The invention relates to a charging state analysis method of electric vehicle based on electrical characteristic sequence analysis, belonging to the technical field of electric vehicle charging.
With the popularity of electric vehicle, more and more people use electric vehicle to travel, uneven battery quality lead to electric vehicle charging accidents frequently, such that how to achieve electric vehicle charging state monitoring through technical means is a popular issue at present. However, no one has proposed an analysis method of electric vehicle charging state, only the design method for electric vehicle charging device. For example, a Chinese patent application (Publication NO. CN202586432U) proposed a monitoring and control system of electric vehicles with charging protection, the system contains voltage and current detection unit; a Chinese patent application (Publication NO. CN210866413U) proposed a monitoring and protection of electric vehicle charging device, and the monitoring device can measure the deformation of the battery; a Chinese patent application (Publication NO. CN109742579B) proposed the electric vehicle charging socket of fireproof and theftproof system, added a temperature sensor in the electric vehicle charging socket. The foregoing Chinese patent applications can monitor the external data during the electric vehicle charging, but lack ability to determine whether the charging state of the electric vehicle is normal or abnormal (such as, battery leakage, charging short circuit, overvoltage charging and so on).
The technical problems to be solved are as follows: in order to solve technical problems existing in the existing technology, a charging state analysis method for an electric vehicle based on electrical characteristic sequence analysis is provided, based on Recurrent Neural Network (RNN) method, analyzing the variation of several kinds of electrical characteristics during electric vehicle charging, so as to know the state of the electric vehicle charging, such that abnormal state can be discovered earlier, and electrical fire occurred by failure can be prevented.
The technical scheme of the invention is as follows:
A charging state analysis method for an electric vehicle based on electrical characteristic sequence analysis, comprising following steps: step S1, obtaining voltage sampling data and current sampling data of the electric vehicle during charging; step S2, setting a time interval, so as to divide the voltage sample data and the current sampling data obtained in step S1 into multiple data sets; step S3, calculating an electrical characteristic vector of each time interval; step S4, adding the calculation results of Step S3 to a temperature sensing value T, and generate an electrical characteristic sequence of whole charging cycle; and step S5, inputting the electrical characteristic sequence of the electric vehicle into a trained Time Recurrent Neural Network (TRNN) in sequence to obtain corresponding results, if one of the results is 1, that said one of the results indicates that a charging state of the electric vehicle is normal; and if one of the results is 0, that said one of the results indicates that a charging state of the electric vehicle is abnormal.
The voltage sampling data and the current sampling data obtained in step S1 are high-frequency raw sampling data or low-frequency amplitude sampling data.
The voltage sampling data and the current sampling data obtained in step S1 are substituted as a further current sampling data.
The electrical characteristic vector calculated in step S2 comprises one or more of followings: active power P, reactive power Q, apparent power S, power factor φ, voltage harmonic Ui, current harmonic Ii, wherein the voltage harmonic Ui and the current harmonic IL are calculated by performing fast Fourier transform (FFT) on the voltage sampling data and the current sampling data obtained in step S1, wherein the voltage harmonic Ui and the current harmonic Ii are in a vector form, and i is from 0 to 11 or more.
The Time Recurrent Neural Network (TRNN) in step S4 adopts a method or a modified method of followings: the Recurrent Neural Network (RNN), Long Short-Term Memory Neural Network (LSTM), or Gated Recurrent Unit (GRU).
The beneficial effect of the invention: compared with the conventional temperature monitoring for the electric vehicle, the invention analyzes the charging state of the electric vehicle by using electrical monitoring, so as to quickly find the abnormal of the electric vehicle charging. In addition, historical data and time sequence changes are considered in the electrical characteristic sequence analysis, so as to improve the accuracy of state analysis.
The invention is further introduced in combination with the drawings and specific embodiments.
Embodiment 1: as illustrated as
Step S1, collecting voltage data and current data of the electric vehicle during charging through a smart socket. The sampling frequency of the smart socket is 6.4 khz/s, and the sampling accuracy is 0.5 level. The collecting time is from the start of the charging to the end of the charging, and the collecting time assumed as 7200 seconds but not limited hereto.
Step S2, setting the time interval as 1 second, then dividing the voltage sampling data and current sampling data obtained in step S1 into 7200 data sets.
