CN114674394A

CN114674394A - Water level monitoring device and system for uploading full-time data

Info

Publication number: CN114674394A
Application number: CN202210315178.XA
Authority: CN
Inventors: 商晓明
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-03-29
Filing date: 2022-03-29
Publication date: 2022-06-28

Abstract

The utility model relates to the field of water level monitoring devices, in particular to a water level monitoring device and a water level monitoring system capable of uploading full-time data, which comprise a signal acquisition unit, a data acquisition unit and a data transmission unit, wherein the signal acquisition unit is used for detecting a water level signal; the signal processing unit is connected to the signal acquisition unit and used for generating a water level state sending instruction according to the water level signal detected by the signal acquisition unit; and the signal sending unit is connected to the signal processing unit and used for sending a water level change signal according to the water level state sending instruction generated by the signal processing unit. The signal processing module can generate a water level state display instruction according to the water level change signal received by the signal receiving module, and the instruction instructs the state demonstration module to display the state of the water level change in an image mode, so that a worker can more easily vividly and accurately master the state of the water level change through the displayed image, the worker can effectively construct and maintain the wind generating set which is not influenced by the water level or is slightly influenced by the water level, and the operation efficiency is improved.

Description

Water level monitoring device and system for uploading full-time data

Technical Field

The utility model relates to the field of water level monitoring devices, in particular to a water level monitoring device and a water level monitoring system capable of uploading full-time data.

Background

In the intertidal zone between the open sea and the land, when the wind power project is built and maintained, the wind power project is influenced by the tide, so that the change of the tide is accurately forecasted and mastered, and the method is very important for the field work arrangement of the intertidal zone project and the improvement of the work efficiency.

The existing water level change monitoring system is shown in fig. 1, and comprises a signal acquisition unit, a signal processing unit and a signal sending unit which are electrically connected in sequence; the signal acquisition unit is arranged on a wind generating set positioned in an intertidal zone and used for detecting a water level signal, the signal processing unit is used for generating a water level state sending instruction according to the water level signal detected by the signal acquisition unit, the signal sending unit sends a water level change signal according to the water level state sending instruction generated by the signal processing unit, and the water level change signal can reflect the change condition of tide and is sent to a mobile terminal (such as a mobile phone) in the form of short message and voice by means of a wireless communication network.

When the water level change monitoring system is used, a mobile terminal in a signal blind area may not normally receive signals due to the signal blind area of a wireless communication network; or, because the mobile terminal is dead or damaged, the mobile terminal cannot normally receive signals, so that workers cannot build and maintain the wind power project in time, the operation efficiency is reduced, and the existing water level monitoring equipment lacks a mechanism for switching into a protection state in severe weather (such as hurricane and tsunami), so that the monitoring device is easily damaged in such environments.

Disclosure of Invention

The utility model provides a water level monitoring devices and system that full-time data was uploaded, the device can in time be under construction and maintenance to letting the staff to the wind-powered electricity generation project, can let monitoring devices turn into the protection state under bad weather and avoid being damaged.

A water level monitoring device for uploading data in full time comprises a device main body, wherein a rotating base is movably mounted in the device main body, a supporting column is movably mounted in the rotating base, a wind speed monitor is fixedly mounted at the top end of the supporting column, a temperature monitor and a solar panel are mounted on the outer side of the upper end of the supporting column, a connecting arm is movably mounted at the upper end of the supporting column, a water level monitor is fixedly mounted at the outer end of the connecting arm, a sliding rod is fixedly mounted on the outer side of the middle end of the supporting column, a first sliding block is movably mounted on the outer side of the sliding rod, a first connecting rod is hinged to the outer end of the first sliding block, a third connecting rod is hinged to the lower end of the first sliding block, a second sliding block is movably mounted at the lower end in the rotating base, a screw rod is fixedly mounted at the lower end in the rotating base, the second sliding block is sleeved on the outer side of the screw rod, a transmission gear is movably mounted at the left end of the outer side of the rotating base, the articulated second connecting rod that is connected with in second slider upper end, second connecting rod upper end is articulated mutually with the support column outside, rotating base left side middle-end movable mounting has the drive division, drive division one end fixedly connected with driving motor, drive division outside fixed mounting has the drive tooth, drive tooth and drive gear looks interlock, the inside movable mounting of drive division has the fixture block, inside the drive division is worn out to fixture block one end, the inboard position movable mounting who corresponds with the drive division of rotating base has the ejector pin, the ejector pin lower extreme downwardly extending to the rotating base bottom.

