JP6913250B2 - Plug-in connection structure for charging, charging stake, robot and its automatic charging system - Google Patents

Description

The present invention relates to the technical field of robots, and particularly to charging plug-in connections, charging stakes, robots and their automatic charging systems.

With the continuous development of information technology, robots based on various functions and various application scenarios are increasingly widely used in various fields of social production. Mobile robots are widely used in industries such as industry, agriculture, medical care, and services as autonomous systems that integrate multiple functions such as environment sensing, dynamic decision-making / planning, and behavior control / execution. Autonomous transportation and picking in places such as warehousing / logistics and production workshops are developing rapidly.

Mobile robots generally consist of energy systems, mechanical structures and sensing systems. The sensing system refers to the sensing system consisting of the sensors, main controller, actuators, and other accessories of the mobile robot, and the mechanical structure includes the chassis, traveling mechanism, and mounting mechanism for mounting and mounting the sensing system. Includes protective chassis. The energy system is mainly a power battery, a battery management system and a charging device, and generally, the charging method of the mobile robot uses a method of manually charging the robot. The manual charging mode is not only labor-intensive, but also has a low degree of automation, which is disadvantageous for the autonomous and continuous work of the mobile robot. In order to realize automatic charging of a robot, generally, a power supply device such as a charging stake is installed, and the mobile robot and the power supply terminal of the power supply device are automatically aligned and connected by using an automatic docking device. Achieve charging operation.

When realizing automatic charging using a charging stake, the most important part is to solve the problem of accurate docking of the charging plug of the mobile robot and the receiving plate of the charging stake. The conventional docking structure can be aligned and fitted using various structures such as a conical structure and a conical cavity to achieve a good automatic alignment connection, but it is difficult to attach the charging contact piece. The contact between the charging contact pieces becomes unstable, the charging contact pieces are heated violently and become dangerous, and the CCD graphic positioning / recognition is combined with the 3-axis moving platform to achieve the correct position. Alignment may be achieved, and this automatic alignment device is complicated in structure and expensive. Therefore, it is necessary to further optimize the conventional automatic alignment device.

The technical problem to be solved by the present invention is a charging difference in order to solve the technical problem that the conventional mobile robot for automatic charging cannot easily and accurately align or recognize the charging stake. It is to provide a built-in connection structure, a charging stake, a robot and its automatic charging system.

In order to achieve the above object, according to the first aspect of the embodiment of the present invention,
The flexible receiving plate includes a support base, a flexible receiving plate, and an insertion panel provided on the flexible receiving plate, and the flexible receiving plate is provided via a plurality of elastic members evenly arranged in the circumferential direction. Attached to the support base, an elastic displacement amount is generated in the circumferential direction perpendicular to the insertion direction, the insertion panel is provided with an insertion socket, and the insertion socket is provided with a plurality of female connector vias. Provides a plug-in connection structure for charging.

According to the second aspect of the embodiment of the present invention, a mounting housing, a PCB function motherboard provided inside the mounting housing, and a power conversion module, a charge monitoring module, and a charge monitoring module electrically connected to the PCB function motherboard. A network communication module is provided at least, the mounting housing is provided with the charging plug-in connection structure, and an elastic contact piece group is correspondingly provided inside the female connector via, and the elastic contact piece group is provided. Provides an automatic charging pile connected to the output terminal of the power conversion module via a charging lead.

According to the third aspect of the embodiment of the present invention, the drive battery unit, the sensing execution system, the frame housing and the moving wheel group are provided, and the sensing execution system and the driving battery unit are housed inside the frame housing. Installed in space, the sensing execution system includes at least a sensor module, a GPU controller and an execution drive unit connected to the moving wheel group at the bottom of the frame housing, at one end of the frame housing the charging difference. A charging interface structure that fits corresponding to the built-in connection structure is further provided, the charging interface structure is provided with a plug-in groove that fits corresponding to the plug-in socket, and the plug-in groove is provided with a plug-in groove that fits. A charging male connector is provided corresponding to the female connector via, and the charging male connector provides a mobile robot connected to the driving battery unit.

