Double-circuit window motor controller and smart window that pushes away
Technical Field
The utility model relates to an intelligence electric door and window field technique especially indicates a double-circuit pushes away window machine controller and smart window.
Background
With the rapid development of artificial intelligence technology, smart homes are more and more widely used. The intelligent home provides a lot of convenience for the life of people, and the intelligent home is of various types including an intelligent control circuit, intelligent household appliances, intelligent furniture and the like. The window is the indispensable decorative article when at home, and the opening and closing of window at home are all manual at present, can be time-wasting relatively like this, therefore present window can't provide the convenient experience of intelligence for people. Under the special condition, if people go out and do not close the window, if meet weather variation and when it is rainy to windy, rainwater can enter the house and wet the furniture, and then still can cause economic loss when bringing about not less trouble to people's life.
SUMMERY OF THE UTILITY MODEL
In view of this, the utility model discloses to the disappearance that prior art exists, its main objective provides a double-circuit pushes away window machine controller and smart window, and double-circuit pushes away window machine controller and realizes that three kinds of modes of cell-phone remote control, remote controller remote control, panel control remote control electric window open/close to smart window can also manually open/close.
In order to achieve the above purpose, the utility model adopts the following technical scheme:
a double-channel sliding window motor controller comprises an MCU central control unit, a WIFI receiving module, a wireless receiving module, a panel key control circuit, a switching power supply module, a DC-DC power supply conversion circuit, a motor driving module, a handle motor driving interface and a flat-open motor driving interface;
the switching power supply module is connected with the DC-DC power supply conversion circuit and outputs direct current to supply power to the whole double-path window-pushing motor controller;
the WIFI receiving module is electrically connected to the MCU, receives a mobile phone WIFI control signal and transmits the mobile phone WIFI control signal to the MCU;
the wireless receiving module is electrically connected with the MCU, receives the wireless infrared signal of the remote controller and transmits the wireless infrared signal to the MCU;
the panel key control circuit is electrically connected with the MCU, and transmits signals of the manual operation keys to the MCU;
the electric property of the motor driving module is connected with the MCU central control unit to receive the control signal of the MCU central control unit, and the motor driving module has double-path output, one path of the motor driving module is connected with the handle motor driving interface, the other path of the motor driving module is connected with the flat-open motor driving interface to respectively control the opening and closing, the lock falling and the unlocking of the handle motor and the flat-open motor so as to realize the intelligent window.
A smart window comprises a window frame and a window sash, wherein one opposite sides of the window frame and the window sash are connected through a hinge, the other side of the window sash is provided with a handle, a handle control device is arranged in the window sash corresponding to the handle, and a handle motor is arranged in the handle control device; the automatic window frame is provided with an automatic opening and closing device, the automatic opening and closing device is connected with the window sash through a rocker arm and drives the window sash to open and close, a flat-open motor is arranged in the automatic opening and closing device, and the handle motor and the flat-open motor are electrically connected with a handle motor driving interface and a flat-open motor driving interface respectively.
Compared with the prior art, the utility model has obvious advantages and beneficial effects, concretely speaking, according to the technical scheme, the double-channel sliding window motor controller is characterized in that the MCU central control unit, the WIFI receiving module, the wireless receiving module, the panel key control circuit, the switching power supply module, the DC-DC power conversion circuit, the motor driving module, the handle motor driving interface and the flat-open motor driving interface are designed; a first remote control mode can be realized through the cell-phone, and this WIFI receiving module can with cell-phone interconnection, comes opening and close of remote control window with cell-phone APP. The second remote control mode is realized by a remote controller, the wireless receiving module and the remote controller are controlled by infrared remote control, and the opening and closing of the window are controlled by the remote controller. The window can be opened and closed by directly pressing the panel key control circuit. And, can also the manual work directly open the window under the manual state, this intelligent window is very practical, brings the convenience for opening/closing of window.
To illustrate the structural features and functions of the present invention more clearly, the present invention will be described in detail with reference to the accompanying drawings and specific embodiments.
Drawings
Fig. 1 is a schematic view of a first viewing angle of a smart window according to an embodiment of the present invention.
Fig. 2 is a schematic view of a second viewing angle of the smart window according to the embodiment of the present invention.
Fig. 3 is the first exploded view of the handle control device of the embodiment of the utility model.
Fig. 4 is a handle controlling means second exploded view of the utility model discloses an embodiment.
Fig. 5 is a first exploded view of the automatic opening and closing device according to the embodiment of the present invention.
Fig. 6 is a second exploded view of the automatic opening and closing device according to the embodiment of the present invention.
Fig. 7 is an outline view of a two-way sliding window motor controller according to an embodiment of the present invention.
Fig. 8 is a schematic circuit diagram of a dual-way window-pushing motor controller and a remote controller according to an embodiment of the present invention.
Fig. 9 is a circuit diagram of an upper circuit board of a two-way sliding window motor controller according to an embodiment of the present invention.
