CN214084578U - Shared electric vehicle helmet box and helmet system - Google Patents

Abstract

The application relates to a shared electric vehicle helmet box and a helmet system, wherein the helmet box mainly comprises a placement detection module, a covering detection module, a signal processing module and an ultraviolet sterilization module; the helmet includes a suicide module. After the helmet is used, a user places the helmet in the helmet box and covers the helmet box, the signal processing module starts to receive a placement detection signal output by the placement detection module and a covering detection signal output by the covering detection module, and outputs a disinfection control signal with preset duration. The ultraviolet sterilization module is connected with the signal processing module and emits ultraviolet light when receiving the sterilization control signal so as to sterilize the helmet in the helmet box. The self-sterilizing module is connected with the ultraviolet sterilizing module and is sterilized simultaneously with the ultraviolet sterilizing module. Under the combined action of the helmet box and the helmet system, the outer shell and the inner wall of the helmet are sufficiently sterilized, thereby reducing the possibility of the helmet remaining with pathogens before the next user uses the helmet.

Description

Shared electric vehicle helmet box and helmet system

Technical Field

The application relates to the field of shared electric vehicles, in particular to a shared electric vehicle helmet box and a helmet system.

Background

In daily life, the shared electric vehicle can provide convenience for the traveling of people. In order to enhance the safety of riders during riding, the state requires that people wear helmets when riding electric vehicles. The shared helmet not only can provide protection for riders during riding, but also can be borrowed at any time and any place, and provides convenience for the riders.

The shared attribute of the shared helmet enables the shared helmet to be used by a plurality of users in sequence, under the large environment of epidemic situations, if a user carries a pathogen, the pathogen can pollute the shared helmet and enable the shared helmet to carry the pathogen in the process of using the shared helmet, and the user who uses the shared helmet subsequently can be infected with the pathogen, so that the shared helmet can be used as an assistant for pathogen transmission.

SUMMERY OF THE UTILITY MODEL

To reduce the potential for pathogen transmission through shared helmets, the present application provides a shared electric vehicle helmet box and helmet system.

In a first aspect, the application provides a shared electric vehicle helmet box, which adopts the following technical scheme:

a sharing electric motor car helmet case can set up in sharing electric motor car, and it includes:

the placement detection module is used for detecting whether a helmet is placed in the helmet box or not and outputting a placement detection signal when the helmet is placed in the helmet box;

the closing detection module is used for detecting whether the helmet box is closed or not and outputting a closing detection signal when the helmet box is closed;

the signal processing module is respectively connected with the placement detection module and the covering detection module and is used for outputting a killing control signal with preset duration when receiving the placement detection signal and the covering detection signal; and

and the ultraviolet sterilization module is connected with the signal processing module and emits ultraviolet light when receiving the sterilization control signal so as to sterilize the helmet in the helmet box.

By adopting the technical scheme, when the helmet is placed in the helmet box, the placement detection module can detect the helmet; and after the helmet box is covered, the covering detection module can detect that the helmet box is in a covering state. At this moment, signal processing module can export the control signal that kills for a period of fixed duration for the ultraviolet light carries out the work of killing in a period of time to the helmet of helmet incasement, and after the helmet finishes using, places in the helmet incasement, and the pathogen on the helmet can effectively be killed, reduces the pathogen infection that the user of using the helmet earlier carried of user who uses the helmet uses the user's of helmet user's possibility at the back.

Optionally, the placement detection module includes a first switch element, which is closed when a helmet is placed in the helmet box and outputs the placement detection signal.

Through adopting above-mentioned technical scheme, proximity switch, pressure switch or photoelectric switch can detect that the helmet box has placed the helmet to make the switch closure, thereby the output is placed the detected signal. The switching element can realize the function of whether placing the helmet in the detection case betterly to can simplify the circuit structure of disinfection system, thereby reduce the cost of manufacture.

Optionally, the covering detection module includes a second switch element, the second switch element is a proximity switch, a pressure switch or a photoelectric switch, and when the helmet box is closed, the second switch element is closed to output the covering detection signal.

Through adopting above-mentioned technical scheme, proximity switch, pressure switch or photoelectric switch can detect the lid of helmet case and close the state to make the switch closure, thereby output lid detection signal. The switch element is used for realizing the function of detecting whether the helmet box is covered, and can simplify the circuit structure of the disinfection system and reduce the manufacturing cost.

