Anti-mis-touch row plug

Abstract

The embodiment of the present application provides a mistaken touch prevention row plug, which comprises a shell assembly, a socket cover and a protection piece. The shell assembly has a containing cavity and an opening communicating with the containing cavity. The socket cover is movably arranged in the containing cavity, and the socket cover has a socket for inserting a plug. The protection piece is movably arranged in the containing cavity, and has a first state of shielding the socket and a second state of opening the socket. The mistaken touch prevention row plug has high safety according to the embodiment of the present application.

Description

Technical Field

[0001] This application relates to the field of power strip technology, and in particular to a power strip designed to prevent accidental activation. Background Technology

[0002] With the widespread use of electronic products, power strips, as commonly used power connection devices, have become a major concern regarding safety and space occupation. Current power strip technologies often feature significant thickness, resulting in substantial space consumption. Furthermore, exposed sockets pose a potential safety hazard, as children may accidentally touch them and experience electric shock. Utility Model Content

[0003] In view of this, the main objective of the embodiments of this application is to provide a power strip with higher security to prevent accidental touches.

[0004] To achieve the above objectives, the technical solution of this application embodiment is implemented as follows:

[0005] This application provides a power strip that prevents accidental touches, including:

[0006] A housing assembly having a receiving cavity and an opening communicating with the receiving cavity;

[0007] A socket cover, movably disposed within the receiving cavity, the socket cover having a socket hole for inserting a plug;

[0008] A protective component is movably disposed within the receiving cavity, having a first state of blocking the socket and a second state of opening the socket.

[0009] In one embodiment, the socket cover is configured to, in response to the plug insertion operation, the protective member lifts the socket cover to extend from the opening, driving the protective member to switch from a first state to a second state; and / or,

[0010] The socket cover is configured to retract into the receiving cavity in response to the plug removal operation, and trigger the protective member to return to the first state.

[0011] In one embodiment, at least a portion of the protective member is located below the socket along the depth direction of the socket, the protective member abuts against the socket cover, and the protective member is configured such that when the plug is inserted, the plug pushes open the protective member, and the protective member drives the socket cover to extend out of the housing assembly from the opening.

[0012] In one embodiment, during the insertion of the plug, the plug causes the protective member to lift the socket cover, and the lifting height of the socket cover increases with the insertion depth of the plug. When the plug is fully inserted, the socket cover is lifted to its maximum height; and / or,

[0013] During the process of removing the plug, the socket cover retracts towards the side closer to the receiving cavity. The amount of retraction of the socket cover increases as the insertion depth of the plug decreases, and the amount of retraction of the socket cover is the greatest when the plug is completely removed.

[0014] In one embodiment, the protective member includes a support portion and a shielding portion connected together. Along the depth direction of the socket, at least a portion of the shielding portion is located below the socket. A portion of the socket cover protrudes toward one side of the receiving cavity to form a first abutment portion. The shielding portion is movable to allow the support portion to abut against the first abutment portion, thereby lifting the socket cover and opening the socket.

[0015] In one embodiment, when the protective member is in the first state, the support portion extends along the depth direction of the insertion hole, and the shielding portion extends along a first direction, which is perpendicular to the depth direction of the insertion hole.

[0016] In one embodiment, the housing assembly further has a connection hole, and a portion of the shielding portion protrudes to form a rotating shaft, the rotating shaft being located within the connection hole; and / or,

[0017] The protective member is recessed in a portion near the socket cover to form a receiving groove. When the protective member is in the first state, at least a portion of the first abutment portion is located within the receiving groove.

[0018] In one embodiment, the anti-accidental contact power strip further includes an elastic element that extends along the depth direction of the socket, with one end of the elastic element abutting against the housing assembly and the other end abutting against the socket cover.

[0019] In one embodiment, a portion of the housing assembly is recessed to form a first groove, and a portion of the socket cover is recessed to form a second groove. The second groove is located on the side of the first groove away from the opening and is disposed opposite to it. A portion of the elastic member is located in the first groove, and another portion of the elastic member is located in the second groove. The opposite ends of the elastic member abut against the groove wall of the first groove and the groove wall of the second groove, respectively.

