CN110596469A - Method and system for detecting radiation quantity of battery of electric automobile - Google Patents

Abstract

The invention provides a method and a system for detecting the radiation quantity of an electric automobile battery, wherein the method comprises the following steps: selecting a vehicle to be tested; determining variable parameters and non-variable parameters of a vehicle to be tested; and according to the variable parameters, carrying out radiation quantity detection on the preset position of the vehicle to be detected, and outputting a radiation quantity detection result. According to the variable control method, the radiation quantity of the battery of the electric automobile can be accurately detected, so that reliable basis is provided for avoiding and reducing radiation, and radiation damage to people in the automobile is reduced.

Description

Method and system for detecting radiation quantity of battery of electric automobile

Technical Field

The invention relates to the technical field of vehicles, in particular to a method and a system for detecting the radiation quantity of an electric automobile battery.

Background

Batteries for electric vehicles produce non-ionizing radiation during use. Non-ionizing radiation is radiation below the frequency of 3 x 1015 hz, also known as electromagnetic radiation. The measurement of electromagnetic radiation actually comprises two dimensions of magnetic field intensity (unit: mu T) and electric field intensity (unit: V/m), and the current national standard (GB 8702-. And the respective standards at the three different frequencies are also different.

In the low-frequency range, the electric field strength limit value of the national standard is 4000V/m, and the electromagnetic induction strength limit value is 100 mu T; in the radio frequency range, the electric field strength limit value of the national standard is 12V/m; in the static range, the national standard GB 8702-2014 temporarily has no limit on the magnetic field at 0Hz, and the standard electric field strength limit value of the international non-ionizing radiation protection Committee (ICNIRP2009) is cited as 400000 muT.

However, if the radiation level is higher than the corresponding safety value, it may cause various degrees of harm to the human body. Therefore, it is necessary to detect the radiation amount of the battery of the electric vehicle so as to take corresponding protective measures. However, in the driving process, the radiation amount of the battery may change under different driving states, and at present, there is no effective means for detecting the radiation amount of the battery in the driving process of the electric vehicle, so that the protection cannot be effectively performed, and the personal safety of the personnel in the vehicle is not facilitated.

Disclosure of Invention

The present invention is directed to solving at least one of the above problems.

Therefore, an object of the present invention is to provide a method for detecting the radiation quantity of an electric vehicle battery, which can accurately detect the radiation quantity of the electric vehicle battery according to a variable control method, thereby providing a reliable basis for avoiding and reducing radiation, so as to reduce radiation damage to people in the vehicle.

Therefore, the second purpose of the invention is to provide a system for detecting the radiation quantity of the battery of the electric automobile.

In order to achieve the above object, an embodiment of a first aspect of the present invention provides a method for detecting radiation quantity of a battery of an electric vehicle, including the following steps: selecting a vehicle to be tested; determining variable parameters and non-variable parameters of the vehicle to be tested; and detecting the radiation quantity of the preset position of the vehicle to be detected according to the variable parameter, and outputting a radiation quantity detection result.

According to the method for detecting the radiation quantity of the battery of the electric automobile, the vehicle to be detected is selected, and the variable parameter and the non-variable parameter of the vehicle to be detected are determined; according to the variable parameter, the radiant quantity detection is carried out on the preset position of the vehicle to be detected, and the radiant quantity detection result is output, namely, according to the variable control method, the radiant quantity of the battery of the electric automobile can be accurately detected, so that the reliable basis for avoiding and reducing radiation is provided, and the radiation injury to personnel in the automobile is reduced.

In addition, the method for detecting the radiation quantity of the battery of the electric automobile according to the above embodiment of the invention may further have the following additional technical features:

in some examples, the variable parameters include vehicle speed and/or acceleration, the non-variable parameters include battery parameters and environment parameters, and the detecting the radiation amount of the preset position of the vehicle to be detected according to the variable parameters and outputting the radiation amount detection result includes: under the same battery parameters and environmental parameters, adjusting the speed and/or the acceleration to control the vehicle to be tested to enter different driving modes; and under the different driving modes, carrying out radiation quantity detection on the preset position of the vehicle to be detected, and outputting a radiation quantity detection result.