Optionally, the ultraviolet ray killing module comprises ultraviolet lamps, and the ultraviolet lamps are uniformly distributed on the inner wall of the helmet box.

Through adopting above-mentioned technical scheme, evenly arrange in the ultraviolet lamp of helmet incasement wall can kill and kill helmet shell and helmet inner wall optional position, can evenly just kill and kill fully to the helmet.

Optionally, the ultraviolet sterilizer further comprises a state display module connected with the signal processing module and used for displaying the state of the ultraviolet sterilizing module.

Through adopting above-mentioned technical scheme, the status display module can show the killing state of helmet incasement, and the user of being convenient for directly knows the killing progress of the helmet of helmet incasement.

Optionally, the status display module includes a display screen or an indicator light;

the display screen can receive the killing control signal and display a designated image when receiving the killing control signal, wherein the designated image reflects the state of the ultraviolet killing module in killing;

the indicator light is connected with the signal processing module, can receive the killing control signal and emits light when receiving the killing control signal.

By adopting the technical scheme, both the display screen and the indicator lamp can reflect the killing progress in the helmet box, and the display screen can clearly and visually display the killing progress in the helmet box in a text form; the indicating lamp shows different killing progress in the helmet box in a lighting mode, and has the advantage of low cost.

Optionally, the helmet box further comprises an electromagnetic lock, the electromagnetic lock is arranged at the opening and closing position of the helmet box and used for locking the helmet box in a closed state, the electromagnetic lock is connected with the signal processing module and can receive the killing control signal and lock the helmet box in the closed state when receiving the killing control signal.

Through adopting above-mentioned technical scheme, when the helmet case disappears and kills the helmet, the electromagnetic lock can lock the helmet case that is in the closure state to reduce the possibility that the user opened the helmet case that is in the state of disappearing and killing by accident, simultaneously, because the helmet case of the state of disappearing and killing by mistake probably causes the injury of ultraviolet ray to the human body.

In a second aspect, the present application provides a shared electric vehicle helmet system, which adopts the following technical solutions:

a shared electric vehicle helmet system includes a helmet and any of the above-described shared electric vehicle helmet boxes.

Through adopting above-mentioned technical scheme, sharing electric motor car helmet system also has the function of killing the helmet.

Optionally, the shared electric vehicle helmet box further includes:

the helmet frame is arranged in the helmet box and used for supporting the helmet;

the helmet power supply module is connected with the signal processing module and comprises a power supply contact group arranged on the helmet frame, and the signal processing module can control the voltage between the power supply contact group;

the helmet comprises a self-extinguishing module, the self-extinguishing module comprises an ultraviolet lamp arranged on the inner wall of the helmet and power receiving contact groups arranged at the bottom of the helmet, and the ultraviolet lamp is positioned on a passage between the power receiving contact groups;

when the helmet is placed on the helmet frame, the power supply contact group is connected with the power receiving contact group, and the voltage between the power supply contact groups can supply power to the ultraviolet lamp on the helmet.

Through adopting above-mentioned technical scheme, place on helmet frame as the helmet, power supply contact group with receive electrical contact group butt, helmet power supply module power supply for the ultraviolet lamp place route of helmet inner wall switches on, and ultraviolet lamp can send the ultraviolet light and kill the helmet, thereby kills the pathogen that remains on helmet shell or inner wall.

Optionally, the placement detection module includes:

the resistance value detection unit is used for detecting the resistance value between the power supply contact groups;

and the resistance value comparison unit is connected with the resistance value detection unit and outputs the placement detection signal when the resistance value between the power supply contact groups is smaller than a preset resistance value.

Through adopting above-mentioned technical scheme, place detection module also can adopt the resistance value that detects between the power supply contact group and the mode of predetermineeing the resistance value comparison and realize detecting the function whether to place the helmet on the helmet frame. When the resistance value detection unit detects that the resistance value between the power supply contact groups is smaller than a preset resistance value, the resistance value comparison unit outputs a placement detection signal. The circuit formed by the resistance value detection unit and the resistance value comparison unit has better stability and is not easy to be interfered by noise.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when the user returns the helmet, the user places the helmet in the helmet frame of helmet incasement and covers the case lid, and the helmet case can start ultraviolet lamp and kill this helmet to kill and stay the pathogen on helmet shell or the inner wall, and then reduce the risk that the pathogen infects for other people, be convenient for provide sanitary service environment for next user.