Preferably, the upper end of the first connecting rod is hinged to the lower side of the connecting arm, the connecting arm is hinged to the supporting column, and the three connecting rods are hinged to the inner side of the rotating base.

Preferably, one end of the screw rod penetrates through the inside of the rotating base, gear teeth are arranged on the outer side of one end of the screw rod, and the gear teeth on the outer side of the screw rod are meshed with the transmission gear.

Preferably, an opening is formed in one side, facing the ejector rod, of the driving portion, one end, corresponding to the ejector rod, of the clamping block is obliquely arranged, and a clamping groove is formed in the rotating base and corresponds to the outer side of the driving portion.

A water level monitoring system with full-time data uploading comprises a signal acquisition unit, a data acquisition unit and a data transmission unit, wherein the signal acquisition unit is used for detecting a water level signal; the signal processing unit is connected to the signal acquisition unit and used for generating a water level state sending instruction according to the water level signal detected by the signal acquisition unit; and a signal sending unit connected to the signal processing unit for sending a water level change signal according to the water level state sending instruction generated by the signal processing unit, wherein the system further comprises:

the signal receiving module is used for receiving the water level change signal sent by the signal sending unit;

the signal processing module is connected to the signal receiving module and used for generating a water level state display instruction according to the water level change signal received by the signal receiving module;

and the state demonstration module is connected to the signal processing module and is used for displaying the state of the water level change according to the water level state display instruction generated by the signal processing module.

Preferably, the signal acquisition unit, the signal processing unit and the signal sending unit form a signal module, and the system comprises a plurality of signal modules;

the signal receiving module is also used for receiving the water level change signals sent by the signal sending units in each signal module; the signal processing module is further used for generating a water level state display instruction according to the water level change signals, received by the signal receiving module, corresponding to each signal module; and the state demonstration module is also used for displaying the state of the water level change of each signal module according to the water level state display instruction which is generated by the signal processing module and corresponds to each signal module.

Preferably, the signal processing unit is electrically connected with an operation detection unit, and is used for detecting the operation condition of the wind generating set in the intertidal zone and sending the obtained operation state signal to the signal processing unit;

the signal processing unit is also used for sending an operation state sending instruction to the signal sending unit according to the received operation state signal;

the signal sending unit is further used for sending a corresponding unit running state signal to the signal receiving module according to the received running state sending instruction;

the signal receiving module is also used for receiving the unit running state signal sent by the signal sending unit;

the signal processing module is also used for generating an operating state display instruction according to the unit operating state signal received by the signal receiving module;

and the state demonstration module is also used for displaying the image of the running state of the unit according to the running state display instruction generated by the signal processing module.

Preferably, the system further comprises a temperature sensor electrically connected with the signal processing unit, and the temperature sensor is used for detecting the temperature of the environment where the wind generating set located in the intertidal zone is located and sending an obtained temperature signal to the signal processing unit;

the signal processing unit is also used for sending a temperature state sending instruction to the signal sending unit according to the received temperature signal;

the signal sending unit is further used for sending a corresponding unit temperature signal to the signal receiving module according to the received temperature state sending instruction;

the signal receiving module is also used for receiving the unit temperature signal sent by the signal sending unit;

the signal processing module is also used for generating a temperature state display instruction according to the unit temperature signal received by the signal receiving module;

and the state demonstration module is also used for displaying images of the temperature of the environment where the unit is located according to the temperature state display instruction generated by the signal processing module.

Preferably, the wind speed sensor is electrically connected with the signal processing unit and is used for detecting the wind speed of the environment where the wind generating set located in the intertidal zone is located and sending the obtained wind speed signal to the signal processing unit;

the signal processing unit is also used for sending a wind speed state sending instruction to the signal sending unit according to the received wind speed signal;

the signal sending unit is also used for sending a corresponding unit wind speed signal to the signal receiving module according to the received wind speed state sending instruction;

the signal receiving module is also used for receiving the unit wind speed signal sent by the signal sending unit;

the signal processing module is also used for generating a wind speed state display instruction according to the unit wind speed signal received by the signal receiving module;

and the state demonstration module is also used for displaying images of the wind speed of the environment where the unit is located according to the wind speed state display instruction generated by the signal processing module.

