CN114839562A

CN114839562A - Mobile power supply testing method and device, computer equipment and storage medium

Info

Publication number: CN114839562A
Application number: CN202210453626.2A
Authority: CN
Inventors: 杨光成; 贺亮; 钟春仁
Original assignee: Shenzhen Zhumang Technology Co ltd
Current assignee: Shenzhen Zhumang Technology Co ltd
Priority date: 2022-04-27
Filing date: 2022-04-27
Publication date: 2022-08-02

Abstract

The application relates to a test method and device of a mobile power supply, computer equipment and a storage medium. The method comprises the following steps: detecting the electric quantity of each mobile power supply, and determining a first mobile power supply and a second mobile power supply with mutually matched electric quantities; controlling the first mobile power supply to charge the second mobile power supply; controlling a second mobile power supply to charge a first mobile power supply; returning to execute the step of controlling the first mobile power supply to charge the second mobile power supply until the first mobile power supply or the second mobile power supply completes the test process at least once; the one-time test process comprises the steps that the electric quantity is from the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity, or from the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity. By adopting the method, the power consumption can be reduced, and the resources can be saved.

Description

Test method and device of mobile power supply, computer equipment and storage medium

Technical Field

The present application relates to the field of shared charging, and in particular, to a method and an apparatus for testing a portable power source, a computer device, and a storage medium.

Background

In the field of shared charging, the mobile power supply needs to be subjected to one or more charging and discharging cycle tests before leaving a factory, and the mobile power supply is allowed to leave the factory for sale only after the cycle tests pass. At present, in a traditional charging and discharging cycle test process of a mobile power supply, heat release is mainly performed through a connected resistor for testing.

However, the conventional test method for the mobile power supply has the problems of large power consumption and resource waste.

Disclosure of Invention

In view of the foregoing, it is desirable to provide a method, an apparatus, a computer device, and a computer readable storage medium for testing a mobile power supply, which can reduce power consumption and save resources.

In a first aspect, the application provides a method for testing a mobile power supply. The method comprises the following steps:

s1, detecting the electric quantity of each mobile power supply, and determining a first mobile power supply and a second mobile power supply with mutually matched electric quantities;

s2 controls the first mobile power supply to charge the second mobile power supply;

if the electric quantity of the first mobile power supply is reduced to a first electric quantity threshold value or zero electric quantity, and the electric quantity of the second mobile power supply is smaller than a second electric quantity threshold value or full electric quantity, performing electric quantity supplementation on the electric quantity of the second mobile power supply until the electric quantity of the second mobile power supply reaches the second electric quantity threshold value or full electric quantity;

if the electric quantity of the second mobile power supply is increased to a second electric quantity threshold value or full electric quantity, and the electric quantity of the first mobile power supply is larger than a first electric quantity threshold value or zero electric quantity, performing discharge processing on the first mobile power supply until the electric quantity of the first mobile power supply is reduced to the first electric quantity threshold value or zero electric quantity;

s3 controls the second mobile power supply to charge the first mobile power supply;

if the electric quantity of the second mobile power supply is reduced to a first electric quantity threshold value or zero electric quantity, and the electric quantity of the first mobile power supply is smaller than a second electric quantity threshold value or full electric quantity, performing electric quantity supplementation on the electric quantity of the first mobile power supply until the electric quantity of the first mobile power supply reaches the second electric quantity threshold value or full electric quantity;

if the electric quantity of the first mobile power supply is increased to a second electric quantity threshold value or full electric quantity, and the electric quantity of the second mobile power supply is larger than a first electric quantity threshold value or zero electric quantity, performing discharge processing on the second mobile power supply until the electric quantity of the second mobile power supply is reduced to the first power supply threshold value or zero electric quantity;

s4, the step of controlling the first mobile power supply to charge the second mobile power supply is executed again until the first mobile power supply or the second mobile power supply completes at least one test process; the one-time test process comprises the steps that the electric quantity is from a first electric quantity threshold value or zero electric quantity to a second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity, or from the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity.

In one embodiment, the determining the first mobile power source and the second mobile power source whose electric quantities are matched with each other includes:

matching the electric quantity of each mobile power supply with a first electric quantity range, a second electric quantity range and a third electric quantity range respectively to obtain a first mobile power supply set of which the electric quantity is in the first electric quantity range, a second mobile power supply set of which the electric quantity is in the second electric quantity range and a third mobile power supply set of which the electric quantity is in the third electric quantity range respectively; the upper limit value of the first electric quantity range is smaller than the lower limit value of a second electric quantity range, and the upper limit value of the second electric quantity range is smaller than the lower limit value of a third electric quantity range;

and for any one mobile power supply set of the first mobile power supply set, the second mobile power supply set and the third mobile power supply set, determining a first mobile power supply and a second mobile power supply with mutually matched electric quantities from the mobile power supply sets.

In one embodiment, after the determining, from the mobile power source set, the first mobile power source and the second mobile power source whose power amounts match each other, the method further includes:

when the mobile power supply set is a first mobile power supply set, supplementing the electric quantity of the first mobile power supply until the electric quantity of the first mobile power supply reaches a second electric quantity threshold or full electric quantity.

when the mobile power supply set is a third mobile power supply set, controlling the first mobile power supply or the second mobile power supply to perform discharge processing until the electric quantity of the first mobile power supply performing discharge processing meets a preset test requirement, or the electric quantity of the second mobile power supply performing discharge processing meets a preset test requirement.

In one embodiment, the controlling the first mobile power source or the second mobile power source to perform discharge processing includes:

controlling the first mobile power supply or the second mobile power supply to perform discharge treatment through a discharge device; the discharging device is connected to a circuit of the first portable power source or a circuit of the second portable power source which needs to be subjected to discharging processing.

In one embodiment, the method further comprises:

monitoring the charging states of the first mobile power supply and the second mobile power supply in a test process;

when the charging state of the first mobile power supply or the second mobile power supply is monitored to be abnormal, the first mobile power supply or the second mobile power supply with the abnormal charging state is recorded.

In one embodiment, the abnormal state of charge includes a charge speed lower than a first preset speed, a charge speed higher than the first preset speed, a discharge speed lower than a second preset speed, a discharge speed higher than the second preset speed, a failure of charging, or a failure of discharging.