[0020] In one embodiment, a portion of the groove wall on the side of the first groove away from the second groove protrudes toward the side closer to the second groove to form a limiting portion, the limiting portion passing through the elastic member.

[0021] This application provides an anti-accidental contact power strip, including a housing assembly, a socket cover, and a protective member. The housing assembly has a receiving cavity and an opening communicating with the receiving cavity. The socket cover is movably disposed within the receiving cavity and has a socket hole for plug insertion. The protective member is movably disposed within the receiving cavity and has a first state of blocking the socket hole and a second state of opening the socket hole. Thus, by providing the protective member, when the anti-accidental contact power strip is not in use, the protective member is in the first state to block the socket hole, reducing the risk of electric shock and improving safety. Attached Figure Description

[0022] Figure 1 This is a schematic diagram of the anti-accidental touch power strip according to an embodiment of this application;

[0023] Figure 2 for Figure 1 Exploded view of a power strip designed to prevent accidental power-on misuse;

[0024] Figure 3 for Figure 2 A partial structural diagram of a power strip designed to prevent accidental touches;

[0025] Figure 4 for Figure 3 Exploded view of some structures of the anti-accidental touch power strip;

[0026] Figure 5 for Figure 4 Schematic diagram of the structure at point A;

[0027] Figure 6 for Figure 3 A partial structural diagram of a power strip designed to prevent accidental touches;

[0028] Figure 7 for Figure 6 A structural diagram from another perspective;

[0029] Figure 8 This is a schematic diagram of the structure of a protective component according to another embodiment of this application;

[0030] Figure 9 This is a cross-sectional view of an anti-accidental touch power strip according to another embodiment of this application. The left side of the figure shows a structural schematic diagram of the protective member in the second state, and the right side of the figure shows a structural schematic diagram of the protective member in the first state.

[0031] Figure 10 This is a cross-sectional view of an anti-accidental contact power strip according to another embodiment of this application. The left side of the figure shows a structural schematic diagram of the protective member in the second state, and the right side of the figure shows a schematic diagram of the protective member opening when the plug is inserted into the socket, and the protective member lifting the socket cover by rotating.

[0032] Explanation of reference numerals in the attached figures

[0033] 10. Housing assembly; 11. Upper housing; 11a. Opening; 12. Lower housing; 13. Mounting base; 13a. Connecting hole; 13b. First groove; 13c. Limiting groove; 14. Limiting part; 20. Socket cover; 20a. Socket hole; 20b. Second groove; 21. First abutting part; 22. Guide member; 30. Protective member; 30a. Receiving groove; 31. Support part; 32. Shielding part; 321. Rotating shaft; 33. Abutting end; 40. Elastic member; 50. Conductive sheet. Detailed Implementation

[0034] To make the objectives, technical solutions, and advantages of the embodiments of this application clearer, the technical solutions of the embodiments of this application will be clearly described below with reference to the accompanying drawings. The following embodiments are only used to more clearly illustrate the technical solutions of this application, and are therefore only examples, and should not be used to limit the scope of protection of this application. All other embodiments obtained by those skilled in the art based on the embodiments of this application without creative effort are within the scope of protection of this application.

[0035] In this document, the term "embodiment" means that a particular feature, structure, or characteristic described in connection with an embodiment may be included in at least one embodiment of this application. The appearance of this phrase in various places throughout the specification does not necessarily refer to the same embodiment, nor is it a separate or alternative embodiment mutually exclusive with other embodiments. It will be explicitly and implicitly understood by those skilled in the art that the embodiments described herein can be combined with other embodiments.

[0036] In the description of the embodiments of this application, unless otherwise expressly specified and limited, technical terms such as "installation," "connection," "joining," and "fixing" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components. Those skilled in the art can understand the specific meaning of the above terms in the embodiments of this application according to the specific circumstances.

[0037] In this application, the orientation or positional relationship between "the depth direction of the socket" and "the first direction" is based on the appendix. Figure 4 The orientation or positional relationship shown is for illustrative purposes only and is not intended to indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, it should not be construed as a limitation of this application.

