CN215056981U - Built-in multilayer hollow glass shutter of autonomous power supply device - Google Patents

Abstract

A multilayer hollow glass shutter with a built-in autonomous power supply device comprises a window body, wherein the window body comprises an inner frame body, an outer frame body, a blind lifting and curtain sheet overturning actuating mechanism, inner glass, outer glass and middle glass; the motor is arranged at the left end of the upper transverse frame cavity, and the positioner is arranged at the right end of the upper transverse frame cavity; control mechanism and autonomic power supply unit, characteristics: control mechanism includes that controller and controller are inserted and are inlayed the stores pylon, the rear side hook that the controller was inserted and is inlayed the stores pylon is put on outer frame body joint strip, there is the stores pylon to insert and inlay the chamber in the middle part, the stores pylon is inserted and is inlayed the chamber and plant including glass and middle glass's upper portion, the controller is planted and is inserted and inlay the front side of stores pylon at the controller, autonomic power supply unit includes that solar photovoltaic cell panel bears frame and solar photovoltaic cell panel, solar photovoltaic cell panel bears the frame and glues with the upper portion of middle glass one side, solar photovoltaic cell panel establishes the one side that bears the frame at solar photovoltaic cell panel. The cleaning-free and anti-solarization water cup has the advantages of no cleaning, no attack from external force and long service life.

Description

Built-in multilayer hollow glass shutter of autonomous power supply device

Technical Field

The utility model belongs to the technical field of sunshade cavity glassware, concretely relates to built-in multilayer cavity glass shutter of autonomic power supply unit.

Background

The structure system of the hollow glass shutter mainly comprises a double-glass single cavity and a triple-glass double cavity, wherein the former is that a hollow cavity is formed between two pieces of glass, namely inner glass and outer glass, the shutter is arranged in the hollow cavity, and the latter is that the inner glass, the middle glass and the outer glass form two hollow cavities, specifically, the inner glass and the middle glass form an inner cavity (namely, an inner hollow cavity), the shutter is arranged in the inner cavity, and the middle glass and the outer glass form an outer cavity (namely, an outer hollow cavity). Examples of the former include CN2564720Y (hollow glass with built-in blind), CN2767624Y (blind in hollow glass), CN2767625Y (blind in hollow glass with improved structure), CN2756796Y (blind in hollow glass), CN2232968Y (integral door and window sash with horizontal blind in double glass), CN2297952Y (magnetically driven laminated retractable curtain), CN2326718Y (fully enclosed blind), CN100535378C (blind in hollow glass with improved structure), CN102444372A (hollow blind with built-in sunshade), CN105064896B (single-control double-layer hollow glass built-in blind), CN105041170B (non-magnet driven double-layer hollow glass built-in blind), CN105041172B (bead chain driven double-layer hollow glass built-in blind), CN109538096A (double-control hollow glass built-in blind with balanced blind cavity and external pressure), CN109538097A (blind anti-slipping device for hollow glass built-in blind), CN109441323A (single-handled hollow glass built-in blinds capable of preventing the blinds from slipping down) and CN109488189A (single-handled hollow glass built-in blinds capable of preventing the blinds from sucking inside), foreign patents such as US20021897681A, 1US2004211528A, US2015159431a1, GB671685A, EP2369121a2, EP1542054a1, W003071082A, and the like; typical examples of the latter are CN105041168B (energy saving type multi-layer hollow glass blind with simplified structure), CN108643809A (dual operation energy saving type multi-layer hollow glass blind), and CN108643808A (single operation energy saving type multi-layer hollow glass built-in blind), etc.

In recent years, in the hollow glass built-in blind having an autonomous power supply function, solar energy is used as an energy source, and for this purpose, reference is made to "autonomously power-supplying and driving hollow glass built-in blind" recommended by CN212454192U and "autonomously power-supplying and driving hollow glass built-in blind having an automatic cord discharging function" provided by CN111980564A, and the like. The hollow glass built-in shutter with the self-powered function is not limited to the exemplified structure with double glass and single cavity.