In a second aspect, the application further provides a testing device for the mobile power supply. The device comprises:

the electric quantity matching module is used for detecting the electric quantity of each mobile power supply and determining a first mobile power supply and a second mobile power supply which are matched with each other in electric quantity;

the charging module is used for controlling the first mobile power supply to charge the second mobile power supply;

the charging module is further configured to, if the electric quantity of the first mobile power supply is reduced to a first electric quantity threshold or zero electric quantity, and the electric quantity of the second mobile power supply is smaller than a second electric quantity threshold or full electric quantity, perform electric quantity supplementation on the electric quantity of the second mobile power supply until the electric quantity of the second mobile power supply reaches the second electric quantity threshold or full electric quantity;

the discharging module is used for performing discharging processing on the first mobile power supply if the electric quantity of the first mobile power supply is larger than a first electric quantity threshold or zero electric quantity when the electric quantity of the second mobile power supply is increased to a second electric quantity threshold or full electric quantity until the electric quantity of the first mobile power supply is reduced to the first electric quantity threshold or zero electric quantity;

the charging module is further used for controlling the second mobile power supply to charge the first mobile power supply;

the charging module is further configured to, if the electric quantity of the second mobile power supply is reduced to a first electric quantity threshold or zero electric quantity, and the electric quantity of the first mobile power supply is smaller than a second electric quantity threshold or full electric quantity, perform electric quantity supplementation on the electric quantity of the first mobile power supply until the electric quantity of the first mobile power supply reaches the second electric quantity threshold or full electric quantity;

the discharging module is further used for performing discharging processing on the second mobile power supply if the electric quantity of the first mobile power supply is increased to a second electric quantity threshold or full electric quantity and the electric quantity of the second mobile power supply is larger than a first electric quantity threshold or zero electric quantity until the electric quantity of the second mobile power supply is reduced to the first power supply threshold or zero electric quantity;

the charging module is further used for controlling the first mobile power supply to charge the second mobile power supply until the first mobile power supply or the second mobile power supply completes at least one test process; the one-time test process comprises the steps that the electric quantity is from a first electric quantity threshold value or zero electric quantity to a second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity, or from the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity.

In a third aspect, the present application also provides a computer device. The computer device comprises a memory storing a computer program and a processor implementing the following steps when executing the computer program:

In a fourth aspect, the present application further provides a computer-readable storage medium. The computer-readable storage medium having stored thereon a computer program which, when executed by a processor, performs the steps of:

if the electric quantity of the second mobile power supply is increased to a second electric quantity threshold or full electric quantity, and the electric quantity of the first mobile power supply is larger than a first electric quantity threshold or zero electric quantity, performing discharge processing on the first mobile power supply until the electric quantity of the first mobile power supply is reduced to the first electric quantity threshold or zero electric quantity;

According to the test method and device of the mobile power supply, the computer equipment and the storage medium, the electric quantity of each mobile power supply is detected, and a first mobile power supply and a second mobile power supply with mutually matched electric quantities are determined; controlling the first mobile power supply to charge the second mobile power supply, and if the electric quantity of the first mobile power supply is reduced to a first electric quantity threshold or zero electric quantity and the electric quantity of the second mobile power supply is smaller than a second electric quantity threshold or full electric quantity, performing electric quantity supplementation on the electric quantity of the second mobile power supply until the electric quantity of the second mobile power supply reaches the second electric quantity threshold or full electric quantity; if the electric quantity of the second mobile power supply is increased to a second electric quantity threshold value or full electric quantity, and the electric quantity of the first mobile power supply is larger than a first electric quantity threshold value or zero electric quantity, performing discharge processing on the first mobile power supply until the electric quantity of the first mobile power supply is reduced to the first electric quantity threshold value or zero electric quantity; controlling a second mobile power supply to charge a first mobile power supply, and if the electric quantity of the second mobile power supply is reduced to a first electric quantity threshold or zero electric quantity and the electric quantity of the first mobile power supply is smaller than a second electric quantity threshold or full electric quantity, performing electric quantity supplementation on the electric quantity of the first mobile power supply until the electric quantity of the first mobile power supply reaches the second electric quantity threshold or full electric quantity; if the electric quantity of the first mobile power supply is increased to a second electric quantity threshold value or full electric quantity, and the electric quantity of the second mobile power supply is larger than a first electric quantity threshold value or zero electric quantity, performing discharge processing on the second mobile power supply until the electric quantity of the second mobile power supply is reduced to the first power supply threshold value or zero electric quantity; returning to execute the step of controlling the first mobile power supply to charge the second mobile power supply until the first mobile power supply or the second mobile power supply completes the test process at least once; the one-time test process comprises the steps that the electric quantity is from the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity, or from the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity. Then, the second mobile power supply is charged through the first mobile power supply when discharging, the first mobile power supply is charged through the second mobile power supply when discharging, mutual charging and discharging between the mobile power supplies can be utilized, the phenomenon that the first mobile power supply and the second mobile power supply discharge through the resistor and waste the discharged electric quantity is avoided, therefore, the electric quantity loss can be reduced in the test process of the mobile power supplies, and resources are saved.

In addition, the test method of the mobile power supply also simplifies the traditional mobile power supply aging scheme, the test process at least comprises 2 mobile power supplies for testing, the number of the mobile power supplies for testing at the same time is increased, and the test efficiency is improved. Through adjustment portable power source charge-discharge test equipment, use the portable power source that awaits measuring to replace the discharge resistance in the traditional scheme to introduce charge-discharge circulation control module group, control the cycle process of whole portable power source test, not only reduce the power consumption, improve efficiency of software testing, still because reduce the resistance and release heat, the temperature also can not be too high, has reduced the cooling equipment quantity that adds between the test car, reduces the testing cost.

