CN210688565U - Intelligent vortex injection energy-saving air conditioner - Google Patents

Intelligent vortex injection energy-saving air conditioner Download PDF

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CN210688565U
CN210688565U CN201921754534.8U CN201921754534U CN210688565U CN 210688565 U CN210688565 U CN 210688565U CN 201921754534 U CN201921754534 U CN 201921754534U CN 210688565 U CN210688565 U CN 210688565U
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indoor
temperature
outdoor
heat exchanger
injection
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徐兴江
徐杰睿
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徐兴江
徐杰睿
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Abstract

An intelligent vortex injection energy-saving air conditioner comprises an indoor unit, an outdoor unit, a vortex tube and an injection device, wherein the indoor unit comprises an indoor heat exchanger, the outdoor unit comprises an outdoor heat exchanger, the outlet end of the indoor heat exchanger is communicated with the inlet end of the vortex tube through a connecting pipeline, the hot outlet end of the vortex tube is communicated with the inlet end of the outdoor heat exchanger through a connecting pipeline, the cold outlet end of the vortex tube is communicated with the suction inlet end of the injection device through a connecting pipeline, the outlet end of the outdoor heat exchanger is communicated with the inlet end of the injection device through a connecting pipeline, and the injection port end of the injection device is communicated with the inlet end of the indoor heat exchanger through a; and a heat exchange medium is arranged in the connecting pipeline. The air conditioner adopts the injection device to replace an expansion throttling device in the original air conditioner, and simultaneously uses the vortex tube to carry out energy separation, thereby not only fully utilizing the energy of indoor high-temperature air to drive the exchange of indoor and outdoor air energy, but also fully utilizing the outdoor air energy with low enthalpy.

Description

Intelligent vortex injection energy-saving air conditioner
Technical Field
The utility model relates to an energy-conserving air conditioner and heat exchange field, especially an energy-conserving air conditioner of intelligence vortex injection.
Background
Global warming presents a serious challenge to human survival and development. With the increasing global population and economic scale, environmental problems and their causes of energy use are continuously recognized. A series of new concepts and policies such as carbon footprint, low-carbon economy, low-carbon technology, low-carbon development, low-carbon life style, low-carbon society, low-carbon city and low-carbon world are applied, the traditional growth mode of the 20 th century is abandoned, the innovative technology and the innovative mechanism of the new century are directly applied, and the social sustainable development is realized through the low-carbon economy mode and the low-carbon life style.
The heat load of machine rooms such as a communication machine room, a data machine room, an automation machine room and a communication base station is large, an air conditioner is in a refrigeration state at outdoor low-temperature hours, and an external cold source cannot be utilized due to the fact that the machine rooms are totally closed. At present, a plurality of energy-saving technologies exist, for example, outdoor cold air is directly or in a heat exchange mode introduced into a machine room, the efficiency of the outdoor cold air is high, but the outdoor air is dirty, the cleanliness of the machine room cannot be solved, and the humidity cannot be guaranteed; the latter has a low heat exchange efficiency, but the humidity is not solved. The energy-saving technology can not only not fully utilize the self heat productivity of the indoor equipment, but also need extra work-doing energy consumption, namely, the indoor heat is discharged outdoors through the mechanical refrigeration of the air conditioner so as to ensure the requirement of the indoor on the environmental temperature.
In summer, no matter civil air conditioner or industrial air conditioner, the indoor air with higher enthalpy value is completely subjected to work by the compressor to reduce the indoor air temperature and perform dehumidification treatment on the indoor air; the energy of the air with higher indoor temperature cannot be fully utilized; in winter, the enthalpy of outdoor air is inherently low, and the temperature of refrigerant in the outdoor unit of the heating system needs to be further reduced to fully utilize the energy of the outdoor air.
Disclosure of Invention
The utility model aims to solve the technical problem that to prior art not enough, provide a reasonable in design, energy-conserving high-efficient, can make full use of indoor outer air energy carry out the intelligent vortex of adjusting temperature and spray energy-conserving air conditioner.
The technical problem to be solved by the utility model is realized through the following technical scheme. The utility model relates to an energy-conserving air conditioner of intelligence vortex injection, this air conditioner includes the indoor set, outdoor unit, vortex tube and injection apparatus, the indoor set includes indoor heat exchanger, outdoor unit includes outdoor heat exchanger, the exit end of indoor heat exchanger passes through the entrance point intercommunication of connecting tube and vortex tube, the hot exit end of vortex tube passes through the entrance point intercommunication of connecting tube and outdoor heat exchanger, the cold exit end of vortex tube passes through the connecting tube and communicates with injection apparatus's sunction inlet end, the exit end of outdoor heat exchanger passes through the connecting tube and communicates with injection apparatus's entrance point, injection apparatus's injection mouth end passes through the connecting tube and communicates with indoor heat exchanger's entrance point; and a heat exchange medium is arranged in the connecting pipeline.
The utility model discloses the technical problem that will solve can also further realize through following technical scheme, to above intelligent vortex sprays energy-conserving air conditioner, still install first solenoid valve on the hot exit end of vortex tube and outdoor heat exchanger's connecting pipeline, still parallelly connected has the compressor bypass on the first solenoid valve, installs compressor and second solenoid valve on the compressor bypass.
The utility model discloses the technical problem that will solve can also further realize through following technical scheme, to above intelligent vortex sprays energy-conserving air conditioner, still install the third solenoid valve on outdoor heat exchanger and injection apparatus's connecting pipeline, still parallelly connected forced circulation pipeline on the third solenoid valve, still install delivery pump and fourth solenoid valve on the forced circulation pipeline.
The utility model discloses the technical problem that will solve can also further realize through following technical scheme, to above intelligent vortex jet energy-conserving air conditioner, this air conditioner still includes intelligent control ware, and indoor unit still includes indoor temperature and humidity transmitter, and outdoor unit still includes outdoor temperature and humidity transmitter, indoor temperature and humidity transmitter, outdoor temperature and humidity transmitter all communicate with intelligent control ware's input, and indoor heat exchanger all is connected with intelligent control ware's output with outdoor heat exchanger, and intelligent control ware adopts the control chip among the prior art, like CPU.
The technical problem to be solved by the utility model can be further realized by the following technical scheme, and for the intelligent vortex injection energy-saving air conditioner, the indoor unit further comprises an indoor cooling tower unit for humidifying the indoor air and an inner fan for accelerating the heat exchange speed of the indoor heat exchanger; the outdoor unit also comprises an outdoor cooling tower unit used for removing dust and cooling outdoor air and an outer fan used for accelerating the heat exchange speed of the outdoor heat exchanger.
