阅读说明：本技术 一种户外基于太阳能的互联网救护车设备 (Outdoor internet ambulance equipment based on solar energy ) 是由 李风雷 于 2019-11-26 设计创作，主要内容包括：本发明提供了一种户外基于太阳能的互联网救护车设备,其包括：救护车、服务器、太阳能充电装置和急救设备；所述服务器内设置有处理器模块、代号编辑模块、用电记录模块、电量显示模块和等级认定模块,所述代号编辑模块用于设置所述救护车的代号a,所述用电记录模块记录每次出勤后所述救护车的耗电等级参数b,所述电量显示模块记录现有电量等级参数c,所述等级认定模块根据所述用电记录模块耗电等级参数b与所述电量显示模块现有电量等级参数c评估出所述救护车可执行的任务等级d；所述处理器模块内设置有基于每辆所述救护车设备现有状态函数F(a,b,c),式中,a为所述救护车的代号,b为耗电等级参数,c为现有电量等级参数。(The invention provides an outdoor solar-based internet ambulance equipment, which comprises: the emergency treatment system comprises an ambulance, a server, a solar charging device and emergency equipment; the server is internally provided with a processor module, a code editing module, an electricity consumption recording module, an electric quantity display module and a grade identification module, wherein the code editing module is used for setting a code a of the ambulance, the electricity consumption recording module records electricity consumption grade parameters b of the ambulance after attendance each time, the electric quantity display module records the existing electric quantity grade parameters c, and the grade identification module evaluates the task grade d executable by the ambulance according to the electricity consumption grade parameters b of the electricity consumption recording module and the existing electric quantity grade parameters c of the electric quantity display module; the processor module is internally provided with a function F (a, b, c) based on the current state of each ambulance equipment, wherein a is the code of the ambulance, b is a power consumption grade parameter, and c is a current electric quantity grade parameter.)

1. An outdoor solar-based internet ambulance apparatus, comprising: an ambulance, a server, a solar charging device and emergency equipment,

the ambulance comprises the solar charging device and the emergency equipment, the server is arranged in the ambulance, the server is communicated with the Internet, preset values and existing state data values of the ambulance equipment of a user are stored in the server, the server matches the ambulance with different electric quantities with rescue work suitable for the electric quantities according to the relevance between the preset values and the existing state data values, and a processor module in the server predicts the usable electric quantity of the ambulance according to weather conditions;

the processor module determines the task level of the ambulance according to the power consumption level and the current electric quantity level so as to adjust the using mode of the ambulance; when the current electric quantity grade is greater than or equal to the power consumption grade, the task grade of the ambulance is the executable rescue task, and the processor module judges the priority of the ambulance again at the moment; when the current electric quantity level is less than the power consumption level, the processor module determines the task level of the ambulance as that the rescue task cannot be executed;

the server is internally provided with a processor module, a code editing module, an electricity consumption recording module, an electric quantity display module and a grade identification module, wherein the code editing module is used for setting a code a of the ambulance, the electricity consumption recording module records electricity consumption grade parameters b of the ambulance after attendance each time, the electric quantity display module records the existing electric quantity grade parameters c, and the grade identification module evaluates the task grade d executable by the ambulance according to the electricity consumption grade parameters b of the electricity consumption recording module and the existing electric quantity grade parameters c of the electric quantity display module;

the processor module is internally provided with a function F (a, b, c) based on the current state of each ambulance equipment, wherein a is the code of the ambulance, b is a power consumption grade parameter, and c is a current electric quantity grade parameter.

2. The outdoor solar-based internet ambulance equipment according to claim 1, wherein said electricity usage recording module counts and records electricity usage of said ambulance after each attendance, said electricity usage recording module determines an electricity consumption level parameter b of said ambulance according to the electricity consumption and kilometer values.