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

1. the signal acquisition unit is used for detecting a water level signal; the signal processing unit can generate a corresponding water level state sending instruction according to the water level signal detected by the signal acquisition unit; the signal sending unit can send a corresponding water level change signal according to the water level state sending instruction; the signal receiving module can receive the water level change signal sent by the signal sending unit; the signal processing module can generate a water level state display instruction according to the water level change signal received by the signal receiving module, and the instruction instructs the state demonstration module to display the image of the water level change state; therefore, the water level change signal and the water level change state correspond to each other, if the water level change signal is obtained when tide rises, the displayed water level change state is tide rise, and vice versa, so that a worker can more easily, vividly and accurately master the water level change state through the displayed image, the worker can effectively construct and maintain the wind generating set which is not influenced by the water level or is slightly influenced by the water level, and the operation efficiency is improved.

2. The device is characterized in that a rotating base is movably arranged in a main body, a support column is movably arranged in the rotating base, a wind speed monitor is fixedly arranged at the top end of the support column, a temperature monitor and a solar panel are arranged on the outer side of the upper end of the support column, the solar panel can absorb solar energy and convert the solar energy into electric energy, when power is supplied to various equipment, a connecting arm is movably arranged at the upper end of the support column, a water level monitor is fixedly arranged at the outer end of the connecting arm, when any one of the monitored data of the wind speed monitor and the water level monitor exceeds a preset numerical value of a system, a driving motor can be started to be communicated with a power supply to run, a second slide block is movably arranged at the lower end in the rotating base, a screw rod is fixedly arranged at the lower end in the rotating base, the second slide block is sleeved on the outer side of the screw rod, a transmission gear is movably arranged at the left end of the outer side of the rotating base, so that the driving motor drives a driving tooth outside a driving part to rotate, just can drive the teeth of a cogwheel of drive gear and screw rod outer end rotatory to let the screw rod drive the second slider and move to the left at its outside, rethread second slider upper end is articulated to be connected with the second connecting rod, second connecting rod upper end is articulated mutually with the support column outside, makes and just can let the second connecting rod take the support column bottom rotatory, with inside wind speed monitor, the temperature monitor income rotating base of its upper end, reach the effect of avoiding equipment to damage under outside bad weather.

3. Through support column middle-end outside fixed mounting there is the slide bar, slide bar outside movable mounting has first slider, first slider outer end articulates and is connected with the head rod, the first slider lower extreme articulates there is three connecting rods, head rod upper end is articulated with the linking arm downside, the linking arm is articulated mutually with the support column, three connecting rods are connected through articulating with the rotating base is inboard, make when the support column rotates and pours into the inside back of rotating base, first slider can slide down in the slide bar outside under the pulling of three connecting rods, make the head rod drive the linking arm rotatory in the support column outside, thereby reach and also take in the inside effect of rotating base with water level monitor.

4. Through the inside movable mounting of drive division there is the fixture block, inside the drive division is worn out to fixture block one end, the inboard position movable mounting that corresponds with the drive division of rotating base has the ejector pin, ejector pin lower extreme downwardly extending to rotating base bottom, then work as along with bracing piece and linking arm all take in inside the rotating base, the second slider also moves left end ejector pin and contacts, be provided with the opening towards one side of ejector pin through the drive division, the fixture block sets up for the slope with the one end that the ejector pin corresponds, the draw-in groove has been seted up in the inside outside that corresponds the drive division of rotating base, make along with the removal of second slider, can order about the ejector pin upper end and get into inside the drive division, thereby utilize the inclined plane of fixture block to order about the fixture block and outwards remove inside getting into the draw-in groove, thereby reach and drive rotating base and rotate 180 with the upper end opening and rotate the lower extreme, thereby further avoid outside weather to damage monitoring facilities.

Drawings

FIG. 1 is a block diagram of a prior art water level change monitoring system;

FIG. 2 is a block diagram of a water level change monitoring system according to the present invention;

FIG. 3 is a block diagram of another water level change monitoring system according to the present invention;

FIG. 4 is a block diagram of another water level change monitoring system according to the present invention;

FIG. 5 is a state diagram of the state demonstration module of FIG. 2 according to the present invention;

FIG. 6 is a perspective view of the device body of the present invention;

FIG. 7 is a perspective view of the interior of the body of the device of the present invention;

FIG. 8 is an enlarged view taken at A of FIG. 7 in accordance with the present invention;

FIG. 9 is an enlarged view taken at B of FIG. 7 in accordance with the present invention;

FIG. 10 is a side view of the swivel base of the present invention;

fig. 11 is a sectional view of a driving part of the present invention.