The utility model discloses the technical problem that will solve can also further realize through following technical scheme, to above intelligent vortex sprays energy-conserving air conditioner, indoor cooling tower unit and outdoor cooling tower unit all include cooling water tank, and cooling blower is installed at cooling water tank's top, and the water distributor is installed to cooling blower's below, is equipped with a plurality of water distributors on the water distributor, and the below of water distributor is provided with the cascade, the external water pipeline in cooling water tank's bottom.
The utility model discloses the technical problem that will solve can also further realize through following technical scheme, to above intelligent vortex sprays energy-conserving air conditioner, still establish ties on the connecting pipeline between outdoor heat exchanger and the injection apparatus and be used for splendid attire heat transfer medium's storage tank.
The utility model discloses the technical problem that will solve can also further realize through following technical scheme, to above intelligent vortex sprays energy-conserving air conditioner, all install the check valve on the hot exit end of vortex tube and the connecting pipeline of cold exit end.
The utility model discloses the technical problem that will solve can also further realize through following technical scheme, to above intelligent vortex sprays energy-conserving air conditioner, heat transfer medium is the refrigerant, and the refrigerant is often used for heat transfer medium to use, and the heat transfer is effectual.
The utility model discloses the technical problem that will solve can also further realize through following technical scheme, to above intelligent vortex sprays energy-conserving air conditioner, injection apparatus is vacuum generator or sprayer.
Compared with the prior art, the utility model discloses a vortex tube and injection apparatus's combination utilizes the vortex tube to come the gaseous state refrigerant separation to be higher temperature gaseous state refrigerant and lower temperature gaseous state refrigerant, higher temperature gaseous state refrigerant carries out the energy exchange with the air that outdoor temperature is less, become microthermal liquid refrigerant, liquid refrigerant and lower temperature gaseous state refrigerant draw through injection apparatus and penetrate, mix the back, get into indoor heat exchanger and carry out the energy exchange with indoor high temperature air, make full use of indoor, outdoor air energy, realize the heat exchange, it is high to have heat exchange efficiency, long service life's characteristics. The air conditioner adopts the injection device to replace an expansion throttling device in the original air conditioner principle, and simultaneously uses the vortex tube to carry out energy separation, thereby not only fully utilizing the energy of indoor high-temperature air to drive the exchange of indoor and outdoor air energy, but also fully utilizing the outdoor air energy with low enthalpy value, and greatly improving the energy-saving efficiency and the energy efficiency ratio of the air conditioner.
Drawings
Fig. 1 is a schematic structural diagram of embodiment 1 of the present invention;
fig. 2 is a first schematic structural diagram of embodiment 2 of the present invention;
fig. 3 is a second schematic structural diagram of embodiment 2 of the present invention;
fig. 4 is a schematic view of a refrigeration structure of embodiment 3 of the present invention;
fig. 5 is a schematic view of a heating structure according to embodiment 3 of the present invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the drawings of the present invention are combined to clearly and completely describe the technical solutions in the embodiments of the present invention, and obviously, the described embodiments are some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1, embodiment 1 provides an intelligent vortex injection energy-saving air conditioner, which includes an indoor unit, an outdoor unit, an intelligent controller, a first check valve, a second check valve 5, a vortex tube 3, a first electromagnetic valve 9, a second electromagnetic valve 8, a third electromagnetic valve 6, a liquid storage tank 11, an injection device 4, and a water pan, wherein the indoor unit includes an indoor fan, an air filter screen, an indoor heat exchanger 1, a compressor 10, a refrigerant liquid pump 7, a water tank, a water pump, a water curtain, and the like, wherein the refrigerant liquid pump 7, the water tank, the water curtain, and the water pump are optional parts; the outdoor unit comprises an outdoor temperature and humidity transmitter, an outdoor fan, an outdoor heat exchanger 2, a water curtain, a water tank, a water pump and the like, wherein the water tank, the water curtain, the water pump and the like are optional parts. Indoor temperature and humidity transmitter, outdoor temperature and humidity transmitter and indoor, outer unit all link to each other with intelligent control ware, vortex tube 3, solenoid valve, check valve and injection apparatus 4 etc. link to each other through the pipeline with indoor, outer unit heat exchanger, indoor, outer unit heat exchanger is through integral type or split type connection. The installation height of the outdoor unit is required to be higher than that of the indoor unit so as to meet the requirement of a working principle of a separate heat pipe on a system, otherwise, a refrigerant liquid pump 7 is additionally arranged between the liquid storage tank 11 and the second electromagnetic valve 8 for forced circulation, or the injection device 4 is required to be replaced by the electronic injection device 4, the flow rate of the refrigerant is automatically adjusted through the electronic injection device 4, when the outdoor temperature is lower than a certain set value, the first electromagnetic valve 9 and the second electromagnetic valve 8 are closed, the third electromagnetic valve 6 (in this case, the third electromagnetic valve 6 is not required) is opened, the compressor 10 is started, and at the moment, the compressor 10 is only used as an air pump to convey the gaseous refrigerant which is generated by the heat exchanger of the indoor unit and comes out of the;
(1) when the temperature of the outdoor air wet bulb (or dry bulb or enthalpy difference) is less than a certain set value (such as 20 ℃ or the indoor and outdoor air enthalpy difference is more than 10 KJ/KG), and the indoor air temperature is more than the indoor set temperature upper limit value, the outdoor unit water pump (under the condition that the outdoor unit is selected with the water pump, the water tank and the water curtain, the outdoor unit pumps the water in the water tank into the water curtain through the water pump to cool and remove dust from the outdoor air) and the outdoor unit fan are started, the indoor unit fan is started in a delayed and sequential manner, the first electromagnetic valve 9 and the second electromagnetic valve 8 are opened (if the outdoor unit cannot be installed more than 100mm, the refrigerant liquid pump 7 is opened), and after energy exchange is carried out between the indoor fan and the indoor high-temperature air through the indoor heat exchanger 1, the gaseous refrigerant coming out from the indoor heat exchanger 1 is separated into a higher-temperature gaseous state and a lower-temperature gaseous state through the vortex, the high-temperature gaseous refrigerant enters the outdoor heat exchanger 2 through the hot end of the vortex tube 3, the first check valve, the first electromagnetic valve 9 and the connecting pipeline for heat exchange, the gaseous refrigerant is changed into a liquid refrigerant after the heat exchange of the outdoor heat exchanger 2, the liquid refrigerant flows back to the indoor unit through the connecting pipeline to flow into the liquid storage tank 11 under the action of gravity, and the liquid refrigerant flowing out of the liquid storage tank 11 enters the injection device 4 through the second electromagnetic valve 8; the low temperature gaseous refrigerant from the cold end of the vortex tube 3 enters the injection device 4 through the second one-way valve 5, is injected and mixed by the injection device 4, enters the indoor heat exchanger 1, exchanges heat with the indoor air under the action of the fan of the indoor unit, then the liquid refrigerant is changed into the gaseous refrigerant, the gaseous refrigerant enters the inlet of the vortex tube 3 again and is separated into two parts of high temperature gaseous state and low temperature gaseous state, the high temperature gaseous refrigerant enters the outdoor heat exchanger 2 through the hot end of the vortex tube 3, the first electromagnetic valve 9, the first one-way valve and the connecting pipeline for heat exchange, the gaseous refrigerant is changed into the liquid refrigerant after the heat exchange of the outdoor heat exchanger 2, the liquid refrigerant flows back to the indoor unit through the connecting pipeline under the action of gravity and flows into the liquid storage tank 11, the liquid refrigerant from the liquid storage tank 11 enters the injection device 4 through the second electromagnetic valve 8, and the low temperature gaseous state from the cold end of the vortex tube 3 enters the injection device 4 through the, the mixture is injected and mixed by the injection device 4, enters the indoor heat exchanger 1 and exchanges heat with the indoor air again under the action of the fan of the indoor heat exchanger 1; and the process is circulated. And when the indoor air temperature is lower than the set lower limit value, the indoor fan stops running, and the water pump of the outdoor unit (the outdoor unit is matched with the water pump, the water tank and the water curtain) and the fan stop running.