2. The state display module can reflect the killing progress in the box, and is beneficial for a user to know the killing progress of the helmet in the box before the user borrows the helmet;

3. the electromagnetic lock can lock the covered helmet box when the helmet box kills the helmet, and is helpful for reducing the possibility that a user carelessly opens the helmet box which is being killed.

Drawings

Fig. 1 is a schematic structural diagram of a shared electric vehicle helmet box in an embodiment of the application.

Fig. 2 is a schematic diagram of a circuit connection structure of the sterilization system in the embodiment of the present application.

Fig. 3 is a sectional view of a shared electric vehicle helmet box in an embodiment of the present application.

Description of reference numerals: 1. a helmet box; 11. a box body; 12. a box cover; 2. a helmet mount 3, a helmet; 4. placing a detection module; 41. a resistance value detection unit; 42. a resistance value comparison unit; 421. a resistance value presetting circuit; 5. a covering monitoring module; 51. a pressure switch; 6. a signal processing module; 7. a status display module; 71. a display screen; 72. an indicator light; 81. an electromagnetic lock body; 82. a magnetic sheet.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is further described in detail below with reference to fig. 1-3 and the embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

The embodiment of the application discloses sharing electric motor car helmet case and sharing electric motor car system.

Referring to fig. 1, the shared electric vehicle helmet box may be placed at a rear hanger of the shared electric vehicle. The helmet box 1 comprises a cuboid box body 11 with one side open and a rectangular plate-shaped box cover 12, the shape of the box cover 12 is matched with the shape of the box body 11, and one side of the box cover 12 and one side of the box body 11 with the opening can be hinged, so that the box cover 12 can cover the box body 11. The box body 11 and the box cover 12 can be made of stainless steel, the box body 11 is formed by welding five stainless steel plates, and the box cover 12 is made of the stainless steel plates.

Referring to fig. 1 and 2, a disinfection system capable of disinfecting a shared helmet may be disposed in the box 11, and includes a covering detection module 5, a placing detection module 4, a signal processing module 6, and an ultraviolet disinfection module. When the helmet 3 is placed in the box body 11, the placement detection module 4 outputs a placement detection signal; when the cover 12 is covered with the box body 11, the covering detection module 5 outputs a covering detection signal. When the helmet 3 is placed in the box body 11 and the box cover 12 initially covers the box body 11, the signal processing module 6 starts to output a disinfection control signal for controlling the disinfection device to work for a preset time.

Referring to fig. 1 and 3, in order to better fix the helmet 3 inside the box body 11, a helmet frame 2 for placing the helmet 3 is disposed at the bottom of the box body 11, and the helmet frame 2 is located at the placing area. The helmet frame 2 may be a support column set composed of a plurality of support columns erected on the bottom surface of the case 11. The arrangement shape of the support column group and the length of each support column are arranged, so that the overall shape of the helmet frame 2 is matched with the shape of the bottom of the helmet 3, and the helmet frame 2 can stably support the helmet 3. The shape of the helmet frame 2 can also be adapted according to the actual installation situation. The helmet frame 2 may be made of steel.

In order to detect whether the helmet 3 is placed on the helmet rack 2, a power supply contact set is arranged on the support column and comprises a first electrical contact a and a second electrical contact b. The first electric contact a and the second electric contact b are respectively positioned on two different support columns, specifically, both are positioned on one surface of the support column away from the inner bottom of the helmet box 1, and a path which has a resistance value of a first resistance value and is used for conducting the first electric contact a and the second electric contact b is arranged between the first electric contact a and the second electric contact b. A third electrical contact c corresponding to the first electrical contact a and a fourth electrical contact d corresponding to the second electrical contact b are provided at the bottom of the helmet 3, and a path having a resistance value of the second resistance value and conducting the third electrical contact c and the fourth electrical contact d is provided in advance in the helmet 3. When the helmet 3 is placed on the helmet frame 2, the first electrical contact a is in interference connection with the third electrical contact c, and the second electrical contact b is in interference connection with the fourth electrical contact d. When the helmet 3 is placed on the helmet stand 2, the resistance value between the first electrical contact a and the second electrical contact b is reduced due to the resistance value between the third electrical contact c and the fourth electrical contact d, and the placement detection module 4 can determine whether the helmet 3 is placed on the helmet stand 2 by detecting the resistance value between the first electrical contact a and the second electrical contact b.