3. The outdoor solar-based internet ambulance equipment according to claim 2, wherein said electricity consumption recording module sets the ambulance power consumption as a primary power consumption within a 5 km journey, with a power consumption level parameter b-1;

in a travel range of more than or equal to 5 kilometers and less than 10 kilometers, the power consumption recording module sets the power consumption of the ambulance as a secondary power consumption, and a power consumption grade parameter b is 2;

in a travel range of more than or equal to 10 kilometers and less than 20 kilometers, the power consumption recording module sets the power consumption of the ambulance as three-level power consumption, and a power consumption level parameter b is 3;

in a travel range of more than or equal to 20 kilometers and less than 40 kilometers, the power consumption recording module sets the power consumption of the ambulance to be four-level power consumption, and a power consumption level parameter b is 4;

and when the travel is more than or equal to 40 kilometers, the power consumption recording module sets the power consumption of the ambulance to be five-level power consumption, and the power consumption level parameter b is 5.

4. The outdoor solar-based internet ambulance equipment according to claim 1, wherein said ambulance further comprises a battery chip, said battery chip detects the remaining power in the onboard battery, said battery chip feeds back a detection structure to said power display module, said power display module ranks the remaining power in said ambulance according to kilometers and power consumption ranking parameters of said power display module.

5. The outdoor solar-based internet ambulance equipment according to claim 4, wherein when the remaining power consumption in said ambulance can satisfy the attendance task of 5 km, said power display module sets the power of said ambulance as a first-class existing power, and an existing power class parameter c is 1;

when the remaining power consumption in the ambulance meets an attendance task of more than or equal to 5 kilometers and less than 10 kilometers, the power display module sets the power of the ambulance as a second-level current power, and the current power level parameter c is 2;

when the remaining power consumption in the ambulance can meet the attendance task of more than or equal to 10 kilometers and less than 20 kilometers, the power display module sets the power of the ambulance as three-level existing power, and the existing power level parameter c is 3;

when the remaining power consumption in the ambulance meets an attendance task of more than or equal to 20 kilometers and less than 40 kilometers, the power display module sets the power of the ambulance to be four-level current power, and the current power level parameter c is 4;

when the remaining power consumption in the ambulance meets the attendance task of more than or equal to 40 kilometers, the power display module sets the power of the ambulance as five-level current power, and the current power level parameter c is 5.

6. The outdoor solar-based internet ambulance equipment according to claim 1, further comprising a light sensor, said light sensor transmitting a light-sensitive electrical signal into said processor module, said processor module including a timer therein, said processor module calculating a pre-charge Δ c generated by said solar charging device during the execution of a rescue mission by said ambulance based on the signals transmitted back from said timer and said light sensor.

7. The outdoor solar-based internet ambulance apparatus according to claim 6, wherein said timer starts timing by means of an electrical signal returned by said light sensor to determine a current time; when the external brightness reaches the preset brightness, the light sensor sends a timing starting signal to the timer, and when the external brightness is smaller than the preset brightness, the light sensor sends a timing closing signal to the timer, wherein the preset brightness is related to the solar charger, and when the solar charger starts to receive solar charging, the external brightness is the preset brightness.

8. The outdoor solar-based internet ambulance equipment according to claim 7, wherein said processor module obtains local weather information from the internet in real-time, said class determination module taking into account said pre-increased power Δ c when assessing said ambulance task execution class if said weather forecast indicates a clear day, and not taking into account said pre-increased power Δ c if said weather forecast does not indicate a clear day;

the timing time of the timer is set to be 6 hours, and the pre-charging quantity delta c is not considered in the rescue actions of the ambulance after the timer starts timing for 4 hours.

9. The outdoor solar-based internet ambulance equipment of claim 8, wherein said processor module evaluates an ambulance executable task class d according to said electricity consumption recording module electricity consumption level parameter b and said electricity quantity display module existing electricity quantity level parameter c, said task class d comprising a non-executable rescue task and an executable rescue task;

when the existing electric quantity grade parameter c is equal to 1, the task grade d of the ambulance is that the rescue task cannot be executed; the processor module sets a real-time power consumption level parameter b for the position information of the injury and the patient for help through the Internet;

when the pre-increment quantity delta c is not considered and the numerical value of the existing quantity of electricity grade parameter c is less than or equal to the value of the real-time electricity consumption grade parameter b, the task grade d of the ambulance is that the rescue task cannot be executed;

when the pre-increment quantity delta c is not considered and the numerical value of the existing quantity of electricity grade parameter c is greater than the value of the real-time electricity consumption grade parameter b, the task grade d of the ambulance is an executable rescue task;

and when the pre-increased electric quantity delta c is considered and the value of the existing electric quantity grade parameter c is greater than or equal to the value of the real-time electric consumption grade parameter b, the task grade d of the ambulance is the executable rescue task.