If the indoor air temperature slowly rises during the operation, but if the outdoor air wet bulb (or dry bulb or enthalpy difference) temperature is greater than a certain set value (for example, 10 ℃ or the indoor and outdoor air enthalpy difference is less than 20 KJ/KG), when the indoor air temperature is greater than the set upper limit value + Δ T (the value can be set), the compressor 10 is started in a delayed and sequential manner, the first electromagnetic valve 9 and the second electromagnetic valve 8 are closed (if the outdoor unit cannot meet the requirement of at least being higher than 100mm when installed, the refrigerant pump is closed), the third electromagnetic valve 6 is opened (if the electronic injection device 4 is adopted, the electronic injection device 4 automatically adjusts the opening degree according to the change of the indoor temperature, at this time, the third valve may not be needed, but the superheat degree of the refrigerant in the indoor heat exchanger 1 is controlled by the air speed of the indoor fan, the larger the superheat degree is, the smaller the fan speed is, until the lowest rotation speed is allowed), the low-temperature gaseous refrigerant from the heat exchanger of the indoor unit is separated into a higher-temperature gaseous refrigerant part and a lower-temperature gaseous refrigerant part after passing through the vortex tube 3, the higher-temperature gaseous refrigerant is sucked by the compressor 10 to be compressed and is changed into a high-temperature high-pressure gaseous refrigerant, then the high-temperature gaseous refrigerant enters the outdoor heat exchanger 2 to exchange heat with outdoor air, the high-temperature high-pressure gaseous refrigerant is changed into a high-pressure low-temperature liquid refrigerant, the liquid refrigerant and the lower-temperature gaseous refrigerant separated from the vortex tube 3 are throttled, injected and mixed by the injection device 4 to be changed into low-temperature low-pressure wet steam, and the low-temperature low-pressure wet steam refrigerant is changed into a; the low-temperature gaseous refrigerant is separated into a higher-temperature gaseous refrigerant part and a lower-temperature gaseous refrigerant part after passing through the vortex tube 3, the higher-temperature gaseous refrigerant is sucked by the compressor 10 to be compressed to be a high-temperature high-pressure gaseous refrigerant, and then enters the outdoor heat exchanger 2 to exchange heat with outdoor air to be a high-pressure low-temperature liquid refrigerant, the liquid refrigerant and the lower-temperature gaseous refrigerant separated from the vortex tube 3 are throttled, injected and mixed by the injection device 4 to be low-temperature low-pressure wet steam, the low-temperature low-pressure wet steam refrigerant exchanges heat with indoor air through the indoor heat exchanger 1 to be a low-temperature gaseous refrigerant, and the circulation is carried out, when the temperature of the indoor air is lower than a set upper limit value, the compressor 10 stops running, the first electromagnetic valve 9 and the second electromagnetic valve 8 are opened, and the third electromagnetic valve 6 is closed.
