CN115158097B - Charging pile management method and system based on Internet of things and storage medium - Google Patents

Abstract

The invention discloses a charging pile management method, a charging pile management system and a storage medium based on the Internet of things, relates to the technical field of new energy, and solves the technical problem that the temperature of a storage battery is overhigh due to long-time charging of the storage battery caused by not considering the temperature of the storage battery.

Description

Charging pile management method and system based on Internet of things and storage medium

Technical Field

The invention belongs to the technical field of new energy, and particularly relates to a charging pile management method, a charging pile management system and a charging pile management storage medium based on the Internet of things.

Background

The function of the charging pile is similar to that of an oiling machine in a gas station, the charging pile can be fixed on the ground or on the wall, is installed in public buildings (public buildings, markets, public parking lots and the like) and residential area parking lots or charging stations, electric automobiles of various models can be charged according to different voltage levels, the input end of the charging pile is directly connected with an alternating current power grid, and the output end of the charging pile is provided with a charging plug for charging the electric automobiles.

The invention with the patent publication number of CN108973760A discloses a charging pile management method based on the Internet of things, which comprises the steps that a user reserves an idle charging pile nearby and the like; the invention not only can intuitively know the data of the charging pile, does not need the operation and maintenance personnel to regularly patrol, but also can realize the automatic control of the charging pile equipment, and realizes an adjusting mode with obvious advantage on the control time under the condition of ensuring the consistent control effect, so that the system can provide higher communication transmission efficiency as far as possible while ensuring the error rate required by the system, and the operation and maintenance cost in unit time is greatly improved.

Present fill electric pile is carrying out the management in-process, generally confirm with input power, input power according to the circuit transmission's mode with confirming, deposit the electric energy to the savings battery that corresponds in, under normal save state, the temperature of savings battery all is in controllable state, if external environment temperature is too high, simultaneously because of not taking into account the temperature of savings battery, just lead to the savings battery very easily because of long-time charging, lead to the temperature of savings battery too high, when serious, still can cause comparatively serious explosion accident.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art; therefore, the invention provides a charging pile management method, a charging pile management system and a charging pile management storage medium based on the Internet of things, which are used for solving the technical problem that the temperature of a storage battery is too high due to long-time charging of the storage battery because the temperature of the storage battery is not taken into consideration.

In order to achieve the above object, an embodiment according to a first aspect of the present invention provides an internet-of-things-based charging pile management system, including a data acquisition end, an experimental data input end, and a management center;

the management center comprises an experimental data processing end, a storage medium, a power parameter ratio opposite end, a charging data processing end and a control terminal;

the experimental data input end is used for inputting external experimental data into the management center, wherein the experimental data comprises charging power parameters, temperature parameters of the battery and charging time;

an experiment data processing end in the management center processes input experiment data in a time interval mode to obtain temperature rise factors corresponding to different charging time lengths, binds time intervals among the different charging time lengths and the temperature rise factors to obtain a plurality of groups of different binding data packets, sequentially arranges the binding data packets into a first binding data packet, a second binding data packet, … … and an mth binding data packet according to the time sequence, and transmits the plurality of groups of binding data packets to a storage medium for storage;

the data acquisition terminal is used for acquiring the temperature parameter of the external environment and transmitting the acquired temperature parameter of the external environment to the management center;

the charging data processing end carries out temperature control type charging processing on the storage battery according to temperature parameters of an external environment and binding data packets stored in the storage medium, under the condition that the temperature state of the storage battery is not known, the temperature state of the storage battery is estimated according to charging time and temperature rising factors obtained through experiments, the estimated temperature parameters are compared with corresponding preset parameters, and the input power of charging is adjusted and controlled according to comparison results.

