CN209748385U - Inner winding mechanism type power generation device - Google Patents

Abstract

The utility model discloses an inner winding mechanism formula power generation facility has solved power generation facility's among the prior art problem that the fixed form of inner winding is single, the structure is complicated. The utility model discloses an interconnect's outside flabellum subassembly and inside electricity generation subassembly, inside electricity generation subassembly is equipped with the axle subassembly including supporting the casing in the supporting the casing, rotates on the axle subassembly and is equipped with upper end cover and lower end cover, upper end cover and lower end cover fixed connection, all are equipped with the magnet in the upper end cover and the lower end cover, are equipped with at least a set of winding on the axle subassembly, the winding is located between upper end cover and the lower end cover and corresponding with the magnet, still is equipped with the collecting ring on the axle subassembly, be equipped with the carbon brush assembly in the supporting the casing, the carbon brush assembly is corresponding with the collecting ring. The utility model discloses simple structure can realize vertical installation, vertical installation and horizontal installation downwards to be applicable to vertical face operating mode and horizontal plane operating mode, improve the device utilization ratio.

Description

Inner winding mechanism type power generation device

Technical Field

The utility model relates to a power generation facility technical field especially indicates an interior winding mechanism formula power generation facility.

Background

At present, with the increasing call for energy conservation and emission reduction, clean energy is vigorously developed in all countries in the world, the clean energy refers to energy with renewable raw materials, such as renewable energy sources of hydroelectric power generation, wind power generation, solar energy and the like, the current situation of increasingly severe energy shortage in China can be well solved, and the winding fixing form in the current wind power generation equipment is single, so that the wind power generation equipment cannot be well applicable to different installation environments, and the use of a power generation device is limited.

SUMMERY OF THE UTILITY MODEL

To not enough among the above-mentioned background art, the utility model provides an interior winding mechanism formula power generation facility has solved power generation facility's among the prior art problem that the interior winding fixed form is single, the structure is complicated.

The technical scheme of the utility model is realized like this: the utility model provides an internal winding mechanism formula power generation facility, includes interconnect's outside flabellum subassembly and inside electricity generation subassembly, inside electricity generation subassembly includes the support housing, is equipped with the axle subassembly in the support housing, rotates on the axle subassembly and is equipped with upper end cover and lower end cover, upper end cover and lower end cover fixed connection, all is equipped with the magnet in the upper end cover and in the lower end cover, is equipped with at least a set of winding on the axle subassembly, and the winding is located between upper end cover and the lower end cover and corresponding with the magnet, still is equipped with the collecting ring on the axle subassembly, is equipped with the carbon brush assembly in the support housing, and the carbon brush assembly is corresponding with.

The upper end cover and the lower end cover are positioned in the supporting shell, a first bearing is arranged between the upper end cover and the supporting shell, a second bearing is arranged between the upper end cover and the crankshaft assembly, and a third bearing is arranged between the lower end cover and the crankshaft assembly.

The crankshaft assembly is a one-way shaft, one end of the one-way shaft penetrates through the upper end cover and extends out of the supporting shell, the other end of the one-way shaft is connected with the supporting shell through a fourth bearing, and a connecting seat is arranged at the lower part of the supporting shell.

The crankshaft assembly is a one-way shaft, and one end of the one-way shaft penetrates through the lower end cover and extends out of the support shell; the other end is connected with the supporting shell through a fourth bearing, the lower part of the supporting shell is provided with a connecting seat, and one side of the supporting shell is provided with a fixed seat.

The crankshaft assembly is a one-way shaft, the one-way shaft penetrates through the lower end cover downwards and extends out of the support shell, and the upper part of the upper end cover extends out of the support shell upwards; the lower part of the supporting shell is provided with a connecting seat, and the middle part of the supporting shell is provided with a second connecting seat.