Drawings

FIG. 1 is a diagram of a hardware environment for a method for testing a mobile power supply according to an embodiment;

FIG. 2 is a flow chart illustrating a method for testing a mobile power supply according to an embodiment;

FIG. 3 is a flowchart illustrating a method for testing a mobile power supply according to another embodiment;

FIG. 4 is a flowchart illustrating a method for testing a mobile power supply according to another embodiment;

FIG. 5 is a flowchart illustrating a method for testing a mobile power supply according to another embodiment;

FIG. 6 is a schematic flow chart illustrating monitoring of a mobile power supply according to one embodiment;

FIG. 7 is a block diagram showing the structure of a test apparatus for a portable power supply according to an embodiment;

FIG. 8 is a diagram illustrating an internal structure of a computer device according to an embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

The test method of the mobile power supply provided by the embodiment of the application is applied to the charge-discharge cycle control module shown in fig. 1. The charging and discharging control module is respectively connected with at least two portable power supplies to be tested and is used for respectively controlling charging and discharging of the portable power supplies to be tested. The portable power source to be tested is respectively connected with a power interface of the charging equipment, and the power interface of the charging equipment is used for supplementing the electric quantity of the portable power source under the control of the charging and discharging cycle control module.

In one embodiment, the charge-discharge cycle control module 102 detects the electric quantity of each mobile power supply, and determines a first mobile power supply 104 and a second mobile power supply 106 whose electric quantities are matched with each other; controlling first mobile power supply 104 to charge second mobile power supply 106; if the electric quantity of the first mobile power supply 104 is reduced to the first electric quantity threshold or zero electric quantity, and the electric quantity of the second mobile power supply 106 is smaller than the second electric quantity threshold or full electric quantity, performing electric quantity supplementation on the electric quantity of the second mobile power supply 106 until the electric quantity of the second mobile power supply 106 reaches the second electric quantity threshold or full electric quantity; if the electric quantity of the second mobile power supply 106 is increased to the second electric quantity threshold or the full electric quantity, and the electric quantity of the first mobile power supply 104 is greater than the first electric quantity threshold or the zero electric quantity, performing discharge processing on the first mobile power supply 104 until the electric quantity of the first mobile power supply 104 is reduced to the first electric quantity threshold or the zero electric quantity; s3 controls second mobile power supply 106 to charge first mobile power supply 104; if the electric quantity of the second mobile power supply 106 is reduced to the first electric quantity threshold or zero electric quantity, and the electric quantity of the first mobile power supply 104 is smaller than the second electric quantity threshold or full electric quantity, performing electric quantity supplementation on the electric quantity of the first mobile power supply 104 until the electric quantity of the first mobile power supply 104 reaches the second electric quantity threshold or full electric quantity; if the electric quantity of the first mobile power supply 104 is increased to the second electric quantity threshold or the full electric quantity, and the electric quantity of the second mobile power supply 106 is greater than the first electric quantity threshold or the zero electric quantity, performing discharge processing on the second mobile power supply 106 until the electric quantity of the second mobile power supply 106 is reduced to the first power supply threshold or the zero electric quantity; s4 returns to execute the step of controlling first mobile power supply 104 to charge second mobile power supply 106 until first mobile power supply 104 or second mobile power supply 106 completes at least one test procedure; the one-time test process comprises the steps that the electric quantity is from the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity, or from the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity. The first mobile power supply and the second mobile power supply can be mobile power banks or other mobile power supply devices, and are not limited thereto.

In one embodiment, as shown in fig. 2, a method for testing a mobile power supply is provided, and is applied to a charge-discharge cycle control module, and the method includes the following steps:

and step S1, detecting the electric quantity of each mobile power supply, and determining a first mobile power supply and a second mobile power supply with the electric quantities matched with each other.

The portable power source is a portable charger which can be carried around and can store electric energy. For example, the mobile power source may be a power bank.

The charge-discharge cycle control module detects the electric quantity of each mobile power supply, matches the electric quantity of each mobile power supply in pairs, and determines a first mobile power supply and a second mobile power supply, wherein the electric quantities are matched with each other. The electric quantity of the mobile power supply can be factory electric quantity. If the electric quantity difference value of the two mobile power supplies is smaller than or equal to the preset difference threshold value, the electric quantities of the two mobile power supplies are matched with each other, and the two mobile power supplies are respectively a first mobile power supply and a second mobile power supply. The preset difference threshold may be set as desired. For example, the preset difference preset may be 0, 5%, etc., without being limited thereto.

It can be understood that newly produced mobile power supplies all need to be subjected to charge-discharge cycle tests to ensure that the mobile power supplies on the market are available and have no faults. Generally, after the mobile power supply is produced, a part of electric quantity exists, and the factory electric quantity of the mobile power supply produced by different manufacturers may be different.

In step S2, the first mobile power supply is controlled to charge the second mobile power supply.

The charge-discharge cycle control module controls the first mobile power supply to charge the second mobile power supply, namely the first mobile power supply is in a discharge state, and the second mobile power supply is in a charge state.

If the electric quantity of the first mobile power supply is reduced to a first electric quantity threshold value or zero electric quantity, and the electric quantity of the second mobile power supply is smaller than a second electric quantity threshold value or full electric quantity, performing electric quantity supplementation on the electric quantity of the second mobile power supply until the electric quantity of the second mobile power supply reaches the second electric quantity threshold value or full electric quantity; if the electric quantity of the second mobile power supply is increased to a second electric quantity threshold value or full electric quantity, and the electric quantity of the first mobile power supply is larger than a first electric quantity threshold value or zero electric quantity, carrying out discharging processing on the first mobile power supply until the electric quantity of the first mobile power supply is reduced to the first electric quantity threshold value or zero electric quantity.

The first electric quantity threshold value and the second electric quantity threshold value can be set according to needs, and the first electric quantity threshold value is smaller than the second electric quantity threshold value. For example, the first charge threshold may be 1% and the second charge threshold may be 99%. The zero charge is 0 and the full charge is 100%.

It can be understood that the one-time test flow of the charging and discharging cycle control module on the mobile power supply includes that the power of the mobile power supply is changed from the first power threshold or zero power to the second power threshold or full power to the first power threshold or zero power, or from the second power threshold or full power to the first power threshold or zero power to the second power threshold or full power. The first electric quantity threshold value or zero electric quantity represents an empty electric quantity state, and the second electric quantity threshold value or full electric quantity represents a full electric quantity state.

Therefore, if the electric quantity of the first mobile power supply is reduced to the first electric quantity threshold value or zero electric quantity, the electric quantity of the second mobile power supply is smaller than the second electric quantity threshold value or full electric quantity, and the second mobile power supply does not reach the full electric quantity state of the test, the charge-discharge cycle control module needs to supplement the electric quantity of the second mobile power supply until the electric quantity of the second mobile power supply reaches the second electric quantity threshold value or full electric quantity.

