CN203747443U - Vehicular solar charging system and automobile - Google Patents

Abstract

The utility model provides a vehicular solar charging system and an automobile. The vehicular solar charging system comprises a solar skylight; an on-board battery; a battery manager detecting the battery information of the on-board battery; a light sensation device detecting light conditions; and a controller. The controller is connected with the solar skylight, the battery manager and the light sensation device. The controller controls the solar skylight to charge the on-board battery according to the battery information of the on-board battery and the light conditions. The vehicular solar charging system which controls the solar skylight to charge the on-board battery through the controller according to the battery information of the on-board battery and the light conditions after an automobile engine stops working can ensure that the on-board battery works with sufficient electric energy and further guarantee the normal starting of the automobile. Moreover, the on-board battery can be prevented from suffering electric energy shortage. The service lifetime of the on-board battery is thus prolonged.

Description

Automobile-used solar recharging system and automobile

Technical field

The utility model relates to automobile technical field, particularly a kind of automobile-used solar recharging system and automobile.

Background technology

Along with the development of automotive engineering, the function of automobile is more and more, as functions such as door lock automatic control function, anti-theft features.The control of these functions all depends on the power source of automobile or the on-vehicle battery in automobile.But when automobile parking, most functions of automobile also need to continue to use, and now, cannot for these functions, power by the power source of automobile, can only rely on on-vehicle battery to power to these functions.So long-term, make on-vehicle battery in power shortage state, if the too low normal startup that can affect automobile of the electric weight of on-vehicle battery brings very big inconvenience to user.In addition, on-vehicle battery, for a long time in power shortage state, also can affect the useful life of on-vehicle battery.

Utility model content

The utility model is intended to solve the problems of the technologies described above at least to a certain extent.

For this reason, first object of the present utility model is to propose a kind of automobile-used solar recharging system, can make on-vehicle battery can not guarantee the normal startup of automobile in power shortage state, and extend the useful life of on-vehicle battery.

Second object of the present utility model is to propose a kind of automobile.

For reaching above-mentioned purpose, according to the utility model first aspect embodiment, a kind of automobile-used solar recharging system has been proposed, comprising: solar energy skylight; On-vehicle battery; Detect the battery manager of the battery information of described on-vehicle battery; Detect the light sensation device of illumination condition; And controller, described controller is connected with described solar energy skylight, described battery manager and described light sensation device, and described controller is controlled described solar cell vehicle window to described charging on-vehicle battery according to the battery information of described on-vehicle battery and described illumination condition.

The automobile-used solar recharging system of the utility model embodiment, the illumination condition of the battery information of the on-vehicle battery that controller can detect according to battery manager and light sensation units test, controlling solar energy skylight charges to on-vehicle battery, make after automobile engine quits work, can utilize solar energy skylight to convert solar energy into electrical energy charges for on-vehicle battery, thereby can make on-vehicle battery under sufficient electric weight, work guaranteeing, guaranteed the normal startup of automobile, and on-vehicle battery can be in power shortage state, and then extended useful life of on-vehicle battery.

In addition, automobile-used solar recharging system of the present utility model also has following additional technical feature:

In an embodiment of the present utility model, described on-vehicle battery comprises storage battery or/and electrokinetic cell bag.

In another embodiment of the present utility model, described battery manager is for detecting the first battery manager of the battery information of described electrokinetic cell bag, described controller is connected with described solar energy skylight, described the first battery manager and described light sensation device, and described controller is controlled described solar cell vehicle window according to the battery information of described electrokinetic cell bag and described illumination condition and charged to described electrokinetic cell bag.

Described storage battery comprises battery pack, the second battery manager and charging DC/DC, described battery manager is for detecting the second battery manager of the battery pack information of described storage battery, described controller is connected with described solar energy skylight, described the second battery manager and described light sensation device, and described controller is controlled described solar cell vehicle window to described charge in batteries according to the battery pack information of described storage battery and described illumination condition.

