CN112032843A - Novel air conditioning device capable of realizing energy conservation and emission reduction - Google Patents

Abstract

The invention discloses a novel air conditioning device capable of realizing energy conservation and emission reduction, and relates to the technical field of air conditioning devices; in order to improve the energy-saving and temperature control effects; the air conditioner comprises an inner machine and an outer machine, wherein an air outlet is formed in one side of the inner machine, a corrugated pipe is fixed on the side wall of the inner machine through a clamping ring, and a bundling pipe, an air exchange pipe and a drain pipe used for draining condensed water in the inner machine are bundled in the corrugated pipe; the bundling tube is internally bundled with an exchange tube used for transmitting a refrigerant medium and an exhaust tube. According to the invention, by arranging the structures such as the ventilator and the air exchange pipe, the temperature can be adjusted by utilizing the difference between the outside air temperature and the indoor air temperature according to the actual situation; through the arrangement of the solution chamber filled with the liquid mercury, the structures such as the air bag floater and the conducting ring, the working of the ventilator can be automatically controlled by utilizing the expansion and contraction characteristics of the liquid mercury, the ventilation is carried out through the ventilation pipe, the temperature control effect is realized, the energy consumption is low, and the purposes of energy conservation and emission reduction are achieved.

Description

Novel air conditioning device capable of realizing energy conservation and emission reduction

Technical Field

The invention relates to the technical field of air conditioning devices, in particular to a novel air conditioning device capable of realizing energy conservation and emission reduction.

Background

An air conditioner, namely an air conditioner, is equipment for adjusting and controlling parameters such as temperature, humidity, cleanliness, flow velocity and the like of ambient air in a building/structure by manual means, and along with the increase of environmental awareness of people, the air conditioner is also developed towards the direction of energy conservation and emission reduction, but most of the existing air conditioners are simple in structure, and cannot meet the environmental protection requirement only by controlling the temperature by a refrigerant under the action of a compressor.

Through the retrieval, chinese patent application number is CN 201721665121.3's patent, discloses a high-efficient energy-saving air conditioner, including the air conditioner casing, be equipped with out the tuber pipe in the air conditioner casing, its structural feature is, is equipped with the atomizing hole on going out the tuber pipe, goes out the intraductal temperature tube that is equipped with of tuber, temperature tube and the laminating of play tuber pipe activity, the inner wall of play tuber pipe in be equipped with the passageway that the spiral is progressive, the passageway includes import and export, import and export are all established on the pipe wall of a tuber pipe, import and export have the water storage storehouse through inlet tube and water piping connection respectively. The air conditioner in the above patent has the following disadvantages: although the energy-saving device has a certain energy-saving effect, the energy-saving mode is single, and the control of the indoor temperature cannot be realized by fully utilizing the external temperature.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides a novel air conditioning device capable of realizing energy conservation and emission reduction.

In order to achieve the purpose, the invention adopts the following technical scheme:

a novel air conditioning device capable of realizing energy conservation and emission reduction comprises an inner machine and an outer machine, wherein an air outlet is formed in one side of the inner machine, a corrugated pipe is fixed on the side wall of the inner machine through a clamping ring, and a bundling pipe, an air exchange pipe and a drain pipe for draining condensed water in the inner machine are bundled in the corrugated pipe; the bundling pipe is internally bundled with an exchange pipe for transferring a refrigerant medium and an exhaust pipe, and the bundling pipe is respectively connected with the inside of the internal machine and the inside of the external machine; one end of the air exchange tube is connected with an air exchanger, the air exchanger is fixed on the outer wall of the bottom of an external machine through screws, a partition plate is fixed on the outer wall of one side of the air exchanger through screws, a solution chamber and an adjusting chamber are installed on the outer wall of the bottom of the partition plate through an installation frame, liquid mercury is filled in the solution chamber, the inner walls of the top of the solution chamber and the top of the adjusting chamber are connected with a same connecting frame in a sliding mode, an air bag floater is fixed at one end, located in the solution chamber, of the connecting frame through screws, the size of the air bag floater is matched with that of the inner wall of the solution chamber, a conducting ring is fixed at one end, located in the adjusting chamber, of the connecting frame, a lifting seat is arranged in the adjusting chamber, two metal rings are arranged in the; the indoor unit is internally provided with a control unit for realizing automatic coordination of the side cloud, and the ventilator and the outdoor unit are electrically connected with the control unit.