[0038] One embodiment of this application provides a power strip that prevents accidental touches. Please refer to [link / reference]. Figure 1 , Figure 2, Figure 3 , Figure 4 , Figure 9 and Figure 10 The anti-accidental contact power strip includes a housing assembly 10, a socket cover 20, and a protective element 30.

[0039] The housing assembly 10 has a receiving cavity and an opening 11a communicating with the receiving cavity.

[0040] The socket cover 20 is movably disposed within the receiving cavity, and the socket cover 20 has a socket hole 20a for inserting a plug.

[0041] The protective component 30 is movably disposed within the receiving cavity, having a first state of blocking the socket 20a and a second state of opening the socket 20a.

[0042] Specifically, the socket cover 20 refers to a component having a socket 20a, being movably disposed within a receiving cavity, and being able to rise or fall relative to the opening 11a.

[0043] It should be noted that the anti-accidental contact power strip has an initial state when the plug is not inserted and an operating state after the plug is inserted. When the anti-accidental contact power strip is in the initial state, the protective component 30 is in the first state. When the anti-accidental contact power strip is in the operating state, the protective component 30 is in the second state.

[0044] The way the socket cover 20 is raised is not limited.

[0045] For example, please refer to Figure 9 The socket cover 20 is configured to respond to a plug insertion operation by having the protective member 30 lift the socket cover 20 out of the opening 11a, thus switching the protective member 30 from a first state to a second state. Therefore, when the plug is inserted, by driving the protective member 30 to lift the socket cover 20, the socket cover 20 can shield the plug after insertion, thereby reducing the risk of electric shock and improving safety.

[0046] The movement of the protective component 30 within the receiving cavity is not limited.

[0047] For example, the protective element 30 rotates within the receiving cavity to switch between a first state and a second state.

[0048] For example, the protective component 30 can move within the receiving cavity to switch between a first state and a second state.

[0049] The anti-accidental contact power strip of this application embodiment includes a housing assembly 10, a socket cover 20, and a protective member 30. The housing assembly 10 has a receiving cavity and an opening 11a communicating with the receiving cavity. The socket cover 20 is movably disposed within the receiving cavity and has a socket hole 20a for inserting a plug. The protective member 30 is movably disposed within the receiving cavity and has a first state that blocks the socket hole 20a and a second state that opens the socket hole 20a. Thus, by providing the protective member 30, when the anti-accidental contact power strip is not in use, the protective member 30 is in the first state to block the socket hole 20a, reducing the risk of electric shock and improving safety.

[0050] In one embodiment, please refer to Figure 10 The socket cover 20 is configured to retract into the receiving cavity in response to a plug removal operation, triggering the protective element 30 to return to its first state. Thus, after the plug is removed, the socket cover 20 retracts into the receiving cavity, reducing the size of the anti-accidental contact power strip and consequently reducing the space it occupies.

[0051] Specifically, the way the socket cover 20 retracts is not limited.

[0052] For example, the anti-accidental contact power strip also includes a resilient element 40, which extends along the depth direction of the socket 20a. One end of the resilient element 40 abuts against the housing assembly 10, and the other end abuts against the socket cover 20. Thus, when the plug is unplugged, the socket cover 20 automatically falls back relative to the opening 11a under the elastic force of the resilient element 40, thereby improving the convenience of using the anti-accidental contact power strip. Furthermore, the falling back of the socket cover 20 causes the protective element 30 to return to its original position below the socket 20a to block the socket 20a, thereby further improving the safety of using the anti-accidental contact power strip.

[0053] Specifically, the elastic element 40 refers to a component that can deform under stress, return to its original shape and generate elastic force after the external force is removed.

[0054] The structure of the elastic element 40 is not limited.

[0055] For example, elastic element 40 is a spring.

