CN215497238U - Networking smart jack - Google Patents

Abstract

The utility model discloses a networking intelligent socket which at least comprises an upper cover, a lower cover and a main board, wherein the upper cover and the lower cover are connected with each other to define a hollow cavity, the main board is arranged in the hollow cavity, the networking intelligent socket is characterized in that the upper cover is in threaded connection with at least two sliding block pressing plates, a sliding block is arranged between the upper cover and the sliding block pressing plates in a sliding manner, the sliding block is connected to the inner wall of the upper cover through a spring, a jack is arranged on the upper cover, the sliding block is provided with an inclined plane, the inclined plane is not vertical to the extending direction of the jack, and when the inclined plane is acted by an external force, the sliding block can move in a plane vertical to the extending direction of the jack, so that the spring can be compressed. In this application, the spring can exert the extrusion force with the electrical apparatus plug, and then strengthens its reliability of being connected with the socket.

Description

Networking smart jack

Technical Field

The utility model relates to the technical field of networking intelligent sockets, in particular to a networking intelligent socket.

Background

In the use process of the daily electric appliance, the socket device is not needed; moreover, with the continuous development of economy, new requirements are gradually made on the quality of life, and along with the emergence of intelligent electric appliances, intelligent requirements are correspondingly made on sockets matched with the intelligent electric appliances. The existing socket is unreliable in connection with the socket and is easy to fall off, so that the networking intelligent socket capable of overcoming the defects is provided.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provides a networking intelligent socket.

The purpose of the utility model is realized by the following technical scheme: the utility model provides a networking smart jack, includes upper cover, lower cover and mainboard at least, the upper cover with the lower cover is connected each other in order to inject the cavity die cavity, the mainboard set up in the cavity die cavity, its characterized in that, threaded connection has two at least slider clamp plates on the upper cover, the upper cover with it is provided with the slider to slide between the slider clamp plate, and the slider is connected to the inner wall of upper cover through the spring, set up the jack on the upper cover, the slider has the inclined plane of slope form, the inclined plane is not perpendicular with the extending direction of jack when the inclined plane receives external force, the slider can remove in the plane perpendicular with the extending direction of jack, makes the spring can be compressed.

Preferably, the upper cover can be concave to limit the containing cavity, a mounting groove is formed in the inner wall of the containing cavity, the hollow cavity is communicated with the containing cavity through the mounting groove, and a ground wire load elastic sheet is arranged in the mounting groove in a nested mode.

Preferably, the mainboard is provided with a relay, the lower cover is concave, and when the mainboard abuts against the lower cover for contact, the relay can be nested in the lower cover.

Preferably, the lower cover is provided with a ground wire input elastic sheet which can be connected to the relay.

Preferably, the upper cover is provided with a second fixing column, the ground wire load elastic sheet can be connected to the second fixing column in a threaded manner, and the sliding block can be located between the upper cover and the ground wire load elastic sheet.

Preferably, the main board is provided with a zero line spring plate and a live line spring plate.

Preferably, the lower cover is provided with a first plug, a first elastic sheet, a second plug and a second elastic sheet, the first plug is connected with the mainboard through the first elastic sheet, and the second plug is connected with the mainboard through the second elastic sheet.

Preferably, a first fixing hole and a second fixing hole are formed in the main board, the zero line elastic piece is arranged in the first fixing hole, and the live line elastic piece is arranged in the second fixing hole.

Preferably, the first fixing hole and the second fixing hole are both alignable with the insertion hole.

Preferably, the ground wire input elastic sheet can penetrate through the lower cover to be connected to the relay.

The utility model has the following advantages:

(1) the most unable remote control of tradition networking smart jack uses, and this application can realize remote control through the wireless connection gateway.

(2) Most no overload outage and self-resuming of traditional networking smart jack are provided with the relay in this application, and then can realize overload protection.

(3) The top of slider can cover the protection through the slider clamp plate, and through the sliding closure clamp plate, one can provide the protection of covering for the slider, and the two can provide the direction for the removal of slider, make it can remove in the horizontal direction.

(4) In this application, the spring can exert the extrusion force with the electrical apparatus plug, and then strengthens its reliability of being connected with the socket.