Preferably: the outer wall of one side of the mounting frame is fixedly provided with a control motor through a screw, the output end of the control motor is rotatably connected with a threaded seat through a coupler, the threaded seat is slidably connected to the inner wall of the adjusting chamber, and the inner wall of the threaded seat is connected to the outer wall of the lifting seat through a thread; the inner wall of the top of the lifting seat is connected with two guide rods in a sliding mode, the two guide rods are fixed on the inner wall of the top of the adjusting chamber through screws, and the control motor is electrically connected with the control unit.

Further: the baffle is of an arc structure.

Further preferred is: one end of the ventilation pipe is connected with an air outlet pipe and an air exhaust pipe through a three-way air valve, the air outlet pipe is communicated with an air outlet of the indoor unit, an air valve motor is arranged on the outer wall of the top of the three-way air valve, an air inlet is arranged on the outer wall of the top of the indoor unit, an air extraction chamber is arranged below the air inlet, a temperature sensor is fixed on the inner wall of one side of the air extraction chamber through screws, one end of the air extraction chamber is connected with an air extraction pipeline through a small fan, and the air extraction pipeline at one end of the air extraction chamber is connected with one end of the air exhaust pipe.

As a preferable aspect of the present invention: and a heat exchange exhaust is also arranged between the air inlet and the air extraction chamber.

Further preferred as the invention: the inner walls of two sides of the heat exchange row are respectively connected with a first water pipe and a second water pipe, the first water pipe and the second water pipe are both bundled in the corrugated pipe, one end of the first water pipe is connected with a water tank, a coolant chamber and a water storage chamber are arranged in the water tank, and the coolant chamber and the water storage chamber are connected to one end of the first water pipe through a three-way valve; the water tank passes through the screw fixation in ventilator bottom outer wall, and water tank one side outer wall passes through the screw fixation and has the water pump, and the water pump connects in inside coolant room and the reservoir chamber through another flow divider, and the second water piping connection is in the input of water pump.

As a still further scheme of the invention: one end of the second water pipe is in a spiral structure.

On the basis of the scheme: the inner machine is of a waist-shaped structure, and the top surface of the inner machine is a cambered surface.

On the basis of the foregoing scheme, it is preferable that: and a baffle is fixed on the outer wall of the top of the inner machine through screws and is positioned above the air inlet.

The invention has the beneficial effects that:

1. according to the invention, by arranging the structures such as the ventilator and the air exchange pipe, the temperature can be adjusted by utilizing the difference between the outside air temperature and the indoor air temperature according to the actual situation; through setting up the solution room and gasbag float and conducting ring isotructure that are filled with liquid mercury, can utilize liquid mercury expend with heat and contract with cold the characteristic, real-time monitoring ambient temperature, when liquid mercury inflation or shrink to a certain extent, the gasbag float goes up and down under the effect of buoyancy, thereby it rises or descends to two becket positions to drive the conducting ring through the link, and switch on the becket circuit, thereby automatic control ventilator work, take a breath through the scavenge pipe, realize the temperature control effect, this mode energy consumption is low, energy saving and emission reduction's purpose has been reached.

2. Through setting up control motor and screw thread seat isotructure, can utilize control motor to drive the screw thread seat rotatory, and then the direction lift of control lift seat along the guide bar to change the level of becket, because liquid mercury content and expansion capacity are fixed, so the regulation of becket height can change the ambient temperature standard that is used for triggering ventilator work, does benefit to control ventilator auxiliary refrigeration or heats, has strengthened controllability, has promoted the controllability.

3. By arranging the three-way air valve, the air valve motor and other structures, the on-off of the air path among the air outlet, the air inlet, the ventilator and the external unit can be reliably controlled, so that reliable adjustment can be performed according to requirements and temperature differences; through setting up temperature sensor, can be convenient for detect the inside air temperature of extraction chamber to whether be convenient for judge the condition that accords with current circulation accuse temperature, thereby switch on corresponding three-way air valve and circulate in order to realize the air cycle, play energy-conserving effect.

4. Through the arrangement of the structures such as the water tank, the heat exchange bar and the like, heat exchange can be carried out on air extracted from the air inlet according to requirements, so that the energy-saving and temperature-control effects are improved; through the second water pipe that sets up helical structure, can promote with air area of contact to promote the heat exchange effect.

5. By arranging the internal machine with the waist-shaped structure, dust accumulation can be reduced to a certain extent, and the environmental protection performance is improved; through setting up the baffle, can play the effect that separates the ash, effectively block in the dust gets into the air inlet.

