CN217362077U - Multipurpose charging socket - Google Patents

Abstract

The application relates to the field of socket, especially relate to a multi-purpose socket that charges, multi-purpose socket that charges includes: a socket body provided with a plug-in area; the charging rack is provided with a wireless charging transmitting module used for outputting electric energy to the wireless charging receiving equipment, an included angle is formed between the charging rack and the socket body, and the charging rack is provided with a wireless charging area for the wireless charging receiving equipment to be placed; the charging frame is connected to the socket body. The electric appliance can be through pegging graft in the plug-in region of socket with power plug in order to acquire the electric energy, and wireless receiving equipment that charges can enough provide the function that the plug-in charges through placing in the wireless district that charges of charging frame in order to acquire the electric energy, can support wireless rechargeable again, and the function is more diversified, and is wider to battery charging outfit's application scope.

Description

Multipurpose charging socket

Technical Field

The application relates to the field of sockets, in particular to a multipurpose charging socket.

Background

The socket is also called a power socket and a switch socket, an electrical accessory used for connecting terminals of a cable is arranged in the socket, and the socket is provided with a jack for plugging a plug. When the plug is plugged into the socket through the conventional jack, the plug can be electrically connected with the electrical accessories in the socket. However, the existing socket has a single function, and most sockets can only support a wired charging mode, so that the socket has room for improvement.

Disclosure of Invention

In order to make the function of socket more diversified to it is more convenient to use, this application provides a multi-purpose socket that charges.

The application provides a multi-purpose socket that charges adopts following technical scheme:

a multi-purpose charging receptacle, comprising: a socket body provided with a plug-in area; the charging rack is provided with a wireless charging transmitting module used for outputting electric energy to wireless charging receiving equipment, an included angle is formed between the charging rack and the socket body, and the charging rack is provided with a wireless charging area for the wireless charging receiving equipment to be placed; the charging frame is connected to the socket body.

Through adopting above-mentioned technical scheme, contained angle has between charging frame and the vertical direction for wireless receiving equipment can place in the top of charging frame, and the top of charging frame forms the wireless charging district that supplies wireless receiving equipment to place. The electric appliance can be through pegging graft in the plug-in region of socket with power plug in order to acquire the electric energy, and wireless receiving equipment that charges can enough provide the function that the plug-in charges through placing in the wireless district that charges of charging frame in order to acquire the electric energy, can support wireless rechargeable again, and the function is more diversified, and is wider to battery charging outfit's application scope. Simultaneously, because the charging frame separates plug-in area and wireless charging district, has reduced the wireless receiving equipment that charges who places in wireless charging district and has taken the space of plug-in area for plug-in charging and wireless charging can go on simultaneously, and are more convenient.

Optionally, the charging rack is connected to the upper portion of the socket body, and the wireless charging area is disposed above the charging rack.

Through adopting above-mentioned technical scheme, the charging frame is connected in socket ontology's upper portion to make the grafting district be located the below of charging frame, thereby utilize the inclination and the mounted position of charging frame, separate grafting district and wireless charging district ingeniously, make grafting district and wireless charging district be located the top and the below of charging frame respectively, the structure is succinct more, compact.

Optionally, the charging frame is rotatably connected to the socket body, and a variable rotation angle is provided between the charging frame and the socket body.

Through adopting above-mentioned technical scheme, when the charging frame need not provide the electric energy, can make the contained angle between charging frame and the socket ontology diminish gradually through the mode that rotates the charging frame, reduce the space of charging frame on the horizontal direction and occupy, improve space utilization.

Optionally, a positioning structure for matching and positioning is arranged between the charging rack and the socket body.

Through adopting above-mentioned technical scheme, when wireless receiving equipment that charges places in the wireless charging area of charging frame, location structure prevents that the charging frame from taking place the rotation by oneself under the action of gravity of wireless receiving equipment that charges, improves wireless receiving equipment's that charges stability of charging.

Optionally, the positioning structure specifically includes: the socket comprises a socket body and is characterized in that a limiting groove or a limiting bulge is arranged on the charging rack, the socket body is provided with the limiting bulge in clamping fit with the limiting groove, or the socket body is provided with the limiting groove in clamping fit with the limiting bulge; the limiting protrusion positions the charging rack at a set angle in a clamping mode with the limiting groove.

Through adopting above-mentioned technical scheme, place in the wireless charging area of charging frame when wireless receiving equipment that charges, spacing groove and spacing protruding joint cooperation prevent that the charging frame from taking place the rotation by oneself under wireless receiving equipment that charges's the action of gravity, improve wireless receiving equipment's that charges stability of charging.

Optionally, the socket body or be provided with the holding hole on the charging frame, the elastic component has set gradually from inside to outside in the holding hole spacing arch, spacing arch is in the elastic component effect part stretches out the holding hole down, spacing arch can the retraction under the exogenic action the holding is downthehole.

Through adopting above-mentioned technical scheme, when the charging frame is equivalent to socket ontology and rotates to the closure state from the open mode, along with the rotation of charging frame itself, can break away from the joint state between spacing groove and the spacing arch, spacing bellied arcwall face makes spacing arch can break away from the joint state fast, and is more laborsaving. The containing hole provides the space that slides for spacing arch, and joint elastic component provides the power that slides for spacing arch for spacing groove can break away from the joint state fast or get into the joint state, and the charging frame of being convenient for carries out the state switching.

Optionally, one end of the charging frame, which is far away from the connection between the charging frame and the socket body, is provided with a bending portion, and the bending portion bends towards a direction close to the wireless charging area.

