CN111395932A

CN111395932A - Manual-automatic integrated hollow glass built-in shutter

Info

Publication number: CN111395932A
Application number: CN202010412875.8A
Authority: CN
Inventors: 袁东琴
Original assignee: Jiangsu Zhongcheng Shutter Manufacturing Co ltd
Current assignee: Jiangsu Zhongcheng Shutter Manufacturing Co ltd
Priority date: 2020-05-15
Filing date: 2020-05-15
Publication date: 2020-07-10
Anticipated expiration: 2040-05-15
Also published as: CN111395932B

Abstract

A manual-automatic integrated hollow glass built-in shutter comprises a window body; the inner glass is arranged corresponding to the front side of the window body, and the outer glass is arranged corresponding to the rear side of the window body; the shutter piece overturning and shutter lifting actuating mechanism is arranged at the upper part of the window body; the shutter curtain is arranged in the shutter curtain cavity; the manual operating mechanism is arranged corresponding to one side of the window body; the method is characterized in that: the automatic operating mechanism comprises a positioner, a motor and a control box, the positioner is connected with the motor, the positioner is arranged on the curtain piece overturning and blind lifting executing mechanism, the motor is arranged on the upper portion of the window body, the motor and the manual operating mechanism are connected or disconnected with the curtain piece overturning and blind lifting executing mechanism, the control box is connected with an external power supply, the positioner is connected with the control box, the turnover shaft working mode switching mechanism is arranged on the upper portion of the window body, and the turnover shaft working mode switching mechanism is connected with the control box. The advantages are that: the selection is flexible; the function is increased; the service life is long.

Description

Manual-automatic integrated hollow glass built-in shutter

Technical Field

The invention belongs to the technical field of sun-shading hollow glass products, and particularly relates to a manual-automatic integrated hollow glass built-in shutter.

Background

The foregoing manual-automatic integration means: the two operation modes of the hand-driven operation and the electric-driven operation are effectively combined with each other, and the hollow glass built-in blind described above is a double-layer hollow glass built-in blind (the same applies hereinafter). The hollow glass built-in shutter has the following advantages: the heat insulation performance is good, so that the energy conservation of the building can be embodied; excellent sound insulation performance to avoid the disturbance of external noise; the condensation and frost prevention can ensure sufficient indoor light and show expected bright effect; the required indoor lighting requirement is obtained and the privacy is protected by adjusting the deflection angle of the curtain sheet of the blind; the shutter curtain sheet (the habit is called as the 'curtain sheet' for short) is prevented from being polluted by dust, so that the excellent cleaning-free effect is embodied; the decorative board has ideal decorative property for buildings so as to improve the grade of the buildings; strong impact resistance, good safety and long service life, thereby meeting the installation requirements of high-rise buildings and the extremely long-term use and maintenance-free requirements, and the like.

Technical information on a hollow glass built-in louver is not disclosed in the published Chinese and foreign patent documents, such as CN2564720Y (hollow glass with built-in louver), CN2767624Y (louver in hollow glass), CN2767625Y (louver in hollow glass with improved structure), CN2756796Y (louver in hollow glass), CN2232968Y (integral door and window sash with transverse louver in double glass), CN2297952Y (magnetically driven laminated retractable curtain), CN2326718Y (fully enclosed louver), CN100535378C (louver in hollow glass with improved structure), CN102444372A (a built-in sun-shading hollow louver), CN105064896B (single-control double-layer hollow glass built-in louver), CN105041168B (energy-saving multilayer hollow glass louver with simplified structure), CN105041170B (non-magnet driven double-layer hollow glass built-in louver), CN105041172B (bead chain double-layer hollow glass built-in louver), CN109538096A (double-control hollow glass built-in louver with louver cavity balanced with external pressure), CN109538097A (blind anti-slipping device for hollow glass built-in blind), CN109441323A (single-control hollow glass built-in blind capable of preventing blind slipping down) and CN109488189A (single-control hollow glass built-in blind capable of preventing inner absorption of glass), foreign patents such as US20021897681A, 1US2004211528A, US2015159431a1, GB671685A, EP2369121a2, EP1542054a1 and W003071082A, and the like.

Common features of the hollow glass built-in blind, not limited to the above examples, are: the turnover of the curtain sheet and the lifting of the blind are realized by hand driving operation, namely, the turnover of the curtain sheet and the lifting of the blind are realized by manual operation of a manual operation mechanism. The components of the structural system of the manual operating mechanism comprise an inner manipulator, an outer manipulator, a turnover shaft driving device, a curtain sheet turnover haulage rope and a curtain sheet turnover haulage rope tensioning device, wherein the outer manipulator which is arranged on one side of inner glass back to outer glass in a vertically moving mode is magnetically attracted together with the inner manipulator arranged between the inner glass and the outer glass through the inner glass, the turnover shaft driving device corresponding to the upper part of the inner manipulator is connected with a turnover shaft of the structural system of the curtain sheet turnover and shutter curtain lifting executing mechanism, the curtain sheet turnover haulage rope is connected with the inner manipulator, a rope winding wheel of the structural system of the turnover shaft driving device and a curtain sheet turnover haulage rope tensioning device corresponding to the lower part of the inner manipulator, so when a user moves the outer manipulator upwards or downwards, the outer manipulator drives the inner manipulator to correspondingly move upwards and downwards, and the inner manipulator drives the curtain sheet turnover haulage rope, the turning rope wheel of the structural system of the turning shaft driving device is driven by the turning traction rope of the curtain piece, and the turning shaft and the rope wheel are fixedly inserted, so that the rope wheel drives the curtain piece turning and shutter lifting actuating mechanism to move, and the curtain piece is turned as required or the shutter is lifted as required.

The above patent structure is bound by the traditional design idea or design concept, so that the operation mode is monotonous, namely, the curtain piece turning and the lifting of the blind can be realized only by a manual operation mechanism. Thus, on the one hand, the user is limited in his freedom of choice of the mode of operation, for example for the elderly population and/or pre-adults with relatively weak physical abilities may choose a relatively light and labor-saving mode of operation; on the other hand, the market expansion of the hollow built-in shutter is more or less influenced due to the simplification or dull plate of the operation mode; on the other hand, once the curtain piece overturning hauling rope is worn and broken due to long time, the curtain piece overturning hauling rope tensioning device, the inner controller and/or the outer controller are damaged, and the like, the curtain piece of the blind cannot be overturned, even the blind cannot be lifted through conventional manual operation according to needs, the use in the future is influenced, once the fault occurs, the blind can be only treated by a production and a seller or replaced by a new one, and therefore the expense of a user is increased, and the resource waste is caused. In view of the foregoing disadvantages, and without limitation, there is a need for reasonable improvements in the art that will be described below.

Disclosure of Invention

The invention aims to provide a manual-automatic integrated hollow glass built-in shutter which is beneficial to meeting the flexible selection requirements of users on different operation modes, enriching operation modes, reasonably increasing functions with practicability, being convenient to replace one operation mode by another operation mode after the other operation mode fails so as to avoid influencing the use, being beneficial to obviously prolonging the service life, reducing the cost of abandoning and replacing users and saving resources.