According to the fourth aspect of the embodiment of the present invention, the robot is provided corresponding to the positioning recognition sensor unit, the automatic charging pile to which the charging plug-in connection structure is attached, and the charging plug-in connection structure. The charging interface structure is provided with at least a charging interface structure, the charging interface structure is provided with an insertion groove corresponding to the insertion socket, and the insertion groove is provided with a charging male connector corresponding to the female connector via. Provide a robot automatic charging system in which the charging male connector is connected to the driving battery unit of the robot.

According to the above technical proposal, in the charging insertion connection structure, the charging pile, the robot and its automatic charging system according to the embodiment of the present invention, by providing a flexible receiving plate, an elastic member is used in the insertion direction. Stablely limited to a plane perpendicular to the plane in the circumferential direction of 360 °, and due to the action of the elastic member, the flexible receiving plate generates a fine displacement in the circumferential direction of 360 °, and when it is inserted and docked. If it is difficult to dock the insertion socket and the insertion groove smoothly due to the influence on the automatic charging pile due to the unevenness of the ground, etc., and the positioning tolerance existing in the automatic positioning recognition sensor unit itself of the mobile robot, it is flexible. The sex plate increases the tolerance of docking error, which greatly reduces the difficulty of automatic alignment and clearly improves the practicality and applicability of the automatic charging system.

In order to more clearly explain the embodiment of the present invention or the technical proposal of the prior art, the drawings necessary for the description of the embodiment or the prior art will be briefly described below, but as is clear, the drawings in the following description will be described. Are only a few examples of the present invention, and one of ordinary skill in the art may obtain other drawings based on these drawings without the need for creative effort.
It is a front view of the plug-in connection structure for 1st charge of the Example of this invention. It is a top view of the plug-in connection structure for 1st charge of the Example of this invention. It is a three-dimensional view of the plug-in connection structure for 1st charge of the Example of this invention. FIG. 1 is a three-dimensional explosion of a first charging plug-in connection structure according to an embodiment of the present invention. FIG. 2 is a three-dimensional explosion diagram 2 of a plug-in connection structure for first charging according to an embodiment of the present invention. It is a front view of the plug-in connection structure for 2nd charge of the Example of this invention. It is a front view of the plug-in connection structure for the third charge of the Example of this invention. It is a front structure view of the automatic charging pile of the Example of this invention. It is a front structure view of the mobile robot of the Example of this invention. FIG. 1 is a three-dimensional diagram of a charging interface structure according to an embodiment of the present invention. FIG. 2 is a three-dimensional diagram 2 of a charging interface structure according to an embodiment of the present invention. It is a structural schematic diagram of the robot automatic charging system of the Example of this invention.

Hereinafter, specific embodiments of the present invention will be further described with reference to the drawings. However, the description of these embodiments facilitates the understanding of the present invention and does not limit the present invention. Furthermore, the technical features described in each embodiment of the invention described below can be combined with each other as long as they do not conflict with each other.

Example 1
As shown in FIG. 1-5, an embodiment of the present invention provides a charging plug-in connection structure 110, wherein the charging plug-in connection structure 110 includes a support base 111, a flexible receiving plate 112, and a flexible receiving plate 112. A plug-in panel 113 provided on the flexible receiving plate 112 is provided, and the flexible receiving plate 112 is attached to the support base 111 via a plurality of elastic members evenly arranged in the circumferential direction. An elastic displacement amount is generated in the circumferential direction perpendicular to the insertion direction, the insertion panel 113 is provided with the insertion socket 1132, and the insertion socket 1132 is provided with a plurality of female connector vias 1133.