10. The outdoor solar-based internet ambulance equipment according to claim 8, wherein task level d comprises non-performable rescue tasks, first priority executive tasks and second priority executive tasks;

the processor module sets a real-time power consumption level parameter b for the position information of the injury and the patient for help through the Internet; when the pre-increment quantity delta c is not considered and the numerical value of the existing quantity of electricity grade parameter c is less than or equal to the value of the real-time electricity consumption grade parameter b, the task grade d of the ambulance is that the rescue task cannot be executed;

when the pre-increment quantity delta c is not considered and c-b is equal to 1, the task grade d of the ambulance is a second priority execution task, wherein b is a real-time power consumption grade parameter, and c is an existing power grade parameter;

when the pre-increased electric quantity delta c is considered and c is equal to b, the task grade d of the ambulance is a task executed by a second priority, wherein b is a real-time electric consumption grade parameter and c is an existing electric quantity grade parameter;

when the pre-increment quantity delta c is not considered and c-b is larger than 1, the task grade d of the ambulance is a first priority execution task, wherein b is a real-time power consumption grade parameter, and c is an existing power quantity grade parameter;

when the pre-increased electric quantity delta c is considered and c is larger than b, the task grade d of the ambulance is a first priority execution task, wherein b is a real-time electricity consumption grade parameter and c is an existing electric quantity grade parameter.

Technical Field

The present invention relates generally to the field of ambulance technology, and more particularly to an outdoor solar-based internet ambulance equipment.

Background

With the continuous improvement of medical level, the rescue concept is more advanced, and the continuous update of emergency equipment makes the emergency treatment of patients on an emergency ambulance possible; in some emergency situations, a large number of injured people often need to be rescued on site; in the existing environment, most ambulances used by hospitals in China do not have a field rescue function or the number of ambulance equipment which is owned by hospitals and can carry out outdoor rescue is very small, so that the normal rescue requirements cannot be met; on the other hand, as the emergency equipment on the ambulance capable of doing outdoor rescue needs to be electrified to work, the ambulance needs a lot of time to charge after each attendance, which greatly delays the use efficiency of the ambulance, thereby making the rescue work difficult; to this end, the present invention provides an outdoor solar-based internet ambulance equipment to at least partially solve the above-mentioned problems.

Disclosure of Invention

In this summary, concepts in a simplified form are introduced that are further described in the detailed description section. This summary of the invention is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

To at least partially solve the above technical problems, the present invention provides an outdoor solar-based internet ambulance equipment, comprising: an ambulance, a server, a solar charging device and emergency equipment,

the ambulance comprises the solar charging device and the emergency equipment, the server is arranged in the ambulance, the server is communicated with the Internet, preset values and existing state data values of the ambulance equipment of a user are stored in the server, the server matches the ambulance with different electric quantities with rescue work suitable for the electric quantities according to the relevance between the preset values and the existing state data values, and a processor module in the server predicts the usable electric quantity of the ambulance according to weather conditions;

the processor module determines the task level of the ambulance according to the power consumption level and the current electric quantity level so as to adjust the using mode of the ambulance; when the current electric quantity grade is greater than or equal to the power consumption grade, the task grade of the ambulance is the executable rescue task, and at the moment, the processor module further judges the priority of the ambulance; when the current electric quantity level is less than the power consumption level, the processor module determines the task level of the ambulance as that the rescue task cannot be executed;

the server is internally provided with a processor module, a code editing module, an electricity consumption recording module, an electric quantity display module and a grade identification module, wherein the code editing module is used for setting a code a of the ambulance, the electricity consumption recording module records electricity consumption grade parameters b of the ambulance after attendance each time, the electric quantity display module records the existing electric quantity grade parameters c, and the grade identification module evaluates the task grade d executable by the ambulance according to the electricity consumption grade parameters b of the electricity consumption recording module and the existing electric quantity grade parameters c of the electric quantity display module;

the processor module is internally provided with a function F (a, b, c) based on the current state of each ambulance equipment, wherein a is the code of the ambulance, b is a power consumption grade parameter, and c is a current electric quantity grade parameter.