As is known in the art, the use of solar photovoltaic panels in hollow glass built-in blinds is increasingly recognized and accepted due to their relatively long service life, which normally can be as long as 20 to 30 years or even longer. However, since most of the existing hollow glass built-in shutters have the above-mentioned double-glass single-cavity structure, they can only be disposed on the side of the outer glass facing outward, i.e. toward the outside, because if they are disposed in the cavity between two inner and outer glasses, they will inevitably interfere with the relevant components for lifting and lowering the blind and turning the blind sheet, such as the turning drum (also called turning roller), turning shaft, etc. The solar photovoltaic cell panel is arranged on one side, facing the outside, of the outer glass of the double-glass single-cavity structure, and the following recognized adverse factors are inevitably generated in the actual use process: firstly, once installed, the photoelectric conversion effect is influenced because the photoelectric conversion device is difficult to clean and maintain even cannot clean and maintain at all and only can rely on stubborn accumulation of dust and dirt; secondly, worrying about the falling and accidents caused by factors such as typhoon and rainstorm; thirdly, due to lack of shielding, once suffering from serious attack of sand dust and/or hail, the monocrystalline silicon piece or the polycrystalline silicon piece of the structural system of the solar photovoltaic cell panel can be damaged. In view of the foregoing situation, the applicant believes that it is objectively difficult to eliminate the foregoing disadvantages in the case of a double-glass single cavity, however, in view of the comprehensive price-inquiry ratio, designing the double-glass single cavity structure as a three-glass double-cavity structure has advantages that the double-glass single cavity structure cannot be compared with that of the double-glass single cavity structure, which is achieved by providing electric energy by solar energy to realize autonomous driving, in addition to those mentioned in CN10504168B and CN108643809A, so that the advantages of labor saving in operation are provided, the cost is significantly reduced without using magnetically attracted inner and outer manipulators, the daylighting area is increased without reserving a channel for the window for the inner manipulator to slide up and down, the solar photovoltaic panel can be in a protection state to meet the requirement of a reasonable period, such as 20 to 30 years of service life, and the like. Based on the advantages of the three-glass double-cavity structure not limited to the above list, the double-glass single-cavity structure is designed to be a three-glass double-cavity structure which is suitable for self-powered power supply and can well protect the self-powered power supply device, so that the effect of one arrow with multiple carvers can be obtained. However, how to properly arrange the solar photovoltaic panel in the hollow cavity is not suggested in the published foreign and foreign patents and non-patent documents. Particularly, under the influence of the traditional design mode or design concept, it is widely believed that the solar photovoltaic cell panel can only be exposed to the outside, and cannot be shielded. In view of the foregoing, the applicant has made active and advantageous investigations and designs, and it is against this background that the technical solutions described below are produced.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a help being in good shielding state and can embodying and exempting from the cleanness, avoid insolate and external environment corruption, exempting from to fall, avoid external force attack such as sand wind hail etc. under the prerequisite that makes the photoelectric conversion effect of solar photovoltaic cell panel performance ideal to satisfy the built-in multilayer cavity glass shutter of autonomous power supply unit of the life requirement of expectation.

The utility model aims to achieve the task, the multilayer hollow glass shutter with the built-in self-powered device comprises a window body, the window body comprises an inner frame body, an outer frame body, a blind lifting and curtain piece overturning actuating mechanism, inner glass, middle glass and outer glass, the inner frame body is positioned between the inner glass and one side of the middle glass facing each other, the peripheral edge part of one side of the inner glass and the middle glass facing each other is fixedly bonded with the inner side and the outer side of the inner frame body by the inner frame body sealing rubber strip arranged around one side of the inner frame body facing away from the inner frame body cavity, the outer frame body is positioned between the middle glass and one side of the outer glass facing each other, the peripheral edge part of one side of the middle glass and the rear glass facing each other is fixedly bonded with the inner side and the outer side of the outer frame body by the outer frame body sealing rubber strip arranged around one side of the outer frame body facing away from the outer frame body cavity, the shutter curtain is arranged in the inner frame body cavity, the upper part of the shutter curtain is connected with the shutter curtain lifting and curtain sheet overturning actuating mechanism, and the shutter curtain lifting and curtain sheet overturning actuating mechanism is arranged in the upper cross frame strip cavity of the upper cross frame strip of the inner frame body at the upper part of the inner frame body cavity of the inner frame body; the motor is arranged at the left end of the upper transverse frame cavity and is in transmission connection with the blind lifting and curtain sheet overturning actuating mechanism, and the positioner is arranged at the right end of the upper transverse frame cavity and is electrically connected with the motor; a control mechanism and an autonomous power supply device, characterized in that the control mechanism comprises a controller and a controller inserting rack, the rear side of the controller inserting rack is hooked on the sealing rubber strip of the outer frame body, a rack inserting cavity is formed in the length direction of the middle part, the hanger inserting cavity is inserted on the upper parts of the inner glass and the middle glass, the controller is inserted on the front side of the controller inserting hanger and is electrically connected with the motor and the positioner, the autonomous power supply device comprises a solar photovoltaic cell panel bearing frame and a solar photovoltaic cell panel, the solar photovoltaic cell panel bearing frame is fixedly connected with the upper part of one side of the middle glass facing the outer glass, the solar photovoltaic cell panel is arranged on one side of the solar photovoltaic cell panel bearing frame facing the back glass along the length direction of the solar photovoltaic cell panel bearing frame, a battery panel wire of the solar photovoltaic battery panel is electrically connected with the controller after penetrating through the outer frame body.