In some examples, the driving modes include: a stationary mode corresponding to a vehicle speed of 0; a first constant speed running mode corresponding to the vehicle speed being a first preset vehicle speed; a second constant speed running mode corresponding to the vehicle speed being a second preset vehicle speed, wherein the second preset vehicle speed is greater than the first preset vehicle speed; a third constant speed running mode corresponding to the vehicle speed being a third preset vehicle speed, wherein the third preset vehicle speed is greater than the second preset vehicle speed; a fourth constant speed running mode corresponding to the vehicle speed being a fourth preset vehicle speed, wherein the fourth preset vehicle speed is greater than the third preset vehicle speed; a first acceleration running mode corresponding to the acceleration being a first preset acceleration; a second acceleration driving mode corresponding to the acceleration being a second preset acceleration, wherein the second preset acceleration is greater than the first preset acceleration; a third acceleration running mode corresponding to an acceleration being a third preset acceleration, wherein the third preset acceleration is greater than the second preset acceleration; and a fourth acceleration running mode corresponding to the acceleration being a fourth preset acceleration, wherein the fourth preset acceleration is greater than the third preset acceleration.

In some examples, the variable parameter includes a battery parameter, the non-variable parameter includes a driving mode and an environmental parameter, and the detecting the radiation amount of the preset position of the vehicle to be detected according to the variable parameter and outputting the detection result of the radiation amount includes: and under the same driving mode and environmental parameters, adjusting the battery parameters, detecting the radiation quantity of the preset position of the vehicle to be detected according to the adjusted battery parameters, and outputting the radiation quantity detection result.

In some examples, the battery parameter includes a content of each chemical element in the battery.

In some examples, further comprising: and generating a radiation protection scheme aiming at each preset position according to the radiation amount detection result.

In some examples, the preset positions include: one or more of a steering wheel, a dashboard, an interior floor, and a front passenger seat.

In some examples, the radiation protection scheme for each preset position includes: moving passengers away from the interior floor or reducing contact time with the interior floor; and/or laying a radiation isolation material on the upper layer of the floor in the vehicle to isolate the radiation.

In some examples, the vehicle under test includes one or more identical electric vehicles.

In order to achieve the above object, an embodiment of a second aspect of the present invention provides a system for detecting a radiation amount of a battery of an electric vehicle, including: the selection module is used for selecting a vehicle to be detected; the determining module is used for determining variable parameters and non-variable parameters of the vehicle to be tested; and the detection module is used for detecting the radiation quantity of the preset position of the vehicle to be detected according to the variable parameter and outputting a radiation quantity detection result.

According to the system for detecting the radiation quantity of the battery of the electric automobile, the vehicle to be detected is selected, and the variable parameter and the non-variable parameter of the vehicle to be detected are determined; according to the variable parameter, the radiant quantity detection is carried out on the preset position of the vehicle to be detected, and the radiant quantity detection result is output, namely, according to the variable control method, the radiant quantity of the battery of the electric automobile can be accurately detected, so that the reliable basis for avoiding and reducing radiation is provided, and the radiation injury to personnel in the automobile is reduced.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is a flow chart of a method of detecting an amount of radiation from a battery of an electric vehicle according to one embodiment of the present invention;

fig. 2 is a block diagram of a system for detecting the amount of radiation from a battery of an electric vehicle according to an embodiment of the present invention.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The following describes a method and a system for detecting the radiation quantity of an electric vehicle battery according to an embodiment of the invention with reference to the accompanying drawings.

Fig. 1 is a flowchart of a method of detecting an amount of radiation from a battery of an electric vehicle according to an embodiment of the present invention. As shown in fig. 1, the method for detecting the radiation quantity of the battery of the electric vehicle comprises the following steps:

step S1: and selecting the vehicle to be tested. Specifically, the vehicle to be tested comprises one or more same electric automobiles.

In a specific embodiment, for example, 5 identical electric vehicles are selected as the test sample, i.e., the vehicle to be tested, so that the accuracy of the test result can be improved.

Step S2: and determining the variable parameter and the non-variable parameter of the vehicle to be tested.

