CN217427710U - Charging system of cleaning device - Google Patents

Abstract

The utility model provides a cleaning device's charging system, include: the device comprises a charging mechanism, a cleaning device, a bracket, a self-powered photovoltaic panel and a shutdown position; the self-powered photovoltaic panel is arranged at a preset position; wherein, preset the position and include: at least one of the clearance of each component on the bracket, the space between the stand and the bracket and the moving track of the stand; the self-powered photovoltaic panel is connected with the charging mechanism through a lead to charge the cleaning device; the first conductive system of the charging mechanism is arranged on the parking position; the second conductive system of the charging mechanism is arranged on the cleaning device; that is to say, the self-powered photovoltaic panel is arranged in the assembly gap of the bracket and is not arranged on the cleaning device, so that the problem of overlarge size of the cleaning device is avoided, the cleaning device can be charged flexibly, the weight of the cleaning device is further reduced, and the stop position is reduced; the charging time of the cleaning device can be shortened, and the structure can be simplified.

Description

Charging system of cleaning device

Technical Field

The utility model belongs to the technical field of charging system, more specifically the utility model specifically says, especially, relates to a cleaning device's charging system.

Background

In the existing cleaning device, a self-powered photovoltaic module is arranged on a cleaning device body. For the case that long-distance cleaning is needed, such as 3 km; accordingly, larger capacity battery life is also required, and thus, larger size self-powered photovoltaic modules are also required. This both increases the weight and requires a larger size limit for the sweeping device; that is, the existing sweeping device is too large in size and cannot be flexibly charged.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims at providing a cleaning device's charging system for reduce cost drops into, reduces cleaning device's size and less cleaning device's weight, realizes nimble charging.

The application discloses cleaning device's charging system includes: the system comprises a charging mechanism, a bracket, a self-powered photovoltaic panel and a parking position;

the self-powered photovoltaic panel is arranged at a preset position; wherein the preset position comprises: at least one of each component gap on the support, a moving track between the stand and the support and the stand;

the self-powered photovoltaic panel is connected with the charging mechanism through a lead to charge the cleaning device;

the first conductive system of the charging mechanism is arranged on the parking position;

and the second conductive system of the charging mechanism is arranged on the cleaning device.

Optionally, in the charging system of the cleaning device, the stand is a fixed stand or a movable stand.

Optionally, in the charging system of the cleaning device, the support is a fixed support or a tracking support.

Optionally, in the charging system of the cleaning device, when the stand is a movable stand, a cleaning unit is integrated on the movable stand.

Optionally, in the charging system of the cleaning device, when the stand is a movable stand, the conductive unit for supplying power to the movable stand is disposed at an edge of the track of the movable stand.

Optionally, in the charging system of the sweeping device, the movable stand is a ferry vehicle.

Optionally, in the charging system of the cleaning device, the charging mechanism is further connected to an external power supply system through a wire.

Optionally, in the charging system for a cleaning device, the charging mechanism includes: a first conductive system and a second conductive system;

the second conductive system is connected with the self-powered photovoltaic panel;

the two conductive systems are in contact with each other, so that electric energy can be transmitted to charge the cleaning device.

Optionally, in the charging system of the cleaning device, the first conducting system includes: the device comprises a positive electrode conductive piece, a negative electrode conductive piece, a mounting support piece, a spring and a guide post;

the guide post is used for guiding and supporting the mounting support piece;

the mounting support is used for moving along the guide post;

the spring is used for reserving a preset compression amount to ensure that the mounting support and the guide post are firmly contacted;

each conductive piece is arranged on the mounting support piece and used for realizing electric energy transmission with the second conductive system.

Optionally, in the charging system of the cleaning device, the conductive member is a ramp-type conductive member.

Optionally, in the charging system of the cleaning device, the second conductive system includes: the device comprises a positive conductive contact, a negative conductive contact and an installation supporting mechanism;

each conductive contact is arranged on the mounting and supporting mechanism and used for realizing the electric energy transmission with the first conductive system.

Optionally, in the charging system of the cleaning device, the conductive contact is curved.

Optionally, in the charging system of the sweeping device, the conductive contact is in a shape of at least one of a spherical surface and a cylindrical surface.

