CN104406658A - Low-power-consumption online groundwater monitoring system and energy saving method - Google Patents

Abstract

The invention discloses a low-power-consumption online groundwater monitoring system and energy saving method. The system comprises a monitoring center, an integrated online monitoring machine for online monitoring of groundwater and an antenna, wherein the integrated online monitoring machine comprises a power supply, a sensor and a mainboard; circuits on the mainboard comprise an input power circuit, an input end of the input power circuit is connected with the power supply, an output end of the input power circuit is connected with one end of a battery detection circuit, a CPU and one end of an information processing module, and the other end of the battery detection circuit is connected with the CPU; the information processing module is connected with the CPU and used for processing data information of the groundwater which is collected by the sensor and acquired by the CPU through an interface circuit, and a communication network sends the data information to the monitoring center through the antenna, so that the labor cost is saved. In addition, the system uses one CUP is as a data center of the mainboard, so that one CPU and a plurality of circuit interfaces are omitted, sizes of circuit elements are reduced, and the power consumption is further reduced.

Description

A kind of underground water on-line monitoring system of low-power consumption and power-economizing method

Technical field

The application relates to groundwater monitoring technical field, particularly relates to a kind of underground water on-line monitoring system and power-economizing method of low-power consumption.

Background technology

Groundwater monitoring has multi-functionals such as measuring water level, pore pressure, perviousness and water sampling, can grasp dynamic change situation in time, thus carry out long-term protection to underground water, to meet the life requirement of people.

At present underground water on-line monitoring all-in-one is generally adopted to the monitoring of underground water, but, because current underground water on-line monitoring all-in-one can only play monitoring effect, then by staff data are carried out making a copy of and take back monitoring center and analyze, cause the waste of human resources, the problem of high cost.In addition, because the circuit component in current underground water on-line monitoring all-in-one is too much, so not only make the volume of all-in-one comparatively huge, and expend the energy in use procedure, in the face of day by day in short supply present of natural resources, current underground water on-line monitoring all-in-one cannot meet actual application demand.

Summary of the invention

In view of this, this application provides a kind of underground water on-line monitoring system and power-economizing method of low-power consumption, to overcome groundwater monitoring labor intensive of the prior art, and problem that is bulky, that expend the energy.

For achieving the above object, the application provides following technical scheme:

A underground water on-line monitoring system for low-power consumption, comprising: monitoring center and on-line monitoring all-in-one;

Described on-line monitoring all-in-one is used for underground water on-line monitoring, and carries out data communication with described monitoring center by described antenna;

The data message that described monitoring center is used for the underground water uploaded according to described on-line monitoring all-in-one carries out analyzing and processing;

Described on-line monitoring all-in-one comprises: power supply, sensor, antenna and the mainboard be simultaneously connected with described power supply, described sensor, described antenna;

Circuit on described mainboard comprises:

Input end is connected with described power supply, the input power circuit be connected with one end of message processing module with one end of battery detection circuit, CPU the while of output terminal;

The other end of described battery detection circuit is connected with described CPU;

Described message processing module is connected with described CPU, and the data message for the underground water collected by the described sensor that interface circuit obtains by described CPU is processed, and sends to described monitoring center by described antenna by communication network.

Preferably, the circuit on described mainboard also comprises: the display input circuit be connected with described CPU.

Preferably, also comprise: for encapsulating the waterproof case of described power supply.

Preferably, described sensor comprises: pressure type water level sensor and float water level sensor.

Preferably, described interface circuit comprises:

Be arranged at the power switch between described CPU and described pressure type water level sensor and interface circuit;

Be arranged at the switching value circuit between described CPU and described float water level sensor.

Preferably, also comprise: upper top is plastics, and other faces are the outer container of metal material;

Wherein, described power supply and described mainboard are arranged at the inside of described outer container, and described sensor setting is in the outside of described outer container.

Preferably, described CPU also comprises time block, for starting CPU according to the first predetermined period, to control the data message that described sensor gathers underground water;

The supply voltage of described data message and collection is preserved by described CPU, and carries out dormancy after the save is completed.

Preferably, described time block is also for starting CPU according to the second predetermined period;

What respond monitoring center after described CPU starts calls survey together, and the described data message preserve self and described supply voltage are sent to described monitoring center, and carry out dormancy after being sent completely.

A underground water on-line monitoring power-economizing method for low-power consumption, comprising:

CPU is according to the first predetermined period self-starting;

The data message of underground water is gathered at startup control sensor;

The supply voltage of described data message and collection is preserved;

Dormancy is carried out after preservation.