Specifically, the support base 111 includes a connection plate 1111 and a vertical mounting plate 1112 perpendicular to the connection plate 1111, and the connection plate (1111) is uniformly provided with a plurality of mounting holes (1113). The flexible receiving plate (112) is attached to the vertical mounting plate (1112) via a plurality of elastic members evenly arranged in the circumferential direction, and the flexible receiving plate (112) is vertical. Generates an elastic displacement on the surface. The connection plate 1111 is used to fix the support base 111 to the mounting housing 120 of the charging stake, and fits the support base 111 with the corresponding screw holes of the mounting housing 120 via the mounting holes 1113 to provide the support base 111. It is mounted at the corresponding position on the mounting housing 120.

Specifically, as shown in FIG. 2, one end of the elastic member is connected to a tension buckle 1123 provided on the flexible receiving plate 112, and the other end is a fixed terminal provided on the vertical mounting plate 1112. It is a tensile elastic member 1121 connected to 1114, and at least four of the tensile elastic members 1121 are evenly arranged on a vertical plane. The plurality of tensile elastic members 1121 apply a uniform tensile force to the flexible receiving plate 112 in the direction of 360 ° of the vertical surface, whereby the flexible receiving plate 112 when there is no external force on the vertical surface. Is always held in a stable relative position with respect to the vertical mounting plate 1112.

Preferably, the tensile elastic member 1121 may be an elastic structural member capable of generating a tensile contraction force, such as a tensile spring, a rubber band, an elastic rope, or an elastic metal reed. The fixed terminal 1114 can be mounted or installed on the vertical mounting plate 1112 by various methods such as screwing, welding, inserting, and punching the sheet metal integrally with the vertical mounting plate 1112, and corresponds to the tensile elastic member. The 1121 may be provided with a connection structure such as a ring, buckle, hook, fixed connector or the like. The tension buckle 1123 has a connection structure that is attached to the flexible receiving plate 112 by a method of processing the protruding portion of the flexible receiving plate 112 by integrally punching the sheet metal, or a method of screwing, welding, inserting, or the like. There may be.

Preferably, as shown in FIG. 6, the elastic member has one end attached to the vertical mounting plate 1112 via a fixed connecting base and the other end via another fixed connecting base. It is a compressive elastic member 1126 attached to 112, and at least four of the compressive elastic members 1126 are evenly arranged on a vertical surface. Similar to the tensile elastic member 1121, the plurality of compressive elastic members 1126 apply a uniform tensile force to the flexible receiving plate 112 in the direction of 360 ° of the vertical surface, whereby there is no external force on the vertical surface. Sometimes the flexible backing plate 112 is always held in a stable relative position with respect to the vertical mounting plate 1112.

Preferably, the compressive elastic member 1126 may have various elastic structures capable of generating compressive and tensile forces, such as compression springs and elastic silicone columns. The fixed connection base may be a raised portion integrally punched out in the vertical mounting plate 1112 and the flexible receiving plate 112, and is screwed, welded, and inserted into the vertical mounting plate 1112 and the flexible receiving plate 112. Alternatively, it may be a riveted connecting structural member.

Preferably, as shown in FIG. 7, the elastic member is an elastic support column 1124, with both ends of the plurality of elastic support columns 1124 via a fixed connection base to the vertical mounting plate 1112 and the flexibility, respectively. It is fixed horizontally with the receiving plate 112. The elastic support column 1124 can generate minute displacements in both the horizontal and vertical directions, and can maintain a stable relative position with respect to the vertical mounting plate 1112 even when there is no external force. The elastic support column 1124 may be various elastic structural members that can be expanded and contracted, such as springs and elastic silicones. The fixed connection base may be a raised portion integrally punched out in the vertical mounting plate 1112 and the flexible receiving plate 112, and is screwed, welded, and inserted into the vertical mounting plate 1112 and the flexible receiving plate 112. Alternatively, it may be a riveted connecting structural member.