Preferably, the mode of processing the input experimental data by the experimental data processing end is as follows:

s1, setting the charging power parameter as the optimal charging parameter, and marking different charging time periods as CD _i Marking the temperature parameters corresponding to different charging time periods as WD _i Wherein i represents different charging time lengths, i =1, 2, … …, n, and the interval time period between each i is 1min;

s2, adopt

Obtaining temperature rise factors S of different stages _i ；

S3, increasing a plurality of temperature increasing factors S _i Extracting, and arranging a plurality of groups of temperature rise factors S according to the arrangement form of the time parameter i values _i Arranging the temperature rise factors S of the same temperature rise factor after finishing the arrangement _i The time parameter of (2) is obtained, a time interval is generated, and then the time interval and a temperature rise factor S are obtained _i Binding to generate a binding data packet, and storing the binding data packet into a storage medium;

s4, if a certain group of temperature rise factors S _i Corresponding to a group of time points separately, obtaining the time point and the next time point as a group of time intervals, then binding to generate a binding numberA packet stored in a storage medium;

and S5, repeating the steps S3 and S4, generating a plurality of groups of binding data packets, arranging the plurality of groups of binding data packets according to the time sequence, arranging the binding data packets into a first binding data packet, a second binding data packet, a … … and an mth binding data packet, and storing the plurality of groups of binding data packets in a storage medium.

Preferably, the charging data processing end performs temperature-controlled charging processing on the storage battery in a manner that:

p1, acquiring an external temperature parameter, and marking the temperature parameter as CH;

p2, setting the charging power as the optimal charging parameter, extracting the binding data packet from the storage medium, and extracting a first group of time intervals and corresponding temperature rise factors S _i Obtaining the initial value X1 and the end value X2 of the time interval, adopting JG ₁ = X2-X1 obtaining interval values of a first set of time intervals, using BD ₁ =S _i ×JG ₁ + CH obtains the temperature BD of the storage battery at the end of charging in the first group of time intervals ₁ Temperature value BD ₁ Comparing with the preset value Y1 when BD ₁ < Y1, the next step is executed when BD ₁ When the charging power is more than or equal to Y1, changing the charging power to reduce the charging power to the lowest charging parameter;

p3, and then BD ₁ Performing secondary processing to extract a second group of time intervals in the second group of binding data packets, and obtaining the interval value JG of the second group of time intervals in the same way as in the step P2 ₂ Using BD ₂ =S _i ×JG ₂ + BD1 obtaining temperature BD of the accumulator at the end of charging in the second time interval ₂ In which S is internal _i Temperature rise factor S corresponding to the second group of bundled data packets _i Temperature value BD ₂ Comparing the preset value Y1 with the preset value Y1 in the same way in the step P2;

p4, and then BD _m-1 Processing m times, and obtaining the time interval value JG of the m-th group of time intervals by adopting the mode of the step P3 _m When using BD _m =JG _m ×S _i +BD _m-1 The last set of temperature values BD _m Comparing with the default value Y1 when BD _m Less than Y1, continuously charging the storage battery, keeping the power parameter unchanged when BD is used _m And when the charging parameter is more than or equal to Y1, adjusting the optimal charging parameter to the lowest charging parameter until the charging is finished, and finishing the storage work of the storage battery.

Preferably, the control terminal is configured to change a charging power parameter of the charging pile, where the change mode is to adjust the optimal charging parameter to the lowest charging parameter;

the power parameter comparison opposite terminal is used for comparing the charging power parameter in the charging process with the optimal charging parameter and the lowest charging parameter stored in the storage medium, checking whether an abnormal power parameter value exists, and if the abnormal power parameter value exists, transmitting the abnormal power parameter value to an external display terminal to warn external maintenance personnel.

Preferably, the storage medium of the charging pile management system based on the internet of things comprises a charging data storage end and a power data storage end, wherein the charging data storage end is used for storing multiple groups of generated binding data packets, and the power data storage end is used for storing preset optimal power parameters and preset minimum power parameters.