Described the second battery manager is connected with battery pack with charging DC/DC respectively, and described the second battery manager detects described battery pack information, and controls charging DC/DC to described batteries charging.

Described battery manager comprises the first battery manager of the battery information that detects described electrokinetic cell bag and the second battery manager that detects the battery pack information of described storage battery, described controller and described solar energy skylight, described the first battery manager is connected with described light sensation device, described controller is controlled described solar cell vehicle window according to the battery information of described electrokinetic cell bag and described illumination condition and is charged to described electrokinetic cell bag, and described controller and described solar energy skylight, described the second battery manager is connected with described light sensation device, described controller is controlled described solar cell vehicle window to described charge in batteries according to the battery pack information of described storage battery and described illumination condition.

Described automobile-used solar recharging system, also comprises direct current transducer, and described direct current transducer is connected with described electrokinetic cell bag; And relay, described relay is connected with described storage battery, described controller and described direct current converter; Described electrokinetic cell bag charges a battery by direct current transducer and relay.

The utility model second aspect embodiment provide a kind of automobile, comprises the automobile-used solar recharging system of the utility model first aspect embodiment.

The automobile of the utility model embodiment, the battery information of the on-vehicle battery that can detect according to battery manager by automobile-used solar recharging system and the illumination condition of light sensation units test, controlling solar energy skylight charges to on-vehicle battery, make after automobile engine quits work, can utilize solar energy skylight to convert solar energy into electrical energy charges for on-vehicle battery, thereby can make on-vehicle battery under sufficient electric weight, work guaranteeing, guaranteed the normal startup of automobile, and on-vehicle battery can be in power shortage state, and then extended useful life of on-vehicle battery.

Additional aspect of the present utility model and advantage in the following description part provide, and part will become obviously from the following description, or recognize by practice of the present utility model.

Accompanying drawing explanation

Above-mentioned and/or additional aspect of the present utility model and advantage accompanying drawing below combination obviously and is easily understood becoming the description of embodiment, wherein:

Fig. 1 is according to the structured flowchart of the automobile-used solar recharging system of an embodiment of the utility model;

Fig. 2 is according to the structured flowchart of the automobile-used solar recharging system of an embodiment intermediate fuel oil car of the utility model;

Fig. 3 is according to the structured flowchart of the automobile-used solar recharging system of hybrid electric vehicle or pure electric vehicle in embodiment of the utility model.

Embodiment

Describe embodiment of the present utility model below in detail, the example of described embodiment is shown in the drawings, and wherein same or similar label represents same or similar element or has the element of identical or similar functions from start to finish.Below by the embodiment being described with reference to the drawings, be exemplary, only for explaining the utility model, and can not be interpreted as restriction of the present utility model.

In description of the present utility model, it will be appreciated that, term " " center ", " longitudinally ", " laterally ", " on ", D score, " front ", " afterwards ", " left side ", " right side ", " vertically ", " level ", " top ", " end ", " interior ", orientation or the position relationship of indications such as " outward " are based on orientation shown in the drawings or position relationship, only the utility model and simplified characterization for convenience of description, rather than device or the element of indication or hint indication must have specific orientation, with specific orientation structure and operation, therefore can not be interpreted as restriction of the present utility model.In addition, term " first ", " second " be only for describing object, and can not be interpreted as indication or hint relative importance.

In description of the present utility model, it should be noted that, unless otherwise clearly defined and limited, term " installation ", " being connected ", " connection " should be interpreted broadly, and for example, can be to be fixedly connected with, and can be also to removably connect, or connect integratedly; Can be mechanical connection, can be to be also electrically connected to; Can be to be directly connected, also can indirectly be connected by intermediary, can be the connection of two element internals.For the ordinary skill in the art, can concrete condition understand the concrete meaning of above-mentioned term in the utility model.