Further, the elastic member is a tensile elastic member 1121 or a compressive elastic member 1126, and at least four of the tensile elastic member 1121 or the compressive elastic member 1126 are evenly arranged on a vertical surface, and the flexible receiving plate is provided. A plurality of limiting support columns 1122 are provided between the 112 and the vertical mounting plate 1112, and one end of the limited supporting column 1122 is fixed to the vertical mounting plate 1112 and the other end is the flexible receiving plate. The limiting support column 1122 is slidably contacted with the 112, or the limiting support column 1122 has one end fixed to the flexible receiving plate 112 and the other end slidably contacting the vertical mounting plate 1112. The tensile elastic member 1121 or the compressive elastic member 1126 supports the flexible receiving plate 112 by generating a tensile force or a compressive force in the direction of 360 ° of the vertical plane, and supports the flexible receiving plate 112 in the horizontal direction. Is abutted against the vertical mounting plate 1112 via an extending structural member, or is provided with a limiting support column 1122 to form a horizontal bearing force.

Preferably, a ball is provided at the free end of the limiting support column 1122, which allows slidable contact. Further, the ball is attached to the inside of the limiting support column 1122 via a spring and cushions a part of the impact force in the insertion direction when docked for charging.

Further, the insertion panel 113 includes a panel housing 1131 covered by the flexible receiving plate 112 and the insertion socket 1132 integrally molded with the panel housing 1131, and the insertion socket 1132. The female connector via 1133 is provided at the tip, and an elastic contact piece group 1135 is correspondingly provided inside the female connector via 1133, and the elastic contact piece group 1135 is connected to a corresponding charging lead. A data line via 1134 is further provided on one side of the female connector via 1133, and a data contact female terminal 1136 is provided inside the data line via 1134.

Specifically, three female connector vias 1133 are provided at the tip of the insertion socket 1132, and the three female connector vias 1133 are arranged in a character shape or a triangular shape, and the three female connector vias 1133 are arranged. An elastic contact piece group 1135 is provided inside any of the above, and the elastic contact piece group 1135 is fixed to the inside of the insertion socket 1132 via a contact piece mounting base 1137. The three female connectors may be live wire, neutral wire and ground when AC charging is performed via the via 1133, and one of the female connector vias 1133 is guided through the guide hole when DC charging is performed. Can be.

At the tip of the plug socket 1132, two data line vias 1134 are provided below the three female connector vias 1133, and data contact female terminals 1136 are provided corresponding to each data line via 1134. The contact female terminal 1136 is provided inside the insertion socket 1132 via the female terminal mounting piece 1138 and is located below the contact piece mounting base 1137.

Preferably, one side of the panel housing 1131 is provided with a cable through hole 1139 for mounting the charging lead and the data line.

Example 2
As shown in FIG. 8, an embodiment of the present invention further provides an automatic charging pile 100, wherein the charging pile is a mounting housing 120, a PCB functional motherboard provided inside the mounting housing 120, and the said. At least a power conversion module 130, a charge monitoring module 140, and a network communication module 150 that are electrically connected to the PCB function motherboard are provided, and the mounting housing 120 is provided with the charging plug connection structure 110 of the first embodiment. An elastic contact piece group 1135 is correspondingly provided inside the female connector via 1133, and the elastic contact piece group 1135 is connected to an output terminal of the power conversion module 130 via a charging lead.

Specifically, the support base 111 of the charging plug-in connection structure 110 is generally mounted on the outside of the side wall in the circumferential direction of the mounting housing 120, or above and below the mounting housing 120 depending on the usage scenario. Attached to both ends. Correspondingly, the charging interface structure 210 of the mobile robot 200 is also provided on the side portion or the upper and lower ends of the mobile robot 200, whereby the automatic charging pile 100 and the mobile robot 200 have docking portions corresponding to each other.

The data contact female terminal 1136 of the plug-in connection structure 110 for charging uploads the related parameters of the drive battery unit 230 of the mobile robot 200, particularly the battery management system, to the automatic charging pile 100 via the data line, and the automatic charging pile The 100 monitors the charging status of the battery, for example, data such as voltage, current and remaining amount in real time, adjusts the output voltage and output current based on these data, and automatically turns on the charging power supply after the battery charging is completed. The battery of the mobile robot 200 is protected by cutting the current.