Drawings

Fig. 1 is a schematic structural diagram of a novel air conditioning device internal unit capable of realizing energy conservation and emission reduction, which is provided by the invention;

FIG. 2 is a schematic structural diagram of a cross-sectional view of an internal unit of the novel air conditioning device capable of realizing energy conservation and emission reduction, which is provided by the invention;

FIG. 3 is a schematic structural diagram of the back side of an external unit of the novel air conditioning device capable of realizing energy conservation and emission reduction, which is provided by the invention;

fig. 4 is a schematic structural diagram of the front side of an external unit of the novel air conditioning device capable of realizing energy conservation and emission reduction, which is provided by the invention;

FIG. 5 is a schematic structural diagram of a cross-sectional view of a novel partition plate of an air conditioning device capable of saving energy and reducing emission, which is provided by the invention;

FIG. 6 is a schematic structural diagram of a cross-sectional view of a solution chamber and a regulating chamber of a novel air conditioning device capable of realizing energy conservation and emission reduction, provided by the invention;

FIG. 7 is a schematic structural diagram of a cross-sectional view of a three-way air valve of a novel air conditioning device capable of realizing energy conservation and emission reduction, which is provided by the invention;

fig. 8 is a circuit flow chart of the novel air conditioning device capable of realizing energy conservation and emission reduction provided by the invention.

In the figure: 1 inner machine, 2 air outlets, 3 corrugated pipes, 4 bundling pipes, 5 ventilation pipes, 6 water discharging pipes, 7 first water pipes, 8 second water pipes, 9 air inlets, 10 baffle plates, 11 temperature sensors, 12 air extraction chambers, 13 heat exchange rows, 14 water pumps, 15 water tanks, 16 ventilators, 17 outer machines, 18 partition plates, 19 connecting frames, 20 mounting frames, 21 solution chambers, 22 control motors, 23 lifting seats, 24 threaded seats, 25 adjusting chambers, 26 conducting rings, 27 metal rings, 28 guide rods, 29 air bag floats, 30 air outlet pipes, 31 exhaust pipes, 32 air valve motors and 33 three-way air valves.

Detailed Description

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

Reference will now be made in detail to embodiments of the present patent, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present patent and are not to be construed as limiting the present patent.

In the description of this patent, it is to be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientations and positional relationships indicated in the drawings for the convenience of describing the patent and for the simplicity of description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the patent.

In the description of this patent, it is noted that unless otherwise specifically stated or limited, the terms "mounted," "connected," and "disposed" are to be construed broadly and can include, for example, fixedly connected, disposed, detachably connected, disposed, or integrally connected and disposed. The specific meaning of the above terms in this patent may be understood by those of ordinary skill in the art as appropriate.

A novel air conditioning device capable of realizing energy conservation and emission reduction is shown in figures 1-8 and comprises an inner machine 1 and an outer machine 17, wherein an air outlet 2 is formed in one side of the inner machine 1, a corrugated pipe 3 is fixed on the side wall of the inner machine 1 through a clamping ring, and a converging pipe 4, an air exchange pipe 5 and a drain pipe 6 for draining condensed water in the inner machine 1 are converged in the corrugated pipe 3; an exchange pipe and an exhaust pipe for transferring refrigerant media are bundled in the bundling pipe 4, and the bundling pipe 4 is respectively connected to the inside of the inner machine 1 and the inside of the outer machine 17; one end of the ventilation pipe 5 is connected with a ventilator 16, the ventilator 16 is fixed on the outer wall of the bottom of an external machine 17 through screws, a partition plate 18 is fixed on the outer wall of one side of the ventilator 16 through screws, a solution chamber 21 and an adjusting chamber 25 are installed on the outer wall of the bottom of the partition plate 18 through a mounting frame 20, liquid mercury is filled in the solution chamber 21, the inner walls of the tops of the solution chamber 21 and the adjusting chamber 25 are connected with a same connecting frame 19 in a sliding mode, an air bag floater 29 is fixed at one end, located on the solution chamber 21, of the connecting frame 19 through screws, the size of the air bag floater 29 is matched with the inner wall of the solution chamber 21, a conducting ring 26 is fixed at one end, located on the adjusting chamber 25, of the connecting frame 19 through screws, a lifting seat 23 is arranged in the adjusting chamber 25, two metal rings 27 are arranged in the vertical direction, the metal ring 27 is connected to the control circuit of the ventilator 16; a control unit is arranged in the inner machine 1, the ventilator 16 and the outer machine 17 are electrically connected with the control unit, and the control unit is embedded into an AI edge algorithm to complete automatic modeling and is used for realizing automatic cooperation of a side cloud end; by arranging the structures of the ventilator 16, the ventilation pipe 5 and the like, the temperature can be adjusted by utilizing the difference between the outside air temperature and the indoor air temperature according to actual conditions; through setting up the solution room 21 that is filled with liquid mercury and structures such as gasbag float 29 and conducting ring 26, can utilize liquid mercury expend with heat and contract with cold the characteristic, real-time monitoring ambient temperature, when liquid mercury inflation or shrink to a certain extent, gasbag float 29 goes up and down under the effect of buoyancy, thereby drive conducting ring 26 through link 19 and rise or descend to two becket 27 positions, and switch on the becket 27 circuit, thereby automatic control ventilator 16 works, take a breath through scavenge pipe 5, realize the temperature control effect, this mode energy consumption is low, energy saving and emission reduction's purpose has been reached.

