CN111854140A - Backflow heat exchange device for layered flow of air conditioner - Google Patents
Backflow heat exchange device for layered flow of air conditioner Download PDFInfo
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- CN111854140A CN111854140A CN202010746159.3A CN202010746159A CN111854140A CN 111854140 A CN111854140 A CN 111854140A CN 202010746159 A CN202010746159 A CN 202010746159A CN 111854140 A CN111854140 A CN 111854140A
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F13/00—Details common to, or for air-conditioning, air-humidification, ventilation or use of air currents for screening
- F24F13/30—Arrangement or mounting of heat-exchangers
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/89—Arrangement or mounting of control or safety devices
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F5/00—Air-conditioning systems or apparatus not covered by F24F1/00 or F24F3/00, e.g. using solar heat or combined with household units such as an oven or water heater
- F24F5/0042—Air-conditioning systems or apparatus not covered by F24F1/00 or F24F3/00, e.g. using solar heat or combined with household units such as an oven or water heater characterised by the application of thermo-electric units or the Peltier effect
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2221/00—Details or features not otherwise provided for
- F24F2221/34—Heater, e.g. gas burner, electric air heater
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- Combustion & Propulsion (AREA)
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Abstract
The invention discloses a backflow heat exchange device for layered flow of an air conditioner, which comprises a mixing cabin, a heating cabin, a fan assembly, a cooling cabin and a shunting cabin, wherein one end of the heating cabin is connected with the mixing cabin, the other end of the heating cabin is connected with the fan assembly, one end of the cooling cabin is connected with the other end of the fan assembly, the other end of the cooling cabin is connected with the shunting cabin, the shunting cabin is communicated with an air conditioning room, a fresh air pipe and at least two groups of return air pipes are arranged on the mixing cabin, the mixing cabin enables the fresh air to exchange heat with the return air in a spiral mode, and the heating cabin heats the air through a magnetocaloric effect.
Description
Technical Field
The invention relates to the technical field of backflow heat exchange, in particular to a backflow heat exchange device for layered flow of an air conditioner.
Background
Air conditioning (air conditioning) is a process of manually adjusting and controlling parameters such as temperature, humidity, cleanliness, and speed of ambient air in a building/structure. Generally comprises a cold source/heat source device, a cold and hot medium delivery and distribution system, a terminal device and other auxiliary devices. Mainly comprises a water pump, a fan and a pipeline system. The end device is responsible for specifically processing air by utilizing the cold and heat quantity from the transmission and distribution to ensure that the air parameters of the target environment meet the requirements.
The heat exchange system is an important component of the air conditioner, the device realizes the preliminary separation of impurities and air through the heat exchange process between fresh air and return air, realizes the separation of water drops with impurities and air, namely the fresh and return air, through the change of the air pressure and the flow rate of the fresh and return air when flowing, and compared with the traditional mode of filtering the air through a filter screen, the device has the advantages that the filtering mode is simpler, and the cleaning cost of the filter screen is saved.
Disclosure of Invention
The invention aims to provide a backflow heat exchange device for layered flow of an air conditioner, which aims to solve the problems in the prior art.
In order to achieve the purpose, the invention provides the following technical scheme: the backflow heat exchange device for layered flow of the air conditioner comprises a mixing cabin, a heating cabin, a fan assembly, a cooling cabin and a shunting cabin, wherein one end of the heating cabin is connected with the mixing cabin, the other end of the heating cabin is connected with the fan assembly, one end of the cooling cabin is connected with the other end of the fan assembly, the other end of the cooling cabin is connected with the shunting cabin, the shunting cabin is communicated with an air conditioning chamber, a fresh air pipe and at least two groups of return air pipes are arranged on the mixing cabin, the mixing cabin enables fresh air to exchange heat with return air in a spiral mode, and the heating cabin heats air through a magneto-thermal effect. The return air is cold air or hot air in the air conditioning room, the fresh air is external hot air or cold air, when the fresh air and the return air carry out spiral heat exchange in the mixing cabin, moisture in the fresh air or the return air is condensed into water and is mixed with impurities in the fresh air, so that the impurities are separated from the air, the mixing cabin enables water drops with the impurities in the air to be separated from the air through the change of an inner space, the heating cabin carries out frictional heat generation through a magnetocaloric effect and heats the air, the air temperature is increased, the fan assembly transmits the heated or unheated air to the cooling cabin, and the shunting cabin shunts the cooled air and transmits the cooled air to each air conditioning room respectively.