Through adopting above-mentioned technical scheme, when wireless receiving equipment that charges places in wireless charging area, the portion of bending can prevent to place in wireless charging area's wireless receiving equipment that charges and break away from wireless charging area, improves the charging stability. When the charging frame is in a closed state, the bending part can be spaced from the socket body, the charging frame is convenient to rotate under stress, and the charging frame is convenient to switch states.

Optionally, one end of the socket body is provided with a mounting table, and the charging rack is rotatably connected to the mounting table.

By adopting the technical scheme, when the charging frame is in a closed state, the charging frame can be parallel to and attached to the panel of the socket body, so that the distance between the charging frame and the socket body is reduced to the maximum extent.

Optionally, the charging frame is provided with an abdicating groove for accommodating the mounting table, one side of the abdicating groove is provided with a shielding piece, and the shielding piece limits the rotation range of the mounting table.

Through adopting above-mentioned technical scheme, shelter from the piece and can prevent to take place excessively to rotate between mount table and the charging frame, reduce and excessively rotate the risk of hanking the electric wire between bad charging frame and the socket ontology to, shelter from the piece and have the effect of sheltering from to the electric wire between charging frame and the socket ontology, carry out multiple protection to the electric wire.

Optionally, a buckle assembly and a reset elastic member are arranged between the charging rack and the socket body; the buckle assembly is used for limiting the relative rotation between the charging frame and the socket body; the reset elastic piece has pre-elastic force for driving the charging frame to rotate, so that the charging frame is opened as the socket body.

Through adopting above-mentioned technical scheme, when the charging frame need not provide the electric energy, the charging frame switches to the closed condition, and buckle subassembly takes place to rotate through preventing charging frame self. When the wireless function that charges is used to needs, can open buckle subassembly for the charging frame takes place to rotate more conveniently, swiftly under the effect of the elastic component that resets automatically.

Optionally, the charging rack and the socket body are rotatably connected through a damping rotating shaft.

Through adopting above-mentioned technical scheme, when wireless receiving equipment that charges places in the wireless charging area of charging frame, the damping pivot prevents that the charging frame from taking place the rotation by oneself under the wireless receiving equipment that charges's of charging action of gravity, improves wireless charging stability. When the charging frame automatically rotates under the action of the reset elastic piece, the rotating speed of the charging frame can be reduced by the rotating damping provided by the damping rotating shaft, and the service life of the connecting structure between the charging frame and the socket body is prolonged.

Optionally, the charging rack is provided with a connection plug, and the socket body is provided with a first socket into which the connection plug is inserted; when the connecting plug is plugged with the first jack, an included angle is formed between the charging frame and the socket body; the socket body is also provided with a second socket for the connection plug to be plugged in, and an included angle is formed between the plugging direction of the first socket and the plugging direction of the second socket; when the connecting plug is plugged with the second socket, the charging frame and the socket body are attached or parallel to each other.

Through adopting above-mentioned technical scheme, when the function that needs use wireless charging, the connecting plug of charging frame can peg graft in first socket for the charging frame is opened for socket ontology, and the charging frame can supply wireless receiving equipment that charges to place. When the charging frame does not need to provide electric energy, the connecting plug of the charging frame can be plugged in the second socket, so that the charging frame is closed relative to the socket body, and the charging frame is more convenient and quicker.

Optionally, the socket body is provided with a fast charging module, and the wireless transmitting module is electrically connected with the fast charging module through an electric wire; the socket body is provided with a double-output interface which is electrically connected with the quick-charging module.

Through adopting above-mentioned technical scheme, fill the module soon and pass through the electric wire to the power supply of wireless transmitting module. The socket body is provided with the dual output interface, can satisfy the electric demand of obtaining of multiple interface.

Drawings

Fig. 1 is a front view of a multipurpose charging socket according to a first embodiment of the present application;

fig. 2 is a schematic diagram illustrating a multi-purpose charging socket according to an embodiment of the present disclosure in a wireless charging state;

fig. 3 is a front view of the multipurpose charging socket according to the second embodiment of the application;

fig. 4 is a comparison view of the multi-purpose charging socket according to the second embodiment of the present invention in different states, in which the charging rack of fig. 4 (a) is in an open state and the charging rack of fig. 4 (b) is in a closed state;

fig. 5 is an exploded view of the charging stand and the socket body according to the second embodiment of the present application;

FIG. 6 is a schematic view of the view from the c direction in FIG. 5;

fig. 7 is an exploded view of the charging stand, the socket body and the stopper protrusion according to the third embodiment of the present application;

fig. 8 is a partially enlarged view of fig. 6 at D.

Fig. 9 is a comparison view of the multipurpose charging socket according to the fourth embodiment of the present application in different states, in which the charging stand of fig. 9 (e) is in an open state and the charging stand of fig. 9 (f) is in a closed state;

fig. 10 is a schematic structural diagram of a multipurpose charging receptacle according to a fourth embodiment of the present application;

FIG. 11 is a schematic view showing the moving trace of the latch according to the fourth embodiment of the present application, wherein the dotted solid arrows indicate the moving direction of the latch;

fig. 12 is a sectional view taken along the direction G-G in fig. 11.

Fig. 13 is a sectional view of the multipurpose charging receptacle according to the fourth embodiment in a closed state.

Fig. 14 is a comparison diagram of the multi-purpose charging socket according to the fifth embodiment of the present invention in different states, wherein the solid arrows with broken lines indicate the plugging direction of the charging rack, the charging rack in fig. 14 (h) is plugged into the first outlet, and the charging rack in fig. 14 (i) is plugged into the second outlet.