If the electric quantity of the second mobile power supply is increased to the second electric quantity threshold value or the full electric quantity, the electric quantity of the first mobile power supply is larger than the first electric quantity threshold value or the zero electric quantity, and the fact that the first mobile power supply does not reach the tested empty electric quantity state is indicated, discharging processing is conducted on the first mobile power supply until the electric quantity of the first mobile power supply is reduced to the first electric quantity threshold value or the zero electric quantity.

In step S3, the second mobile power supply is controlled to charge the first mobile power supply.

The charge-discharge cycle control module controls the second mobile power supply to charge the first mobile power supply, namely the second mobile power supply is in a discharge state, and the first mobile power supply is in a charge state.

If the electric quantity of the second mobile power supply is reduced to the first electric quantity threshold value or zero electric quantity, the electric quantity of the first mobile power supply is smaller than the second electric quantity threshold value or full electric quantity, and the first mobile power supply does not reach the full electric quantity state, the electric quantity of the first mobile power supply is supplemented until the electric quantity of the first mobile power supply reaches the second electric quantity threshold value or full electric quantity.

If the electric quantity of the first mobile power supply is increased to the second electric quantity threshold value or the full electric quantity, the electric quantity of the second mobile power supply is larger than the first electric quantity threshold value or the zero electric quantity, and the second mobile power supply is indicated to be in an empty electric quantity state, discharging processing is conducted on the second mobile power supply until the electric quantity of the second mobile power supply is reduced to the first power supply threshold value or the zero electric quantity.

Step S4, returning to the step of controlling the first mobile power supply to charge the second mobile power supply until the first mobile power supply or the second mobile power supply completes at least one test flow; the one-time test process comprises the steps that the electric quantity is from the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity, or from the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity.

The test flow is also referred to as an aging test flow.

It can be understood that, in the test process of the mobile power supply, the electric quantity of the first mobile power supply is from the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity, and the step of controlling the first mobile power supply to charge the second mobile power supply is executed in return, so that the electric quantity of the first mobile power supply is from the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity, and a test flow is completed.

Similarly, the electric quantity of the second mobile power supply is from the second electric quantity threshold or the full electric quantity to the first electric quantity threshold or the zero electric quantity, and the step of controlling the first mobile power supply to charge the second mobile power supply is executed in a return mode, so that the electric quantity of the second mobile power supply is from the first electric quantity threshold or the zero electric quantity to the second electric quantity threshold or the full electric quantity, and a test process is completed.

Of course, the first mobile power source and the second mobile power source may also complete a plurality of test procedures, such as 2 times or 3 times, and the like, which is not limited herein.

When the first mobile power supply and the second mobile power supply both complete the test process at least once, the test of the first mobile power supply and the second mobile power supply is realized.

The testing method of the mobile power supply detects the electric quantity of each mobile power supply, and determines a first mobile power supply and a second mobile power supply which are matched with each other in electric quantity; controlling the first mobile power supply to charge the second mobile power supply, and if the electric quantity of the first mobile power supply is reduced to a first electric quantity threshold or zero electric quantity and the electric quantity of the second mobile power supply is smaller than a second electric quantity threshold or full electric quantity, performing electric quantity supplementation on the electric quantity of the second mobile power supply until the electric quantity of the second mobile power supply reaches the second electric quantity threshold or full electric quantity; if the electric quantity of the second mobile power supply is increased to a second electric quantity threshold value or full electric quantity, and the electric quantity of the first mobile power supply is larger than a first electric quantity threshold value or zero electric quantity, performing discharge processing on the first mobile power supply until the electric quantity of the first mobile power supply is reduced to the first electric quantity threshold value or zero electric quantity; controlling a second mobile power supply to charge a first mobile power supply, and if the electric quantity of the second mobile power supply is reduced to a first electric quantity threshold or zero electric quantity and the electric quantity of the first mobile power supply is smaller than a second electric quantity threshold or full electric quantity, performing electric quantity supplementation on the electric quantity of the first mobile power supply until the electric quantity of the first mobile power supply reaches the second electric quantity threshold or full electric quantity; if the electric quantity of the first mobile power supply is increased to a second electric quantity threshold value or full electric quantity, and the electric quantity of the second mobile power supply is larger than a first electric quantity threshold value or zero electric quantity, performing discharge processing on the second mobile power supply until the electric quantity of the second mobile power supply is reduced to the first power supply threshold value or zero electric quantity; returning to execute the step of controlling the first mobile power supply to charge the second mobile power supply until the first mobile power supply or the second mobile power supply completes the test process at least once; the one-time test process comprises the steps that the electric quantity is from the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity, or from the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity. Then, the second mobile power supply is charged through the first mobile power supply when discharging, the first mobile power supply is charged through the second mobile power supply when discharging, mutual charging and discharging between the mobile power supplies can be utilized, the phenomenon that the first mobile power supply and the second mobile power supply discharge through the resistor and waste the discharged electric quantity is avoided, therefore, the electric quantity loss can be reduced in the test process of the mobile power supplies, and resources are saved.

In one embodiment, determining a first mobile power source and a second mobile power source whose power amounts match each other includes: matching the electric quantity of each mobile power supply with a first electric quantity range, a second electric quantity range and a third electric quantity range respectively to obtain a first mobile power supply set with the electric quantity in the first electric quantity range, a second mobile power supply set with the electric quantity in the second electric quantity range and a third mobile power supply set with the electric quantity in the third electric quantity range respectively; the upper limit value of the first electric quantity range is smaller than the lower limit value of the second electric quantity range, and the upper limit value of the second electric quantity range is smaller than the lower limit value of the third electric quantity range; and determining a first mobile power supply and a second mobile power supply with mutually matched electric quantities from the mobile power supply sets aiming at any one of the first mobile power supply set, the second mobile power supply set and the third mobile power supply set.

The first electric quantity range, the second electric quantity range and the third electric quantity range can be set as required, the upper limit value of the first electric quantity range is smaller than the lower limit value of the second electric quantity range, and the upper limit value of the second electric quantity range is smaller than the lower limit value of the third electric quantity range. For example, the first electrical quantity ranges from 0% to 20%, the second electrical quantity ranges from 50% to 60%, and the third electrical quantity ranges from 80% to 100%. The mobile power supply in the first electric quantity range is in a low electric quantity state, the mobile power supply in the second electric quantity range is in a medium electric quantity state, and the mobile power supply in the third electric quantity range is in a high electric quantity state.