[0056] It should be noted that one end of the elastic element 40 abuts against the housing assembly 10, and the other end abuts against the socket cover 20. When the plug is inserted into the anti-accidental contact power strip through the socket 20a, the protective element 30 causes the socket cover 20 to rise relative to the opening 11a. At this time, the elastic element 40 is compressed, generating elastic potential energy. When the plug is fully inserted, the plug abuts against the protective element 30 to prevent the protective element 30 from moving under the elastic force of the elastic element 40. When the plug is pulled out, the external force on the protective element 30 disappears, and the elastic element 40 releases its elastic potential energy according to its own property of restoring its original shape, so as to cause the socket cover 20 to retract relative to the opening 11a, thereby causing the protective element 30 to return to its first state to block the socket 20a.

[0057] In one embodiment, please refer to Figure 9 and Figure 10 The socket cover 20 is configured to respond to a plug insertion operation by having the protective member 30 lift the socket cover 20 out of the opening 11a, driving the protective member 30 to switch from a first state to a second state. The socket cover 20 is also configured to respond to a plug removal operation by retracting the socket cover 20 into the receiving cavity, triggering the protective member 30 to return to the first state. Thus, on the one hand, when the plug is inserted, driving the protective member 30 to lift the socket cover 20 allows the socket cover 20 to shield the plug after insertion, reducing the risk of electric shock and improving safety. On the other hand, after the plug is removed, the socket cover 20 retracts into the receiving cavity, reducing the size of the anti-accidental contact power strip, thereby reducing its space occupation and improving ease of use.

[0058] In one embodiment, please refer to Figure 4 and Figure 9 Along the depth direction of the socket 20a, at least a portion of the protective member 30 is located below the socket 20a. The protective member 30 abuts against the socket cover 20. The protective member 30 is configured such that when the plug is inserted, the plug pushes open the protective member 30, and the protective member 30 drives the socket cover 20 to extend from the opening 11a out of the housing assembly 10.

[0059] Specifically, the depth direction of the socket 20a refers to the direction in which the socket cover 20 rises or falls relative to the opening 11a.

[0060] During the process of inserting the plug through the socket 20a, i.e., during the transition of the anti-accidental contact power strip from its initial state to its working state, since a portion of the protective member 30 is located below the socket 20a, the plug first contacts the protective member 30, and the protective member 30 moves under the pressure of the plug. During the movement of the protective member 30, on the one hand, a portion of the protective member 30 abuts against the socket cover 20 to lift the socket cover 20, causing the socket cover 20 to rise relative to the opening 11a; on the other hand, the protective member 30 opens the area of ​​the socket 20a through its own movement, allowing the plug to be smoothly inserted into the socket 20a for power supply. Once the plug is fully inserted, the protective member 30 switches from the first state to the second state.

[0061] During the process of unplugging, the socket cover 20 slowly falls back, while the protective component 30 switches from the second state to the first state to block the socket 20a.

[0062] In one embodiment, please refer to Figure 9 During the insertion of the plug, the plug drives the protective component 30 to lift the socket cover 20. The lifting height of the socket cover 20 increases with the depth of plug insertion. When the plug is fully inserted, the socket cover 20 is lifted to its maximum height.

[0063] Specifically, during the insertion of the plug into the anti-accidental contact power strip, the tip of the plug first contacts the protective member 30 and applies a pushing force. As the insertion depth gradually increases, the protective member 30 moves under the action of the pushing force. Since the protective member 30 and the socket cover 20 are linked, the protective member 30 transmits the pushing force of the plug to the socket cover 20 during its movement, thereby lifting the socket cover 20. As the plug continues to go deeper, the range of motion of the protective member 30 increases, causing the socket cover 20 to rise continuously. When the plug is fully inserted, the socket cover 20 rises to its maximum height.

[0064] It should be noted that the insertion depth of the plug and the lifting height of the socket cover 20 can vary linearly. Of course, they can also vary non-linearly.

[0065] In one embodiment, please refer to Figure 10 During the process of unplugging the plug, the socket cover 20 retracts towards the side closer to the receiving cavity. The amount of retraction of the socket cover 20 increases as the insertion depth of the plug decreases. When the plug is completely unplugged, the amount of retraction of the socket cover 20 is the largest.

