CN210622994U - Wind power generation monitoring equipment based on Internet of things - Google Patents

Abstract

The utility model provides a wind power generation monitoring device based on the Internet of things, which comprises a main body, a control block, a moving block and a monitoring head; the method is characterized in that: the main body is of a rectangular internal hollow structure, the main body is the outer side of a top bin of the wind power generation device, the top end of the right side of the main body is of an inclined structure, and the periphery of the outer side of an upper groove of the main body is of an inclined structure; the side edge of the supporting piece is provided with a control block, the control block can transmit data with a mobile phone or a computer through a network, the rear side inside the upper groove is provided with a connecting shaft, and the inside of the top groove is provided with a spring; the movable block is installed in the top groove in an embedded mode, the supporting piece is of an electric cylinder structure, when the control block receives a command for controlling the supporting piece, the supporting piece can be forced to be outwards propped, the monitoring head is controlled to rotate, the monitoring angle is controlled, the upper groove is used for being arranged at the top end of the main body, and the monitoring head can be turned over in the upper groove.

Description

Wind power generation monitoring equipment based on Internet of things

Technical Field

The utility model belongs to the technical field of supervisory equipment, more specifically say, in particular to wind power generation supervisory equipment based on thing networking.

Background

A typical television monitoring system is mainly composed of two parts, a front-end device and a back-end device, wherein the front-end device is generally composed of a camera, a manual or electric lens, a cradle head, a protective cover, a monitor, an alarm detector, a multifunctional decoder and the like, and the front-end device and the back-end device respectively play their roles and establish corresponding relations (transmitting video/audio signals and control and alarm signals) with various devices of a central control system through wired, wireless or optical fiber transmission media. In an actual television monitoring system, these front-end devices are not necessarily used simultaneously, but a camera and a lens for realizing monitoring of live image acquisition are indispensable. The backend devices may be further divided into a central control device and a sub-control device.

For example, application No.: relate to an intelligent house supervisory equipment based on thing networking among CN201821033364.X, the power distribution box comprises a box body, one side fixedly connected with guard box of box inner wall bottom to the inside bottom of box is rotated and is connected with the support column, the top of support column runs through the box and extends to the outside of box, the support column extends to the outside one end fixedly connected with top case of box to the opposite side fixedly connected with U template of box inner wall bottom, the utility model relates to a thing networking technology field. This intelligent house supervisory equipment based on thing networking, the output through temperature comparator and humidity comparator all is connected with central processing unit's input through feedback module, has facilitated user's use more, and the bottom through the U template is rotated and is connected with the threaded rod, and intelligent supervisory equipment can carry out the regulation of angle, also can carry out the adjustment in position, can the omnidirectional detect, and the data of detection can be more accurate, use convenience more.

Based on equipment discovery among the prior art, current wind power generation supervisory equipment is when using, and the structure of supervisory equipment outside and inside is perfect inadequately simultaneously, is not convenient for monitor the state of outside fan piece and inside generator, and current wind power generation supervisory equipment when using, and the structure of supplementary clearance camera lens dust is perfect inadequately, is not convenient for convenient clean camera lens dust.

Therefore, in view of the above, research and improvement are performed on the existing structure and defects, and a wind power generation monitoring device based on the internet of things is provided, so as to achieve the purpose of higher practical value.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a wind power generation supervisory equipment based on thing networking to solve current wind power generation supervisory equipment when using, the supervisory equipment outside is not perfect with inside structure simultaneously, is not convenient for monitor the state of outside fan piece and inside generator, and current wind power generation supervisory equipment when using, and the structure of supplementary clearance camera lens dust is perfect inadequately, is not convenient for the problem of convenient clean camera lens dust.