Step S3: and according to the variable parameters, carrying out radiation quantity detection on the preset position of the vehicle to be detected, and outputting a radiation quantity detection result. Namely, the radiation quantity of the battery of the electric automobile can be accurately detected by adopting a variable control method, so that reliable basis is provided for avoiding and reducing radiation, and radiation damage to people in the automobile is reduced.

In one embodiment of the invention, the preset positions comprise: one or more of a steering wheel, a dashboard, an interior floor, and a front passenger seat.

In one embodiment of the invention, the variable parameters include vehicle speed and/or acceleration, and the non-variable parameters include battery parameters and environmental parameters. Based on this, according to the variable parameter, carry out the radiometric detection to the preset position of the vehicle that awaits measuring to the process of output radiometric test result includes: under the same battery parameters and environmental parameters, adjusting the speed and/or acceleration to control the vehicle to be tested to enter different driving modes; and under different driving modes, carrying out radiation quantity detection on the preset position of the vehicle to be detected, and outputting a radiation quantity detection result. Namely, the battery parameters and the environmental parameters are ensured to be unchanged, the vehicle speed and/or the acceleration are/is adjusted, the vehicle to be detected enters different driving modes, and then the radiation quantity of the preset position in the vehicle to be detected is detected in different driving modes, so that the accuracy of the detection result is improved.

Specifically, in an embodiment of the present invention, the driving modes include, for example:

corresponding to a static mode when the vehicle speed is 0, namely the vehicle to be tested is in a static state.

And the first constant speed running mode corresponds to the vehicle speed being a first preset vehicle speed. The first preset vehicle speed is, for example, 20km/h, i.e. the vehicle is in a constant speed running state at 20 km/h.

And a second constant speed running mode corresponding to the vehicle speed being a second preset vehicle speed, wherein the second preset vehicle speed is greater than the first preset vehicle speed. The second preset vehicle speed is, for example, 40km/h, i.e. the vehicle is in a constant speed running state at 40 km/h.

And a third constant speed running mode corresponding to the vehicle speed being a third preset vehicle speed, wherein the third preset vehicle speed is greater than the second preset vehicle speed. The third preset vehicle speed is, for example, 80km/h, i.e. the vehicle is in a constant speed running state at 80 km/h.

And a fourth constant speed running mode corresponding to the vehicle speed being a fourth preset vehicle speed, wherein the fourth preset vehicle speed is greater than the third preset vehicle speed. The fourth preset vehicle speed is, for example, 120km/h, i.e. the vehicle is in a constant speed running state at 120 km/h.

Corresponding to a first acceleration running mode in which the acceleration is a first preset acceleration. The first predetermined acceleration is, for example, 10m/S²I.e. the vehicle is at 10m/S²And accelerating the running state.

A second acceleration running mode corresponding to the acceleration being a second preset acceleration, wherein the second preset accelerationThe acceleration is set to be greater than a first preset acceleration. The second predetermined acceleration is, for example, 20m/S²I.e. the vehicle is at 20m/S²And accelerating the running state.

And a third acceleration running mode corresponding to the acceleration being a third preset acceleration, wherein the third preset acceleration is greater than the second preset acceleration. The third predetermined acceleration is, for example, 30m/S²I.e. the vehicle is at 30m/S²And accelerating the running state.

And a fourth acceleration running mode corresponding to the acceleration being a fourth preset acceleration, wherein the fourth preset acceleration is greater than the third preset acceleration. The fourth predetermined acceleration is, for example, 40m/S²I.e. the vehicle is at 40m/S²And accelerating the running state.

Alternatively, in another embodiment of the present invention, the variable parameters include battery parameters and the non-variable parameters include driving modes and environmental parameters. Based on this, according to the variable parameter, carry out the radiometric detection to the preset position of the vehicle that awaits measuring to the process of output radiometric test result includes: and under the same driving mode and environmental parameters, adjusting battery parameters, detecting the radiation quantity of the preset position of the vehicle to be detected according to the adjusted battery parameters, and outputting a radiation quantity detection result. Namely, the driving mode and the environmental parameters of the vehicle are guaranteed to be unchanged, the battery parameters are adjusted, and the radiation quantity of the preset position in the vehicle to be detected is detected according to the adjusted battery parameters, so that the accuracy of the detection result is improved.

