CN213584336U - Lock control component - Google Patents

Abstract

A lock control component belongs to the electrical technical field and is used for solving the problem of bias voltage of a waterproof electric connection switch, the lock control component is constructed to cause the standard deformation of the lock control component and generate the horizontal or outward standard movement when a standard pin is inserted into a jack to bias the waterproof electric connection switch, so that the switch is switched on, the effect is that the requirement on the conductor standard performance is higher, the possibility that the waterproof electric connection switch is conducted by a pin which is not a plug is extremely low under the possibility, and the scheme that the pin is switched on a power supply and is realized by the lock control component which causes the standard movement can lead to better anti-touch performance.

Description

Lock control component

Technical Field

The application relates to the field of electrical technology, in particular to a lock control component.

Background

As the standard of living of people increases, the number of home appliances kept in each home gradually increases. Therefore, the demand for the outlet and the socket has sharply increased as a device for providing a power interface to the home appliance. Meanwhile, people have higher requirements on the safety performance of the socket and the power strip. In daily life, children touch the jacks of the socket and the power strip by fingers intentionally or unintentionally, or insert the jacks by conductors, so that electric shock accidents occur. In addition, in a toilet or other wet and watery environment (such as outdoor construction in rainy and snowy days), water is liable to enter the socket and the socket strip from the jack, which in turn causes electric shock and short-circuit accidents.

Some sockets and power strips in the prior art have certain functions of moisture protection, water protection and electric shock protection. These functions are typically implemented as follows: the socket and the power strip are provided with a water-splashing-proof cover plate, the socket and the power strip are provided with a leakage and short-circuit protection device, the socket and the power strip are provided with a touch-proof protection door, the socket and the power strip are provided with a water-proof sealing base plate and the like. However, the above solutions have drawbacks in terms of reliability and safety. The rubber material used for sealing the jacks can be worn after being inserted and pulled for a plurality of times, so that the sealing effect is reduced or lost, and further, the electric leakage danger is generated. Although the waterproof cover plate can prevent water from splashing, the reliability is still not high, because the waterproof cover can be lifted up after the electric appliance plug is inserted into the jack, and the protection effect is lost. In addition, the waterproof cover plate cannot prevent water immersion, so that it is unsafe to use the waterproof cover plate in places where water is likely to accumulate, such as outdoors, in low-lying places, basements, and the like. The sealing pad plate has a certain protection effect when used in water with low pressure, but the protection effect tends to be ineffective in deep water or places with high pressure.

In summary, the solutions in the prior art, although usable within a certain range, cannot meet the safety requirements under special circumstances. In addition, the reliability and the life-span of waterproof socket among the prior art and row of inserting still have the problem, consequently have the potential safety hazard. In view of the above, there is an urgent need to develop sockets and rows with higher waterproof, leakage-proof and electric shock-proof properties.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem of the bias voltage of the waterproof electric connection switch, the utility model provides a following technical scheme: a lock member is configured to cause a standard deformation of the lock member and a standard movement laterally or outwardly to bias a waterproof electrical connection switch to switch on when a standard pin is inserted into an insertion hole.

Furthermore, when the pin is pulled out of the jack, the pin is separated from the lock control component, so that the lock control component is not deformed any more and is far away from the waterproof electric connection switch, and the waterproof electric connection switch is reset.

Further, the standard pins are pins of a plug having a standard width or having a standard thickness or having a standard width and thickness.

Further, the lock member is made of a conductor material and includes a push paddle arranged perpendicular to a bottom surface of the compartment and a fixing clip portion including a pair of fixing jaws; the planes of the pushing shifting sheet and the fixing clamp part are vertical to each other; the push-pull piece has a bend near the end, the bend has a first bend portion abutting against the waterproof electric connection switch, and has a second bend portion facing the pin, the gap of the push-pull piece is set to a size fitting the width of the pin, so that the push-pull piece biases the movable contact piece to the contact static contact piece only when the pin conforming to the standard specified size is inserted into the jack, but cannot bias the movable contact piece to the contact static contact piece when the pin or other conductor not conforming to the standard specified size is inserted into the jack, and resets when the pin is pulled out from the jack; and two fixing clips opposed to each other, each fixing clip being formed near an end portion with a bent portion facing the pin, a distance between the two fixing clips being set to a size fitting a thickness of the pin so that the pin is gripped by the fixing clip through the bent portion when inserted into the insertion hole and is reset when the pin is extracted from the insertion hole.