In FIGS. 1-11: 1-device main body, 2-support column, 3-wind speed monitor, 4-temperature monitor, 5-water level monitor, 6-connecting arm, 7-first connecting rod, 8-first sliding block, 9-sliding rod, 10-second connecting rod, 11-three connecting rod, 12-solar panel, 13-rotating base, 14-second sliding block, 15-screw rod, 16-transmission gear, 17-driving part, 18-clamping block, 19-top rod, 20-driving tooth and 21-clamping groove.

Detailed Description

Referring to fig. 1 to 11, a schematic plan structure diagram and a schematic perspective structure diagram of a water level monitoring device and system for uploading full-time data are shown.

A water level monitoring device for uploading data in full time comprises a device main body 1, a rotating base 13 is movably arranged in the device main body 1, a supporting column 2 is movably arranged in the rotating base 13, a wind speed monitor 3 is fixedly arranged at the top end of the supporting column 2, a temperature monitor 4 and a solar panel 12 are arranged on the outer side of the upper end of the supporting column 2, a connecting arm 6 is movably arranged at the upper end of the supporting column 2, a water level monitor 5 is fixedly arranged at the outer end of the connecting arm 6, a sliding rod 9 is fixedly arranged on the outer side of the middle end of the supporting column 2, a first sliding block 8 is movably arranged on the outer side of the sliding rod 9, a first connecting rod 7 is hinged at the outer end of the first sliding block 8, a third connecting rod 11 is hinged at the lower end of the first sliding block 8, a second sliding block 14 is movably arranged at the lower end of the inner part of the rotating base 13, a screw rod 15 is fixedly arranged at the lower end of the inner part of the rotating base 13, and the second sliding block 14 is sleeved on the outer side of the screw rod 15, the left end movable mounting in the rotating base 13 outside has drive gear 16, the articulated second connecting rod 10 that is connected with in second slider 14 upper end, second connecting rod 10 upper end is articulated mutually with the 2 outsides of support column, rotating base 13 left side middle-end movable mounting has drive portion 17, drive portion 17 one end fixedly connected with driving motor, drive portion 17 outside fixed mounting has drive tooth 20, drive tooth 20 and drive gear 16 interlock mutually, drive portion 17 inside movable mounting has fixture block 18, inside fixture block 18 one end was worn out drive portion 17, the inboard position movable mounting who corresponds with drive portion 17 of rotating base 13 has ejector pin 19, the lower extreme downwardly extending of ejector pin 19 reaches rotating base 13 bottom.

In concrete real-time, head rod 7 upper end is articulated with 6 downside of linking arm, linking arm 6 is articulated mutually with support column 2, three connecting rods 11 are connected through articulated with 13 inboards of rotating base, make when support column 2 rotate pour rotating base 13 inside back, first slider 8 can slide downwards in the slide bar 9 outside under the pulling of three connecting rods 11, make head rod 7 drive linking arm 6 rotatory in the 2 outsides of support column, thereby reach and also take in the inside effect of rotating base 13 with water level monitor 5.

In real time, one end of the screw rod 15 penetrates through the inside of the rotating base 13, gear teeth are arranged on the outer side of one end of the screw rod 15, the gear teeth on the outer side of the screw rod 15 are connected with the transmission gear 16 in an occlusion mode, so that after the driving motor drives the driving teeth 20 on the outer portion of the driving portion 17 to rotate, the transmission gear 16 and the gear teeth on the outer end of the screw rod 15 can be driven to rotate, the screw rod 15 drives the second sliding block 14 to move to the left on the outer side of the second sliding block, the upper end of the second sliding block 14 is hinged to the second connecting rod 10, the upper end of the second connecting rod 10 is hinged to the outer side of the supporting column 2, the second connecting rod 10 can drive the bottom of the supporting column 2 to rotate, the wind speed monitor 3 and the temperature monitor 4 on the upper end of the second connecting rod are collected into the rotating base 13, and the effect of avoiding the damage of the equipment under the external severe weather is achieved.

In concrete real-time, one side that drive division 17 was provided with the opening towards ejector pin 19, the one end that fixture block 18 and ejector pin 19 correspond sets up for the slope, draw-in groove 21 has been seted up in the inside outside that corresponds drive division 17 of rotating base 13, make along with the removal of second slider 14, can order about ejector pin 19 upper end and get into inside the drive division 17, thereby utilize the inclined plane of fixture block 18 to order about fixture block 18 inside outwards moving gets into draw-in groove 21, thereby reach and drive rotating base 13 rotatory 180 and rotate the lower extreme with the upper end opening, thereby further avoid outside weather to damage monitoring facilities.