According to the above technical scheme, the utility model provides a pair of cleaning device's charging system, include: the device comprises a charging mechanism, a cleaning device, a bracket, a self-powered photovoltaic panel and a shutdown position; the self-powered photovoltaic panel is arranged at a preset position; wherein, preset the position and include: at least one of the clearance of each component on the bracket, the space between the stand and the bracket and the moving track of the stand; the self-powered photovoltaic panel is connected with the charging mechanism through a lead to charge the cleaning device; the first conductive system of the charging mechanism is arranged on the parking position; the second conductive system of the charging mechanism is arranged on the cleaning device; that is to say, the self-powered photovoltaic panel is arranged in the assembly gap of the bracket and is not arranged on the cleaning device, so that the problem of overlarge size of the cleaning device is avoided, the cleaning device can be flexibly charged, the weight of the cleaning device is further reduced, and the stop position is reduced; the charging time of the cleaning device can be accelerated, and the structure can be simplified.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic view of a charging system of a cleaning device according to an embodiment of the present invention;

fig. 2 is a schematic view of a charging system of another sweeping device provided in an embodiment of the present invention;

fig. 3 is a schematic view of a charging system of another sweeping device provided in an embodiment of the present invention;

fig. 4 is a schematic view of a charging system of another sweeping device provided in an embodiment of the present invention;

fig. 5 is a schematic view of a cleaning device according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In this application, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The embodiment of the application provides a charging system of a cleaning device, which is used for solving the problem that in the prior art, a self-powered photovoltaic module is arranged on a cleaning device body; for the case that long-distance cleaning is needed, such as 3 km; accordingly, larger capacity battery life is also required, and therefore, larger size self-powered photovoltaic modules are also required. This both adds weight and requires a larger size limit for the sweeping device; that is, the existing cleaning device has the problems of overlarge volume and incapability of flexible charging.

Referring to fig. 1, the charging system of the sweeping device includes: charging mechanism 10, cradle 60, self-powered photovoltaic panel 50, and stand 30.

The self-powered photovoltaic panel 50 is disposed at a predetermined position.

Wherein, predetermine the position and include: at least one of the respective assembly gaps 70 on the stand 60, the space between the stand 30 and the stand 60, and the moving track of the stand 30. That is, the self-powered photovoltaic panel 50 can be disposed on the rack 60 at each device gap 70; the self-powered photovoltaic panel 50 may also be disposed between the stand 30 and the support 60; the self-powered photovoltaic panel 50 can also be disposed in the movement trajectory of the stand 30.

In addition, the number of the self-powered photovoltaic panels 50 may be plural, that is, the charging mechanism 10 may be powered by plural self-powered photovoltaic panels 50; the self-powered photovoltaic panel 50 may also be single, that is, the charging mechanism 10 is powered by a single self-powered photovoltaic panel 50.

If the number of self-powered photovoltaic panels 50 is single, the self-powered photovoltaic panels 50 are disposed on the rack 60 at one of the respective module gaps 70, between the stand 30 and the rack 60, and the movement trajectory of the stand 30.

If the number of the self-powered photovoltaic panels 50 is plural, each of the self-powered photovoltaic panels 50 may be disposed on the rack 60 in one of the movement tracks of each of the module gap 70, between the stand 30 and the rack 60, and the stand 30; or a combination of at least two of the movement trajectories of the components gaps 70 on the support 60, the space between the stand 30 and the support 60, and the stand 30 may be provided, which is not described herein any more, and is within the protection scope of the present application depending on the actual situation.

It should be noted that a plurality of photovoltaic modules are disposed on the support 60, and each photovoltaic module generates power according to solar radiation.

Referring to fig. 5, a schematic view of sweeping device 20 is shown. This cleaning device 20 is used for cleaning each photovoltaic module to avoid photovoltaic module because sheltered from the problem that leads to the generated energy low by debris such as fallen leaves.

When the self-powered photovoltaic panel 50 is disposed between the module gap 70 or the stand 30 and the bracket 60, the cleaning device 20 cleans the self-powered photovoltaic panel 50 together when cleaning each photovoltaic module, thereby avoiding the problem of providing a separate cleaning unit for the self-powered photovoltaic module 50.

