CN114607263B

CN114607263B - Energy-saving door and window with intelligent screen window

Info

Publication number: CN114607263B
Application number: CN202210211734.9A
Authority: CN
Inventors: 关四海; 关宇晗; 侯千一
Original assignee: Jiangxi Wangong Aluminum Co ltd
Current assignee: Jiangxi Wangong Aluminum Co ltd
Priority date: 2022-03-04
Filing date: 2022-03-04
Publication date: 2023-09-19
Anticipated expiration: 2042-03-04
Also published as: CN114607263A

Abstract

The application provides an energy-saving door and window with an intelligent screen window.A screen window is detachably connected to one side of a door and window frame, a water storage tank is arranged at the upper part of the door and window frame, a water outlet end of the water storage tank is communicated with a water inlet end of a cylinder body, the cylinder body is fixedly connected to one side of the door and window frame, an overflow hole is formed in the upper part of the cylinder body, a second inner cavity in the cylinder body is communicated with a pressure cylinder through a pressure output pipe, the pressure cylinder is connected to the side wall of the door and window frame, a partition plate with a connecting hole is arranged in the cylinder body, the interior of the cylinder body is divided into a first inner cavity and a second inner cavity which are mutually communicated through the partition plate with the connecting hole, a control component is slidably connected in the first inner cavity and penetrates through the partition plate with the connecting hole to extend into the second inner cavity for controlling the water level in the second inner cavity, a switching cavity is arranged at the lower part of the door and window frame, and the pressure rack component is slidably connected in the pressure cylinder and the switching cavity for controlling the opening and closing of a baffle, and the light transmittance of the door and window in the sun can be controlled by utilizing rainwater collected in the rainy days.

Description

Energy-saving door and window with intelligent screen window

Technical Field

The application relates to a door and window, in particular to an energy-saving door and window with an intelligent screen window.

Background

When the temperature difference between day and night is large, the traditional doors and windows have the defect that the use condition cannot be adjusted according to sunlight when the traditional doors and windows are used, when the problem of illumination is solved, a motor is often used for driving parts, so that the problem of illumination is solved, the manufacturing cost and the use cost are definitely increased, the economy is poor, and especially in the present of energy shortage, the consumption of energy is definitely increased;

however, the sunlight problem is a problem to be solved urgently, especially in some areas with extreme weather, the day and night temperature difference is large, the daytime illumination group is also used in the southern area of China, for example, the daytime weather is hot, people often go out to work in the daytime, the indoor temperature cannot be well controlled, so that the indoor temperature is extremely high after going home from work, great uncomfortable feeling is caused, and the power supply is ensured at all times in some intelligent households, so that the use economy is poor;

based on the problems, the application discloses an energy-saving door and window with an intelligent screen window.

Disclosure of Invention

The application aims to solve the technical problem of providing an energy-saving door and window with an intelligent screen window, which can control the light transmittance of the door and window when sunlight is sufficient by utilizing rainwater collected in rainy days to realize intelligent adjustment.

In order to solve the technical problems, the application provides an energy-saving door window with an intelligent screen window, which comprises a door window frame, the screen window, a water storage tank, a cylinder body, overflow holes, a pressure output tube, a pressure cylinder, a first inner cavity, a water level control assembly, a baffle plate with a connecting hole, a second inner cavity, a pressure rack assembly, gears, baffles, glass and a switching cavity, wherein the screen window is detachably connected to one side of the door window frame, the water storage tank is arranged on the upper part of the door window frame, the water outlet end of the water storage tank is communicated with the water inlet end of the cylinder body, the cylinder body is fixedly connected to one side of the door window frame, the upper part of the cylinder body is provided with the overflow holes, the second inner cavity in the cylinder body is communicated with the pressure cylinder through the pressure output tube, the pressure cylinder is connected to the side wall of the door window frame, the baffle plate with the connecting hole separates the interior of the cylinder body into the first inner cavity and the second inner cavity which are mutually communicated, the control assembly is slidably connected in the first inner cavity and penetrates through the baffle plate with the connecting hole and extends to the second inner cavity, the lower part of the water level of the door window frame is arranged at the lower part of the door window frame, the water level control assembly is communicated with the window frame, the pressure rack is connected to the upper side of the window frame through the baffle plate at the left side of the window frame, and the window frame is fully meshed with the window frame when the pressure is far enough, and the window frame is rotatably connected to the window frame is far from the left in the window frame.