As the preferred technical scheme, be provided with helical blade in the hybrid tank, the hybrid tank below is provided with the blow off pipe, and the middle part in the hybrid tank outside sets up diaphragm, two sets of risers from last to down, diaphragm, two sets of risers and hybrid tank three mutually support and constitute the water storage tank in the hybrid tank outside, turn right from a left side on the diaphragm and be provided with inlet tube and booster pipe, water storage tank sprays water smoke to the hybrid tank. The mixing cabin provides space for mixing return air and fresh air, the spiral fan blades rotate in the mixing cabin under the drive of the return air, thereby leading the fresh air and the return air to generate spiral airflow in the mixing cabin, leading the impurities in the fresh air and the return air to be discharged out of the mixing cabin by the blow-off pipe, leading the transverse plate, the vertical plate and the mixing cabin to be mutually matched at the outer side of the mixing cabin to form a water storage cabin, leading the water storage cabin to mix water and spray water mist into the mixing cabin, impurities in fresh return air are separated from air by spraying water mist, water is infused into the water storage cabin through the water inlet pipe, air is infused into the water storage cabin through the pressure increasing pipe according to the height of the water level in the water storage cabin, air exhausted by the air conditioning system, namely exhaust air, is infused into the water storage cabin through the pressure increasing pipe, when the water level in the water storage chamber is high, the pressure increasing pipe infuses a small amount of exhaust gas into the water storage chamber, when the water level in the water storage chamber is low, the pressure increasing pipe infuses a large amount of exhaust gas into the water storage chamber, the amount and the speed of the water mist sprayed out of the water storage cabin are kept basically consistent by controlling the amount of the discharged air entering the water storage cabin.
As preferred technical scheme, turn right from a left side and divide into condensation cabin, accelerating tube, separation chamber, decompression cabin in proper order in the mixing chamber, spiral flabellum sets up in the condensation cabin, and spiral flabellum divide into loading board, a plurality of group spiral shell, a plurality of groups the spiral shell setting forms the condensation space that the aperture constantly reduces in loading board top, the intermediate position of loading board is provided with the air vent that the aperture constantly reduces, the aperture of air vent upper end with the aperture of condensation space lower extreme is the same, the internal position of condensation cabin is provided with a supporting bench below the loading board. The condensation cabin is new trend and return air mix and provides the space, the acceleration rate pipe makes new return air and the water droplet that has impurity obtain certain moving speed, the separation cabin provides the space for water droplet and air separation, the decompression cabin makes remaining water droplet and air separation under the gravity of self in the air, the loading board provides the support for the installation of spiral plate, spiral fan blade rotates in the condensation cabin under the promotion of return air, make return air and new trend rotate and constantly fuse the heat transfer in the condensation space, the condensation space through the continuous reduction in aperture improves the contact probability of impurity and water droplet in the new return air, thereby improve the separation effect of impurity and air.
As the preferred technical scheme, the aperture of acceleration tube is constantly dwindled from a left side to the right side, the aperture of disengagement chamber is constantly increased from a left side to the right side, the terminal surface is the arc terminal surface of turning the internal depression under the disengagement chamber, the blow off pipe sets up the summit department of terminal surface under the disengagement chamber, the top of disengagement chamber is provided with the spray pipe. The aperture of acceleration rate pipe constantly reduces, make the left atmospheric pressure increase of acceleration rate pipe, air on through fan subassembly extraction acceleration rate pipe right side, make acceleration rate pipe right side be the low pressure, the fresh air return obtains higher velocity of flow under the effect of the acceleration rate pipe that atmospheric pressure and aperture reduce, thereby make the fresh air return that has the water droplet improve flow velocity behind the acceleration rate pipe, make the water droplet that has high translation speed back and air separation in getting into the separate cabin, the fresh air return then up moves under the influence of fan subassembly in the space of low pressure, the water droplet with impurity after separating with the fresh air return falls in the separate cabin bottom and through blow off pipe discharge hybrid chamber, the spray pipe sprays water smoke to the separate cabin, further carry out impurity filtering to the fresh air return through water smoke.
As preferred technical scheme, the water storage cabin lower extreme is provided with the grommet, and the lower terminal surface inside of water storage cabin is provided with the water gauge valve, the water gauge valve includes shell, water yield board, shell intermediate position level is provided with the slide groove, and the shell right-hand member is provided with the apopore, the apopore runs through the shell, the water yield board is located the slide groove, is located the within range of apopore on the water yield board and is provided with a plurality of groups limbers, the left side that the slide inslot portion is located the water yield board is provided with the limiting plate, be provided with the spring between limiting plate and the water yield board, the spray pipe is connected with the shell pipe in the position and the shell. The grommet provides the support for rope pulling inner panel, the outlet channel of water storage cabin is controlled to the water yield valve, when water level was high in the water storage cabin, the outlet channel that the water yield valve made the water storage cabin reduces, when water level was low in the water storage cabin, the outlet channel increase of water storage cabin is made to the water yield valve, through the control of water yield valve to outlet channel, make the water yield of water storage cabin keep unanimous from beginning to end, the shell provides the support for the installation of water gauge board, the water gauge board is mutually supported with the shell and is controlled the outlet channel of water storage cabin, the apopore provides the passageway for the rivers in the water storage cabin pass through the shell, the limbers is controlled for rivers intake spray pipe, the limiting plate is injectd the shift position of water gauge board in the skateboard deck groove, the spring provides the power that resets for the water gauge board.