Referring to fig. 2, in particular, the placement detection module 4 includes a resistance value detection unit 41 for detecting the magnitude of the resistance value between the first electrical contact a and the second electrical contact b, and a resistance value comparison unit 42 for comparing the collected resistance value with a preset resistance value.

The resistance value detecting unit 41 includes a resistance tester G, and two detecting terminals of the resistance tester G are respectively connected to the first electrical contact a and the second electrical contact b to detect a resistance value between the first electrical contact a and the second electrical contact b. The resistance tester G can output a resistance detection signal reflecting the magnitude of the resistance between the first electrical contact a and the second electrical contact b. The resistance value comparing unit 42 includes a resistance value presetting circuit 421 and a comparator N1. The resistance presetting circuit 421 is configured to output a resistance presetting signal reflecting the preset resistance, where the preset resistance is smaller than the first resistance but larger than a resistance obtained by connecting the first resistance and the second resistance in parallel. The resistance presetting circuit 421 includes a fixed resistor R1 and a sliding resistor R2. The fixed resistor R1 and the slide rheostat R2 are connected in series with a power supply, the fixed resistor R1 is arranged close to the positive pole of the power supply, and the common end of the fixed resistor R1 and the slide rheostat R2 outputs the preset resistance signal. The magnitude of the preset resistance signal can be directly changed by adjusting the magnitude of the resistance value of the sliding rheostat R2, and the larger the resistance value of the sliding rheostat R2 is, the larger the preset resistance signal is. The comparator N1 has a non-inverting input terminal connected to the resistance value presetting circuit 421 for receiving the resistance value presetting signal, and an inverting input terminal connected to the resistance value detecting unit 41 for receiving the analog resistance value detecting signal.

It can be understood that, since the resistance detection signal detected by the resistance tester G is a digital signal, and the resistance comparison unit 42 is an analog circuit, the digital signal cannot be input into the resistance comparison unit 42 for comparison, the resistance detection unit 41 may further include an analog-to-digital converter, which is connected to the output end of the resistance tester G and converts the digital resistance detection signal into an analog resistance detection signal. The digital-to-analog converter applied in this embodiment can make the converted analog resistance detection signal in direct proportion to the detected resistance value.

Referring to fig. 2 and 3, when the helmet 3 is placed on the helmet rack 2, the resistance value between the first electrical contact a and the second electrical contact b is a resistance value obtained by connecting the first resistance value and the second resistance value in parallel, and is smaller than the preset resistance value, so that the resistance detection signal is smaller than the resistance preset signal, and the output end of the comparator N1 outputs a high level, that is, the comparator N1 outputs a placement detection signal. When the helmet 3 is not placed on the helmet rack 2, the resistance value between the first electrical contact a and the second electrical contact b is a first resistance value which is larger than a preset resistance value, so that the resistance detection signal is larger than the resistance preset signal, and the output end of the comparator N1 outputs a low level, that is, the comparator N1 does not output a placement detection signal.

That is, when the helmet 3 is placed on the helmet stand 2, the placement detection module 4 outputs a high-level placement detection signal.

Referring to fig. 1 and 2, the covering detection module 5 is used for detecting whether the box cover 12 and the box body 11 are covered, and includes a pressure switch 51.

The pressure switch 51 can be fixedly installed in the box body 11 and is located at the edge of the opening of the box body 11, the sensing contact of the pressure switch 51 faces the outside of the opening of the box body 11, and when the box cover 12 covers the box body 11, the box cover 12 abuts against the sensing contact of the pressure switch 51. One end of the pressure switch 51 is connected to the positive electrode of the power supply, and the other end is a free end capable of outputting the covering detection signal. When the cover 12 covers the box 11, the pressure switch 51 is closed, and at this time, the free end of the pressure switch 51 outputs a high-level signal, that is, a cover detection signal. When the cover 12 and the box 11 are not covered, the free end of the pressure switch 51 is suspended and does not output a covering detection signal.