Specifically, the battery parameters include the content of each chemical element in the battery. And adjusting the parameters of the battery, namely adjusting the content of each chemical element. For example, for a high-nickel ternary lithium ion battery, different contents of nickel, cobalt and manganese can be adjusted, and then the radiation amount is detected.

In a specific embodiment, for example, the vehicles to be tested are selected to include 5 identical electric vehicles. The preset positions include: steering wheel position, instrument panel position, floor position, front passenger seat position. The vehicle speed and/or the acceleration are/is used as variable parameters, and the battery parameters and the environment parameters are used as non-variable parameters. Then, keeping the battery parameter and the environmental parameter unchanged, and respectively testing the parameters to be testedAnd (3) measuring different driving modes of the vehicle, such as: a stationary mode, a first constant speed traveling mode at 20km/h, a second constant speed traveling mode at 40km/h, a third constant speed traveling mode at 80km/h, a fourth constant speed traveling mode at 120km/h, a fourth constant speed traveling mode at 10m/S²At a first acceleration running mode of 20m/S²At a second acceleration running mode of 30m/S²At a third acceleration running mode of 40m/S²In the fourth acceleration running mode, the radiation amount, such as the magnetic field intensity, at different positions (such as the position of a steering wheel, the position of an instrument panel, the position of a floor, and the position of a passenger seat) in the vehicle is in units of μ T.

The specific test results are shown in table 1 below.

TABLE 1

It should be noted that the acceleration referred to in table 1 and the foregoing text refers to an absolute value, i.e., includes both acceleration and deceleration conditions.

As can be seen from table 1, in the rest mode, there is a slight, negligible battery radiation at the dashboard. In the constant-speed driving mode, except for the steering wheel, the instrument panel, the floor and the front passenger seat are all provided with trace battery radiation, which indicates that the radiation quantity is irrelevant to the speed of a new electric automobile. The radiation generated by the electric vehicle is not enough to cause harm to human bodies, but the high radiation (compared with the radiation generated in other modes) is generated instantaneously when the electric vehicle is accelerated, and the radiation is obviously reduced after the electric vehicle is driven smoothly due to the release and recovery of the kinetic energy of the driving motor. When in the run-up module, battery radiation at the floor is most severe.

And analyzing the test result: from the driver's point of view, the battery radiation of the steering wheel and the dashboard is negligible, so that the damage of the battery radiation to the driver is essentially absent. From a copilot point of view, the battery radiation of the instrument panel and the seat is negligible, so that the harm of the battery radiation to the passenger in the copilot position is substantially absent. From the point of view of the passengers, the radiation of the battery at the floor is greatest, the type of person who is liable to contact the floor for a long time is generally a child, who falls more easily from the seat to the floor in acceleration and deceleration conditions, thus increasing the contact time with the floor, and is relatively more exposed to radiation.

Based on this, in one embodiment of the invention, the method further comprises: and generating a radiation protection scheme aiming at each preset position according to the radiation amount detection result.

As mentioned above, the preset positions include, for example: one or more of a steering wheel, a dashboard, an interior floor, and a front passenger seat. Based on this, the radiation protection scheme aiming at each preset position comprises the following steps: moving passengers away from the interior floor or reducing contact time with the interior floor; and/or laying a radiation isolation material on the upper layer of the floor in the vehicle to isolate radiation, so as to reduce radiation injury to human bodies. In other words, for children, special protection measures can be provided, which are fixed away from the floor or reduce the contact time with the floor by installing a child seat or other means in acceleration and deceleration states. Further, an isolation material can be arranged on the upper layer of the vehicle floor to isolate and weaken battery radiation, so that radiation damage to the body is reduced.

In a specific embodiment, the variable can be set as a battery parameter, the non-variable can be set as a vehicle speed and/or an acceleration, and then the radiation quantity of the battery of the electric vehicle can be accurately detected through a variable control method, so that a reliable basis is provided for avoiding and reducing radiation, and radiation injury to people in the vehicle is reduced. For example, for a high-nickel ternary lithium ion battery, environmental parameters, a vehicle speed and/or acceleration can be kept unchanged, different contents of nickel, cobalt and manganese are set, and then the radiation amount is detected.