Fig. 10 is a circuit diagram of a lower circuit board of a dual-way sliding window motor controller according to an embodiment of the present invention.
Fig. 11 is a circuit diagram of a remote controller according to an embodiment of the present invention.
The attached drawings indicate the following:
10. window frame 11, rocking arm
20. Window sash 21, handle
30. Handle control device 301 and first cavity
31. First casing 32, first cover plate
33. Handle motor 34, first tooth group
35. Second tooth set 36, third tooth set
37. Handle clutch 38 and carrier gear
39. Falling lock rotator 391 and rack
40. Automatic opening and closing device 401 and second cavity
41. Second casing 42, second cover plate
43. Flat-open motor 44, fourth tooth group
45. Fifth gear set 46, on-off clutch
47. Sixth tooth set 48, seventh tooth set
49. Open-close rotator 50 and two-way window-pushing motor controller
51. MCU central control unit 52, WIFI receive module
53. Wireless receiving module 54 and panel key control circuit
55. Switching power supply module 56 and DC-DC power supply conversion circuit
57. Motor drive module 58 and handle motor drive interface
59. Flat-open motor drive interface 501 and LED indicating circuit
60. Remote controller 61, remote controller MCU circuit
62. Remote controller indicator lamp circuit 63 and remote controller key circuit
64. A wireless transmission circuit.
Detailed Description
Referring to fig. 1 to 11, a specific structure of a preferred embodiment of the present invention is shown, which is a smart window, and the smart window can be opened, closed, unlocked and locked by remote control of a mobile phone, remote control of a remote controller 60 and manual control.
As shown in fig. 1 and 2, the smart window includes a window frame 10 and a window sash 20. The opposite sides of the window frame 10 and the window sash 20 are connected through a hinge, the other side of the window sash 20 is provided with a handle 21, and the handle 21 can rotate so as to realize unlocking and locking between the window frame 10 and the window sash 20. In order to realize the automatic control of unlocking and locking, a handle control device 30 is arranged in the window sash 20 corresponding to the position of the handle 21, a handle motor 33 is arranged in the handle control device 30, and the handle motor 33, a gear and a clutch are reasonably arranged to realize the purposes of automatic and manual unlocking and locking. The specific structure of the handle control device 30 is shown in fig. 3 and 4.
And the window frame 10 is provided with an automatic opening and closing device 40, the automatic opening and closing device 40 is connected with the window sash 20 through the rocker arm 11 and drives the window sash 20 to open and close, a flat-open motor 43 is arranged in the automatic opening and closing device 40, and the flat-open motor 43, a gear and a clutch are reasonably arranged to achieve the opening and closing purposes of the window. The detailed structure of the automatic opening and closing device 40 is shown in fig. 5 and 6.
As shown in fig. 3 and 4, the handle control device 30 includes a first housing 31, a first cover plate 32, a handle motor 33, a first tooth group 34, a second tooth group 35, a third tooth group 36, a handle clutch 37, a carrier gear 38, a drop lock rotator 39, and a rack 391.
The first casing 31 and the first cover plate 32 enclose to form a first cavity 301 for assembling each driving device, the handle motor 33 and each gear are installed in the first cavity 301, an output shaft of the handle motor 33 is connected with a turbine, the turbine is meshed with the first tooth group 34, the first tooth group 34 is meshed with the second tooth group 35, the second tooth group 35 is meshed with the third tooth group 36, and the third tooth group 36 is linked with the handle clutch 37. The handle clutch 37 is disengaged from the carrier gear 38 in the manual control state and is in contact with the carrier gear 38 in the electric control state. The carrier gear 38 is connected to a drop lock rotator 39, and the drop lock rotator 39 is in contact with the rack 391.
The handle clutch 37 performs both manual and automatic control functions of the handle control device 30. When the handle is automatically controlled, the handle clutch 37 is in an on state, and the handle motor 33 drives the lock-falling rotator 39 to rotate, so that the window sash 20 is driven to be unlocked or locked. When manually controlled, the handle clutch 37 is in the "off" state, so that the handle 21 is manually rotated to directly drive the handle clutch 37. In particular, the handle control device 30 of the present embodiment, by properly arranging the positions of the respective sets of teeth and the handle clutch 37, makes the torque larger, the speed gentle, and the sound more quiet when unlocking (or locking) the window. Furthermore, due to the design of the handle clutch 37, the locking and unlocking of the window sash 20 is smoother and less prone to jamming.
And, still because the reasonable overall arrangement of these tooth group, handle clutch 37 and lock rotator 39 etc. for whole controller is more small-size, and the whole that casing and apron formed is the cuboid, and length is about 180mm, and the width is about 38mm, and thickness is 16 to 20mm, can install at the narrow space in casement 20 position.
As shown in fig. 5 and 6, the automatic opening and closing device 40 includes a second housing 41, a second cover 42, a side-hung motor 43, a fourth gear set 44, a fifth gear set 45, an opening and closing clutch 46, a sixth gear set 47, a seventh gear set 48, and an opening and closing rotator 49.
