KR20140005302U - Disk brake of landscape windmill - Google Patents

Abstract

Disclosed is a disk brake apparatus for a landscape windmill. And is rotatably installed by an installation frame provided inside the landscape windmill structure of the present invention. A disk member provided on an outer circumferential surface of the rotating shaft so as to prevent rotation of the rotating shaft due to inertia or wind pressure acting on the blade in a state where the driving motor is stopped; A pair of pads for pressing both surfaces of the disk member, and a plurality of pads disposed on opposite surfaces of the respective ends of the carrier, wherein the pads are spaced apart from each other, A carrier assembly including a pair of pad supports and an elastic body disposed between the pad supports to generate elasticity so that the pads are spaced apart from each other; And an operating portion provided at one side of the carrier for actuating each pad support provided on the carrier with pneumatic or hydraulic pressure generated from a pneumatic or hydraulic pressure generating portion so that each of the pads presses or separates the disk member . According to the present invention, a disk-shaped disk member is provided on the outer circumferential surface of a rotary shaft for rotating a blade of a landscape windmill, and both sides of the disk member are pressed by a pad, thereby effectively stopping the rotation of the rotary shaft .

Description

DISK BRAKE OF LANDSCAPE WINDMILL BACKGROUND OF THE INVENTION [0001]

The present invention relates to a disk brake apparatus for a landscape windmill, and more particularly, to a disk brake apparatus for a landscape windmill capable of effectively stopping a rotating shaft for driving a windmill blade.

 In general, windmills for landscaping are installed on sightseeing spots and play a role of landscaping to make landscapes beautiful.

Such a landscape windmill is not rotated by wind but has a structure that is forcibly rotated by a driving member such as a driving motor.

When the wing is rotated by the wind or inertia, the rotating shaft rotates irrespective of the driving of the driving motor, and the driving motor or the speed reducer .

 Therefore, when a typhoon occurs, the rotation shaft must be stopped to prevent the driving member from malfunctioning.

This problem can be somewhat solved by providing a brake device as shown in FIG. 1 in Korean Utility Model Registration No. 20-0312831 (2003: 05.16). That is, the conventional brake apparatus includes a band member 52 fixed to one side of the installation frame 12, an operation end 54 coupled to the other end of the band member 52, And an actuator 56 which is installed on the other side and moves forward or backward of the operation end 54 so that the inner surface of the band member 52 is in close contact with or spaced from the outer circumferential surface of the rotary shaft 30.

However, in the prior art braking device, the band member 52 pulls the one end of the band member 52 with the actuator 56 while the rotating member 30 is wrapped around the rotating shaft 30, The rotation of the rotary shaft 30 can be suppressed but the band member 52 does not completely surround the rotary shaft 30 so that even if one end of the band member 52 is pulled by the actuator 56, There is a problem that the rotating shaft 30 does not stop and rotates.

In this way, when the rotary shaft 30 is forcibly rotated by the wind pressure acting on the blades, the driving motor for driving the rotary shaft 30 and the speed reducer may be damaged.

Further, the conventional braking device is constituted by a band brake device, so that there is a problem that only one-way rotation of the rotating shaft can be restricted.

Korean Registered Utility Model No. 20-0312831 (2003: 05. 16)

The object of the present invention is to provide a braking device capable of preventing the rotating shaft from rotating due to the wind pressure acting on the wing while the rotating shaft of the wind turbine for landscape is stopped. .

In addition, the problems to be solved by the present invention are not limited to the technical problems mentioned above, and other technical problems which are not mentioned are clarified from the following description to those having ordinary skill in the art to which the present invention belongs It can be understood.

According to the present invention, the above object is achieved by a windmill structure for a landscape, which is rotatably installed by an installation frame provided inside the windmill structure. A disk member provided on an outer circumferential surface of the rotating shaft so as to prevent rotation of the rotating shaft due to inertia or wind pressure acting on the blade in a state where the driving motor is stopped; A pair of pads for pressing both surfaces of the disk member, and a plurality of pads disposed on opposite surfaces of the respective ends of the carrier, wherein the pads are spaced apart from each other, A carrier assembly including a pair of pad supports and an elastic body disposed between the pad supports to generate elasticity so that the pads are spaced apart from each other; And an operating portion provided at one side of the carrier for actuating each pad support provided on the carrier with pneumatic or hydraulic pressure generated from a pneumatic or hydraulic pressure generating portion so that each of the pads presses or separates the disk member Of the wind turbine for landscape windmill.