The task of the invention is accomplished in such a way that the manual-automatic integrated hollow glass built-in shutter comprises a window body; the inner glass is arranged corresponding to the front side of the window body, the outer glass is arranged corresponding to the rear side of the window body, and a space between the inner glass and the outer glass is formed into a blind cavity; the curtain piece overturning and shutter lifting actuating mechanism is arranged at the upper part of the window body; the shutter blind is arranged in the shutter blind cavity, and the upper part of the shutter blind is connected with the shutter piece overturning and shutter blind lifting actuating mechanism at the position of the upper part of the window body; the manual operating mechanism is arranged corresponding to one side of the window body; the automatic operating mechanism comprises a positioner, a motor and a control box, the positioner is electrically connected with the motor through a circuit, the positioner is arranged on the curtain sheet overturning and blind lifting actuating mechanism at the upper part of the window body, the motor is arranged at the upper part of the window body, the motor and the manual operating mechanism are respectively connected with or disconnected from the curtain sheet overturning and blind lifting actuating mechanism through the overturning shaft operating mode switching mechanism, the control box is electrically connected with an external power supply circuit and arranged on a wall body along with the window body, the positioner is led out of the window body through an electric circuit and is electrically connected with the control box, the overturning shaft operating mode switching mechanism is also arranged at the upper part of the window body and is matched with the curtain sheet overturning and blind lifting actuating mechanism, and the overturning shaft operating mode switching mechanism is also led out of the electric circuit through the electric circuit and is electrically connected with the window body control box.

In a specific embodiment of the present invention, the window body includes an upper cross frame strip, a lower cross frame strip, a left longitudinal frame strip and a right longitudinal frame strip, wherein the left end of the upper cross frame strip is connected to the upper end of the left longitudinal frame strip, the right end of the upper cross frame strip is connected to the upper end of the right longitudinal frame strip, the left end of the lower cross frame strip is connected to the lower end of the left longitudinal frame strip, and the right end of the lower cross frame strip is connected to the lower end of the right longitudinal frame strip; the peripheral edge part of one side of the inner glass facing the outer glass is simultaneously attached to the front sides of the upper transverse frame strip, the lower transverse frame strip, the left longitudinal frame strip and the right longitudinal frame strip, and the peripheral edge part of one side of the outer glass facing the inner glass is simultaneously attached to the rear sides of the upper transverse frame strip, the lower transverse frame strip, the left longitudinal frame strip and the right longitudinal frame strip; a sealing rubber strip embedding cavity is formed at the peripheral edge part of one opposite side of the inner glass and the outer glass, and a sealing rubber strip for bonding and fixing the peripheral edge part of one opposite side of the inner glass and the outer glass together with the upper transverse frame strip, the lower transverse frame strip, the left longitudinal frame strip and the right longitudinal frame strip is embedded in the sealing rubber strip embedding cavity; the manual operating mechanism is arranged corresponding to the position of the right longitudinal frame strip; the curtain piece overturning and shutter curtain lifting actuating mechanism, the positioner of the automatic operating mechanism, the motor and the overturning shaft working mode switching mechanism are arranged on the upper cross frame strip; the upper part of the blind arranged in the blind cavity is connected with a blind piece overturning and blind lifting actuating mechanism at the position of the upper cross frame strip; the control box is arranged on the wall body at the position along with the left longitudinal frame strip.

In another specific embodiment of the present invention, a top cross frame strip slot cavity running through from the left end to the right end of the top cross frame strip is formed on one side of the top cross frame strip in the length direction and facing the inner glass, and a top cross frame strip inserting tube integrated with the top wall of the top cross frame strip slot cavity is further formed on the top of the top cross frame strip in the length direction; a left longitudinal frame strip slot cavity which penetrates from the upper end to the lower end of the left longitudinal frame strip is formed on one side, facing the right longitudinal frame strip, of the left longitudinal frame strip, and a left longitudinal frame strip inserting pipe which forms an integral structure with the bottom wall of the left longitudinal frame strip slot cavity of the left longitudinal frame strip is further formed on the left side of the left longitudinal frame strip in the height direction; a right longitudinal frame strip slot cavity which is communicated from the upper end to the lower end of the right longitudinal frame strip is formed on one side of the right longitudinal frame strip, which faces the left longitudinal frame strip, a right longitudinal frame strip inserting pipe which is inserted and embedded with the right longitudinal frame strip is further arranged on the right side of the right longitudinal frame strip in the height direction, and an inner controller sliding groove is formed in the height direction of one side of the right longitudinal frame strip, which faces the inner glass; the left end of the blind arranged in the blind cavity formed between the inner glass and the outer glass extends into the left longitudinal frame strip groove cavity, and the right end of the blind extends into the right longitudinal frame strip groove cavity; the manual operation mechanism is arranged corresponding to the position of the sliding cavity of the inner manipulator, the curtain piece overturning and shutter lifting actuating mechanism, the positioner of the automatic operation mechanism, the motor and the overturning shaft working mode switching mechanism are arranged in the groove cavity of the upper transverse frame strip, the positioner is led to the outside after the positioner penetrates through the upper end of the left longitudinal frame strip by an electric circuit and is electrically connected with the control box, and the overturning shaft working mode switching mechanism is led to the outside after the switching mechanism electric circuit penetrates through the upper end of the left longitudinal frame strip and is electrically connected with the control box.

In another specific embodiment of the present invention, the curtain sheet turning and blind lifting actuator comprises a turning shaft, a pair of turning shaft supporting seats, a pair of turning rope wheels and a pair of rope winders, wherein the pair of turning shaft supporting seats are arranged in the upper cross frame strip slot cavity of the upper cross frame strip and are fixedly embedded with the upper cross frame strip slot cavity bottom plate of the upper cross frame strip slot cavity, the pair of rope winders are respectively sleeved at two ends of the turning shaft and are respectively and rotatably supported on the pair of turning shaft supporting seats towards one end of the pair of turning shaft supporting seats, the left end of the turning shaft extends to the left end of one rope winder positioned at the left side of the pair of rope winders, and the pair of turning rope wheels are respectively and directly formed on the pair of rope winders at positions corresponding to the pair of turning shaft supporting seats; the blind is provided with a pair of blind turning ladder ropes and a pair of blind lifting traction ropes which correspond to the pair of turnover shaft supporting seats, the upper ends of the pair of blind turning ladder ropes are upwards led to a pair of turnover rope wheels through the lower parts of the pair of turnover shaft supporting seats, one to two circles are wound on the pair of turnover rope wheels, the lower ends of the pair of blind lifting traction ropes are fixed with bottom strips of the blind, and the upper ends of the pair of blind lifting traction ropes are led to a pair of rope winders after sequentially passing through a blind traction rope hole formed in a blind of the blind and the pair of turnover shaft supporting seats, are then wound on the pair of rope winders in a spiral state and are fixed with one ends of the pair of rope winders, which are far away from the pair of turnover shaft supporting seats; the positioner of the automatic operating mechanism is arranged on a turning shaft, the turning shaft working mode switching mechanism is matched with the turning shaft, the turning shaft working mode switching mechanism disconnects the connection relation between the left end of the turning shaft and the motor under the condition that the manual operating mechanism is in a manual operating mode, and the turning shaft working mode switching mechanism disconnects the connection relation between the right end of the turning shaft and the manual operating mechanism under the condition that the automatic operating mechanism is in an automatic operating mode; the upper end of the left longitudinal frame strip is provided with a circuit yielding hole corresponding to the position of the groove cavity of the upper transverse frame strip, the positioner leads the outside world to be electrically connected with the control box after the electric circuit passes through the circuit yielding hole, and the switching mechanism of the working modes of the turnover shaft is also led the outside world to be electrically connected with the control box after the electric circuit of the switching mechanism passes through the circuit yielding hole.