[0066] Specifically, during the unplugging process, the plug moves in the opposite direction along the insertion path, and its length within the receiving cavity gradually decreases. As the plug moves outward, the supporting force of the plug on the protective member 30 gradually decreases, and the protective member 30 slowly switches from the second state to the first state. At this time, the socket cover 20 also retracts towards the side closer to the receiving cavity. The greater the depth of plug extraction (i.e., the smaller the length within the receiving cavity), the greater the return amount of the protective member 30, and the greater the retraction amount of the socket cover 20. When the plug is completely unplugged from the anti-accidental contact power strip, the protective member 30 returns to the first state, and the retraction amount of the socket cover 20 reaches its maximum value, falling back into the receiving cavity.

[0067] In one embodiment, please refer to Figure 9 and Figure 10 During plug insertion, the plug drives the protective component 30 to lift the socket cover 20. The lifting height of the socket cover 20 increases with the insertion depth of the plug, reaching its maximum height when the plug is fully inserted. During plug removal, the socket cover 20 retracts towards the receiving cavity. The retraction amount of the socket cover 20 increases with the decreasing insertion depth of the plug, reaching its maximum retraction amount when the plug is fully removed. Therefore, on the one hand, when the plug is inserted into the anti-accidental contact power strip, the socket cover 20 rises to its maximum height, effectively shielding the plug and reducing the risk of electric shock, thus improving safety. On the other hand, during plug removal, the socket cover 20 retracts into the receiving cavity, reducing the size of the anti-accidental contact power strip and thus minimizing its space requirements, improving ease of use.

[0068] In one embodiment, please refer to Figure 4 , Figure 7 and Figure 8 The protective component 30 includes a support portion 31 and a shielding portion 32 connected together. At least a portion of the shielding portion 32 is located below the socket 20a along the depth direction of the socket 20a. A portion of the socket cover 20 protrudes towards the receiving cavity to form a first abutment portion 21. The shielding portion 32 is movable to allow the support portion 31 to abut against the first abutment portion 21, thereby lifting the socket cover 20 and opening the socket 20a. Thus, the shielding portion 32 can shield the socket 20a when the power strip is not in use, reducing the risk of electric shock and improving safety.

[0069] Specifically, the shielding part 32 refers to the component used to shield the socket 20a when the protective member 30 is in the first state.

[0070] The support part 31 refers to the component that abuts against the first abutting part 21 and lifts the socket cover 20 during the process of inserting the plug into the socket 20a, and prevents the socket cover 20 from falling back by continuously applying a supporting force after the plug is fully inserted.

[0071] The shielding part 32 and the supporting part 31 can be integrally formed. Of course, they can also be separately formed.

[0072] The shielding part 32 can be entirely located under the socket 20a, or only a part of it can be located under the socket 20a, as long as it can shield the socket 20a and prevent accidental contact.

[0073] The first contact part 21 refers to the component on the socket cover 20 that is used to contact the support part 31.

[0074] The shape of the first abutting part 21 is not limited, as long as it can abut against the support part 31 to lift the socket cover 20.

[0075] In one embodiment, please refer to Figure 4 and Figure 9 When the protective component 30 is in the first state, the support part 31 extends along the depth direction of the socket 20a, and the shielding part 32 extends along a first direction, which is perpendicular to the depth direction of the socket 20a. This makes the structure of the anti-accidental contact power strip more compact and also provides a better lifting effect on the socket cover 20.

[0076] In one embodiment, please refer to Figure 4 and Figure 5The housing assembly 10 also has a connection hole 13a, and a portion of the shielding part 32 protrudes to form a rotating shaft 321, which is located within the connection hole 13a. Thus, through the cooperation of the rotating shaft 321 and the connection hole 13a, the protective member 30 can accurately achieve the function of shielding the plug 20a during plug insertion and removal, thereby improving the reliability and stability of the anti-accidental contact power strip operation.