In one embodiment, for any one of the first mobile power supply set, the second mobile power supply set and the third mobile power supply set, the first mobile power supply and the second mobile power supply with mutually matched electric quantities are randomly determined from the mobile power supply sets.

In another embodiment, for any one of the first mobile power supply set, the second mobile power supply set and the third mobile power supply set, the first mobile power supply and the second mobile power supply with the same electric quantity are determined from the mobile power supply sets.

In other embodiments, the first mobile power source and the second mobile power source may be determined in other manners.

In this embodiment, the electric quantity of each mobile power supply is respectively matched with the first electric quantity range, the second electric quantity range and the third electric quantity range, so as to obtain a first mobile power supply set with the electric quantity in the first electric quantity range, a second mobile power supply set with the electric quantity in the second electric quantity range and a third mobile power supply set with the electric quantity in the third electric quantity range, and then, for any one of the first mobile power supply set, the second mobile power supply set and the third mobile power supply set, the first mobile power supply and the second mobile power supply with the electric quantities matched with each other can be accurately determined from the mobile power supply sets.

In one embodiment, after determining the first mobile power source and the second mobile power source with the electric quantities matched with each other from the mobile power source set, the method further comprises the following steps: when the mobile power supply set is the first mobile power supply set, the electric quantity of the first mobile power supply is supplemented until the electric quantity of the first mobile power supply reaches a second electric quantity threshold value or full electric quantity.

After the charge-discharge cycle control module determines a first mobile power supply and a second mobile power supply which are matched with each other, the electric quantity of the first mobile power supply and the electric quantity of the second mobile power supply are factory electric quantity, when the mobile power supply set is a first mobile power supply set, the electric quantity of the first mobile power supply and the electric quantity of the second mobile power supply are both in a first electric quantity range, the upper limit value of the first electric quantity range is smaller than the lower limit value of a second electric quantity range, the upper limit value of the second electric quantity range is smaller than the lower limit value of a third electric quantity range, and the power supply movement in the first electric quantity range is in a low electric quantity state. Therefore, the first portable power source needs to be supplemented with electric quantity, and then a corresponding charge-discharge cycle test is performed.

It should be noted that, since the mobile power source has a charging loss during charging, that is, the mobile power source with 100% of power is charged externally, the charged mobile power source cannot obtain 100% of power, but about 70% -80% of power (depending on the charging conversion rate of the mobile power source).

Therefore, in this embodiment, since the first mobile power source and the second mobile power source that are matched with each other are both in the low power state, if the first mobile power source charges the second mobile power source, the charging is not full and is far away, so that the power of the second mobile power source needs to be supplemented, and then the charge and discharge cycle test is performed, so that the charge and discharge cycle test can be completed more accurately.

In one embodiment, as shown in fig. 3, a method for testing a mobile power supply is provided, which is applied to a charge-discharge cycle control module, and includes the following steps:

step 302, reading the factory electric quantity of the mobile power supply to be tested, and pairing the mobile power supply to be tested in pairs according to the factory electric quantity.

In this embodiment, it is determined that the first mobile power source and the second mobile power source which are matched with each other are both in the first electric quantity range, that is, the first mobile power source and the second mobile power source are both in a low electric quantity state, for example, the first mobile power source and the second mobile power source are both in a 0% -20% state.

And step 304, performing power supply on the first mobile power supply through the power supply interface until the power supply of the first mobile power supply is supplied to a second power supply threshold value or full power supply.

And step 306, controlling the first mobile power supply to charge the mutually matched second mobile power supplies until the electric quantity of the first mobile power supply is the first electric quantity threshold value or zero electric quantity.

And 308, acquiring the electric quantity of the second mobile power supply and supplementing the electric quantity of the second mobile power supply through the power interface until the electric quantity of the second mobile power supply is a second electric quantity threshold or full electric quantity.

In this scheme, because of the existence of the charging loss, the first mobile power supply charges the second mobile power supply, and the electric quantity of the second mobile power supply is not necessarily full, so the electric quantity of the second mobile power supply needs to be detected and then the electric quantity is supplemented.

And step 310, controlling the second mobile power supply to charge the mutually matched first mobile power supplies until the electric quantity of the second mobile power supply is the first electric quantity threshold value or zero electric quantity. And returning to step 304 until the power of the first mobile power supply is replenished to the second power threshold or full power.

After the above steps 302 to 310, the first mobile power source has completed the charge/discharge cycle of the power amount from the second power threshold or full power amount to the first power threshold or zero power amount and then to the second power threshold or full power amount, and the power amount of the second mobile power source is still discharged to the second power threshold or full power amount, so it is necessary to return to step 304 to repeat the above process. It is emphasized that the number of charging and discharging times of the portable power source in the charging and discharging cycle test before the portable power source leaves the factory is at least 1, and the whole test is completed after the portable power sources to be tested complete the cycle test.

In one embodiment, as shown in fig. 4, a method for testing a mobile power supply is provided, which is applied to a charge-discharge cycle control module, and includes the following steps:

step 402, reading the factory electricity quantity of the mobile power supply to be tested, and pairing the mobile power supply to be tested in pairs according to the factory electricity quantity.

In this embodiment, it is determined that the first mobile power source and the second mobile power source which are matched with each other are both in the second electric quantity range, that is, the first mobile power source and the second mobile power source are both in the medium electric quantity state, for example, the first mobile power source and the second mobile power source are both in 50% -60%.

And step 404, controlling the first mobile power supply to charge the mutually matched second mobile power supplies.

In this embodiment, since the first mobile power source and the second mobile power source are both in a medium electric quantity state, for example, the electric quantity is about 50% to 60%, it can be known from the calculation of the charge conversion rate of the mobile power source that the charge-discharge cycle test can be started without supplementing the electric quantity to the mobile power source (the first mobile power source is just full or is not much even if the first mobile power source is not full of the second mobile power source).

And step 406, controlling the second mobile power supply to charge the mutually matched first mobile power supplies.