In another specific embodiment of the present invention, a trip shaft support embedded cavity is formed on the upper transverse frame bar groove cavity bottom plate of the upper transverse frame bar groove cavity and at a position corresponding to the pair of trip shaft support seats, and an opening of the trip shaft support embedded cavity faces the inner glass; the lower parts of the pair of turnover shaft supporting seats are respectively provided with a turnover shaft supporting seat caulking groove, the turnover shaft supporting seat caulking grooves are matched with the cavity wall of the turnover shaft supporting seat caulking cavity in an embedding way, a supporting seat traction rope abdicating hole is formed in the middle position of the lower parts of the pair of turnover shaft supporting seats, the upper parts of the pair of turnover shaft supporting seats are respectively provided with a turnover rope wheel cavity, the pair of turnover rope wheels are respectively and directly formed on the pair of rope winders at the positions corresponding to the turnover rope wheel cavities, the pair of turnover shaft supporting seats are respectively provided with a bearing, one end of the pair of rope winders facing the pair of turnover shaft supporting seats is respectively extended with a rope winder rotating supporting seat, and the rope winder rotating supporting seat is in rotating fit with the bearing hole of the bearing; the upper ends of the pair of blind curtain lifting traction ropes penetrate through the supporting seat traction rope yielding holes from bottom to top, and the upper ends of the pair of blind curtain overturning ladder ropes are upwards led to overturning rope pulley cavities at positions corresponding to overturning ladder rope grooves formed in the front side and the rear side of the pair of overturning shaft supporting seats and then sleeved on the pair of overturning rope pulleys.

In another specific embodiment of the present invention, a lifting traction rope clamping seat is respectively disposed at one end of each of the pair of rope winders away from the pair of turnover shaft supporting seats, a blind lifting traction rope clamping groove is disposed on the lifting traction rope clamping seat, a clamping seat locking hole is further disposed on the lifting traction rope clamping seat, a clamping seat locking screw is disposed at a position corresponding to the clamping seat locking hole, the upper end of the pair of blind lifting traction ropes is clamped in the blind lifting traction rope clamping groove, and the clamping seat locking screw is locked with the turnover shaft; and the outer walls of the pair of rope winders are provided with claw grooves at intervals in the circumferential direction around the pair of rope winders, and the lifting traction rope clamping seat is provided with claws at intervals in the circumferential direction around the lifting traction rope clamping seat, the positions of the claws correspond to the claw grooves, and the claws are matched with the claw grooves.

In a more specific embodiment of the present invention, the switching mechanism of the operation mode of the turning shaft includes a manual mode electromagnetic clutch and an automatic mode electromagnetic clutch supported on the bottom plate of the upper cross frame bar groove cavity at a position corresponding to the upper cross frame bar groove cavity, the manual mode electromagnetic clutch is engaged with the right end of the turning shaft and establishes or releases the connection between the right end of the turning shaft and the manual operation mechanism by the manual mode electromagnetic clutch, the automatic mode electromagnetic clutch is engaged with the left end of the turning shaft and establishes or releases the connection between the left end of the turning shaft and the motor by the automatic mode electromagnetic clutch; the manual mode electromagnetic clutch and the automatic mode electromagnetic clutch are electrically connected with the control box through the switching mechanism electric circuit; a wiring groove is formed at the upper part of the upper cross frame strip groove cavity in the length direction and at the position corresponding to the lower part of the upper cross frame strip insertion pipe, and is used for laying the circuit for electrically connecting the positioner, the motor and the control box in the wiring groove and laying the electric circuit of the switching mechanism for electrically connecting the manual mode electromagnetic clutch and the automatic mode electromagnetic clutch with the control box in the wiring groove.

In a further specific embodiment of the present invention, the manual operating mechanism includes an inner manipulator, an outer manipulator, a flipping shaft driving device, a curtain flipping belt and a curtain flipping belt tensioning device, the inner manipulator is disposed in the inner manipulator sliding groove in a manner of moving up and down, the outer manipulator is disposed in a side of the inner glass facing away from the outer glass in a manner of moving up and down through an outer manipulator sliding guide bar at a position corresponding to the inner manipulator and magnetically attracted to the inner manipulator through the inner glass, the flipping shaft driving device is disposed at a junction between a right end of the upper cross frame bar groove and an upper end of the inner manipulator sliding groove at a position corresponding to a right side of the manual mode electromagnetic clutch, and the right end of the flipping shaft is connected to or disconnected from the flipping shaft driving device by the manual mode electromagnetic clutch, the curtain sheet overturning traction belt tensioning device is arranged at the bottom of the height direction of the inner controller sliding groove at a position corresponding to the lower part of the inner controller, one end of the curtain sheet overturning traction belt is fixedly connected with the upper part of the inner controller, the middle part of the curtain sheet overturning traction belt is sequentially sleeved on the overturning shaft driving device and the curtain sheet overturning traction belt tensioning device, and the other end of the curtain sheet overturning traction belt is fixedly connected with the lower part of the inner controller.

In yet a more specific embodiment of the invention, the cross-sectional shape of the flip shaft is a regular hexagon.

In yet a further particular embodiment of the invention, a raceway notch is formed at the bottom of the raceway and along the length of the raceway; the motor is a positive and negative rotation motor.

One of the technical effects of the technical scheme provided by the invention is that the automatic operating mechanism and the turnover shaft working mode switching mechanism are additionally arranged, so that the requirement of flexibly selecting manual and automatic operating modes according to requirements of a user is favorably met; secondly, the functions with practicability are reasonably increased because the manual operation and the automatic operation can be carried out through electric control; thirdly, when any one of the manual operation mode and the automatic operation mode has a fault, the other operation mode can continuously ensure the turnover of the curtain sheet and the lifting of the blind curtain, and the use is not influenced; fourthly, because two operation modes are provided, the service life can be obviously prolonged, the replacement cost of a user is reduced, and the resource is saved.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present invention.

Fig. 2 is a detailed structural view of the curtain blade turning and blind lifting actuator shown in fig. 1.

Fig. 3 is a detailed configuration diagram of the automatic operation mechanism and the trip shaft operation mode switching mechanism shown in fig. 1.

Fig. 4 is an enlarged view of a portion a of fig. 3.

Detailed Description

In order to clearly understand the technical spirit and the advantages of the present invention, the applicant below describes in detail by way of example, but the description of the example is not intended to limit the technical scope of the present invention, and any equivalent changes made according to the present inventive concept, which are merely in form and not in material, should be considered as the technical scope of the present invention.

In the following description, all the concepts related to the directions or orientations of up, down, left, right, front and rear are based on the position state of fig. 1, and thus, it should not be understood as a particular limitation to the technical solution provided by the present invention.