Example 3
As shown in FIG. 9, an embodiment of the present invention provides a mobile robot 200, which includes a drive battery unit 230, a sensing execution system 240, a frame housing 220 and a mobile wheel group 250. The sensing execution system 240 and the driving battery unit 230 are attached to the accommodation space inside the frame housing 220, and the sensing execution system 240 is the sensor module 241 and the GPU controller 242 and the bottom of the frame housing 220. An execution drive unit 243 connected to the moving wheel group 250 is included, and at one end of the frame housing 220, a charging interface structure 210 that fits with the charging plug connection structure 110 of the first embodiment is further provided. The charging interface structure 210 is provided with an insertion groove 212 for fitting corresponding to the insertion socket 1132, and the insertion groove 212 has a charging male connector 213 corresponding to the female connector via 1133. The charging male connector 213 is provided and is connected to the driving battery unit 230.

As shown in FIGS. 10 and 11, the charging interface structure 210 is provided in the receiving panel 211, the receiving panel 211, and the insertion groove 212 and the insertion groove 212 which are fitted corresponding to the insertion socket 1132. A charging male connector 213 provided corresponding to the female connector via 1133 and a data male connector 214 provided corresponding to the data line via 1134 are provided inside the above. The data male connector 214 is fixed to the back surface of the insertion groove 212 via the data male connector mounting piece 215, and the data male connector 214 is fitted with the data contact female terminal 1136 to form a robot drive battery unit 230. The data is transmitted to the automatic charging pile 100. The charging male connector 213 may be a metal conductor column having a circular or square equal cross section, which is fitted corresponding to the elastic contact piece group 1135, and the elastic contact piece group 1135 has two pieces having a certain elasticity. The metal pieces are provided symmetrically, and the metal conductor column is provided between the metal pieces and is in close contact with each other by elasticity, or one elastic metal piece is curved so that both ends are in contact with each other. , Preferably a copper plate.

Preferably, a plurality of panel support columns 216 are evenly provided on the back surface of the receiving panel 211, and panel screw holes 217 are evenly provided on the edge of the receiving panel 211, and the panel support columns 216 and the panel screw holes 217 are provided. The receiving panel 211 is fixedly supported by the battery case, whereby the insertion groove 212 coincides with the insertion direction.

Specifically, the groove width of the insertion groove 212 decreases from the groove opening toward the groove bottom, and the cross section of the corresponding insertion socket 1132 increases from the end face toward the bottom. For example, the insertion groove 212 may have a trapezoidal groove, or any other structure in which the groove width decreases from the groove opening toward the groove bottom, and the insertion socket 1132 is vice versa. The inner wall of the insertion groove 212 may be smoothed. The part where the two surfaces inside the trapezoidal groove are joined has the shape of an arc line. The insertion groove 212 preferably has a shape similar to that of a trapezoidal groove, and such a cross-sectional shape has a better positioning action than a circular or conical shape, and the relative direction between the insertion groove 212 and the insertion socket 1132. Can be aligned and connected only if is accurate, thus avoiding poor contact due to reverse insertion or rotation.

Example 4
As shown in FIG. 12, an embodiment of the present invention further provides a robot automatic charging system, which is an automatic charging system to which the positioning recognition sensor unit 260 and the charging plug-in connector structure of the first embodiment are attached. A charging pile 100 and a charging interface structure 210 provided in the robot corresponding to the charging plug-in connection structure are provided at least, and the charging interface structure 210 is fitted with a difference corresponding to the plug-in socket 1132. The insertion groove 212 is provided, and the insertion groove 212 is provided with a charging male connector 213 corresponding to the female connector via 1133, and the charging male connector 213 is provided in the driving battery unit 230 inside the robot 200. Be connected.