The utility model discloses wind power generation supervisory equipment's purpose and efficiency based on thing networking is reached by following concrete technical means:

a wind power generation monitoring device based on the Internet of things comprises a main body, a control block, a moving block and a monitoring head; the method is characterized in that: the main body is of a rectangular internal hollow structure, the main body is the outer side of a top bin of the wind power generation device, the top end of the right side of the main body is of an inclined structure, and the periphery of the outer side of an upper groove of the main body is of an inclined structure; the side edge of the supporting piece is provided with a control block, the control block can transmit data with a mobile phone or a computer through a network, the rear side inside the upper groove is provided with a connecting shaft, and the inside of the top groove is provided with a spring; the moving block is arranged in the top groove in an embedded mode, and the inner end of the moving block is connected with the spring; the rear end of the monitoring head is connected with the rear end of the inner part of the upper groove through a connecting shaft, the front end of the monitoring head is in contact with the contact element, and an induction head is arranged above the front end of the monitoring head.

Further, the body includes a guide, a drain, a support, a control block, an upper groove, and a top groove; the bottom of the inside of the main body is of an inclined structure, the bottom of the main body is provided with a guide piece of a wedge-shaped structure, and the rear end of the bottom of the main body is provided with a drainage port.

Furthermore, the bottom of the supporting piece is connected with the bottom end of the bottom of the main body, the top end of the supporting piece is connected with the bottom of the monitoring head, an upper groove of a rectangular structure is formed in the top end of the main body, and a top groove of a T-shaped structure is formed in the side edge of the upper groove.

Furthermore, the moving block is of a T-shaped structure, the outer end of the moving block is provided with a contact element, the contact element is made of silica gel, and the outer end of the contact element is of a wedge-shaped structure.

Further, the monitoring head comprises a stopper and an induction head; the monitoring head is of a rectangular structure, the monitoring head is installed inside the upper groove, and stoppers of wedge structures are arranged above the front end and the rear end of the monitoring head.

Compared with the prior art, the utility model discloses following beneficial effect has:

in the device, a supporting piece and a moving block are arranged, wherein the supporting piece is of an electric cylinder structure, so that when a control block receives a command for controlling the supporting piece, the supporting piece can be forced to be outwards propped, so that a monitoring head is controlled to rotate, and the monitoring angle is controlled, an upper groove is formed in the top end of a main body and can be overturned inside the monitoring head, the periphery of the upper groove is of an inclined structure, so that rainwater can be guided outwards when falling down, a top groove is used for installing the moving block, so that the moving block can move inside the moving block, so that the moving block can be stably installed, and the top groove is of a T-shaped structure and cannot be easily separated after the moving block is installed;

the moving block is arranged in the top groove, so that the moving block can be forced to move outwards when being embedded in the top groove, and the moving block can be contacted with the front end of the monitoring head through the contact element on the outer side, the moving block is of a T-shaped structure and can be arranged in the top groove and cannot be easily separated, so that the spring can always support the moving block, the contact element is always contacted with the monitoring head, the contact element is made of silica gel and can be always contacted with the front end of the monitoring head, the monitoring head can enable the contact element to be always contacted with the front end of the monitoring head when being overturned every time, the front end of the monitoring head is always kept clean, dust is removed, the problems that the external fan blade and the internal generator are inconvenient to monitor are solved when in use, the external and internal structures of the monitoring device are not perfect enough, and when the existing wind power generation monitoring equipment is used, the structure for assisting in cleaning the dust on the lens is not perfect, and the dust on the lens is not convenient and fast to clean.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic view of the internal structure of the present invention.

Fig. 3 is a schematic diagram of a partially enlarged structure of a portion a of the present invention, which is drawn from fig. 1.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a main body; 101. a guide; 102. a water outlet; 103. a support member; 104. a control block; 105. an upper groove; 106. a top groove; 2. a moving block; 201. a contact member; 3. a monitoring head; 301. a stopper; 302. an inductive head.