Solar energy, as the regenerative resource of cleanliness without any pollution, is widely used in all trades and professions.After solar cell power generation technology occurs, solar cell and vehicle dormer window are grouped together and arise at the historic moment in the solar energy skylight that obtains.The solar cell being arranged in vehicle dormer window can convert solar energy into electrical energy, thereby can utilize the electric energy in automobile solar energy skylight to charge to novel storage battery.Predictably, solar energy skylight will be improved self function all the more and promote along with the continuous progress of science and technology.Below with reference to accompanying drawing, describe according to automobile-used solar recharging system and the automobile of the utility model embodiment.

Fig. 1 is according to the structured flowchart of the automobile-used solar recharging system of an embodiment of the utility model.

As shown in Figure 1, according to the automobile-used solar recharging system of the utility model embodiment, comprise solar energy skylight 100, on-vehicle battery 200, battery manager 300, light sensation device 400 and controller 500.

Particularly, in embodiment of the present utility model, on-vehicle battery 200 can comprise storage battery or/and electrokinetic cell bag.As pure electric automobile, described on-vehicle battery 200 can only comprise electrokinetic cell bag, also can comprise electrokinetic cell bag and storage battery simultaneously; As fuel vehicle, described on-vehicle battery 200 only comprises storage battery; As hybrid electric vehicle, described on-vehicle battery 200 comprises electrokinetic cell bag and storage battery.

Battery manager 300 is connected with on-vehicle battery 200, can detect the battery information of on-vehicle battery 200.Wherein, the battery information of on-vehicle battery 200 can comprise dump energy, temperature, voltage of on-vehicle battery 200 etc.Battery manager 300 can pass through CAN(Controller Area Network, controller local area network) battery information is sent to controller 500.

Light sensation device 400 can detect illumination condition.As detect intensity of illumination of 100 current positions, solar energy skylight etc.

Controller 500 is connected with solar energy skylight 100, battery manager 300 and light sensation device 400, and controller 500 is controlled solar energy skylight 100 to on-vehicle battery 200 chargings according to the battery information of on-vehicle battery 200 and illumination condition.In embodiment of the present utility model, controller 500 meets first when pre-conditioned at the battery information of storage battery or electrokinetic cell bag and illumination condition, controls solar energy skylight 100 to storage battery or/and electrokinetic cell bag charges.

Wherein, first is pre-conditioned for storage battery is or/and the battery information of electrokinetic cell bag is less than the first power threshold (as 5% of storage battery total capacity, electrokinetic cell bag total capacity 10%), and the intensity of illumination of 100 current positions, solar energy skylight is greater than illumination threshold value.The first power threshold and illumination threshold value can be set with experience as required.The sustainable detection battery information of battery manager 300 in charging process, and be sent to controller 500, if the dump energy of on-vehicle battery 200 is greater than the second power threshold, if dump energy is 100% of storage battery total capacity, dump energy is 100% of electrokinetic cell bag total capacity, and controller 500 control solar energy skylights 100 stop charging to on-vehicle battery 200.Wherein, the second power threshold is greater than the first power threshold.

As shown in Figure 2, storage battery 210 comprises battery pack 211, the second battery manager 302 and charging DC/DC212, battery manager is for detecting the second battery manager 302 of the battery pack information of storage battery, controller 500 is connected with light sensation device 400 with solar energy skylight 100, the second battery manager 302, and controller 500 is controlled solar cell vehicle window 100 to storage battery 210 chargings according to battery pack 211 information of storage battery 210 and illumination condition.The second battery manager 302 is connected with battery pack 211 with charging DC/DC212 respectively, and the second battery manager 302 detects battery pack 211 information, and controls charging DC/DC212 to batteries charging.