Also comprise, described CPU according to the second predetermined period self-starting, and upon actuation respond monitoring center call survey together, by self preserve described data message and described supply voltage be sent to described monitoring center;

Dormancy is carried out after being sent completely.

From above technical scheme, this application discloses a kind of underground water on-line monitoring system and power-economizing method of low-power consumption, comprising: monitoring center, on-line monitoring all-in-one and the antenna be installed on described on-line monitoring all-in-one; Described on-line monitoring all-in-one is used for underground water on-line monitoring, and carries out data communication with described monitoring center by described antenna; Described monitoring center is used for the groundwater monitoring data analysis process of uploading according to described on-line monitoring all-in-one; Described on-line monitoring all-in-one comprises: power supply, sensor and the mainboard be simultaneously connected with described power supply, described sensor; Circuit on described mainboard comprises: input end is connected with described power supply, the input power circuit be connected with one end of message processing module with one end of battery detection circuit, CPU the while of output terminal; The other end of described battery detection circuit is connected with described CPU; Described message processing module is connected with described CPU, and the data message for the underground water collected by the described sensor that interface circuit obtains by described CPU is processed, and sends to described monitoring center by antenna by communication network.This system is by the data center of use CPU as mainboard, and eliminate a CPU and multiple circuit interface, and save original clock circuit and reserce cell, thus circuit component is reduced at double, volume also reduces at double, further reduces power consumption.In addition, by message processing module, the underground water data message of sensor collection is sent to Surveillance center by antenna by communication network, has saved human cost.

Accompanying drawing explanation

In order to be illustrated more clearly in the embodiment of the present invention or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment or description of the prior art below, apparently, accompanying drawing in the following describes is only embodiments of the invention, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to the accompanying drawing provided.

The structural representation of the underground water on-line monitoring system of a kind of low-power consumption that Fig. 1 provides for the embodiment of the present application one;

Circuit diagram on a kind of mainboard that Fig. 2 provides for the embodiment of the present application one;

The structural representation of the underground water on-line monitoring system of a kind of low-power consumption that Fig. 3 provides for the embodiment of the present application two;

Circuit diagram on a kind of mainboard that Fig. 4 provides for the embodiment of the present application two;

Circuit diagram on the another kind of mainboard that Fig. 5 provides for the embodiment of the present application two;

The underground water on-line monitoring power-economizing method process flow diagram of a kind of low-power consumption that Fig. 6 provides for the embodiment of the present application three.

Embodiment

Below in conjunction with the accompanying drawing in the embodiment of the present invention, be clearly and completely described the technical scheme in the embodiment of the present invention, obviously, described embodiment is only the present invention's part embodiment, instead of whole embodiments.Based on the embodiment in the present invention, those of ordinary skill in the art, not making the every other embodiment obtained under creative work prerequisite, belong to the scope of protection of the invention.

For overcoming groundwater monitoring labor intensive of the prior art, and problem that is bulky, that expend the energy, this application provides a kind of underground water on-line monitoring system of low-power consumption, concrete scheme is as described below:

Embodiment one

The embodiment of the present application one provides a kind of underground water on-line monitoring system of low-power consumption, as shown in Figure 1, and the structural representation of the underground water on-line monitoring system of a kind of low-power consumption that Fig. 1 provides for the embodiment of the present application one.This system comprises: monitoring center 101, on-line monitoring all-in-one 102 and communication network 103, and on-line monitoring all-in-one 102 comprises: power supply 1021, mainboard 1022, sensor 1023 and antenna 1024.

Monitoring center 101 carries out analyzing and processing for the data message of the underground water uploaded according to on-line monitoring all-in-one, by obtaining the data message of the underground water that on-line monitoring all-in-one 102 is uploaded in time, thus realizes the real-time monitoring to underground water.

On-line monitoring all-in-one 102 for underground water on-line monitoring, and carries out data communication by antenna 1024 by communication network 103 with monitoring center 101.

As shown in Figure 2, the circuit diagram on a kind of mainboard of providing for the embodiment of the present application one of Fig. 2.Circuit on mainboard comprises:

Input end is connected with power supply, the input power circuit 202 be connected with one end of message processing module 204 with one end of battery detection circuit 203, CPU201 the while of output terminal.

The other end of battery detection circuit 203 is connected with CPU201, and wherein, battery detection circuit 203 is specially AD battery testing circuit.Battery detection circuit is for detecting voltage, and when voltage is less than 3V, equipment quits work, and only powers to internal clocking, other function Close All.