Further, the water level control assembly includes: the pressure cylinder is connected in the first inner cavity in a sliding mode and penetrates through the partition plate with the connecting hole to extend into the second inner cavity, the first spring is sleeved on the pressure cylinder, two ends of the first spring are respectively connected to the partition plate of the upper portion of the pressure cylinder and the partition plate of the cylinder body, a plurality of drain holes are formed in the lower portion of the pressure cylinder, the limiting plate is arranged at the lower end of the pressure cylinder and abuts against the lower end face of the partition plate with the connecting hole, and the float is arranged at the lower end of the limiting plate.

Further, the pressure rack assembly includes: the pressure disk, the second spring, pressure channel, rack, exhaust check valve and blast pipe, the pressure disk links to each other with the rack, and pressure disk sliding connection is in the pressure cylinder, and the second spring housing is on the rack, and the second spring both ends are supported respectively on the lateral wall of pressure cylinder inner wall and door window frame, all are equipped with pressure channel on pressure disk and the rack, and rack sliding connection is in switching the intracavity, and the rack is with every the gear meshes and is used for controlling the steering of baffle, and the exhaust check valve sets up in the blast pipe, and the blast pipe intercommunication is at pressure channel's pressure output, can control the switching of baffle and adjust the intake of daytime.

Further, the energy-saving door and window further comprises: the condenser pipe, drainage passageway, valve and air exit, condenser pipe one end intercommunication is in the blast pipe upper end, the condenser pipe is the coiled pipe, the condenser pipe other end extends to in the drainage passageway, the drainage passageway sets up on the side frame of door and window frame, condenser pipe mouth of pipe is towards the valve, the valve articulates on drainage passageway upside inner wall, the air exit sets up on the door and window frame and is linked together with drainage passageway, the valve sets up the intercommunication department at air exit and drainage passageway, can improve indoor temperature and humidity.

Further, the energy-saving door and window further comprises: the water tank is characterized by comprising a condensation drain pipe, a water collecting tank, an introducing pipe, a pump, an eduction pipe, a backflow one-way valve and a backflow port, wherein the condensation drain pipe is communicated with the lower end of the exhaust pipe, the water collecting tank is connected with the lower end of a door window frame, the condensation drain pipe is communicated with the inside of the water collecting tank, one end of the introducing pipe is communicated with the water collecting tank, the introducing pipe is positioned on one side far away from the condensation drain pipe, the other end of the introducing pipe is communicated with the pump, an output pipeline of the pump is communicated with the backflow port, the backflow port is arranged on a cylinder body and is communicated with a second inner cavity, and the backflow one-way valve is arranged at the communication position of the output pipeline of the pump and the backflow port, so that the water quantity in the cylinder body can be kept.

Further, the energy-saving door and window further comprises: the first filter element is arranged between the water storage groove and the cylinder body, so that no impurity is contained in water, and normal operation of doors and windows is guaranteed.

Further, the energy-saving door and window further comprises: the second filter element is arranged at one end, far away from the air valve, in the drainage channel.

Further, the heat absorbing material is wrapped outside the cylinder body, the material is black, the heat absorbing rate is improved, the water evaporation is convenient, and sufficient driving force is ensured to finish driving the baffle plate.

Further, the outer wall of the condensing tube is wrapped with a heat insulation material, so that the reduction of the temperature of the gas is ensured to finish the reduction of the indoor temperature and the adjustment of the indoor humidity.

Further, a matched thread plug is arranged at the air outlet.

In summary, adopt above-mentioned device, can utilize the rainwater that rainy day was collected to control the door and window luminousness when the sunshine is sufficient and realize intelligent regulation, can control opening and shutting of baffle and adjust the intake of daytime, can improve indoor temperature and humidity, can keep the volume of water in the jar to maintain the regulation to the baffle, can guarantee that the aquatic does not contain impurity, guarantee door and window's normal operating, improve the heat absorption rate, be convenient for the evaporation of water, guarantee sufficient driving force and accomplish the drive to the baffle, ensure that gas temperature reduces to accomplish the reduction to indoor temperature and adjust indoor humidity.