In specific implementation, the signal acquisition unit is used for detecting a water level signal; the signal processing unit can generate a corresponding water level state sending instruction according to the water level signal detected by the signal acquisition unit; the signal sending unit can send a corresponding water level change signal according to the water level state sending instruction; the signal receiving module can receive the water level change signal sent by the signal sending unit; the signal processing module can generate a water level state display instruction according to the water level change signal received by the signal receiving module, and the instruction instructs the state demonstration module to display the image of the water level change state; therefore, the water level change signal and the water level change state correspond to each other, if the water level change signal is obtained when tide rises, the displayed water level change state is tide rise, and vice versa, so that a worker can more easily, vividly and accurately master the water level change state through the displayed image, the worker can effectively construct and maintain the wind generating set which is not influenced by the water level or is slightly influenced by the water level, and the operation efficiency is improved.

The operation of the water level change monitoring system will be described in detail with reference to fig. 2.

The signal acquisition unit is arranged on a wind generating set positioned in an intertidal zone and used for detecting a water level signal, and the signal processing unit can generate a corresponding water level state sending instruction according to the water level signal detected by the signal acquisition unit; the signal sending unit can send a corresponding water level change signal according to the water level state sending instruction; the signal receiving module can receive the water level change signal sent by the signal sending unit; the signal processing module can generate a water level state display instruction according to the water level change signal received by the signal receiving module, and the instruction instructs the state demonstration module to display the image of the water level change state.

It should be noted that: in fig. 2, the signal sending unit and the signal receiving module are connected by a line segment, which only indicates that there is signal transmission between the two units and does not indicate the electrical connection relationship between the signal sending unit and the signal receiving module.

The water level change monitoring system described in the above embodiment may further include a mobile terminal such as a mobile phone, and fig. 3 is added with the mobile terminal on the basis of fig. 2, where the mobile terminal is configured to receive and display the water level change signal sent by the signal sending unit, such as a short message and/or a voice. Because the mobile terminal is convenient for the staff to carry, the water level change signal can be provided for the staff at any time.

In the water level change monitoring system described in the above embodiment, the connection mode between the signal receiving module and the signal sending unit may be wired connection or wireless connection. The wired connection usually adopts a direct electrical connection mode, such as the internet, laying an optical cable or a local area network cable, the wireless connection usually uses a wireless communication network, such as a global communication network, a mobile network and a communication network, and the specific connection mode can be selected according to actual needs.

In the water level change monitoring system described in the above embodiment, the signal acquisition unit, the signal processing unit, and the signal transmission unit form a signal module not shown in the figure, and the system may include a plurality of signal modules; the signal receiving module is also used for receiving the water level change signals sent by the signal sending units in each signal module; the signal processing module is also used for generating a water level state display instruction according to the water level change signals corresponding to each signal module received by the signal receiving module; the state demonstration module is also used for carrying out image display on the state of the water level change of each signal module according to the water level state display instruction which is generated by the signal processing module and corresponds to each signal module

As shown in fig. 5, the arabic numerals in the figure represent machine position numbers of each wind turbine generator set in the intertidal zone, for example, numeral 12 represents machine position No. 12, the displayed image represents that the tidal water is not in the machine position state, numeral 13 represents machine position No. 13, and the displayed image represents that the tidal water reaches the machine position state; by way of example: a water level change signal sent by a signal sending unit in a signal module corresponding to the machine position No. 12 is collected when the tide water does not reach the machine position, a water level state display instruction carrying machine position information 12 is generated after the tide water is processed by a signal processing module, and an image of the tide water not reaching the machine position state is displayed at a position corresponding to the machine position No. 12 on a state demonstration module; the water level change signal sent by the signal sending unit in the signal module corresponding to the machine position No. 13 is collected when the tide reaches the machine position, and then after the tide is processed by the signal processing module, a water level state display instruction carrying machine position information 13 is generated, and an image of the tide reaching the machine position state is displayed at a position corresponding to the serial number of the machine position No. 13 on the state demonstration module; therefore, the staff can vividly and accurately master the state of the water level change of each machine position through the images, so that the staff can effectively construct and maintain the wind generating set which is not influenced by the water level or is slightly influenced by the water level.

In the water level change monitoring system described in the above embodiment, the state demonstration module may be a display screen or an indicator light, and the display screen or the indicator light is easy to accurately and vividly display the state of the water level change.