In order to utilize the air energy of outdoor low enthalpy value to the maximum extent, the injection device 4 can be replaced by an electronic injection device 4, when the temperature of outdoor air wet bulb (or dry bulb or enthalpy difference) is less than a certain set value (for example, 10 ℃ or the difference of indoor and outdoor air enthalpies is greater than 20 KJ/KG), and the indoor air temperature is greater than the indoor set temperature upper limit value + Δ T (the value can be set), the electronic injection device 4 is completely opened, the first electromagnetic valve 9 and the second electromagnetic valve 8 are closed (if the outdoor unit cannot be installed and is at least higher than 100mm, the refrigerant pump is closed), the third electromagnetic valve 6 (in this case, the third electromagnetic valve 6 is not required) is opened, the compressor 10 is started, and at the moment, the compressor 10 is only used as an air pump to deliver the gaseous state generated by the indoor unit heat exchanger and coming out from the hot end of the vortex refrigerant pipe 3; the low-temperature low-pressure gaseous refrigerant generated by the indoor unit heat exchanger is separated into a higher-temperature gaseous refrigerant part and a lower-temperature gaseous refrigerant part through the vortex tube 3, the higher-temperature gaseous refrigerant is sucked by the compressor 10 to be compressed and changed into a higher-temperature higher-pressure gaseous refrigerant, then the higher-temperature gaseous refrigerant enters the outdoor heat exchanger 2 to exchange heat with outdoor air, and the higher-temperature and lower-temperature gaseous refrigerant is changed into a higher-pressure and lower-temperature liquid refrigerant, and the lower-temperature gaseous refrigerant separated from the vortex tube 3 and the liquid refrigerant are throttled, injected and mixed by the injection device 4 to be changed into low-temperature low-pressure wet steam; the low-temperature low-pressure wet steam refrigerant is changed into a low-temperature low-pressure gaseous refrigerant after exchanging heat with indoor air through the indoor heat exchanger 1. The low-temperature low-pressure gaseous refrigerant is separated into a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant after passing through the vortex tube 3, the higher-temperature gaseous refrigerant is sucked by the compressor 10 to be compressed to be a higher-temperature higher-pressure gaseous refrigerant, and then enters the outdoor heat exchanger 2 to exchange heat with outdoor air to be a higher-pressure low-temperature liquid refrigerant, the liquid refrigerant and the lower-temperature gaseous refrigerant separated from the vortex tube 3 are throttled, injected and mixed by the electronic injection device 4 to be low-temperature lower-pressure wet steam, the low-temperature lower-pressure wet steam refrigerant exchanges heat with indoor air through the indoor heat exchanger 1 to be a low-temperature gaseous refrigerant, and the circulation is carried out in such a way that when the indoor air temperature is less than a set upper limit value, the compressor 10 stops running, the first electromagnetic valve 9 and the second electromagnetic valve 8 are opened (if the outdoor unit cannot be more than 100mm, the refrigerant pump is turned on), the third electromagnetic valve 6 is turned off;
(2) when the outdoor installation height unit can not meet the condition that the temperature (or the dry bulb or enthalpy difference value) of an outdoor wet bulb is at least 100mm higher than that of an indoor unit or is more than a certain set value (such as 20 degrees or the enthalpy difference between indoor and outdoor air is less than 10 Kj/Kg), and the indoor air temperature is more than the set indoor temperature upper limit value, an outdoor water pump (under the condition that the outdoor unit is matched with a water pump, a water tank and a water curtain, the outdoor unit pumps water in the water tank into the water curtain through the water pump to carry out cooling and dust removal treatment on outdoor air) and an outdoor unit fan are started, a first electromagnetic valve 9 and a second electromagnetic valve 8 are closed (if the outdoor unit can not meet the condition that the temperature is at least more than 100mm, a refrigerant pump is closed), a third electromagnetic valve 6 is opened (if an electronic injection device 4 is adopted, the electronic injection device 4 automatically adjusts the opening degree according to the change of the indoor temperature, and the third electromagnetic, the superheat degree of a refrigerant in the indoor heat exchanger 1 is controlled by the air speed of an indoor fan, the higher the superheat degree is, the lower the rotating speed of the fan is until the lowest rotating speed is allowed), and the fans of the indoor unit are started in a delayed manner, and the compressor 10 of the unit is started in a delayed manner; after energy exchange is carried out between the indoor fan and indoor high-temperature air through the indoor heat exchanger 1, gaseous refrigerants coming out of the indoor heat exchanger 1 are separated into a higher-temperature gaseous state and a lower-temperature gaseous state after passing through the vortex tube 3; the high-temperature gaseous refrigerant enters the outdoor heat exchanger 2 through the hot end of the vortex tube 3, the compressor 10 and the connecting pipeline for heat exchange, is changed into a liquid refrigerant after the heat exchange of the outdoor heat exchanger 2, flows back to the indoor unit through the connecting pipeline and flows into the liquid storage tank 11, the liquid refrigerant from the liquid storage tank 11 enters the indoor heat exchanger 1 through the low-temperature gaseous refrigerant from the cold end of the vortex tube 3 after passing through the third electromagnetic valve 6 and being throttled, injected and mixed by the injection device 4, and exchanges heat with indoor air under the action of a fan of the indoor unit; the gaseous refrigerant coming out of the indoor heat exchanger 1 is separated into a higher-temperature gaseous state and a lower-temperature gaseous state after passing through the vortex tube 3; the high-temperature gaseous refrigerant enters the outdoor heat exchanger 2 through the hot end of the vortex tube 3, the compressor 10 and the connecting pipeline for heat exchange, is changed into a liquid refrigerant after the heat exchange of the outdoor heat exchanger 2, flows back to the indoor unit through the connecting pipeline and flows into the liquid storage tank 11, the liquid refrigerant coming out of the liquid storage tank 11 enters the indoor heat exchanger 1 through the third electromagnetic valve 6 and the low-temperature gaseous refrigerant coming out of the cold end of the vortex tube 3 after throttling, injection and mixing by the injection device 4, and then exchanges heat with indoor air under the action of the fan of the indoor unit. And when the indoor air temperature is lower than the set lower limit value, the indoor fan stops running, the water pump of the outdoor unit (the outdoor unit is matched with the water pump, the water tank and the water curtain) and the fan stop running, and the operation is circulated.
(3) When the temperature of the outdoor air wet bulb is lower than a set value (such as 0 ℃) under the condition that the outdoor unit is selectively provided with the water pump, the water tank and the water curtain, the outdoor water pump stops running so as to prevent the fins of the outdoor heat exchanger 2 from being frozen and influence the air intake of the heat exchanger, thereby influencing the heat dissipation effect of the heat exchanger;
under the condition that a water pump, a water tank and a water curtain are selected and matched, if the humidity of indoor air is smaller than a set lower limit value, the water pump is started, water in the water tank is pumped into the water curtain, the indoor air is humidified, and when the humidity of the indoor air is larger than a set upper limit value, the water pump stops running.
Referring to fig. 2-3, embodiment 2 provides an intelligent vortex + injection energy-saving air conditioner, which includes an indoor unit and an outdoor unit, wherein the indoor unit further includes an intelligent controller, an indoor temperature and humidity transmitter, a first electromagnetic valve 30, a second electromagnetic valve 3231, a third electromagnetic valve, a compressor 25, a first vortex tube 24, a second vortex tube 36, a first vacuum generator 28, a second vacuum generator 29, a first check valve 33, a second check valve 35, an injection device 23, a water pan, an indoor fan, an air filter screen, a first indoor heat exchanger 21, a second indoor heat exchanger 26, a liquid storage tank 37, a refrigerant liquid pump 38, a refrigerant air pump 34 (or compressor 25), a water tank, a water pump, a water curtain, and the like, wherein, the liquid storage tank 37, the refrigerant liquid pump 38, the water tank, the water curtain, the water pump and the like are selected parts (the water tank, the water curtain and the water pump are not marked in the figure, and the water curtain is arranged in front of the air inlet of the heat exchanger); the outdoor unit comprises an outdoor temperature and humidity transmitter, an outdoor fan, a first outdoor heat exchanger 22, a second outdoor heat exchanger 27, a water tank, a water pump, a water curtain and the like, wherein the water tank, the water curtain and the water pump are optional parts. The indoor temperature and humidity transmitter, the outdoor temperature and humidity transmitter, the indoor and outdoor units are connected with the intelligent controller, the first vortex tube 24 is connected with the compressor 25, and the first outdoor heat exchanger 22 is connected with the injection device 23 and the first indoor heat exchanger 21 through pipelines; the second vortex tube 36 passes through the first check valve 33 and the second vacuum generator 29; the second vacuum generator 29, the second outdoor heat exchanger 27, the first vacuum generator 28 and the second vortex tube 36 are connected with the first vacuum generator 28 through pipelines in a split type, wherein the installation height of the outdoor unit heat exchanger is required to be higher than that of the indoor unit so as to meet the requirement of the working principle of the split type heat pipe on the system, otherwise, a refrigerant liquid pump 38 is additionally arranged at the outlet of the liquid storage tank 37 for forced circulation.