The self-powered photovoltaic panel 50 is connected with the charging mechanism 10 through a wire 40 to charge the cleaning device 20; that is, the self-powered photovoltaic panel 50 transmits the electric power generated by solar irradiation to the charging mechanism 10 through the conducting wire 40, so that the charging mechanism 10 charges the cleaning device 20.

The first conductive system 15 of the charging mechanism 10 is arranged on the stand 30; the second conductive system 16 of the charging mechanism 10 is provided on the cleaning device 20.

That is, when the two conductive systems of the charging mechanism 10 are in contact, the charging mechanism 10 charges the cleaning device 20.

In practical applications, the charging mechanism 10 may also be connected to an external power supply system through a wire 40 to receive electric energy from the external power supply system and charge the cleaning device 20. Of course, other modes are possible, and details are not described herein, and all of them are within the scope of the present application as appropriate.

In the present embodiment, the self-powered photovoltaic panel 50 is disposed at a predetermined position; wherein, preset the position and include: at least one of each component gap 70 on the support 60, the distance between the stand 30 and the support 60, and the moving track of the stand 30; the self-powered photovoltaic panel 50 is connected with the charging mechanism 10 through a wire 40 to charge the cleaning device 20; the first conductive system 15 of the charging mechanism 10 is arranged on the stand 30; the second conductive system 16 of the charging mechanism 10 is disposed on the cleaning device 20; that is, the self-powered photovoltaic panel 50 is not disposed on the sweeping device 20 at the module gap 70 of the rack 60, avoiding the problem of over-sizing the sweeping device 20; the cleaning device can be flexibly charged, so that the weight of the cleaning device is further reduced, and the stop position is reduced; the charging time of the cleaning device can be shortened, and the structure can be simplified.

It should be noted that, in the prior art, the self-powered photovoltaic panel needs to be equipped with a corresponding cleaning system, which generally includes a cleaning brush, a supporting mechanism, etc., to reduce the influence of dust on the self-powered photovoltaic panel, which also increases the additional cost.

In addition, the self-powered photovoltaic panel can move along with the cleaning device, is influenced by a vibration environment, generally adopts a flexible assembly, and thus the power is the same, and the cost input is higher than that of a glass assembly.

In the present embodiment, the self-powered photovoltaic panel 50 is disposed on the support 60, and at least one of the component gap 70, the space between the stand 30 and the support 60, and the moving track of the stand 30; that is, the self-powered photovoltaic panel 50 can be cleaned along with the cleaning path of the cleaning device 20 and the moving track of the parking space 30, and a cleaning system does not need to be separately arranged for the self-powered photovoltaic panel 50, so that the cost is reduced.

Meanwhile, the self-powered photovoltaic panel 50 is not disposed on the cleaning device 20, that is, the self-powered photovoltaic panel 50 does not move along with the cleaning device 20, and a photovoltaic panel with lower power can be used, so that the hardware cost is reduced.

In practical applications, the stand 30 may be a fixed stand; it may also be a mobile stand. The fixed and movable stands are described below, respectively:

(1) the stand 30 is a fixed stand.

Specifically, the bracket 60 may be a fixed bracket; alternatively, the carriage 60 is a tracking carriage.

That is, the bracket 60 is in a fixed position and orientation; alternatively, the support 60 may track the direction of solar irradiation to maximize the solar irradiation received by the components on which the support 60 is disposed; accordingly, the self-powered photovoltaic panel 50 disposed on the support can rotate along with the rotation of the tracking support, so as to increase the power generation amount of the self-powered photovoltaic panel 50.

Referring to fig. 1, the charging system of the sweeping device comprises a sweeping device 20, a charging mechanism 10, a stand 30 and a self-powered photovoltaic panel 50.

The self-powered photovoltaic panel 50 is disposed in the module gap 70 of the mounting bracket. The self-powered photovoltaic panel 50 is connected to the charging mechanism 10 and can charge the sweeping device 20.

Placing the self-powered photovoltaic panel 50 in the assembly gap 70 reduces the size of the stand 30, reduces the cantilever length, improves reliability, and reduces safety risks.

Referring to fig. 2, the preset position further includes: between the stand 30 and the cradle 60.