According to a preferable technical scheme, an airflow valve is arranged in the pressure increasing pipe and comprises a fixing ring, a casing and an inner plate, the side end face of the casing is fixed to the inner end face of the fixing ring, a sliding groove in a shape like a Chinese character mi is formed in the casing, at least six groups of airflow holes are arrayed in the sliding groove on the casing, a stretching hole is formed in the lower end face of the casing, the inner plate is in a shape like a Chinese character mi and is located in the sliding groove, the inner plate is connected with the casing in a sliding mode, a plurality of groups of air holes are formed in the inner plate in the range located in the airflow holes, at least six groups of springs are arranged in the casing in the position corresponding to the. The airflow valve controls the ventilation quantity of the pressurization pipe, when the water level in the water storage cabin is high, the airflow valve enables the pressurization pipe to infuse and exhaust gas with small flow quantity in the water storage cabin, when the water level in the water storage cabin is low, the airflow valve enables the pressurization pipe to infuse and exhaust gas with large flow quantity in the water storage cabin, the fixing ring fixes the shell, the shell provides support for the installation of the inner plate, the shell and the inner plate are matched with each other to control the ventilation quantity of the pressurization pipe, the shell and the inner plate are matched with each other to be equivalent to a throttling valve, the channel for the pressurization pipe to infuse air into the water storage cabin is increased through the arrangement of the rice-shaped sliding groove and the inner plate, the stretching hole provides a channel for the inner plate to be stretched.
According to the preferable technical scheme, a pull ring is arranged in the range of the stretching hole on the lower end face of the inner plate, a rope is arranged on the pull ring, the other end of the rope penetrates through the grommet and is provided with at least four groups of floats, a branch rope is arranged on the rope, and the other end of the branch rope is arranged in the sliding plate groove and is fixed with the water quantity plate. The pull ring is for the inner panel by tensile support that provides, and the rope is through the pull ring to the inner panel is tensile downwards to make the inner panel take place deformation in the cover shell, thereby make gas pocket and air current hole take place the dislocation, thereby make the ventilation capacity of pressure boost pipe reduce, the cursory floats in aqueous and provides tensile inner panel and the power that pulls the water gage board for the rope.
As preferred technical scheme, turn right constantly to increase from a left side in the inside aperture of decompression chamber, decompression chamber right-hand member and heating cabin pipe connection, be provided with four at least group heating element in the heating cabin, heating element includes friction shell, friction ball, the friction ball sets up in the friction shell, the preceding terminal surface of the heating cabin body corresponds the position of friction shell right half and is provided with the logical groove of admitting air, and the rear end face of the heating cabin body corresponds the position of friction shell left half and is provided with logical groove of giving vent to anger. The decompression chamber internal pressure reduces for impurity and air separate, and heating element rubs the themogenesis through the magnetocaloric effect, thereby heats fresh air return, and the friction shell provides the support for the installation of friction ball, and the friction ball rotates the friction in the friction shell under the drive of air current, and the logical groove of admitting air is connected decompression chamber and heating cabin, and logical groove of giving vent to anger is connected heating cabin and fan subassembly.
According to a preferable technical scheme, the friction shell is a hollow spherical shell, the friction ball is located inside the friction shell, a plurality of groups of friction plates are arranged on the outer surface of the friction ball, the end faces of the friction plates, which are in contact with the friction shell, are all magnet-embedded end faces, the inner end face of the friction shell is a magnet-embedded end face, and through holes are formed in the friction shell corresponding to the air inlet through groove and the air outlet through groove. The friction plate drives the friction ball to rotate in the friction shell under the driving of the air flow, the friction ball provides support for the installation of the friction plate, and the through hole provides a channel for the air flow to rub the friction shell.
