CN218029834U - Novel high energy-saving bridge-cut-off aluminum alloy energy-saving window - Google Patents

Abstract

The utility model discloses a novel energy-conserving bridge cut-off aluminum alloy energy-conserving window of high energy-conserving relates to the energy-conserving window technical field of aluminum alloy, include: a first window and a second window are movably arranged in the window frame; a support rod is fixedly arranged in the middle of the inner side of the window frame; sponge strips are fixedly arranged at the front and the rear of the supporting rod; the controller and the storage battery are fixedly arranged on the left side of the front face of the window frame, and the controller is arranged at the bottom of the storage battery; the solar photovoltaic panels are fixedly arranged on two sides of the top of the back of the window frame through the rotating shaft seats; the beneficial effects are that: the novel high-energy-saving bridge-cut-off aluminum alloy energy-saving window can monitor outdoor temperature and rainfall through the temperature sensor and the rainfall sensor, when the temperature value or the rainfall value exceeds a set value, the controller can control the first motor and the second motor to work simultaneously, the first window and the second window are moved to a closed state respectively, and the first window and the second window can be closed automatically, so that heat can be reduced to enter a room, and the heat insulation effect is improved; and simultaneously can prevent rainwater from permeating into the room.

Description

Novel high energy-saving bridge-cut-off aluminum alloy energy-saving window

Technical Field

The utility model relates to an energy-conserving window technical field of aluminum alloy, concretely relates to novel energy-conserving bridge cut-off aluminum alloy energy-conserving window of high energy-conservation.

Background

The energy-saving door and window is used for increasing the lighting and ventilation area or representing the character characteristics of modern buildings, the energy-saving door and window can improve the optical performance, the thermal performance and the sealing performance of materials and improve the structure of the door and window to achieve the expected effect, and the energy-saving door and window should be considered from the following aspects, namely the material of the door and window, the glass and the energy conservation of the door and window are the integral energy conservation;

when the existing aluminum alloy energy-saving door and window is used, dust on the window is not convenient to clean; people forget to close the window, and when the people are in rainy days, rainwater can be sprinkled into the room; meanwhile, in high-temperature weather, sunlight can penetrate through the glass and irradiate into the room, so that the indoor temperature is increased, and the problem that the existing aluminum alloy energy-saving door and window cannot be automatically closed is solved; therefore, a novel high-energy-saving bridge-cut-off aluminum alloy energy-saving window is provided to solve the problems.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

The not enough to prior art, the utility model provides a novel energy-conserving bridge cut-off aluminum alloy energy-saving window of high energy-conserving has solved the problem that proposes in the above-mentioned background art.

(II) technical scheme

The utility model discloses a following technical scheme realizes: the utility model provides a novel energy-conserving bridge cut-off aluminum alloy energy-saving window of high energy-conservation, include: the device comprises a window frame, a first window, a second window, a support rod, a sponge strip, a controller, a rotating shaft seat, a solar photovoltaic panel, a temperature sensor, a rainfall sensor and a storage battery; a first window and a second window are movably arranged in the window frame; a support rod is fixedly arranged in the middle of the inner side of the window frame; sponge strips are fixedly arranged on the front and the rear of the supporting rod; the controller and the storage battery are fixedly mounted on the left side of the front face of the window frame, and the controller is arranged at the bottom of the storage battery; the solar photovoltaic panel is fixedly arranged on two sides of the top of the back of the window frame through the rotating shaft seat; a temperature sensor is fixedly arranged on the left side of the bottom of the back of the window frame; a rainfall sensor is fixedly arranged on the right side of the bottom of the back of the window frame;

the first window includes: the first bottom cavity, the first threaded lead screw, the first motor, the first top cavity, the first sliding rod, the first sliding block, the first threaded sleeve and the first embedding groove are formed in the first bottom cavity; the first window is arranged on the front side inside the window frame; the first bottom cavity is arranged inside the front side of the bottom of the window frame; a first motor is fixedly arranged on the right side in the first bottom cavity; a first threaded lead screw is fixedly mounted on the left side of the first motor; the first top cavity is arranged inside the front side of the top of the window frame; a first sliding rod is fixedly arranged in the first top cavity; a first sliding block is fixedly arranged at the top of the first window, and the interior of the first sliding block is movably arranged on a first sliding rod; a first threaded sleeve is fixedly installed at the bottom of the first window, and the inner part of the first threaded sleeve is movably installed on a first threaded lead screw; the first embedding groove is formed in the left side inside the window frame;