The upper end cover and the lower end cover are positioned above the supporting shell, the lower end cover is fixedly connected with the supporting shell through the outer cover body, a first bearing is arranged between the upper end cover and the crankshaft assembly, a second bearing is arranged between the lower end cover and the crankshaft assembly, and a third bearing and a fourth bearing are arranged between the crankshaft assembly and the supporting shell.

The crankshaft assembly is a one-way shaft, and the upper end cover and the lower end cover are arranged at the upper end of the one-way shaft; the lower end of the one-way shaft is positioned in the support shell, and the lower part of the support shell is provided with a connecting seat.

The crankshaft assembly is a bidirectional shaft, the bidirectional shaft comprises an upper cylinder shaft and a lower cylinder shaft, and the upper cylinder shaft and the lower cylinder shaft are arranged on the same central axis; the upper drum shaft is fixedly connected with the supporting shell, the upper end cover and the lower end cover are installed on the upper drum shaft, the lower drum shaft is connected with the supporting shell through a third bearing and a fourth bearing, and the lower portion of the supporting shell is provided with a connecting seat.

The utility model discloses simple structure can realize vertical installation, vertical installation and horizontal installation downwards to be applicable to vertical face operating mode and horizontal plane operating mode, improve the device utilization ratio. Furthermore, the utility model discloses a winding and the fixed connection mode of spindle subassembly take place relative rotation through winding and magnet and realize the electricity generation, and whole interior winding mechanism compact structure is convenient for install, and the power generation rate is high, has higher spreading value.

Drawings

In order to illustrate the embodiments of the present invention more clearly, the drawings that are needed in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and that other drawings can be obtained by those skilled in the art without inventive work.

Fig. 1 is a schematic structural view of the present invention in embodiment 1.

Fig. 2 is a schematic structural view of the present invention in embodiment 2.

Fig. 3 is a schematic structural view of the present invention in embodiment 3.

Fig. 4 is a schematic structural view of the present invention in embodiment 4.

Fig. 5 is a schematic structural view of the present invention in embodiment 5.

Fig. 6 is a schematic structural view of the present invention in embodiment 6.

Fig. 7 is a schematic structural view of the present invention in embodiment 7.

Fig. 8 is a schematic structural view of the present invention in embodiment 8.

Fig. 9 is a schematic structural view of the present invention in embodiment 9.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without any creative effort belong to the protection scope of the present invention.

As shown in fig. 1, in embodiment 1, an internal winding mechanism type power generation device includes an external fan blade assembly and an internal power generation assembly that are connected to each other, where the external fan blade assembly drives the internal power generation assembly to rotate, and power generation is implemented by using an electromagnetic induction principle. The internal power generation assembly comprises a supporting shell 1, a crankshaft assembly 2 is arranged in the supporting shell 1, an upper end cover 3 and a lower end cover 5 are arranged on the crankshaft assembly 2 in a rotating mode, the upper end cover 3 and the lower end cover 5 are fixedly connected through bolts, magnets 6 are arranged in the upper end cover 3 and the lower end cover 5 respectively, the magnets are fixed on the upper end cover and the lower end cover respectively, at least one group of windings 7 are fixedly arranged on the crankshaft assembly 2, the windings 7 are located between the upper end cover 3 and the lower end cover 5 and correspond to the magnets 6, the windings rotate synchronously along with the shaft assembly, the windings rotate relative to the magnets, and the windings cut magnetic induction lines to achieve power generation. The crankshaft component 2 is also provided with a collecting ring 8, the supporting shell 1 is provided with a carbon brush assembly 9, and the carbon brush assembly 9 corresponds to the collecting ring 8. The power generation component leads out the generated electricity through a conducting wire, the collecting ring 8 and the carbon brush assembly 9. The collector ring 8 is a circular tube type, a barrel type or a disc type and is selected according to requirements.

