant to exchange heat with the outdoor air. It is understood that the integrated air conditioner 100 of the embodiment of the present invention may further include an expansion device, such as a capillary tube, for expanding the refrigerant condensed in the condenser 700 into a refrigerant of a low pressure state. The evaporator 120 of the indoor side 210 is provided corresponding to the condenser 700 of the outdoor side 220, so that the refrigerant in a low-temperature and low-pressure state from the expansion device is returned to the compressor 140.

In other embodiments, the drive disk 305 of the laminar flow fan 300 has a flat surface, and the motor 400 is fixedly disposed on the flat surface of the drive disk 305. Fig. 20 is a schematic front view of a laminar flow fan 110 with a drive disk 305 having a flat surface. Fig. 21 is a schematic perspective view of another perspective of the laminar flow fan 110 shown in fig. 20. In a preferred embodiment, an inverted conical protrusion 353 is further provided on a side surface of the driving disk 305 adjacent to the annular disk 301, and the inverted conical protrusion 353 can effectively guide the air entering the laminar flow fan 300 through the air inlet channel 302 into a gap between the disks, thereby improving the efficiency of forming laminar air.

Fig. 22 is a schematic view showing air circulation of the laminar flow fan 110 shown in fig. 20, in which air inlet passages 302 are formed at the centers of a plurality of annular disks 301 to allow air outside the laminar flow fan 300 to enter; a plurality of discharge ports 303 are formed in gaps between the plurality of annular disks 301 to blow out laminar air.

The connection 306 of the laminar flow fan 300 may be a blade 361, a connection rod 362, or the like.

Fig. 23 is a schematic cross-sectional view of the laminar flow fan 110 shown in fig. 20. In this embodiment, the connecting member 306 is a blade 361, and the cross section of the blade 361 has two curves sequentially arranged along the rotation direction of the annular disc 301, and the length of the chord 373 of the two curves has a linear relationship with the air volume of the laminar flow fan 110, so that the air volume of the laminar flow fan 110 can be greatly increased by increasing the length of the chord 373, and the laminar flow air circulation is promoted. It should be noted that the two curves may be arcs, non-arcs, straight lines, and the like, and the straight line may be a special curve. The length of the chord line 373 may be the distance between the two ends of the two curves, when the distance between the two ends of the two curves is the same. When the distances between the two end points of the two curves are different, if the two ends of the two curves are not intersected, the length of the chord line 373 may be the length of the connecting line of the middle points of the curves of the cross section of the blade 361 except the two curves; if only one end of the two curves intersects, the length of the chord line 373 may be the length of the line connecting the midpoint of the cross-section of the vane 361 except for the two curves and the end point of the intersection of the two curves.

In a preferred embodiment, the vanes 361 are plural and are evenly spaced throughout the drive disk 305 and the plurality of annular disks 301. The blades 361 uniformly penetrate through the driving disk 305 and the annular disks 301 at intervals, so that the driving disk 305 and the annular disks 301 can be stably connected, and further, when the motor 400 drives the driving disk 305 to rotate, the driving disk 305 can stably drive the annular disks 301 to rotate, and the working reliability of the laminar flow fan 110 is improved.

Fig. 24 is a schematic diagram showing the relationship between the length of the chord 373 and the wind pressure of the laminar flow fan 110 shown in fig. 20 when the outer diameter, the inner diameter, the number of layers, the pitch, the thickness, the installation angle of the blades 361, and the rotation speed of the motor 400 are all kept constant, wherein the abscissa axis refers to the length of the chord 373 of the blades 361, and the wind pressure refers to the pressure difference between the outlet 303 and the inlet of the air inlet channel 302. Note that the outer diameter of the annular disk 301 is the radius of its outer circumference, and the inner diameter is the radius of its inner circumference. The air boundary layer 304 rotates from inside to outside to form laminar wind, which moves centrifugally and thus leaves the outlet 303 at a higher velocity than the air entering the air inlet channel 302. The pressure difference between the outlet 303 and the inlet of the air intake channel 302 is the wind pressure, and the length of the chord 373 is in linear relation with the wind pressure. The wind pressure of the laminar flow fan 110 can be greatly improved by increasing the length of the chord 373, and the comprehensive performance of the laminar flow fan 110 is effectively guaranteed.