The disk member may be formed integrally with the outer circumferential surface of the rotating shaft.

The disk member may include a pair of engaging portions formed in a semi-cylindrical shape and surrounding the rotating shaft, the pair of engaging portions being coupled to the rotating shaft by a fixing bolt or a fixing key; And a plurality of half disk-shaped disks integrally provided at one end of each of the engaging portions.

The diameter of the disk member may be 1.5 to 4 times larger than the diameter of the rotation shaft.

The operation unit includes a main body having a piston which is coupled to an end of one of the pad supports and which is operated forward and backward by hydraulic pressure or air pressure to be supplied; And one end connected to the piston in the main body and the other end contacting the pad support opposed to the pad support to which the main body is coupled so that the pad of the pad support presses the disk member while advancing by the operation of the piston And may include a working load that is operative.

According to the present invention, a disk-shaped disk member is provided on the outer circumferential surface of a rotating shaft for rotating a blade of a landscape windmill. By pressing both surfaces of the disk member with pads, the pressing force of the pads is concentrated on the disk contact surface, Thus, it is possible to effectively stop the rotation of the rotating shaft and to stably maintain the stopped state of the rotating shaft.

In addition, since the disk member is configured to be divided, it is possible to provide an effect applicable to a previously installed rotary shaft.

Further, by applying the disc brake, it is possible to provide an effect of controlling the rotation in the forward and reverse directions of the rotation axis.

1 is a schematic cross-sectional view showing a conventional disk brake apparatus for a landscape windmill.
Fig. 2 is an exploded perspective view showing a disk brake device for a landscape windmill according to the present invention. Fig.
3 is a cross-sectional view showing the state of the disk brake of the landscape windmill shown in FIG.
Fig. 4 is a sectional view showing a state in which the disc brake unit of the landscape windmill shown in Fig. 3 is operated. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, a description of known functions or configurations will be omitted for the sake of clarity of the present invention.

2 is an exploded perspective view showing a disc brake apparatus for a landscape windmill according to the present invention, FIG. 3 is a sectional view of a coupled state of the disc brake apparatus for a landscape windmill shown in FIG. 2, and FIG. 4 Is a sectional view showing a state in which the disc brake device of the landscape windmill shown in Fig. 3 is operated.

2 to 4, a disk brake apparatus for a landscape windmill according to the present invention is rotatably installed by an installation frame (not shown) provided inside a landscape windmill structure. A rotating shaft 200 rotated by a driving motor (not shown) having a speed reducer and a rotating shaft 200 for preventing rotation of the rotating shaft 200 due to inertia or wind pressure acting on the blade in a state where a driving motor .

The brake device includes a disk member 300 provided on the outer circumferential surface of the rotary shaft 200, a carrier 410 mounted on an installation frame (not shown), and a pair for pressing both surfaces of the disk member 300 A pair of pad supports 430A and 430B having pads 420 on opposite sides of the respective ends of the pad 420 and the intermediate portions of which are spaced from each other and are axially coupled to the carrier 410, A carrier device 400 including an elastic body 440 installed between the pad supports 430A and 430B to generate elasticity so that the pads 420 are spaced apart from each other; An operation portion for operating each of the pad supports 430A and 430B installed on the carrier 410 by pneumatic or hydraulic pressure generated from the hydraulic pressure generator 500 so that each pad 420 presses or separates the disk member 300, (600).

This will be described in more detail as follows.

A rotating shaft 200 rotatably coupled to the installation frame, a windmill blade coupled to an end of the rotary shaft 200, a drive motor for driving the rotary shaft 200, a speed reducer, and the like Are well known and will not be described in detail.