Drawings

FIG. 1 is an exploded schematic view of a preferred networked smart outlet of the present invention;

FIG. 2 is a schematic structural view of a preferred upper cover of the present invention;

FIG. 3 is a schematic structural view of a preferred lower cover of the present invention;

FIG. 4 is an assembled view of a preferred slider of the present invention;

fig. 5 is an assembly view of a preferred ground input spring of the present invention.

In the figure, 1-an upper cover, 2-a spring, 3-a sliding block, 4-a sliding block pressing plate, 5-a ground wire load elastic sheet, 6-a main board, 7-a zero-fire wire elastic sheet, 8-a lower cover, 9-a ground wire input elastic sheet, 10-a hollow cavity, 11-a first fixed column, 12-an accommodating cavity, 13-an installation groove, 14-a second fixed column, 15-a jack, 16-a first fixed hole, 17-a second fixed hole, 7 a-a zero-line elastic sheet, 7 b-a fire wire elastic sheet, 18-a first plug, 19-a first elastic sheet, 20-a relay, 21-a second plug, 22-a second elastic sheet and 23-an inclined plane.

Detailed Description

The utility model will be further described with reference to the accompanying drawings, without limiting the scope of the utility model to the following:

as shown in fig. 1 to 5, the present application provides a networking smart socket, which at least comprises an upper cover 1, a main board 6 and a lower cover 8. The lower cover 8 and the upper cover 1 are connected and fixed through a threaded connection mode to form a hollow cavity 10. For example, the inside of the upper cover 1 is provided with at least one first fixing column 11 with a screw hole. The lower cover 8 is provided with at least two fixing holes. When the fixing hole is aligned with the first fixing column, the screw is inserted into the screw hole and the fixing hole simultaneously to realize the threaded connection of the upper cover 1 and the lower cover 8. The main plate 6 is disposed in the hollow cavity 10.

Preferably, the upper cover 1 is concave so as to define a housing cavity 12. The inner wall of the receiving cavity 12 is provided with a mounting groove 13. At least one second fixing column 14 with a screw hole is arranged on the upper cover 1. The installation groove 13 is provided with a ground wire loading elastic sheet 5 in a nested mode. The screw hole is formed in the ground wire load elastic sheet 5, and when the screw hole is aligned with the second fixing column, the connection and fixation of the ground wire load elastic sheet 5 and the upper cover 1 can be achieved by simultaneously inserting screws into the screw hole and the second fixing column.

Preferably, the upper cover 1 is provided with a slider 3 capable of moving in the radial direction of the receiving cavity 12. The upper part of the sliding block 3 can be covered and protected by a sliding block pressing plate 4, one part can provide covering and protecting for the sliding block 3 by a sliding cover pressing plate 4, and the two parts can provide guiding for the movement of the sliding block 3, so that the sliding block can move in the horizontal direction. The slider 3 can be connected to the inner wall of the hollow cavity 10 by means of a spring 2, the spring 2 being able to be compressed when the slider 3 is moved by an external force. When the external force disappears, the slider 3 can move again to return to its original position under the action of the spring 2. The existing socket is unreliable in connection between the plug and the socket of the electric appliance and is easy to fall off. In this application, spring 2 can exert the extrusion force with the electrical apparatus plug, and then strengthens its reliability of being connected with the socket.

Preferably, at least two insertion holes 15 are provided on the upper cover 1. The receiving cavity 12 can communicate with the outside through the insertion hole 15. When the slider 3 is in the initial state, the slider 3 can close the insertion hole 15. The bottom of the slider 3 has an inclined slope 13. When a plug pin is inserted into the jack 15, the plug pin can abut against and contact with the inclined surface, so that the sliding block 3 is pushed to move, and finally the spring 2 is compressed.

Preferably, the main plate 6 is provided with a first fixing hole 16 and a second fixing hole 17 aligned with the insertion hole 15. The zero line and live line elastic sheet 7 at least comprises a zero line elastic sheet 7a and a live line elastic sheet 7 b. The neutral spring 7a may be disposed in the first fixing hole 16. The live spring 7b may be disposed in the second fixing hole 17.