If the electric quantity of the second mobile power supply is reduced to a first electric quantity threshold value or zero electric quantity, and the electric quantity of the first mobile power supply is smaller than a second electric quantity threshold value or full electric quantity, performing electric quantity supplementation on the electric quantity of the first mobile power supply until the electric quantity of the first mobile power supply reaches the second electric quantity threshold value or full electric quantity; if the electric quantity of the first mobile power supply is increased to a second electric quantity threshold value or full electric quantity, and the electric quantity of the second mobile power supply is larger than a first electric quantity threshold value or zero electric quantity, carrying out discharging processing on the second mobile power supply until the electric quantity of the second mobile power supply is reduced to the first power supply threshold value or zero electric quantity.

Step 408, returning to execute the step of controlling the first mobile power supply to charge the second mobile power supply until the first mobile power supply or the second mobile power supply completes at least one test flow; the one-time test process comprises the steps that the electric quantity is from the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity, or from the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity.

In one embodiment, after determining the first mobile power source and the second mobile power source with the electric quantities matched with each other from the mobile power source set, the method further comprises the following steps: when the mobile power supply set is a third mobile power supply set, controlling the first mobile power supply or the second mobile power supply to perform discharge processing until the electric quantity of the first mobile power supply performing discharge processing meets a preset test requirement, or the electric quantity of the second mobile power supply performing discharge processing meets the preset test requirement.

The preset test requirements may be set as desired. For example, the preset test requirement is that the electric quantity of the mobile power supply is a preset target value; the preset target value may be set as required, such as 0%, 50%, 60%, or 55%. And after the electric quantity of the first mobile power supply or the second mobile power supply meets the preset test requirement through discharging, performing a charge-discharge cycle test process.

It can be understood that, according to the factory electricity quantity and the charging conversion rate of the mobile power supply, whether the first mobile power supply charges the second mobile power supply to the second electricity quantity threshold or full electricity quantity or whether the second mobile power supply charges the first mobile power supply to the second electricity quantity threshold or full electricity quantity is still surplus is calculated. The charging conversion rate of the mobile power supply is usually 70% -80%, and according to the calculation of the conversion rate, the mobile power supply in the high-power state charges another mobile power supply in the high-power state, and the electric quantity of the charged mobile power supply is still surplus after the electric quantity of the charged mobile power supply reaches a second electric quantity threshold or full electric quantity. Therefore, at this time, it is necessary to perform discharge processing on one of the mobile power supplies in the high-charge state so that the mobile power supply can meet the requirements of the charge-discharge cycle test.

In this embodiment, when the mobile power supply set is the third mobile power supply set, and the mobile power supply in the first mobile power supply set is in a high power state, the first mobile power supply or the second mobile power supply is controlled to perform discharge processing until the power of the first mobile power supply performing discharge processing meets a preset test requirement, or the power of the second mobile power supply performing discharge processing meets a preset test requirement, so that the first mobile power supply and the second mobile power supply can be tested more accurately.

In one embodiment, as shown in fig. 5, a method for testing a mobile power supply is provided, which is applied to a charge-discharge cycle control module, and includes the following steps:

step 502, reading the factory electric quantity of the mobile power supply to be tested, and pairing the mobile power supply to be tested in pairs according to the factory electric quantity.

In this embodiment, it is determined that the first mobile power source and the second mobile power source that are matched with each other are both in the third electric quantity range, that is, the first mobile power source and the second mobile power source are both in a high electric quantity state, for example, the first mobile power source and the second mobile power source are both in 80% -100%.

Step 504, calculating whether the first mobile power supply charges the second mobile power supply or whether the second mobile power supply has surplus electric quantity when charging the first mobile power supply according to the factory electric quantity and the charging conversion rate.

The charging conversion rate of the mobile power supply is generally 70% -80%, and according to the conversion rate, the charging of one mobile power supply in a high-power state to another mobile power supply in a high-power state will certainly exceed 100% of power. Therefore, at this time, the first portable power source or the second portable power source needs to be subjected to discharge processing, so that the first portable power source or the second portable power source can meet the requirement of the charge-discharge cycle test of the portable power source.

Step 506, if the electric quantity surplus occurs, controlling the first mobile power supply or the second mobile power supply to discharge until the electric quantity of the first mobile power supply or the second mobile power supply reaches a first electric quantity threshold value or zero electric quantity.

In one embodiment, controlling the first mobile power supply or the second mobile power supply to perform discharge processing includes: controlling the first mobile power supply or the second mobile power supply to perform discharge treatment through discharge equipment; the discharge device is connected to a circuit of the first portable power source or a circuit of the second portable power source which needs to be subjected to discharge processing.

The discharge device is a device for discharging the first mobile power supply or the second mobile power supply. The discharge device may be a resistor, and may also be a load terminal, which is not limited herein.

In one embodiment, the method further comprises: monitoring the charging states of the first mobile power supply and the second mobile power supply in a test process; when the charging state of the first mobile power supply or the second mobile power supply is monitored to be abnormal, the first mobile power supply or the second mobile power supply with the abnormal charging state is recorded.

The charging state includes a normal state and an abnormal state. The abnormal state of charge includes, but is not limited to: the charging speed is lower than a first preset speed, the charging speed is higher than the first preset speed, the discharging speed is lower than a second preset speed, the discharging speed is higher than the second preset speed, and the charging or discharging is impossible. Wherein, first preset speed and second preset speed all can set up as required.

Specifically, the charge-discharge cycle control module identifies whether the first mobile power supply and the second mobile power supply are abnormal or not according to the charging states of the first mobile power supply and the second mobile power supply; and if the charging state is abnormal, recording the first mobile power supply or the second mobile power supply with the abnormal charging state and outputting the record.

If the first mobile power supply or the second mobile power supply is abnormal, the charging and discharging cycle control module can remind the user of the abnormality through a prompting lamp arranged on the charging and discharging cycle control module. When the first mobile power supply or the second mobile power supply is abnormal, the charge-discharge cycle control module can display different colors by controlling the prompting lamps of the first mobile power supply or the second mobile power supply so as to prompt a tester of the abnormal state of the first mobile power supply or the second mobile power supply.

Furthermore, the charger baby with the abnormal state can be removed from the circulation test process.

In this embodiment, the charging states of the first mobile power supply and the second mobile power supply are monitored in a test process; when the charging state of the first mobile power supply or the second mobile power supply is monitored to be abnormal, the first mobile power supply or the second mobile power supply with the abnormal charging state is recorded, the abnormal mobile power supply can be accurately determined, and therefore the method can be used for carrying out corresponding processing on the abnormal mobile power supply in the follow-up process.