The disk member 300 is formed in a disk shape and has a plurality of heat dissipating holes and is mounted on the outer circumferential surface of the rotary shaft 200 and coupled thereto. The disc member 300 is not shown in the drawing, but a part of the rotating shaft 200 may be radially protruded. 2 to 4, the disk member 300 is formed in a semicylindrical shape and surrounds the rotation axis 200, and is coupled to the rotation axis 200 by a fixing bolt or a fixed key. (320), and semi-circular discs (330) integrally or separately formed at one end of each coupling portion (320) and coupled to be integrated.

In other words, the disk 330 having a semi-circular plate shape is provided at the end of each coupling part 320, respectively. Accordingly, when the coupling portions 320 are coupled to the rotating shaft 200, the disks 330 are connected to each other to form an integrated disk. At this time, each engaging portion 320 is coupled to the rotating shaft 200 by a fixing bolt passing through the engaging portion 320 and coupled to the rotating shaft 200, or a fixed key.

The disc 330 may be integrally formed with a centering fitting hole without being divided and may be fitted to the rotational shaft 200 and then coupled to the coupling portion 320, The disk 330 may be integrally formed and be fitted to the rotation shaft 200.

As described above, the disk member 300 is configured by the two engaging portions 320, so that the disk member 300 can be applied to the previously installed rotating shaft 200 to be coupled. That is, in order to install the disk member 300, unnecessary work such as separating or moving the rotary shaft 200 is not required.

At this time, the diameter of the disc member 300, that is, the total diameter of the disc 320, is formed to be 1.5 to 4 times larger than the diameter of the rotating shaft 200. This is because as the edge of the disc member 300 is farther from the center of the rotary shaft 200, the resistance against the rotation of the rotary shaft 200 can greatly act when the edge of the disc member 300 is pressed by the pads 420. When the diameter of the disc member 300 is less than 1.5 times the diameter of the rotary shaft 200, the force against rotation of the rotary shaft 200 acts as described above, The force against the rotation of the rotary shaft 200 is increased, but the manufacturing cost is increased, and a large space is required for installing and operating the disc member 300. Therefore, it is preferably formed to have a size of 2-3 times.

The carrier device 400 is provided with a pair of pad supports 430A and 430B and the body 610 of the actuating part 600 is installed on one of the pad supports 430A. At this time, as shown in FIGS. 2 to 3, a seating frame 170 for mounting the carrier 410 stably is provided on the upper surface of the installation frame. The mounting frame 170 is formed on the upper surface with an inclined surface 172 having an inclination corresponding to the inclination of the rotating shaft 200 which is inclined. The carrier 410 is provided on the inclined surface 172, Can be held at right angles to both surfaces of the disc 330. [ That is, the seating frame 170 is fixed to the upper surface of the mounting frame 170, and the carrier 410 is installed on the inclined surface 172 of the mounting frame 170.

The carrier device 400 is configured such that the pad 420 is always spaced from the surface of the disk 330 by the elastic body 440.

The actuating part 600 is provided with a piston (not shown) which is coupled to the end of one of the pad supports 430A among the pad supports 430A and 430B and operated forward and backward by the supplied hydraulic pressure or pneumatic pressure The main body 610 is brought into contact with the pad support 430B opposed to the pad support 430A to which the main body 610 is coupled and the other end is engaged with the piston at the inside of the main body 610, Each pad of the pad supports 430A and 430B is actuated to press the disk 330 of the disk member 300 while advancing.

The main body 610 may be a cylinder body operated by pneumatic pressure or hydraulic pressure, or may be formed of a main body for housing the diaphragm.

Hereinafter, the operation of the brake device according to the present invention will be described.

When the drive motor 120 is stopped, the rotary shaft 200 rotates due to inertia or wind pressure acting on the blade. Such a natural rotation operation may damage the speed reducer provided in the drive motor 120. [

Therefore, it is important to stop the rotary shaft 200 by controlling the braking device when stopping the rotary shaft 200 due to various conditions such as approaching a typhoon or maintenance.

To this end, when the brake device is operated, the main body 610 receiving the hydraulic pressure or the air pressure generated in the pneumatic or hydraulic pressure generator 500 advances the piston (not shown).

