CN201332267Y - Electric energy monitoring system - Google Patents

Abstract

The utility model discloses an electric energy monitoring system, comprising electric energy meters, a collector, network equipment and a server, wherein the electric energy meters are used for detecting the electric energy data of each electric energy measuring point; the collector is connected with the electric energy meters and is used for collecting the electric energy data of each electric energy meter; the network equipment is connected with the collector and transmits the electric energy data collected by the collector to the server; and the server is used for receiving the electric energy data and calculates and processes the electric energy data. The electric energy monitoring system gives full consideration to the real time, the accuracy and the efficiency of data collecting and realizes the automation, the intelligence and the networking of data collecting and analyzing by adopting an advanced software and hardware design scheme.

Description

Electric energy monitoring system

Technical field

The utility model relates to a kind of electric power system, relates in particular to a kind of electric energy monitoring system.

Background technology

Be accompanied by the raising of increase, development of technology and the harbour production automation level of harbour capacity, the power load at harbour constantly increases, and power consumption equipment is more and more, and metering points of electric energy constantly increases, so power energy monitoring and controlling and the examination complexity day by day that becomes.Meanwhile, the statistics of harbour service teams and groups production efficiency is very loaded down with trivial details and make mistakes easily, and the examination of operation teams and groups also proposes new requirement to electric energy management system.Under the modern economy condition, how to improve utilization of power efficient, reduce production costs, improve the important process that the business economic benefit becomes port construction.

Obtaining the Various types of data of electric power meter accurately, fast, economically, is to carry out the basis that load monitoring, electrical energy consumption analysis, teams and groups' examination, the electricity charge are settled accounts automatically, shown to count application managements such as operation conditions monitoring, load plan.

Send a duplicate to analysis in the past by hand and had many problems, as: analytical cycle is long, and inconvenience is in time pinpointed the problems, and causes big energy loss; The time of sending a duplicate to is inconsistent and manual sends a duplicate to typing and has error, causes the analytical calculation error bigger; Human factor is more, and inefficiency can not reflect information about power timely and accurately; Manual data wants input computer to analyze again, and personnel's workload is bigger, and efficient is low; And in actual applications based on the Automatic meter reading system of pulse, usually pulsing is lost phenomenon, the energy data of gathering is with a low credibility, the electric energy related data kind of gathering is few, can't reach practical requirement, more can not satisfy the requirement of unattended station the high density of power consumption equipment, big capacity, multiple class electrical energy data acquiring.

Under such environmental background, design and develop power energy monitoring and controlling and checking system has important practical significance.

The utility model content

At the defective of prior art, the purpose of this utility model provide a kind of can be in real time, gather, analyze the electric energy monitoring system of energy data automatically.

Electric energy monitoring system of the present utility model comprises: electric energy meter, collector, the network equipment, server, and wherein, described electric energy meter is used to detect the energy data of each metering points of electric energy; Described collector is connected with electric energy meter, is used to gather the energy data of each electric energy meter; The described network equipment is connected with described collector, and the energy data of described collector collection is transferred to server; Described server is used to receive described energy data, and described energy data is calculated and handles.

Preferably, described server comprises system management module, data typing module, computation analysis module, comprehensive inquiry module and system diagnostics module.

Preferably, described computation analysis module comprises at least one in utilization rate of electrical computing unit, electric substation's daily load rate computing unit, the electric substation power factor calculating unit or a plurality of in transformer load coefficient calculation unit in the station, power factor calculating unit, transformer station's daily load rate computing unit, transformer station's power consumption rate computing unit, the transformer station.

Send a duplicate to traditional craft and to compare, electric energy monitoring system of the present utility model has taken into full account real time of data acquisition, accuracy, efficiency, adopts advanced design scheme of hardware and software to realize automation, the intellectuality and networked of data collection and analysis.

Description of drawings

Fig. 1 is the structural representation of the electric energy monitoring system of the utility model preferred implementation.

Fig. 2 is the Organization Chart of server in the electric energy monitoring system shown in Figure 1;

Fig. 3 is the structural representation of computation analysis module in the server shown in Figure 2.

Embodiment

Power energy monitoring and controlling divided for three steps finished, and the first step is finished the data acquisition of electric energy meter in the transformer station, and data are based upon on the server, realizes initial analysis and examination to electric energy; Second step was finished the collection of electric substation's data, was sent to server by local area network (LAN) or Networks of Fiber Communications, finished the examination with electrical efficiency to teams and groups; The operation signal of the 3rd step with the control centre is sent to server, realizes statistics and examination to each flow process electricity consumption situation.

