CN113804309A - New energy generator monitoring facilities - Google Patents

Abstract

The invention discloses new energy generator monitoring equipment which comprises a generator main body, wherein the generator main body comprises a straight cylinder, a control module, a ventilating net, a base, a water inlet and an adjusting device, the monitoring equipment is arranged in the middle of the straight cylinder and comprises an upper monitoring disc and a lower monitoring disc, and a strip-shaped block is arranged on the upper side of the monitoring equipment. According to the invention, through a small generator main body, monitoring equipment is arranged on the main body and is divided into an upper layer part and a lower layer part, wherein the upper layer part forms a monitoring module structure for monitoring the formation of heat productivity in the generator, and the lower layer forms an auxiliary kinetic energy module.

Description

New energy generator monitoring facilities

Technical Field

The invention relates to the field of equipment monitoring, in particular to new energy generator monitoring equipment.

Background

In the current new energy power generation equipment, no matter large power generation equipment or small power generation equipment can not be used for state monitoring and diagnosis in operation, and scheduled maintenance and possible faults and other phenomena need to be eliminated according to monitoring results, so that the generator monitoring equipment needs to fully collect information aiming at target power generation, and some monitoring equipment also has a certain degree of protection effect.

However, the existing hydroelectric power generation equipment has the phenomena of insufficient monitoring and excessively low information collection amount in large-scale equipment and small-scale equipment power generation, and particularly under the condition facing to a small-scale hydroelectric generator, the existing hydroelectric power generation equipment belongs to the small-scale equipment, if newly-increased equipment is only used for maintenance, and cannot improve the structure of the existing hydroelectric power generation equipment, the existing simple and reliable functionality of the small-scale hydroelectric generator can be reduced, and therefore in the process facing to the hydroelectric power generation equipment, the monitoring equipment capable of further improving the equipment utilization rate and the information is required to be arranged.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a new energy generator monitoring device.

In order to solve the technical problems, the invention provides the following technical scheme:

the invention relates to a new energy generator monitoring device, which comprises a generator main body, wherein the generator main body comprises a straight cylinder, a control module, a ventilating net, a base, a water inlet and an adjusting device, the middle part of the straight cylinder is provided with a monitoring device, the monitoring device comprises an upper monitoring disc and a lower monitoring disc, the upper side of the monitoring device is provided with a strip-shaped block, the surface of the upper monitoring disc is provided with a sliding track, the surface of the sliding track is provided with a sliding block, the inner side of the upper monitoring disc is provided with a fixing ring, the surface of the fixing ring is provided with a fixing hole, the inner side of the upper monitoring disc comprises a driving motor and a receiving module, the bottom end of the sliding block is provided with a conical cylinder, the top end of the conical cylinder is provided with a groove cylinder, the inner side of the groove cylinder is provided with an electric steering engine, the top end of the electric steering engine is provided with a support rod, and the top end of the support rod is provided with the monitoring module, one side surface mounting of monitoring module has infrared thermal imaging camera, infrared induction camera is installed on monitoring module's top, the inboard mid-mounting of monitoring dish has perpendicular dwang down, the mid-mounting of perpendicular dwang has the coil pole, the rolling disc is installed in the outside of coil pole, and the magnet induction circle is installed to the outside bottom of its rolling disc, and fixed gear is installed on the outside top of rolling disc, and the dead lever is installed on the top of its fixed gear, the outside surface mounting of fixed gear has outer ring gear, the surface mounting of outer ring gear has the flabellum.

As a preferred technical scheme of the invention, the control module is electrically connected with the receiving module, the receiving module is respectively electrically connected with the magnet induction coil, the monitoring module and the driving motor, and the receiving module comprises an MCU micro-control chip and a voltage sensor.

As a preferred technical scheme of the invention, the upper monitoring disc and the straight cylinder are fixedly connected through a fixing ring and a fixing hole by bolts, the inner wall of the upper monitoring disc is smoothly arranged, the driving motor is in transmission connection with the sliding track, and the sliding track is in an arc sliding rail structure and comprises a synchronous belt and a pinion structure.