Message processing module 204 is connected with CPU201, and the data message of the underground water that the sensor for being obtained by CPU201 collects processes, and sends to monitoring center by antenna by communication network.

The application can also use message processing module 204 to carry out correcting time in network, eliminates the clock circuit in primary circuit and reserce cell further, makes reduction in bulk, and decrease the power consumption of clock circuit and interface circuit thereof.Wherein, message processing module 204 can be 2G mixed-media network modules mixed-media, and as GSM/GPRS module, can also be 3G network module or 4G mixed-media network modules mixed-media, this is not restricted, can environmentally require or actual needs sets.

In the application, all elements all adopt energy saving component, particularly use CPU instead energy-saving chip STM32L151VDT, by realize more than 60% energy-conservation.

From above technical scheme, the underground water on-line monitoring system of disclosed this kind of low-power consumption of the embodiment of the present application one, by using a CPU as the data center of mainboard, eliminate a CPU and multiple circuit interface, and save original clock circuit and reserce cell, thus making the circuit component minimizing at double in the on-line monitoring all-in-one in system, volume also reduces at double, further reduces power consumption.In addition, by using message processing module that the underground water data message of sensor collection is sent to Surveillance center by antenna by communication network, human cost has been saved.

Embodiment two

The embodiment of the present application two discloses a kind of underground water on-line monitoring system of low-power consumption, as shown in Figure 3, and the structural representation of the underground water on-line monitoring system of a kind of low-power consumption that Fig. 3 provides for the embodiment of the present application two.This system comprises: monitoring center 301, on-line monitoring all-in-one 302 and communication network 303, and on-line monitoring all-in-one 302 comprises: power supply 3021, mainboard 3022, sensor 3023, waterproof case 3024, outer container 3025 and antenna 3026.

Wherein, power supply 3021 is the lithium battery of the arbitrary value between 3.7V to 12V, comprises 3.7V and 12V.Due to the significantly reduction of energy consumption, the battery capacity therefore selected also can significantly reduce, in this application, 3.7V lithium electricity high density battery can be selected to reduce the volume of all-in-one further, certainly, do not limit in this application, also can be other forms of power supply, as dry cell etc.In the present embodiment, because power acquisition 3.7V lithium electricity is for electricity substituted original 12V Switching Power Supply, efficiency significantly improves.

Waterproof case 3024, for packaging power 3021, prevents power supply 3021 from intaking and causes scrapping, and concrete, caisson is the common water-tight device of prior art, specifically repeats no more in this application.

Sensor 3023 comprises: pressure type water level sensor and float water level sensor, and wherein, float water level sensor is dry contact, does not need the power supply of power supply.

As shown in Figure 4, the circuit diagram on a kind of mainboard of providing for the embodiment of the present application two of Fig. 4.Mainboard, except the circuit described in embodiment one, also comprises: the display input circuit be connected with CPU, the switching value circuit being arranged at power switch between CPU and pressure type water level sensor and interface circuit and being arranged between CPU and float water level sensor.Namely the motherboard circuit described in the embodiment of the present application two comprises: the input power circuit 401 be connected with power supply; The CPU401, battery detection circuit 403 and the message processing module 404 that are connected with input power circuit 401 simultaneously; The power switch 406 be connected with pressure type water level sensor with CPU401 and interface circuit 407; The switching value circuit 408 be connected with float water level sensor with CPU401; The display input circuit 405 be connected with CPU401.Wherein, battery detection circuit 403 and message processing module 404 are also connected with CPU401.

It should be noted that, display input circuit 405 is separated with mainboard, only uses when Installation and Debugging.

Concrete, power switch is 3.7V power switch, wherein, the lithium battery power supply of the corresponding 3.7V of 3.7V power switch, when power supply exports as other magnitudes of voltage, the magnitude of voltage of power switch needs identical with electric power output voltage value; Interface circuit is RS485 interface circuit, or RS232 interface circuit, can also be the interface circuit of other form; Switching value circuit is Gray code switching value circuit, also can be other forms of switching value circuit.

Data message in CPU401 is carried out pre-service by message processing module 404, is the signal that antenna can send, is sent to communication network by antenna, transfer to monitoring center by communication network by Data Integration.

Specifically it should be noted that, mainboard is 4 laminate mainboards, adopts the small package of paster, reduces volume further.

Concrete, as shown in Figure 5, the circuit diagram on the another kind of mainboard that Fig. 5 provides for the embodiment of the present application two.This circuit is except shown in Fig. 4, also comprise the time block 4011 be arranged in CPU, it should be noted that, this time block 4011 can be arranged in CPU, also can be separated with CPU, only need meet and can control according to predetermined period the data message that described sensor gathers underground water.