In a specific embodiment of the present invention, an inner glass bead is provided at a peripheral edge portion of the inner glass facing the inner frame, the inner glass bead is bonded to the inner side of the inner frame at a position corresponding to the inner side of the front of the inner frame sealing tape, an intermediate glass inner bead is provided at a peripheral edge portion of the intermediate glass facing the inner frame, the intermediate glass inner bead is bonded to the outer side of the inner frame at a position corresponding to the inner side of the rear of the inner frame sealing tape, an intermediate glass outer bead is provided at a peripheral edge portion of the intermediate glass facing the outer frame, the intermediate glass outer bead is bonded to the inner side of the outer frame at a position corresponding to the inner side of the front of the outer frame sealing tape, an outer glass bead is provided at a peripheral edge portion of the outer glass facing the outer frame, the outer glass weather strip is bonded to the outer side of the outer frame at a position corresponding to the rear inner side of the outer frame sealing rubber strip.

In another specific embodiment of the present invention, the inner frame sealing rubber strip and the outer frame sealing rubber strip are polysulfide rubber strips.

In another specific embodiment of the present invention, a hook strip is folded and unfolded at the rear side of the controller inserting rack, and the hook strip is hooked on the upper portion of the outer frame sealing rubber strip.

In another specific embodiment of the present invention, the controller is inserted between the controller-defining bars formed at the upper and lower portions of the front side of the controller-inserting hanger.

In yet another specific embodiment of the present invention, the outer frame strip is provided with a panel wire hole corresponding to the controller, and the panel wire of the solar photovoltaic panel is electrically connected to the controller after passing through the panel wire hole.

In a more specific embodiment of the present invention, the controller is provided with a controller remote control operator.

In yet another specific embodiment of the present invention, the controller remote operator is a hand-held portable operator or a fixed operator attached to the inner glass.

In a still more specific embodiment of the present invention, the inner glass sealing strip, the middle glass inner sealing strip, the middle glass outer sealing strip and the outer glass sealing strip are butyl rubber strips.

In yet another specific embodiment of the present invention, the motor is a forward/reverse motor.

The technical scheme provided by the utility model the technical effect lie in: because the solar photovoltaic cell panel bearing frame of the structural system of the autonomous power supply device is cemented with the upper part of one side of the middle glass facing the outer glass, and the solar photovoltaic cell panel is arranged on one side of the solar photovoltaic cell panel bearing frame facing the outer glass, the solar photovoltaic cell panel can be shielded in a cavity between the middle glass and the outer glass, so that the solar photovoltaic cell panel is free from cleaning, solarization and corrosion of the external environment, falling and attack by external force such as wind, sand, hail and the like, and can meet the expected service life requirement.

Drawings

Fig. 1 is an assembly structure diagram of the present invention.

Fig. 2 is a schematic view illustrating an application of the present invention.

Detailed Description

In order to make the technical essence and advantages of the present invention more clear, the applicant below describes in detail the embodiments, but the description of the embodiments is not a limitation of the present invention, and any equivalent changes made according to the inventive concept, which are only formal and not essential, should be considered as the technical scope of the present invention.

In the following description, all the concepts related to up, down, left, right, inner, middle and outer are based on the position state of fig. 1 and 2, and thus, it cannot be understood as a specific limitation to the technical solution provided by the present invention.