Drawings

FIG. 1 is a schematic view of a first overall structure of an energy-saving door and window with an intelligent screen window according to the present application;

FIG. 2 is a schematic view of a part A of the energy saving door and window with an intelligent screen window according to the present application;

FIG. 3 is a schematic view of a second overall structure of an energy-saving door and window with an intelligent screen window according to the present application;

FIG. 4 is a schematic view of a part B of the energy saving door and window with an intelligent screen window according to the present application;

FIG. 5 is a schematic view of a first cross-sectional configuration of an energy efficient door and window with an intelligent screen of the present application;

FIG. 6 is a schematic view of the enlarged partial C portion of FIG. 5 of an energy efficient door and window with an intelligent screen according to the present application;

FIG. 7 is a schematic view of a part D of the power saving door and window with an intelligent screen in the enlarged partial structure of FIG. 5;

FIG. 8 is a schematic view of the enlarged partial structure of portion E of FIG. 5 of an energy saving door and window with an intelligent screen window according to the present application;

FIG. 9 is a schematic view of the enlarged partial F structure of FIG. 5 of an energy saving door and window with an intelligent screen window according to the present application;

FIG. 10 is a schematic view of a partially enlarged structure of portion G of FIG. 5 of an energy efficient door and window with an intelligent screen according to the present application;

FIG. 11 is a schematic view of a second cross-sectional configuration of an energy efficient door and window with an intelligent screen of the present application;

FIG. 12 is a third cross-sectional schematic view of an energy efficient door and window with an intelligent screen;

fig. 13 is a schematic view of a partially enlarged H-section structure of the energy saving door and window with an intelligent screen according to the present application.

In the figure: a door and window frame 1; a screen window 2; a water storage tank 3; a first connecting pipe 4; a cylinder 5; an overflow aperture 6; a pressure output pipe 7; a pressure cylinder 8; a first lumen 9; a water level control assembly 10; a partition plate 11 with a connecting hole; a second lumen 12; a pressure rack assembly 13; a gear 14; a baffle 15; a pressure cylinder 16; a first spring 17; a drain hole 18; a limit plate 19; a float 20; a pressure plate 21; a second spring 22; a pressure channel 23; a rack 24; an exhaust check valve 25; an exhaust pipe 26; a condenser tube 27; a drainage channel 28; a valve 29; an air outlet 30; a condensate drain pipe 31; a water collection tank 32; an introduction pipe 33; a pump 34; a lead-out pipe 35; a return check valve 36; a return port 37; a first cartridge 38; a second filter element 39; a glass 40; the cavity 41 is switched.

Detailed Description

The application will be described in detail hereinafter with reference to the drawings in conjunction with embodiments. It should be noted that, without conflict, the embodiments of the present application and features of the embodiments may be combined with each other.

As shown in the attached drawings, the embodiment of the application provides an energy-saving door and window with an intelligent screen window, which comprises a door and window frame 1, the screen window 2, a water storage tank 3, a cylinder body 5, an overflow hole 6, a pressure output pipe 7, a pressure cylinder 8, a first inner cavity 9, a water level control assembly 10, a partition plate 11 with a connecting hole, a second inner cavity 12, a pressure rack assembly 13, a gear 14, a baffle 15, glass 40 and a switching cavity 41, wherein the screen window 2 is detachably connected to one side of the door and window frame 1, the water storage tank 3 is arranged at the upper part of the door and window frame 1, the water outlet end of the water storage tank 3 is communicated with the water inlet end of the cylinder body 5 through a first connecting pipe 4, the cylinder body 5 is fixedly connected to one side of the door and window frame 1, the upper part of the cylinder body 5 is provided with the overflow hole 6, the second inner cavity 12 in the cylinder body 5 is communicated with the pressure cylinder 8 through the pressure output pipe 7, the partition plate 11 with the connecting hole is arranged in the cylinder body 5, the partition plate 11 with the connecting hole separates the interior of the cylinder body 5 into the first inner cavity 9 which is mutually communicated and the second inner cavity 12, the second inner cavity 12 is connected with the second inner cavity 12 which is connected with the gear 14 in the sliding frame 10 in the cylinder body 5, the lower cavity 15 is arranged in the lower side of the door and is connected with the inner cavity 1 through the baffle 15, and the inner cavity 15 which is connected to the pressure rack assembly 1, and the lower side of the partition plate 15 is connected to the pressure cylinder 1 through the pressure cylinder 15, and the inner cavity 15 is connected to the inner cavity 15 in the sliding part 1, and the pressure control part which is connected to the inner cavity 1 and the inner cavity 1, and the partition plate 1 is connected to the inner cavity 1 and the side 1, which is connected to the partition plate 1 and the inner cavity 1 and the 4 is 4.