Time block 4011, for starting CPU according to the first predetermined period, gathers the data message of underground water to control sensor;

The supply voltage of data message and collection is preserved by CPU, and carries out dormancy after the save is completed.

Time block 4011 is also for starting CPU according to the second predetermined period;

What respond monitoring center after CPU starts calls survey together, and the data message preserve self and supply voltage are sent to monitoring center, and carry out dormancy after being sent completely.

Concrete, generally arrange the collection that every day carries out 6 underground water data messages, namely the first predetermined period can be 4 hours, certainly, does not limit at this, can select as the case may be, as carried out 5 times or gathering for 10 times.

In the application, set and carry out uploading of a secondary data in, namely arranging the second predetermined period is 24 hours, by all data upload of gathering in 24 hours to monitoring center, saves electric energy further.

Except carrying out data acquisition and data upload, on-line monitoring all-in-one entirety is in dormant state, has more effectively like this saved energy, avoids wasting phenomenon.

After mainboard 3022 carefully connects the wire, with 706 marine glues perfusion (as shown in dash area in Fig. 3), be encapsulated in dress mainboard shell in, sensor 3023 connect with the line of mainboard 3022 after, its main body is placed in outside outer container 3025.Wherein, the upper top of outer container 3025 is plastics, and other faces are metal material.Power supply 3021 and mainboard 3022 are arranged at the inside of outer container 3025, and sensor 3023 is arranged at the outside of outer container 3025.

In the application, to the requirement of outer container 3025 be: and have the convenient fixed leg installed between the shell of dress mainboard and waterproof case 3024, earnestly there is mounting flange with cement; Perforate is arranged at bottom; Little being convenient to of volume is installed; Top is plastic material, to the unshielded effect of antenna; Other face is metal, has some strength.Concrete, shell and outer container 3025 inside of dress mainboard are provided with fixed leg, waterproof case 3024 is also provided with fixed leg with outer container 3025 inside, interface between sensor wire and outer container has fixture splice and solidus groove (as shown in Figure 3, fixture splice and wire casing is followed successively by from top to bottom) below mainboard, and 10 kilograms of pulling force can be born, there is fixable flange between outer container 3025 and outside cement are honest, thus realize the fixing of on-line monitoring all-in-one.

From above technical scheme, the on-line monitoring all-in-one of the embodiment of the present application two this low-power consumption disclosed, by using a CPU as the data center of mainboard, eliminate a CPU and multiple circuit interface, and save original clock circuit and reserce cell, thus the circuit component in the on-line monitoring all-in-one in system is reduced at double, volume also reduces at double, further reduce power consumption, and, by the improvement of the elements such as the CPU to power supply, mainboard, the volume of all-in-one is reduced further, power consumption etc. reduce further.In addition, by using message processing module that the underground water data message of sensor collection is sent to Surveillance center by antenna by communication network, human cost has been saved.

Embodiment three

The embodiment of the present application three provides a kind of underground water on-line monitoring power-economizing method of low-power consumption, as shown in Figure 6, and the underground water on-line monitoring power-economizing method process flow diagram of a kind of low-power consumption that Fig. 6 provides for the embodiment of the present application three.The method wakes mainly through CPU realization of being sunk into sleep up, comprising:

S601:CPU is according to the first predetermined period self-starting.

Concrete, generally arrange the collection that every day carries out 6 underground water data messages, namely the first predetermined period can be 4 hours, certainly, does not limit at this, can select as the case may be, as carried out 5 times or gathering for 10 times.

S602: the data message gathering underground water at startup control sensor.

Wherein, also comprise carry out this process of correcting time in network when starting, specifically can pass through GSM/GPRS module, or the realization such as 3G or 4G module.

S603: the supply voltage of data message and collection is preserved, enters step S605 after having preserved.

S604:CPU according to the second predetermined period self-starting, and upon actuation respond monitoring center call survey together, by self preserve data message and described supply voltage be sent to monitoring center.

In the application, set and carry out uploading of a secondary data in, namely arranging the second predetermined period is 24 hours, all data gathered in 24 hours is uploaded to monitoring center by GSM/GPRS module via antenna, saves electric energy further.

S605: carry out dormancy.

Except carrying out data acquisition and data upload, on-line monitoring all-in-one entirety is in dormant state, has more effectively like this saved energy, avoids wasting phenomenon.