the second window includes: the second bottom cavity, the second slide bar, the second top cavity, the second motor, the second threaded lead screw, the second threaded sleeve, the second slide block and the second embedding groove; the second window is arranged at the rear side of the inner part of the window frame; the second bottom cavity is arranged inside the rear side of the bottom of the window frame; a second sliding rod is fixedly arranged in the second bottom cavity; the second top cavity is arranged inside the rear side of the top of the window frame; a second motor is fixedly arranged on the left side inside the second top cavity; a second threaded screw rod is fixedly arranged on the right side of the second motor; a second threaded sleeve is fixedly mounted at the top of the second window, and the interior of the second threaded sleeve is movably mounted on a second threaded lead screw; a second sliding block is fixedly arranged at the bottom of the second window, and the interior of the second sliding block is movably arranged on a second sliding rod; the second embedding groove is formed in the right side inside the window frame.

As a preferred, inside screw thread of first thread bush and the outside screw thread looks adaptation of first screw thread lead screw, just first slider is sliding connection with first slide bar.

As a preferred, the inside screw thread of second thread bush and the outside screw thread looks adaptation of second screw thread lead screw, just the second slider is sliding connection with the second slide bar.

As an optimization of the utility model, the bracing piece sets up between first window and second window, and around just the sponge strip is all hugged closely on first window and second window.

Preferably, the inner part of the first embedding groove and the left side of the first window are in an embedding structure; and the inner part of the second embedding groove and the right side of the second window are of an embedding structure.

As an optimization of the utility model, the solar photovoltaic board passes through the rotatable 90 of pivot seat maximum limit.

As an optimization, the controller is electrically connected with the storage battery, the solar photovoltaic panel, the first motor, the second motor, the temperature sensor and the rainfall sensor.

(III) advantageous effects

Compared with the prior art, the utility model, following beneficial effect has:

(1) The novel high-energy-saving bridge-cut-off aluminum alloy energy-saving window can monitor outdoor temperature and rainfall through the temperature sensor and the rainfall sensor, when the temperature value or the rainfall value exceeds a set value, the controller can control the first motor and the second motor to work simultaneously, the first window and the second window are moved to a closed state respectively, and the first window and the second window can be closed automatically, so that heat can be reduced to enter a room, and the heat insulation effect is improved; and simultaneously can prevent rainwater from permeating into the room.

(2) The novel high-energy-saving bridge-cut-off aluminum alloy energy-saving window is tightly attached to the surfaces of the first window and the second window through the sponge strips, so that the sealing property between the first window and the second window can be ensured when the first window and the second window are closed; when first window and second window removed, the sponge strip can be cleaned first window and second window surface, makes the sponge strip be convenient for clear up the dust that is stained with on first window and the second window.

(3) The novel high-energy-saving bridge-cutoff aluminum alloy energy-saving window can rotationally adjust the position of the solar photovoltaic panel through the rotating shaft seat, so that sunlight and rainwater can be blocked when the solar photovoltaic panel is unfolded, and the solar photovoltaic panel is prevented from entering a room; the solar photovoltaic panel can absorb solar energy, then the controller can convert the solar energy into electric energy to be directly used by the first motor, the second motor, the temperature sensor and the rainfall sensor, and meanwhile, the storage battery can store the electric energy, so that the normal use of the window can be ensured under the condition of no sunshine; thereby achieving the effect of energy saving.

(4) The novel high-energy-saving bridge-cut-off aluminum alloy is energy-saving by arranging a first embedding groove and a second embedding groove; when the first window is in a closed state, the left side of the first window is embedded in the first embedding groove; when the second window is in a closed state, the right side of the second window is embedded in the second embedding groove; thereby improving sealability and stability when the first and second windows are closed.