Description of reference numerals:

1. a socket body; 11. a charging interface; 12. a plug-in area; 13. a quick charging module; 14. a dual output interface; 15. a panel; 151. mounting grooves; 152. an installation port; 153. a connecting port; 16. a bottom case; 17. a first socket; 18. a second socket; 2. a charging stand; 21. a wireless charging region; 22. a support surface; 23. a non-slip mat; 24. a yielding groove; 25. a first threading hole; 26. a shielding sheet; 27. a limiting groove; 28. a position avoiding groove; 29. a bending part; 4. a wireless charging transmitting module; 5. a rotating member; 51. a damping rotating shaft; 6. a mounting table; 61. a second threading hole; 62. a limiting bulge; 63. a housing hole; 64. clamping an elastic piece; 7. a plug; 8. resetting the elastic member; 9. a buckle assembly; 91. a locking plate; 911. a slider; 912. a locking hole; 92. locking the elastic piece; 93. locking; 931. a buckling block; 10. wireless receiving arrangement that charges.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the 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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Embodiments of the present invention are described in further detail below with reference to figures 1-14 of the specification.

The embodiment of the application discloses a multi-purpose socket that charges.

The first embodiment is as follows:

referring to fig. 1, the multipurpose charging socket includes a socket body 1 and a charging stand 2, and the charging stand 2 is fixed to the socket body 1. The socket body 1 is used for plug-in connection of an electric appliance with a power plug so as to obtain electric energy. The socket body 1 can be fixed on a fixed object such as a wall, the panel 15 of the socket body 1 is provided with a charging interface 11 for plugging a power plug, and a space in front of the panel 15 of the socket body 1 forms a plugging area 12 for plugging the power plug. In the present embodiment, the socket body 1 as a whole is disposed with its face plate 15 parallel to the vertical direction by default.

Referring to fig. 2, the charging rack 2 is hollow, the wireless charging transmitting module 4 is disposed inside the charging rack 2, and the wireless charging transmitting module 4 is configured to output electric energy to the wireless charging receiving device 10 in a wireless charging manner. Specifically, the wireless charging and transmitting module 4 comprises a circuit board and a wireless charging coil, wherein the circuit board is bolted in the charging rack 2, and the wireless charging coil is welded and fixed on the circuit board. The wireless charging reception apparatus 10 refers to an electronic apparatus supporting wireless charging, such as a smartphone supporting wireless charging.

Referring to fig. 2, an included angle is formed between the charging rack 2 and the socket body 1, and in this embodiment, since the socket body 1 is disposed in a vertical direction, the included angle is also an included angle between the charging rack 2 and the vertical direction. The wireless charging reception device 10 can be placed on the upper surface of the charging stand 2 for wireless charging, and the upper space of the charging stand 2 forms a wireless charging area 21 for placing the wireless charging reception device 10.

Referring to fig. 2, when the wireless charging receiving apparatus 10 is placed on the charging stand 2, a supporting surface 22 for supporting the wireless charging receiving apparatus 10 is formed on the upper surface of the charging stand 2, and an included angle between the charging stand 2 and the socket body 1 is actually an included angle between the supporting surface 22 and the socket body 1. In this embodiment, the socket body 1 is integrally arranged in a vertical direction, and the degree of the included angle between the supporting surface 22 and the socket body 1 is 90 °, so that the supporting surface 22 is arranged in a horizontal direction, and the wireless charging and receiving device 10 can be stably placed on the supporting surface 22; in other embodiments, the degree of the included angle may be slightly larger than 90 ° or slightly smaller than 90 °, as long as the effect of stable placement can be achieved.

Referring to fig. 2, specifically, the charging rack 2 is fixed on the upper portion of the socket body 1, so that the wireless charging area 21 is located above the charging rack 2, the plugging area 12 is located below the charging rack 2, the charging rack 2 separates the wireless charging area 21 from the plugging area 12, the space occupation of the wireless charging receiving device 10 placed in the wireless charging area 21 on the plugging area 12 is reduced, the plug-in charging and the wireless charging can be performed simultaneously, and the structure is more concise and compact.

Referring to fig. 2, on the other hand, since the charging rack 2 is fixed to the upper portion of the socket body 1, the wires of the charging rack 2 inserted into the socket body 1 are also concentrated on the upper portion of the socket body 1 and enter the socket body 1, in the wire combing process inside the socket body 1, the wires from the charging rack 2 can be concentrated in the upper space of the socket body 1, the occupation of the lower space of the socket body 1 is reduced, the wire combing of the socket body 1 is facilitated, and the charging rack 2 and the wires connected therewith do not interfere with the lower portion of the socket body 1, the influence of the charging rack 2 on the wire layout of the lower portion of the socket body 1 is reduced, and the socket body 1 is easier to arrange.

Referring to fig. 1, regarding the fixing manner between the socket body 1 and the charging rack 2, in this embodiment, the socket body 1 and the charging rack 2 are integrally formed, and in other embodiments, the fixing manner may also be bolting or clamping, as long as the effect that the socket body 1 and the charging rack 2 can be relatively fixed can be achieved.

Referring to fig. 2, regarding the power supply of the wireless charging transmitting module 4, in this embodiment, a quick charging module 13 for providing electric energy to the wireless charging transmitting module 4 is installed inside the socket body 1, and the wireless charging transmitting module 4 is electrically connected to the quick charging module 13 through an electric wire.

Referring to fig. 1 and 2, regarding the arrangement of the jack interface on the panel 15 of the socket body 1, in the present embodiment, the panel 15 of the socket body 1 is provided with a conventional jack and a dual output interface 14, and the dual output interface 14 is electrically connected to the fast charging module 13. The conventional jacks include two jacks and three jacks, the dual-output interface 14 is also called A1C interface, and has a USB TYPE a interface and a USB TYPE C interface, so that the dual-output interface can be used by matching with more rechargeable devices.