Referring to fig. 1, a window 1 is shown; an inner glass 2 and an outer glass 3 are shown, the inner glass 2 is arranged corresponding to the front side of the window body 1, the outer glass is arranged corresponding to the rear side of the window body 1, the peripheral edge parts of the opposite sides of the inner glass 2 and the outer glass 3 are fixedly bonded with the window body 1 through sealing rubber strips, and the space between the inner glass 2 and the outer glass 3 is formed into a blind cavity 10; a curtain piece overturning and blind lifting actuating mechanism 5 is shown, and the curtain piece overturning and blind lifting actuating mechanism 5 is arranged at the upper part of the window body 1; a blind 6 is shown, the blind 6 is arranged in the blind cavity 10 and the upper part of the blind 6 is connected with the blind blade overturning and blind lifting actuator 5 at the position of the upper part of the window body 1; a manually operated mechanism 4 is shown, which manually operated mechanism 4 is arranged in correspondence with one side of the aforementioned window 1, i.e. in correspondence with one longitudinal side (right side in the figure) of window 1.

The technical key points of the technical scheme provided by the invention are as follows: the structure system of the hollow glass built-in shutter also comprises an automatic operating mechanism 7 and a turnover shaft operating mode switching mechanism 8, the automatic operating mechanism 7 comprises a positioner 71, a motor 72 and a control box 73, the positioner 71 is electrically connected with the motor 72 by a line, the positioner 71 is arranged on the curtain turnover and shutter lifting actuating mechanism 5 at the upper part of the window body 1, the motor 72 is arranged at the upper part of the window body 1, the motor 72 and the manual operating mechanism 4 are respectively connected with or disconnected from the curtain turnover and shutter lifting actuating mechanism 5 by the turnover shaft operating mode switching mechanism 8, the control box 73 is electrically connected with an external power circuit and arranged on a wall body along with the window body 1, the positioner 71 is electrically connected with the control box 73 by leading out the window body 1 by an electric line, the turnover shaft operating mode switching mechanism 8 is also arranged at the upper part of the window body 1 and is matched with the curtain turnover and shutter lifting actuating mechanism 5 The switching mechanism 8 for the operation mode of the flip shaft is also electrically connected to the control box 73 through the switching mechanism electric circuit leading out window 1.

The applicant needs to state that: if the aforementioned control box 73 is affixed to a reasonable position on the side of the inner glass 2 facing the room, i.e. on the side of the inner glass 2 facing away from the outer glass 3, it should be considered as an equivalent form change and still fall within the technical scope of the present disclosure.

Continuing with fig. 1, the window 1 comprises an upper horizontal frame 11, a lower horizontal frame 12, a left vertical frame 13 and a right vertical frame 14, the left end of the upper horizontal frame 11 is connected with the upper end of the left vertical frame 13 through an L-shaped or 7-shaped corner connector 16, the right end of the upper horizontal frame 11 is connected with the upper end of the right vertical frame 14 through the corner connector 16, the left end of the lower horizontal frame 12 is connected with the lower end of the left vertical frame 13 through the corner connector 16, the right end of the lower horizontal frame 12 is connected with the lower end of the right vertical frame 14 through the corner connector 16, the peripheral edge of the side of the inner glass 2 facing the outer glass 3 is simultaneously contacted with the front sides of the upper horizontal frame 11, the lower horizontal frame 12, the left vertical frame 13 and the right vertical frame 14, the peripheral edge of the side of the outer glass 3 facing the inner glass 2 is simultaneously contacted with the rear sides of the upper horizontal frame 11, the lower horizontal frame 12, the left vertical frame 13 and the right vertical frame 14, the peripheral edge of the side of the outer glass 3 is simultaneously contacted with the rear sides of the upper horizontal frame 11, the lower horizontal frame 12, the left vertical frame 13 and the vertical frame 14, the louver window mechanism is provided with the louver sealing mechanism, the louver 14, the louver sealing mechanism for fixing the louver sealing mechanism and the louver 7 is provided at the position of the upper vertical frame 14, the louver mechanism, the louver 14, the louver mechanism is provided at the position of the louver 14, the louver 14 and the louver mechanism, the louver 14, the louver mechanism, the louver 14 is provided at the louver 14, the louver mechanism is provided at the louver mechanism, the louver mechanism is provided at.

Continuing to refer to fig. 1, a top transverse frame strip slot cavity 111 penetrating from the left end to the right end of the top transverse frame strip 11 is formed on one side of the top transverse frame strip 11 facing the inner glass 2 in the length direction, and a top transverse frame strip inserting tube 112 integrally formed with the top wall of the top transverse frame strip slot cavity 111 is formed on the top of the top transverse frame strip 11 in the length direction; a left longitudinal frame strip slot cavity 131 penetrating from the upper end to the lower end of the left longitudinal frame strip 13 is formed on one side of the left longitudinal frame strip 13 facing the right longitudinal frame strip 14, and a left longitudinal frame strip insertion pipe 132 integrated with the bottom wall of the left longitudinal frame strip slot cavity 131 is formed on the left side of the left longitudinal frame strip 13 in the height direction; a right longitudinal frame strip slot cavity 141 running through from the upper end to the lower end of the right longitudinal frame strip 14 is formed on one side of the right longitudinal frame strip 14 facing the left longitudinal frame strip 13, a right longitudinal frame strip inserting pipe 142 inserted and connected with the right longitudinal frame strip 14 is further arranged on the right side of the right longitudinal frame strip 14 in the height direction, and an inner manipulator sliding slot 143 is formed on one side of the right longitudinal frame strip 14 facing the inner glass 2 in the height direction; the left end of the blind 6 disposed in the blind cavity 10 formed between the inner glass 2 and the outer glass 3 is inserted into the left vertical frame groove 131, and the right end of the blind 6 is inserted into the right vertical frame groove 141; the manual operating mechanism 4 is disposed corresponding to the position of the inner manipulator sliding chamber 143, the curtain inverting and venetian blind lifting actuator 5, the positioner 71, the motor 72, and the switching mechanism 8 for the operation mode of the tilt shaft of the automatic operating mechanism 7 are disposed in the top horizontal frame rail cavity 111, the positioner 71 is electrically connected to the control box 73 by an electrical circuit after passing through the top end of the left vertical frame 13, and the switching mechanism 8 for the operation mode of the tilt shaft is electrically connected to the control box 73 by an electrical circuit of the switching mechanism after passing through the top end of the left vertical frame 13.