In one embodiment, as shown in fig. 6, a method for testing a mobile power supply is provided, which is applied to a charge-discharge cycle control module, and includes the following steps:

step 602, monitoring the charging states of the first mobile power supply and the second mobile power supply in the cyclic charging process.

And step 604, identifying whether the first mobile power supply and the second mobile power supply are abnormal or not according to the charging state.

And 606, recording and outputting the abnormal state of the first mobile power supply or the second mobile power supply if the abnormality occurs.

It should be understood that, although the steps in the flowcharts related to the embodiments as described above are sequentially displayed as indicated by arrows, the steps are not necessarily performed sequentially as indicated by the arrows. The steps are not limited to being performed in the exact order illustrated and, unless explicitly stated herein, may be performed in other orders. Moreover, at least a part of the steps in the flowcharts related to the embodiments described above may include multiple steps or multiple stages, which are not necessarily performed at the same time, but may be performed at different times, and the execution order of the steps or stages is not necessarily sequential, but may be rotated or alternated with other steps or at least a part of the steps or stages in other steps.

Based on the same inventive concept, the embodiment of the present application further provides a testing apparatus for a mobile power supply, which is used for implementing the above-mentioned testing method for a mobile power supply. The implementation scheme for solving the problem provided by the device is similar to the implementation scheme described in the method, so that specific limitations in the embodiment of the testing device for one or more mobile power supplies provided below can refer to the limitations on the testing method for the mobile power supplies in the foregoing, and details are not described here.

In one embodiment, as shown in fig. 7, there is provided a test apparatus for a mobile power supply, including: a charge amount matching module 702, a charging module 704, and a discharging module 706, wherein:

the electric quantity matching module 702 is configured to detect electric quantities of the mobile power supplies, and determine a first mobile power supply and a second mobile power supply, where the electric quantities are matched with each other.

The charging module 704 is configured to control the first mobile power source to charge the second mobile power source.

The charging module 704 is further configured to, if the power of the first mobile power source is reduced to the first power threshold or zero power, and the power of the second mobile power source is less than the second power threshold or full power, perform power compensation on the power of the second mobile power source until the power of the second mobile power source reaches the second power threshold or full power.

The discharging module 706 is configured to, if the electric quantity of the second mobile power supply rises to the second electric quantity threshold or the full electric quantity, and the electric quantity of the first mobile power supply is greater than the first electric quantity threshold or the zero electric quantity, perform discharging processing on the first mobile power supply until the electric quantity of the first mobile power supply is reduced to the first electric quantity threshold or the zero electric quantity.

The charging module 704 is further configured to control the second mobile power supply to charge the first mobile power supply.

The charging module 704 is further configured to, if the power of the second mobile power supply is reduced to the first power threshold or zero power, and the power of the first mobile power supply is less than the second power threshold or full power, perform power compensation on the power of the first mobile power supply until the power of the first mobile power supply reaches the second power threshold or full power.

The discharging module 706 is further configured to perform discharging processing on the second mobile power supply if the electric quantity of the first mobile power supply is increased to a second electric quantity threshold or full electric quantity, and the electric quantity of the second mobile power supply is greater than the first electric quantity threshold or zero electric quantity, until the electric quantity of the second mobile power supply is reduced to the first power supply threshold or zero electric quantity.

The charging module 702 is further configured to control the first mobile power supply to charge the second mobile power supply until the first mobile power supply or the second mobile power supply completes at least one test procedure; the one-time test process comprises the steps that the electric quantity is from the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity, or from the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity.

The testing device of the mobile power supply detects the electric quantity of each mobile power supply and determines a first mobile power supply and a second mobile power supply which are matched with each other in electric quantity; controlling the first mobile power supply to charge the second mobile power supply, and if the electric quantity of the first mobile power supply is reduced to a first electric quantity threshold or zero electric quantity and the electric quantity of the second mobile power supply is smaller than a second electric quantity threshold or full electric quantity, performing electric quantity supplementation on the electric quantity of the second mobile power supply until the electric quantity of the second mobile power supply reaches the second electric quantity threshold or full electric quantity; if the electric quantity of the second mobile power supply is increased to a second electric quantity threshold value or full electric quantity, and the electric quantity of the first mobile power supply is larger than a first electric quantity threshold value or zero electric quantity, performing discharge processing on the first mobile power supply until the electric quantity of the first mobile power supply is reduced to the first electric quantity threshold value or zero electric quantity; controlling a second mobile power supply to charge a first mobile power supply, and if the electric quantity of the second mobile power supply is reduced to a first electric quantity threshold or zero electric quantity and the electric quantity of the first mobile power supply is smaller than a second electric quantity threshold or full electric quantity, performing electric quantity supplementation on the electric quantity of the first mobile power supply until the electric quantity of the first mobile power supply reaches the second electric quantity threshold or full electric quantity; if the electric quantity of the first mobile power supply is increased to a second electric quantity threshold value or full electric quantity, and the electric quantity of the second mobile power supply is larger than a first electric quantity threshold value or zero electric quantity, performing discharge processing on the second mobile power supply until the electric quantity of the second mobile power supply is reduced to the first power supply threshold value or zero electric quantity; returning to execute the step of controlling the first mobile power supply to charge the second mobile power supply until the first mobile power supply or the second mobile power supply completes the test process at least once; the one-time test process comprises the steps that the electric quantity is from the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity, or from the second electric quantity threshold value or full electric quantity to the first electric quantity threshold value or zero electric quantity to the second electric quantity threshold value or full electric quantity. Then, the second mobile power supply is charged through the first mobile power supply when discharging, the first mobile power supply is charged through the second mobile power supply when discharging, mutual charging and discharging between the mobile power supplies can be utilized, the phenomenon that the first mobile power supply and the second mobile power supply discharge through the resistor and waste the discharged electric quantity is avoided, therefore, the electric quantity loss can be reduced in the test process of the mobile power supplies, and resources are saved.