Drawings

FIG. 1 is a front view of the whole of the present invention;

FIG. 2 is a schematic view of the overall back structure of the present invention;

FIG. 3 is a schematic view of the structure of the integral window frame of the present invention;

FIG. 4 is a schematic front sectional view of the integrated window frame and the first window according to the present invention;

FIG. 5 is a schematic front sectional view of the integrated window frame and the second window of the present invention;

FIG. 6 is a schematic top cross-sectional view of the integrated first and second windows of the present invention;

fig. 7 is an enlarged schematic structural diagram of the whole fig. 6 a of the present invention.

The reference numerals are illustrated below:

1. a window frame; 2. a first window; 201. a first bottom chamber; 202. a first threaded lead screw; 203. a first motor; 204. a first top cavity; 205. a first slide bar; 206. a first slider; 207. a first threaded sleeve; 208. A first damascene groove; 3. a second window; 301. a second bottom cavity; 302. a second slide bar; 303. a second top cavity; 304. a second motor; 305. a second threaded lead screw; 306. a second threaded sleeve; 307. a second slider; 308. a second damascene groove; 4. a support bar; 5. a sponge strip; 6. a controller; 7. a rotating shaft seat; 8. a solar photovoltaic panel; 9. a temperature sensor; 10. a rainfall sensor; 11. and (4) a storage battery.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

As shown in fig. 1-7, a novel energy-saving bridge-cut-off aluminum alloy energy-saving window comprises: the solar window comprises a window frame 1, a first window 2, a second window 3, a support rod 4, a sponge strip 5, a controller 6, a rotating shaft seat 7, a solar photovoltaic panel 8, a temperature sensor 9, a rainfall sensor 10 and a storage battery 11; a first window 2 and a second window 3 are movably arranged in the window frame 1; a support rod 4 is fixedly arranged in the middle of the inner side of the window frame 1; sponge strips 5 are fixedly arranged at the front and the back of the supporting rod 4; the controller 6 and the storage battery 11 are fixedly installed on the left side of the front face of the window frame 1, and the controller 6 is arranged at the bottom of the storage battery 11; the solar photovoltaic panel 8 is fixedly arranged on two sides of the top of the back of the window frame 1 through the rotating shaft seat 7; a temperature sensor 9 is fixedly arranged on the left side of the bottom of the back of the window frame 1; a rainfall sensor 10 is fixedly arranged on the right side of the bottom of the back of the window frame 1;

the first window 2 includes: a first bottom cavity 201, a first threaded lead screw 202, a first motor 203, a first top cavity 204, a first slide bar 205, a first slide block 206, a first threaded sleeve 207 and a first embedding groove 208; the first window 2 is arranged at the front side inside the window frame 1; the first bottom cavity 201 is arranged inside the front side of the bottom of the window frame 1; a first motor 203 is fixedly arranged on the right side in the first bottom cavity 201; a first threaded lead screw 202 is fixedly arranged on the left side of the first motor 203; the first top cavity 204 is arranged inside the front side of the top of the window frame; a first sliding rod 205 is fixedly arranged in the first top cavity 204; a first sliding block 206 is fixedly installed at the top of the first window 2, and the inside of the first sliding block 206 is movably installed on a first sliding rod 205; a first threaded sleeve 207 is fixedly installed at the bottom of the first window 2, and the first threaded sleeve 207 is movably installed on the first threaded lead screw 202; the first mosaic groove 208 is arranged at the left side inside the window frame 1;

the second window 3 includes: a second bottom cavity 301, a second slide bar 302, a second top cavity 303, a second motor 304, a second threaded lead screw 305, a second threaded sleeve 306, a second slide block 307 and a second embedding groove 308; the second window 3 is arranged at the rear side inside the window frame 1; the second bottom cavity 301 is arranged inside the rear side of the bottom of the window frame 1; a second sliding rod 302 is fixedly arranged in the second bottom cavity 301; the second top cavity 303 is arranged inside the rear side of the top of the window frame 1; a second motor 304 is fixedly arranged at the left side in the second top cavity 303; a second threaded lead screw 305 is fixedly arranged on the right side of the second motor 304; a second thread sleeve 306 is fixedly arranged at the top of the second window 3, and the second thread sleeve 306 is movably arranged on a second thread screw 305; a second sliding block 307 is fixedly arranged at the bottom of the second window 3, and the inside of the second sliding block 307 is movably arranged on the second sliding rod 302; the second mosaic groove 308 is provided at the right side of the inside of the window frame 1.