The water level change monitoring system described in the above embodiment may further include a main control cabinet, and the signal processing unit and the signal transmitting unit are disposed in the main control cabinet; the main control cabinet is arranged in or outside a tower of the wind generating set positioned in the intertidal zone so as to conveniently carry out centralized management on the signal processing unit and the signal sending unit.

In the water level change monitoring system described in the above embodiment, the signal acquisition unit may be a float switch or an ultrasonic sensor, so as to accurately measure the water level.

The float switch is in a normally open state when no water exists, is in a closed state when water exists, generates voltage after being closed, and the signal processing unit judges water level change according to the existence of the voltage and sends a water level state sending instruction to the signal sending unit according to a judgment result.

The ultrasonic sensor has long ultrasonic reflection time when water exists, generates pulse signals corresponding to the tide signals, the signal processing unit judges the water level change according to different pulse signals, and sends a water level state sending instruction to the signal sending unit according to the judgment result.

The water level change monitoring system described in the above embodiment may further include an operation detection unit electrically connected to the signal processing unit. Fig. 4 is added with an operation detection unit on the basis of fig. 3, and the operation detection unit is used for detecting the operation condition of the wind generating set located in the intertidal zone, such as fault information, and sending the obtained operation state signal to the signal processing unit.

The signal processing unit is also used for sending an operation state sending instruction to the signal sending unit according to the received operation state signal; the signal sending unit is also used for sending a corresponding unit running state signal to the signal receiving module according to the received running state sending instruction; the signal receiving module is also used for receiving the unit running state signal sent by the signal sending unit; the signal processing module is also used for generating an operating state display instruction according to the unit operating state signal received by the signal receiving module; and the state demonstration module is also used for displaying the image of the running state of the unit according to the running state display instruction generated by the signal processing module.

The operation of the water level change monitoring system with the operation detection unit will be described in detail with reference to fig. 4.

The operation detection unit sends the detected operation state signal of the wind generating set to the signal processing unit, and the signal processing unit sends an operation state sending instruction to the signal sending unit according to the received operation state signal; the signal sending unit sends a corresponding unit running state signal to the signal receiving module in a wireless or wired mode according to the received running state sending instruction; the signal receiving module receives the unit running state signal sent by the signal sending unit, the signal processing module generates a running state display instruction according to the unit running state signal received by the signal receiving module, and the state demonstration module displays the running state of the wind generating set according to the running state display instruction generated by the signal processing module.

The operation detection unit is arranged and used for detecting the operation state of the wind generating set, so that a worker can accurately and visually master the operation condition of the wind generating set in the intertidal zone, and the normal operation of the wind generating set is ensured.

As shown in fig. 4, the water level change monitoring system described in the above embodiment may further include a temperature sensor electrically connected to the signal processing unit, and configured to detect a temperature of an environment in which the wind turbine generator set located in the intertidal zone is located, and send an obtained temperature signal to the signal processing unit.

The signal processing unit is also used for sending a temperature state sending instruction to the signal sending unit according to the received temperature signal; the signal sending unit is also used for sending a corresponding unit temperature signal to the signal receiving module according to the received temperature state sending instruction; the signal receiving module is also used for receiving the unit temperature signal sent by the signal sending unit; the signal processing module is also used for generating a temperature state display instruction according to the unit temperature signal received by the signal receiving module; the state demonstration module is also used for displaying images of the temperature of the environment where the unit is located according to the temperature state display instruction generated by the signal processing module.

The operation of the water level variation monitoring system with the wind speed sensor will be described in detail with reference to fig. 4.

The wind speed sensor sends a detected wind speed signal of the environment where the wind driven generator unit is located to the signal processing unit, and the signal processing unit sends a wind speed state sending instruction to the signal sending unit according to the received wind speed signal; the signal sending unit sends a corresponding unit wind speed signal to the signal receiving module in a wireless or wired mode according to the received wind speed state sending instruction; the signal receiving module receives the unit wind speed signal sent by the signal sending unit; the signal processing module generates a wind speed state display instruction according to the unit wind speed signal received by the signal receiving module; and the state demonstration module is used for displaying images of the wind speed of the environment where the wind generating set is located according to the wind speed state display instruction generated by the signal processing module.

Due to the fact that the wind speed sensor is arranged and used for detecting the wind speed of the environment where the wind generating set is located, workers can accurately and visually master the wind speed situation of the environment where the wind generating set is located in the intertidal zone, and whether the workers need to be arranged to build and maintain the wind generating set or not can be determined.