Concrete, the operating time of sensor is less than 60 seconds, and the operating time of GSM/GPRS module is less than 120 seconds, and other times are all in deep sleep, and in addition, except CPU dormancy, other circuit all turn off.

From above technical scheme, the embodiment of the present application three discloses a kind of underground water on-line monitoring power-economizing method of low-power consumption, only work when needs image data or uploading data by making monitoring all-in-one, all the other times are all in deep sleep state, thus saved energy, avoid wasting phenomenon.

Finally, also it should be noted that, in this article, the such as relational terms of first and second grades and so on is only used for an entity or operation to separate with another entity or operational zone, and not necessarily requires or imply the relation that there is any this reality between these entities or operation or sequentially.And, term " comprises ", " comprising " or its any other variant are intended to contain comprising of nonexcludability, thus make to comprise the process of a series of key element, method, article or equipment and not only comprise those key elements, but also comprise other key elements clearly do not listed, or also comprise by the intrinsic key element of this process, method, article or equipment.When not more restrictions, the key element limited by statement " comprising ... ", and be not precluded within process, method, article or the equipment comprising described key element and also there is other identical element.

In this instructions, each embodiment adopts the mode of going forward one by one to describe, and what each embodiment stressed is the difference with other embodiments, between each embodiment identical similar portion mutually see.

To the above-mentioned explanation of the disclosed embodiments, professional and technical personnel in the field are realized or uses the application.To be apparent for those skilled in the art to the multiple amendment of these embodiments, General Principle as defined herein when not departing from the spirit or scope of the application, can realize in other embodiments.Therefore, the application can not be restricted to these embodiments shown in this article, but will meet the widest scope consistent with principle disclosed herein and features of novelty.

Claims (10)

1. a underground water on-line monitoring system for low-power consumption, is characterized in that, comprising: monitoring center and on-line monitoring all-in-one;

Described on-line monitoring all-in-one is used for underground water on-line monitoring, and carries out data communication with described monitoring center by described antenna;

The data message that described monitoring center is used for the underground water uploaded according to described on-line monitoring all-in-one carries out analyzing and processing;

Described on-line monitoring all-in-one comprises: power supply, sensor, antenna and the mainboard be simultaneously connected with described power supply, described sensor, described antenna;

Circuit on described mainboard comprises:

Input end is connected with described power supply, the input power circuit be connected with one end of message processing module with one end of battery detection circuit, CPU the while of output terminal;

The other end of described battery detection circuit is connected with described CPU;

Described message processing module is connected with described CPU, and the data message for the underground water collected by the described sensor that interface circuit obtains by described CPU is processed, and sends to described monitoring center by described antenna by communication network.

2. system according to claim 1, is characterized in that, the circuit on described mainboard also comprises: the display input circuit be connected with described CPU.

3. system according to claim 1, is characterized in that, also comprises: for encapsulating the waterproof case of described power supply.

4. system according to claim 1, is characterized in that, described sensor comprises: pressure type water level sensor and float water level sensor.

5. system according to claim 4, is characterized in that, described interface circuit comprises:

Be arranged at the power switch between described CPU and described pressure type water level sensor and interface circuit;

Be arranged at the switching value circuit between described CPU and described float water level sensor.

6. system according to claim 1, is characterized in that, also comprises: upper top is plastics, and other faces are the outer container of metal material;

Wherein, described power supply and described mainboard are arranged at the inside of described outer container, and described sensor setting is in the outside of described outer container.

7. system according to claim 1, is characterized in that, described CPU also comprises time block, for starting CPU according to the first predetermined period, to control the data message that described sensor gathers underground water;

The supply voltage of described data message and collection is preserved by described CPU, and carries out dormancy after the save is completed.

8. system according to claim 7, is characterized in that, described time block is also for starting CPU according to the second predetermined period;

What respond monitoring center after described CPU starts calls survey together, and the described data message preserve self and described supply voltage are sent to described monitoring center, and carry out dormancy after being sent completely.

9. a underground water on-line monitoring power-economizing method for low-power consumption, is characterized in that, be applied to system as claimed in claim 6, comprise:

CPU is according to the first predetermined period self-starting;

The data message of underground water is gathered at startup control sensor;

The supply voltage of described data message and collection is preserved;

Dormancy is carried out after preservation.

10. method according to claim 9, it is characterized in that, also comprise: described CPU according to the second predetermined period self-starting, and upon actuation respond monitoring center call survey together, by self preserve described data message and described supply voltage be sent to described monitoring center;

Dormancy is carried out after being sent completely.