Furthermore, the electricity consumption recording module is used for counting and recording the electricity consumption of the ambulance after attendance at each time, and the electricity consumption recording module determines the electricity consumption grade parameter b of the ambulance according to the electricity consumption and the kilometer value.

Further, within a 5 km journey, the power consumption recording module sets the power consumption of the ambulance as a first-level power consumption, and the power consumption level parameter b is 1;

in a travel range of more than or equal to 5 kilometers and less than 10 kilometers, the power consumption recording module sets the power consumption of the ambulance as a secondary power consumption, and a power consumption grade parameter b is 2;

in a travel range of more than or equal to 10 kilometers and less than 20 kilometers, the power consumption recording module sets the power consumption of the ambulance as three-level power consumption, and a power consumption level parameter b is 3;

in a travel range of more than or equal to 20 kilometers and less than 40 kilometers, the power consumption recording module sets the power consumption of the ambulance to be four-level power consumption, and a power consumption level parameter b is 4;

and when the travel is more than or equal to 40 kilometers, the power consumption recording module sets the power consumption of the ambulance to be five-level power consumption, and the power consumption level parameter b is 5.

Furthermore, the ambulance further comprises a battery chip, the battery chip detects the residual electric quantity in the vehicle-mounted battery, the battery chip feeds back the detection structure to the electric quantity display module, and the electric quantity display module performs grade division on the residual electric quantity in the ambulance according to the kilometer number and the power consumption grade parameter of the electric quantity display module.

Further, when the remaining power consumption in the ambulance can meet the attendance task of 5 kilometers, the power display module sets the power of the ambulance as a first-level current power, and a current power level parameter c is 1;

when the remaining power consumption in the ambulance meets an attendance task of more than or equal to 5 kilometers and less than 10 kilometers, the power display module sets the power of the ambulance as a second-level current power, and the current power level parameter c is 2;

when the remaining power consumption in the ambulance can meet the attendance task of more than or equal to 10 kilometers and less than 20 kilometers, the power display module sets the power of the ambulance as three-level existing power, and the existing power level parameter c is 3;

when the remaining power consumption in the ambulance meets an attendance task of more than or equal to 20 kilometers and less than 40 kilometers, the power display module sets the power of the ambulance to be four-level current power, and the current power level parameter c is 4;

when the remaining power consumption in the ambulance meets the attendance task of more than or equal to 40 kilometers, the power display module sets the power of the ambulance as five-level current power, and the current power level parameter c is 5.

Further, the ambulance also comprises a light sensor, the light sensor transmits a light-sensitive electric signal to the processor module, the processor module comprises a timer, and the processor module calculates the pre-charging amount delta c generated by the solar charging device in the process of executing the rescue task by the ambulance according to the signal transmitted back by the timer and the light sensor.

Further, the timer starts to time through an electric signal transmitted back by the light sensor so as to determine the current time; when the external brightness reaches the preset brightness, the light sensor sends a timing starting signal to the timer, and when the external brightness is smaller than the preset brightness, the light sensor sends a timing closing signal to the timer, wherein the preset brightness is related to the solar charger, and when the solar charger starts to receive solar charging, the external brightness is the preset brightness.

Further, the server acquires local weather information from the internet in real time, if the weather forecast shows that the weather forecast is sunny, the level determination module takes the pre-increased electric quantity delta c into consideration when evaluating the level of the ambulance executing the task, and if the weather forecast does not show that the weather forecast is sunny, the pre-increased electric quantity delta c is not considered;

the timing time of the timer is set to be 6 hours, and the pre-charging quantity delta c is not considered in the rescue actions of the ambulance after the timer starts timing for 4 hours.