That is, the self-powered photovoltaic panel 50 may be disposed between the stand 30 and the cradle 60.

Specifically, the charging system of the cleaning device includes the cleaning device 20, the stand 30, the tracking bracket (60 shown in fig. 2), the charging mechanism 10, the self-powered photovoltaic panel 50, and/or an external power supply system (not shown).

The self-powered photovoltaic panel 50 is arranged at the edge of the tracking carriage (60), i.e. between the parking place 30 and the tracking carriage (60); and/or, tracking the position of the assembly gap 70 on the carriage (60), the self-powered photovoltaic panel 50 can rotate as the tracking carriage (60) rotates. The second conductive system 16 of the charging mechanism 10 is disposed on the cleaning device 20, and the first conductive system 15 of the charging mechanism 10 is disposed on the stand 30 and connected to the self-powered photovoltaic panel 50 through the wire 40.

It should be noted that the stand 30 is fixed and does not rotate following the rotation of the tracking bracket (60).

The self-powered photovoltaic panel 50 rotates along with the rotation of the tracking bracket (60), so that more power generation can be obtained, the same charging power requirement is met, the size requirement is small, and the cost is lower.

In this embodiment, the sweeping device 20 can sweep the self-powered photovoltaic module, so as to sweep the self-powered photovoltaic module more cleanly and improve the power generation capacity; the self-cleaning system of the self-powered photovoltaic panel 50 can be omitted, reducing the cost.

(2) The stand 30 is a mobile stand.

The bracket 60 may be a fixed bracket; alternatively, the carriage 60 is a tracking carriage.

That is, the bracket 60 is fixed in position and orientation; alternatively, the support 60 may track the direction of solar irradiation to maximize the solar irradiation received by the components on which the support 60 is disposed.

The self-powered photovoltaic panel 50 rotates along with the rotation of the tracking bracket (60), so that more power generation can be obtained, the same charging power requirement is met, the size requirement is small, and the cost is lower.

In practice, the cleaning unit 311 is integrated on the movable stand. That is, the cleaning unit 311 provided in the movable stand can clean the traveling path provided in the movable stand.

Thus, the preset position may include: the traveling path of the stand can be moved. That is, as shown in fig. 3, the self-powered photovoltaic panel 50 is disposed in the path of travel of the movable stand.

It should be noted that the mobile parking space also needs to be powered by electric energy, and therefore, the mobile parking space also needs to be charged.

Specifically, a charging unit matched with the movable stand is needed so that the movable stand can receive the electric energy of the self-powered photovoltaic panel 50 arranged on the traveling path of the movable stand.

The charging means may be the same as or different from the charging mechanism described above. The specific structure of the charging unit is not described in detail herein, and reference may be made to the following description of the charging mechanism, and the specific structure may also be within the scope of the present application depending on the actual situation.

The charging unit also has two parts, namely a first conductive unit 312 and a second conductive unit 313. The first conductive unit 312 is disposed on the movable stand; the second conductive unit 313 is disposed at an edge of the movable gate rail; that is, the second conductive unit 313 supplying power to the movable stand is disposed at the edge of the movable stand rail.

That is, when the first conductive unit 312 is in contact with the second conductive unit 313, the corresponding self-powered photovoltaic panel 50 supplies power to the movable stand.

When the charging unit is consistent with the above charging mechanism, the second conductive system 16 disposed on the cleaning device 20 may be directly connected to the second conductive unit 313 disposed on the edge of the rail, so as to charge the cleaning device 20.

The second conductive system 16 provided on the sweeping device 20 can also be connected to the first conductive system 15 provided on the mobile stand; meanwhile, the first conductive unit 312 disposed at the movable stand is connected to the second conductive unit 313 disposed at the edge of the track, so that the self-powered photovoltaic panel 50 disposed at the movable stand supplies power to the cleaning device 20 and the movable stand, respectively.

That is, the self-powered photovoltaic panel 50 can charge both the sweeping device 20 and the mobile parking space. The specific charging process is not repeated here, and is determined according to the actual situation, all within the protection scope of the present application.