As shown in fig. 2, in embodiment 2, an internal winding mechanism type power generating device, preferably, a set of windings 7 is fixedly arranged on a crankshaft assembly 2, and magnets 6 are respectively arranged on the lower part of an upper end cover and the upper part of a lower end cover, and the windings are positioned between the magnets. The shaft assembly is provided with blades, the blades drive the winding to rotate through the shaft assembly, the winding and the magnet rotate relatively, and the winding cuts the magnetic induction line to generate electricity. The upper end cover 3 and the lower end cover 5 are positioned in the supporting shell 1, a first bearing 10 is arranged between the upper end cover 3 and the supporting shell 1, a second bearing 11 is arranged between the upper end cover 3 and the crankshaft component 2, and a third bearing 12 is arranged between the lower end cover 5 and the crankshaft component 2. The crankshaft assembly 2 is a one-way shaft, and a hollow part can be arranged in the one-way shaft and used for passing through an electric wire. One end of the one-way shaft penetrates through the upper end cover 3 and extends out of the support shell 1, the other end of the one-way shaft is connected with the support shell 1 through a fourth bearing 13 and is located inside the support shell, and a connecting seat 14a is arranged at the lower part of the support shell 1. When the fan blade supporting device is used, the fan blade supporting device is vertically arranged and used under the working condition in a vertical plane, and the fan blade is located on the upper portion of the supporting shell, so that the structure is compact, and the installation is convenient.

The other structure is the same as embodiment 1.

As shown in fig. 3, in embodiment 3, two sets of windings 7 are fixedly disposed on a crankshaft assembly 2, the two sets of windings are fixedly disposed on a unidirectional shaft in parallel, the two sets of windings are both disposed in an upper end cover 3 and a lower end cover 5, an intermediate bracket is disposed between the upper end cover 3 and the lower end cover 5, and magnets are disposed on upper and lower portions of the intermediate bracket and respectively matched with the windings to form two sets of power generation base assemblies.

The other structure is the same as embodiment 2.

As shown in fig. 4, in embodiment 4, three groups of windings 7 are fixedly disposed on a crankshaft assembly 2, the three groups of windings are fixedly disposed on a unidirectional shaft in parallel, the three groups of windings are all disposed in an upper end cover 3 and a lower end cover 5, two middle brackets are disposed between the upper end cover 3 and the lower end cover 5, and magnets are disposed on upper and lower portions of the middle brackets and respectively matched with the windings to form three groups of power generation base assemblies.

The other structure is the same as in example 3.

As shown in fig. 5, in embodiment 5, the shaft assembly 2 is a unidirectional shaft, and the unidirectional shaft may be hollow for passing an electric wire therethrough. One end of the one-way shaft passes through the lower end cover 5 and extends out of the support shell 1; the other end is connected with the support housing 1 through a fourth bearing 13 and is located in the support housing, and the lower portion of the support housing 1 is provided with a connecting seat 14b for axial connection. One side of supporting shell 1 is equipped with fixing base 15b, during the use, and is fixed through the fixing base, and the one-way axle level setting this moment for the operating mode uses in the horizontal plane, compact structure, simple to operate.

The other structure is the same as embodiment 2.

As shown in fig. 6, in embodiment 6, an internal winding mechanism type power generating apparatus, a set of windings 7 is fixedly provided on a crankshaft assembly 2, and magnets 6 are respectively installed on a lower portion of an upper end cover and an upper portion of a lower end cover, the windings being located between the magnets. The crankshaft assembly 2 is a one-way shaft, the one-way shaft penetrates through the lower end cover 5 downwards and extends out of the support shell 1, and the upper part of the upper end cover 3 extends out of the support shell 1 upwards; the lower portion of the support housing 1 is provided with a connecting seat 14c, and the middle portion of the support housing 1 is provided with a second connecting seat 16 c. When the fan blade supporting device is used, the fan blade supporting device is vertically arranged and used under the working condition in a vertical plane, and the fan blade is located on the lower portion of the supporting shell and is compact in structure and convenient to install.