According to the method for detecting the radiation quantity of the battery of the electric automobile, the vehicle to be detected is selected, and the variable parameter and the non-variable parameter of the vehicle to be detected are determined; according to the variable parameter, the radiant quantity detection is carried out on the preset position of the vehicle to be detected, and the radiant quantity detection result is output, namely, according to the variable control method, the radiant quantity of the battery of the electric automobile can be accurately detected, so that the reliable basis for avoiding and reducing radiation is provided, and the radiation injury to personnel in the automobile is reduced.

The invention further provides a system for detecting the radiation quantity of the battery of the electric automobile.

Fig. 2 is a block diagram of a system for detecting the amount of radiation from a battery of an electric vehicle according to an embodiment of the present invention. As shown in fig. 2, the system 100 for detecting the radiation amount of the battery of the electric vehicle includes: a selection module 110, a determination module 120 and a detection module 130.

Specifically, the selection module 110 is used for selecting a vehicle to be tested. Specifically, the vehicle to be tested comprises one or more same electric automobiles.

In a specific embodiment, for example, 5 identical electric vehicles are selected as the test sample, i.e., the vehicle to be tested, so that the accuracy of the test result can be improved.

The determination module 120 is used to determine the variable parameters and the non-variable parameters of the vehicle under test.

The detection module 130 is configured to perform radiation amount detection on a preset position of the vehicle to be detected according to the variable parameter, and output a radiation amount detection result. Namely, the radiation quantity of the battery of the electric automobile can be accurately detected by adopting a variable control method, so that reliable basis is provided for avoiding and reducing radiation, and radiation damage to people in the automobile is reduced.

In one embodiment of the invention, the preset positions comprise: one or more of a steering wheel, a dashboard, an interior floor, and a front passenger seat.

In one embodiment of the invention, the variable parameters include vehicle speed and/or acceleration, and the non-variable parameters include battery parameters and environmental parameters. Based on this, the process that the detection module 130 detects the radiation amount of the preset position of the vehicle to be detected according to the variable parameter and outputs the detection result of the radiation amount includes: under the same battery parameters and environmental parameters, adjusting the speed and/or acceleration to control the vehicle to be tested to enter different driving modes; and under different driving modes, carrying out radiation quantity detection on the preset position of the vehicle to be detected, and outputting a radiation quantity detection result. Namely, the battery parameters and the environmental parameters are ensured to be unchanged, the vehicle speed and/or the acceleration are/is adjusted, the vehicle to be detected enters different driving modes, and then the radiation quantity of the preset position in the vehicle to be detected is detected in different driving modes, so that the accuracy of the detection result is improved.

Specifically, in an embodiment of the present invention, the driving modes include, for example:

corresponding to a static mode when the vehicle speed is 0, namely the vehicle to be tested is in a static state.

And the first constant speed running mode corresponds to the vehicle speed being a first preset vehicle speed. The first preset vehicle speed is, for example, 20km/h, i.e. the vehicle is in a constant speed running state at 20 km/h.

And a second constant speed running mode corresponding to the vehicle speed being a second preset vehicle speed, wherein the second preset vehicle speed is greater than the first preset vehicle speed. The second preset vehicle speed is, for example, 40km/h, i.e. the vehicle is in a constant speed running state at 40 km/h.

And a third constant speed running mode corresponding to the vehicle speed being a third preset vehicle speed, wherein the third preset vehicle speed is greater than the second preset vehicle speed. The third preset vehicle speed is, for example, 80km/h, i.e. the vehicle is in a constant speed running state at 80 km/h.

And a fourth constant speed running mode corresponding to the vehicle speed being a fourth preset vehicle speed, wherein the fourth preset vehicle speed is greater than the third preset vehicle speed. The fourth preset vehicle speed is, for example, 120km/h, i.e. the vehicle is in a constant speed running state at 120 km/h.

Corresponding to a first acceleration running mode in which the acceleration is a first preset acceleration. The first predetermined acceleration is, for example, 10m/S²I.e. the vehicle is at 10m/S²And accelerating the running state.