Preferably, the management method of the charging pile management system based on the internet of things comprises the following steps:

analyzing and processing the experimental data to obtain corresponding temperature rise factors in different time periods through the input experimental data, and binding different time intervals and the temperature rise factors to obtain a plurality of groups of different binding data packets;

step two, in the charging process, according to the difference of charging duration, dividing charging into a plurality of charging stages, wherein each charging stage corresponds to different temperature rise factors, acquiring external temperature, and estimating the temperature of the battery in the charging process according to the temperature rise factors;

and step three, comparing the estimated battery temperature with a preset value, obtaining whether the battery temperature is normal or not according to a comparison result, if the battery temperature is in an abnormal state, adjusting the charging power parameter to the lowest value, and then performing charging operation.

Compared with the prior art, the invention has the beneficial effects that: the method comprises the steps of processing input experimental data according to the input experimental data to obtain temperature rise factors corresponding to different charging durations, transmitting the temperature rise factors to a storage medium, acquiring temperature parameters of an external environment, performing temperature-controlled charging processing on a storage battery according to the external temperature parameters and a binding data packet inside the storage medium, estimating the temperature state of the storage battery according to the charging durations and the temperature rise factors obtained through experiments under the condition that the temperature state of the storage battery is unknown, comparing the estimated battery temperature with a preset value, obtaining whether the battery temperature is normal or not according to a comparison result, adjusting a charging power parameter to a lowest value if the battery temperature is in an abnormal state, and then performing charging.

Drawings

FIG. 1 is a schematic diagram of a principle framework of the present invention;

FIG. 2 is a schematic diagram of a storage medium according to the present invention.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Referring to fig. 1, the application provides a charging pile management system based on the internet of things, which includes a data acquisition end, an experiment data input end and a management center;

the output end of the data acquisition end is electrically connected with the input end of the management center, and the output end of the experimental data input end is electrically connected with the input end of the management center;

the management center comprises an experimental data processing end, a storage medium, a power parameter ratio opposite end, a charging data processing end and a control terminal;

the output end of the experimental data processing end is electrically connected with the input end of a storage medium, the power parameter ratio is in bidirectional connection with the storage medium, the storage medium is in bidirectional connection with the charging data processing end, and the output end of the charging data processing end is electrically connected with the input end of a control terminal;

the experimental data input end is used for inputting external experimental data into the management center, wherein the experimental data comprises charging power parameters, temperature parameters of the battery and charging time;

the experimental data processing end in the management center processes the input experimental data to obtain temperature rise factors corresponding to different charging durations and transmits the temperature rise factors to the storage medium, wherein the specific processing mode is as follows:

s1, setting the charging power parameter as the optimal charging parameter, and marking different charging time periods as CDs _i Marking the temperature parameters corresponding to different charging time periods as WD _i Wherein i represents different charging time lengths, i =1, 2, … …, n, and the interval time period between each i is 1min;

s2, adopt

Obtaining temperature rise factors S of different stages _i (specifically, temperature raising factor S _i Possibly 0, but not possibly negative);

s3, increasing a plurality of temperature increasing factors S _i Extracting, and arranging a plurality of groups of temperature rise factors S according to the arrangement form of the time parameter i values _i Arranging, and after arranging, belonging to the same temperature rise factor S _i The time parameter of (2) is obtained, a time interval is generated, and then the time interval and a temperature rise factor S are obtained _i Binding to generate a binding data packet, and storing the binding data packet into a storage medium;

s4, if a certain group of temperature rise factors S _i Independently corresponding to a certain group of time points, acquiring the time point and the next time point as a group of time intervals, binding, generating a binding data packet, and storing the binding data packet in a storage medium;

and S5, repeating the steps S3 and S4, generating a plurality of groups of binding data packets, arranging the plurality of groups of binding data packets according to the time sequence, arranging the binding data packets into a first binding data packet, a second binding data packet, a … … and an mth binding data packet, and storing the plurality of groups of binding data packets in a storage medium.