The other structure is the same as embodiment 1.

As shown in fig. 7, in embodiment 7, an internal winding mechanism type power generation device, the upper end cover 3 and the lower end cover 5 are located above the support housing 1, the lower end cover 5 is fixedly connected to the support housing 1 through the outer cover 30, and the upper end cover 3 and the lower end cover 5 are installed in an "outer leakage manner" for installation in a large space. A first bearing 10a is arranged between the upper end cover 3 and the crankshaft assembly 2, a second bearing 11a is arranged between the lower end cover 5 and the crankshaft assembly 2, and a third bearing 12a and a fourth bearing 13a are arranged between the crankshaft assembly 2 and the support shell 1.

Preferably, the crankshaft assembly 2 is fixedly provided with two groups of windings 7, the two groups of windings are fixedly arranged on the one-way shaft in parallel, the two groups of windings are both positioned in the upper end cover 3 and the lower end cover 5, an intermediate bracket is arranged between the upper end cover 3 and the lower end cover 5, the upper part and the lower part of the intermediate bracket are both provided with magnets, and the magnets are respectively matched with the windings to form two groups of power generation basic assemblies. The crankshaft assembly 2 is a one-way shaft, and the upper end cover 3 and the lower end cover 5 are arranged at the upper end of the one-way shaft; the lower end of the one-way shaft is positioned in the support shell 1, and the lower part of the support shell 1 is provided with a connecting seat 14 d. During the use, vertical setting is fixed through the connecting seat.

The other structure is the same as embodiment 1.

As shown in fig. 8, in embodiment 8, an internal winding mechanism type power generation device, the crankshaft assembly 2 is a bidirectional shaft, the bidirectional shaft includes an upper bobbin 2-1 and a lower bobbin 2-2, the upper bobbin 2-1 and the lower bobbin 2-2 are arranged on the same central axis, the upper bobbin 2-1 is fixedly provided with a set of windings 7, magnets 6 are respectively mounted on the lower portion of an upper end cover and the upper portion of a lower end cover, and the windings are located between the magnets. The upper cylinder shaft 2-1 is fixedly connected with the supporting shell 1, the upper end cover 3 and the lower end cover 5 are installed on the upper cylinder shaft 2-1, the lower cylinder shaft 2-2 is connected with the supporting shell 1 through a third bearing 12a and a fourth bearing 13a, and the lower part of the supporting shell 1 is provided with a connecting seat 14 e. When the magnetic induction cutting machine is used, the upper cylinder shaft 2-1 rotates to drive the winding and the magnet to rotate relatively, and cutting of magnetic induction lines is generated. The lower cylinder shaft is positioned in the supporting shell, so that the resistance of the upper cylinder shaft is reduced, and the power generation efficiency is improved.

The other structure is the same as in example 7.

As shown in fig. 9, in embodiment 9, an internal winding mechanism type power generator, a set of windings 7 is fixedly arranged on a crankshaft assembly 2, magnets 6 are respectively arranged on the lower part of an upper end cover and the upper part of a lower end cover, and the windings are positioned between the magnets. The crankshaft component 2 is a one-way shaft, collecting rings 8 are further arranged on the outer circumferences of the upper end cover and the lower end cover, a connecting seat 14f is arranged at the lower portion of the supporting shell 1, a carbon brush assembly 9 is arranged on the supporting shell, and the carbon brush assembly 9 corresponds to the collecting rings 8. The generated electricity is led out through the collector ring 8 and the carbon brush assembly 9.