And a second acceleration running mode corresponding to the acceleration being a second preset acceleration, wherein the second preset acceleration is greater than the first preset acceleration. The second predetermined acceleration is, for example, 20m/S²I.e. the vehicle is at 20m/S²And accelerating the running state.

And a third acceleration running mode corresponding to the acceleration being a third preset acceleration, wherein the third preset acceleration is greater than the second preset acceleration. The third predetermined acceleration is, for example, 30m/S²I.e. the vehicle is at 30m/S²And accelerating the running state.

And a fourth acceleration running mode corresponding to the acceleration being a fourth preset acceleration, wherein the fourth preset acceleration is greater than the third preset acceleration. The fourth predetermined acceleration is, for example, 40m/S²I.e. the vehicle is at 40m/S²And accelerating the running state.

Alternatively, in another embodiment of the present invention, the variable parameters include battery parameters and the non-variable parameters include driving modes and environmental parameters. Based on this, the process that the detection module 130 detects the radiation amount of the preset position of the vehicle to be detected according to the variable parameter and outputs the detection result of the radiation amount includes: and under the same driving mode and environmental parameters, adjusting battery parameters, detecting the radiation quantity of the preset position of the vehicle to be detected according to the adjusted battery parameters, and outputting a radiation quantity detection result. Namely, the driving mode and the environmental parameters of the vehicle are guaranteed to be unchanged, the battery parameters are adjusted, and the radiation quantity of the preset position in the vehicle to be detected is detected according to the adjusted battery parameters, so that the accuracy of the detection result is improved.

Specifically, the battery parameters include the content of each chemical element in the battery. And adjusting the parameters of the battery, namely adjusting the content of each chemical element. For example, for a high-nickel ternary lithium ion battery, different contents of nickel, cobalt and manganese can be adjusted, and then the radiation amount is detected.

In one embodiment of the present invention, the system 100 further comprises a processing module (not shown in the figures). The processing module is used for generating a radiation protection scheme aiming at each preset position according to the radiation amount detection result.

As mentioned above, the preset positions include, for example: one or more of a steering wheel, a dashboard, an interior floor, and a front passenger seat. Based on this, the radiation protection scheme generated by the processing module for each preset position comprises: moving passengers away from the interior floor or reducing contact time with the interior floor; and/or laying a radiation isolation material on the upper layer of the floor in the vehicle to isolate radiation, so as to reduce radiation injury to human bodies. In other words, for example, special protection measures can be provided for children, by mounting a child seat or otherwise, in the acceleration and deceleration states, so as to be away from the floor or to reduce the contact time with the floor. Further, an isolation material can be arranged on the upper layer of the vehicle floor to isolate and weaken battery radiation, so that radiation damage to the body is reduced.

In a specific embodiment, the determining module 120 may further set the variable as a battery parameter, and set the non-variable as a vehicle speed and/or an acceleration, and further, the detecting module 130 may accurately detect the radiation amount of the battery of the electric vehicle through a variable control method, so as to provide a reliable basis for avoiding and reducing radiation, so as to reduce radiation injury to people in the vehicle. For example, for a high-nickel ternary lithium ion battery, environmental parameters, a vehicle speed and/or acceleration can be kept unchanged, different contents of nickel, cobalt and manganese are set, and then the radiation amount is detected.

It should be noted that a specific implementation manner of the system for detecting radiation amount of an electric vehicle battery according to the embodiment of the present invention is similar to a specific implementation manner of the method for detecting radiation amount of an electric vehicle battery according to the embodiment of the present invention, and please refer to the description of the method part specifically, and details are not repeated here in order to reduce redundancy.

According to the system for detecting the radiation quantity of the battery of the electric automobile, the vehicle to be detected is selected, and the variable parameter and the non-variable parameter of the vehicle to be detected are determined; according to the variable parameter, the radiant quantity detection is carried out on the preset position of the vehicle to be detected, and the radiant quantity detection result is output, namely, according to the variable control method, the radiant quantity of the battery of the electric automobile can be accurately detected, so that the reliable basis for avoiding and reducing radiation is provided, and the radiation injury to personnel in the automobile is reduced.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (10)

1. A method for detecting the radiation quantity of an electric automobile battery is characterized by comprising the following steps:

selecting a vehicle to be tested;

determining variable parameters and non-variable parameters of the vehicle to be tested;

and detecting the radiation quantity of the preset position of the vehicle to be detected according to the variable parameter, and outputting a radiation quantity detection result.