Referring to fig. 1, regarding the selection of the socket body 1, in this embodiment, the socket body 1 is preferably an 86-type socket, and in other embodiments, the socket body 1 may be another fixed socket, which only achieves the effect of being able to be fixed to a fixed object to support the charging rack 2.

Referring to fig. 1 and 2, in order to enable the wireless charging receiving device 10 to be placed on the charging rack 2 more stably, the charging rack 2 is further fixedly provided with a non-slip mat 23, the non-slip mat 23 is made of an elastic material such as a rubber material, the non-slip mat 23 is annular in shape as a whole, and the non-slip mat 23 is embedded and fixed on the supporting surface 22. When the wireless charging receiving device 10 is placed on the charging rack 2, static friction force exists between the anti-slip pad 23 and the wireless charging receiving device 10, and the anti-slip pad 23 can absorb the vibration of the wireless charging receiving device 10 by using the elasticity of the anti-slip pad 23, so that the risk that the wireless charging receiving device 10 is separated from the charging rack 2 under the condition of non-manual action is reduced.

The implementation principle of the first embodiment of the application is as follows: the electrical apparatus can be through pegging graft power plug in the grafting district 12 of socket in order to obtain the electric energy, and wireless receiving equipment 10 that charges can enough provide the function that the plug charges in order to obtain the electric energy through placing in the wireless district 21 that charges of charging frame 2, can support wireless rechargeable again, and the function is more diversified, and is wider to battery charging outfit's application scope. Meanwhile, the plugging area 12 and the wireless charging area 21 are separated by the charging frame 2, so that the space occupation of the wireless charging receiving equipment 10 placed in the wireless charging area 21 on the plugging area 12 is reduced, the plug-in charging and the line charging can be carried out simultaneously, and the convenience is improved.

The second embodiment:

referring to fig. 3 and 4, the present embodiment is different from the first embodiment in that: charging frame 2 rotates with socket ontology 1 and is connected, has turned angle between charging frame 2 and the socket ontology 1, and in turned angle's within range, the upset can take place for socket ontology 1 for charging frame 2.

As shown in fig. 4, ≈ α in the drawing is an angle formed between the charging rack 2 and the socket body.

As shown in fig. 4a, when the angle of ≈ α reaches the maximum, the charging rack 2 corresponds to the socket body 1 being in an open state, and at this time, the charging rack 2 is opened, and the wireless charging service can be provided.

As shown in fig. 4b, when the angle of ≤ α is the minimum, the charging rack 2 is equivalent to the socket body 1 being in the closed state, at this time, the charging rack 2 is closed, the charging rack 2 does not provide the wireless charging service temporarily, and the occupied space in the horizontal direction is reduced, so that the space utilization rate can be improved, and the jack on the socket body 1 is shielded.

Referring to fig. 4, in the present embodiment, the range of the rotation angle between the charging stand 2 and the socket body 1 is set to 0 ° to 90 °. When the charging frame 2 is in an open state, the angle alpha is 90 degrees; when the charging frame 2 is in a closed state, the angle alpha is 0 deg. It is understood that, in the embodiment of the present invention, in order to set the socket body 1 in the vertical direction and in the horizontal direction when the charging rack 2 is in the open state, the range of the rotation angle is set to 0 ° to 90 °, and in other embodiments, the set range of the rotation angle may be adaptively adjusted if influenced by the factors such as the socket body 1 being inclined or the charging rack 2 being unparallel in the upper and lower surfaces.

Referring to fig. 4, in the present embodiment, when the charging rack 2 is in the closed state, the charging rack 2 and the socket body 1 may be parallel to each other and have a space therebetween, and in other embodiments, the charging rack 2 and the socket body 1 may also be attached to each other, so as to achieve an effect of improving a space utilization rate.

Referring to fig. 4 and 5, in the present embodiment, the area of the charging rack 2 matches the area of the panel 15 of the socket body 1, and when the charging rack 2 is in the closed state, each jack in the plugging area 12 of the socket body 1 can be shielded, so that contaminants or children are prevented from directly contacting the jacks, and the durability and safety of the socket body 1 are improved.

Referring to fig. 4, regarding a specific connection manner between the charging stand 2 and the socket body 1, in the present embodiment, a rotation member 5 is provided between one end of the charging stand 2 and an upper portion of the socket body 1, and the charging stand 2 is rotatably connected to the upper portion of the socket body 1 by the rotation member 5.

Referring to fig. 4, the charging stand 2 may change its inclination by rotating, and may switch the open state or the closed state, for example, when wireless charging is required, the charging stand 2 may be rotated in a forward direction, the charging stand 2 may be turned up to the maximum, and the charging stand 2 may be switched to the open state. When wireless charging is temporarily not required, the charging rack 2 can be rotated reversely, the charging rack 2 is turned downwards to the maximum limit, and the charging rack 2 is switched to a closed state.

Referring to fig. 4, in this embodiment, the charging rack 2 can be switched between the open state and the closed state only by turning over, which is more convenient. In addition, as a locking structure is not arranged between the charging frame 2 and the socket body 1, the charging frame 2 and the socket body are not directly locked in a closed state, so that the state switching of the charging frame 2 can be completed more quickly and simply. For example, socket body 1 in this application embodiment can fixed mounting in near the wall department of head of a bed, and when the user lies in the bed, the stick out can easily be dialled and upset charging frame 2, can provide wireless charging function on the charging frame 2, whole use convenient and fast.