In this embodiment, the internal thread of the first threaded sleeve 207 is matched with the external thread of the first threaded lead screw 202, and the first sliding block 206 is slidably connected with the first sliding rod 205.

When the window is used, the first motor 203 drives the first threaded lead screw 202 to rotate, so that the first threaded sleeve 207 can horizontally move left and right on the first threaded lead screw 202, the first threaded sleeve 207 can synchronously drive the first window 2 to horizontally move left and right, and the first window 2 can be automatically opened and closed;

the first window 2 moves while synchronously driving the first sliding block 206 to move on the first sliding rod 205, so that the first window 2 moves more stably, and the stability can be improved.

In this embodiment, the internal thread of the second thread sleeve 306 is matched with the external thread of the second threaded lead screw 305, and the second sliding block 307 is slidably connected with the second sliding rod 302.

When the window is used, the second motor 304 drives the second threaded lead screw 305 to rotate, so that the second threaded sleeve 306 can horizontally move left and right on the second threaded lead screw 305, and the second threaded sleeve 306 can synchronously drive the second window 3 to horizontally move left and right, so that the second window 3 can be automatically opened and closed;

the second window 3 moves while synchronously driving the second slider 307 to move on the second sliding bar 302, so that the second window 3 moves more stably, and the stability can be improved.

In this embodiment, the support rod 4 is disposed between the first window 2 and the second window 3, and the front and rear sponge strips 5 are tightly attached to the first window 2 and the second window 3.

When the window is used specifically, the sponge strips 5 are tightly attached to the surfaces of the first window 2 and the second window 3, so that when the first window 2 and the second window 3 are closed, the sealing performance between the first window 2 and the second window 3 can be ensured; when the first window 2 and the second window 3 move, the sponge strip 5 can wipe the surfaces of the first window 2 and the second window 3, so that the sponge strip 5 can clean dust attached to the first window 2 and the second window 3.

In this embodiment, the inside of the first damascene groove 208 and the left side of the first window 2 are damascene structures; and the inside of the second embedding groove 308 and the right side of the second window 3 are embedded structures.

When the first window 2 is in a closed state, the left side of the first window 2 can be embedded in the first embedding groove 208; when the second window 3 is in a closed state, the right side of the second window 3 can be embedded in the second embedding groove 308; so that the sealability and stability when the first and second windows 2 and 3 are closed can be improved.

In this embodiment, the solar photovoltaic panel 8 can rotate 90 ° through the maximum range of the rotating shaft base 7.

When the solar window is used specifically, solar energy can be absorbed through the solar photovoltaic panel 8, then the controller 6 can convert the solar energy into electric energy to be directly used by the first motor 203, the second motor 304, the temperature sensor 9 and the rainfall sensor 10, and meanwhile, the electric energy can be stored through the storage battery 11, so that the normal use of the window can be ensured under the condition of no sunshine;

can rotate the regulation to the position of solar photovoltaic board 8 through pivot seat 7, can block sunlight and rainwater when solar photovoltaic board 8 expandes simultaneously, prevent to get into indoorly.

In this embodiment, the controller 6 is electrically connected to the storage battery 11, the solar photovoltaic panel 8, the first motor 203, the second motor 304, the temperature sensor 9, and the rainfall sensor 10.

When the solar rain sensor is used specifically, the working states of the storage battery 11, the solar photovoltaic panel 8, the first motor 203, the second motor 304, the temperature sensor 9 and the rainfall sensor 10 can be controlled through the controller 6, and a display and a control button are arranged on the controller 6; the temperature and the rain amount value monitored by the temperature sensor 9 and the rain amount sensor 10 can be displayed in real time through the display on the controller 6; the movement of the first and second windows 2, 3 may be manually controlled by control buttons on the controller 6;

the outdoor temperature can be monitored through the temperature sensor 9, and when the temperature exceeds a set value, the controller 6 can control the first motor 203 and the second motor 304 to work, so that the first window 2 and the second window 3 are moved to a closed state, heat can be reduced from entering the room, and the heat insulation effect is improved;

outdoor rainwater can be monitored through the rainfall sensor 10, and when the rainfall exceeds a set value, the controller 6 can control the first motor 203 and the second motor 304 to operate, so that the first window 2 and the second window 3 are moved to a closed state, and rainwater can be prevented from being sprayed indoors.