As shown in Figure 3, battery manager comprises the first battery manager 301 of the battery information that detects electrokinetic cell bag 220 and the second battery manager 302 that detects the battery pack information of storage battery 210, controller 500 and solar energy skylight 100, the first battery manager 301 is connected with light sensation device 400, controller 500 is controlled solar cell vehicle window 100 to 220 chargings of electrokinetic cell bag according to the battery information of electrokinetic cell bag 220 and illumination condition, and controller 500 and solar energy skylight 100, the second battery manager 302 is connected with light sensation device 400, controller 500 is controlled solar cell vehicle window 100 to storage battery 210 chargings according to the battery pack information of storage battery 210 and illumination condition.Direct current transducer 600 is connected with electrokinetic cell bag 220, and relay 700 is connected with storage battery 210, controller 500 and direct current transducer 600, and electrokinetic cell bag 220 is by direct current transducer 600 and relay 700 accumulators 210 chargings.

In another embodiment, battery manager is for detecting the first battery manager 301 of the battery information of electrokinetic cell bag 220, controller 500 is connected with light sensation device 400 with solar energy skylight 100, the first battery manager 301, and controller 500 is controlled solar cell vehicle window 100 to 220 chargings of electrokinetic cell bag according to the battery information of electrokinetic cell bag 220 and illumination condition.

To the automobile-used solar recharging system operation principle of the utility model embodiment simply be described below.

After automobile engine or motor quit work, battery manager 300 in automobile continues to detect the battery information of on-vehicle battery 200, and be sent to controller 500 by CAN bus, controller 500 judges according to the battery information of on-vehicle battery 200 whether the dump energy of on-vehicle battery 200 or voltage are less than corresponding threshold value, if be less than, illustrate that on-vehicle battery 200 needs charge controller 500 further by light sensation device 400, to detect current illumination condition, if it is pre-conditioned that current illumination condition meets, be that intensity of illumination surpasses default illumination threshold value, controller 500 100 pairs, solar energy skylight of control on-vehicle batteries 200 charge.If do not meet pre-conditionedly, continue to detect current illumination condition, until that current illumination condition meets is pre-conditioned, controller 500 is controlled 100 pairs, solar energy skylight on-vehicle batteries 200 and is charged.

Battery manager 300 is controlled the charging current of the DC conversion modules in on-vehicle battery 200 in charging process according to battery information; and the lasting information about power that detects on-vehicle battery 200; be sent to controller 500; if the dump energy of on-vehicle battery 200 or voltage are less than corresponding threshold value; as electric weight reaches 100%; controller 500 is controlled charging and is finished, thereby has realized the battery self-protection functions such as monomer and inclusion over-charge protective, charge balancing, monomer and inclusion Cross prevention, overcurrent protection.

Automobile-used solar recharging system of the present utility model, the illumination condition of the battery information of the on-vehicle battery that controller can detect according to battery manager and light sensation units test, controlling solar energy skylight charges to on-vehicle battery, make after automobile engine quits work, can utilize solar energy skylight to convert solar energy into electrical energy charges for on-vehicle battery, thereby can make on-vehicle battery under sufficient electric weight, work guaranteeing, guaranteed the normal startup of automobile, and on-vehicle battery can be in power shortage state, and then extended the useful life of on-vehicle battery.

Fig. 2 is according to the structured flowchart of the automobile-used solar recharging system of an embodiment intermediate fuel oil car of the utility model.In the present embodiment, on-vehicle battery 200 comprises storage battery 210.Particularly, as shown in Figure 2, according to the automobile-used solar recharging system of the utility model embodiment, comprise solar energy skylight 100, storage battery 210, the second battery manager 302, light sensation device 400, controller 500, storage battery 210 comprises battery, 211, the second battery manager 302 and charging DC/DC212, the second battery manager 302 is connected with battery pack 211 with charging DC/DC212 respectively, the second battery manager 212 detects battery pack 211 information, and controls charging DC/DC212 to batteries charging.Above-mentioned storage battery 210 has increased the second battery manager 302 and charging DC/DC212 on the basis of existing storage battery, therefore this storage battery has the state information that self detects battery pack, not only can send to controller 500 battery pack 211 information of storage battery, and can adjust the charge mode of battery pack 211 charging of solar energy skylight 100 accumulators, thereby the function that possesses battery pack 211 intelligent charges of solar energy skylight 100 accumulators, and storage battery 210 can rely on the battery manager of self and charging DC/DC to control completely, avoided causing storage battery 210 not mate with car load ECU because change storage battery 210, the problem that solar energy skylight 100 cannot accumulators 210 be charged normal.