Fig. 1 is the structural representation of the electric energy monitoring system of preferred implementation.Electric energy monitoring system described in the utility model comprises: electric energy meter 1, collector 2, the network equipment 3, server 4, and wherein, described electric energy meter 1 is used to detect the energy data of each metering points of electric energy; Described collector 2 is connected with electric energy meter 1, is used to gather the energy data of each electric energy meter 1; The described network equipment 3 is connected with described collector 2, and the energy data that described collector 2 is gathered is transferred to server 4; Described server 4 is used to receive described energy data, and described energy data is calculated and handles.

Wherein, as shown in Figure 2, the software and hardware architecture in the server is the core of whole system.Described server comprises system management module 41, data typing module 42, computation analysis module 43, comprehensive inquiry module 44 and system diagnostics module 45.Following mask body is introduced each module:

1. system management module 41

The definition of system management module 41 main realization communication resource managements, user management, system's timing task management, internal system parameter and modification, data and archives backup and recovery, system's operation maintenance etc. specifically comprise:

A., the user and the corresponding password of different rights are set in database, guarantee the low user of rank can not the unauthorized operation database and the disabled user can not use database; Be provided with system manager, professional operator, general user and four levels of casual user in the application software, each user's opereating specification and operating right can be provided with separately and revise, the regular job of system, parameter setting, functions such as data query are different and different according to authority, and perfect system operation note and event log are provided;

B. set the scheme of checking meter, promptly be provided with and check meter the time interval (as 1 hour), system can carry out automatic data logging, for the user provides continuously, Various types of data accurately; Also can set the situation of change of two loads of a less time interval (as one minute) Continuous Tracking certain or certain; Or set corresponding fixed point according to teams and groups' operation situation and check meter the time, so that add up each teams and groups' electricity consumption situation;

C. the record of operating personnel's log-in events and record that system is revised thereof, and generate journal file;

D. the definition of the registration of teams and groups, department and production line and respective home information, teams and groups' operation is related with the time;

E. table number registration comprises definition CT, PT no-load voltage ratio;

F. backup functionality, system's support automatically and manually backup can be provided with two independently raw data bases, and all manual entries, retouching operation is strict authorizes, and detail record is arranged, and the data of manual intervention are had distinguishing mark.

2. data typing module 42

Data typing module 42 is mainly used in the required data of input system computational analysis, and the data that supervisory control system can't obtain automatically, or system can obtain but the artificial data of adjusting of needs automatically.By user terminal typing related data so as system the data of gathering are revised and are carried out ASSOCIATE STATISTICS and calculate.Typing is for example:

A. the manual amendment shows code data;

B. manually append items such as various electric weight;

C. teams and groups' corresponding equipment fault, power supply trouble, the maintenance of plan plant equipment, plan power supply unit overhaul interruption duration etc.

3. computation analysis module 43

Computation analysis module 43 is used to carry out multi-level data computation, statistics and analysis.Statistical computation comprises composite statistical calculations and single statistical computation, and according to result of calculation graphing and making form.For example comprise:

A. to the power consumption of department or production line per diem, the moon, season, year add up;

B. to the power consumption of full company integral body per diem, the moon, season, year add up;

C. to maintenance power failure or the statistics of fault outage time;

D. the needed calculating of functional module comprises that utilization rate of electrical calculates, electric energy balance calculates, Load distribution is calculated and the desired calculating of other functions.

4. comprehensive inquiry module 44

The function of this module is to realize the inquiry of different operating personnel to computational analysis, the result of appraisal, system operational parameters etc., and inquiry mode can comprise historical query and inquiry in real time.For example comprise:

A. realize the demonstration and the inquiry of information such as electric weight, load, Continuous Tracking monitoring.

B., the relevant information inquiry is provided, comprises load curve, each Calculation results etc., and can realize the Presentation Function of various curves;

C. the inquiry of abnormal data;

D. to the demonstration and the inquiry of the stoichiometric point or the circuit of communication failure.

5. system diagnostics module 45

This functional module realizes the function of automatic checking, can check easily and whether the affirmation system exists unusually, mainly comprise server and database self check, communication work station and channel resource self check, application work station and application program self check, the self check of system configuration table parameter etc., and can carry out fault alarm.

The information of electric energy meter collection comprises for example following data: at the bottom of the meritorious table of the integral point end, the idle table, power factor, voltage, electric current etc.; The collection active power of following the tracks of, reactive power, power factor, voltage, electric current etc.

The electric weight relevant information that can add up comprises for example following data: the 1# of transformer station, 2# main transformer inlet wire electric weight; The total feed electric weight of transformer station's outlet; The inner capacitor feed electric weight of standing; Power consumption in standing; The electric weight related data of each ammeter in 11 electric substations.

Preferably, as shown in Figure 3, described computation analysis module 43 comprises at least one in utilization rate of electrical computing unit 4305, electric substation's daily load rate computing unit 4306, the electric substation power factor calculating unit 4307 or a plurality of in transformer load coefficient calculation unit 4301 in the station, power factor calculating unit 4302, transformer station's daily load rate computing unit 4303, transformer station's power consumption rate computing unit 4304, the transformer station.