Preferably, the lower cover 8 is provided with a ground wire input elastic sheet 9. The lower cover 8 is provided with a first plug 18, a first elastic sheet 19, a second plug 21 and a second elastic sheet 22. The main board 6 is provided with a relay 20. The first plug 18 is connected with the first elastic sheet 19.

The first elastic sheet 19 is connected with the main board 6. The second plug 21 is connected with the second elastic sheet 22, and the second elastic sheet 22 is connected with the main board 6. The ground wire input elastic sheet 9 is connected with the relay 20. The type and specification of the relay can be configured according to actual requirements, and then the maximum current allowed by the main board 6 can be controlled. When the current overload occurs, the relay contact can be automatically separated to disconnect the current, so that the purpose of protecting the circuit is achieved.

The working principle of this application does: after the lower cover 8 is inserted into the special networking intelligent socket, the first plug 18 and the second plug 21 can be respectively connected with the zero line and the live line of the networking intelligent socket. The ground wire of the networking intelligent socket is connected with the ground wire input elastic sheet 9. At this point, the motherboard 6 will be in a powered-up state. Then plugs of other electrical appliances can be inserted into the upper cover 1, and the ground wire load spring 5 is connected with the ground wire of the electrical appliance to provide ground protection. The zero line and the live line of the electric appliance plug are respectively connected with the zero line elastic sheet 7a and the live line elastic sheet 7b to provide commercial power for the electric appliance. Mainboard 6 provides wireless function simultaneously, and connecting gateway can be real-time on gateway APP, remote control and set up the work of intelligent networking smart jack.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the utility model. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A networking smart jack at least comprises an upper cover (1), a lower cover (8) and a main board (6), wherein the upper cover (1) and the lower cover (8) are connected with each other to define a hollow cavity (10), the main board (6) is arranged in the hollow cavity (10), the networking smart jack is characterized in that at least two sliding block pressing plates (4) are in threaded connection with the upper cover (1), a sliding block (3) is arranged between the upper cover (1) and the sliding block pressing plates (4) in a sliding mode, the sliding block (3) is connected to the inner wall of the upper cover (1) through a spring (2), a jack (15) is arranged on the upper cover (1), the sliding block (3) is provided with an inclined slope (23) which is not perpendicular to the extending direction of the jack (15), and when the slope is acted by an external force, the sliding block (3) can move in a plane perpendicular to the extending direction of the jack (15), so that the spring (2) is compressed.

2. The networking smart jack of claim 1, wherein the upper cover (1) is concave to define a containing cavity (12), a mounting groove (13) is formed in the inner wall of the containing cavity (12), the hollow cavity (10) is communicated with the containing cavity (12) through the mounting groove (13), and a ground wire load spring (5) is nested in the mounting groove (13).

3. A networked smart socket according to claim 2, wherein a relay (20) is provided on the main board (6), the lower cover (8) is concave, and the relay (20) can be nested in the lower cover (8) when the main board (6) and the lower cover (8) are in abutting contact.

4. A networked smart socket according to claim 3, wherein a ground input dome (9) is provided on the lower cover (8), the ground input dome (9) being connectable to the relay (20).

5. A networked smart jack according to claim 4, wherein a second fixing post (14) is provided on the upper cover (1), the ground load spring (5) being threadably connected to the second fixing post (14), wherein the slider (3) is positionable between the upper cover (1) and the ground load spring (5).

6. A networked smart socket according to claim 5, wherein a neutral spring (7a) and a live spring (7b) are provided on the motherboard (6).

7. The networking smart jack of claim 6, wherein the lower cover (8) is provided with a first plug (18), a first elastic sheet (19), a second plug (21) and a second elastic sheet (22), the first plug (18) is connected with the motherboard (6) through the first elastic sheet (19), and the second plug (21) is connected with the motherboard (6) through the second elastic sheet (22).

8. A networked smart socket according to claim 7, wherein a first fixing hole (16) and a second fixing hole (17) are provided on the main board (6), the neutral wire spring (7a) is provided in the first fixing hole (16), and the live wire spring (7b) is provided in the second fixing hole (17).

9. A networked smart socket according to claim 8, wherein the first fixing hole (16) and the second fixing hole (17) are each alignable with the jack (15).

10. A networked smart socket according to claim 9, wherein the ground input dome (9) is extendable through the lower cover (8) to connect to the relay (20).

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