Referring to fig. 2 in combination with fig. 1 and 3, the curtain sheet turnover and blind lifting actuator 5 includes a turnover shaft 51, a pair of turnover shaft supporting seats 52, a pair of turnover rope pulleys 53 and a pair of rope winders 54, wherein the pair of turnover shaft supporting seats 52 are disposed in the upper cross frame bar cavity 111 of the upper cross frame bar 11 and are fixedly embedded with the upper cross frame bar cavity bottom plate 1111 of the upper cross frame bar cavity 111, the pair of rope winders 54 are respectively sleeved on both ends of the turnover shaft 51 and the pair of rope winders 54 are respectively rotatably supported on the pair of turnover shaft supporting seats 52 towards one end of the pair of turnover shaft supporting seats 52, the left end of the turnover shaft 51 extends to the left end of one rope winder on the left side of the pair of rope winders 54, and the pair of turnover rope pulleys 53 are respectively and directly formed on the pair of rope winders 54 at positions corresponding to the pair of turnover shaft supporting seats 52; the blind 6 has a pair of blind turning rope 61 and a pair of blind lifting rope 62 corresponding to the pair of turning shaft supporting seats 52, the upper ends of the pair of blind turning rope 61 are led upwards to the pair of turning rope wheels 53 through the lower parts of the pair of turning shaft supporting seats 52, and are wound on the pair of turning rope wheels 53 by one to two turns, the lower ends of the pair of blind lifting rope 62 are fixed with the bottom bar 63 of the blind 6, and the upper ends of the pair of blind lifting rope 62 are led to the pair of rope winders 54 after sequentially passing through the blind pulling rope hole 641 opened on the blind 64 of the blind 6 and the pair of turning shaft supporting seats 52, and are then wound on the pair of rope winders 54 in a spiral state and then are fixed with the ends of the pair of rope winders 54 far away from the pair of turning shaft supporting seats 52; the positioner 71 of the automatic operation mechanism 7 is provided on the tilt shaft 51, the tilt shaft operation mode switching mechanism 8 is engaged with the tilt shaft 51, the left end of the tilt shaft 51 is disconnected from the motor 72 by the tilt shaft operation mode switching mechanism 8 in the manual operation mode of the manual operation mechanism 4, and the right end of the tilt shaft 51 is disconnected from the manual operation mechanism 4 by the tilt shaft operation mode switching mechanism 8 in the automatic operation mode of the automatic operation mechanism 7; a circuit-avoiding hole 133 is formed at the upper end of the left vertical frame 13 and at a position corresponding to the upper horizontal frame groove 111, the positioner 71 is electrically connected to the control box 73 by the electrical circuit after passing through the circuit-avoiding hole 133, and the flip-axle operating mode switching mechanism 8 is electrically connected to the control box 73 by the switching mechanism electrical circuit after passing through the circuit-avoiding hole 133.

A trip shaft support embedded cavity 11111 is formed in the upper transverse frame bar cavity bottom plate 1111 of the upper transverse frame bar cavity 111 and at a position corresponding to the pair of trip shaft supports 52, and the opening of the trip shaft support embedded cavity 11111 faces the inner glass 2; a trip shaft support embedding groove 521 is formed at the lower part of each of the pair of trip shaft support seats 52, the trip shaft support embedding groove 521 is embedded with the cavity wall of the trip shaft support embedding cavity 11111, a support traction rope abdicating hole 522 is formed at the central position of the lower part of each of the pair of trip shaft support seats 52, a trip sheave cavity 523 is formed at the upper part of each of the pair of trip shaft support seats 52, the pair of trip sheaves 53 are respectively and directly formed on the pair of rope winders 54 at the position corresponding to the trip sheave cavity 523, a bearing 524 is respectively arranged on each of the pair of trip shaft support seats 52, a rope winder rotation support seat 543 extends from one end of each of the pair of rope winders 54 facing the pair of trip shaft support seats 52, and the rope winder rotation support seat 543 is in rotation fit with the bearing hole 5241 of the bearing 524; the upper ends of the pair of blind lifting pulling ropes 62 pass through the supporting seat pulling rope abdicating holes 522 from bottom to top, and the upper ends of the pair of blind turnover rope pulleys 61 are guided upwards to the turnover rope pulley cavities 523 at positions corresponding to the turnover rope grooves 525 formed on the front and rear sides of the pair of turnover shaft supporting seats 52, and then are sleeved on the pair of turnover rope pulleys 53.

One end of each of the pair of rope winders 54, which is far from the pair of turning shaft supporting seats 52, is provided with a lifting traction rope clamping seat 541, the lifting traction rope clamping seat 541 is provided with a blind lifting traction rope clamping groove 5411, the lifting traction rope clamping seat 541 is further provided with a clamping seat locking hole 542, a clamping seat locking screw 5421 is provided at a position corresponding to the clamping seat locking hole 542, the upper end part of the pair of blind lifting traction ropes 62 is clamped and fixed in the blind lifting traction rope clamping groove 5411, and the clamping seat locking screw 5421 is locked with the turning shaft 51; claw grooves 544 are formed on the outer walls of the pair of rope reels 54 at intervals in the circumferential direction around the pair of rope reels 54, and claws 5412 corresponding to the claw grooves 544 are formed on the elevating traction rope holder 541 at intervals in the circumferential direction around the elevating traction rope holder 541, and the claws 5412 are fitted into the claw grooves 544.

Continuing to refer to fig. 1 and 3, the switching mechanism 8 includes a manual mode electromagnetic clutch 81 and an automatic mode electromagnetic clutch 82 supported on the upper cross frame groove bottom 1111 at a position corresponding to the upper cross frame groove 111, the manual mode electromagnetic clutch 81 being engaged with the right end of the turning shaft 51 and the manual mode electromagnetic clutch 81 establishing or releasing the connection between the right end of the turning shaft 51 and the manual operation mechanism 4, the automatic mode electromagnetic clutch 82 being engaged with the left end of the turning shaft 51 and the automatic mode electromagnetic clutch 82 establishing or releasing the connection between the left end of the turning shaft 51 and the motor 72; the manual mode electromagnetic clutch 81 and the automatic mode electromagnetic clutch 82 are electrically connected to the control box 73 by the switching mechanism electric line. A wire groove 113 is formed at an upper portion of the upper frame bar groove cavity 111 in a longitudinal direction and at a position corresponding to a lower portion of the upper frame bar inserting pipe 112, and a line for electrically connecting the positioner 71 with the motor 72 and the control box 73 is laid in the wire groove 113, and a switching mechanism electric line for electrically connecting the manual mode electromagnetic clutch 81 and the automatic mode electromagnetic clutch 82 with the control box 73 is also laid in the wire groove 113.

As shown in fig. 1, a motor shaft 721 of the motor 72 is connected to or disconnected from the left end of the reversing shaft 51 via an automatic mode electromagnetic clutch 82.

Referring to fig. 1, the manual operating mechanism 4 includes an inner manipulator 41, an outer manipulator 42, a flipping shaft driving device 43, a curtain-flipping traction belt 44 and a curtain-flipping traction belt tension device 45, the inner manipulator 41 is disposed in the inner manipulator sliding slot 143 in a vertically movable manner, the outer manipulator 42 is disposed in a position corresponding to the inner manipulator 41 in a vertically movable manner through an outer manipulator sliding guide 421 on a side of the inner glass 2 facing away from the outer glass 3, the outer manipulator 42 is magnetically attracted to the inner manipulator 41 through the inner glass 2, the outer manipulator sliding guide 421 is attached to the inner glass 2, the flipping shaft driving device 43 is disposed at a boundary between a right end of the upper horizontal bezel cavity 111 and the inner manipulator sliding slot 143 at a position corresponding to a right side of the manual mode electromagnetic clutch 81, and the connection between the right end of the flipping shaft 51 and the flipping shaft driving device 43 is established or released by the manual mode electromagnetic clutch 81 at an upper end of the manual mode electromagnetic clutch 81 In connection with this, the curtain turning traction belt tensioning device 45 is disposed at the bottom of the inner manipulator sliding slot 143 in the height direction at a position corresponding to the lower portion of the inner manipulator 41, one end of the curtain turning traction belt 44 is fixedly connected to the upper portion of the inner manipulator 41, the middle portion of the curtain turning traction belt 44 is sequentially sleeved on the turning shaft driving device 43 and the curtain turning traction belt tensioning device 45, and the other end of the curtain turning traction belt 44 is fixedly connected to the lower portion of the inner manipulator 41.