As preferred technical scheme, it is two sets of the return air pipe sets up in the outside of condensation cabin, and two sets of return air pipes all communicate with the condensation cabin inside, from last down seeing, the contained angle between return air pipe and the condensation cabin is 30, sees from the look ahead, the contained angle between return air pipe and the condensation cabin is 50. The setting of angle makes the return air pipe and the approximate perpendicular between the spiral plate through with the condensation cabin for the air increases to the motive force of spiral plate in the return air pipe, makes the slew velocity of spiral air current improve in the condensation space.
Compared with the prior art, the invention has the beneficial effects that:
1. return air carries out the spiral heat transfer with the new trend in the hybrid chamber in this device to make new return air temperature reduce and produce water smoke, water smoke moves and constantly fuses into the water droplet in the spiral air current, and water smoke fuses the impurity in the new return air at the fusion in-process, thereby makes impurity and new return air separation, for ventilating through the filter screen and carry out filterable mode, this mode is simpler, still need not clear up the hybrid chamber in addition when brief filter screen cost.
2. Through the setting on the angle between return air pipe and the hybrid chamber for the approximate perpendicular between return air pipe and the spiral plate, make the air increase to the propulsion of spiral plate in the return air pipe, thereby the slew velocity of spiral air current improves in the condensation space.
3. Heating element in this device heats fresh air through the magnetocaloric effect, and heating element's rotation power derives from the air current moreover, to the heating method of fresh air return in this dress, for the traditional mode that heats the air through the heating pipe, this mode is more direct, simple, need not consume the electric energy moreover.
Drawings
FIG. 1 is a schematic view of the installation of the overall structure of a laminar flow reflux heat exchanger for an air conditioner according to the present invention;
FIG. 2 is a front half-sectional view of a mixing chamber of the stratified flow heat-exchange reflux unit for an air conditioner of the present invention;
FIG. 3 is a top view of a mixing chamber of the laminar flow recuperator for air conditioner of the present invention;
FIG. 4 is a schematic structural view of a spiral fan blade of the backflow heat exchange device for laminar flow of an air conditioner of the present invention;
FIG. 5 is a top view of the airflow valve of the laminar flow recuperator for air conditioner of the present invention;
FIG. 6 is a diagram showing the change of the operating state of the airflow valve of the heat-exchanger unit for laminar flow air conditioner according to the present invention;
FIG. 7 is a front view of a heating assembly of the laminar flow recuperator for air conditioners of the present invention;
FIG. 8 is a top view of the heating element of the laminar flow recuperator for air conditioner of the present invention;
fig. 9 is a schematic structural view of a region a in fig. 2 of the backflow heat exchange device for laminar flow for air conditioners according to the present invention.
The reference numbers are as follows: 1. a mixing chamber; 2. a heating compartment; 3. a fan assembly; 4. a cooling chamber; 5. a diversion compartment; 6. a shunt tube; 7. a fresh air duct; 8. a return air duct; 9. a vertical plate; 9-1, a transverse plate; 10. a helical fan blade; 11. a water storage compartment; 12. a pressure increasing pipe; 1-1, a condensation cabin; 1-2, a speed increasing pipe; 1-3, a separation cabin; 1-4, a decompression chamber; 1-5, a blow-off pipe; 2-1, rubbing the shell; 2-2, friction ball; 2-3, friction plates; 10-1, a bearing plate; 10-2, spiral plate; 10-3, vent holes; 11-1, a grommet; 11-2, a shell; 11-3, a water gauge plate; 11-4, a sliding plate groove; 11-5, a water spraying pipe; 12-1, fixing a ring; 12-2, a casing; 12-3, an inner plate; 12-4, airflow holes; 12-5, stretching holes; 12-6, a spring; 12-7, a pull ring; 12-8, ropes; 12-9, floating; 12-10 and branch ropes.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
It should be noted that, if directional indications (such as up, down, left, right, front, and back) are involved in the embodiment, the directional indications are only used to explain the relative positional relationship between the components, the motion situation, and the like in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indications are changed accordingly.
In addition, if there is a description of "first", "second", etc. in an embodiment, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicit indication of the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.
Example (b): as shown in fig. 1-9, the backflow heat exchange device for layered flow of air conditioner comprises a mixing cabin 1, a heating cabin 2, a fan assembly 3 and a cooling cabin 4, the reposition of redundant personnel cabin 5, 2 one ends in heating cabin are connected with mixing cabin 1, the 2 other ends in heating cabin are connected with fan subassembly 3, 4 one ends in cooling cabin are connected with the 3 other ends in fan subassembly, the 4 other ends in cooling cabin are connected with reposition of redundant personnel cabin 5, reposition of redundant personnel cabin 5 intercommunication air conditioning room, mixing cabin 1, heating cabin 2, fan subassembly 3, cooling cabin 4 and reposition of redundant personnel cabin 5 turn right from a left side and according to the intercommunication, fresh air pipe 7 is installed to mixing cabin 1 upper end, install the check valve in the fresh air pipe 7, the check valve makes the new trend can only get into mixing cabin 1, the welding of 1 upper end both sides in mixing cabin has at least two sets of return air pipes 8, mixing cabin 1 makes new trend and return air spiral heat transfer, heating cabin.