The data acquisition terminal is used for acquiring the temperature parameter of the external environment and transmitting the acquired temperature parameter of the external environment to the management center;

the charging data processing end carries out temperature control type charging processing on the storage battery according to external temperature parameters and a binding data packet inside the storage medium, under the temperature state that the storage battery is not known, the temperature state of the storage battery is estimated according to charging duration and temperature rising factors obtained by experiments, the temperature state of the storage battery is estimated, the estimation mode is adopted, the overhigh temperature of the storage battery can be avoided, serious accidents are avoided at the same time, and the temperature control type charging processing mode is as follows:

p1, acquiring an external temperature parameter, and marking the temperature parameter as CH;

p2, setting the charging power as the optimal charging parameter, extracting the binding data packet from the storage medium, and extracting a first group of time intervals and corresponding temperature rise factors S _i Obtaining the initial value X1 and the end value X2 of the time interval, adopting JG ₁ = X2-X1 obtaining interval values of a first set of time intervals, using BD ₁ =S _i ×JG ₁ + CH obtaining the temperature BD of the storage battery at the end of charging in the first group of time intervals ₁ A temperature value BD ₁ With a predetermined value Y1Comparing (specifically, the default value Y1 is a group of early warning temperature values, and specific values are drawn by external personnel), when BD ₁ < Y1, the next step is performed when BD ₁ When the charging power is more than or equal to Y1, changing the charging power to reduce the charging power to the lowest charging parameter (specifically, the lowest charging parameter is set by an operator, and under a normal condition, in a high-temperature environment, when a storage battery is charged, the temperature of the storage battery can reach a corresponding early warning value generally after charging for 6 hours, and at the moment, the stored electric quantity of the storage battery reaches 80%, so that when the charging power is regulated to the lowest, the normal use of an external driver on a vehicle can not be influenced);

p3, and then BD ₁ Performing secondary processing to extract a second group of time intervals in the second group of binding data packets, and obtaining the interval value JG of the second group of time intervals in the same way as in the step P2 ₂ Using BD ₂ =S _i ×JG ₂ + BD1 obtaining temperature BD of the accumulator at the end of charging in the second time interval ₂ In which S is internal _i Temperature rise factor S corresponding to the second group of bundled data packets _i A temperature value BD ₂ Comparing the preset value Y1 with the preset value Y1 in the same way in the step P2;

p4, and then BD _m-1 Processing m times, and obtaining the time interval value JG of the m-th group of time intervals by adopting the mode of the step P3 _m In the case of using BD _m =JG _m ×S _i +BD _m-1 The last set of temperature values BD _m Comparing with the default value Y1 when BD _m Less than Y1, continuously charging the storage battery, keeping the power parameter unchanged when BD is used _m And when the charging parameter is more than or equal to Y1, adjusting the optimal charging parameter to the lowest charging parameter until the charging is finished, and finishing the storage work of the storage battery.

The control terminal is used for changing the charging power parameter of the charging pile in a mode of adjusting the optimal charging parameter to the lowest charging parameter;

the power parameter comparison opposite terminal is used for comparing the charging power parameter in the charging process with the optimal charging parameter and the lowest charging parameter stored in the storage medium, checking whether an abnormal power parameter value exists, and if the abnormal power parameter value exists, transmitting the abnormal power parameter value to an external display terminal to warn external maintenance personnel;

a charging pile management method based on the Internet of things comprises the following steps:

analyzing and processing the experimental data to obtain corresponding temperature rise factors in different time periods through the input experimental data, and binding different time intervals and the temperature rise factors to obtain a plurality of groups of different binding data packets;

step two, in the charging process, according to the difference of charging duration, dividing charging into a plurality of charging stages, wherein each charging stage corresponds to different temperature rise factors, acquiring external temperature, and estimating the temperature of the battery in the charging process according to the temperature rise factors;

and step three, comparing the estimated battery temperature with a preset value, obtaining whether the battery temperature is normal or not according to a comparison result, if the battery temperature is in an abnormal state, adjusting the charging power parameter to the lowest value, and then performing charging operation.