The second casing 41 and the second cover plate 42 enclose to form a second cavity 401 for assembling each driving device, the flat-open motor 43 and each gear are installed in the second cavity 401, an output shaft of the flat-open motor 43 is connected with a turbine, the turbine is meshed with the fourth tooth group 44, the fourth tooth group 44 is meshed with the fifth tooth group 45, and the fifth tooth group 45 is meshed with the opening and closing clutch 46. The opening/closing clutch 46 is separated from the sixth tooth group 47 in the manual control state and is in contact with the sixth tooth group 47 in the electric control state. The sixth set of teeth 47 meshes with a seventh set of teeth 48, said seventh set of teeth 48 being connected to an opening and closing rotator 49, said opening and closing rotator 49 being connected to the rocker 11. So that the swing arm 11 is driven in both a power and a manual manner to open the window sash 20.
As shown in fig. 7 and 8, the handle motor 33 and the casement motor 43 are electrically connected to the handle motor driving interface 58 and the casement motor driving interface 59 of the two-way casement window motor controller 50, respectively. When the computer is remotely controlled, the motor is driven to rotate by the two-way window-pushing motor controller 50.
The two-way sliding window motor controller 50 comprises an MCU (microprogrammed control unit) central control unit 51, a WIFI (wireless fidelity) receiving module 52, a wireless receiving module 53, a panel key control circuit 54, a switching power supply module 55, a DC-DC (direct current-direct current) power supply conversion circuit 56, a motor driving module 57, a handle motor driving interface 58 and a flat-open motor driving interface 59. The switching power supply module 55 is connected to the DC-DC power conversion circuit 56, and outputs a direct current to power the entire two-way sliding window motor controller 50. The WIFI receiving module 52 is electrically connected to the MCU central control unit 51, and the WIFI receiving module 52 receives the mobile phone WIFI control signal and transmits the signal to the MCU central control unit 51. The wireless receiving module 53 is electrically connected to the MCU central control unit 51, and the wireless receiving module 53 receives the wireless infrared signal from the remote controller 60 and transmits the signal to the MCU central control unit 51. The panel key control circuit 54 is electrically connected to the MCU central control unit 51, and the panel key control circuit 54 transmits signals of the manual operation keys to the MCU central control unit 51. The electric property of the motor drive module 57 is connected with the MCU central control unit 51 to receive the control signal of the MCU central control unit 51, and the motor drive module 57 has two-way output, one way is connected with the handle motor drive interface 58, the other way is connected with the flat-open motor drive interface 59 to respectively control the handle motor 33 and the flat-open motor 43 to realize the opening and closing, the lock falling and the unlocking of the intelligent window.
And, the two-way sliding window motor controller 50 further comprises an LED indicating circuit 501, wherein the LED indicating circuit 501 is electrically connected to the MCU central control unit 51, and is configured to sense the code matching and code deletion learning states of the MCU.
As shown in fig. 9, the MCU 51 includes a control chip U4 of model STM8S0003F3 and its peripheral circuits, and the control chip U4 is connected to a writing socket NC for writing programs. The WIFI receiving module 52 includes a WT8266 control chip U8 and its peripheral circuits. The wireless receiving module 53 includes a control chip U2 with model number of RFM219 and its peripheral circuits, and the control chip U2 is connected to a program burning socket CON 6. The panel key control circuit 54 has three keys SW1, SW2, SW3, which are an up key, a down key, and a stop key on the control panel, respectively. As shown in fig. 10, the motor driving module 57 includes two a4950 motor control chips U3 and U4, which are respectively connected to the handle motor driving interface 58 and the opening motor driving interface 59.
As shown in fig. 8 and fig. 11, the remote controller 60 further includes a remote controller MCU circuit 61, and a remote controller indicator light circuit 62, a remote controller key circuit 63 and a wireless transmitter circuit 64 electrically connected to the remote controller MCU circuit 61, respectively, on the circuit board of the remote controller 60. The remote controller MCU circuit 61 comprises a main control chip U1 with the model of EM78P153SN and peripheral circuits thereof; the wireless transmission circuit 64 includes a model CMT2110/17A chip and its peripheral circuits.
The utility model discloses a double-circuit pushes away window motor controller 50 in exchanging the direct current and going out the class, and double-circuit direct current takes separation and reunion motor control system. The technical parameters are as follows:
the double-path window-pushing motor controller 50 adopts a superheterodyne remote control mode, and has strong anti-interference capability and long remote control distance. When the electric wrench works, the handle motor 33 is started firstly by pressing the up key, and the flat-open motor 43 is started after the handle motor 33 stops; the flat-open motor 43 is firstly closed by pressing the row key, and the handle motor 33 is closed after the flat-open motor 43 stops (note: the handle motor 33450mA and the flat-open motor 43500 mA).
The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any slight modifications, equivalent changes and modifications made by the technical spirit of the present invention to the above embodiments are all within the scope of the technical solution of the present invention.