In one embodiment, the electric quantity matching module 702 is further configured to match the electric quantity of each mobile power supply with a first electric quantity range, a second electric quantity range, and a third electric quantity range, respectively, to obtain a first mobile power supply set with an electric quantity within the first electric quantity range, a second mobile power supply set with an electric quantity within the second electric quantity range, and a third mobile power supply set with an electric quantity within the third electric quantity range; the upper limit value of the first electric quantity range is smaller than the lower limit value of the second electric quantity range, and the upper limit value of the second electric quantity range is smaller than the lower limit value of the third electric quantity range; and determining a first mobile power supply and a second mobile power supply with mutually matched electric quantities from the mobile power supply sets aiming at any one of the first mobile power supply set, the second mobile power supply set and the third mobile power supply set.

In one embodiment, the charging module 704 is further configured to, when the mobile power source set is the first mobile power source set, charge the first mobile power source until the charge of the first mobile power source reaches the second charge threshold or the full charge.

In one embodiment, the discharging module 706 is configured to control the first mobile power source or the second mobile power source to perform discharging processing when the mobile power source set is the third mobile power source set until the electric quantity of the first mobile power source performing discharging processing meets a preset test requirement, or the electric quantity of the second mobile power source performing discharging processing meets the preset test requirement.

In one embodiment, the discharging module 706 is further configured to control the first mobile power source or the second mobile power source to perform discharging processing through a discharging device; the discharge device is connected to a circuit of the first portable power source or a circuit of the second portable power source which needs to be subjected to discharge processing.

In one embodiment, the apparatus further comprises a monitoring module; the monitoring module is also used for monitoring the charging states of the first mobile power supply and the second mobile power supply in a test process; when the charging state of the first mobile power supply or the second mobile power supply is monitored to be abnormal, the first mobile power supply or the second mobile power supply with the abnormal charging state is recorded.

In one embodiment, the abnormal state of charge includes a charge speed lower than a first preset speed, a charge speed higher than the first preset speed, a discharge speed lower than a second preset speed, a discharge speed higher than the second preset speed, a failure to charge, or a failure to discharge.

All or part of each module in the testing device of the mobile power supply can be realized by software, hardware and a combination thereof. The modules can be embedded in a hardware form or independent from a processor in the computer device, and can also be stored in a memory in the computer device in a software form, so that the processor can call and execute operations corresponding to the modules.

In one embodiment, a computer device is provided, which may be a terminal, and its internal structure diagram may be as shown in fig. 8. The computer apparatus includes a processor, a memory, an input/output interface, a communication interface, a display unit, and an input device. The processor, the memory and the input/output interface are connected by a system bus, and the communication interface, the display unit and the input device are connected by the input/output interface to the system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The input/output interface of the computer device is used for exchanging information between the processor and an external device. The communication interface of the computer device is used for carrying out wired or wireless communication with an external terminal, and the wireless communication can be realized through WIFI, a mobile cellular network, NFC (near field communication) or other technologies. The computer program is executed by a processor to implement a method of testing a mobile power supply.

Those skilled in the art will appreciate that the architecture shown in fig. 8 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

In one embodiment, a computer device is further provided, which includes a memory and a processor, the memory stores a computer program, and the processor implements the steps of the above method embodiments when executing the computer program.

In an embodiment, a computer-readable storage medium is provided, on which a computer program is stored which, when being executed by a processor, carries out the steps of the above-mentioned method embodiments.

In an embodiment, a computer program product is provided, comprising a computer program which, when being executed by a processor, carries out the steps of the above-mentioned method embodiments.

It should be noted that, the user information (including but not limited to user equipment information, user personal information, etc.) and data (including but not limited to data for analysis, stored data, displayed data, etc.) referred to in the present application are information and data authorized by the user or sufficiently authorized by each party, and the collection, use and processing of the related data need to comply with the relevant laws and regulations and standards of the relevant country and region.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, database, or other medium used in the embodiments provided herein may include at least one of non-volatile and volatile memory. The nonvolatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical Memory, high-density embedded nonvolatile Memory, resistive Random Access Memory (ReRAM), Magnetic Random Access Memory (MRAM), Ferroelectric Random Access Memory (FRAM), Phase Change Memory (PCM), graphene Memory, and the like. Volatile Memory can include Random Access Memory (RAM), external cache Memory, and the like. By way of illustration and not limitation, RAM can take many forms, such as Static Random Access Memory (SRAM) or Dynamic Random Access Memory (DRAM), among others. The databases referred to in various embodiments provided herein may include at least one of relational and non-relational databases. The non-relational database may include, but is not limited to, a block chain based distributed database, and the like. The processors referred to in the embodiments provided herein may be general purpose processors, central processing units, graphics processors, digital signal processors, programmable logic devices, quantum computing based data processing logic devices, etc., without limitation.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present application shall be subject to the appended claims.

Claims

1. A method for testing a mobile power supply, the method comprising:

2. The method of claim 1, wherein determining the first mobile power source and the second mobile power source with the electric quantities matching each other comprises:

matching the electric quantity of each mobile power supply with a first electric quantity range, a second electric quantity range and a third electric quantity range respectively to obtain a first mobile power supply set with the electric quantity in the first electric quantity range, a second mobile power supply set with the electric quantity in the second electric quantity range and a third mobile power supply set with the electric quantity in the third electric quantity range respectively; the upper limit value of the first electric quantity range is smaller than the lower limit value of a second electric quantity range, and the upper limit value of the second electric quantity range is smaller than the lower limit value of a third electric quantity range;

3. The method of claim 2, further comprising, after determining the first mobile power source and the second mobile power source with the power quantities matching each other from the mobile power source set:

4. The method of claim 2, further comprising, after determining the first mobile power source and the second mobile power source with the power quantities matching each other from the mobile power source set:

5. The method of claim 4, wherein the controlling the first mobile power source or the second mobile power source to perform discharge processing comprises:

6. The method according to any one of claims 1 to 5, further comprising:

7. The method of claim 6, wherein the abnormal state of charge condition comprises a charge speed lower than a first preset speed, a charge speed higher than the first preset speed, a discharge speed lower than a second preset speed, a discharge speed higher than the second preset speed, no charge, or no discharge.

8. A testing apparatus for a mobile power supply, the apparatus comprising:

9. A computer device comprising a memory and a processor, the memory storing a computer program, characterized in that the processor, when executing the computer program, implements the steps of the method of any of claims 1 to 7.

10. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method of any one of claims 1 to 7.