Referring to fig. 1, there is shown a window 1, which includes an inner frame 11, an outer frame 12, a blind 13, a blind lifting and blind turning actuator 14, an inner glass 15a, an intermediate glass 15b and an outer glass 15c, wherein the inner frame 11 is located between the inner glass 15a and the intermediate glass 15b on the opposite sides, the inner frame sealing strip 112 disposed around the inner frame 11 on the opposite side to the inner frame cavity 111 bonds and fixes the peripheral edge portions of the inner glass 15a and the intermediate glass 15b on the opposite sides to the inner and outer side surfaces of the inner frame 11, that is, the front sides of the inner glass 15a and the intermediate glass 15b are respectively fixed to the front and rear sides of the inner frame 11, the outer frame 12 is located between the intermediate glass 15b and the outer glass 15c on the opposite side, and the peripheral edge portions of the intermediate glass 15b and the rear glass 15c are fixed to the peripheral edge portions of the outer frame 12 on the opposite sides to the outer frame cavity 121 by the outer frame sealing strip 122 disposed around the outer frame 12 on the opposite side to the outer frame cavity 121 The inner and outer sides are bonded, that is, the rear side of the middle glass 15b and the front side of the outer glass 15c are respectively fixed with the front and rear sides of the outer frame 12, the blind 13 is arranged in the inner frame cavity 111 and the upper part of the blind 13 is connected with the blind lifting and turning actuator 14, and the blind lifting and turning actuator 14 is arranged in the upper beam cavity 1131 of the inner frame upper beam 113 at the upper part of the inner frame cavity 111 of the inner frame 11; a motor 2 and a positioner 3 are shown, the motor 2 is arranged at the left end of the upper transverse frame cavity 1131 and is in transmission connection with the shutter lifting and turning actuating mechanism 14, and the positioner 3 is arranged at the right end of the upper transverse frame cavity 1131 and is electrically connected with the motor 2; a control mechanism 4 and an autonomous power supply 5 are shown.

As the technical scheme provided by the utility model: the control mechanism 4 comprises a controller 41 and a controller inserting and embedding rack 42, the rear side of the controller inserting and embedding rack 42 is hooked on the outer frame body sealing rubber strip 122, a rack inserting and embedding cavity 421 is formed in the length direction of the middle part, the rack inserting and embedding cavity 421 is inserted and embedded on the upper parts of the inner glass 15a and the middle glass 15b, the controller 41 is inserted and embedded on the front side of the controller inserting and embedding rack 42 and is electrically connected with the motor 2 and the positioner 3, the autonomous power supply device 5 comprises a solar photovoltaic cell panel bearing frame 51 and a solar photovoltaic cell panel 52, the solar photovoltaic cell panel bearing frame 51 is cemented with the upper part of one side, facing the outer glass 15c, of the middle glass 15b, the solar photovoltaic cell panel 52 is arranged on one side, facing the rear glass 15c, of the solar photovoltaic cell panel bearing frame 51 along the length direction of the solar photovoltaic cell panel bearing frame 51, the panel lead of the solar photovoltaic panel 52 is electrically connected to the controller 41 after passing through the outer frame 12.

Since the above-mentioned venetian blind 13 and venetian blind lifting and blind turning actuator 14 belong to the prior art, for example, refer to CN112081517A (remote control type magnetically driven hollow glass built-in venetian blind), etc., and since the above-mentioned motor 2 and positioner 3 belong to the prior art, for example, refer to CN111520058A (a hollow blind using solar self-powered wireless control and manual control), CN112081518A (rechargeable magnetically driven hollow glass built-in venetian blind), etc., in addition to the above-mentioned CN112081517A, the applicant does not describe any further.

As shown in fig. 1, an inner glass bead 15d is provided at a peripheral edge portion of the inner glass 15a facing the inner frame 11, the inner glass bead 15d is bonded to an inner side (front side in the illustrated state) of the inner frame 11 at a position corresponding to a front inner side of the inner frame seal 112, an intermediate glass inner bead 15e is provided at a peripheral edge portion of the intermediate glass 15b facing the inner frame 11, the intermediate glass inner bead 15e is bonded to an outer side (rear side in the illustrated state) of the inner frame 11 at a position corresponding to a rear inner side of the inner frame seal 112, an intermediate glass outer bead 15f is provided at a peripheral edge portion of the intermediate glass 15b facing the outer frame 12, the intermediate glass outer bead 15f is bonded to an inner side of the outer frame 12 at a position corresponding to a front inner side (front side in the illustrated state) of the outer frame seal 122, an outer glass bead 15g is provided at a peripheral edge portion of the outer glass 15c facing the outer frame 12, and the outer glass bead 15g is bonded to the outer side of the outer frame 12 at a position corresponding to the rear inner side (rear side in the illustrated state) of the outer frame sealing bead 122.