As a preferred technical scheme of the invention, the sliding block is in transmission connection with the sliding track, the conical cylinder is in fixed connection with the groove cylinder, the groove cylinder is in fixed connection with the electric steering engine, the electric steering engine is in transmission connection with the supporting rod, and the supporting rod is in fixed connection with the monitoring module.

As a preferred technical scheme of the present invention, the infrared thermal imaging camera is perpendicular to the surface of the straight cylinder, the infrared sensing camera is one of an infrared distance measuring camera or an infrared laser camera, the monitoring module further includes a PWM module therein, and the outer surface of the strip block is a mirror surface.

As a preferred technical solution of the present invention, the vertical rotating rod and the rotating disk are fixedly connected through a coil rod, the lower monitoring disk penetrates through the inner side of the straight cylinder, the vertical rotating rod is a part of the inner structure of the straight cylinder, the rotating disk and the outer gear ring are engaged through a fixed gear, the inner walls of the rotating disk and the lower monitoring disk are movably connected through a bearing, the fixed gear and the lower monitoring disk are fixedly connected through a fixed rod, the fixed rod is arranged in a rectangular structure, the outer gear ring and the fan blades are fixedly connected, and the fan blades penetrate through the lower monitoring disk to the surface thereof.

According to a preferable technical scheme of the invention, strong magnets are arranged on the inner side of the magnet induction ring, the strong magnets are arranged at two ends of the magnet induction ring, and the magnet induction ring is fixedly connected with the lower monitoring disc.

Compared with the prior art, the invention has the following beneficial effects:

according to the invention, through a small generator main body, monitoring equipment is arranged on the main body and is divided into an upper layer part and a lower layer part, wherein the upper layer part forms a monitoring module structure for monitoring the formation of heat productivity in the generator, and the lower layer forms an auxiliary kinetic energy module.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the upper monitoring plate configuration of the present invention;

FIG. 3 is a schematic view of the slider structure of the present invention;

FIG. 4 is a cross-sectional view of the lower monitoring plate configuration of the present invention;

FIG. 5 is a top view of the fixed gear arrangement of the present invention;

in the figure: 1. a generator main body; 101. a straight cylinder; 102. a control module; 103. a ventilation net; 104. a base; 105. a water inlet; 106. an adjustment device; 2. monitoring equipment; 201. an upper monitoring disc; 202. a lower monitoring disc; 203. a sliding track; 204. a fixing ring; 205. a fixing hole; 3. a strip-shaped block; 4. a slider; 401. a tapered barrel; 402. a grooved drum; 403. an electric steering engine; 404. a support bar; 5. a monitoring module; 501. an infrared thermal imaging camera; 502. an infrared sensing camera; 6. a vertical rotating rod; 601. a coil rod; 602. rotating the disc; 603. a magnet induction coil; 604. fixing a gear; 605. fixing the rod; 606. an outer ring gear; 607. a fan blade.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