The utility model provides a novel energy-conserving bridge cut-off aluminum alloy energy-saving window's of high energy-conserving theory of operation:

firstly, solar energy can be absorbed through the solar photovoltaic panel 8, then the controller 6 can convert the solar energy into electric energy to be directly used by the first motor 203, the second motor 304, the temperature sensor 9 and the rainfall sensor 10, and meanwhile, the electric energy can be stored through the storage battery 11, so that the normal use of a window can be ensured under the condition of no sunshine;

the outdoor temperature and the rainfall value can be monitored through the temperature sensor 9 and the rainfall sensor 10, and when the temperature value or the rainfall value exceeds a set value, the controller 6 can control the first motor 203 and the second motor 304 to work; moving the first window 2 and the second window 3 to the closed state;

the specific operation is as follows: the first motor 203 drives the first threaded lead screw 202 to rotate, so that the first threaded sleeve 207 horizontally moves on the first threaded lead screw 202, the first threaded sleeve 207 synchronously drives the first window 2 to horizontally move, and the first window 2 can be automatically closed; the first window 2 synchronously drives the first sliding block 206 to move on the first sliding rod 205 while moving, so that the first window 2 is more stable when moving, and the stability can be improved;

the second motor 304 drives the second threaded lead screw 305 to rotate, so that the second threaded sleeve 306 can horizontally move on the second threaded lead screw 305, and the second threaded sleeve 306 can synchronously drive the second window 3 to horizontally move, so that the second window 3 can be automatically closed; and the second window 3 moves and simultaneously drives the second sliding block 307 to move on the second sliding rod 302, so that the second window 3 is more stable when moving, and the stability can be improved;

so that the first window 2 and the second window 3 can be automatically closed by the above operation; heat can be reduced to enter the room, and the heat insulation effect is improved; meanwhile, rainwater can be prevented from being sprayed into the room;

meanwhile, the sponge strips 5 are tightly attached to the surfaces of the first window 2 and the second window 3, so that when the first window 2 and the second window 3 are closed, the sealing performance between the first window 2 and the second window 3 can be ensured; when the first window 2 and the second window 3 move, the sponge strip 5 can wipe the surfaces of the first window 2 and the second window 3, so that the sponge strip 5 can clean dust attached to the first window 2 and the second window 3;

meanwhile, when the first window 2 is in a closed state, the left side of the first window 2 may be inlaid in the first inlaying groove 208; when the second window 3 is in a closed state, the right side of the second window 3 can be inlaid in the second inlaying groove 308; so that the sealability and stability when the first and second windows 2 and 3 are closed can be improved.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention and are not intended to limit the spirit and scope of the present invention. Without departing from the design concept of the present invention, various modifications and improvements made by the technical solutions of the present invention should fall within the protection scope of the present invention, and the technical contents claimed in the present invention have been fully recorded in the claims.

Claims (7)

1. The utility model provides a novel energy-conserving bridge cut-off aluminum alloy energy-conserving window of high energy-conserving, includes: the solar energy rain-proof window comprises a window frame (1), a first window (2), a second window (3), a support rod (4), a sponge strip (5), a controller (6), a rotating shaft seat (7), a solar photovoltaic panel (8), a temperature sensor (9), a rainfall sensor (10) and a storage battery (11); the method is characterized in that: a first window (2) and a second window (3) are movably arranged in the window frame (1); a support rod (4) is fixedly arranged in the middle of the inner side of the window frame (1); sponge strips (5) are fixedly arranged at the front and the rear of the supporting rod (4); the controller (6) and the storage battery (11) are fixedly mounted on the left side of the front face of the window frame (1), and the controller (6) is arranged at the bottom of the storage battery (11); the solar photovoltaic panel (8) is fixedly arranged on two sides of the top of the back of the window frame (1) through the rotating shaft seat (7); a temperature sensor (9) is fixedly arranged on the left side of the bottom of the back of the window frame (1); a rainfall sensor (10) is fixedly arranged on the right side of the bottom of the back of the window frame (1);