In the present embodiment, the inner frame sealant 112 and the outer frame sealant 122 are polysulfide rubber strips.

Continuing to refer to fig. 1, a hook strip 422 is folded and unfolded at the rear side of the controller inserting and embedding hanger 42, and the hook strip 422 is hooked on the upper part of the outer frame body sealing rubber strip 122; a controller restricting piece 423 is formed on each of the upper and lower portions of the front side of the controller insertion hanger 42, and the controller 41 is inserted between the upper and lower controller restricting pieces 423.

A panel wire-avoiding hole 123 is formed on the outer frame strip 12 and corresponding to the controller 41, and the panel wire of the solar photovoltaic panel 52 is electrically connected to the controller 41 after passing through the panel wire-avoiding hole 123.

As shown in fig. 1, the controller 41 is provided with a controller remote operator 411, and the controller remote operator 411 is a hand-held portable operator or a fixed operator attached to the inner glass 15b, and the former is selected in this embodiment.

Preferably, the inner glass sealing strip 15d, the middle glass inner sealing strip 15e, the middle glass outer sealing strip 15f and the outer glass sealing strip 15g are butyl rubber strips; the motor 2 is a forward and reverse rotating motor; the solar photovoltaic cell panel 52 is made of a monocrystalline silicon wafer or a polycrystalline silicon wafer.

Referring to fig. 2 in conjunction with fig. 1, fig. 2 shows the structure of fig. 1 after the assembly is completed, and the controller inserting and embedding rack 42 is inserted and embedded in the upper right corner of the inner glass 15a and the middle glass 15b in a straddling manner through the rack inserting and embedding cavity 421 thereof, and since the whole autonomous power supply device 5 shown in fig. 1 is located between the middle glass 15b and the outer glass 15c, the technical effects of the applicant described in the above technical effect column can be fully realized.

Claims (10)

1. A multilayer hollow glass shutter with a built-in self-powered device comprises a window body (1), wherein the window body (1) comprises an inner frame body (11), an outer frame body (12), a blind (13), a blind lifting and blind overturning actuating mechanism (14), inner glass (15a), intermediate glass (15b) and outer glass (15c), the inner frame body (11) is positioned between one sides of the inner glass (15a) and the intermediate glass (15b) which face towards each other, peripheral edge parts of one sides of the inner glass (15a) and the intermediate glass (15b) which face away from an inner frame body cavity (111) are bonded and fixed with the inner side surface and the outer side surface of the inner frame body (11) through inner frame body sealing rubber strips (112) arranged around the periphery of one side of the inner frame body (11) which faces away from the inner frame body cavity (111), the outer frame body (12) is positioned between one sides of the intermediate glass (15b) and the outer glass (15c) which face towards each other, and outer frame body sealing rubber strips (12) arranged around the periphery of one side of the outer frame body cavity (121) which faces away from the outer frame body cavity (12) which faces away from the outer frame body cavity (15) which faces away from each other are arranged 122) The peripheral edge parts of the opposite sides of the middle glass (15b) and the rear glass (15c) are bonded and fixed with the inner side surface and the outer side surface of the outer frame body (12), the blind (13) is arranged in the inner frame body cavity (111), the upper part of the blind (13) is connected with a blind lifting and turning actuating mechanism (14), and the blind lifting and turning actuating mechanism (14) is arranged in an upper transverse frame strip cavity (1131) of an inner frame body upper transverse frame strip (113) at the upper part of the inner frame body cavity (111) of the inner frame body (11); the motor (2) is arranged at the left end of the upper transverse frame bar cavity (1131) and is in transmission connection with the shutter lifting and curtain sheet overturning actuating mechanism (14), and the positioner (3) is arranged at the right end of the upper transverse frame bar cavity (1131) and is electrically connected with the motor (2); a control mechanism (4) and an autonomous power supply device (5), characterized in that the control mechanism (4) comprises a controller (41) and a controller inserting and embedding hanger (42), the rear side of the controller inserting and embedding hanger (42) is hooked on the outer frame body sealing rubber strip (122), a hanger inserting and embedding cavity (421) is formed in the length direction of the middle part, the hanger inserting and embedding cavity (421) is inserted on the upper parts of the inner glass (15a) and the middle glass (15b), the controller (41) is inserted on the front side of the controller inserting and embedding hanger (42) and is electrically connected with the motor (2) and the positioner (3), the autonomous power supply device (5) comprises a solar photovoltaic cell panel bearing frame (51) and a solar photovoltaic cell panel (52), the solar photovoltaic cell panel bearing frame (51) and the middle glass (15b) are adhered to the upper part of one side of the outer glass (15c), the solar photovoltaic cell panel (52) is arranged on one side, facing the rear glass (15c), of the solar photovoltaic cell panel bearing frame (51) along the length direction of the solar photovoltaic cell panel bearing frame (51), and a cell panel lead of the solar photovoltaic cell panel (52) penetrates through the outer frame body (12) and then is electrically connected with the controller (41).