The other structure is the same as embodiment 1.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides an interior winding mechanism formula power generation facility, includes interconnect's outside flabellum subassembly and inside electricity generation subassembly which characterized in that: the internal power generation assembly comprises a supporting shell (1), a crankshaft assembly (2) is arranged in the supporting shell (1), an upper end cover (3) and a lower end cover (5) are arranged on the crankshaft assembly (2) in a rotating mode, the upper end cover (3) is fixedly connected with the lower end cover (5), magnets (6) are arranged in the upper end cover (3) and the lower end cover (5), at least one group of windings (7) are arranged on the crankshaft assembly (2), the windings (7) are located between the upper end cover (3) and the lower end cover (5) and correspond to the magnets (6), collector rings (8) are further arranged on the crankshaft assembly (2), carbon brush assemblies (9) are arranged in the supporting shell (1), and the carbon brush assemblies (9) correspond to the collector rings (8).

2. The internal winding mechanism type power generation device according to claim 1, wherein: the bearing is characterized in that the upper end cover (3) and the lower end cover (5) are located in the supporting shell (1), a first bearing (10) is arranged between the upper end cover (3) and the supporting shell (1), a second bearing (11) is arranged between the upper end cover (3) and the crankshaft assembly (2), and a third bearing (12) is arranged between the lower end cover (5) and the crankshaft assembly (2).

3. The internal winding mechanism type power generation device according to claim 2, wherein: the crankshaft assembly (2) is a one-way shaft, one end of the one-way shaft penetrates through the upper end cover (3) and extends out of the supporting shell (1), the other end of the one-way shaft is connected with the supporting shell (1) through a fourth bearing (13), and a connecting seat (14 a) is arranged on the lower portion of the supporting shell (1).

4. The internal winding mechanism type power generation device according to claim 2, wherein: the crankshaft assembly (2) is a one-way shaft, and one end of the one-way shaft penetrates through the lower end cover (5) and extends out of the support shell (1); the other end is connected with the supporting shell (1) through a fourth bearing (13), a connecting seat (14 b) is arranged at the lower part of the supporting shell (1), and a fixed seat (15 b) is arranged at one side of the supporting shell (1).

5. The internal winding mechanism type power generation device according to claim 2, wherein: the crankshaft assembly (2) is a one-way shaft, the one-way shaft penetrates through the lower end cover (5) downwards and extends out of the support shell (1), and the upper part of the upper end cover (3) extends out of the support shell (1) upwards; the lower part of the support shell (1) is provided with a connecting seat (14 c), and the middle part of the support shell (1) is provided with a second connecting seat (16 c).

6. The internal winding mechanism type power generation device according to claim 1, wherein: the bearing assembly is characterized in that the upper end cover (3) and the lower end cover (5) are located above the supporting shell (1), the lower end cover (5) is fixedly connected with the supporting shell (1) through an outer cover body (30), a first bearing (10 a) is arranged between the upper end cover (3) and the crankshaft assembly (2), a second bearing (11 a) is arranged between the lower end cover (5) and the crankshaft assembly (2), and a third bearing (12 a) and a fourth bearing (13 a) are arranged between the crankshaft assembly (2) and the supporting shell (1).

7. The internal winding mechanism type power generation device according to claim 6, wherein: the crankshaft assembly (2) is a one-way shaft, and the upper end cover (3) and the lower end cover (5) are arranged at the upper end of the one-way shaft; the lower end of the one-way shaft is positioned in the support shell (1), and the lower part of the support shell (1) is provided with a connecting seat (14 d).

8. The internal winding mechanism type power generation device according to claim 6, wherein: the crankshaft assembly (2) is a bidirectional shaft, the bidirectional shaft comprises an upper barrel shaft (2-1) and a lower barrel shaft (2-2), and the upper barrel shaft (2-1) and the lower barrel shaft (2-2) are arranged on the same central axis; the upper barrel shaft (2-1) is fixedly connected with the supporting shell (1), the upper end cover (3) and the lower end cover (5) are installed on the upper barrel shaft (2-1), the lower barrel shaft (2-2) is connected with the supporting shell (1) through a third bearing (12 a) and a fourth bearing (13 a), and the lower portion of the supporting shell (1) is provided with a connecting seat (14 e).