Since the specific structures of the turning shaft driving device 43 and the curtain turning traction belt tensioning device 45 are in the prior art, for example, chinese patent documents CN108678637A and CN109488189A can be seen respectively, the applicant does not describe the same.

In the present embodiment, the cross-sectional shape of the flip shaft 51 is a regular hexagon; the motor 72 is a counter-rotating motor. Preferably, after the above-mentioned components are arranged in the upper cross frame strip groove 111, the opening of the upper cross frame strip groove 111 is covered by a protection sheet (also called "guard" or "protection strip"), and the side of the opening of the inner manipulator sliding groove 143 facing the inner glass 2 is also covered by the protection sheet.

Referring to fig. 4, a wiring groove notch 1131 is formed at the bottom of the wiring groove 113 along the length direction of the wiring groove 113, and the line for electrically connecting the positioner 71 to the motor 72, the electric line for electrically connecting the positioner 71 to the controller 73, and the switching mechanism electric line for electrically connecting the manual mode electromagnetic clutch 81 and the automatic mode electromagnetic clutch 82 are led into the wiring groove 113 through the wiring groove notch 1131 and are electrically connected to the control box 73 through the line relief hole 133. On the panel of control box 73, manual/automatic switching touch button 731, up touch arrow 732, and down touch arrow 733 are provided. In the present embodiment, the controller 73 is preferably, but not exclusively, a JZ-YI controller manufactured by the electronic control elements ltd of wuxi city, Jiangsu province, China.

The applicant describes the working process of the present invention with reference to fig. 1 to 3, in the manual operation mode, the manual and automatic switching touch button 731 is touched by the user to switch to the manual mode, at this time, the automatic mode electromagnetic clutch 82 of the structural system of the turnover shaft operation mode switching mechanism 8 disconnects the connection between the motor shaft 721 of the motor 72 and the left end of the turnover shaft 51, and the manual mode electromagnetic clutch 81 establishes the connection between the turnover shaft driving device 43 and the right end of the turnover shaft 51. In the manual operation mode, when the curtain sheet 64 is to be turned over by a certain angle, the outer controller 42 is moved by a user according to a known operation manner, the outer controller 42 drives the inner controller 41, the inner controller 41 drives the curtain sheet turning traction belt 44, the curtain sheet turning traction belt 44 drives the turning shaft driving device 43, the turning shaft driving device 43 drives the turning shaft 51 to rotate by a desired angle, the turning shaft 51 drives the pair of rope rolling devices 54 and the pair of turning rope wheels 53 integrally formed thereon to rotate by an angle, and the pair of curtain sheet turning rope wheels 53 drives the pair of curtain sheet turning rope wheels to turn by an angle, so that the curtain sheet 64 turns by a corresponding angle. The direction of inversion of the curtain 64, such as inward or outward inversion (also referred to as "tilt down or tilt up"), depends on the direction of up or down travel of the outer manipulator 42. When the blind is to be lifted up or lowered down, the outer manipulator 42 is operated in the same manner as described above, i.e., the pair of cord winders 54 are rotated by the trip shaft 51, and the blind lifting/lowering pulling cords 62 are wound up or unwound by the pair of cord winders 54 to raise or lower the blind 6.

When the curtain sheet 64 is to be turned over and the blind 6 is to be lifted or lowered in the automatic mode (also referred to as "electric mode"), the manual/automatic switching touch button 731 of the control box 73 is touched by the user to switch the mode to the automatic mode, and at this time, the manual mode electromagnetic clutch 81 of the structural system of the turning shaft operation mode switching mechanism 8 disconnects the connection between the turning shaft driving device 43 and the right end of the turning shaft 51, and the automatic mode electromagnetic clutch 82 establishes the connection between the motor shaft 721 of the motor 72 and the left end of the turning shaft 51.

When the curtain sheet 64 is turned upwards by a certain angle, a user touches an upward touch arrow 732, the positioner 71 rotates the motor 72, the motor shaft 721 drives the turning shaft 51 to rotate by a corresponding angle through the automatic mode electromagnetic clutch 82, the turning shaft 51 drives the pair of rope winders 54 and the pair of turning rope wheels 53 integrally formed thereon to rotate by a corresponding angle, and the pair of turning rope wheels 53 drives the pair of curtain sheet turning rope wheels 61 to turn by a corresponding angle, so that the curtain sheet 64 is turned by a corresponding angle. Conversely, when the down touch arrow 733 is pressed, the motor 72 is reversed, and the curtain sheet 64 is turned in the reverse direction by the aforementioned reverse process.

In the automatic mode, when the blind 6 is to be retracted upward, the operator presses the upward touching arrow 732, the motor 72 rotates forward, specifically, the motor shaft 721 drives the turning shaft 51 to rotate correspondingly through the automatic mode electromagnetic clutch 82, and then the turning shaft 51 drives the pair of cord winders 54 to rotate correspondingly, so as to drive the blind lifting/lowering pulling cord 62 to continuously wind around the cord winders 54 in a spiral state, until the blind 6 is lifted to a desired extent, the finger is not separated from the upward arrow, and vice versa.

If the blind 6 is raised upward or lowered downward to the limit, but the operator's finger is not yet separated from the upward touch arrow 732 or the downward touch arrow 733, the operation of the motor 72 is stopped by the positioner 71, i.e., the operation power of the motor 72 is cut off by the positioner 71. Because the function of the positioner 71 is to control the number of positive and negative rotation turns of the motor 72 to precisely control the blind 6 to ascend to the limit or descend to the limit position, the control of the motor 72 and the protection of the motor 72 are achieved. The aforementioned electrically operated control box 73 is electrically connected to an external power supply circuit of 220 volts.

The applicant needs to state that: if the window 1 is large in width, the width of the blind 6 is correspondingly increased, in which case it is possible to increase the number of the aforementioned slat overturning ladder cords 61, blind lifting traction cords 62, and the pair of overturning shaft bearing blocks 52, the pair of overturning cords 53, and the pair of cord winders 54 of the structural system of the slat overturning and blind lifting actuator 5 adaptively, for example, to three, so that the present application is not limited by the above-mentioned embodiment. In addition, if the structure is modified reasonably to increase the number of the motors 72 to increase the lifting force, the invention also falls into the technical scope of the invention.

In conclusion, the technical scheme provided by the invention overcomes the defects in the prior art, successfully completes the invention task and truly realizes the technical effects of the applicant in the technical effect column.