A grommet 11-1 is welded at the lowest part of the lower end face of the water storage cabin 11 (namely the upper end face of the cabin body of the mixing cabin 1), a water quantity valve is fixedly installed inside the lower end face of the water storage cabin 11, the highest point of the water quantity valve is horizontal to the lowest point of the water storage cabin 11, the water quantity valve comprises a shell 11-2 and a water quantity plate 11-3, a sliding plate groove 11-4 is horizontally machined at the middle position inside the shell 11-2, a water outlet hole is machined at the right end of the shell 11-2, the water outlet hole penetrates through the shell 11-2 and is communicated with the sliding plate groove 11-4, the water quantity plate 11-3 is positioned in the sliding plate groove 11-4, a plurality of groups of water through holes are machined in the range of the water outlet hole on the water quantity plate 11-3, a limiting plate is welded at the left side of the water quantity plate 11-3 inside the sliding plate groove 11-, the spray pipe 11-5 is connected with the shell 11-2 through a pipeline at the position of the water outlet hole.
An air flow valve is fixedly arranged in the pressure increasing pipe 12 and comprises a fixing ring 12-1, a sleeve 12-2 and an inner plate 12-3, the fixing ring 12-1 is welded with the inner wall of the pressure increasing pipe 12, the sleeve 12-2 and the inner plate 12-3 are made of rubber materials, the hardness of the inner plate 12-3 is smaller than that of the sleeve 12-2, the side end face of the sleeve 12-2 is fixed with the inner end face of the fixing ring 12-1, a chute in a shape of Chinese character mi is processed inside the sleeve 12-2, at least six groups of air flow holes 12-4 are arrayed on the sleeve 12-2 at the position of the chute, a stretching hole 12-5 is processed at the lower end face of the sleeve 12-2, the inner plate 12-3 is in a shape of Chinese character mi and is positioned in the chute, the inner plate 12-3 is connected with the sleeve 12-2 in a sliding mode, a plurality of air, at least six groups of springs 12-6 are arranged in the position corresponding to the sliding grooves in the shell 12-2, one end of each spring 12-6 is fixed with the fixing ring 12-1, and the other end of each spring 12-6 is fixed with the inner plate 12-3.
The lower end face of the inner plate 12-3 is located in the range of the stretching hole 12-5, a pull ring 12-7 is machined, a rope 12-8 is tied on the pull ring 12-7, the other end of the rope 12-8 penetrates through a grommet 11-1 and is fixed with at least four groups of floats 12-9, a branch rope 12-10 is fixed on the rope 12-8, and the other end of the branch rope 12-10 penetrates through the lower end face of the water storage cabin 11 and is fixed with the left end face of the water gauge plate 11-3 through a pulley and a sliding plate groove 11-4.
The mixing cabin 1 is divided into a condensation cabin 1-1, an accelerating pipe 1-2, a separation cabin 1-3 and a decompression cabin 1-4 from left to right in sequence, a spiral fan blade 10 is rotatably arranged in the condensation cabin 1-1, the spiral fan blade 10 is divided into a bearing plate 10-1 and a plurality of groups of spiral plates 10-2, the plurality of groups of spiral plates 10-2 are welded on the upper end surface of the bearing plate 10-1, the plurality of groups of spiral plates 10-2 are mutually matched to form a condensation space with continuously reduced aperture above the bearing plate 10-1, an air vent 10-3 with continuously reduced aperture is processed at the middle position of the bearing plate 10-1, the aperture at the upper end of the air vent 10-3 is the same as the aperture at the lower end of the condensation space, a supporting platform is welded below the bearing plate 10-1 inside the, the bearing plate 10-1 is arranged on the supporting platform through a pulley block.
Two groups of return air pipes 8 are welded on the outer side of the condensation cabin 1-1, the two groups of return air pipes 8 are communicated with the interior of the condensation cabin 1-1, the included angle between the return air pipes 8 and the condensation cabin 1-1 is 30 degrees when viewed from top to bottom, and the included angle between the return air pipes 8 and the condensation cabin 1-1 is 50 degrees when viewed from the front.