In this embodiment, the water level control assembly 10 includes: the pressure cylinder 16 is slidably connected in the first inner cavity 9 and penetrates through the baffle plate 11 with the connecting hole to extend into the second inner cavity 12, the first spring 17 is sleeved on the pressure cylinder 16, two ends of the first spring 17 are respectively connected to the upper portion of the pressure cylinder 16 and the baffle plate of the cylinder body 5, a plurality of drain holes 18 are formed in the lower portion of the pressure cylinder 16, the limiting disc 19 is arranged at the lower end of the pressure cylinder 16 and abuts against the lower end face of the baffle plate 11 with the connecting hole, and the float 20 is arranged at the lower end of the limiting disc 19.

In this embodiment, the pressure rack assembly 13 includes: the pressure plate 21 is connected with the rack 24, the pressure plate 21 is slidably connected in the pressure cylinder 8, the second spring 22 is sleeved on the rack 24, two ends of the second spring 22 respectively prop against the inner wall of the pressure cylinder 8 and the side wall of the door and window frame 1, the pressure plate 21 and the rack 24 are respectively provided with the pressure channel 23, the rack 24 is slidably connected in the switching cavity 41, the rack 24 is meshed with each gear 14 for controlling the turning of the baffle 15, the exhaust check valve 25 is arranged in the exhaust pipe 26, the exhaust pipe 26 is communicated with the pressure output end of the pressure channel 23, rainwater falls into the water storage tank 3 for collection, after the rainwater is filtered by the first filter element 38, the rainwater enters the first inner cavity 9 of the cylinder 5 from the first connecting pipe 4, and then gradually becomes more along with the water, the pressure provided by the water to the pressure cylinder 16 can lead the pressure cylinder 16 to overcome the elasticity of the first spring 17 to drive the pressure cylinder 16 to move downwards, so that the water discharge hole 18 enters the second inner cavity 12 after losing the limit of the baffle plate 11 with the connecting hole, thus the water in the first inner cavity 9 can flow downwards into the second inner cavity 12 through the water discharge hole 18, the water can contact the floater 20 along with the gradual rising of the water quantity in the second inner cavity 12, the floater 20 is driven to move upwards, finally the water discharge hole 18 is reset, the water level in the second inner cavity 12 is stabilized, then the water in the first inner cavity 9 can gradually rise, overflows after reaching the height of the overflow hole 6, the constant liquid level of the first inner cavity 9 is ensured, when hot weather arrives, such as noon, sunlight is sufficient, the temperature rises, the heat absorbing material is wrapped outside the cylinder 5, the material is black, and a great amount of heat can be absorbed by the material, the heat can make the inside quick temperature rise of cylinder body 5, the water in the second inner chamber 12 can be made to the temperature that rises carries out quick evaporation, the pressure that the evaporation brought can be transmitted to in the pneumatic cylinder 8 from pressure output tube 7, the threshold value that does not reach exhaust check valve 25 this moment, pressure can promote pressure dish 21 and move to compressing second spring 22's direction, pressure dish 21 can drive rack 24 and move, rack 24 can electric gear 14 rotates, gear 14 can drive baffle 15 and rotate, make the baffle 15 of mutual plane originally become a straight line, and form a complete plane, can prevent like this that light from entering into indoor from glass 40, like this can prevent the further rising of indoor temperature.