Considering the limited space inherent in the integrated air conditioner 100, there is a certain constraint on the overall occupied volume of the laminar flow fan 110. Specifically, considering that the thickness of the laminar flow fan 110 is not too large, the number of the annular disks 301, the distance between two adjacent annular disks 301, and the thickness of the annular disks 301 may be correspondingly constrained; the outer diameter of the annular disk 301 may be correspondingly constrained in view of the lateral footprint of the laminar flow fan 110 not being too large. For example, the outer diameter of each annular disc 301 may be set to 170mm to 180mm, and the inner diameter of each annular disc 301 is set to 110mm to 120mm, so that the air volume may be effectively increased, and the air outlet of the laminar flow fan 110 is ensured to meet the use requirements of users. When the outer diameter and the inner diameter of the annular disk 301 are constant, the longer the chord 373 is, the greater the air volume and the wind pressure of the laminar flow fan 110 are, but the length of the chord 373 is also restricted to a certain extent, so as to avoid the blade 361 from excessively penetrating the annular disk 301, which leads to the reduction of the stability of the laminar flow fan 110. In summary, the length of the chord 373 can be set to the maximum range that can be achieved, so that the wind volume and the wind pressure of the laminar flow fan 110 can meet the use requirements of users. In a preferred embodiment, the annular disk 301 has an outer diameter of 175mm, an inner diameter of 115mm, 8 layers, a pitch of 13.75mm, a thickness of 2mm, a blade 361 mounted at an angle of 25.5 °, and a motor 400 rotating at 1000rpm, it has been found that the wind volume and pressure are both greatly increased and substantially linear after increasing the length of the chord 373. The length of the chord 373 is set to a maximum range of 40mm to 42mm that can be achieved while ensuring the stability of the laminar flow fan 110. Moreover, when the length of the chord 373 is set to 42mm, the air volume of the laminar flow fan 110 can reach 1741m³And h, the wind pressure can reach 118.9Pa, and the use requirements of users can be completely met.

In some embodiments, the blade 361 may be a double arc blade 310, the cross section of which has a double arc convex toward the direction of rotation of the annular disk 301, and includes an inner arc 371 and a back arc 372 arranged in sequence along the direction of rotation of the annular disk 301, and the inner arc 371 and the back arc 372 have the same center and are arranged in parallel. Fig. 25 is a schematic cross-sectional view of a laminar flow fan 110 having a double-arc blade 310. In a preferred embodiment, the outer diameter of each annular disc 301 is 170mm to 180mm, the inner diameter of each annular disc 301 is 110mm to 120mm, the difference between the outer diameter and the inner diameter of each annular disc 301 is about 60mm, the distance between the two ends of the inner arc 371 and the distance between the two ends of the back arc 372 are the same, the length of the chord line 373 is the distance between the two ends of the inner arc 371 or the back arc 372 and is set to 40mm to 42mm, so that the two ends of the inner arc 371 and the back arc 372 are respectively 10mm away from the inner circumference and the outer circumference of the annular disc 301, and the length of the chord line 373 is set to the maximum range which can be reached under the premise of ensuring the stability of the laminar flow fan 110, so that the air volume and the air pressure of the laminar flow fan 110 can meet the use requirements of users.

Fig. 26 is a schematic diagram showing the relationship between the installation angle α of the double-arc blade 310 and the air volume and the wind pressure when the outer diameter, the inner diameter, the number of layers, the pitch, the thickness, the chord length of the double-arc blade 310 and the rotation speed of the motor 400 are all kept constant, and the abscissa axis refers to the installation angle of the double-arc blade 310, that is, an included angle formed by a chord line 373 between two end points of an inner arc 371 and a connecting line 374 passing through the midpoint of the chord line 373 and the central axis of the annular disk 301 on the same cross section of the double-arc blade 310 and the annular disk 301.

In other embodiments, the blade 361 may be an aviation blade 320, the cross section of which has a double arc convex toward the direction of rotation of the annular disk 301, and the double arc includes an inner arc 371 and a back arc 372 arranged in sequence along the direction of rotation of the annular disk 301, and the inner arc 371 and the back arc 372 have different centers and both ends intersect. Fig. 27 is a cross-sectional schematic view of a laminar flow fan 110 having aero blades 320.