(1) When the temperature of outdoor air wet bulb (or dry bulb or enthalpy difference) is less than a certain set value (such as 20 ℃ or the enthalpy difference of indoor and outdoor air is more than 10 Kj/Kg), and the temperature of indoor air is more than the upper limit value of indoor set temperature, the water pump of the outdoor unit (under the condition that the water pump, the water tank and the water curtain are selected and matched, the water in the water tank is pumped into the water curtain by the outdoor unit through the water pump to carry out cooling and dedusting treatment on the outdoor air) and the outdoor fan are started, and the indoor fan is started in a delayed and sequential manner. After energy exchange is performed between the indoor fan and the indoor high-temperature air in the second indoor heat exchanger 26, a part of the gaseous refrigerant coming out of the second indoor heat exchanger 26 passes through the second vortex tube 36 and is separated into a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant. The other part of the refrigerant enters an inlet of a second vacuum generator 29, the refrigerant with higher temperature and gas state separated by the first check valve 33 and the second vortex tube 36 is ejected to a second outdoor heat exchanger 27 by the second vacuum generator 29 for heat exchange, the refrigerant with lower temperature and gas state discharged from the cold end of the second vortex tube 36 enters a suction end of the first vacuum generator 28 through a second check valve 35 under the action of gravity, the refrigerant with liquid state returns to an inlet end of the first vacuum generator 28 of the indoor unit through a connecting pipeline, the refrigerant with lower temperature and gas state discharged from the cold end of the second vortex tube 36 enters a suction end of the first vacuum generator 28 through the second check valve 35, the refrigerant with lower temperature and gas state enters a second indoor heat exchanger 26 after being ejected and mixed by the first vacuum generator 28, and the refrigerant with indoor air is changed into the refrigerant with gas state after heat exchange under the action of a fan of the. One part of the gaseous refrigerant enters the inlet of the second vortex tube 36 and is separated into a higher-temperature gaseous state and a lower-temperature gaseous state, the other part of the gaseous refrigerant enters the inlet of the second vacuum generator 29, the higher-temperature gaseous refrigerant separated from the second vortex tube 36 through the first one-way valve 33 is ejected to the second outdoor heat exchanger 27 through the second vacuum generator 29 for heat exchange, the lower-temperature gaseous refrigerant is sucked into the suction end of the first vacuum generator 28 through the second one-way valve 35 and is ejected and mixed through the first vacuum generator 28 to enter the second indoor heat exchanger 26, and the gaseous refrigerant and the indoor high-temperature air are subjected to energy exchange under the action of the fan of the indoor unit. When the indoor air temperature is lower than the set lower limit value, the indoor fan stops running, and the water pump of the outdoor unit (the outdoor unit is matched with the water pump, the water tank and the water curtain) and the fan stop running; if the indoor air temperature slowly rises during the operation process, but if the outdoor air wet bulb (or dry bulb or enthalpy difference value) temperature is larger than a certain set value (such as 10 ℃ or the indoor and outdoor air enthalpy difference value is smaller than 20 KJ/KG), when the indoor air temperature is larger than the indoor set temperature upper limit value +0.5 ℃, the indoor unit fan and the outdoor unit fan are started to operate, the third electromagnetic valve is closed, and the refrigerant air pump 34 (or the compressor 25) is started. After energy exchange is carried out between the indoor fan and the indoor high-temperature air through the second indoor heat exchanger 26, one part of the gaseous refrigerant coming out of the second indoor heat exchanger 26 is separated into a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant after passing through the second vortex tube 36, the other part of the gaseous refrigerant enters the inlet of the second vacuum generator 29, the gaseous refrigerant is forcibly introduced through the refrigerant air pump 34, the higher-temperature gaseous refrigerant separated through the first check valve 33 and the second vortex tube 36 is sprayed to the second outdoor heat exchanger 27 by the second vacuum generator 29 for heat exchange, the gaseous refrigerant is changed into a liquid refrigerant after heat exchange by the second outdoor heat exchanger 27, the liquid refrigerant flows back to the inlet end of the first vacuum generator 28 of the indoor unit through a connecting pipeline under the action of gravity, the lower-temperature gaseous refrigerant coming out of the cold end of the second vortex tube 36 enters the air suction end of the first vacuum generator 28 through the second check valve 35, the refrigerant is injected and mixed by the first vacuum generator 28, enters the second indoor heat exchanger 26, and is subjected to heat exchange with indoor air under the action of the fan of the indoor unit, so that the liquid refrigerant is changed into a gaseous refrigerant. When the indoor air temperature is higher than the set upper limit value + Δ T (the value can be set, and the set range is 1-10 degrees), the compressor 25 is started in a delayed and sequential manner, the low-temperature gaseous refrigerant from the indoor unit heat exchanger 1 passes through the first vortex tube 24 and is separated into a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant, the higher-temperature gaseous refrigerant is sucked by the compressor 25 to be compressed and changed into a high-temperature high-pressure gaseous refrigerant, and then enters the first outdoor heat exchanger 22 to exchange heat with the outdoor air, so that the high-temperature low-temperature liquid refrigerant and the lower-temperature gaseous refrigerant from the first vortex tube 24 are changed into high-pressure low-temperature liquid refrigerant, and the high-temperature low-temperature gaseous refrigerant passes through the injection device 23 (if the electronic injection device 23 is adopted, the electronic injection device 23 automatically adjusts the opening degree according to the change of the indoor temperature, while the superheat degree, the lower the rotation speed of the fan is, the lower the rotation speed is until the lowest rotation speed is allowed) to be throttled, injected and mixed to be changed into low-temperature low-pressure wet steam, and the low-temperature low-pressure wet steam refrigerant is changed into a low-temperature gaseous refrigerant after exchanging heat with indoor air through the first indoor heat exchanger 21. The low-temperature gaseous refrigerant is separated into a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant after passing through the first vortex tube 24, the higher-temperature gaseous refrigerant is sucked by the compressor 25 to be compressed to be a high-temperature high-pressure gaseous refrigerant, and then enters the first outdoor heat exchanger 22 to exchange heat with outdoor air, so that the high-temperature gaseous refrigerant is changed into a high-pressure low-temperature liquid refrigerant and a lower-temperature gaseous refrigerant from the first vortex tube 24, and the high-pressure low-temperature liquid refrigerant is changed into low-temperature low-pressure wet steam after being throttled, injected and mixed by the injection device 23, and the low-temperature low-pressure wet steam refrigerant is changed into the low-temperature gaseous refrigerant after being. And the process is circulated. Until the indoor air temperature is less than the set upper limit value, the operation of the compressor 25 is stopped. The above process is circulated.