As shown in fig. 2, a charging pile storage medium based on the internet of things includes a charging data storage end and a power data storage end, wherein the charging data storage end is used for storing multiple groups of generated binding data packets, and the power data storage end is used for storing preset optimal power parameters and preset minimum power parameters.

Part of data in the formula is obtained by removing dimensions and calculating the numerical value of the data, and the formula is a formula which is closest to the real condition and obtained by simulating a large amount of collected data through software; the preset parameters and the preset threshold values in the formula are set by those skilled in the art according to actual conditions or obtained through simulation of a large amount of data.

The working principle of the invention is as follows: processing the input experimental data according to the input experimental data to obtain temperature rise factors corresponding to different charging durations, transmitting the temperature rise factors to a storage medium, acquiring temperature parameters of an external environment, performing temperature-controlled charging processing on the storage battery according to the external temperature parameters and a binding data packet inside the storage medium, estimating the temperature state of the storage battery according to the charging durations and the temperature rise factors obtained by the experiment under the condition that the temperature state of the storage battery is unknown, comparing the estimated battery temperature with a preset value, and obtaining whether the battery temperature is normal or not according to a comparison result.

Although the present invention has been described in detail with reference to the preferred embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the spirit and scope of the present invention.

Claims (5)

1. A charging pile management system based on the Internet of things is characterized by comprising a data acquisition end, an experiment data input end and a management center;

the management center comprises an experimental data processing end, a storage medium, a power parameter ratio opposite end, a charging data processing end and a control terminal;

the experimental data input end is used for inputting external experimental data into the management center, wherein the experimental data comprise charging power parameters, temperature parameters of the battery and charging time;

an experiment data processing end in the management center processes input experiment data in a time interval mode to obtain temperature rise factors corresponding to different charging time lengths, binds time intervals among the different charging time lengths and the temperature rise factors to obtain a plurality of groups of different binding data packets, sequentially arranges the binding data packets into a first binding data packet, a second binding data packet, … … and an mth binding data packet according to the time sequence, and transmits the plurality of groups of binding data packets to a storage medium for storage;

the data acquisition terminal is used for acquiring the temperature parameter of the external environment and transmitting the acquired temperature parameter of the external environment to the management center;

the charging data processing end carries out temperature-controlled charging processing on the storage battery according to the temperature parameters of the external environment and the binding data packet stored in the storage medium, under the condition that the temperature state of the storage battery is unknown, the temperature state of the storage battery is estimated according to the charging time and the temperature rise factor obtained by the experiment, the estimated temperature parameters are compared with the corresponding preset parameters, and the input power of charging is adjusted and controlled according to the comparison result;

the experimental data processing end processes the input experimental data in the following modes:

s1, setting the charging power parameter as the optimal charging parameter, and marking different charging time periods as CDs _i Marking the temperature parameters corresponding to different charging time periods as WD _i Wherein i represents different charging time lengths, i =1, 2, … …, n, and the interval time period between each i is 1min;

s2, adopt

Obtaining temperature rise factors S of different stages _i ；

S3, increasing a plurality of temperature increasing factors S _i Extracting, and arranging a plurality of groups of temperature rise factors S according to the arrangement form of the time parameter i values _i Arranging, and after arranging, belonging to the same temperature rise factor S _i The time parameter of (2) is obtained, a time interval is generated, and then the time interval and a temperature rise factor S are obtained _i Binding to generate a binding data packet, and storing the binding data packet into a storage medium;

s4, if a certain group of temperature rise factors S _i Individually corresponding to a group of time points, and obtaining the time pointsBinding the next time point which is a group of time intervals to generate a binding data packet, and storing the binding data packet in a storage medium;

and S5, repeating the steps S3 and S4, generating a plurality of groups of binding data packets, arranging the plurality of groups of binding data packets according to the time sequence, arranging the binding data packets into a first binding data packet, a second binding data packet, a … … and an mth binding data packet, and storing the plurality of groups of binding data packets in a storage medium.