Referring to fig. 4, regarding the mounting structure between the charging rack 2 and the socket body 1, in the present embodiment, a mounting table 6 is provided at one end of the socket body 1, a bottom end of the mounting table 6 is integrally formed at an upper portion of the socket body 1, an upper end of the mounting table 6 extends in a horizontal direction, and the charging rack 2 is rotatably connected to one end of the mounting table 6 away from the socket body 1 through a rotating member 5. By utilizing the length space provided by the mounting table 6, when the charging rack 2 is in a closed state, the charging rack 2 can be parallel to or attached to the socket body 1, so that the distance between the charging rack 2 and the socket body 1 is reduced to the maximum extent.

Referring to fig. 5 and 6, an end of the charging rack 2 near a connection between the charging rack 2 and the socket body 1 is concavely provided with a relief groove 24, and the mounting stand 6 is accommodated in the relief groove 24. The two side groove walls of the yielding groove 24 are respectively close to the two sides of the mounting table 6, and the rotating part 5 is arranged between the side wall of the mounting table 6 and the groove wall of the yielding groove 24.

Referring to fig. 5 and 6, in this embodiment, the groove bottom of the abdicating groove 24 is provided with a first threading hole 25 communicated with the inside of the charging rack 2, the mounting table 6 is hollow inside, and one end of the mounting table 6 far away from the socket body 1 is provided with a second threading hole 61 communicated with the first threading hole 25, and the electric wire inside the charging rack 2 can enter the inside of the socket body 1 through the first threading hole 25 and the second threading hole 61. The abdicating groove 24 provides a movable space for the mounting table 6, when the charging rack 2 and the socket body 1 rotate relatively, the mounting table 6 actually rotates in the abdicating groove 24 relative to the charging rack 2, and the distance between the first threading hole 25 and the second threading hole 61 is relatively short, so that the probability that the electric wire between the charging rack 2 and the socket body 1 is broken due to over-rotation is reduced.

Referring to fig. 5 and 6, specifically, the charging rack 2 is further fixedly provided with a shielding piece 26, the shielding piece 26 is located on one side of the avoiding groove 24 close to the supporting surface 22, and the shielding piece 26 passes through a rotation path of the mounting platform 6 relative to the charging rack 2 rotating in the avoiding groove 24. In the present embodiment, the shielding sheet 26 is integrally formed with the charging stand 2.

Referring to fig. 5 and 6, when the charging stand 2 is turned to the open state, the shielding piece 26 is close to the mounting stand 6, and prevents the mounting stand 6 from rotating in the abdicating slot 24 relative to the charging stand 2, so that the rotation range of the mounting stand 6 is limited to be only within the range of the set rotation angle, and the risk of the electric wire between the charging stand 2 and the socket body 1 being damaged by excessive rotation is reduced. In the present embodiment, the upper surface of the mounting stand 6 is disposed to be parallel to a horizontal plane, and the shielding sheet 26 is entirely parallel to the charging stand 2, so as to increase the contact effect between the shielding sheet 26 and the mounting stand 6 in the open state, and reduce the risk that the shielding sheet 26 is separated from the charging stand 2 after long-term use.

Referring to fig. 5 and 6, further, the area of the shielding piece 26 matches the area of the avoiding groove 24, so that the shielding piece 26 can shield the installation platform 6 and the wires between the charging rack 2 and the socket body 1, and can protect the wires multiply.

Referring to fig. 5, in order to improve the stability of wireless charging, in the present embodiment, the rotating member 5 is preferably a damping rotating shaft 51, a fixed end of the damping rotating shaft 51 is inserted and fixed to the mounting platform 6, and a movable end of the damping rotating shaft 51 is fixedly connected to the charging rack 2, so as to realize rotational connection between the charging rack 2 and the mounting platform 6. In the present embodiment, the damping rotation shaft 51 and the mounting base 6 are fixed by bonding, and the damping rotation shaft 51 and the charging stand 2 are fixed by bolting.

Referring to fig. 5, the damping rotating shaft 51 may provide a rotational damping, and when the charging rack 2 is in an open state, the damping rotating shaft 51 provides a supporting force for the charging rack 2 through the rotational damping, so that the charging rack 2 is sufficient to support an object within a preset weight range, the risk of the charging rack 2 turning over by itself is reduced, and the stability of wireless charging is improved. Wherein, the automatic upset that takes place refers to charging frame 2 under the effect of self gravity or the effect of the gravity of the object of the preset weight within range of bearing, and the automatic circumstances that takes place the upset of non-manpower interference.

Referring to fig. 5, in the present embodiment, the number of the damping rotating shafts 51 is 2, and two damping rotating shafts 51 are respectively located at both sides of the mounting stand 6, so that the connection between the charging stand 2 and the socket body 1 is more stable. It should be noted that, in the case of the selected damping spindle 51, in addition to considering whether the rotational damping provided by the damping spindle 51 can support the charging stand 2 more stably, it is also necessary to consider whether the manual force can easily pull the flip charging stand 2, and in this embodiment, the damping spindle 51 is preferably a metal damping spindle.

Referring to fig. 5 and 6, in order to reduce the risk that the charging rack 2 is automatically switched to the closed state under the influence of gravity in the open state, a positioning structure for matching and positioning is further arranged between the charging rack 2 and the socket body 1. Location structure includes mutual joint complex spacing groove 27 and spacing arch 62, and when charging frame 2 was in the open mode, spacing groove 27 and spacing arch 62 joint were fixed a position charging frame 2 at the angle of settlement, and in this embodiment, this angle of settlement is the contained angle maximum value between charging frame 2 and socket ontology 1, is 90 promptly, and spacing groove 27 and spacing arch 62 pass through the joint cooperation, reduce the risk that charging frame 2 took place to overturn by oneself.