Specifically, the positioning recognition sensor unit is used to recognize the position of the automatic charging pile 100, and the automatic charging pile 100 and the mobile robot 200 are based on a wireless communication method such as WiFi or Bluetooth (registered trademark). Data can be sent and received. If the remaining amount of the mobile robot 200 is insufficient and it is necessary to charge it, the position of the automatic charging stake 100 is specified by a method such as WiFi or Bluetooth (registered trademark), and the robot automatically arrives near the automatic charging stake 100. Alternatively, the position of the automatic charging stake 100 is preset in the mobile robot 200, the mobile robot 200 arrives in the vicinity of the automatic charging stake 100 according to a predetermined route, and the mobile robot 200 is in the vicinity of the automatic charging stake 100. At one time, a plurality of methods such as CCD pattern recognition, infrared sensing, radar guidance, and laser guidance can be used to determine an accurate insertion direction, and the insertion can be performed quickly.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the present invention is not limited to the described embodiments. As a person skilled in the art, various changes, modifications, substitutions and modifications made to these embodiments without departing from the principles and gist of the present invention are also within the scope of the invention.

In the charging insertion connection structure, the automatic charging pile, and the robot automatic charging system according to the embodiment of the present invention, by providing a flexible receiving plate, an elastic member is used to rotate 360 ° on a plane perpendicular to the insertion direction. It is stably limited in the direction, and due to the action of the elastic member, the flexible receiving plate generates a fine displacement in the circumferential direction of 360 °, and when it is inserted and docked, the automatic charging pile due to the unevenness of the ground etc. When it is difficult to dock the insertion socket and the insertion groove smoothly due to the influence on the robot and the positioning tolerance existing in the automatic positioning recognition sensor unit itself of the mobile robot, the allowable amount of docking error is allowed by the flexible receiving plate. Increases, thereby significantly reducing the difficulty of automatic alignment and clearly improving the practicality and applicability of the automatic charging system. Therefore, it has industrial applicability.

100-Automatic charging pile 110-Drive connection structure for charging 120-Mounting housing 130-Power conversion module 140-Charging monitoring module 150-Network communication module 160-PCB function motherboard 200-Mobile robot 210-Charging interface structure 220-Frame Housing 230-Drive battery unit 240-Sensing execution system 250-Mobile wheel group 241-Sensor module 241
242-GPU controller 242
243-Executive drive unit 111-Support base 1111-Connector plate 1112-Vertical mounting plate 1113-Mounting hole 1114-Fixed terminal 112-Flexible receiving plate 1121-Tensile elastic member 1122-Limited support column 1123-Tension buckle 1124-Elasticity Support column 1125-Fixed connection 1126-Compressive elastic member 113-Insert panel 1131-Panel housing 1132-Insert socket 1133-Female connector via 1134-Data line via 1135-Elastic contact piece group 1136-Data contact female terminal 1137- Contact piece mounting base 1138-Female terminal mounting piece 1139-Cable through hole 211-Receiving panel 212-Inlet groove 213-Charging male connector 214-Data male connector 215-Data male connector mounting piece 216-Panel support pillar 217-Panel screw hole

Claims (9)