In order to maximize the utilization of outdoor low enthalpy air energy, the injection device 23 may be replaced with an electron injection device 23. When the temperature of outdoor air wet bulb (or dry bulb or enthalpy difference) is less than a certain set value (such as 10 ℃ or the indoor and outdoor air enthalpy difference is more than 20 KJ/KG), and the indoor air temperature is more than the indoor set temperature upper limit value + delta T (the value can be set, the set range is 1-10 ℃), the electronic injection device 23 is completely opened, the compressor 25 is started, at the moment, the compressor 25 is only used as an air pump to convey the gaseous refrigerant which is generated by the indoor unit heat exchanger and comes out from the hot end of the vortex tube, the lower-temperature and low-pressure gaseous refrigerant which is generated by the indoor unit heat exchanger is separated into a higher-temperature gaseous refrigerant part and a lower-temperature gaseous refrigerant part through the vortex tube, the higher-temperature gaseous refrigerant is sucked by the compressor 25 to be compressed to become a higher-temperature and high-pressure gaseous refrigerant, and then enters the outdoor heat exchanger to perform heat exchange with the outdoor air, the liquid refrigerant and the gaseous refrigerant separated from the vortex tube at lower temperature are throttled, injected and mixed by the injection device 23 to become wet steam at lower temperature and lower pressure; the lower-temperature low-pressure wet steam refrigerant is changed into a lower-temperature low-pressure gaseous refrigerant after exchanging heat with indoor air through the indoor heat exchanger. The lower-temperature low-pressure gaseous refrigerant is separated into a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant after passing through the vortex tube, the higher-temperature gaseous refrigerant is sucked by the compressor 25 to be compressed to become a higher-temperature higher-pressure gaseous refrigerant, and then enters the outdoor heat exchanger to exchange heat with outdoor air to become a higher-pressure low-temperature liquid refrigerant, the liquid refrigerant and the lower-temperature gaseous refrigerant separated from the vortex tube are throttled, injected and mixed by the injection device 23 to become lower-temperature low-pressure wet steam, and the lower-temperature low-pressure wet steam refrigerant is subjected to heat exchange with indoor air through the indoor heat exchanger to become a low-temperature gaseous refrigerant. And the process is circulated. Until the indoor air temperature is less than the set upper limit value, the operation of the compressor 25 is stopped. The above process is circulated.
(2) When the temperature of the outdoor air wet bulb (or the outdoor air dry bulb) is more than or equal to a certain set value (such as 30 ℃ or the enthalpy difference between indoor air and outdoor air is less than 5 KJ/KG), but the temperature of the outdoor air wet bulb (or the outdoor air dry bulb) meets the set value, when the temperature of the indoor air is more than the set upper limit value of the indoor temperature, the indoor unit fan and the outdoor unit fan are started to operate, the third electromagnetic valve is closed, and the refrigerant air pump 34 (or the compressor 25) is started. After energy exchange is performed between the indoor fan and the indoor high-temperature air in the second indoor heat exchanger 26, a part of the gaseous refrigerant coming out of the second indoor heat exchanger 26 passes through the second vortex tube 36 and is separated into a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant. The other part of the refrigerant enters an inlet of a second vacuum generator 29, is forcibly introduced by a refrigerant air pump 34, is sprayed to a second outdoor heat exchanger 27 by the second vacuum generator 29 to carry out heat exchange through a higher-temperature gaseous refrigerant separated by a first check valve 33 and a second vortex tube 36, is changed into a liquid refrigerant after the heat exchange of the second outdoor heat exchanger 27, returns to an inlet end of a first vacuum generator 28 of the indoor unit through a connecting pipeline under the action of gravity, enters a suction end of the first vacuum generator 28 through a second check valve 35, is injected and mixed by the first vacuum generator 28, enters a second indoor heat exchanger 26, and is changed into a gaseous refrigerant after the heat exchange with indoor air under the action of a fan of the indoor unit. During the operation, if the indoor air temperature rises to be greater than the set upper limit value + Δ T (which may be set, which is set in the range of 1-10 degrees), the compressor 25 is started in a delayed and sequential manner, after the low-temperature and low-pressure gaseous refrigerant from the heat exchanger 1 of the indoor unit passes through the first vortex tube 24, the refrigerant is separated into a higher temperature gaseous state and a lower temperature gaseous state, the higher temperature gaseous state refrigerant is sucked by the compressor 25 for compression, is changed into a high temperature and high pressure gaseous state refrigerant, then enters the first outdoor heat exchanger 22 for heat exchange with outdoor air, is changed into a low temperature and high pressure liquid state refrigerant and a lower temperature gaseous state refrigerant from the first vortex tube 24, the refrigerant is throttled, injected and mixed by the injection device 23 to become low-temperature low-pressure wet steam, and the low-temperature low-pressure wet steam refrigerant is subjected to heat exchange with indoor air by the first indoor heat exchanger 21 to become a low-temperature low-pressure gaseous refrigerant. The low-temperature gaseous refrigerant is separated into a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant after passing through the first vortex tube 24, the higher-temperature gaseous refrigerant is sucked by the compressor 25 to be compressed to be a high-temperature high-pressure gaseous refrigerant, and then enters the first outdoor heat exchanger 22 to exchange heat with outdoor air, so that the high-temperature gaseous refrigerant is changed into a high-pressure low-temperature liquid refrigerant and a lower-temperature gaseous refrigerant from the first vortex tube 24, and the high-pressure low-temperature liquid refrigerant is changed into low-temperature low-pressure wet steam after being throttled, injected and mixed by the injection device 23, and the low-temperature low-pressure wet steam refrigerant is changed into the low-temperature gaseous refrigerant after being. And the process is circulated. Until the indoor air temperature is less than the set upper limit value, the operation of the compressor 25 is stopped. The above process is circulated.