That is, when the box cover 12 is closed to the box body 11, the closing detection module 5 outputs a high-level closing detection signal.

In order to realize the covering detection function of the covering detection module 5, the pressure switch 51 may be replaced with a proximity switch or a photoelectric switch. The principle of using a proximity switch or an electro-optical switch is similar to that of using the pressure switch 51 and will not be described in detail.

Referring to fig. 2 and 3, similarly, the placement detection module 4 may also employ a switch element such as a proximity switch, a pressure switch, or a photoelectric switch. The switch element is arranged on any support column, specifically, the switch element is arranged on one surface of the support column far away from the bottom in the helmet box 1, one end of the switch element is connected with the anode of the power supply, and the other end of the switch element is a free end capable of outputting a placement detection signal. When the helmet 3 is placed on the helmet frame 2, the switch element in the placement detection module 4 is closed, and the free end of the switch element outputs a high-level signal, that is, a placement detection signal.

Referring to fig. 2, the signal processing module 6 functions to output a sterilization control signal for controlling the operation of the sterilization device for a preset time period when the placement detection signal and the closing detection signal start to be received. The signal processing module 6 comprises a processing unit for receiving and processing the placement detection signal and the covering detection signal, and a timing unit for outputting a killing control signal with preset duration.

The processing unit may be a two-input and gate U2. One input end of the AND gate U2 is connected with the output end of the comparator N1 and can receive and receive a setting detection signal; the other input end is connected with the free end of the pressure switch 51 and can receive the closing detection signal. When the and gate U2 receives the low level signal output from the comparator N1 or the low level signal output from the free end of the pressure switch 51, the and gate U2 outputs a low level signal. When the and gate U2 receives the placement detection signal and the closure detection signal at the same time, the and gate U2 outputs a high level signal. The signal at the output of the and gate U2 appears as a processed signal when it transitions from a low signal to a high signal.

Referring to fig. 1 and 2, the timing unit starts to output a kill control signal for a preset duration when receiving the processing signal. In this embodiment, the timing unit employs a timer triggered by a rising edge, and a trigger end of the timer is connected to the output end of the gate U2, and is capable of receiving the processing signal, operating under the trigger of the processing signal, and outputting a killing control signal with a preset duration and a high level. In order to meet the high-frequency use requirement of the helmet 3, the preset time is generally short, and can be 3-5min, and is generally not more than 10 min.

Referring to fig. 2, the ultraviolet ray sterilizing module includes a power supply, a first ultraviolet ray lamp set L1 and a photoelectric switch U1, output ends of the first ultraviolet ray lamp set L1 and the photoelectric switch U1 are connected in series to the power supply, and when the photoelectric switch U1 is closed, the power supply supplies power to the first ultraviolet ray lamp set L1, so that the first ultraviolet ray lamp set L1 emits ultraviolet ray light. The input anode of the photoelectric switch U1 is connected with the output end of the timer, the input cathode is connected with the negative electrode of the power supply, and when the timer outputs a killing control signal, the two output ends of the photoelectric switch U1 can be conducted. When the sterilizing control signal is received, the output end of the photoelectric switch U1 is connected, and the power supply supplies power to the first ultraviolet lamp group L1, so that the first ultraviolet lamp group L1 emits ultraviolet light. Since the sterilizing control signal continues for a preset time period, the first ultraviolet lamp group L1 can emit light for the preset time period.

Referring to fig. 1 and 2, a first ultraviolet lamp group L1 is disposed in the case 11 and includes a plurality of ultraviolet lamps. A plurality of ultraviolet lamps of first ultraviolet banks L1 can evenly be arranged in bottom surface and side in box 11 to the realization is followed all directions and is sent ultraviolet ray to the helmet 3 that is located box 11, and is more comprehensive thorough to the disinfection and sterilization effect of helmet 3. The power of the first ultraviolet lamp group L1 is high to achieve a more effective disinfection and sterilization of the helmet 3 within a shorter preset time period.

The disinfection system can also comprise a state display module 7, the state display module 7 is connected with the timing unit and used for indicating whether the ultraviolet disinfection module is in the working state or not, and the disinfection time can also be displayed, so that convenience is provided for a user to check the disinfection progress.