In order to improve the adjustability; as shown in fig. 5 and 6, a control motor 22 is fixed on the outer wall of one side of the mounting frame 20 through a screw, the output end of the control motor 22 is rotatably connected with a threaded seat 24 through a coupling, the threaded seat 24 is slidably connected to the inner wall of the adjusting chamber 25, and the inner wall of the threaded seat 24 is connected to the outer wall of the lifting seat 23 through a screw; the inner wall of the top of the lifting seat 23 is connected with two guide rods 28 in a sliding manner, the two guide rods 28 are fixed on the inner wall of the top of the adjusting chamber 25 through screws, and the control motor 22 is electrically connected with the control unit; through setting up structures such as control motor 22 and screw thread seat 24, can utilize control motor 22 to drive screw thread seat 24 rotatory, and then control lift seat 23 and go up and down along the direction lift of guide bar 28 to change the level of becket 27, because liquid mercury content and expansion capacity are fixed, so the regulation of becket 27 height can change the ambient temperature standard that is used for triggering the work of ventilator 16, do benefit to control ventilator 16 and assist refrigeration or heat, strengthened controllability, promoted the controllability.

To further improve reliability; as shown in fig. 4 and 5, the partition 18 has an arc-shaped structure; through setting up baffle 18 and being the arc structure, and ventilator 16 is located outer machine 17 below, can avoid outer machine 17 exhaust air to the influence that ventilator 16 work effect brought.

In order to improve the air conditioning effect; as shown in fig. 1, 2 and 7, one end of the ventilation pipe 5 is connected with an air outlet pipe 30 and an exhaust pipe 31 through a three-way air valve 33, the air outlet pipe 30 is communicated with the air outlet 2 of the indoor unit 1, an air valve motor 32 is arranged on the outer wall of the top of the three-way air valve 33, an air inlet 9 is arranged on the outer wall of the top of the indoor unit 1, an air extraction chamber 12 is arranged below the air inlet 9, a temperature sensor 11 is fixed on the inner wall of one side of the air extraction chamber 12 through a screw, one end of the air extraction chamber 12 is connected with an air extraction pipeline through a small-sized fan, and the air extraction pipeline at one end of the air extraction chamber 12 is connected with one end of the exhaust pipe 31 and; by arranging the three-way air valve 33, the air valve motor 32 and other structures, the on-off of the air paths among the air outlet 2, the air inlet 9, the ventilator 16 and the external unit 17 can be reliably controlled, so that reliable adjustment can be performed according to requirements and temperature differences; the temperature sensor 11 is arranged, so that the temperature of the air in the air extraction chamber 12 can be conveniently detected, whether the current circulating temperature control condition is met or not can be conveniently judged, the corresponding three-way air valve 33 is conducted to realize air circulating circulation, and the energy-saving effect is achieved; the temperature sensor 11 is of the type QAA 2012.

In order to improve the energy-saving effect; as shown in fig. 2, a heat exchange bar 13 is further arranged between the air inlet 9 and the air extraction chamber 12, inner walls of two sides of the heat exchange bar 13 are respectively connected with a first water pipe 7 and a second water pipe 8, the first water pipe 7 and the second water pipe 8 are both bundled in the corrugated pipe 3, one end of the first water pipe 7 is connected with a water tank 15, a coolant chamber and a water storage chamber are arranged in the water tank 15, the coolant chamber and the water storage chamber are connected with one end of the first water pipe 7 through a three-way valve, the water tank 15 is fixed on an outer wall of the bottom of the ventilator 16 through screws, a water pump 14 is fixed on an outer wall of one side of the water tank 15 through screws, the water pump 14 is connected inside the coolant chamber and the water storage chamber through another; through the arrangement of the structures such as the water tank 15 and the heat exchange row 13, heat exchange can be carried out on air extracted from the air inlet 9 according to requirements, so that the energy-saving and temperature-control effects are improved; in addition, the flow divider valve can be convenient for switching and communicating the coolant chamber and the water storage chamber, so that the coolant and water are utilized to realize dual cooling, and the cooling effect is improved.