Fig. 28 is a schematic diagram of the relationship between the installation angle α of the aviation blade 320 and the air volume and the air pressure when the outer diameter, the inner diameter, the number of layers, the pitch, the thickness, the chord length of the aviation blade 320 and the rotation speed of the motor 400 of the laminar flow fan 110 shown in fig. 27 are all kept unchanged, and the abscissa axis refers to the installation angle of the aviation blade 320, that is, the included angle formed by the chord 373 between the middle points of the inner arc 371 or the back arc 372 and the connecting line 374 passing through the middle point of the chord 373 and the central axis of the annular disk 301 on the same cross section of the aviation blade 320 and the annular disk 301.

The annular disk 301 of the laminar flow fan 300 may also be arranged according to one or more of the following configurations: the distance between two adjacent annular disks 301 is gradually increased along the flowing direction of air in the air inlet channel 302; the inner diameters of the plurality of annular disks 301 are gradually reduced along the flowing direction of the airflow in the air inlet channel 302; each annular disc 301 is an arc-shaped disc that gradually approaches the drive disc 305 from the inside to the outside.

In some embodiments, the plurality of annular disks 301 of the laminar flow fan 300 are arranged in parallel at intervals with the same central axis, and the interval between two adjacent annular disks 301 is gradually increased along the direction in which air flows in the air intake passage 302. Fig. 29 is a schematic front view of the laminar flow fan 110 in which the pitch of the annular disks 301 is gradually changed. The inventor finds that, through multiple experiments, as the distance between two adjacent annular disks 301 gradually increases along the flowing direction of air in the air inlet channel 302, the air volume of the laminar flow fan 110 can be effectively increased, so that the air outlet of the laminar flow fan 110 meets the use requirement of a user.

Taking the laminar flow fan 110 disposed at the upper portion in the housing 200 as an example, fig. 31 is a schematic diagram illustrating a relationship between gradual change of the pitch of the plurality of ring disks 301 and the air volume and the air pressure when the outer diameter, the inner diameter, the number, the thickness, and the rotation speed of the motor 400 of the laminar flow fan 110 shown in fig. 29 are all kept unchanged, wherein the abscissa axis refers to a change amount of the pitch between two adjacent ring disks 301 along the direction from bottom to top. As shown in fig. 31, when all the above mentioned parameters are kept unchanged, the distance between every two adjacent annular disks 301 in the plurality of annular disks 301 gradually changes from bottom to top, which has a large influence on the air volume and a small influence on the air pressure; when the variation of the distance between two adjacent annular disks 301 along the direction from bottom to top, which is represented by the abscissa axis, is a positive number, it is described that the distance between every two adjacent annular disks 301 in the plurality of annular disks 301 gradually increases from bottom to top; when the variation of the spacing between two adjacent annular disks 301 along the direction from bottom to top, which is represented by the abscissa axis, is a negative number, it indicates that the spacing between every two adjacent annular disks 301 in the plurality of annular disks 301 gradually decreases from bottom to top. Therefore, as can be seen from fig. 31, when the variation amount of the pitch between every two adjacent annular disks 301 of the plurality of annular disks 301 is-1 mm, 1mm and 2mm, the air volume and the air pressure of the laminar flow fan 110 are greatly improved.

As mentioned above, the connecting member 306 of the laminar flow fan 300 in the embodiment of the present invention may be a connecting rod 362. Fig. 30 is a schematic perspective view of the laminar flow fan 110 shown in fig. 29. The connecting rods 362 may be a plurality of rods, and are uniformly spaced throughout the edge portions of the drive disk 305 and the plurality of annular disks 301. The connecting rods 362 uniformly penetrate through the edge portions of the driving disk 305 and the annular disks 301 at intervals, so that the connection relationship between the driving disk 305 and the annular disks 301 can be ensured to be stable, and further, when the motor 400 drives the driving disk 305 to rotate, the driving disk 305 can stably drive the annular disks 301 to rotate, and the working reliability of the laminar flow fan 110 is improved. Meanwhile, when the connecting member 306 is the connecting rod 362, the rotation speed of the motor 400 is approximately linear with the air volume of the laminar flow fan 110, so that in a preferred embodiment, the motor 400 can be further configured to: the rotating speed of the motor 400 is determined according to the obtained target air volume of the laminar flow fan 110. That is, the target air volume of the laminar flow fan 110 may be obtained first, and then the rotation speed of the motor 400 may be determined according to a linear relationship between the target air volume and the rotation speed of the motor 400. The target air volume may be obtained by an input operation of the user. In a preferred embodiment, the outer diameter of the annular disc 301 is 175mm, the inner diameter is 115mm, the number of layers is 8, and the distance between two adjacent annular discs 301 is sequentially set from bottom to top: 13.75mm, 14.75mm, 15.75mm, 16.75mm, 17.75mm, 18.75mm, 19.75mm, when the thickness is 2mm, the linear relation between the rotating speed of the motor 400 and the air volume of the laminar flow fan 110 is more obvious.