Further, the processor module evaluates an executable task grade d of the ambulance according to the power consumption grade parameter b of the power consumption recording module and the current power quantity grade parameter c of the power quantity display module, wherein the task grade d comprises an unexecutable rescue task and an executable rescue task;

when the existing electric quantity grade parameter c is equal to 1, the task grade d of the ambulance is that the rescue task cannot be executed; the processor module sets a real-time power consumption level parameter b for the position information of the injury and the patient for help through the Internet;

when the pre-increment quantity delta c is not considered and the numerical value of the existing quantity of electricity grade parameter c is less than or equal to the value of the real-time electricity consumption grade parameter b, the task grade d of the ambulance is that the rescue task cannot be executed;

when the pre-increment quantity delta c is not considered and the numerical value of the existing quantity of electricity grade parameter c is greater than the value of the real-time electricity consumption grade parameter b, the task grade d of the ambulance is an executable rescue task;

and when the pre-increased electric quantity delta c is considered and the value of the existing electric quantity grade parameter c is greater than or equal to the value of the real-time electric consumption grade parameter b, the task grade d of the ambulance is the executable rescue task.

Further, the task level d includes non-executable rescue tasks, first priority execution tasks, and second priority execution tasks;

the processor module sets a real-time power consumption level parameter b for the position information of the injury and the patient for help through the Internet; when the pre-increment quantity delta c is not considered and the numerical value of the existing quantity of electricity grade parameter c is less than or equal to the value of the real-time electricity consumption grade parameter b, the task grade d of the ambulance is that the rescue task cannot be executed;

when the pre-increment quantity delta c is not considered and c-b is equal to 1, the task grade d of the ambulance is a second priority execution task, wherein b is a real-time power consumption grade parameter, and c is an existing power grade parameter;

when the pre-increased electric quantity delta c is considered and c is equal to b, the task grade d of the ambulance is a task executed by a second priority, wherein b is a real-time electric consumption grade parameter and c is an existing electric quantity grade parameter;

when the pre-increment quantity delta c is not considered and c-b is larger than 1, the task grade d of the ambulance is a first priority execution task, wherein b is a real-time power consumption grade parameter, and c is an existing power quantity grade parameter;

when the pre-increased electric quantity delta c is considered and c is larger than b, the task grade d of the ambulance is a first priority execution task, wherein b is a real-time electricity consumption grade parameter and c is an existing electric quantity grade parameter.

Compared with the prior art, the invention has the beneficial effects that:

the ambulance is provided with a server, a preset value and an existing state data value of the ambulance equipment of a user are stored in the server, the preset value of the ambulance equipment comprises a power consumption level and an ambulance task level, the existing state data value comprises an existing electric quantity level, and a processor module determines the task level of the ambulance according to the power consumption level and the existing electric quantity level so as to adjust the using mode of the ambulance; when the current electric quantity grade is greater than or equal to the power consumption grade, the task grade of the ambulance is the executable rescue task, and at the moment, the processor module further judges the priority of each ambulance; when the current electric quantity level is less than the power consumption level, the processor module determines the task level of the ambulance as the non-executable rescue task. According to the invention, through the relevance of the preset value of the internet ambulance equipment based on solar energy and the existing state data value, the ambulances with different electric quantities are matched with the ambulance work suitable for the electric quantities, so that the ambulances can still execute some emergency tasks with less electric consumption under the condition of insufficient electric quantities, and the emergency efficiency is improved; on the other hand, the ambulance equipment provided by the invention also has a solar charging function, and the processor module can reasonably estimate the available electric quantity of the ambulance according to weather conditions.

Further, the task level d of the present invention includes a non-executable rescue task, a first priority execution task and a second priority execution task; when a plurality of ambulance vehicles exist, the rescue personnel can select proper ambulance vehicles to execute tasks according to the priority level evaluated by the server.