The wind speed sensor is a device for converting the air flow speed into electric signals with a certain corresponding relation, and the signal processing unit can generate corresponding wind speed state display instructions according to different electric signals.

In addition, the water level change monitoring system described in the embodiment of the utility model can be used for not only tidal prediction of intertidal zone projects, but also tidal monitoring of rivers, lakes, seas and reservoirs

The working principle of the water level monitoring device and the water level monitoring system for uploading full-time data is as follows.

Firstly, a signal acquisition unit is used for detecting a water level signal; the signal processing unit can generate a corresponding water level state sending instruction according to the water level signal detected by the signal acquisition unit; the signal sending unit can send a corresponding water level change signal according to the water level state sending instruction; the signal receiving module can receive the water level change signal sent by the signal sending unit; the signal processing module can generate a water level state display instruction according to the water level change signal received by the signal receiving module, and the instruction instructs the state demonstration module to display the image of the water level change state; therefore, the water level change signal and the water level change state are corresponding to each other, if the water level change signal is obtained when tide rises, the displayed water level change state is tide rises, and vice versa, so that a worker can more easily, vividly and accurately master the water level change state through a displayed image, so that the construction and maintenance of a wind generating set which is not influenced by the water level or is less influenced by the water level can be effectively organized, the operation efficiency is improved, then, a rotating base 13 is movably arranged in the device main body 1, a supporting column 2 is movably arranged in the rotating base 13, a wind speed monitor 3 is fixedly arranged at the top end of the supporting column 2, a temperature monitor 4 and a solar panel 12 are arranged on the outer side of the upper end of the supporting column 2, the solar panel 12 can absorb solar energy and then convert the solar energy into electric energy, electric power is provided for various devices, and meanwhile, a connecting arm 6 is movably arranged at the upper end of the supporting column 2, the outer end of the connecting arm 6 is fixedly provided with the water level monitor 5, when the data monitored by any one of the wind speed monitor 3 and the water level monitor 5 exceeds a preset value of the system, the driving motor can be started to be communicated with the power supply to run, a second slide block 14 is movably arranged at the lower end inside the rotating base 13, a screw rod 15 is fixedly arranged at the lower end inside the rotating base 13, the second slide block 14 is sleeved outside the screw rod 15, a transmission gear 16 is movably arranged at the left end outside the rotating base 13, so that the driving motor drives a driving gear 20 outside the driving part 17 to rotate, the transmission gear 16 and the gear teeth at the outer end of the screw rod 15 can be driven to rotate, the screw rod 15 drives the second slide block 14 to move to the left side outside the driving gear teeth, the upper end of the second slide block 14 is hinged and connected with a second connecting rod 10, the upper end of the second connecting rod 10 is hinged with the outer side of the supporting column 2, so that the second connecting rod 10 can drive the bottom of the supporting column 2 to rotate, the wind speed monitor 3 and the temperature monitor 4 at the upper ends of the wind speed monitor and the temperature monitor are collected into the rotating base 13 to achieve the effect of avoiding the damage of the equipment under the severe weather outside, then a sliding rod 9 is fixedly installed on the outer side of the middle end of the supporting column 2, a first sliding block 8 is movably installed on the outer side of the sliding rod 9, the outer end of the first sliding block 8 is hinged with a first connecting rod 7, the lower end of the first sliding block 8 is hinged with three connecting rods 11, the upper end of the first connecting rod 7 is hinged with the lower side of a connecting arm 6, the connecting arm 6 is hinged with the supporting column 2, the three connecting rods 11 are hinged with the inner side of the rotating base 13, so that after the supporting column 2 is rotated and poured into the rotating base 13, the first sliding block 8 can slide downwards on the outer side of the sliding rod 9 under the pulling of the three connecting rods 11, the first connecting rod 7 drives the connecting arm 6 to rotate on the outer side of the supporting column 2, and the effect of collecting the water level monitor 5 into the rotating base 13 is achieved, finally, a clamping block 18 is movably arranged in the driving part 17, one end of the clamping block 18 penetrates out of the driving part 17, a top rod 19 is movably arranged at a position, corresponding to the driving part 17, on the inner side of the rotating base 13, a bottom end of the top rod 19 extends downwards to the bottom of the rotating base 13, when the supporting rod 2 and the connecting arm 6 are both taken in the rotating base 13, the second sliding block 14 also moves to the left end to be contacted with the top rod 19, an opening is arranged at one side, facing the top rod 19, of the driving part 17, an end, corresponding to the top rod 19, of the clamping block 18 is obliquely arranged, a clamping groove 21 is formed in the rotating base 13, corresponding to the outer side of the driving part 17, so that the upper end of the top rod 19 can be driven to enter the driving part 17 along with the movement of the second sliding block 14, the clamping block 18 is driven to move outwards to enter the clamping groove 21 by utilizing the inclined plane of the clamping block 18, and the purpose of driving the rotating base 13 to rotate 180 degrees to rotate the opening at the upper end to the lower end, thereby further avoiding damage to the monitoring device from external weather.