In this embodiment, the energy-saving door and window further includes: the condenser tube 27, drainage passageway 28, valve 29 and air exit 30, condenser tube 27 one end intercommunication is in blast pipe 26 upper end, condenser tube 27 is the coiled pipe, the condenser tube 27 other end extends to in the drainage passageway 28, drainage passageway 28 sets up on the side frame of door and window frame 1, condenser tube 27 mouth of pipe is towards valve 29, valve 29 articulates on drainage passageway 28 upside inner wall, air exit 30 sets up on door and window frame 1 and is linked together with drainage passageway 28, valve 29 sets up in the intercommunication department of air exit 30 and drainage passageway 28, and when pressure continuously risees, exhaust check valve 25 can open, and unnecessary gas can enter into blast pipe 26 from exhaust check valve 25 like this, and the gas temperature is higher this moment, and along with high pressure making the gas upwards move, condenser tube 27 outer wall parcel insulating material to in condenser tube 27 internal temperature reduction and liquefaction, unnecessary pressure can be gone into in drainage passageway 28 from condenser tube 27, and high pressure gas can dash out valve 29 and get into indoor from air exit 30, and the temperature has been reduced simultaneously to the humidity of the room can be brought to the temperature of the room through the falling.

In this embodiment, the energy-saving door and window further includes: the water collecting device comprises a condensation drain pipe 31, a water collecting tank 32, an introducing pipe 33, a pump 34, an eduction pipe 35, a backflow one-way valve 36 and a backflow port 37, wherein the condensation drain pipe 31 is communicated with the lower end of the exhaust pipe 26, the water collecting tank 32 is connected with the lower end of the door window frame 1, the condensation drain pipe 31 is communicated with the interior of the water collecting tank 32, one end of the introducing pipe 33 is communicated with the water collecting tank 32, the introducing pipe 33 is positioned at one side far away from the condensation drain pipe 31, the other end of the introducing pipe 33 is communicated with the pump 34, an output pipeline of the pump 34 is communicated with the backflow port 37, the backflow port 37 is arranged on the cylinder 5 and is communicated with the second inner cavity 12, the backflow one-way valve 36 is arranged at the position where the output pipeline of the pump 34 and the backflow port 37 are communicated, after gas moving in the condensation pipe 27 is condensed, water can flow back into the water collecting tank 32 from the condensation drain pipe 31, a water level sensor is additionally arranged in the second inner cavity 12, when water in the first inner cavity 9 is insufficient to supplement water in the second inner cavity 12, the water in the second inner cavity 12 is operated through the pump 34, the water in the water collecting tank 32 is enabled to enter the second inner cavity 33, and then the backflow port is enabled to enter the backflow port 36 as the backflow one-way valve to obtain upward speed after the backflow port 12.

In this embodiment, the energy-saving door and window further includes: the first filter element 38 is arranged between the water storage tank 3 and the cylinder 5, and ensures the purity of water entering the cylinder 5.

In this embodiment, the energy-saving door and window further includes: the second filter element 39 is arranged at one end, far away from the air valve 29, of the drainage channel 28, so that the air entering the drainage channel 28 can be ensured to be clean, and the indoor air quality can be ensured.

The air outlet 30 is provided with a matched screw plug, and in winter, the external temperature is lower, and the air outlet 30 is sealed by the screw plug, so that the indoor temperature is ensured.