Claims

1. A manual-automatic integrated hollow glass built-in shutter comprises a window body (1); an inner glass (2) and an outer glass (3), wherein the inner glass (2) is arranged corresponding to the front side of the window body (1), the outer glass is arranged corresponding to the rear side of the window body (1), and the space between the inner glass (2) and the outer glass (3) is formed into a blind cavity (10); the curtain piece overturning and shutter curtain lifting actuating mechanism (5) is arranged at the upper part of the window body (1); the blind (6) is arranged in the blind cavity (10), and the upper part of the blind (6) is connected with the blind overturning and blind lifting actuating mechanism (5) at the position of the upper part of the window body (1); the manual operating mechanism (4), the manual operating mechanism (4) is arranged corresponding to one side of the window body (1); the automatic operating mechanism (7) comprises a positioner (71), a motor (72) and a control box (73), the positioner (71) is electrically connected with the motor (72) through a circuit, the positioner (71) is arranged on the curtain turnover and blind lifting actuating mechanism (5) at the upper part of the window body (1), the motor (72) is arranged at the upper part of the window body (1), the motor (72) and the manual operating mechanism (4) are respectively connected with or disconnected from the curtain turnover and blind lifting actuating mechanism (5) through the turnover shaft operating mode switching mechanism (8), the control box (73) is electrically connected with an external power circuit and arranged on a wall body along with the window body (1), the positioner (71) is led out of the window body (1) through an electric circuit and is electrically connected with the control box (73), the turnover shaft working mode switching mechanism (8) is also arranged at the upper part of the window body (1) and is matched with the curtain sheet turnover and blind lifting actuating mechanism (5), and the turnover shaft working mode switching mechanism (8) is also led out of the window body (1) by an electric circuit of the switching mechanism and is electrically connected with the control box (73).

2. The manual-automatic integrated hollow glass built-in shutter as claimed in claim 1, wherein the shutter (1) comprises an upper cross frame strip (11), a lower cross frame strip (12), a left longitudinal frame strip (13) and a right longitudinal frame strip (14), the left end of the upper cross frame strip (11) is connected with the upper end of the left longitudinal frame strip (13), the right end of the upper cross frame strip (11) is connected with the upper end of the right longitudinal frame strip (14), the left end of the lower cross frame strip (12) is connected with the lower end of the left longitudinal frame strip (13), and the right end of the lower cross frame strip (12) is connected with the lower end of the right longitudinal frame strip (14); the peripheral edge of one side, facing the outer glass (3), of the inner glass (2) is simultaneously attached to the front sides of the upper transverse frame strip (11), the lower transverse frame strip (12), the left longitudinal frame strip (13) and the right longitudinal frame strip (14), and the peripheral edge of one side, facing the inner glass (2), of the outer glass (3) is simultaneously attached to the rear sides of the upper transverse frame strip (11), the lower transverse frame strip (12), the left longitudinal frame strip (13) and the right longitudinal frame strip (14); a sealing rubber strip embedding cavity (15) is formed in the peripheral edge part of the opposite side of the inner glass (2) and the outer glass (3), and a sealing rubber strip for bonding and fixing the peripheral edge part of the opposite side of the inner glass (2) and the outer glass (3) together with the upper transverse frame strip (11), the lower transverse frame strip (12), the left longitudinal frame strip (13) and the right longitudinal frame strip (14) is embedded in the sealing rubber strip embedding cavity (15); the manual operating mechanism (4) is arranged corresponding to the position of the right longitudinal frame strip (14); the curtain piece overturning and shutter curtain lifting actuating mechanism (5), the positioner (71) of the automatic operating mechanism (7), the motor (72) and the overturning shaft working mode switching mechanism (8) are arranged on the upper cross frame strip (11); the upper part of the blind (6) arranged in the blind cavity (10) is connected with a blind piece overturning and blind lifting actuating mechanism (5) at the position of the upper cross frame strip (11); the control box (73) is arranged on the wall at the position along with the left longitudinal frame strip (13).

3. The manual-automatic hollow glass built-in blind according to claim 2, characterized in that a top cross frame strip slot cavity (111) running from the left end to the right end of the top cross frame strip (11) is formed in the length direction of the top cross frame strip (11) and on the side facing the inner glass (2), and a top cross frame strip inserting tube (112) forming an integrated structure with the top wall of the top cross frame strip slot cavity (111) is further formed on the top of the top cross frame strip (11) in the length direction; a left longitudinal frame strip slot cavity (131) which penetrates from the upper end to the lower end of the left longitudinal frame strip (13) is formed in one side, facing the right longitudinal frame strip (14), of the left longitudinal frame strip (13), and a left longitudinal frame strip insertion pipe (132) which forms an integral structure with the bottom wall of the left longitudinal frame strip slot cavity (131) is formed in the left side of the left longitudinal frame strip (13) in the height direction; a right longitudinal frame strip slot cavity (141) which penetrates from the upper end to the lower end of the right longitudinal frame strip (14) is formed in one side, facing the left longitudinal frame strip (13), of the right longitudinal frame strip (14), a right longitudinal frame strip inserting pipe (142) which is inserted and embedded with the right longitudinal frame strip (14) is further arranged on the right side of the right longitudinal frame strip (14) in the height direction, and an inner manipulator sliding slot (143) is formed in the right longitudinal frame strip (14) in the height direction, facing the inner glass (2); the left end of the blind (6) arranged in the blind cavity (10) formed between the inner glass (2) and the outer glass (3) is inserted into the left longitudinal frame strip groove cavity (131), and the right end of the blind (6) is inserted into the right longitudinal frame strip groove cavity (141); the manual operating mechanism (4) is arranged corresponding to the position of the inner controller sliding cavity (143), the curtain sheet overturning and blind lifting executing mechanism (5), the positioner (71) of the automatic operating mechanism (7), the motor (72) and the overturning shaft working mode switching mechanism (8) are arranged in the upper transverse frame strip groove cavity (111), the positioner (71) is led to the outside after penetrating through the upper end of the left longitudinal frame strip (13) by an electric circuit and is electrically connected with the control box (73), and the overturning shaft working mode switching mechanism (8) is led to the outside after penetrating through the upper end of the left longitudinal frame strip (13) by the electric circuit of the switching mechanism and is electrically connected with the control box (73).

4. A manual-automatic hollow glass built-in blind according to claim 3, characterized in that said blind turnover and blind lifting actuator (5) comprises a turnover shaft (51), a pair of turnover shaft supporting seats (52), a pair of turnover rope wheels (53) and a pair of rope winders (54), the pair of turnover shaft supporting seats (52) is arranged in the upper cross frame bar groove cavity (111) of the upper cross frame bar (11) and is embedded and fixed with the upper cross frame bar groove cavity bottom plate (1111) of the upper cross frame bar groove cavity (111), the pair of rope winders (54) are respectively sleeved and fixed at the two ends of the turnover shaft (51) and the pair of rope winders (54) are respectively and rotatably supported on the pair of turnover shaft supporting seats (52) towards one end of the pair of turnover shaft supporting seats (52), the left end of the turnover shaft (51) extends to the left end of one of the pair of rope winders (54) which is positioned at the left, a pair of turning rope wheels (53) are respectively and directly formed on a pair of rope winders (54) at the positions corresponding to the pair of turning shaft supporting seats (52); the blind (6) is provided with a pair of blind turning ladder ropes (61) and a pair of blind lifting traction ropes (62) which correspond to the pair of turning shaft supporting seats (52), the upper ends of the pair of blind turning ladder ropes (61) are upwards led to a pair of turning rope wheels (53) through the lower parts of the pair of turning shaft supporting seats (52), and one to two circles are wound on the pair of turning rope wheels (53), the lower ends of the pair of blind lifting traction ropes (62) are fixed with bottom strips (63) of the blind (6), the upper ends of a pair of blind lifting traction ropes (62) sequentially penetrate through a blind sheet traction rope hole (641) formed in a blind sheet (64) of the blind (6) and a pair of turnover shaft supporting seats (52), then are led to a pair of rope winders (54), and are wound on the pair of rope winders (54) in a spiral state and then are respectively fixed with one ends of the pair of rope winders (54) far away from the pair of turnover shaft supporting seats (52); a positioner (71) of the automatic operation mechanism (7) is arranged on a turnover shaft (51), the turnover shaft working mode switching mechanism (8) is matched with the turnover shaft (51), the connection relationship between the left end of the turnover shaft (51) and the motor (72) is disconnected by the turnover shaft working mode switching mechanism (8) under the manual operation mode of the manual operation mechanism (4), and the connection relationship between the right end of the turnover shaft (51) and the manual operation mechanism (4) is disconnected by the turnover shaft working mode switching mechanism (8) under the automatic operation mode of the automatic operation mechanism (7); a circuit yielding hole (133) is formed in the upper end of the left longitudinal frame strip (13) and in a position corresponding to the upper transverse frame strip groove cavity (111), the positioner (71) is guided to the outside to be electrically connected with the control box (73) after the electric circuit penetrates through the circuit yielding hole (133), and the turnover shaft working mode switching mechanism (8) is guided to the outside to be electrically connected with the control box (73) after the electric circuit of the switching mechanism penetrates through the circuit yielding hole (133) in the same way.