[0077] In one embodiment, please refer to Figure 4 , Figure 7 , Figure 8 and Figure 9 The protective member 30 is recessed in a portion near the socket cover 20 to form a receiving groove 30a. When the protective member is in the first state, at least a portion of the first abutment portion 21 is located within the receiving groove 30a. This allows the protective member 30 to avoid the first abutment portion 21 in the first state, thereby making the structure of the anti-accidental contact power strip more compact and reducing its thickness.

[0078] Specifically, the receiving groove 30a refers to the structure used to receive the first abutment part 21 when the protective member 30 is in the first state.

[0079] The size and shape of the receiving groove 30a are not limited, as long as it can accommodate at least a portion of the first abutment portion 21.

[0080] The portion of the protective member 30 near the socket cover 20 may be recessed on the side opposite to the opening 11a to form a receiving groove 30a. Alternatively, the portion of the protective member 30 near the socket cover 20 may be recessed along the first direction and on the side opposite to the socket cover 20 to form a receiving groove 30a.

[0081] In one embodiment, please refer to Figure 8 , Figure 9 and Figure 10 One end of the receiving groove 30a is closed to form an abutment end 33, which abuts against the first abutment part 21. As a result, the external force when the plug is inserted can be efficiently transmitted to the socket cover 20, reducing the risk of the socket cover 20 jamming or failing to rise properly due to unstable force transmission, and improving the reliability of the anti-accidental contact power strip.

[0082] Specifically, the abutting end 33 refers to the component used to abut against the first abutting part 21 to lift the socket cover 20.

[0083] The shape of the abutment end 33 is not limited.

[0084] For example, the abutting end 33 is arc-shaped. This allows for better stress distribution when the abutting end 33 abuts against the first abutting portion 21, reducing the possibility of excessive localized stress. Furthermore, it allows for smoother relative sliding between the abutting end 33 and the first abutting portion 21, reducing wear between the components.

[0085] In one embodiment, please refer to Figure 4 and Figure 6 A portion of the housing assembly 10 is recessed to form a first groove 13b, and a portion of the socket cover 20 is recessed to form a second groove 20b. The second groove 20b is located on the side of the first groove 13b opposite to the opening 11a and is disposed opposite to it. A portion of the elastic member 40 is located within the first groove 13b, and another portion of the elastic member 40 is located within the second groove 20b. The opposite ends of the elastic member 40 abut against the groove walls of the first groove 13b and the second groove 20b, respectively. Thus, by placing a portion of the elastic member 40 within the first groove 13b and another portion within the second groove 20b, the displacement of the elastic member 40 is restricted, keeping the elastic member 40 stable during operation and improving the stability of the anti-accidental contact power strip operation.

[0086] Specifically, a portion of the housing assembly 10 is recessed toward the side near the opening 11a to form a first groove 13b, and a portion of the socket cover 20 is recessed toward the side away from the opening 11a to form a second groove 20b. The openings of the first groove 13b and the second groove 20b are arranged opposite to each other.

[0087] It should be noted that the fact that a portion of the elastic element 40 is located within the first groove 13b and another portion is located within the second groove 20b does not mean that the elastic element 40 is completely contained within both the first and second grooves 13b. In reality, a portion of the elastic element 40 near the first groove 13b is located within the first groove 13b and abuts against its wall, while a portion of the elastic element 40 near the second groove 20b is located within the second groove 20b and abuts against its wall. Depending on the operation of the anti-accidental contact power strip, the middle region of the elastic element 40 can be located within or outside either the first or second groove 13b.

[0088] The shape and size of the first groove 13b and the second groove 20b are not limited, as long as they can accommodate the elastic element 40.

[0089] In one embodiment, please refer to Figure 4A portion of the groove wall of the first groove 13b, on the side opposite to the second groove 20b, protrudes towards the side closer to the second groove 20b to form a limiting portion 14, which passes through the elastic member 40. This further restricts the displacement of the elastic member 40 within the first groove 13b, ensuring that the elastic member 40 always moves along its extension direction. This reduces elastic force loss and component wear caused by lateral bending or twisting of the elastic member 40, thereby improving the working efficiency and service life of the elastic member 40.