2. The multiple-glazing louver with built-in autonomous power supply device according to claim 1, characterized in that an inner-glass weather strip (15d) is provided at a peripheral edge portion of the inner glass (15a) on the side facing the inner frame (11), the inner-glass weather strip (15d) is bonded to the inner side of the inner frame (11) at a position corresponding to the front inner side of the inner-frame sealing strip (112), an intermediate-glass inner weather strip (15e) is provided at a peripheral edge portion of the intermediate glass (15b) on the side facing the inner frame (11), the intermediate-glass inner weather strip (15e) is bonded to the outer side of the inner frame (11) at a position corresponding to the rear inner side of the inner-frame sealing strip (112), an intermediate-glass outer weather strip (15f) is provided at a peripheral edge portion of the intermediate glass (15b) on the side facing the outer frame (12), the middle glass outer seal strip (15f) is adhered to the inner side of the outer frame body (12) at a position corresponding to the front inner side of the outer frame body sealing rubber strip (122), an outer glass seal strip (15g) is arranged at the peripheral edge part of one side, facing the outer frame body (12), of the outer glass (15c), and the outer glass seal strip (15g) is adhered to the outer side of the outer frame body (12) at a position corresponding to the rear inner side of the outer frame body sealing rubber strip (122).

3. The self-powered device built-in multiple-glazed window blind according to claim 1 or 2, wherein the inner frame sealant strip (112) and the outer frame sealant strip (122) are polysulfide rubber strips.

4. The built-in multiple-glazed window blind of claim 1, wherein a hooking strip (422) is folded at the rear side of the controller-inserting hanger (42), and the hooking strip (422) is hooked on the upper portion of the outer frame sealing rubber strip (122).

5. The multiple-glazed window blind with built-in autonomous power supply apparatus as claimed in claim 1, wherein a controller defining bar (423) is formed at each of upper and lower portions of a front side of the controller insert-fitting hanger (42), and the controller (41) is inserted between the controller defining bars (423) of the upper and lower portions.

6. The built-in multiple-layer hollow glass shutter of the autonomous power supply device according to claim 1, characterized in that a panel wire-off hole (123) is opened on the outer frame strip (12) and corresponding to the controller (41), and the panel wire of the solar photovoltaic panel (52) is electrically connected to the controller (41) after passing through the panel wire-off hole (123).

7. The multiple-glazed window blind with built-in autonomous power supply device as claimed in claim 1, 5 or 6, characterized in that the controller (41) is equipped with a controller remote operator (411).

8. The insulated multiple-glazed window blind with built-in autonomous power supply device as claimed in claim 7, wherein said controller remote operator (411) is a hand-held portable operator or a fixed operator attached to said inner glass (15 b).

9. The self-powered device built-in multilayer hollow glass blind according to claim 2, characterized in that the inner glass sealing strip (15d), the middle glass inner sealing strip (15e), the middle glass outer sealing strip (15f) and the outer glass sealing strip (15g) are butyl rubber strips.

10. The built-in multilayer hollow glass shutter of the autonomous power supply device according to claim 1, characterized in that the motor (2) is a counter-rotating motor.

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