2. The method for detecting the battery radiation quantity of the electric automobile according to claim 1, wherein the variable parameters comprise vehicle speed and/or acceleration, the non-variable parameters comprise battery parameters and environment parameters, and the detecting the radiation quantity of the preset position of the vehicle to be detected according to the variable parameters and outputting the radiation quantity detection result comprises:

under the same battery parameters and environmental parameters, adjusting the speed and/or the acceleration to control the vehicle to be tested to enter different driving modes;

and under the different driving modes, carrying out radiation quantity detection on the preset position of the vehicle to be detected, and outputting a radiation quantity detection result.

3. The method for detecting the radiation quantity of the battery of the electric automobile according to claim 2, wherein the driving mode comprises:

a stationary mode corresponding to a vehicle speed of 0;

a first constant speed running mode corresponding to the vehicle speed being a first preset vehicle speed;

a second constant speed running mode corresponding to the vehicle speed being a second preset vehicle speed, wherein the second preset vehicle speed is greater than the first preset vehicle speed;

a third constant speed running mode corresponding to the vehicle speed being a third preset vehicle speed, wherein the third preset vehicle speed is greater than the second preset vehicle speed;

a fourth constant speed running mode corresponding to the vehicle speed being a fourth preset vehicle speed, wherein the fourth preset vehicle speed is greater than the third preset vehicle speed;

a first acceleration running mode corresponding to the acceleration being a first preset acceleration;

a second acceleration driving mode corresponding to the acceleration being a second preset acceleration, wherein the second preset acceleration is greater than the first preset acceleration;

a third acceleration running mode corresponding to an acceleration being a third preset acceleration, wherein the third preset acceleration is greater than the second preset acceleration;

and a fourth acceleration running mode corresponding to the acceleration being a fourth preset acceleration, wherein the fourth preset acceleration is greater than the third preset acceleration.

4. The method for detecting the radiation quantity of the battery of the electric automobile according to claim 1, wherein the variable parameters comprise battery parameters, the non-variable parameters comprise driving modes and environment parameters, and the detecting the radiation quantity of the preset position of the vehicle to be detected according to the variable parameters and outputting the detection result of the radiation quantity comprises:

and under the same driving mode and environmental parameters, adjusting the battery parameters, detecting the radiation quantity of the preset position of the vehicle to be detected according to the adjusted battery parameters, and outputting the radiation quantity detection result.

5. The method for detecting the radiation dose of the battery of the electric automobile according to claim 4, wherein the battery parameter comprises the content of each chemical element in the battery.

6. The method for detecting the radiation quantity of the battery of the electric automobile according to any one of claims 1 to 5, characterized by further comprising:

and generating a radiation protection scheme aiming at each preset position according to the radiation amount detection result.

7. The method for detecting the radiation quantity of the battery of the electric automobile according to claim 1, wherein the preset position comprises: one or more of a steering wheel, a dashboard, an interior floor, and a front passenger seat.

8. The method for detecting the radiation dose of the battery of the electric automobile according to claim 7, wherein the radiation protection scheme for each preset position comprises:

moving passengers away from the interior floor or reducing contact time with the interior floor; and/or

And laying a radiation isolation material on the upper layer of the floor in the vehicle to perform radiation isolation.

9. The method for detecting the radiation dose of the battery of the electric automobile according to claim 1, wherein the vehicle to be detected comprises one or more same electric automobiles.

10. A system for detecting the radiation quantity of an electric automobile battery is characterized by comprising:

the selection module is used for selecting a vehicle to be detected;

the determining module is used for determining variable parameters and non-variable parameters of the vehicle to be tested;

and the detection module is used for detecting the radiation quantity of the preset position of the vehicle to be detected according to the variable parameter and outputting a radiation quantity detection result.