The aperture of the accelerating pipe 1-2 is continuously reduced from left to right, the aperture of the separating cabin 1-3 is continuously increased from left to right, the lower end face of the separating cabin 1-3 is an arc-shaped end face which is concave inwards, the blow-off pipe 1-5 is welded at the top point of the lower end face of the separating cabin 1-3, the spray pipe 11-5 is arranged above the separating cabin 1-3, and water is sprayed into the separating cabin 1-3 in a water mist mode through the spray pipe 11-5.
The internal pore diameter of the decompression chamber 1-4 is continuously increased from left to right, the right end of the decompression chamber 1-4 is connected with a heating chamber 2 through a pipeline, at least four groups of heating components are installed in the heating chamber 2, each heating component comprises a friction shell 2-1 and a friction ball 2-2, the friction balls 2-2 are rotatably installed in the friction shell 2-1, an air inlet through groove is machined in the position, corresponding to the right half part of the friction shell 2-1, of the front end surface of the chamber body of the heating chamber 2, an air outlet through groove is machined in the position, corresponding to the left half part of the friction shell 2-1, of the rear end surface of the chamber body of the heating chamber 2, and an electromagnetic valve.
The friction shell 2-1 is a hollow spherical shell, the friction ball 2-2 is positioned inside the friction shell 2-1, a plurality of groups of friction plates 2-3 are welded on the outer surface of the friction ball 2-2, the end surfaces of the friction plates 2-3, which are in contact with the friction shell 2-1, are magnetic-embedded end surfaces, the inner end surface of the friction shell 2-1 is a magnetic-embedded end surface, and through holes are machined in the friction shell 2-1 at positions corresponding to the air inlet through groove and the air outlet through groove.
Further, the heating cabin 2 still sets up five at least normal atmospheric temperature passageways, and install the solenoid valve in the normal atmospheric temperature passageway, the solenoid valve that leads to in groove and the normal atmospheric temperature passageway of giving vent to anger all is connected with external controller, when fresh air return need not heat, the solenoid valve that leads to in the groove of giving vent to anger closes, the solenoid valve in the normal atmospheric temperature passageway is opened, fresh air return passes through normal atmospheric temperature passageway and gets into in the fan subassembly 3, when fresh air return needs to heat, the solenoid valve in the normal atmospheric temperature passageway closes, the solenoid valve in the logical groove of giving vent to anger opens, fresh air return gets into fan subassembly.
During fan subassembly 3 transmits fresh air to cooling tank 4, the cooling tube is installed in the slope in cooling tank 4, and the lower terminal surface welding of cooling tank 4 has the drain pipe, and cooling tank 4 cools down fresh air through the cooling tube, and reposition of redundant personnel cabin 5 shunts the air after the cooling, and the outside welding of reposition of redundant personnel cabin 5 has at least three shunt tubes of group 6, and shunt tubes 6 is connected with the air-conditioning room.
The working principle of the invention is as follows:
when the air conditioning unit operates, the fan assembly 3 extracts air in the decompression chambers 1-4 through the heating chamber 2, meanwhile, the return air pipe 8 infuses return air into the condensation chambers 1-1, the fresh air pipe 7 infuses fresh air into the condensation chambers 1-1, and the fresh air and the return air exchange heat spirally in the condensation chambers 1-1.
When the return air and the fresh air are fused in the condensation cabin 1-1, the fresh air with high temperature meets the return air with low temperature or the fresh air with low temperature meets the return air with high temperature, and the fresh return air is condensed to form water mist in the condensation cabin 1-1.
The return air pushes the spiral fan blade 10 to rotate in the condensation cabin 1-1, so that the fresh air and the return air perform spiral heat exchange in the condensation cabin 1-1, meanwhile, the water mist is continuously fused into water drops under the drive of the airflow and absorbs the surrounding impurities, so that the impurities are separated from the fresh air, the fresh air returns to the decompression chamber 1-4 under the influence of the fan component 3 while rotating in the condensation chamber 1-1, and when the fresh air returns through the speed increasing pipe 1-2, because the aperture of the speed increasing pipe 1-2 is shrunk, the speed of the fresh air returning through the speed increasing pipe 1-2 is increased, after the fresh air returning enters the separation cabin 1-3, the fresh return air continues to move in the direction of the decompression chambers 1-4 under the influence of the fan assembly 3, whereas the water droplets with impurities fall under the influence of weight and speed into the bottom of the separation chamber 1-3.
When the air conditioner unit operates, the inlet pipe feeds water into the water storage cabin 11, the floats 12-9 in the water storage cabin 11 float upwards under the support of water and respectively pull the inner plate 12-3 and the water gauge plate 11-3 through the ropes 12-8 and the branch ropes 12-20, so that the water gauge valve and the airflow valve respectively control the fluid flow of the pressure pipe 12 and the water storage cabin 11, and the pressure pipe 12 feeds air into the water storage cabin 11 under the action of an external machine, so that the pressure in the water storage cabin 11 is increased.