When in use, in rainy weather, rainwater falls into the water storage tank 3 to be collected, then water is filtered by the first filter element 38, then enters the first inner cavity 9 of the cylinder body 5 from the first connecting pipe 4, then the water gradually increases, the pressure provided by the water to the pressure cylinder 16 can enable the pressure cylinder 16 to overcome the elastic force of the first spring 17 to drive the pressure cylinder 16 to move downwards, so that the water drain hole 18 loses the limit of the baffle plate 11 with the connecting hole and then enters the second inner cavity 12, thus the water in the first inner cavity 9 can flow downwards into the second inner cavity 12 through the water drain hole 18, the water can contact the floater 20 along with the gradual rise of the water quantity in the second inner cavity 12 to drive the floater 20 to move upwards, finally the water drain hole 18 is reset, the water level in the second inner cavity 12 is stabilized, then the water in the first inner cavity 9 gradually rises, the water overflows after reaching the height of the overflow hole 6, ensuring the constant liquid level of the first inner cavity 9, when hot weather comes, such as noon, sufficient sunlight and high temperature, the cylinder 5 is wrapped with heat absorbing material, the material is black, the material absorbs a large amount of heat, the heat can quickly raise the temperature in the cylinder 5, the raised temperature can quickly evaporate water in the second inner cavity 12, the pressure brought by evaporation can be transmitted from the pressure output pipe 7 to the pressure cylinder 8, at the moment, the threshold value of the exhaust one-way valve 25 is not reached, the pressure can push the pressure disc 21 to move in the direction of compressing the second spring 22, the pressure disc 21 can drive the rack 24 to move, the rack 24 can drive the electric gear 14 to rotate, the gear 14 can drive the baffle 15 to rotate, so that the baffles 15 originally in a mutual plane become a straight line and form a complete plane, thus light can be prevented from entering the room from the glass 40, so as to prevent the indoor temperature from further rising, the second spring 22 is at the compressed limit position, when the pressure continues to rise, the exhaust one-way valve 25 is opened, so that redundant gas can enter the exhaust pipe 26 from the exhaust one-way valve 25, the gas temperature is higher, the gas moves upwards along the condensing pipe 27 along with the high pressure, the outer wall of the condensing pipe 27 wraps the heat insulation material, so that the temperature in the condensing pipe 27 is reduced and liquefied, the redundant pressure can be discharged into the drainage channel 28 from the condensing pipe 27, the high-pressure gas can rush up the valve 29 to enter the room from the air outlet 30, the temperature of the gas at the moment is reduced, certain humidity is brought to the room at the same time, meanwhile, the windward side of the valve 29 is provided with the arc-shaped protrusions, the gas can be assisted to split, and better enter various positions in the room, meanwhile, because the air is high-pressure, a part of outdoor air is guided by pressure and filtered by the second filter element 39 and then mixed with high-pressure air into the room, so that larger air inflow is brought, the indoor air quality is improved, in the process, along with the rise of the temperature, the water in the second inner cavity 12 is gradually reduced, after a period of time, the water in the first inner cavity 9 overcomes the elastic force of the first spring 17 and then is replenished into the second inner cavity 12 through the water draining hole 18 to keep the water in the second inner cavity 12, after the air moving in the condensing pipe 27 is condensed, the water flows back into the water collecting tank 32 from the condensing water draining pipe 31 to be collected, a water level sensor is additionally arranged in the second inner cavity 12, when the water in the first inner cavity 9 is insufficient to replenish the water in the second inner cavity 12, the water level sensor is operated through the pump 34, so that the water in the water collection tank 32 enters the pump 34 from the inlet pipe 33 and then gets a velocity upward movement, flushing the return check valve 36 into the second inner chamber 12 as a supplement.

Of course, the above description is not intended to limit the application to the particular embodiments disclosed, but the application is not limited to the particular embodiments disclosed, as variations, modifications, additions or substitutions within the spirit and scope of the application will become apparent to those of ordinary skill in the art.

Claims

1. An energy-conserving door and window with intelligent screen window, its characterized in that: comprises a door window frame (1), a screen window (2), a water storage tank (3), a cylinder body (5), an overflow hole (6), a pressure output pipe (7), a pressure cylinder (8), a first inner cavity (9), a water level control component (10), a baffle plate (11) with a connecting hole, a second inner cavity (12), a pressure rack component (13), a gear (14), a baffle plate (15), glass (40) and a switching cavity (41), wherein the screen window (2) is detachably connected to one side of the door window frame (1), the water storage tank (3) is arranged on the upper part of the door window frame (1), the water outlet end of the water storage tank (3) is communicated with the water inlet end of the cylinder body (5), the cylinder body (5) is fixedly connected to one side of the door window frame (1), the upper part of the cylinder body (5) is provided with the overflow hole (6), the second inner cavity (12) in the cylinder body (5) is communicated with the pressure cylinder (8) through the pressure output pipe (7), the pressure cylinder (8) is connected to the side wall of the door window frame (1), the inner cavity (11) is separated from the first inner cavity (12) by the second inner cavity (9), the control assembly (10) is slidably connected in the first inner cavity (9) and penetrates through the partition board (11) with the connecting hole to extend into the second inner cavity (12) for controlling the water level in the second inner cavity (12), a switching cavity (41) is arranged at the lower part of the door and window frame (1), the pressure rack assembly (13) is slidably connected in the pressure cylinder (8) and the switching cavity (41) for controlling the opening and closing of the baffle plates (15), a plurality of baffle plates (15) uniformly arranged on the upper frame and the lower frame of the door and window frame (1) are rotatably connected to the door and window frame (1), the pressure rack assembly (13) is meshed with the gear (14), one gear (14) is connected to the lower end of each baffle plate (15), and the glass (40) is connected to one side, far away from the screen window (2), of the door and window frame (1);