[0090] Specifically, the limiting part 14 refers to the component inside the first groove 13b used to limit the displacement of the elastic member 40 during the deformation process under force.

[0091] The shape of the limiting part 14 is not limited.

[0092] For example, the limiting part 14 is cylindrical.

[0093] In one specific embodiment, the housing assembly 10 includes an upper housing 11, a lower housing 12, and a mounting base 13. The upper housing 11 and the lower housing 12 enclose a receiving cavity. The mounting base 13 is located on the side of the protective member 30 opposite to the socket cover 20 and is connected to the lower housing 12. The upper housing 11 has an opening 11a communicating with the receiving cavity. The protective member 30 is movably disposed within the receiving cavity along the depth direction of the socket 20a. When the protective member 30 is in a first state, the socket cover 20 falls back relative to the opening 11a. When the protective member 30 is in a second state, the socket cover 20 rises relative to the opening 11a. This makes the anti-accidental contact power strip structure more compact and reduces the space occupied by the anti-accidental contact power strip.

[0094] Specifically, the connection method between the mounting base 13 and the lower housing 12 is not limited.

[0095] For example, housing assembly 10 also includes fasteners, mounting base 13 having a first fastening hole, lower housing 12 having a second fastening hole, and fasteners passing through the first and second fastening holes to connect mounting base 13 and lower housing 12.

[0096] In one specific embodiment, the mounting base 13 has a connecting hole 13a, and a portion of the shielding part 32 protrudes to form a rotating shaft 321, which is located within the connecting hole 13a. Thus, through the cooperation of the rotating shaft 321 and the connecting hole 13a, the protective member 30 can accurately achieve the function of shielding the plug 20a and opening the socket 20a during plug insertion and removal, thereby improving the reliability and stability of the anti-accidental contact power strip operation.

[0097] In one specific embodiment, a portion of the mounting base 13 is recessed to form a first groove 13b, and a portion of the socket cover 20 is recessed to form a second groove 20b. The second groove 20b is located on the side of the first groove 13b opposite to the opening 11a and is disposed opposite to it. A portion of the elastic member 40 is located within the first groove 13b, and another portion of the elastic member 40 is located within the second groove 20b. The opposite ends of the elastic member 40 abut against the groove walls of the first groove 13b and the second groove 20b, respectively. Thus, by placing a portion of the elastic member 40 within the first groove 13b and another portion within the second groove 20b, the displacement of the elastic member 40 is restricted, keeping the elastic member 40 stable during operation and improving the stability of the anti-accidental contact power strip operation.

[0098] Specifically, along the depth direction of the insertion hole 20a, the openings of the first groove 13b and the second groove 20b are positioned opposite each other.

[0099] In one specific embodiment, a portion of the socket cover 20 protrudes from the side opposite to the opening 11a to form a guide 22, and a portion of the mounting base 13 is recessed from the side opposite to the socket cover 20 to form a limiting groove 13c. The guide 22 is movably disposed within the limiting groove 13c. Thus, the limiting groove 13c provides a guiding path for the socket cover 20, effectively suppressing lateral swaying of the socket cover 20 during lifting and lowering, and improving the stability of the anti-accidental contact power strip operation.

[0100] Specifically, guide 22 refers to a component used to cooperate with limit groove 13c to limit the lateral movement of socket cover 20.

[0101] The shape of the guide 22 is not limited.

[0102] For example, guide 22 is cylindrical.

[0103] For example, the end of the guide member 22 that is away from the insertion hole 20a is arc-shaped, which makes it easier for the guide member 22 to be inserted into the limiting groove 13c and reduces assembly resistance.

[0104] In one specific embodiment, the anti-accidental contact power strip also includes a conductive sheet 50. The mounting base 13 has an opening, and along the depth direction of the socket 20a, the opening of the mounting base 13 is located below the socket 20a. The conductive sheet 50 is disposed between the lower housing 12 and the mounting base 13, and a portion of the conductive sheet 50 passes through the opening of the mounting base 13, and along the depth direction of the socket 20a, the conductive sheet 50 is located below the socket 20a. This allows the conductive sheet 50 to contact the plug after it is inserted through the socket 20a, thus enabling power transmission.