When the water level in the water storage tank 11 is high, the pressure of the water on the water spray pipe 11-5 is higher than the pressure of the water on the water spray pipe 11-5 when the water level is low, and at the same time, the pressurizing pipe 12 pumps a small amount of air into the water storage tank 11, so that the water at the bottom of the water storage tank 11 is sprayed into the separation tank 1-3 through the water flow valve and the water spray pipe 11-5 under the extrusion of the water above and the air pressure;
when the water level in the water storage cabin 11 is low, the pressure ratio of water to the water spray pipe 11-5 is smaller at the moment, the atomization effect is not good when the water enters the separation cabin 1-3 through the water spray pipe 11-5, and a large amount of air is infused into the water storage cabin 11 through the pressurization pipe 12, so that the water enters the separation cabin 1-3 in a water mist state through the water quantity valve and the water spray pipe 11-5 under the action of high pressure.
When the fresh return air flows below the spray pipe 11-5, the impurities are contacted with the water mist and separated from the fresh return air under the driving of the water mist, so that the fresh return air is subjected to secondary filtration.
When the fresh and return air needs to be heated, the fresh and return air enters the friction shell 2-1 through the air inlet through groove and pushes the friction plate 2-3, so that the friction ball 2-2 drives the friction plate 2-3 to rotate in the friction shell 2-1, the heating assembly heats the fresh and return air through the magnetocaloric effect, and the heated fresh and return air enters the fan assembly 3 through the air outlet through groove; when the new meeting wind does not need to be heated, the new return wind enters the fan assembly 3 through the normal temperature channel.
The fan assembly 3 transmits fresh and return air to the cooling cabin 4, the cooling cabin 4 cools the fresh and return air through the cooling pipe, the shunting cabin 5 shunts the cooled air, and the cooled fresh and return air is infused into the air-conditioning room through the shunting pipe 6.
It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.
Claims (10)
1. The return heat transfer device that idle call layering flows, its characterized in that: this backward flow heat transfer device includes mixing cabin (1), heating cabin (2), fan subassembly (3), cooling cabin (4), reposition of redundant personnel cabin (5), heating cabin (2) one end is connected with mixing cabin (1), and the heating cabin (2) other end is connected with fan subassembly (3), cooling cabin (4) one end is connected with the fan subassembly (3) other end, and the cooling cabin (4) other end is connected with reposition of redundant personnel cabin (5), reposition of redundant personnel cabin (5) intercommunication air conditioning room, be provided with fresh air pipe (7) and at least two sets of return air pipes (8) on mixing cabin (1), mixing cabin (1) make new trend and return air spiral heat transfer, heating cabin (2) respond to the wind heating through the magneto-thermal effect.
2. The laminar flow heat return apparatus for an air conditioner according to claim 1, characterized in that: be provided with helical fan blade (10) in mixing tank (1), mixing tank (1) below is provided with blow off pipe (1-5), and the middle part in mixing tank (1) outside sets up diaphragm (9-1), two sets of riser (9) from last to down, diaphragm (9-1), two sets of riser (9) and mixing tank (1) three mutually support and constitute water storage tank (11) in mixing tank (1) outside, turn right from a left side on diaphragm (9-1) and be provided with inlet tube and booster tube (12), water storage tank (11) are to spraying water smoke in mixing tank (1).
3. The laminar flow heat return apparatus for an air conditioner according to claim 2, characterized in that: the mixing cabin (1) is sequentially divided into a condensation cabin (1-1), an accelerating pipe (1-2), a separation cabin (1-3) and a decompression cabin (1-4) from left to right, the spiral fan blades (10) are arranged in the condensation cabin (1-1), the spiral fan blades (10) are divided into a bearing plate (10-1) and a plurality of groups of spiral plates (10-2), the plurality of groups of spiral plates (10-2) are arranged on the upper end face of the bearing plate (10-1), the plurality of groups of spiral plates (10-2) are mutually matched to form a condensation space with continuously reduced aperture above the bearing plate (10-1), vent holes (10-3) with continuously reduced aperture are arranged at the middle position of the bearing plate (10-1), the aperture of the upper ends of the vent holes (10-3) is the same as the aperture of the lower ends of the condensation space, a supporting platform is arranged inside the condensation cabin (1-1) and below the bearing plate (10-1).