Particularly, the electric energy generated by the solar power generation device is set as the pre-increased electric quantity delta c, the pre-increased electric quantity delta c influences the rating of the task grade, and the rating effect of the pre-increased electric quantity delta c on the task grade is determined by combining weather forecast and the working time of the solar power generation device, so that the accuracy of the pre-increased electric quantity delta c is improved.

Further, the power consumption recording module of the invention records the power consumption level parameter b of the ambulance after each attendance, the power display module records the existing power level parameter c, and when the existing power level parameter c of each ambulance is smaller than the real-time power consumption level parameter b, the ambulance of the invention can also select a proper ambulance to perform rescue tasks in a take-over manner according to the specific values of the parameter b and the parameter c, for example: setting the existing electric quantity grade parameters c of the ambulances participating in the rescue task as c₁、c₂、c₃，c₁、c₂、c₃Need to satisfy c₁+c₂+c₃≥b。

Drawings

In order that the advantages of the invention will be readily understood, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments that are illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered to be limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings.

FIG. 1 is a schematic structural diagram of an outdoor solar-based Internet ambulance equipment according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a connection relationship between the internet and each module in the server according to an embodiment of the present invention.

Detailed Description

In the following description, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. It will be apparent, however, to one skilled in the art, that embodiments of the invention may be practiced without one or more of these specific details. In other instances, well-known features have not been described in detail so as not to obscure the embodiments of the invention.

In the following description, a detailed structure will be presented for a thorough understanding of embodiments of the invention. It is apparent that the implementation of the embodiments of the present invention is not limited to the specific details familiar to those skilled in the art. The following detailed description of preferred embodiments of the invention, however, the invention is capable of other embodiments in addition to those detailed.

In the description of the present invention, the terms "inside", "outside", "longitudinal", "transverse", "upper", "lower", "top", "bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are for convenience only to describe the present invention without requiring the present invention to be necessarily constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1 and 2, an embodiment of the present invention provides an outdoor solar-based internet ambulance equipment, which comprises: the solar emergency ambulance system comprises an ambulance 1, a server 2, a solar charging device 3 and emergency equipment 4, wherein a preset value and an existing state data value of outdoor solar-based internet ambulance equipment are stored in the server 2;

specifically, the preset value of the ambulance equipment comprises a power consumption level and an ambulance task level, the existing state data value comprises an existing electric quantity level, and the processor module determines the task level of the ambulance 1 according to the power consumption level and the existing electric quantity level so as to adjust the using mode of the ambulance 1; when the current electric quantity grade is greater than or equal to the power consumption grade, the task grade of the ambulance 1 is the executable rescue task, and at the moment, the processor module further judges the priority of each ambulance 1; when the current electric quantity level is less than the power consumption level, the processor module determines the task level of the ambulance 1 as non-executable rescue task. According to the embodiment of the invention, through the relevance of the preset value of the internet ambulance equipment based on solar energy and the data value of the existing state, the ambulances with different electric quantities are matched with the ambulance work suitable for the electric quantities, so that the ambulances can still execute some first-aid tasks with less electric consumption under the condition of insufficient electric quantities, and the first-aid efficiency is improved; on the other hand, the ambulance equipment provided by the embodiment of the invention also has a solar charging function, and the processor module can reasonably estimate the available electric quantity of the ambulance according to weather conditions.

Specifically, each module in server 2 all communicates with the internet to through internet transfer information, ambulance 1 includes solar charging device 3 and emergency equipment 4, solar charging device 3 is used for charging 4 for emergency equipment.

Specifically, be provided with processor module, code editing module, power consumption record module, electric quantity display module in the server 2, the grade is affirmed the module, code editing module is used for setting up every ambulance 1's code a, power consumption record module record every turn the power consumption level parameter b of this ambulance 1 that attendance, electric quantity display module record current electric quantity level parameter c, the executable task grade d of this ambulance is evaluateed out according to power consumption record module power consumption level parameter b and the current electric quantity level parameter c of electric quantity display module to the grade affirmation module. The processor module is internally provided with a function F (a, b, c) based on the current state of each ambulance equipment, wherein a is the code of the ambulance, b is a power consumption grade parameter, and c is a current electric quantity grade parameter; the processor module rationally allocates use of the ambulance based on the state model.