Example 1

As shown in fig. 1-5, the invention provides a new energy generator monitoring device, which comprises a generator main body 1, wherein the generator main body 1 comprises a straight cylinder 101, a control module 102, a ventilation net 103, a base 104, a water inlet 105 and an adjusting device 106, a monitoring device 2 is installed in the middle of the straight cylinder 101, the monitoring device 2 comprises an upper monitoring disc 201 and a lower monitoring disc 202, a strip-shaped block 3 is installed on the upper side of the monitoring device 2, a sliding rail 203 is arranged on the surface of the upper monitoring disc 201, a sliding block 4 is installed on the surface of the sliding rail 203, a fixing ring 204 is installed on the inner side of the upper monitoring disc 201, a fixing hole 205 is installed on the surface of the fixing ring 204, a driving motor and a receiving module are installed on the inner side of the upper monitoring disc 201, a conical cylinder 401 is installed at the bottom end of the sliding block 4, a groove cylinder 402 is installed at the top end of the conical cylinder 401, electric steering wheel 403 is installed to the inboard of groove section of thick bamboo 402, bracing piece 404 is installed on electric steering wheel 403's top, monitoring module 5 is installed on the top of bracing piece 404, one side surface mounting of monitoring module 5 has infrared thermal imaging camera 501, infrared induction camera 502 is installed on monitoring module 5's top, the inboard mid-mounting of monitoring dish 202 has perpendicular dwang 6 down, the mid-mounting of perpendicular dwang 6 has coil pole 601, rolling disc 602 is installed in the outside of coil pole 601, and magnet induction circle 603 is installed to the outside bottom of its rolling disc 602, and fixed gear 604 is installed on the outside top of rolling disc 602, and dead lever 605 is installed on the top of its fixed gear 604, the outside surface mounting of fixed gear 604 has outer ring gear 606, the surface mounting of outer ring gear 606 has flabellum 607.

Further, the control module 102 is electrically connected to the receiving module, the receiving module is electrically connected to the magnet coil 603, the monitoring module 5 and the driving motor, and the receiving module includes an MCU micro-control chip and a voltage sensor.

Go up monitoring dish 201 and straight section of thick bamboo 101 and be bolt fixed connection through solid fixed ring 204 and fixed orifices 205, the inner wall of going up monitoring dish 201 is smooth setting, driving motor and slip track 203 are the transmission and connect, and its slip track 203 is circular arc slide rail structure, and includes hold-in range and pinion structure.

The sliding block 4 is in transmission connection with the sliding track 203, the conical barrel 401 is fixedly connected with the groove barrel 402, the groove barrel 402 is fixedly connected with the electric steering engine 403, the electric steering engine 403 is in transmission connection with the supporting rod 404, and the supporting rod 404 is fixedly connected with the monitoring module 5.

Infrared thermal imaging camera 501 is perpendicular setting with straight section of thick bamboo 101 surface, infrared induction camera 502 is one of infrared range finding camera or infrared laser camera, monitoring module 5 is inside still includes the PWM module, the outside surface of strip piece 3 is the mirror surface setting.

Perpendicular dwang 6 and carousel 602 are fixed connection through coil bar 601, and it is inboard that its lower monitoring disc 202 runs through to straight section of thick bamboo 101, and perpendicular dwang 6 is a part of straight section of thick bamboo 101 inner structure, carousel 602 and outer ring gear 606 are connected for the meshing through fixed gear 604, and its carousel 602 sets up for bearing swing joint with lower monitoring disc 202 inner wall, fixed gear 604 and lower monitoring disc 202 are fixed connection through dead lever 605, and its dead lever 605 sets up for rectangular structure, outer ring gear 606 and flabellum 607 are fixed connection, and its flabellum 607 runs through down and detects the dish to its surface.

The magnet induction coil 603 inboard is provided with the strong magnet, and its strong magnet all is located the both ends setting of magnet induction coil 603, magnet induction coil 603 is fixed connection with lower monitoring panel 202.

Specifically, the monitoring device 2 is mainly based on the small generator main body 1 and is structured as a structure, on the premise of not destroying the original functionality, that is, the straight cylinder 101, the control module 102, the ventilation net 103, the base 104, the water inlet 105 and the adjusting device 106 which are present in the monitoring device 2 form sufficient monitoring under the condition of improving the internal rotating structure, that is, the monitoring device 2 can change the structure of the monitoring device and apply the structure to the same other new energy generator main bodies 1.