4. The laminar flow heat return apparatus for an air conditioner according to claim 3, characterized in that: the aperture of acceleration rate pipe (1-2) is turned right from a left side and is constantly reduced, the aperture of disengagement chamber (1-3) is turned right from a left side and is constantly increased, the terminal surface is the arc terminal surface of turning the internal depression under disengagement chamber (1-3), blow off pipe (1-5) sets up the summit department of terminal surface under disengagement chamber (1-3), the top of disengagement chamber (1-3) is provided with spray pipe (11-5).
5. The laminar flow heat return apparatus for an air conditioner according to claim 4, characterized in that: a grommet (11-1) is arranged at the lower end of the water storage cabin (11), a water quantity valve is arranged in the inner part of the lower end surface of the water storage cabin (11), the water quantity valve comprises a shell (11-2) and a water quantity plate (11-3), a sliding plate groove (11-4) is horizontally arranged in the middle of the shell (11-2), a water outlet hole is arranged at the right end of the shell (11-2), the water outlet hole penetrates through the shell (11-2), the water gauge plate (11-3) is positioned in the sliding plate groove (11-4), a plurality of groups of water through holes are arranged in the range of the water outlet holes on the water gauge plate (11-3), a limiting plate is arranged inside the sliding plate groove (11-4) and positioned at the left side of the water gauge plate (11-3), a spring is arranged between the limiting plate and the water gauge plate (11-3), and the water spraying pipe (11-5) is connected with the shell (11-2) through a pipeline at the position of the water outlet hole.
6. The laminar flow heat return apparatus for an air conditioner according to claim 5, characterized in that: an airflow valve is arranged in the pressure increasing pipe (12), the airflow valve comprises a fixing ring (12-1), a casing (12-2) and an inner plate (12-3), the side end face of the casing (12-2) is fixed with the inner end face of the fixing ring (12-1), a sliding groove in a shape of a Chinese character 'mi' is arranged in the casing (12-2), at least six groups of airflow holes (12-4) are arrayed on the casing (12-2) at the position of the sliding groove, a stretching hole (12-5) is arranged on the lower end face of the casing (12-2), the inner plate (12-3) is in a shape of a Chinese character 'mi' and is positioned in the sliding groove, the inner plate (12-3) is connected with the casing (12-2) in a sliding manner, a plurality of groups of air holes are arranged in the range of the airflow holes (12-4) on the inner plate (12-3), at least six groups of springs (12, one end of the spring (12-6) is fixed with the fixing ring (12-1), and the other end of the spring (12-6) is fixed with the inner plate (12-3).
7. The laminar flow heat return apparatus for an air conditioner according to claim 6, characterized in that: and pull rings (12-7) are arranged in the range of the stretching holes (12-5) on the lower end face of the inner plate (12-3), ropes (12-8) are arranged on the pull rings (12-7), the other ends of the ropes (12-8) penetrate through the grommet (11-1) and are provided with at least four groups of floats (12-9), branch ropes (12-10) are arranged on the ropes (12-8), and the other ends of the branch ropes (12-10) are positioned in the sliding plate grooves (11-4) and are fixed with the water gauge plate (11-3).
8. The laminar flow heat return apparatus for an air conditioner according to claim 7, characterized in that: the inside aperture of decompression chamber (1-4) is turned right from a left side and is constantly increased, decompression chamber (1-4) right-hand member and heating cabin (2) pipe connection, be provided with four at least heating element groups in heating cabin (2), heating element includes friction shell (2-1), friction ball (2-2) set up in friction shell (2-1), the position that the preceding terminal surface of the heating cabin (2) cabin body corresponds friction shell (2-1) right half is provided with the logical groove of admitting air, and the position that the rear end surface of the heating cabin (2) cabin body corresponds friction shell (2-1) left half is provided with logical groove of giving vent to anger.
9. The laminar flow heat return apparatus for an air conditioner according to claim 8, characterized in that: the friction shell (2-1) is a hollow spherical shell, the friction ball (2-2) is located inside the friction shell (2-1), a plurality of groups of friction plates (2-3) are arranged on the outer surface of the friction ball (2-2), the end faces, in contact with the friction shell (2-1), of the friction plates (2-3) are all magnet-embedded end faces, the inner end face of the friction shell (2-1) is a magnet-embedded end face, and through holes are formed in the friction shell (2-1) corresponding to the air inlet through grooves and the air outlet through grooves.
10. The laminar flow reflux heat exchange device for an air conditioner according to claim 9, characterized in that: two sets of return air pipe (8) set up in the outside of condensation cabin (1-1), and two sets of return air pipe (8) all communicate with condensation cabin (1-1) is inside, down looks from the top, the contained angle between return air pipe (8) and condensation cabin (1-1) is 30, looks from the foresight, the contained angle between return air pipe (8) and condensation cabin (1-1) is 50.
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