In some embodiments, the inner diameters of the plurality of annular disks 301 of the laminar flow fan 300 of the embodiment of the present invention are gradually reduced along the direction of the airflow flowing in the air intake channel 302. Taking the laminar flow fan 300 disposed at the upper portion in the housing 200 as an example, fig. 32 is a schematic cross-sectional view of the laminar flow fan 300 in which the inner diameter of the annular disk 301 is gradually changed. Fig. 33 is a schematic diagram showing the relationship between the gradual change of the inner diameter of a plurality of ring disks 301 and the air volume and the air pressure when the outer diameter, the pitch, the number, the thickness and the rotation speed of the motor 400 of the laminar flow fan 110 having the laminar flow fan 300 shown in fig. 32 are all kept constant, wherein the abscissa axis refers to the change amount of the inner diameter of each ring disk 301 and the inner diameter of the ring disk 301 adjacent below. As shown in fig. 33, when the above mentioned parameters are all kept unchanged, the inner diameters of the plurality of annular disks 301 gradually change from bottom to top, which has a large influence on the air volume and a small influence on the air pressure. When the variation of the inner diameter of each annular disc 301 represented by the abscissa axis and the inner diameter of the adjacent annular disc 301 below is a positive number, it indicates that the inner diameters of the plurality of annular discs 301 gradually increase from bottom to top; when the variation of the inner diameter of each annular disc 301 and the inner diameter of the adjacent annular disc 301 below is negative, the inner diameters of the annular discs 301 gradually decrease from bottom to top. As shown in fig. 33, when the inner diameters of the plurality of annular disks 301 gradually decrease from bottom to top, the air volume increases and the air pressure decreases slightly; when the inner diameters of the plurality of annular disks 301 gradually increase from bottom to top, the wind pressure slightly increases, and the wind volume greatly decreases. In a preferred embodiment, the outer diameter of the annular disc 301 is 175mm, the maximum inner diameter of the annular disc 301 is 115mm, the distance is 13.75mm, the number is 8, the thickness is 2mm, the rotation speed of the motor 400 is 1000rpm, and then, considering the overall consideration of the air volume and the air pressure, the variation between the inner diameter of each annular disc 301 and the inner diameter of the adjacent annular disc 301 below may be set to-5 mm, that is, the inner diameters of the 8 annular discs 301 are respectively: 115mm, 110mm, 105mm, 100mm, 95mm, 90mm, 85mm, 80 mm.

In some embodiments, the annular disc 301 of the laminar flow fan 300 is an arcuate disc that gradually approaches the drive disc 305 from the inside to the outside. Taking the laminar flow fan 300 arranged at the upper part in the casing 200 as an example, each annular disc 301 is set to be an arc-shaped disc which gradually rises from inside to outside and protrudes upwards, so that the angle of the external air entering the laminar flow fan 300 is more consistent with the flow of the fluid, the external air entering the laminar flow fan 300 is more facilitated, the air volume loss is effectively reduced, and the air outlet of the laminar flow fan 110 is ensured to meet the use requirements of users. Fig. 34 is a schematic view of the central angle θ of the inner and outer diameter connecting lines of the plurality of annular disks 301 on the same longitudinal section passing through the central axis. Fig. 35 is a schematic diagram of the relationship between the central angle θ and the wind volume and wind pressure when the outer diameter, the number of layers, the pitch, the thickness of the annular disc 301 and the rotation speed of the motor 400 are all kept unchanged. As shown in fig. 35, when each of the above-mentioned parameters is kept constant, as the central angle θ is gradually increased, the air volume is increased and then decreased, and the air pressure is slightly increased. In a preferred embodiment, the annular disks 301 have an outer diameter of 175mm, a number of 10 layers, a pitch of 13.75mm, a thickness of 2mm, and a rotation speed of the motor 400 of 1000rpm, and the central angle θ may be set to 9 ° to 30 ° in consideration of the air volume and the wind pressure. And as shown in fig. 35, when the central angle θ is set to 15 °, the air volume of the laminar flow fan 110 reaches the maximum value.