When the piston is advanced, the operation rod 620 advances and the main body 610 pushes the end of the unmated pad support 430A. Accordingly, the pad support 430B pushed by the operation rod 620 rotates about an axis, and the pad 420 is pressed against the disk 330. [ The pad support 430A coupled to the main body 610 by the reaction force generated by the operation also rotates about the axis and the pad 420 coupled to the end of the pad support 430A presses the other surface of the disk 330. [

That is, by the forward movement of the operation rod 620, the respective pad supports 430A and 430B rotate in directions opposite to each other, and each pad 420 presses both surfaces of the disk 330.

When the pad 420 presses the disk 330 by the operation of the pad supports 430A and 430B, the rotation of the rotary shaft 200 is stopped. This is because each pad 420 presses the rotation of the disk member 300 integrated with the rotary shaft 200 to prevent it.

Each of the pads 420 presses the edge region of the disk 330 at a predetermined distance from the center of the rotary shaft 200, so that the force for restricting the rotation of the rotary shaft 200 is large. This phenomenon increases in proportion to the size of the disc 330. [ However, as the size of the disk 330 increases, the space for installing the brake device must be widened. Therefore, the size of the disk 330 can not be increased to an infinite level. The diameter of the disk 330 is approximately 1.5 to 4 times the diameter of the rotary shaft 200 As shown in Fig.

When the pad 420 presses the disk 330 by the hydraulic pressure or the pneumatic pressure to operate the operation rod 620 to move backward while the rotary shaft 200 is stopped, And 430B are removed so that the pad supports 430A and 430B return to their original positions due to the elasticity of the elastic body 440. As a result, the pads 420, Is spaced from both sides of the disk 330, and thus the rotation axis 200 can be rotated.

As described above, the rotation of the rotary shaft 200 can be effectively prevented by applying the disc brake type braking device of pneumatic or hydraulic pressure to the rotary shaft 200 of the landscape windmill.

It will be understood by those skilled in the art that although specific embodiments of the present invention have been illustrated and described, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention, It is obvious to those who have. Therefore, such modifications or variations should not be individually understood from the technical idea or viewpoint of the present invention, but the modified embodiments should be included in the claims of utility model registration of the present invention.

170: seat frame 172: inclined surface
200: rotating shaft 300: disk member
320: coupling portion 330: disk
400: Carrier device 410: Carrier
420: pads 430A, 430B: pad support
440: Elastic body 500: Pneumatic or hydraulic generator
600: operating part 610: main body
620: Working load

Claims (1)

And is rotatably installed by an installation frame installed inside the windmill structure for landscaping. A rotation shaft which is rotated by a drive motor having a speed reducer and a rotation shaft which is not rotated by the wind pressure acting on the inertia or the blade in a state where the drive motor is stopped,
A disk member provided on an outer circumferential surface of the rotary shaft; A pair of pads for pressing both surfaces of the disk member, and a plurality of pads disposed on opposite surfaces of the respective ends of the carrier, wherein the pads are spaced apart from each other, A carrier assembly including a pair of pad supports and an elastic body disposed between the pad supports to generate elasticity so that the pads are spaced apart from each other; And an operating portion provided at one side of the carrier for actuating each pad support provided on the carrier with a pneumatic or hydraulic pressure generated from a pneumatic or hydraulic pressure generating portion so that each pad presses or separates the disk member,
Wherein the disk member comprises:
A pair of engaging portions formed integrally with the outer circumferential surface of the rotary shaft or formed in a semi-cylindrical shape to surround the rotary shaft and coupled to the rotary shaft by a fixing bolt or a fixing key; And each of the semi-circular discs integrally provided at one end of each of the engaging portions,
The diameter of the disk member may be,
Is formed to be 1.5 - 4 times larger than the diameter of the rotating shaft,
Wherein,
A main body having a piston which is coupled to an end of one of the pad supports and which is operated forward and backward by hydraulic pressure or air pressure to be supplied; And one end connected to the piston in the main body and the other end contacting the pad support opposed to the pad support to which the main body is coupled so that the pad of the pad support presses the disk member while advancing by the operation of the piston Including a working working rod,
On the upper surface of the seat frame installed in the installation frame,
Wherein the carrier is provided on the inclined surface so that each of the pads can be held at a right angle to both surfaces of the disk, the inclined surface having an inclination corresponding to the inclination of the rotating shaft,
Disk brake device of landscape windmill.

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