Under the condition that an outdoor unit is selectively provided with a water pump, a water tank and a water curtain, when the temperature of an outdoor air wet bulb is lower than a certain set value (such as 0 ℃), the outdoor circulating water pump stops running so as to prevent fins of an outdoor heat exchanger from being frozen and influence the air intake of the heat exchanger, thereby influencing the heat dissipation effect of the heat exchanger; under the condition that a water pump, a water tank and a water curtain are selected and matched, if the indoor humidity is smaller than the set lower limit value, the water pump is started, water in the circulating water tank is pumped onto the water curtain, the indoor is humidified, and when the indoor humidity is larger than the set upper limit value, the water pump stops running.
In this embodiment, two relatively independent systems are combined into one outdoor unit and one indoor unit, and if the two relatively independent systems are separated into two independent units, one system is an outdoor unit and one indoor unit; or the system II and the scheme are combined into an outdoor unit and an indoor unit.
Referring to fig. 4-5, embodiment 3 is an intelligent vortex + jet energy-saving air conditioner, including an indoor unit and an outdoor unit, where the indoor unit further includes an intelligent controller, an indoor temperature and humidity sensor, a one-way valve, a vortex tube 43, a first solenoid valve 47, a second solenoid valve 48, a third solenoid valve 50, a fourth solenoid valve 49, a four-way valve 46, a liquid storage tank, a jet device 44, a water pan, an indoor fan, an air filter, an indoor heat exchanger 42, a water tank, a water pump, a water curtain, and the like, where the liquid storage tank, the water curtain, and the water pump are optional parts; the outdoor unit also comprises an outdoor temperature and humidity transmitter, an outdoor fan, an outdoor heat exchanger 41, a water curtain, a water tank, a water pump and the like, wherein the water tank, the water curtain, the water pump and the like are optional parts (not marked in the figure, and the water curtain is arranged in front of an air inlet of the heat exchanger); of course, the compressor 45, the four-way valve 46, the solenoid valve, the vortex tube 43, etc. may be disposed in the outdoor unit; the injection device 44 is selected to replace an expansion throttling device in the original air conditioning principle, and the vortex tube 43 is used for energy separation. The energy-saving efficiency and the energy efficiency ratio of the air conditioner are greatly improved.
(1) The refrigeration condition is as follows:
when the air conditioner is in a starting state, when the indoor temperature is higher than the set temperature value, the compressor 45 is started, the outdoor fan is started, the vortex tube 43 separates the low-temperature low-pressure gaseous refrigerant from the indoor evaporator into a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant, the higher-temperature gaseous refrigerant is sucked by the compressor 45, works by the compressor 45 and is changed into a high-temperature high-pressure gaseous refrigerant, the high-temperature high-pressure gaseous refrigerant enters the outdoor condenser after passing through the four-way valve 46, after heat exchange is carried out between the outdoor heat exchanger 41 and outdoor air, the high-temperature high-pressure gaseous refrigerant is changed into a low-temperature high-pressure liquid refrigerant, the low-temperature gaseous refrigerant from the cold end of the vortex tube 43 passes through the second electromagnetic valve 48 (at the moment, the second electromagnetic valve 48 is in a starting state) and the lower-temperature gaseous refrigerant from the cold end of the vortex tube 43, changing into low-temperature low-pressure gaseous refrigerant; the vortex tube 43 separates the low-temperature and low-pressure gaseous refrigerant coming out of the interior evaporator into two parts, namely a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant, through the first electromagnetic valve 47 (at this time, the first electromagnetic valve 47 is in an open state) and the vortex tube 43; the gaseous refrigerant with higher temperature is sucked by the compressor 45, and is changed into a gaseous refrigerant with high temperature and high pressure by the work of the compressor 45, the gaseous refrigerant with high temperature and high pressure enters the outdoor heat exchanger 41 after passing through the four-way valve 46, after the heat exchange with the outdoor air is carried out by the outdoor heat exchanger 41, the gaseous refrigerant with lower temperature and high pressure is changed into a liquid refrigerant with low temperature and high pressure by passing through the second electromagnetic valve 48 (at this time, the second electromagnetic valve 48 is in an open state) and the gaseous refrigerant with lower temperature coming out of the cold end of the vortex tube 43, the gaseous refrigerant is throttled, injected and mixed by the injection device 44, and then returns to the indoor heat exchanger 42 through the four-way valve 46, after the energy exchange with the indoor air is carried out by the indoor heat exchanger 42, the gaseous refrigerant with low temperature and low pressure is changed into a gaseous refrigerant with lower temperature and low pressure, the gaseous refrigerant coming out, the circulation operation is carried out in such a way, and the compressor 45 and the outdoor fan stop operating until the indoor air temperature is 1-2 ℃ lower than the set temperature.