It has a plug-in connection structure for charging,
The support base (111), the flexible receiving plate (112), and the insertion panel (113) provided on the flexible receiving plate (112) are provided, and the flexible receiving plate (112) is provided in the circumferential direction. It is attached to the support base (111) via a plurality of elastic members evenly arranged in the insertion direction, and an elastic displacement amount is generated in the circumferential direction perpendicular to the insertion direction. A plug-in socket (1132) is provided, and the plug-in socket (1132) is provided with a plurality of female connector vias (1133) .
The support base (111) includes a connecting plate (1111) and a rectangular vertical mounting plate (1112) perpendicular to the connecting plate (1111).
A plurality of tension buckles (1123) are provided in the central portion of the flexible receiving plate (112), and a plurality of tension buckles (1123) correspond to the rectangular vertical mounting plate (1112). A fixed terminal (1114) is provided,
The plurality of elastic members are at least four tensile elastic members (1121) having one end connected to the tensile buckle (1123) and the other end connected to the fixed terminal (1114), and the at least four elastic members. the tensile elastic member (1121), respectively, the charge from the central portion, that is located towards the positions of the four apex angles of the rectangular vertical mounting plate (1112) of said flexible backing plate (112) Plug-in connection structure. The front SL connection plate (1111), a plurality of mounting holes (1113) are provided evenly, wherein the vertical mounting plate (1112) via a plurality of elastic members are disposed uniformly in the circumferential direction the The charging plug-in connection structure according to claim 1, wherein a flexible receiving plate (112) is attached, and the flexible receiving plate (112) generates an elastic displacement amount in a vertical surface. The even without least four of the tensile elastic member (1121) are uniformly arranged in a vertical plane, the charging plug connection structure according to claim 1. Between the front Symbol flexible backing plate (112) and said vertical mounting plate (1112), at least four restriction support column (1122) are provided, the limited support column (1122), said rectangular Located in each of the four areas separated by the diagonals of the vertical mounting plate (1112), the limiting support column (1122) has one end fixed to the vertical mounting plate (1112) and the other end the flexible receiver. Sliding contact with the plate (112), or the limiting support column (1122), one end fixed to the flexible receiving plate (112) and the other end slidable to the vertical mounting plate (1112). contact, charging plug connection structure according to claim 1. A ball is provided at the free end of the limiting support column (1122), and the ball is attached to the inside of the limiting support column (1122) via a spring and is slidably contacted by the ball. Plug-in connection structure for charging according to 4. The insertion panel (113) includes a panel housing (1131) covered by the flexible receiving plate (112) and the insertion socket (1132) integrally molded with the panel housing (1131). A female connector via (1133) is provided at the tip of the insertion socket (1132), and an elastic contact piece group (1135) is correspondingly provided inside the female connector via (1133). , The elastic contact piece group (1135) is connected to a corresponding charging lead, and a data line via (1134) is further provided on one side of the female connector via (1133). The charging plug-in connection structure according to any one of claims 1-5, wherein a data contact female terminal (1136) is provided inside the device. It ’s an automatic charging stake,
A mounting housing (120), a PCB functional motherboard (160) provided inside the mounting housing (120), a power conversion module (130) electrically connected to the PCB functional motherboard (160), and charge monitoring. A charging plug connection structure (110) according to any one of claims 1 to 6 is provided in the mounting housing (120), which includes at least a module (140) and a network communication module (150). An elastic contact piece group (1135) is correspondingly provided inside the female connector via (1133), and the elastic contact piece group (1135) is an output of the power supply conversion module (130) via a charging lead. An automatic charging pile connected to the terminal. It ’s a mobile robot,
The drive battery unit (230), the sensing execution system (240), the frame housing (220), and the moving wheel group (250) are provided, and the sensing execution system (240) and the driving battery unit (230) are the frame. Attached to the containment space inside the housing (220), the sensing execution system (240) comprises the sensor module (241), the GPU controller (242) and the moving wheel group (250) at the bottom of the frame housing (220). At least one of the execution drive units (243) connected to the frame housing (220) corresponds to the charging plug connection structure (110) according to any one of claims 1 to 6. A charging interface structure (210) for fitting is further provided, and the charging interface structure (210) is provided with an insertion groove (212) for fitting corresponding to the insertion socket (1132). The groove (212) is provided with a charging male connector (213) corresponding to the female connector via (1133), and the charging male connector (213) is connected to the drive battery unit (230) to move. robot. It is a robot automatic charging system
A positioning recognition sensor unit (260), an automatic charging pile (100) to which the charging plug-in connection structure (110) according to any one of claims 1 to 6 is attached, and the charging plug-in connection structure ( A charging interface structure (210) provided in the robot (200) corresponding to 110) is provided at least, and the charging interface structure (210) is fitted with an insertion groove corresponding to the insertion socket (1132). (212) is provided, the insertion groove (212) is provided with a charging male connector (213) corresponding to the female connector via (1133), and the charging male connector (213) is the robot (200). ) Internal drive battery unit (230) connected to the robot automatic charging system.

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