To facilitate heat exchange; as shown in fig. 3, one end of the second water pipe 8 is in a spiral structure, and the contact area with air can be increased by arranging the second water pipe 8 in the spiral structure, so that the heat exchange effect is improved.

To reduce dust accumulation; as shown in fig. 1, the inner unit 1 is of a waist-shaped structure, the top surface of the inner unit 1 is an arc surface, and the inner unit 1 with the waist-shaped structure can reduce dust accumulation to a certain extent and improve environmental protection performance.

In order to further play a role of dust prevention; as shown in fig. 1, a baffle 10 is fixed on the outer wall of the top of the internal machine 1 through screws, the baffle 10 is located above the air inlet 9, and by arranging the baffle 10, the effect of isolating dust can be achieved, and dust is effectively prevented from entering the air inlet 9.

When the ventilator 16 works, the temperature can be adjusted by utilizing the difference between the outside air temperature and the indoor air temperature according to the actual situation; specifically, the solution chamber 21 filled with the liquid mercury can monitor the external temperature in real time by utilizing the expansion and contraction characteristics of the liquid mercury, when the liquid mercury expands or contracts to a certain degree, the air bag floater 29 is lifted under the action of buoyancy, so that the conducting ring 26 is driven to ascend or descend to the positions of the two metal rings 27 through the connecting frame 19, and the circuit of the metal rings 27 is conducted, so that the ventilator 16 is automatically controlled to work, ventilation is performed through the ventilation pipe 5, the temperature control effect is realized, the energy consumption is low in the mode, and the purposes of energy conservation and emission reduction are achieved; due to the arrangement of the control motor 22, the threaded seat 24 and other structures, the control motor 22 can be utilized to drive the threaded seat 24 to rotate, and the lifting seat 23 is further controlled to lift along the direction of the guide rod 28, so that the horizontal height of the metal ring 27 is changed, and the liquid mercury content and the expansion capacity are fixed, so that the external temperature standard for triggering the ventilator 16 to work can be changed by adjusting the height of the metal ring 27, the ventilator 16 can be controlled to perform auxiliary refrigeration or heating, the controllability is enhanced, and the adjustability is improved; by arranging the three-way air valve 33, the air valve motor 32 and other structures, the on-off of the air passages among the air outlet 2, the air inlet 9, the ventilator 16 and the external unit 17 can be reliably controlled by the control unit, so that reliable adjustment can be performed according to a set mode and temperature difference; the temperature sensor 11 can detect the air temperature inside the air extraction chamber 12, so as to feed back a signal to the control unit, and conveniently judge whether the current circulating temperature control condition is met, so that the corresponding three-way air valve 33 is conducted to realize air circulating circulation, and an energy-saving effect is achieved; through setting up structures such as water tank 15 and heat transfer row 13, can control 14 work of water pump according to the demand, arrange 13 through the heat transfer with the water of water tank 15 and carry out the heat exchange to the air of extraction in the air intake 9 to promote energy-conservation and accuse temperature effect.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (9)