the first window (2) comprises: the device comprises a first bottom cavity (201), a first threaded lead screw (202), a first motor (203), a first top cavity (204), a first sliding rod (205), a first sliding block (206), a first threaded sleeve (207) and a first embedding groove (208); the first window (2) is arranged on the front side inside the window frame (1); the first bottom cavity (201) is arranged inside the front side of the bottom of the window frame (1); a first motor (203) is fixedly arranged on the right side in the first bottom cavity (201); a first threaded lead screw (202) is fixedly arranged on the left side of the first motor (203); the first top cavity (204) is arranged inside the front side of the top of the window frame; a first sliding rod (205) is fixedly arranged in the first top cavity (204); a first sliding block (206) is fixedly mounted at the top of the first window (2), and the inside of the first sliding block (206) is movably mounted on a first sliding rod (205); a first threaded sleeve (207) is fixedly mounted at the bottom of the first window (2), and the first threaded sleeve (207) is movably mounted on a first threaded lead screw (202) in the first window; the first embedding groove (208) is formed in the left side inside the window frame (1);

the second window (3) comprises: the device comprises a second bottom cavity (301), a second sliding rod (302), a second top cavity (303), a second motor (304), a second threaded lead screw (305), a second threaded sleeve (306), a second sliding block (307) and a second embedding groove (308); the second window (3) is arranged at the rear side inside the window frame (1); the second bottom cavity (301) is arranged inside the rear side of the bottom of the window frame (1); a second sliding rod (302) is fixedly arranged in the second bottom cavity (301); the second top cavity (303) is arranged inside the rear side of the top of the window frame (1); a second motor (304) is fixedly arranged on the left side inside the second top cavity (303); a second threaded lead screw (305) is fixedly arranged on the right side of the second motor (304); a second threaded sleeve (306) is fixedly mounted at the top of the second window (3), and the interior of the second threaded sleeve (306) is movably mounted on a second threaded lead screw (305); a second sliding block (307) is fixedly mounted at the bottom of the second window (3), and the inside of the second sliding block (307) is movably mounted on a second sliding rod (302); the second embedding groove (308) is arranged on the right side inside the window frame (1).

2. The novel high energy-saving bridge-cut-off aluminum alloy energy-saving window of claim 1, characterized in that: the internal thread of the first thread sleeve (207) is matched with the external thread of the first threaded lead screw (202), and the first sliding block (206) is in sliding connection with the first sliding rod (205).

3. The novel high energy-saving bridge-cut-off aluminum alloy energy-saving window of claim 1, characterized in that: the internal thread of the second thread sleeve (306) is matched with the external thread of the second thread lead screw (305), and the second sliding block (307) is in sliding connection with the second sliding rod (302).

4. The novel energy-saving bridge-cut-off aluminum alloy energy-saving window with high energy-saving performance as claimed in claim 1, is characterized in that: the supporting rod (4) is arranged between the first window (2) and the second window (3), and the sponge strips (5) are tightly attached to the first window (2) and the second window (3) from front to back.

5. The novel energy-saving bridge-cut-off aluminum alloy energy-saving window with high energy-saving performance as claimed in claim 1, is characterized in that: the inner part of the first embedding groove (208) and the left side of the first window (2) are in an embedding structure; and the inner part of the second embedding groove (308) and the right side of the second window (3) are in an embedding structure.

6. The novel high energy-saving bridge-cut-off aluminum alloy energy-saving window of claim 1, characterized in that: the solar photovoltaic panel (8) can rotate by 90 degrees in the maximum range through the rotating shaft seat (7).

7. The novel high energy-saving bridge-cut-off aluminum alloy energy-saving window of claim 1, characterized in that: the controller (6) is electrically connected with the storage battery (11), the solar photovoltaic panel (8), the first motor (203), the second motor (304), the temperature sensor (9) and the rainfall sensor (10).

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