2. The charging pile management system based on the internet of things of claim 1, wherein the charging data processing end performs temperature-control charging processing on the storage battery in a manner that:

p1, acquiring an external temperature parameter, and marking the temperature parameter as CH;

p2, setting the charging power as the optimal charging parameter, extracting the binding data packet from the storage medium, and extracting a first group of time intervals and corresponding temperature rise factors S _i Obtaining the initial value X1 and the end value X2 of the time interval by adopting JG ₁ = X2-X1 obtaining interval values of a first set of time intervals, using BD ₁ ＝S _i ×JG ₁ + CH obtaining the temperature BD of the storage battery at the end of charging in the first group of time intervals ₁ A temperature value BD ₁ Comparing with the default value Y1 when BD ₁ < Y1, the next step is performed when BD ₁ When the charging power is more than or equal to Y1, changing the charging power to reduce the charging power to the lowest charging parameter;

p3, and then BD ₁ Performing secondary processing to extract a second group of time intervals in the second group of binding data packets, and obtaining the interval value JG of the second group of time intervals in the same way as in the step P2 ₂ Using BD ₂ ＝S _i ×JG ₂ + BD1 obtaining temperature BD of the accumulator at the end of charging in the second time interval ₂ In which S is internal _i Temperature rise factor S corresponding to the second group of bundled data packets _i A temperature value BD ₂ Comparing the preset value Y1 with the preset value Y1 in the same way in the step P2;

p4, and then BD _m-1 Processing m times to obtain the time interval value JG of the mth group time interval by adopting the mode of the step P3 _m When using BD _m ＝JG _m ×S _i +BD _m-1 The last set of temperature values BD _m Comparing with the default value Y1 when BD _m Less than Y1, continuously charging the storage battery, keeping the power parameter unchanged when BD is used _m And when the charging parameter is more than or equal to Y1, adjusting the optimal charging parameter to the lowest charging parameter until the charging is finished, and finishing the storage work of the storage battery.

3. The charging pile management system based on the internet of things as claimed in claim 2, wherein the control terminal is configured to change the charging power parameter of the charging pile in a manner of adjusting the optimal charging parameter to the lowest charging parameter;

the power parameter comparison opposite terminal is used for comparing the charging power parameter in the charging process with the optimal charging parameter and the lowest charging parameter stored in the storage medium, checking whether an abnormal power parameter value exists, and if the abnormal power parameter value exists, transmitting the abnormal power parameter value to an external display terminal to warn external maintenance personnel.

4. The storage medium of the charging pile management system based on the internet of things is characterized by comprising a charging data storage end and a power data storage end, wherein the charging data storage end is used for storing multiple groups of generated binding data packets, and the power data storage end is used for storing preset optimal power parameters and preset minimum power parameters.

5. The management method of the charging pile management system based on the Internet of things according to any one of claims 1 to 3, characterized by comprising the following steps:

analyzing and processing the experimental data through the input experimental data to obtain corresponding temperature rise factors in different time periods, and binding different time intervals and the temperature rise factors to obtain a plurality of groups of different binding data packets;

step two, in the charging process, according to the difference of charging duration, dividing charging into a plurality of charging stages, wherein each charging stage corresponds to different temperature rise factors, acquiring external temperature, and estimating the temperature of the battery in the charging process according to the temperature rise factors;

and step three, comparing the estimated battery temperature with a preset value, obtaining whether the battery temperature is normal or not through a comparison result, and if the battery temperature is in an abnormal state, adjusting the charging power parameter to the lowest value and then carrying out charging operation.

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