Transformer load coefficient calculation unit 4301 is used for transformer load factor beta in the computer installation in standing, system counts the time T that transformer puts into operation automatically, the meritorious electric weight Wp of unit/h, run duration transformer load side, the capacity of idle power Wq of unit/kW.h, run duration transformer load side, unit/kvar.h, transformer rated capacity Se, unit/kVA.But calculating transformer load factor β then:

$\mathrm{\β}=\frac{S}{S_e}$

Wherein:

$S=\frac{\sqrt{{\left(W_p\right)}^2+{\left(W_q\right)}^2}}{T}$

It is the powerfactorcos of an electricity consumption system that power factor calculating unit 4302 is used to calculate with transformer station, selectively, if electric energy meter can be gathered power factor, then needn't calculate unit 4302 by power factor and calculate.System counts the total meritorious electric weight Wrp that supplies with transformer station automatically, total capacity of idle power Wrq of unit/kW.h, supply transformer station, unit/kvar.h.Then can calculate the powerfactorcos of transformer station's system:

$\cos \mathrm{\φ}=\frac{W_{\mathrm{rp}}}{\sqrt{{\left(W_{\mathrm{rp}}\right)}^2+{\left(W_{\mathrm{rq}}\right)}^2}}$

Transformer station's daily load rate computing unit 4303 is used to calculate the daily load rate K of transformer station _f, system calculates the average burden with power p of transformer station's actual electricity consumption in the testing period automatically _p, unit/kW, its numerical value equal the maximum hourly average burden with power P that actual power consumption occurs in the testing period divided by electricity consumption hourage, transformer station _Max, unit/kW.Then can calculate daily load rate K _f:

$K_f=\frac{P_p}{P_{\max }}\×100\%$

Transformer station's power consumption rate computing unit 4304 is used to calculate the station power consumption rate α of transformer station, and system counts 1#, 2# in the station of a working year, 3# station respectively automatically with power transformation amount W _P1, W _P2, W _P3With total electricity consumption W _p, unit/kW.h, but computer installation power consumption rate α then:

$\mathrm{\&alpha;}=\frac{{\mathrm{<figure-callout\; id="1"\; label="W\; p"\; filenames="Y20082023419800121.png"\; state="\{\{state\}\}">W</figure-callout>}}_p+{\mathrm{<figure-callout\; id="2"\; label="W\; p"\; filenames="Y20082023419800121.png"\; state="\{\{state\}\}">W</figure-callout>}}_p+W_{p3}}{W_p}\&times;100\%$

Utilization rate of electrical computing unit 4305 is used to calculate utilization rate of electrical η in the transformer station in the transformer station, and system counts the 1# of transformer station, 2# main transformer inlet wire electric weight W automatically _P, unit/kW.h, each feeder line electric weight w of institute _Pi, transformer loss electric weight Δ W in standing _P, power consumption w stands _Pz, capacitor feeder line electric weight w _Pr, ground connection becomes and arc suppression coil feed w _PjCan generate utilization rate of electrical η in electric energy balance figure and electric energy balance table and the station.Utilization rate of electrical η in the computer installation then:

$\mathrm{\&eta;}=\frac{\underset{1}{\overset{11}{\mathrm{\&Sigma;}}}{w}_{\mathrm{pi}}+w_{\mathrm{pz}}+w_{\mathrm{pr}}+w_{\mathrm{pj}}}{W_p}\&times;100\%$

Electric substation's daily load rate computing unit 4306 is used to calculate each daily load rate K of electric substation _Fi, system counts the average burden with power p of actual electricity consumption in each electric substation's testing period automatically _Ip, unit/kW, the maximum hourly average burden with power P that each electric substation occurred in the testing period _Imax, unit/kW.Then can calculate daily load rate K _Fi:

$K_{\mathrm{fi}}=\frac{P_{\mathrm{ip}}}{P_{i\max }}\&times;100\%$

The electric substation power factor is calculated unit 4307 and is used to calculate with the do powerfactorcos of an electricity consumption system of power transformation _i, system counts the total meritorious electric weight W of each electric substation's feeder line automatically _iRp, total capacity of idle power W of unit/kW.h, electric substation's feeder line _iRq, unit/kvar.h.The power factor that then can calculate electric substation's system is:

$\cos \mathrm{\&phi;i}=\frac{W_{\mathrm{irp}}}{\sqrt{{\left(W_{\mathrm{irp}}\right)}^2+{\left(W_{\mathrm{irq}}\right)}^2}}$

Preferably, can generate accounting report automatically by system according to result of calculation, its content comprises all results of computational analysis gained.

Although by above-mentioned preferred implementation the utility model is described, those skilled in the art should understand that: under the situation that does not break away from the utility model spirit and scope, can make different variations and modification to the utility model.