Specifically, the code editing module numbers each ambulance which can be rescued outdoors in the hospital, sets the code a to 1, a to 2, a to 3, and so on.

Specifically, the power consumption recording module is used for counting and recording the power consumption of the ambulance on each attendance; in the embodiment of the invention, the first-aid equipment arranged in the ambulance comprises but is not limited to an emergency cot, a cardio-pulmonary resuscitation machine, an electrocardiogram equipment, a respirator, an infusion injection pump, a defibrillator, an in-car lamp, an aspirator and a cooling and warming all-in-one machine; the electricity consumption recording module records the total electricity consumption of the emergency equipment during each attendance and records the kilometer value corresponding to the electricity consumption; and the electricity consumption recording module determines the electricity consumption level parameter b of the vehicle according to the electricity consumption and the kilometer value.

Specifically, within a 5-kilometer travel, the power consumption recording module sets the power consumption of the ambulance as first-level power consumption, and the power consumption level parameter b is 1;

in the travel range of more than or equal to 5 kilometers and less than 10 kilometers, the power consumption recording module sets the power consumption of the ambulance as secondary power consumption, and the power consumption grade parameter b is 2;

in the travel range of more than or equal to 10 kilometers and less than 20 kilometers, the power consumption recording module sets the power consumption of the ambulance as three-level power consumption, and the power consumption grade parameter b is 3;

in the travel range of more than or equal to 20 kilometers and less than 40 kilometers, the power consumption recording module sets the power consumption of the ambulance as four-level power consumption, and the power consumption level parameter b is 4;

when the travel is more than or equal to 40 kilometers, the power consumption recording module sets the power consumption of the ambulance as five-level power consumption, and the power consumption level parameter b is 5; wherein, the higher the power consumption level, the larger the power consumption, and the power consumption of the embodiment of the present invention is the total power consumption required for the ambulance 1 to perform the rescue task.

Specifically, a battery chip is arranged on a vehicle-mounted battery box of the ambulance 1 in the embodiment of the present invention, the battery chip detects the remaining power in the battery, and feeds back a detection structure to a power display module, and the power display module performs grade division on the remaining power in the ambulance according to the number of kilometers and data in the power display module:

when the remaining power consumption in the ambulance can only meet the attendance task of 5 kilometers, the power display module sets the power of the ambulance as the first-level existing power, and the existing power level parameter c is 1;

when the remaining power consumption in the ambulance can meet the attendance task of more than or equal to 5 kilometers and less than 10 kilometers, the power display module sets the power of the ambulance as the second-level current power, and the current power level parameter c is 2;

when the remaining power consumption in the ambulance can meet the attendance task of more than or equal to 10 kilometers and less than 20 kilometers, the power display module sets the power of the ambulance as three-level current power, and the current power level parameter c is 3;

when the remaining power consumption in the ambulance can meet the attendance task of more than or equal to 20 kilometers and less than 40 kilometers, the power display module sets the power of the ambulance as four-level current power, and the current power level parameter c is 4;

when the remaining power consumption in the ambulance can meet the attendance task of more than or equal to 40 kilometers, the power display module sets the power of the ambulance as the five-level existing power, and the existing power level parameter c is 5.

Specifically, the ambulance is charged by the solar charging device while going out; the light sensor 5 is arranged on the ambulance equipment of the embodiment of the invention, the light sensor 5 transmits a light-sensitive electric signal to the processor module, the processor module comprises a timer, and the processor module calculates the pre-charging quantity delta c generated by the solar charging device in the process of executing the rescue task by the ambulance 1 according to the signal transmitted back by the timer and the light sensor 5; the timer starts to time through an electric signal transmitted back by the light sensor so as to determine the current time; when the external brightness reaches the preset brightness, the light sensor 5 sends a timing starting signal to the timer, and when the external brightness is smaller than the preset brightness, the light sensor 5 sends a timing closing signal to the timer, wherein the preset brightness is related to the solar charger, and when the solar charger starts to receive solar charging, the external brightness is the preset brightness. The processor module acquires local weather information from the Internet in real time, and if the weather forecast shows that the weather forecast does not show that the weather forecast shows that the weather forecast does not show. In the embodiment of the invention, the timing time of the timer is set to be 6 hours, and the pre-charging quantity delta c is not considered in the rescue action performed after the timer starts to time for 4 hours.