Referring to fig. 5 and 6, in the present embodiment, the charging rack 2 is provided with a limiting groove 27, and the socket body 1 is provided with a limiting protrusion 62 for the limiting groove 27 to be clamped. The quantity of spacing arch 62 is 2, and two spacing arch 62 integrated into one piece respectively are in the both sides of mount table 6, and spacing arch 62 is whole to be hemispherical, and spacing arch 62's surface is provided with the arcwall face. Correspondingly, the number of the limiting grooves 27 is also 2, and two limiting grooves 27 are concavely arranged on the two side groove walls of the yielding groove 24. When charging frame 2 switches to the closure state from the open mode, along with the rotation of charging frame 2 itself, can break away from the joint state between spacing groove 27 and the spacing arch 62, spacing arch 62's arcwall face makes spacing arch 62 can break away from the joint state fast, makes the state switching of charging frame 2 more laborsaving.

It can be understood that the limiting grooves 27 and the limiting protrusions 62 are in a one-to-one snap-fit structure, and when the limiting grooves 27 are disposed on the charging rack 2, the limiting protrusions 62 need to be correspondingly disposed on corresponding positions of the socket body 1. In other embodiments, if the limiting groove 27 is disposed on the socket body 1, the limiting protrusion 62 may be correspondingly disposed on the corresponding position of the charging rack 2, and the limiting groove 27 and the limiting protrusion 62 may achieve the positioning effect.

Referring to fig. 5 and 6, in order to facilitate the entrance of the limiting groove 27 into the limiting protrusion 62, the charging rack 2 is further provided with two avoiding grooves 28, the number of the avoiding grooves 28 is 2, the two avoiding grooves 28 are respectively concavely arranged on the two side groove walls of the avoiding groove 24, the avoiding grooves 28 extend in an arc shape around the rotation axis of the charging rack 2, one end of the avoiding groove 28 is communicated with the surface of the charging rack 2 deviating from the wireless charging area 21, and the other end of the avoiding groove 28 points to the limiting groove 27 but is not communicated with the limiting groove 27. When the charging rack 2 is switched from the closed state to the open state, the limiting protrusion 62 can slide in the avoiding groove 28 along with the rotation of the charging rack 2, until the limiting protrusion 62 and the limiting protrusion 62 are in a clamping state.

Referring to fig. 5, in order to facilitate the turning of the charging rack 2 by the human body, a bent portion 29 is disposed at an end of the charging rack 2 away from the connection between the charging rack 2 and the socket body 1, and the bent portion 29 is bent in a direction approaching the wireless charging area 21. When the charging frame 2 is in the open state, the bent portion 29 can prevent an object placed in the wireless charging area 21 from being separated from the wireless charging area 21, and charging stability is improved. When charging frame 2 is in the closed state, bending portion 29 can produce the interval with socket ontology 1 between, and the rotation takes place for charging frame 2 atress of being convenient for, makes things convenient for charging frame 2 to carry out the state switching.

Example three:

referring to fig. 7 and 8, the present embodiment is different from the second embodiment in that: the limiting projection 62 adopts a telescopic structure.

Referring to fig. 7 and 8, in particular, the stopper projection 62 is generally spherical. The two sides of the mounting table 6 are respectively provided with a containing hole 63 for containing the limiting protrusion 62 in a concave manner, and the containing hole 63 extends towards the inside of the mounting table 6 along the horizontal direction. The position-limiting protrusion 62 is slidably coupled in the receiving hole 63, the radius of the receiving hole 63 matches the radius of the position-limiting protrusion 62, and the opening of the receiving hole 63 is narrowed to prevent the position-limiting protrusion 62 from being separated from the inside of the receiving hole 63. The inside of the containing hole 63 is also provided with a clamping elastic piece 64, and the clamping elastic piece 64 and the limiting bulge 62 are sequentially arranged in the containing hole 63 from inside to outside. The clamping elastic member 64 is preferably a spring, one end of the clamping elastic member 64 abuts against the bottom of the accommodating hole 63, the other end abuts against the limiting protrusion 62, and under the elastic force of the clamping elastic member 64, the limiting protrusion 62 partially extends out of the accommodating hole 63.

Referring to fig. 7 and 8, the accommodating hole 63 provides a sliding space for the limiting protrusion 62, the clamping elastic piece 64 provides sliding power for the limiting protrusion 62, when the charging rack 2 is switched between the open state and the closed state, the charging rack 2 has an external force effect on the limiting protrusion 62, under the external force effect, the limiting protrusion 62 can be completely retracted into the accommodating hole 63, so that the limiting block can be rapidly separated from the clamping state or enter the clamping state, and the charging rack 2 is convenient for state switching.

Example four:

referring to fig. 9 and 10, the present embodiment is different from the second embodiment in that: be provided with between charging frame 2 and the socket ontology 1 and reset elastic component 8 and buckle subassembly 9, when charging frame 2 was in the closure state, it is dead through buckle subassembly 9 lock between charging frame 2 and the socket ontology 1, and buckle subassembly 9 has and can drive charging frame 2 and take place the pivoted elastic force in advance, and after buckle subassembly 9 unblock, reset elastic component 8 can promote charging frame 2 and take place the upset, makes charging frame 2 automatic switch to the open mode from the closure state.

Referring to fig. 10, in particular, the return elastic member 8 is preferably a torsion spring, the return elastic member 8 is disposed around the rotation member 5, and both ends of the return elastic member 8 respectively abut against the charging stand 2 and the socket body 1.