In practical application, as shown in fig. 3, the movable stand is a ferry 31; the ferry vehicle 31 can transport the sweeping devices 20 in a row; of course, other forms are possible, and are not described herein any more, and all are within the scope of the present application, depending on the actual situation.

Referring to fig. 3, when the sweeping device 20 is mated with the ferry vehicle 31, the self-powered photovoltaic panel 50 may be disposed in the travel path of the ferry vehicle 31, with the second conductive unit 313 disposed at the edge of the rail of the ferry vehicle 31. The ferry vehicle 31 is provided with a cleaning unit 311, and can clean dust for the self-powered photovoltaic panel 50. Meanwhile, after the first conductive unit 312 on the ferry vehicle 31 is butted with the second conductive unit 313, the ferry vehicle 31 and/or the sweeping device 20 can be charged. Alternatively, the cleaning device 20 is provided with the second conductive system 16 and the second conductive unit 313 on the rail, so that the cleaning device 20 can be charged after the two are contacted.

In practical application, referring to fig. 4, the charging mechanism 10 includes: a first conductive system 15 and a second conductive system 16.

The first conductive system 15 is disposed on the sweeping device 20.

The second conductive system 16 is disposed at the stand 30 and connected to the self-powered photovoltaic panel 50. That is, the conductive system disposed at the stationary stand and/or the movable stand is connected to the self-powered photovoltaic panel 50 or the external power supply system.

That is, the first conductive system 15 may be disposed on the sweeping device 20, and the second conductive system 16 may be disposed on the stand 30; of course, it is not excluded that the second conductive system 16 is provided on the cleaning device 20, and the first conductive system 15 is provided on the stand 30; the method is not particularly limited, and is within the scope of the present application as appropriate.

Specifically, when the stand 30 is a fixed stand, the first conductive system 15 is connected to the sweeping device 20; the second conductive system 16 is arranged on a stationary stand. When the stand 30 is a movable stand, the second conductive system 16 is arranged on the cleaning device 20; the first conductive system 15 is arranged on the movable stand. Of course, the present invention is not limited to the above examples, and the details are not repeated here and are within the scope of the present application.

Contact between the two conductive systems enables the transfer of electrical energy to charge sweeping device 20.

That is, when the two conductive systems come into contact, charging of the sweeping device 20 may begin.

Specifically, the first conductive system 15 includes: positive electrode conductive member 12, negative electrode conductive member 19, mounting support member 11, spring 13, and guide post 14.

A guide post 14 for guiding and supporting the mounting support 11; specifically, the guide posts 14 are provided on the mounting support 11 such that the mounting support 11 can move along the guide posts 14.

A support 11 is mounted for movement along the guide posts 14.

And the spring 13 is used for reserving a preset compression amount to ensure that the contact between the mounting support 11 and the guide post 14 is firm.

Positive conductor 12 and negative conductor 19 are disposed on the mounting support for enabling electrical energy transfer with second conductive system 16.

The positive conductor 12 and the negative conductor 19 are connected to the positive and negative poles of the second conductive system 16; that is, the positive conductor 12 is connected to the positive conductive contact 17 of the second conductive system 16, and the negative conductor 19 is connected to the negative conductive contact 21 of the second conductive system 16; the positive and negative conductive members (including 12 and 19 shown in fig. 4) of the first conductive system 15 are in contact with the positive and negative conductive contacts (including 17 and 21 shown in fig. 4) of the second conductive system 16, so as to conduct, and charge the cleaning device 20.

In practical applications, the conductive members (including 12 and 19 shown in fig. 4) are ramp-type conductive members, so that the conductive members (including 12 and 19 shown in fig. 4) are in close contact with the conductive contacts (including 17 and 21 shown in fig. 4) of the second conductive system 16, the problem of poor contact is avoided, and the contact accuracy is improved.

A second conductive system 16, comprising: a positive conductive contact 17, a negative conductive contact 21, and a mounting support mechanism 18.

The positive conductive contact 17 and the negative conductive contact 21 are both arranged on the mounting support mechanism 18 and used for realizing the electric energy transmission with the first conductive system 15.