5. The manual-automatic hollow glass built-in shutter is characterized in that a turning shaft support embedded cavity (11111) is formed in the upper transverse frame bar groove cavity bottom plate (1111) of the upper transverse frame bar groove cavity (111) and at the position corresponding to the pair of turning shaft support seats (52), and the opening of the turning shaft support embedded cavity (11111) faces to the inner glass (2); a turning shaft supporting seat embedding groove (521) is formed at the lower part of each turning shaft supporting seat (52), the embedding groove (521) of the turnover shaft supporting seat is embedded and matched with the cavity wall of the embedding cavity (11111) of the turnover shaft supporting seat, and a support seat traction rope abdicating hole (522) is arranged at the middle position of the lower parts of the pair of turnover shaft support seats (52), a turning rope wheel cavity (523) is respectively formed at the upper parts of the pair of turning shaft supporting seats (52), the pair of turning rope wheels (53) are respectively and directly formed on a pair of rope winders (54) at the positions corresponding to the turning rope wheel cavities (523), and a bearing (524) is respectively arranged on the pair of turnover shaft supporting seats (52), one end of each rope winder (54) facing the turnover shaft supporting seats (52) is respectively extended with a rope winder rotating supporting seat (543), the rope winder rotation supporting seat (543) is in rotation fit with a bearing hole (5241) of the bearing (524); the upper ends of the pair of blind curtain lifting traction ropes (62) penetrate through the supporting seat traction rope abdicating holes (522) from bottom to top, and the upper ends of the pair of blind curtain overturning ladder ropes (61) are upwards led to overturning rope wheel cavities (523) at positions corresponding to overturning ladder rope grooves (525) formed in the front side and the rear side of the pair of overturning shaft supporting seats (52) and then sleeved on the pair of overturning rope wheels (53).

6. A manual-automatic hollow glass built-in blind window according to claim 4, characterized in that one end of each of the pair of rope rolling devices (54) far away from the pair of turnover shaft supporting seats (52) is provided with a lifting traction rope clamping seat (541), the lifting traction rope clamping seat (541) is provided with a blind lifting traction rope clamping groove (5411), the lifting traction rope clamping seat (541) is further provided with a clamping seat locking hole (542), a clamping seat locking screw (5421) is provided at a position corresponding to the clamping seat locking hole (542), the upper end parts of the pair of blind lifting traction ropes (62) are clamped in the blind lifting traction rope clamping groove (5411), and the clamping seat locking screw (5421) is locked with the turnover shaft (51); claw grooves (544) are formed on the outer walls of the pair of rope winders (54) at intervals in the circumferential direction of the pair of rope winders (54), claws (5412) corresponding to the claw grooves (544) are formed on the lifting traction rope clamping seat (541) at intervals in the circumferential direction of the lifting traction rope clamping seat (541), and the claws (5412) are matched with the claw grooves (544).

7. A hand-automatic hollow glass built-in blind according to claim 4, characterized in that said switching mechanism (8) of the operation mode of the turning shaft comprises a manual mode electromagnetic clutch (81) and an automatic mode electromagnetic clutch (82) supported on the bottom plate (1111) of the upper cross frame groove at a position corresponding to the upper cross frame groove (111), the manual mode electromagnetic clutch (81) being engaged with the right end of the turning shaft (51), and the manual mode electromagnetic clutch (81) establishes or releases the connection between the right end of the turning shaft (51) and the manual operation mechanism (4), the automatic mode electromagnetic clutch (82) is matched with the left end of the turning shaft (51), and the left end of the turning shaft (51) is connected or disconnected with the motor (72) by the automatic mode electromagnetic clutch (82); a manual mode electromagnetic clutch (81) and an automatic mode electromagnetic clutch (82) electrically connected to the control box (73) by the switching mechanism electric line; a wiring groove (113) is formed at the upper part of the upper frame strip groove cavity (111) in the length direction and at a position corresponding to the lower part of the upper frame strip insertion pipe (112), a line for electrically connecting the positioner (71), the motor (72) and the control box (73) is laid in the wiring groove (113), and a switching mechanism electric line for electrically connecting the manual mode electromagnetic clutch (81) and the automatic mode electromagnetic clutch (82) with the control box (73) is also laid in the wiring groove (113).

8. The manual-automatic hollow glass built-in blind according to claim 7, characterized in that said manual operating mechanism (4) comprises an inner manipulator (41), an outer manipulator (42), a turning shaft driving device (43), a curtain turning traction belt (44) and a curtain turning traction belt tensioning device (45), the inner manipulator (41) is disposed in said inner manipulator sliding groove (143) in a manner of moving up and down, the outer manipulator (42) is disposed in a manner of moving up and down through an outer manipulator sliding guide bar (421) at a position corresponding to said inner manipulator (41) at a side of said inner glass (2) opposite to said outer glass (3) and magnetically attracted with the inner manipulator (41) through the inner glass (2), the turning shaft driving device (43) is disposed at a position corresponding to a right side of said manual mode electromagnetic clutch (81) at a right end of an upper cross frame bar groove cavity (111) and a right end of said inner manipulator sliding groove (143) The connection relation between the right end of the turnover shaft (51) and the turnover shaft driving device (43) is established or released by a manual mode electromagnetic clutch (81), a curtain turning traction belt tensioning device (45) is arranged at the bottom of the height direction of an inner manipulator sliding groove (143) at a position corresponding to the lower part of the inner manipulator (41), one end of a curtain turning traction belt (44) is fixedly connected with the upper part of the inner manipulator (41), the middle part of the curtain turning traction belt (44) is sequentially sleeved on the turnover shaft driving device (43) and the curtain turning traction belt tensioning device (45), and the other end of the curtain turning traction belt (44) is fixedly connected with the lower part of the inner manipulator (41).

9. An automated manual hollow glass built-in blind according to claim 4 or 6 or 7 or 8, characterized in that the cross-sectional shape of the turning shaft (51) is a regular hexagon.

10. An automated hollow glass built-in blind according to claim 7, characterised in that a cabling channel notch (1131) is formed at the bottom of the cabling channel (113) and along the length of the cabling channel (113); the motor (72) is a positive and negative rotation motor.