(2) Heating condition:
when the indoor temperature is lower than the set temperature value in the state that the air conditioner is turned on, the compressor 45 is turned on, the outdoor fan is turned on, the four-way valve 46 is powered on to convert the flow direction of the refrigerant, and the vortex tube 43 separates the low-temperature and low-pressure gaseous refrigerant coming out of the outdoor condenser through the third electromagnetic valve 50 (at this time, the third electromagnetic valve 50 is in the on state) into a gaseous refrigerant with a higher temperature and a gaseous refrigerant with a lower temperature. The gaseous refrigerant with higher temperature is sucked by the compressor 45, and is changed into a gaseous refrigerant with high temperature and high pressure by the work of the compressor 45, the gaseous refrigerant with high temperature and high pressure enters the indoor heat exchanger 42 after passing through the four-way valve 46, and is changed into a liquid refrigerant with low temperature and high pressure after passing through the fourth electromagnetic valve 49 (the fourth electromagnetic valve 49 is in an open state at this time) and the gaseous refrigerant with lower temperature coming out of the cold end of the vortex tube 43 after being subjected to heat exchange with the indoor air by the indoor evaporator, and then the gaseous refrigerant is throttled, injected and mixed by the injection device 44, returns to the outdoor heat exchanger 41 through the four-way valve 46, and is changed into a gaseous refrigerant with. The vortex tube 43 separates the low-temperature and low-pressure gaseous refrigerant coming out of the outdoor heat exchanger 41 into two parts, namely a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant, through the third electromagnetic valve 50 (at this time, the third electromagnetic valve 50 is in an open state) and the vortex tube 43; the gaseous refrigerant with higher temperature is sucked by the compressor 45, and is changed into a gaseous refrigerant with high temperature and high pressure by the work of the compressor 45, the gaseous refrigerant with high temperature and high pressure enters the indoor heat exchanger 42 after passing through the four-way valve 46, and is changed into a liquid refrigerant with low temperature and high pressure after exchanging heat with indoor air through the heat exchanger, the gaseous refrigerant with lower temperature coming out from the cold end of the vortex tube 43 via the fourth electromagnetic valve 49 (at this time, the fourth electromagnetic valve 49 is in an open state) and is injected and mixed by the injection device 44, and then returns to the outdoor heat exchanger 41 via the four-way valve 46, and is changed into a gaseous refrigerant with low temperature and low pressure after exchanging energy. The low-temperature low-pressure gaseous refrigerant passes through the third electromagnetic valve 50 (at this time, the third electromagnetic valve 50 is in an open state) and the vortex tube 43, the vortex tube 43 separates the low-temperature low-pressure gaseous refrigerant coming out of the outdoor heat exchanger 41 into a higher-temperature gaseous refrigerant and a lower-temperature gaseous refrigerant, the operation is circulated in such a way until the temperature of the indoor air is 1-2 ℃ higher than the set temperature, the compressor 45 and the four-way valve 46 are powered off, the outdoor fan stops operating, and when the outdoor unit needs defrosting, if the injection device 44 is changed into the electronic injection device 44, the electronic injection device 44 is only required to be opened to the maximum opening degree, the defrosting can be performed at regular time, and the defrosting is not required to be performed by.
The foregoing is only a part of the embodiments of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements can be made without departing from the principles of the present invention, and these improvements should be regarded as the protection scope of the present invention.

Claims (10)

1. The utility model provides an energy-conserving air conditioner of intelligence vortex injection which characterized in that: the air conditioner comprises an indoor unit, an outdoor unit, a vortex tube and an injection device, wherein the indoor unit comprises an indoor heat exchanger, the outdoor unit comprises an outdoor heat exchanger, the outlet end of the indoor heat exchanger is communicated with the inlet end of the vortex tube through a connecting pipeline, the hot outlet end of the vortex tube is communicated with the inlet end of the outdoor heat exchanger through a connecting pipeline, the cold outlet end of the vortex tube is communicated with the suction inlet end of the injection device through a connecting pipeline, the outlet end of the outdoor heat exchanger is communicated with the inlet end of the injection device through a connecting pipeline, and the injection port end of the injection device is communicated with the inlet end of the indoor heat; and a heat exchange medium is arranged in the connecting pipeline.
2. The intelligent vortex-jet energy-saving air conditioner according to claim 1, characterized in that: and a first electromagnetic valve is also arranged on a connecting pipeline between the heat outlet end of the vortex tube and the outdoor heat exchanger, a compressor bypass is also connected in parallel on the first electromagnetic valve, and a compressor and a second electromagnetic valve are arranged on the compressor bypass.
3. The intelligent vortex-jet energy-saving air conditioner according to claim 1, characterized in that: and a third electromagnetic valve is also arranged on a connecting pipeline of the outdoor heat exchanger and the injection device, a forced circulation pipeline is also connected in parallel on the third electromagnetic valve, and a conveying pump and a fourth electromagnetic valve are also arranged on the forced circulation pipeline.
4. The intelligent vortex-jet energy-saving air conditioner according to claim 1, characterized in that: the air conditioner further comprises an intelligent controller, the indoor unit further comprises an indoor temperature and humidity transmitter, the outdoor unit further comprises an outdoor temperature and humidity transmitter, the indoor temperature and humidity transmitter and the outdoor temperature and humidity transmitter are communicated with the input end of the intelligent controller, and the indoor heat exchanger and the outdoor heat exchanger are connected with the output end of the intelligent controller.
5. The intelligent vortex-jet energy-saving air conditioner according to claim 1, characterized in that: the indoor unit further comprises an indoor cooling tower unit for humidifying indoor air and an inner fan for accelerating the heat exchange speed of the indoor heat exchanger; the outdoor unit also comprises an outdoor cooling tower unit used for removing dust and cooling outdoor air and an outer fan used for accelerating the heat exchange speed of the outdoor heat exchanger.
6. The intelligent vortex-jet energy-saving air conditioner according to claim 5, characterized in that: the indoor cooling tower unit and the outdoor cooling tower unit both comprise cooling water tanks, cooling fans are installed at the tops of the cooling water tanks, water distribution pipes are installed below the cooling fans, a plurality of water distributors are arranged on the water distribution pipes, water curtains are arranged below the water distributors, and tap water pipelines are externally connected to the bottoms of the cooling water tanks.
7. The intelligent vortex-jet energy-saving air conditioner according to claim 1, characterized in that: and a storage tank for containing a heat exchange medium is also connected in series on the connecting pipeline between the outdoor heat exchanger and the injection device.
8. The intelligent vortex-jet energy-saving air conditioner according to claim 1, characterized in that: and one-way valves are arranged on connecting pipelines of the hot outlet end and the cold outlet end of the vortex tube.
9. The intelligent vortex-jet energy-saving air conditioner according to claim 1, characterized in that: the heat exchange medium is a refrigerant.
10. The intelligent vortex-jet energy-saving air conditioner according to claim 1, characterized in that: the injection device is a vacuum generator or an injector.
CN201921754534.8U 2019-10-18 2019-10-18 Intelligent vortex injection energy-saving air conditioner Active CN210688565U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201921754534.8U CN210688565U (en) 2019-10-18 2019-10-18 Intelligent vortex injection energy-saving air conditioner

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201921754534.8U CN210688565U (en) 2019-10-18 2019-10-18 Intelligent vortex injection energy-saving air conditioner

Publications (1)

Publication Number Publication Date
CN210688565U true CN210688565U (en) 2020-06-05

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Family Applications (1)

Application Number Title Priority Date Filing Date
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Country Status (1)

Country Link
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