Detailed Description

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 3:

the utility model provides a wind power generation monitoring device based on the Internet of things, which comprises a main body 1, a control block 104, a moving block 2 and a monitoring head 3; the method is characterized in that: the main body 1 is a rectangular internal hollow structure, the main body 1 is the outer side of a top bin of the wind power generation device, the top end of the right side of the main body 1 is an inclined structure, and the periphery of the outer side of an upper groove 105 of the main body 1 is an inclined structure; a control block 104 is arranged on the side of the supporting part 103, the control block 104 can transmit data with a mobile phone or a computer through a network, a connecting shaft is arranged on the rear side of the inside of the upper groove 105, and a spring is arranged inside the top groove 106; the moving block 2 is installed inside the top groove 106 in an embedded mode, and the inner end of the moving block 2 is connected with a spring; the rear end of the monitoring head 3 is connected with the inner rear end of the upper groove 105 through a connecting shaft, the front end of the monitoring head 3 is in contact with the contact element 201, and an induction head 302 is arranged above the front end of the monitoring head 3.

Wherein the main body 1 comprises a guide 101, a drain 102, a support 103, a control block 104, an upper groove 105, and a top groove 106; the inside bottom of main part 1 is slope column structure, and the bottom of main part 1 is equipped with guide 101 of wedge structure, and the bottom rear end of main part 1 is equipped with down the mouth of a river 102, the inside bottom of main part 1 of here is slope column structure, be for when making the rainwater get into, can carry out the water conservancy diversion with the rainwater, thereby make the rainwater by the inside of water conservancy diversion to down the mouth of a river 102, thereby discharge the rainwater, guide 101 is used for establishing in the inside bottom of main part 1, if the rainwater drips, can be with the rainwater water conservancy diversion, avoid rainwater and generator to contact, influence its life.

Wherein the bottom of the supporting member 103 is connected to the bottom of the main body 1, the top of the supporting member 103 is connected to the bottom of the monitoring head 3, the top of the main body 1 is provided with an upper groove 105 having a rectangular structure, and the side of the upper groove 105 is provided with a top groove 106 having a T-shaped structure, where the supporting member 103 is an electric cylinder structure, so that when the control block 104 receives a command for controlling the supporting member 103, the supporting member 103 can be forced outward to control the monitoring head 3 to rotate, thereby controlling the monitoring angle, the upper groove 105 is used for being arranged at the top of the main body 1, so that the monitoring head 3 can be turned over inside, the periphery of the upper groove 105 is an inclined structure, so that when rainwater falls, the rainwater can be guided outward, and the top groove 106 is used for installing the moving block 2, so that the moving block 2 can move inside, therefore, the moving block 2 can be stably installed, and the top groove 106 is of a T-shaped structure, so that the moving block 2 cannot be easily separated after being installed.

Wherein, the moving block 2 is a T-shaped structure, the outer end of the moving block 2 is provided with a contact member 201, the contact member 201 is made of silica gel, furthermore, the outer end of the contact member 201 is a wedge-shaped structure, the moving block 2 is arranged in the top groove 106, so that the moving block 2 can be forced to move outwards when embedded in the top groove 106, thereby the moving block 2 can be contacted with the front end of the monitoring head 3 through the contact member 201 at the outer side, the moving block 2 is a T-shaped structure, and can be arranged in the top groove 106 and can not easily disengage, thereby the spring can always support the moving block 2, thereby the contact member 201 is always contacted with the monitoring head 3, the contact member 201 is made of silica gel, so that the monitoring head 3 can always be contacted with the front end of the monitoring head 3 when overturned each time, the contact member 201 can always be contacted with the front end of the monitoring head 3, so that the front end of the monitoring head 3 is always kept clean, thereby removing dust.