Fig. 3 is according to the structured flowchart of the automobile-used solar recharging system of hybrid electric vehicle or pure electric vehicle in embodiment of the utility model.In the present embodiment, on-vehicle battery 200 comprises storage battery 210 and electrokinetic cell bag 220, according to the automobile-used solar recharging system of the utility model embodiment, comprise solar energy skylight 100, storage battery 210, electrokinetic cell bag 220, the first battery manager 301, the second battery manager 302, light sensation device 400, controller 500, storage battery 210 comprises battery 211, the second battery manager 302 and charging DC/DC212, the second battery manager 302 is connected with battery pack 211 with charging DC/DC212 respectively, the second battery manager 212 detects battery pack 211 information, and control charging DC/DC212 to batteries charging.This system also comprises direct current transducer 600 and relay 700, direct current transducer 600 is connected with electrokinetic cell bag 220, relay 700 is connected with storage battery 210, controller 500 and direct current transducer 600, and electrokinetic cell bag 220 is by direct current transducer 600 and relay 700 accumulators 210 chargings.

In an other embodiment, on-vehicle battery 200 only comprises electrokinetic cell bag 220, according to the automobile-used solar recharging system of the utility model embodiment, comprise solar energy skylight 100, electrokinetic cell bag 220, the first battery manager 301, light sensation device 400, controller 500.Controller 500 is connected with light sensation device 400 with solar energy skylight 100, the first battery manager 301, and controller 500 is controlled solar cell vehicle window 100 to 220 chargings of electrokinetic cell bag according to the battery information of electrokinetic cell bag 220 and illumination condition.

Controller 500 meets first when pre-conditioned at the battery information of on-vehicle battery 200 and illumination condition, controls solar cell vehicle window to storage battery or/and electrokinetic cell bag charges.Wherein, first pre-conditioned for storage battery or/and the battery information of electrokinetic cell bag is less than the first power threshold (as 5% of storage battery total capacity, electrokinetic cell bag total capacity 10%) and the intensity of illumination of 100 current positions, solar energy skylight is greater than illumination threshold value.

Controller 500 meets second when pre-conditioned at the battery information of on-vehicle battery 200 and illumination condition, and control relay is closed, and controls electrokinetic cell bag and charge to storage battery by direct current transducer and relay.Wherein, second is pre-conditioned for the battery information of storage battery is less than the first power threshold, and the battery information of electrokinetic cell bag is greater than the second power threshold, and the intensity of illumination of 100 current positions, solar energy skylight is less than illumination threshold value.Wherein, the second power threshold is greater than the firstth power threshold.

To the automobile-used solar recharging system operation principle of the utility model embodiment simply be described below.

Light sensation device 400 continues to detect current illumination condition, and be sent to controller 500 by CAN bus, battery manager 300 continues to detect the battery information of storage battery 210 and electrokinetic cell bag 220, and the battery information of storage battery 210 and electrokinetic cell bag 220 is sent to controller 500 by CAN bus.Controller 500 meets pre-conditioned at judgement illumination condition, while being more than illumination threshold value as intensity of illumination, according to the battery pack information of storage battery 210, judge that whether storage battery 210 needs charging, if needed, controls 100 pairs, solar energy skylight storage battery 210 and charges.If it is pre-conditioned that illumination condition does not meet, when electrokinetic cell bag 220 electric weight are sufficient, controller 500 control relays are closed, thereby electrokinetic cell bag 220 can be charged by direct current transducer 600 and 700 pairs of storage batterys 210 of relay.