Claims

1. A water level monitoring system capable of uploading full-time data comprises a device main body (1), a wind speed monitor (3), a temperature monitor (4) and a water level monitor (5), wherein signal acquisition units are arranged inside the wind speed monitor (3), the temperature monitor (4) and the water level monitor (5) and used for detecting water level signals, temperature signals and wind speed signals; the signal processing unit is connected to the signal acquisition unit and used for generating a water level state sending instruction according to the water level signal detected by the signal acquisition unit; and a signal sending unit connected to the signal processing unit for sending a water level change signal according to the water level state sending instruction generated by the signal processing unit, wherein the system further comprises:

2. The water level monitoring system for uploading full-time data as claimed in claim 1, wherein: the signal acquisition unit, the signal processing unit and the signal sending unit form a signal module, and the system comprises a plurality of signal modules;

the signal receiving module is also used for receiving a water level change signal sent by a signal sending unit in each signal module; the signal processing module is further used for generating a water level state display instruction according to the water level change signals, received by the signal receiving module, corresponding to each signal module; and the state demonstration module is also used for displaying the state of the water level change of each signal module according to the water level state display instruction which is generated by the signal processing module and corresponds to each signal module.

3. The water level monitoring system for uploading full-time data as claimed in claim 1, wherein: the signal processing unit is electrically connected with an operation detection unit and used for detecting the operation condition of the wind generating set positioned in an intertidal zone and sending the obtained operation state signal to the signal processing unit;

the signal processing module is also used for generating an operating state display instruction according to the unit operating state signal received by the signal receiving module

4. The water level monitoring system for uploading full-time data as claimed in claim 1, wherein: the temperature monitor (4) is used for detecting the temperature of the environment where the wind generating set located in the intertidal zone is located and sending the obtained temperature signal to the signal processing unit;

5. The water level monitoring system for uploading full-time data as claimed in claim 1, wherein: the wind speed monitor (3) is used for detecting the wind speed of the environment where the wind generating set located in an intertidal zone is located and sending an obtained wind speed signal to the signal processing unit;

6. The utility model provides a water level monitoring device that full-time data uploaded, includes device main part (1), its characterized in that: a rotating base (13) is arranged in the device main body (1), a supporting column (2) which can be rotatably received in the rotating base (13) is arranged at the upper end of the rotating base, the top end of the supporting column (2) is fixedly provided with a wind speed monitor (3), the outer side of the upper end of the supporting column (2) is provided with a temperature monitor (4) and a solar panel (12), a connecting arm (6) is arranged at the upper end of the supporting column (2), a water level monitor (5) is fixedly arranged at the outer end of the connecting arm (6), a sliding rod (9) is fixedly arranged on the outer side of the middle end of the supporting column (2), a first sliding block (8) is movably arranged on the outer side of the sliding rod (9), the outer end of the first sliding block (8) is connected with a first connecting rod (7), the lower end of the first sliding block (8) is connected with three connecting rods (11), and a second sliding block (14) is arranged inside the rotating base (13).

7. The water level monitoring device for uploading full-time data according to claim 6, wherein: the lower end in the rotating base (13) is provided with a screw rod (15), the second sliding block (14) is sleeved on the outer side of the screw rod (15), and the upper end of the second sliding block (14) is connected with a second connecting rod (10).

8. The water level monitoring device for uploading full-time data according to claim 6, wherein: rotating base (13) left side middle-end is provided with drive division (17), drive division (17) one end fixedly connected with driving motor, the drive division (17) outside is provided with drive tooth (20).

9. The water level monitoring device for uploading full-time data according to claim 8, wherein: a clamping block (18) is arranged in the driving portion (17), one end of the clamping block (18) penetrates out of the driving portion (17), and a push rod (19) is arranged on the inner side of the rotating base (13) and corresponds to the driving portion (17).

10. The water level monitoring device for uploading full-time data according to claim 9, wherein: one end of the clamping block (18) is obliquely arranged, and a clamping groove (21) is formed in the rotating base (13).