The status display module 7 may be specifically a display screen 71. The trigger terminal of the display screen 71 is connected to the output terminal of the timer, and can receive the high-level killing control signal. The display screen 71 is pre-stored with designated image information, when the trigger terminal receives a high-level killing control signal, the display screen 71 starts to display the designated image information, and the designated image information may include characters of 'during killing, do not open', and the like, or may include '… seconds after the killing is finished', so as to prompt the user that the helmet 3 is in a killing state and the use has the risk of cross infection.

Of course, the status display module 7 may also include an indicator light 72. The indicator light 72 is installed outside the helmet box 1, and the trigger end of the indicator light 72 is connected with the output end of the timer and receives the high-level killing control signal. When the killing control signal is received, the indicator lamp 72 is changed from non-lighting to lighting or from one color to another color, so that the helmet box 1 can be prompted to have the killing state. In order to reduce the possibility that the user mistakenly opens the disinfecting helmet box 1, the disinfecting helmet box 1 can be locked by an electromagnetic lock in addition to displaying the disinfecting state through the state display module 7.

The electromagnetic lock includes an electromagnetic lock body 81 and a magnetic sheet 82. The electromagnetic lock body 81 is disposed on the open edge of the box 11, and the magnetic sheet 82 is disposed on the box cover 12 at a position corresponding to the electromagnetic lock body 81. The trigger end of the electromagnetic lock body 81 is connected with the timing unit, specifically connected with the output end of the timer, and can receive the high-level killing control signal. When receiving a high-level sterilization control signal, the electromagnetic lock body 81 attracts the magnetic sheet 82, so that the helmet box 1 cannot be opened, and the user is prevented from opening the sterilized helmet box 1 by mistake.

Referring to fig. 1 and 3, it is of course possible to design a helmet 3 having a second group L2 of ultraviolet lamps therein, in addition to the helmet box 1 which can sterilize the helmet 3. Since the power supply for supplying power to the second ultraviolet lamp group L2 is heavy and is not suitable for being installed on the helmet 3, the second ultraviolet lamp group L2 is disposed on the path between the third electrical contact c and the fourth electrical contact d on the helmet 3, and when the helmet 3 is placed on the helmet stand 2, the helmet box 1 can supply power to the second ultraviolet lamp group L2 through the first electrical contact a and the second electrical contact b.

Specifically, when the helmet 3 is placed on the helmet frame 2, the first electrical contact a abuts against the third electrical contact c, and the second electrical contact b abuts against the fourth electrical contact d, so that a path between the first electrical contact a and the second electrical contact b is parallel to a path between the third electrical contact c and the fourth electrical contact d, that is, the first ultraviolet lamp group L1 is parallel to the second ultraviolet lamp group L2, and the second ultraviolet lamp group L2 and the first ultraviolet lamp group L1 operate in synchronization. The helmet 3 with the second ultraviolet lamp group L2 can fully kill the inner wall of the helmet 3 under the combined action of the helmet box 1 with the first ultraviolet lamp group L1.

Referring to fig. 2, it is understood that other components capable of isolating the circuit may be used for the photoelectric switch U1.

The implementation principle of the embodiment is as follows: when the user finishes using the helmet 3, the helmet 3 is placed in the helmet box 1 and covers the helmet box 1, the first ultraviolet lamp group L1 and the second ultraviolet lamp group L2 start to work for a preset time, and the helmet 3 is disinfected and sterilized for the preset time. In the disinfection and sterilization process, the display screen 71 prompts the user that the helmet 3 is in sterilization, and the electromagnetic lock locks the helmet box 1 to prevent the user from opening the helmet box 1 which is not sterilized, and taking out the helmet 3 which possibly carries pathogens of a user before infection. After the disinfection and sterilization is finished, the helmet box 1 can be opened, the helmet 3 can be taken out, the helmet 3 is disinfected, pathogens are basically killed, and the user can safely use the helmet 3, so that the possibility that the shared helmet is used as a carrier for pathogen propagation and helps is reduced.

It should be understood that the helmet 3 and the helmet box 1 can be used together to form a helmet system, and those skilled in the art can form the helmet system according to the above disclosure while knowing the structures of the helmet 3 and the helmet box 1, and the helmet system is not specifically disclosed in order to keep the description concise.