Wherein the monitoring head 3 comprises a flight 301 and an inductive head 302; the monitoring head 3 is of a rectangular structure, the monitoring head 3 is installed inside the upper groove 105, blocking pieces 301 of wedge-shaped structures are arranged above the front end and the rear end of the monitoring head 3, the monitoring head 3 is used for monitoring the fan and the generator inside the main body 1, when the generator breaks down, the damaged structure can be clearly seen, the bottom of the monitoring head 3 is connected with the supporting piece 103, the supporting piece 103 can effectively control the monitoring head 3, the obtained monitoring head 3 can conveniently control the angle, the blocking pieces 301 are arranged at the front end and the rear end of the main body 1, rainwater can be guided when the monitoring head is in rainy days, rainwater entering is reduced, and the sensing head 302 is arranged at the front end of the monitoring head 3 and used for monitoring the sensing fan.

The specific use mode and function of the embodiment are as follows:

in the utility model, when in use, the mobile phone can be connected through the network, so that the control block 104 can receive the outgoing command, so that the support 103 is supported outward, thereby the monitoring head 3 can switch the monitoring position, when the monitoring head 3 overturns, the moving block 2 receives the power transmitted by the spring, so that the moving block 2 can always drive the contact member 201 to move outwards, so that the contact member 201 can remove the dust at the front end of the monitoring head 3, thereby reducing the influence of dust on the monitoring effect, when in rainy days, the blocking piece 301 can be matched with the top end of the main body 1 to guide the falling rainwater, thereby reducing the entering rainwater, and when a small amount of rainwater enters the inside of the main body 1, the rainwater is guided by the guide member 101, so that rainwater flows at the bottom of the main body 1, and thus rainwater can be discharged from the drain port 102.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (5)

1. A wind power generation monitoring device based on the Internet of things comprises: the device comprises a main body (1), a control block (104), a moving block (2) and a monitoring head (3); the method is characterized in that: the main body (1) is of a rectangular internal hollow structure, the main body (1) is the outer side of a top bin of the wind power generation device, the top end of the right side of the main body (1) is of an inclined structure, and the periphery of the outer side of an upper groove (105) of the main body (1) is of an inclined structure; a control block (104) is arranged on the side edge of the supporting piece (103), the control block (104) can transmit data with a mobile phone or a computer through a network, a connecting shaft is arranged on the rear side of the inside of the upper groove (105), and a spring is arranged inside the top groove (106); the moving block (2) is installed inside the top groove (106) in an embedded mode, and the inner end of the moving block (2) is connected with the spring; the rear end of the monitoring head (3) is connected with the inner rear end of the upper groove (105) through a connecting shaft, the front end of the monitoring head (3) is in contact with the contact element (201), and an induction head (302) is arranged above the front end of the monitoring head (3).

2. The wind power generation monitoring device based on the internet of things as claimed in claim 1, wherein: the main body (1) comprises a guide (101), a lower nozzle (102), a support (103), a control block (104), an upper groove (105), and a top groove (106); the bottom end of the inside of the main body (1) is of an inclined structure, a guide piece (101) of a wedge-shaped structure is arranged at the bottom of the main body (1), and a drainage port (102) is arranged at the rear end of the bottom of the main body (1).

3. The wind power generation monitoring device based on the internet of things as claimed in claim 1, wherein: the bottom of support piece (103) is connected with the bottom of main part (1), and the top of support piece (103) is connected with the bottom of monitoring head (3), and the top of main part (1) is equipped with upper trough (105) of rectangular structure to the side of upper trough (105) is equipped with top groove (106) of T shape structure.

4. The wind power generation monitoring device based on the internet of things as claimed in claim 1, wherein: the moving block (2) is of a T-shaped structure, the outer end of the moving block (2) is provided with a contact element (201), the contact element (201) is made of silica gel, and the outer end of the contact element (201) is of a wedge-shaped structure.

5. The wind power generation monitoring device based on the internet of things as claimed in claim 1, wherein: the monitoring head (3) comprises a stopper (301) and an induction head (302); the monitoring head (3) is of a rectangular structure, the monitoring head (3) is installed inside the upper groove (105), and blocking pieces (301) of a wedge-shaped structure are arranged above the front end and the rear end of the monitoring head (3).

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