Thus, it should be appreciated by those skilled in the art that while a number of exemplary embodiments of the invention have been illustrated and described in detail herein, many other variations or modifications consistent with the principles of the invention may be directly determined or derived from the disclosure of the present invention without departing from the spirit and scope of the invention. Accordingly, the scope of the invention should be understood and interpreted to cover all such other variations or modifications.

Claims (10)

1. An integrated air conditioner, comprising:

the indoor air inlet and the indoor air outlet are formed in the shell on the indoor side, and the outdoor air inlet and the outdoor air outlet are formed in the shell on the outdoor side; and

the laminar flow fan is arranged in the indoor side and is provided with an air inlet channel; wherein the indoor air passes through indoor air intake reachs inlet air duct, laminar flow fan passes through fluid viscosity effect disturbance entering inlet air duct the indoor air forms laminar flow wind, laminar flow wind passes through indoor air outlet discharges the casing reachs indoorly.

2. The unitary air conditioner according to claim 1,

the shell on the indoor side surrounds the laminar flow fan for a circle and is provided with the indoor air outlet.

3. The unitary air conditioner of claim 2, further comprising:

the first heat exchanger is arranged on the indoor side and used for exchanging heat with indoor air entering the indoor side through the indoor air inlet, and the indoor air after heat exchange of the first heat exchanger reaches the air inlet channel.

4. The unitary air conditioner of claim 3, further comprising:

an air supply fan disposed outside the chamber; and

the second heat exchanger is arranged on the outdoor side and used for exchanging heat with outdoor air entering the outdoor side through the outdoor air inlet;

the air supply fan drives the outdoor air to pass through the outdoor air inlet, the second heat exchanger exchanges heat and then the heat is discharged out of the shell through the outdoor air outlet to the outdoor.

5. The unitary air conditioner according to claim 4,

the air supply fan is a centrifugal fan.

6. The unitary air conditioner according to claim 4,

the first heat exchanger is an evaporator, and the second heat exchanger is a condenser;

the integrated air conditioner further includes: a compressor for compressing a refrigerant;

the condenser is used for condensing the refrigerant from the compressor;

the evaporator is correspondingly connected with the condenser and used for returning the refrigerant to the compressor.

7. The unitary air conditioner according to claim 2,

the laminar flow fan includes:

the laminar flow fan comprises a plurality of annular discs, the annular discs are arranged in parallel at intervals, have the same central axis and have centers which jointly form the air inlet channel, and the indoor air enters the air inlet channel and reaches gaps among the annular discs; and

and the motor is configured to drive the plurality of annular discs to rotate, so that the air boundary layer close to the surfaces of the plurality of annular discs is driven by the plurality of rotating annular discs to rotate and move from inside to outside to form the laminar wind.

8. The unitary air conditioner according to claim 7,

the laminar flow fan further includes:

a driving disk arranged in parallel with the plurality of annular disks at intervals; and

a connector extending through the drive disk and the plurality of annular disks to connect the plurality of annular disks to the drive disk;

the motor is configured to directly drive the drive disk to rotate, and the drive disk drives the plurality of annular disks to rotate.

9. The unitary air conditioner according to claim 8,

the connecting piece is a blade, the cross section of the blade is provided with a double-arc protruding towards the rotating direction of the annular disk, and the double-arc comprises an inner arc and a back arc which are sequentially arranged along the rotating direction of the annular disk; wherein the content of the first and second substances,

the inner arc and the back arc have different circle centers and the two ends are intersected, or

The inner arc and the back arc have the same circle center and are arranged in parallel.

10. The unitary air conditioner according to claim 8,

the annular disc is arranged according to one or more of the following structures:

the distance between two adjacent annular disks is gradually increased along the flowing direction of the airflow in the air inlet channel;

the inner diameters of the annular disks are gradually reduced along the flowing direction of the airflow in the air inlet channel;

each annular disc is an arc disc which is gradually close to the driving disc from the inner side to the outer side.

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