Claims (10)

1, a kind of electric energy monitoring system is characterized in that, comprising: electric energy meter, collector, the network equipment, server, wherein,

Described electric energy meter is used to detect the energy data of each metering points of electric energy;

Described collector is connected with electric energy meter, is used to gather the energy data of each electric energy meter;

The described network equipment is connected with described collector, and the energy data of described collector collection is transferred to server;

Described server is used to receive described energy data, and described energy data is calculated and handles.

2, electric energy monitoring system according to claim 1 is characterized in that, described server comprises system management module, data typing module, computation analysis module, comprehensive inquiry module and system diagnostics module.

3, electric energy monitoring system according to claim 2, it is characterized in that described computation analysis module comprises at least one in utilization rate of electrical computing unit, electric substation's daily load rate computing unit, the electric substation power factor calculating unit or a plurality of in transformer load coefficient calculation unit in the station, power factor calculating unit, transformer station's daily load rate computing unit, transformer station's power consumption rate computing unit, the transformer station.

4, electric energy monitoring system according to claim 3 is characterized in that, the transformer load coefficient calculation unit is calculated according to following mode in standing:

Transformer load coefficient note is made β in the described station,

$\mathrm{\&beta;}=\frac{S}{S_e}$

Wherein:

$S=\frac{\sqrt{{\left(W_p\right)}^2+{\left(W_q\right)}^2}}{T}$

T is the time that transformer puts into operation, and Wp is the meritorious electric weight of run duration transformer load side, and Wq is the capacity of idle power of run duration transformer load side, and Se is the transformer rated capacity.

5, electric energy monitoring system according to claim 3 is characterized in that, power factor is calculated the unit and calculated according to following mode:

Described power factor note is made cos φ,

$\cos \mathrm{\&phi;}=\frac{W_{\mathrm{rp}}}{\sqrt{{\left(W_{\mathrm{rp}}\right)}^2+{\left(W_{\mathrm{rq}}\right)}^2}}$

Wrp is for supplying with the total meritorious electric weight of transformer station, and Wrq is for supplying with total capacity of idle power of transformer station.

6, electric energy monitoring system according to claim 3 is characterized in that, transformer station's daily load rate computing unit calculates according to following mode:

Transformer station's daily load rate note is made K _f,

$K_f=\frac{P_p}{P_{\max }}\&times;100\%$

P _pBe transformer station's average burden with power of actual electricity consumption in the testing period, its numerical value equals actual power consumption divided by electricity consumption hourage, P _MaxBe the maximum hourly average burden with power of transformer station in the testing period appearance.

7, electric energy monitoring system according to claim 3 is characterized in that, the power consumption rate computing unit of transformer station calculates according to following mode:

Transformer station's power consumption rate note is made α,

$\mathrm{\&alpha;}=\frac{W_{p1}+W_{p2}+W_{p3}}{W_p}\&times;100\%$

W _P1, W _P2, W _P3Be respectively the first, second, third transformer station power transformation amount of a working year, W _pBe total electricity consumption.

8, electric energy monitoring system according to claim 3 is characterized in that, the utilization rate of electrical computing unit calculates according to following mode in the transformer station:

The utilization rate of electrical note is made η in the transformer station

$\mathrm{\&eta;}=\frac{\underset{1}{\overset{11}{\mathrm{\&Sigma;}}}{w}_{\mathrm{pi}}+w_{\mathrm{pz}}+w_{\mathrm{pr}}+w_{\mathrm{pj}}}{W_p}\&times;100\%$

W _PBe transforming plant main transformer inlet wire electric weight, w _PiBe each institute's feeder line electric weight, w _PzBe station power consumption, w _PrBe capacitor feeder line electric weight, w _PjFor ground connection becomes and the arc suppression coil feed.

9, electric energy monitoring system according to claim 3 is characterized in that, electric substation's daily load rate computing unit calculates according to following mode:

Electric substation's daily load rate note is made K _Fi,

$K_{\mathrm{fi}}=\frac{P_{\mathrm{ip}}}{P_{i\max }}\&times;100\%$

P _IpBe the average burden with power of actual electricity consumption in the testing period of each electric substation, P _ImaxBe of the maximum hourly average burden with power of each electric substation in the testing period appearance.

10, electric energy monitoring system according to claim 3 is characterized in that, electric substation's power factor is calculated the unit and calculated according to following mode:

Electric substation's power factor note is made cos φ i,

$\cos \mathrm{\&phi;i}=\frac{W_{\mathrm{irp}}}{\sqrt{{\left(W_{\mathrm{irp}}\right)}^2+{\left(W_{\mathrm{irq}}\right)}^2}}$

W _IrpBe the total meritorious electric weight of each electric substation's feeder line, W _IrqTotal capacity of idle power for electric substation's feeder line.

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