[0105] In the description of this application, the references to terms such as "in one embodiment," "in some embodiments," "in a specific embodiment," or "exemplary," etc., refer to a specific feature, structure, material, or characteristic described in connection with that embodiment or example, which is included in at least one embodiment or example of the embodiments of this application. In this application, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Moreover, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples. Furthermore, without contradiction, those skilled in the art can combine the different embodiments or examples described in this application, as well as the features of the different embodiments or examples.

[0106] The above description is merely a preferred embodiment of this application and is not intended to limit the application. Various modifications and variations can be made to this application by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this application are included within the scope of protection of this application.

Claims

1. A mistaken touch prevention row plug, characterized by, include: A housing assembly having a receiving cavity and an opening communicating with the receiving cavity; A socket cover, movably disposed within the receiving cavity, the socket cover having a socket hole for inserting a plug; A protective component is movably disposed within the receiving cavity, having a first state of blocking the socket and a second state of opening the socket.

2. The anti-mis-touch row of claim 1, wherein, The socket cover is configured to respond to the plug insertion operation, wherein the protective member lifts the socket cover to extend from the opening, and drives the protective member to switch from the first state to the second state; And / or, The socket cover is configured to retract into the receiving cavity in response to the plug removal operation, and trigger the protective member to return to the first state.

3. The anti-mis-touch row of claim 1, wherein, Along the depth direction of the socket, at least a portion of the protective member is located below the socket, the protective member abuts against the socket cover, and the protective member is configured such that when the plug is inserted, the plug pushes open the protective member, and the protective member drives the socket cover to extend out of the housing assembly from the opening.

4. The anti-mis-touch row of claim 1, wherein, During the insertion of the plug, the plug causes the protective member to lift the socket cover. The lifting height of the socket cover increases with the insertion depth of the plug, and when the plug is fully inserted, the socket cover is lifted to its maximum height; and / or, During the process of removing the plug, the socket cover retracts towards the side closer to the receiving cavity. The amount of retraction of the socket cover increases as the insertion depth of the plug decreases, and the amount of retraction of the socket cover is the greatest when the plug is completely removed.

5. The anti-mis-touch row plug of claim 1, wherein, The protective component includes a support portion and a shielding portion connected together. Along the depth direction of the socket, at least a portion of the shielding portion is located below the socket. A portion of the socket cover protrudes toward one side of the receiving cavity to form a first abutment portion. The shielding portion is movable to allow the support portion to abut against the first abutment portion, thereby lifting the socket cover and opening the socket.

6. The anti-mis-touch row of claim 5, wherein, When the protective component is in the first state, the support portion extends along the depth direction of the insertion hole, and the shielding portion extends along a first direction, which is perpendicular to the depth direction of the insertion hole.

7. The anti-mis-touch row of claim 5 or 6, wherein, The housing assembly also has a connection hole, and a portion of the shielding portion protrudes to form a rotating shaft, the rotating shaft being located within the connection hole; And / or, The protective member is recessed in a portion near the socket cover to form a receiving groove. When the protective member is in the first state, at least a portion of the first abutment portion is located within the receiving groove.

8. The mistaken-touch-preventing row plug of any one of claims 1-6, wherein, The anti-accidental contact power strip also includes an elastic element that extends along the depth of the socket. One end of the elastic element abuts against the housing assembly, and the other end abuts against the socket cover.

9. The anti-mis-touch row of claim 8, wherein, Part of the shell assembly is recessed to form a first recess, part of the socket cover is recessed to form a second recess, the second recess is located opposite the first recess on a side away from the opening, part of the elastic member is located in the first recess, another part of the elastic member is located in the second recess, and opposite ends of the elastic member respectively abut against a groove wall of the first recess and a groove wall of the second recess.

10. The anti-mis-touch row of claim 9, wherein, Part of the groove wall of the first recess on a side away from the second recess is protruded towards a side close to the second recess to form a limiting part, and the limiting part is arranged in the elastic member.

Images