the pressure rack assembly (13) comprises: the device comprises a pressure disc (21), a second spring (22), a pressure channel (23), racks (24), an exhaust one-way valve (25) and an exhaust pipe (26), wherein the pressure disc (21) is connected with the racks (24), the pressure disc (21) is slidably connected in a pressure cylinder (8), the second spring (22) is sleeved on the racks (24), two ends of the second spring (22) are respectively abutted against the inner wall of the pressure cylinder (8) and the side wall of a door and window frame (1), the pressure channel (23) is respectively arranged on the pressure disc (21) and the racks (24), the racks (24) are slidably connected in a switching cavity (41), the racks (24) are meshed with each gear (14) and used for controlling the steering of a baffle plate (15), the exhaust one-way valve (25) is arranged in the exhaust pipe (26), and the exhaust pipe (26) is communicated with the pressure output end of the pressure channel (23);

the energy-saving door and window further comprises: the condenser comprises a condenser tube (27), a drainage channel (28), an air valve (29) and an air outlet (30), wherein one end of the condenser tube (27) is communicated with the upper end of an exhaust tube (26), the condenser tube (27) is a coiled tube, the other end of the condenser tube (27) extends into the drainage channel (28), the drainage channel (28) is arranged on a side frame of a door and window frame (1), the mouth of the condenser tube (27) faces the air valve (29), the air valve (29) is hinged to the inner wall of the upper side of the drainage channel (28), the air outlet (30) is arranged on the door and window frame (1) and is communicated with the drainage channel (28), and the air valve (29) is arranged at the communication position of the air outlet (30) and the drainage channel (28).

The energy-saving door and window further comprises: the novel water heater comprises a condensation drain pipe (31), a water collecting tank (32), an introducing pipe (33), a pump (34), an eduction pipe (35), a backflow one-way valve (36) and a backflow port (37), wherein the condensation drain pipe (31) is communicated with the lower end of an exhaust pipe (26), the water collecting tank (32) is connected with the lower end of a door and window frame (1), the condensation drain pipe (31) is communicated with the inside of the water collecting tank (32), one end of the introducing pipe (33) is communicated with the water collecting tank (32), the introducing pipe (33) is located at one side far away from the condensation drain pipe (31), the other end of the introducing pipe (33) is communicated with the pump (34), an output pipeline of the pump (34) is communicated with the backflow port (37), and the backflow port (37) is arranged on a cylinder body (5) and is communicated with a second inner cavity (12), and the backflow one-way valve (36) is arranged at the communicating part of the output pipeline of the pump (34) and the backflow port (37).

2. An energy saving door and window with intelligent screen according to claim 1, characterized in that the water level control assembly (10) comprises: pressure cylinder (16), first spring (17), wash port (18), spacing dish (19) and float (20), pressure cylinder (16) sliding connection is in first inner chamber (9) and pass in taking connecting hole baffle (11) to extend to second inner chamber (12), first spring (17) cover is on pressure cylinder (16), connect respectively on the baffle of pressure cylinder (16) upper portion and cylinder body (5) at first spring (17) both ends, pressure cylinder (16) lower part is equipped with a plurality of wash ports (18), and spacing dish (19) set up in pressure cylinder (16) lower extreme and support on taking connecting hole baffle (11) lower terminal surface, spacing dish (19) lower extreme is equipped with float (20).

3. The energy efficient door and window with intelligent screen of claim 1, further comprising: the first filter element (38) is arranged between the water storage groove (3) and the cylinder body (5).

4. An energy efficient door and window with an intelligent screen according to claim 3, further comprising: the second filter element (39) is arranged at one end, far away from the air valve (29), in the drainage channel (28).

5. An energy efficient door and window with an intelligent screen according to claim 1, wherein: the cylinder body (5) is wrapped with heat absorbing materials, and the materials are black.

6. An energy efficient door and window with an intelligent screen according to claim 1, wherein: and the outer wall of the condensing tube (27) is wrapped with a heat insulation material.

7. An energy efficient door and window with an intelligent screen according to claim 1, wherein: the exhaust outlet (30) is provided with a matched thread plug.