If storage battery 210 does not need charging, further according to the battery information of electrokinetic cell bag 220, judge whether electrokinetic cell bag 220 needs charging, if needed, controller 500 100 pairs, solar energy skylight of control electrokinetic cell bags 220 charge.

In the process that storage battery 210 is charged, controller 500 can be controlled and be charged by solar energy skylight 100 or 220 pairs of storage batterys 210 of electrokinetic cell bag according to illumination condition.

In to the charging process of storage battery 210 and electrokinetic cell bag 220, whether controller 500 can finish according to the battery information control storage battery 210 of storage battery 210 and electrokinetic cell bag 220 and the charging process of electrokinetic cell bag 220.

The automobile-used solar recharging system of the utility model embodiment, can to the electrokinetic cell bag in hybrid vehicle or electric automobile, charge by solar energy skylight, and when illumination condition is bad, by electrokinetic cell bag, storage battery is charged, thereby can make on-vehicle battery under sufficient electric weight, work guaranteeing, guaranteed the normal startup of automobile, and on-vehicle battery can be in power shortage state, and then extended the useful life of on-vehicle battery.In addition, with photoelectricity, for oil, can save limited petroleum resources, and when charging without engine, pollution-free, noiselessness.

In order to realize above-described embodiment, the utility model also proposes a kind of automobile, comprises the automobile-used solar recharging system in above-described embodiment.

Automobile of the present utility model, the battery information of the on-vehicle battery that can detect according to battery manager by automobile-used solar recharging system and the illumination condition of light sensation units test, controlling solar energy skylight charges to on-vehicle battery, make after automobile engine quits work, can utilize solar energy skylight to convert solar energy into electrical energy charges for on-vehicle battery, thereby can make on-vehicle battery under sufficient electric weight, work guaranteeing, guaranteed the normal startup of automobile, and on-vehicle battery can be in power shortage state, and then extended useful life of on-vehicle battery.

In flow chart or any process of otherwise describing at this or method describe and can be understood to, represent to comprise that one or more is for realizing the module of code of executable instruction of the step of specific logical function or process, fragment or part, and the scope of preferred implementation of the present utility model comprises other realization, wherein can be not according to order shown or that discuss, comprise according to related function by the mode of basic while or by contrary order, carry out function, this should be understood by embodiment person of ordinary skill in the field of the present utility model.

The logic and/or the step that in flow chart, represent or otherwise describe at this, for example, can be considered to for realizing the sequencing list of the executable instruction of logic function, may be embodied in any computer-readable medium, for instruction execution system, device or equipment (as computer based system, comprise that the system of processor or other can and carry out the system of instruction from instruction execution system, device or equipment instruction fetch), use, or use in conjunction with these instruction execution systems, device or equipment.With regard to this specification, " computer-readable medium " can be anyly can comprise, storage, communication, propagation or transmission procedure be for instruction execution system, device or equipment or the device that uses in conjunction with these instruction execution systems, device or equipment.The example more specifically of computer-readable medium (non-exhaustive list) comprises following: the electrical connection section (electronic installation) with one or more wirings, portable computer diskette box (magnetic device), random-access memory (ram), read-only memory (ROM), the erasable read-only memory (EPROM or flash memory) of editing, fiber device, and portable optic disk read-only memory (CDROM).In addition, computer-readable medium can be even paper or other the suitable medium that can print described program thereon, because can be for example by paper or other media be carried out to optical scanner, then edit, decipher or process in electronics mode and obtain described program with other suitable methods if desired, be then stored in computer storage.

Should be appreciated that each several part of the present utility model can realize with hardware, software, firmware or their combination.In the above-described embodiment, a plurality of steps or method can realize with being stored in memory and by software or the firmware of suitable instruction execution system execution.For example, if realized with hardware, the same in another embodiment, can realize by any one in following technology well known in the art or their combination: have for data-signal being realized to the discrete logic of the logic gates of logic function, the application-specific integrated circuit (ASIC) with suitable combinational logic gate circuit, programmable gate array (PGA), field programmable gate array (FPGA) etc.