The monitoring device 2 is mainly divided into an upper monitoring disc 201 and a lower monitoring disc 202, the upper monitoring disc 201 can be installed on the straight cylinder 101 according to an inner fixing ring 204 and a fixing hole 205, the upper monitoring disc 201 mainly controls a synchronous belt and a pinion to drive a sliding track 203 according to a driving motor and an inner receiving module, the sliding track 203 drives a sliding block 4 to circularly rotate on the circular sliding track 203, and a monitoring module 5 contained in the sliding block 4 can further form a 360-degree monitoring effect aiming at an easy-to-generate point of the generator main body 1;

the sliding block 4 is mainly supported by the conical barrel 401, the supporting rod 404 is driven by the electric steering engine 403 to swing back and forth by the driving of the groove barrel 402 and the electric steering engine 403, the monitoring module 5 can swing back and forth at the same time, finally the infrared thermal imaging camera 501 can monitor the vertical angle formed by the upper and lower angles aiming at the heating point, meanwhile, the infrared sensing camera 502 forms the ranging change according to the strip-shaped block 3 under the condition of adopting the infrared ranging camera, namely, under the condition that the sliding track 203 and the straight barrel 101 are in the same ring shape, the distance of the infrared ranging camera when ranging to the straight barrel 101 is longer, and the sliding block is shorter when ranging to the strip-shaped block 3, the rotating angle under the condition of uniform speed of 4 can be judged, when the shorter distance of the strip-shaped block 3 is monitored, the monitoring module 5 sends a pulse signal to the receiving module according to the PWM module to record the number of the strip-shaped blocks 3, therefore, the heating temperatures corresponding to different angles are recorded, the receiving module can send corresponding messages to the connected terminals according to the wireless connection module contained in the receiving module after receiving, the effect of monitoring the temperatures in a real-time and multi-range mode is achieved, and the target area with large heating amount can be traced according to data.

The lower monitoring disc 202 is mainly communicated with the inside of the straight cylinder 101, after water enters from the water inlet 105, the vertical rotating rod 6 rotates according to the internal structure of the straight cylinder 101 to generate power, and because the water flow can not be accurately controlled, the rotating speed of the vertical rotating rod 6 changes due to the water flow, because the lower monitoring disc 202 is mainly provided with a rotating disc 602, a fixed gear 604 and an outer gear ring 606 structure to form a planetary gear structure, the vertical rotating rod 6 is connected to the rotating disc 602 by a coil rod 601 to form an internal integral rotating structure, when the speed of the internal rotating disc 602 is higher, the damping structure of the outer gear ring 606 can further reduce the rotating speed of the vertical rotating rod 6, when the speed of the rotating disc 602 is lower, because the wind power at the hydraulic power generation part is usually higher, the fan blades 607 can drive the outer gear ring 606 to increase the internal rotating speed compared with the internal low-speed, the rotating speed of the vertical rotating rod 6 can be always kept to be a certain constant speed, so that stable voltage output is formed;

meanwhile, under the condition that the coil rod 601 rotates, the magnetic induction coil 603 and the coil on the surface of the coil rod 601 form a cutting magnetic induction line, the voltage generated correspondingly can be measured after the coil rod 601 is externally connected to the receiving module, and whether the rotation speed of the vertical rotating rod 6 is constant or not can be monitored according to the constant degree of the voltage, so that the power generation efficiency is monitored.