Step S3, performing Fast Fourier transform algorithm (FFT) calculation on the voltage sampling data and the current sampling data of every is obtained in step S2, so as to obtain 0 to 11th harmonic Ui of voltage and 0 to 11th harmonic Ii of current, and calculating active power Pi of each harmonic successively:
Pi=UiIi
Wherein, Ui is an amplitude of harmonic voltage of order i, and Ii is an amplitude of harmonic current of order i. The total active power P is obtained by summing the active power of each harmonic:
P=Σi=011Pi
Then, calculating apparent power S, reactive power Q and power factor cos 0 according to the Root Mean Square (RMS) value of the voltage and the current.
Where U and I are voltage RMS value and current RMS value respectively. Then, the characteristics calculated every is are: active power P, apparent power S, reactive power Q and power factor cos Ø, 0 to 11th harmonic voltage Hv, 0 to 11th harmonic current HC.
Step S4, adding the calculated results of step S3 to the temperature sensing value T to construct the characteristic vector V:
V=[P,S,Q,cos ϕ,U1, . . . ,U11,I1, . . . ,I11,T]
This vector has length 29. Then, the electrical characteristic sequence of the whole charging cycle can be expressed as:
[V1,V2, . . . ,V7200]
Where V1 represents the characteristic vector of the 1st second, V2 represents the characteristic vector of the 2nd second, and V7200 represents the characteristic vector of the 7200th second.
Step 5, inputting the electrical characteristic sequence [V1, V2, . . . , V7200] of the electric vehicle into trained Time Recurrent Neural Network (TRNN) in sequence to obtain corresponding results [R1, R2, . . . , R7200]. If Ri=1, it indicates that the electric vehicle's charging state in the ith second is normal. If Ri=0, it indicates that the electric vehicle's charging state in the ith second is abnormal (e.g., battery leakage, charging short circuit, overvoltage charging, etc.).
Through the above steps, the charging state of the electric vehicle can be analyzed in real time according to the electric monitoring quantity of the electric vehicle, such that an abnormal charging state can be found in time, and the explosion and fire of the electric vehicle can be prevented.
The concept of the charging state analysis method for an electric vehicle based on electrical characteristic sequence analysis provided by the invention is that charging states of the electric vehicle during charging can be reflected by the voltage and current of the power supply port, once the electric vehicle has the abnormal state, the abnormal state can be quickly reflected through electric monitoring quantity, and the recorded electrical characteristics sequence is utilized to quickly analyze where is the problem. The existing monitoring means such as temperature and deformation monitoring only respond when the electric vehicle changes violently, such as high temperature and deformation. When the electric vehicle occurs this kind of situation, the electric vehicle often enters a very dangerous state, it may happen explosion or electrical fire at any time.
Based on above, only for the specific implementation of the present invention, but the protection scope of the present invention is not limited hereto, any familiar with this technology in the field of technical personnel in the present invention disclosed, within the limits of technology can easily think of change or replace, should be covered within the scope of protection of the present invention, therefore, the protection range of the present invention should be referred to the extent of protection of the right to request shall prevail.
Filing Document | Filing Date | Country | Kind |
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PCT/CN2021/072731 | 1/19/2021 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2022/155791 | 7/28/2022 | WO | A |
Number | Name | Date | Kind |
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10322641 | Tani | Jun 2019 | B2 |
10367354 | Tyler et al. | Jul 2019 | B2 |
Number | Date | Country |
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202586432 | Dec 2012 | CN |
206938504 | Jan 2018 | CN |
108197073 | Jun 2018 | CN |
109760542 | May 2019 | CN |
110441594 | Nov 2019 | CN |
210866413 | Jun 2020 | CN |
111398820 | Jul 2020 | CN |
211391010 | Sep 2020 | CN |
109742579 | Oct 2020 | CN |
111884224 | Nov 2020 | CN |
112215434 | Jan 2021 | CN |
116736164 | Sep 2023 | CN |
Entry |
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FIT translation (Year: 2021). |
FIT translation (Year: 2023). |
International Search Report and Written Opinion of the corresponding PCT application No. PCT/CN2021/072731 mailed on Sep. 28, 2021. |
Number | Date | Country | |
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20230241993 A1 | Aug 2023 | US |