Those skilled in the art are appreciated that realizing all or part of step that above-described embodiment method carries is to come the hardware that instruction is relevant to complete by program, described program can be stored in a kind of computer-readable recording medium, this program, when carrying out, comprises step of embodiment of the method one or a combination set of.

In addition, each functional unit in each embodiment of the utility model can be integrated in a processing module, can be also that the independent physics of unit exists, and also can be integrated in a module two or more unit.Above-mentioned integrated module both can adopt the form of hardware to realize, and also can adopt the form of software function module to realize.If described integrated module usings that the form of software function module realizes and during as production marketing independently or use, also can be stored in a computer read/write memory medium.

The above-mentioned storage medium of mentioning can be read-only memory, disk or CD etc.

In the description of this specification, the description of reference term " embodiment ", " some embodiment ", " example ", " concrete example " or " some examples " etc. means to be contained at least one embodiment of the present utility model or example in conjunction with specific features, structure, material or the feature of this embodiment or example description.In this manual, the schematic statement of above-mentioned term is not necessarily referred to identical embodiment or example.And the specific features of description, structure, material or feature can be with suitable mode combinations in any one or more embodiment or example.

Although illustrated and described embodiment of the present utility model, those having ordinary skill in the art will appreciate that: in the situation that not departing from principle of the present utility model and aim, can carry out multiple variation, modification, replacement and modification to these embodiment, scope of the present utility model is by claim and be equal to and limit.

Claims (7)

1. an automobile-used solar recharging system, is characterized in that, comprising:

Solar energy skylight;

On-vehicle battery;

Detect the battery manager of the battery information of described on-vehicle battery;

Detect the light sensation device of illumination condition; And

Controller, described controller is connected with described solar energy skylight, described battery manager and described light sensation device, and described controller is controlled described solar cell vehicle window to described charging on-vehicle battery according to the battery information of described on-vehicle battery and described illumination condition.

2. automobile-used solar recharging system as claimed in claim 1, is characterized in that, described on-vehicle battery comprises storage battery or/and electrokinetic cell bag.

3. automobile-used solar recharging system as claimed in claim 2, it is characterized in that, described battery manager is for detecting the first battery manager of the battery information of described electrokinetic cell bag, described controller is connected with described solar energy skylight, described the first battery manager and described light sensation device, and described controller is controlled described solar cell vehicle window according to the battery information of described electrokinetic cell bag and described illumination condition and charged to described electrokinetic cell bag.

4. automobile-used solar recharging system as claimed in claim 2, it is characterized in that, described storage battery comprises battery pack, the second battery manager and charging DC/DC, described battery manager is for detecting the second battery manager of the battery pack information of described storage battery, described controller is connected with described solar energy skylight, described the second battery manager and described light sensation device, and described controller is controlled described solar cell vehicle window to described charge in batteries according to the battery pack information of described storage battery and described illumination condition.

5. automobile-used solar recharging system as claimed in claim 4, it is characterized in that, described the second battery manager is connected with battery pack with charging DC/DC respectively, and described the second battery manager detects described battery pack information, and controls charging DC/DC to described batteries charging.

6. automobile-used solar recharging system as claimed in claim 2, it is characterized in that, described battery manager comprises the first battery manager of the battery information that detects described electrokinetic cell bag and the second battery manager that detects the battery pack information of described storage battery, described controller and described solar energy skylight, described the first battery manager is connected with described light sensation device, described controller is controlled described solar cell vehicle window according to the battery information of described electrokinetic cell bag and described illumination condition and is charged to described electrokinetic cell bag, and described controller and described solar energy skylight, described the second battery manager is connected with described light sensation device, described controller is controlled described solar cell vehicle window to described charge in batteries according to the battery pack information of described storage battery and described illumination condition.

7. an automobile, is characterized in that, comprises the automobile-used solar recharging system as described in claim 1-6 any one.