1. A novel air conditioning device capable of realizing energy conservation and emission reduction comprises an inner machine (1) and an outer machine (17), and is characterized in that an air outlet (2) is formed in one side of the inner machine (1), a corrugated pipe (3) is fixed on the side wall of the inner machine (1) through a clamping ring, and a bundling pipe (4), an air exchange pipe (5) and a drain pipe (6) for draining condensed water in the inner machine (1) are bundled in the corrugated pipe (3); an exchange pipe and an exhaust pipe for transferring refrigerant media are bundled in the bundling pipe (4), and the bundling pipe (4) is respectively connected to the inside of the internal unit (1) and the inside of the external unit (17); one end of the ventilation pipe (5) is connected with a ventilator (16), the ventilator (16) is fixed on the outer wall of the bottom of the outer machine (17) through screws, a partition plate (18) is fixed on the outer wall of one side of the ventilator (16) through screws, a solution chamber (21) and an adjusting chamber (25) are installed on the outer wall of the bottom of the partition plate (18) through a mounting frame (20), liquid mercury is filled in the solution chamber (21), the inner walls of the tops of the solution chamber (21) and the adjusting chamber (25) are connected with a same connecting frame (19) in a sliding mode, an air bag floater (29) is fixed at one end, located on the solution chamber (21), of the connecting frame (19) through screws, the size of the air bag floater (29) is matched with the inner wall of the solution chamber (21), a conductive ring (26) is fixed at one end, located on the adjusting chamber (25), of the adjusting chamber (25) through screws, a lifting seat (, the distance between the two metal rings (27) is smaller than the thickness of the conductive ring (26), the size of the conductive ring (26) is matched with the inner diameter of the metal ring (27), and the metal ring (27) is connected to a control circuit of the ventilator (16); the indoor unit (1) is internally provided with a control unit for realizing automatic cooperation of the side cloud, and the ventilator (16) and the outdoor unit (17) are electrically connected with the control unit.

2. The novel air conditioning device capable of realizing energy conservation and emission reduction as claimed in claim 1, wherein a control motor (22) is fixed on the outer wall of one side of the mounting frame (20) through screws, the output end of the control motor (22) is rotatably connected with a threaded seat (24) through a coupler, the threaded seat (24) is slidably connected with the inner wall of the adjusting chamber (25), and the inner wall of the threaded seat (24) is connected with the outer wall of the lifting seat (23) through threads; the inner wall of the top of the lifting seat (23) is connected with two guide rods (28) in a sliding mode, the two guide rods (28) are fixed to the inner wall of the top of the adjusting chamber (25) through screws, and the control motor (22) is electrically connected with the control unit.

3. The novel air conditioning device capable of saving energy and reducing emission as claimed in claim 2, wherein the partition plate (18) is of an arc structure.

4. The novel air conditioning device capable of saving energy and reducing emission as claimed in claim 3, one end of the air exchanging pipe (5) is connected with an air outlet pipe (30) and an exhaust pipe (31) through a three-way air valve (33), the air outlet pipe (30) is communicated with the air outlet (2) of the indoor unit (1), the outer wall of the top of the three-way air valve (33) is provided with an air valve motor (32), an air inlet (9) is arranged on the outer wall of the top of the indoor unit (1), an air extraction chamber (12) is arranged below the air inlet (9), a temperature sensor (11) is fixed on the inner wall of one side of the air extraction chamber (12) through screws, one end of the air extraction chamber (12) is connected with an air extraction pipeline through a small-sized fan, an air exhaust pipeline at one end of the air exhaust chamber (12) is connected with one end of an air exhaust pipe (31) and one end of an air exhaust pipe in the bundling pipe (4) through another three-way air valve (33) with the same specification.

5. The novel air conditioning device capable of saving energy and reducing emission as claimed in claim 4, wherein a heat exchange row (13) is further arranged between the air inlet (9) and the air extraction chamber (12).

6. The novel air conditioning device capable of realizing energy conservation and emission reduction according to claim 5, wherein the inner walls of the two sides of the heat exchange bar (13) are respectively connected with a first water pipe (7) and a second water pipe (8), the first water pipe (7) and the second water pipe (8) are both bundled in the corrugated pipe (3), one end of the first water pipe (7) is connected with a water tank (15), a coolant chamber and a water storage chamber are arranged in the water tank (15), and the coolant chamber and the water storage chamber are connected to one end of the first water pipe (7) through a three-way valve; the water tank (15) is fixed on the outer wall of the bottom of the ventilator (16) through screws, the outer wall of one side of the water tank (15) is fixed with the water pump (14) through screws, the water pump (14) is connected with the inside of the coolant chamber and the water storage chamber through another flow dividing valve, and the second water pipe (8) is connected with the input end of the water pump (14).

7. The novel air conditioning device capable of saving energy and reducing emission as claimed in claim 6, wherein one end of the second water pipe (8) is in a spiral structure.

8. The novel air conditioning device capable of saving energy and reducing emission according to claim 7, wherein the inner unit (1) is of a waist-shaped structure, and the top surface of the inner unit (1) is an arc surface.

9. The novel air conditioning device capable of saving energy and reducing emission according to claim 8, wherein a baffle (10) is fixed on the outer wall of the top of the inner unit (1) through screws, and the baffle (10) is located above the air inlet (9).

Images