Referring to fig. 11, the latch assembly 9 includes a locking plate 91 slidably connected to the socket body 1, a locking elastic member 92 for pushing the locking plate 91, and a latch 93 fixedly disposed on the charging rack 2, wherein a position of the locking plate 91 corresponds to a position of the latch 93, when the charging rack 2 rotates, the latch 93 moves circumferentially around the rotating member 5, and when the charging rack 2 is in a closed state, the latch 93 is in a snap-fit engagement with the locking plate 91.

Referring to fig. 10 and 12, in the present embodiment, the socket body 1 includes a panel 15 and a bottom shell 16 assembled together, the locking plate 91 is slidably connected between the panel 15 and the bottom shell 16, specifically, a mounting groove 151 is formed on a side of the panel 15 close to the bottom shell 16, the locking plate 91 is accommodated and slidably connected in the mounting groove 151, and the bottom shell 16 covers the mounting groove 151, so that the locking plate 91 is difficult to be separated from the mounting groove 151 as a whole. The edge of the panel 15 is opened with an installation opening 152 communicated with the installation groove 151, one end of the locking plate 91 is exposed out of the panel 15 through the installation opening 152, and the end of the locking plate 91 forms a force bearing end for applying force to a human body.

Referring to fig. 10 and 12, the side wall of the locking plate 91 received in one end of the mounting groove 151 is fixedly provided with a sliding block 911, and when the locking plate 91 moves, the sliding block 911 slides in the mounting groove 151, but since the area of the mounting opening 152 is not enough for the sliding block 911 to pass through, the sliding block 911 is restricted in the mounting groove 151, so that the locking plate 91 cannot be completely separated from the mounting opening 152. The locking elastic member 92 is preferably a spring, the locking elastic member 92 is disposed in the mounting groove 151, one end of the locking elastic member 92 abuts against the sliding block 911, and the other end is fixed to an inner wall of the mounting groove 151 on the side away from the mounting opening 152.

Referring to fig. 12, when the locking plate 91 is in a non-manual operation state, the sliding block 911 abuts against the inner wall of the mounting groove 151 on the side close to the mounting opening 152 under the elastic force of the locking elastic member 92; when the locking plate 91 is moved in the direction of entering the mounting groove 151 as a whole, the sliding block 911 moves in synchronization with the locking plate 91, and the locking spring 92 is gradually compressed.

Referring to fig. 12, a portion of the locking plate 91 exposed out of the panel 15 is provided with a locking hole 912 for the lock catch 93 to engage, and the locking hole 912 is a through hole. The surface of the panel 15 is provided with a connection port 153 communicating with the locking hole 912, and the connection port 153 allows the locking hole 912 to be completely exposed out of the panel 15, so as to facilitate the matching contact between the locking hole 912 and the latch 93.

Referring to fig. 13, one end of the latch 93 is bolted to the charging stand 2, and the other end of the latch 93 is provided with a latch block 931 for forming a snap fit with the locking hole 912, and in this embodiment, the latch block 931 is formed by bending an end of the latch 93, and one side of the latch block 931 is formed with an inclined guide surface.

Referring to fig. 13, when the charging rack 2 is switched from the open state to the closed state, the lock catch 93 performs a circular motion, the fastening block 931 gradually approaches the lock plate 91 and finally is fastened to the lock plate 91, and the lock catch 93 and the lock plate 91 are locked. In the above process, the guide surface of the fastening block 931 first passes through the connection port 153 and contacts the sidewall of the locking hole 912, and under the action of the guide surface, the whole locking plate 91 moves in the direction of entering the socket body 1 as the fastening block 931 continues to move, and when the fastening block 931 completely passes through the locking hole 912, the whole locking plate 91 moves in the direction of leaving the socket body 1 under the action of the elastic force of the locking elastic member 92, so that the fastening block 931 forms a snap fit with the locking plate 91.

Referring to fig. 11, the above process is actually the switching of the charging stand 2 from the open state to the closed state, and the user only needs to apply a force to the charging stand 2, so that the charging stand 2 is turned over to complete the process.

Referring to fig. 13, when the charging rack 2 needs to be switched from the closed state to the open state, the user may drag the locking plate 91 to move the locking plate 91 away from the socket body 1 until the locking plate 91 is disengaged from the fastening block 931, and at this time, the lock catch 93 and the locking plate 91 are unlocked, and under the action of the return elastic member 8 (see fig. 10), the lock catch 93 moves circularly and gradually moves away from the locking plate 91, and finally, the charging rack 2 is switched from the closed state to the open state.

Referring to fig. 13, in particular, the force-bearing end of the locking plate 91 is bent toward the insertion region 12. The locking plate 91 is disposed at the lower portion of the socket body 1, and the lock 93 is disposed at an end of the charging rack 2 away from the rotating member 5. When charging frame 2 need switch to the open mode from the closed condition, the user dials locking plate 91 downwards, can unblock hasp 93, makes charging frame 2 automatic upset.

Referring to fig. 10, in the present embodiment, the rotation member 5 is a damping rotation shaft 51, and the charging stand 2 and the socket body 1 are rotatably connected by the damping rotation shaft 51, and the damping rotation shaft 51 is preferably a hydraulic type damping rotation shaft. When the charging frame 2 automatically rotates under the action of the reset elastic piece 8, the rotating speed of the charging frame 2 can be reduced by the rotating damping provided by the damping rotating shaft 51, the collision strength between the charging frame 2 and the socket body 1 is reduced, and the service life of the connecting structure between the charging frame 2 and the socket body 1 is prolonged.

Example five:

referring to fig. 14, the present embodiment is different from the second embodiment in that: the charging frame 2 and the socket body 1 are connected in a plug-in connection mode.