Specifically, the processor module evaluates the task level d executable by the ambulance according to the power consumption level parameter b of the power consumption recording module and the current power level parameter c of the power display module;

when there is only one ambulance, the task grade d includes non-executable rescue tasks and executable rescue tasks, and the grade assessment method of the grade determination module is as follows:

when the current electric quantity grade parameter c is equal to 1, the task grade d of the ambulance is that the rescue task cannot be executed;

the processor module sets a real-time power consumption level parameter b for the position information of the wounded seeking help through the internet; when the pre-increment quantity delta c is not considered and the numerical value of the existing quantity of electricity grade parameter c is less than or equal to the value of the real-time electricity consumption grade parameter b, the task grade d of the ambulance is that the rescue task cannot be executed;

when the pre-increment quantity delta c is not considered and the value of the existing quantity of electricity grade parameter c is larger than the value of the real-time electricity consumption grade parameter b, the task grade d of the ambulance is the executable rescue task;

when the pre-increased electric quantity delta c is considered and the value of the existing electric quantity grade parameter c is larger than or equal to the value of the real-time electric consumption grade parameter b, the task grade d of the ambulance is that the ambulance task can be executed.

When at least two ambulances are included, the task level d includes non-performable rescue tasks, a first priority to perform tasks, and a second priority to perform tasks;

the processor module sets a real-time power consumption level parameter b for the position information of the wounded seeking help through the internet; when the pre-increment quantity delta c is not considered and the numerical value of the existing quantity of electricity grade parameter c is less than or equal to the value of the real-time electricity consumption grade parameter b, the task grade d of the ambulance is that the rescue task cannot be executed;

when the pre-increment quantity delta c is not considered and c-b is equal to 1, the task grade d of the ambulance is a second priority to execute the task, wherein b is a real-time power consumption grade parameter, and c is an existing power grade parameter;

when the pre-increased electric quantity delta c is considered and c is equal to b, the task grade d of the ambulance is a task executed by a second priority, wherein b is a real-time electric consumption grade parameter and c is an existing electric quantity grade parameter;

when the pre-increment quantity delta c is not considered and c-b is larger than 1, the task grade d of the ambulance is a first priority execution task, wherein b is a real-time power consumption grade parameter, and c is an existing power quantity grade parameter;

when the pre-increased electric quantity delta c is considered and c is larger than b, the task grade d of the ambulance is a first priority execution task, wherein b is a real-time electric consumption grade parameter and c is an existing electric quantity grade parameter.

In some embodiments of the invention, when the existing electric quantity grade parameter c of each ambulance is less than the real-time power consumption grade parameter b, a plurality of ambulances can be considered to perform a rescue task in a take-over manner, and the existing electric quantity grade parameters c of the ambulances participating in the rescue task are respectively set as c₁、c₂、c₃Push with the subclass, and c₁、c₂、c₃By analogy, c should be satisfied₁+c₂+c₃≥b。

Unless defined otherwise, technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Terms such as "component" and the like, when used herein, can refer to either a single part or a combination of parts. Terms such as "mounted," "disposed," and the like, as used herein, may refer to one component as being directly attached to another component or one component as being attached to another component through intervening components. Features described herein in one embodiment may be applied to another embodiment, either alone or in combination with other features, unless the feature is otherwise inapplicable or otherwise stated in the other embodiment.

The present invention has been described in terms of the above embodiments, but it should be understood that the above embodiments are for purposes of illustration and description only and are not intended to limit the invention to the scope of the described embodiments. It will be appreciated by those skilled in the art that many variations and modifications may be made to the teachings of the invention, which fall within the scope of the invention as claimed.