The positive conductive contact 17 and the negative conductive contact 21 are correspondingly connected with the positive electrode and the negative electrode of the first conductive system 15; that is, the positive conductive contact 17 is connected to the positive conductor 12 of the first conductive system 15 and the negative conductive contact 21 is connected to the negative conductor 19 of the first conductive system 15; after the positive and negative conductive members (including 12 and 19 shown in fig. 4) of the first conductive system 15 contact with the conductive contacts (including 17 and 21 shown in fig. 4) of the second conductive system 16, conduction is achieved, and the cleaning device 20 can be charged.

In practical applications, the conductive contacts (including 17 and 21 shown in fig. 4) have curved shapes, which ensure smooth contact with the conductive members (including 12 and 19 shown in fig. 4) of the first conductive system 15.

Specifically, the conductive contacts (including 17 and 21 shown in fig. 4) are in the shape of at least one of a sphere and a cylinder. Of course, the conductive contacts (including 17 and 21 shown in fig. 4) are not excluded from other shapes, and are not described in detail here, and are within the protection scope of the present application.

Features described in the embodiments in the present specification may be replaced with or combined with each other, and the same and similar portions among the embodiments may be referred to each other, and each embodiment is described with emphasis on differences from other embodiments. In particular, the system or system embodiments are substantially similar to the method embodiments and therefore are described in a relatively simple manner, and reference may be made to some of the descriptions of the method embodiments for related points. The above-described system and system embodiments are merely illustrative, wherein units described as separate components may or may not be physically separate, and components shown as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.

Those of skill would further appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both, and that the various illustrative components and steps have been described above generally in terms of their functionality in order to clearly illustrate this interchangeability of hardware and software. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (13)

1. A charging system for a cleaning device, comprising: the system comprises a charging mechanism, a bracket, a self-powered photovoltaic panel and a parking position;

the self-powered photovoltaic panel is arranged at a preset position; wherein the preset position comprises: at least one of each component gap on the support, a moving track between the stand and the support and the stand;

the self-powered photovoltaic panel is connected with the charging mechanism through a lead to charge the cleaning device;

the first conductive system of the charging mechanism is arranged on the parking place;

and the second conductive system of the charging mechanism is arranged on the cleaning device.

2. The charging system for a cleaning device as set forth in claim 1, wherein said holder is a fixed holder or a tracking holder.

3. The charging system for a sweeping device according to claim 1, wherein the stand is a fixed stand or a movable stand.

4. The charging system for a cleaning device as set forth in claim 3, wherein when the stand is a movable stand, a cleaning unit is integrated with the movable stand.

5. The charging system for a cleaning device as claimed in claim 3, wherein when the stand is a movable stand, the conductive unit for supplying power to the movable stand is disposed at an edge of the rail of the movable stand.

6. The charging system for a sweeping device according to claim 3, wherein said movable stand is a ferry vehicle.

7. The charging system for cleaning devices as defined in claim 1, wherein said charging mechanism is further connected to an external power supply system via a wire.

8. The cleaning device charging system according to any one of claims 1 to 7, wherein the charging mechanism includes: a first conductive system and a second conductive system;

the first conductive system is connected with the self-powered photovoltaic panel;

the contact between the two conductive systems can transfer electric energy to charge the cleaning device.

9. The charging system for a cleaning device as set forth in claim 8, wherein said first conducting system comprises: the device comprises a positive electrode conductive piece, a negative electrode conductive piece, a mounting support piece, a spring and a guide post;

the guide post is used for guiding and supporting the mounting support piece;

the mounting support is used for moving along the guide post;

the spring is used for reserving a preset compression amount to ensure that the mounting support and the guide post are firmly contacted;

each conductive piece is arranged on the mounting support piece and used for realizing electric energy transmission with the second conductive system.

10. The charging system for a sweeping device according to claim 9, wherein said conductive member is a ramp-type conductive member.

11. The charging system for a sweeping device according to claim 8, wherein said second conducting system comprises: the device comprises a positive conductive contact, a negative conductive contact and an installation supporting mechanism;

each conductive contact is arranged on the mounting and supporting mechanism and used for realizing the electric energy transmission with the first conductive system.

12. The cleaning device charging system according to claim 11, wherein the conductive contact is curved.

13. The sweeping device charging system of claim 11, wherein the conductive contacts are at least one of spherically and cylindrically shaped.

Images