This device simple structure can use according to actual conditions direct mount under small-size water conservancy power generation equipment, also can carry out the institutional advancement according to current module under the middle-sized water conservancy new forms of energy power generation structure and form monitoring effect, and the monitoring data that obtains simultaneously is reliable, maintains simply, and the electronic equipment who involves is few, and consequently the fault rate is also lower.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. The utility model provides a new forms of energy generator monitoring facilities, includes generator main body (1), generator main body (1) includes straight section of thick bamboo (101), control module (102), ventilative net (103), base (104), water inlet (105) and adjusting device (106), its characterized in that, the mid-mounting of straight section of thick bamboo (101) has monitoring facilities (2), and its monitoring facilities (2) include and monitor dish (201) and lower monitoring dish (202), strip piece (3) are installed to the upside of monitoring facilities (2), the surface of going up monitoring dish (201) is provided with slip track (203), and the surface mounting of its slip track (203) has sliding block (4), solid fixed ring (204) is installed to the inboard of going up monitoring dish (201), and the surface mounting of solid fixed ring (204) has fixed orifices (205), the inboard of going up monitoring dish (201) includes driving motor and receiving module, a tapered cylinder (401) is installed at the bottom end of the sliding block (4), a groove cylinder (402) is installed at the top end of the tapered cylinder (401), an electric steering engine (403) is installed on the inner side of the groove cylinder (402), a supporting rod (404) is installed at the top end of the electric steering engine (403), a monitoring module (5) is installed at the top end of the supporting rod (404), an infrared thermal imaging camera (501) is installed on the surface of one side of the monitoring module (5), an infrared induction camera (502) is installed at the top end of the monitoring module (5), a vertical rotating rod (6) is installed in the middle of the inner side of the lower monitoring disc (202), a coil rod (601) is installed on the surface of the middle of the vertical rotating rod (6), a rotating disc (602) is installed on the outer side of the coil rod (601), and a magnet induction coil (603) is installed at the bottom end of the outer side of the rotating disc (602), the fixed gear (604) is installed at the top end of the outer side of the rotating disc (602), the fixing rod (605) is installed at the top end of the fixed gear (604), an outer gear ring (606) is installed on the surface of the outer side of the fixed gear (604), and fan blades (607) are installed on the surface of the outer gear ring (606).

2. The new energy generator monitoring device according to claim 1, wherein the control module (102) is electrically connected to the receiving module, the receiving module is electrically connected to the magnetic induction coil (603), the monitoring module (5) and the driving motor, and the receiving module comprises an MCU micro-control chip and a voltage sensor.

3. The new energy generator monitoring device according to claim 1, wherein the upper monitoring disc (201) and the straight cylinder (101) are fixedly connected through a fixing ring (204) and a fixing hole (205) by bolts, the inner wall of the upper monitoring disc (201) is smoothly arranged, the driving motor and the sliding rail (203) are in transmission connection, the sliding rail (203) is in a circular arc sliding rail structure, and the new energy generator monitoring device comprises a synchronous belt and a pinion structure.

4. The new energy generator monitoring device according to claim 3, wherein the sliding block (4) is in transmission connection with the sliding track (203), the tapered cylinder (401) is in fixed connection with the groove cylinder (402), the groove cylinder (402) is in fixed connection with the electric steering engine (403), the electric steering engine (403) is in transmission connection with the supporting rod (404), and the supporting rod (404) is in fixed connection with the monitoring module (5).

5. The new energy generator monitoring device according to claim 4, wherein the infrared thermal imaging camera (501) is perpendicular to the surface of the straight cylinder (101), the infrared sensing camera (502) is one of an infrared distance measurement camera or an infrared laser camera, the monitoring module (5) further comprises a PWM module, and the outer side surface of the strip-shaped block (3) is mirror-surface-arranged.

6. The new energy generator monitoring device as claimed in claim 1, wherein the vertical rotating rod (6) and the rotating disk (602) are fixedly connected through a coil rod (601), the lower monitoring disk (202) thereof penetrates to the inner side of the straight cylinder (101), the vertical rotating rod (6) is part of the inner structure of the straight cylinder (101), the rotating disk (602) and the outer gear ring (606) are in meshing connection through a fixed gear (604), the inner walls of the rotating disk (602) and the lower monitoring disk (202) are in movable connection with each other through a bearing, the fixed gear (604) and the lower monitoring disk (202) are fixedly connected through a fixed rod (605), the fixed rod (605) thereof is in rectangular structure, the outer gear ring (606) and the fan blades (607) thereof are fixedly connected, and the fan blades (607) thereof penetrate through the lower monitoring disk to the surface thereof.

7. The new energy generator monitoring device according to claim 6, wherein strong magnets are arranged inside the magnet induction ring (603), the strong magnets are arranged at two ends of the magnet induction ring (603), and the magnet induction ring (603) is fixedly connected with the lower monitoring disc (202).

Images