The foregoing is a preferred embodiment of the present application and is not intended to limit the scope of the application in any way, and any features disclosed in this specification (including the abstract and drawings) may be replaced by alternative features serving equivalent or similar purposes, unless expressly stated otherwise. That is, unless expressly stated otherwise, each feature is only an example of a generic series of equivalent or similar features.

Claims (10)

1. The utility model provides a sharing electric motor car helmet case can set up in sharing electric motor car, its characterized in that includes:

the placement detection module (4) is used for detecting whether a helmet (3) is placed in the helmet box (1) or not, and outputting a placement detection signal when the helmet (3) is placed in the helmet box (1);

the covering detection module (5) is used for detecting whether the helmet box (1) is covered or not and outputting a covering detection signal when the helmet box (1) is covered;

the signal processing module (6) is respectively connected with the placement detection module (4) and the covering detection module (5) and is used for outputting a disinfection control signal with preset duration when receiving the placement detection signal and the covering detection signal; and

and the ultraviolet sterilization module is connected with the signal processing module (6) and sends out ultraviolet light when receiving the sterilization control signal so as to sterilize the helmet (3) in the helmet box (1).

2. A shared electric vehicle helmet box according to claim 1, characterized in that the placement detection module (4) comprises a first switching element for closing when a helmet (3) is placed inside the helmet box (1) and outputting the placement detection signal.

3. The shared electric vehicle helmet box of claim 1, wherein the closing detection module (5) comprises a second switch element, the second switch element is a proximity switch, a pressure switch or a photoelectric switch, and when the helmet box (1) is closed, the second switch element is closed to output the closing detection signal.

4. The shared electric vehicle helmet box of claim 1, wherein the ultraviolet killing module comprises a first ultraviolet lamp set, and the first ultraviolet lamp set is uniformly arranged on the inner wall of the helmet box (1).

5. The shared electric vehicle helmet box of claim 1, further comprising:

and the state display module (7) is connected with the signal processing module (6) and is used for displaying the state of the ultraviolet ray killing module.

6. A shared electric vehicle helmet box according to claim 5, characterized in that the status display module (7) comprises a display screen (71) or an indicator light (72);

the display screen (71) receives the killing control signal, and displays a designated image when receiving the killing control signal, wherein the designated image reflects the state of the ultraviolet killing module in killing;

the indicator light (72) is connected with the signal processing module (6), can receive the killing control signal and emits light when receiving the killing control signal.

7. The shared electric vehicle helmet box of claim 1, further comprising:

the electromagnetic lock is arranged at the opening and closing position of the helmet box (1) and used for locking the helmet box (1) in a closed state, is connected with the signal processing module (6) and can receive the killing control signal and lock the helmet box (1) in the closed state when receiving the killing control signal.

8. A shared electric vehicle helmet system, characterized by comprising a helmet (3) and a shared electric vehicle helmet box according to any one of claims 1 to 7.

9. The shared electric vehicle helmet system of claim 8, wherein the shared electric vehicle helmet box further comprises:

the helmet frame (2) is arranged in the helmet box (1) and is used for supporting the helmet (3);

the helmet power supply module is connected with the signal processing module (6) and comprises a power supply contact group arranged on the helmet frame (2), and the signal processing module (6) can control the voltage between the power supply contact group;

the helmet (3) comprises a self-extinguishing module, the self-extinguishing module comprises a second ultraviolet lamp group arranged on the inner wall of the helmet (3) and a power receiving contact group arranged at the bottom of the helmet (3), and the second ultraviolet lamp group is positioned on a passage between the power receiving contact groups;

when the helmet (3) is placed on the helmet frame (2), the power supply contact group is connected with the power receiving contact group, and the voltage between the power supply contact groups can supply power to a second ultraviolet lamp group on the helmet (3).

10. A shared electric vehicle helmet system according to claim 9, wherein the placement detection module (4) comprises:

a resistance value detection unit (41) for detecting a resistance value between the power supply contact groups;

and the resistance value comparison unit (42) is connected with the resistance value detection unit (41), and outputs the placement detection signal when the resistance value between the power supply contact groups is smaller than a preset resistance value.

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