Referring to fig. 14, specifically, a connection plug 7 is fixedly disposed at one end of the charging rack 2 close to the socket body 1, and the connection plug 7 is a power line plug capable of realizing electrical connection. The socket body 1 is provided with a first jack 17 and a second jack 18, wherein the first jack 17 can realize an electrically connected power line socket, the first jack 17 and the second jack 18 are both used for the connection plug 7 to be plugged, and an included angle is formed between the plugging direction of the first jack 17 and the plugging direction of the second jack 18.

Referring to fig. 14, in the present embodiment, the plugging direction of the first outlet 17 is set in a vertical direction, and the plugging direction of the second outlet 18 is set in a horizontal direction. When the connecting plug 7 is plugged with the first jack 17, the included angle between the charging rack 2 and the socket body 1 is 90 degrees, and at the moment, the charging rack 2 is in an open state; when the connecting plug 7 is plugged into the second jack 18, the included angle between the charging rack 2 and the socket body 1 is 0 degree, and the charging rack 2 is in a closed state at the moment. The charging stand 2 can be switched to the open state or the closed state by plugging the connection plug 7 into the first outlet 17 or the second outlet 18.

Referring to fig. 14, the charging rack 2 can change the inclination of itself by being plugged in different positions, the switching mode is simpler and quicker, and the charging rack 2 and the socket body 1 can be separated, so that a user can repair or clean a single component conveniently.

Referring to fig. 14, in some embodiments, the charging rack 2 and the socket body 1 may further adopt a magnetic attraction structure or a snap-fit structure, which is separable, so as to enhance the connection stability between the charging rack 2 and the socket body 1.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: equivalent changes in structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (13)

1. Multipurpose charging socket, its characterized in that includes:

a socket body (1) provided with a plug-in area (12);

the socket comprises a charging rack (2), a wireless charging transmitting module (4) used for outputting electric energy to a wireless charging receiving device (10) is arranged on the charging rack (2), an included angle is formed between the charging rack (2) and a socket body (1), and a wireless charging area (21) for placing the wireless charging receiving device (10) is arranged on the charging rack (2); the charging frame (2) is connected to the socket body (1).

2. The multipurpose charging receptacle according to claim 1, wherein: the charging rack (2) is connected to the upper portion of the socket body (1), and the wireless charging area (21) is arranged above the charging rack (2).

3. The multipurpose charging receptacle according to claim 2, wherein: the charging frame (2) is rotatably connected with the socket body (1), and a changeable rotating angle is formed between the charging frame (2) and the socket body (1).

4. The multipurpose charging receptacle according to claim 2, wherein: a positioning structure matched and positioned is arranged between the charging frame (2) and the socket body (1).

5. The multipurpose charging receptacle according to claim 4, wherein: the positioning structure is specifically as follows: a limiting groove (27) or a limiting bulge (62) is arranged on the charging frame (2), a limiting bulge (62) in clamping fit with the limiting groove (27) is arranged on the socket body (1), or the limiting groove (27) in clamping fit with the limiting bulge (62) is arranged on the socket body (1);

the charging rack (2) is positioned at a set angle by the limiting protrusion (62) in a clamping connection mode with the limiting groove (27).

6. The multipurpose charging receptacle according to claim 5, wherein: socket body (1) or be provided with holding hole (63) on charging frame (2), elastic component (64) has set gradually from inside to outside in holding hole (63) spacing arch (62), spacing arch (62) are in elastic component (64) effect part stretches out holding hole (63), spacing arch (62) can the retraction under the exogenic action in holding hole (63).

7. The multipurpose charging receptacle according to claim 1, wherein: one end, far away from the connection position between the charging frame (2) and the socket body (1), of the charging frame (2) is provided with a bending portion (29), and the bending portion (29) bends towards the direction close to the wireless charging area (21).

8. The multipurpose charging receptacle according to claim 1, wherein: one end of the socket body (1) is provided with a mounting table (6), and the charging frame (2) is rotatably connected to the mounting table (6).

9. The multipurpose charging receptacle of claim 8, wherein: charging frame (2) are provided with and hold abdicating groove (24) of mount table (6), one side of abdicating groove (24) is provided with shielding piece (26), shielding piece (26) restriction the rotation range of mount table (6).

10. The multipurpose charging receptacle according to claim 4, wherein: a buckle component (9) and a reset elastic piece (8) are arranged between the charging rack (2) and the socket body (1);

the buckle assembly (9) is used for limiting the relative rotation between the charging frame (2) and the socket body (1);

the reset elastic piece (8) has pre-elastic force for driving the charging rack (2) to rotate, so that the charging rack (2) is opened corresponding to the socket body (1).

11. The multipurpose charging receptacle according to claim 3, wherein: the charging frame (2) is rotatably connected with the socket body (1) through a damping rotating shaft (51).

12. The multipurpose charging receptacle according to claim 2, wherein: the charging rack (2) is provided with a connecting plug (7), and the socket body (1) is provided with a first socket (17) for the connecting plug (7) to be plugged; when the connecting plug (7) is plugged with the first jack (17), an included angle is formed between the charging rack (2) and the socket body (1);

the socket body (1) is also provided with a second socket (18) for the connection plug (7) to be plugged, and an included angle is formed between the plugging direction of the first socket (17) and the plugging direction of the second socket (18); when the connecting plug (7) is plugged with the second socket (18), the charging rack (2) is attached to or parallel to the socket body (1).

13. The multipurpose charging receptacle according to claim 1, wherein: the socket body (1) is provided with a quick charging module (13), and the wireless charging transmitting module (4) is electrically connected with the quick charging module (13) through a wire; the socket body (1) is provided with a double-output interface (14) which is electrically connected with the quick-charging module (13).

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