Furthermore, the bending part of the fixed clamping piece is closer to the insertion hole than the bending part of the pushing shifting piece, so that the pin is ensured to be clamped by the pair of fixed clamping pieces before being pushed to push the pushing shifting piece when being inserted into the insertion hole.

Further, the lock member is made of a conductor material and includes a push paddle formed separately and placed on the compartment and a pair of fixing jaws arranged perpendicular to the bottom surface of the compartment; the section of the pushing shifting piece is formed into a V shape with a downward opening, the top end of the pushing shifting piece is a hinge point, one side edge of the pushing shifting piece is close to the jack, and the other side edge of the pushing shifting piece is covered with an insulating bush and abuts against the waterproof electric connection switch; the included angle of two side edges of the pushing shifting piece is set to be matched with the size of the width of the pin, so that the pushing shifting piece only biases the movable contact piece to be contacted with the static contact piece under the condition that the pin which meets the standard specified size is inserted into the jack, but cannot bias the movable contact piece to be contacted with the static contact piece under the condition that the pin which does not meet the standard specified size or other conductors are inserted into the jack, and resets when the pin is pulled out of the jack; and two fixing clips opposed to each other, each fixing clip being formed near an end portion with a bent portion facing the pin, a distance between the two fixing clips being set to a size fitting a thickness of the pin so that the pin is gripped by the fixing clip through the bent portion when inserted into the insertion hole and is reset when the pin is extracted from the insertion hole.

Furthermore, the bending part of the fixed clamping piece is closer to the insertion hole than the contact part of the pushing shifting piece and the pin, so that the pin is ensured to be clamped by the pair of fixed clamping pieces and then pushed to push the pushing shifting piece when being inserted into the insertion hole.

Further, the lock member is disposed in the compartments and aligned with the insertion holes, the number of compartments corresponds to the number of insertion holes, each compartment formed in the housing is disposed below the corresponding insertion hole, and the inside of the compartment is accessible from the outside of the housing via the insertion hole.

Has the advantages that: the lock accuse component can produce standard deformation and horizontal or outside removal standard distance, shows that the conductor of inserting the jack is very big probably the standard to participate in, otherwise can't reach the horizontal or outside removal standard distance of standard, compares in inserting not through the lock accuse component, by the scheme of conductor direct action electric connection switch, the utility model discloses require higher to the conductor standardness, and make waterproof electric connection switch by the probably extremely low of participating in the switch-on of the pin of non-plug under this kind probably, therefore participate in the scheme that the switch-on power realized through the lock accuse component that arouses the standard removal and can lead to better protection against electric shock performance.

Drawings

The foregoing and other aspects of the present application will be more fully understood and appreciated by reference to the following detailed description, taken with reference to the accompanying drawings, in which:

fig. 1 is a perspective view of a safety receptacle module according to the present application.

Fig. 2 is a perspective view of a safety receptacle module according to another embodiment of the present application.

Fig. 3 is a top view of the safety receptacle module of fig. 1.

Figure 4 is a side view of the secure receptacle module of figure 1.

Fig. 5 is a cross-sectional view of a waterproof electrical connection switch of a safety receptacle module according to another embodiment of the present application.

Fig. 6 is a top view of a secure receptacle module according to another embodiment of the present application.

Figure 7 is a side view of the secure receptacle module of figure 6.

Fig. 8 is an electrical schematic diagram of the safety receptacle module of fig. 1.

Fig. 9 is a circuit diagram of the safety receptacle module of fig. 8.

Fig. 10 is an electrical schematic diagram of a safety receptacle module according to another embodiment of the present application.

Fig. 11 is a circuit diagram of the safety receptacle module of fig. 10.

Fig. 12 is a perspective view of a safety receptacle module according to another embodiment of the present application.

Figure 13 is a top plan view of the secure receptacle module of figure 12.

Fig. 14 is an electrical schematic diagram of the safety receptacle module of fig. 12.

Fig. 15 is a circuit diagram of the safety receptacle module of fig. 12.

Fig. 16 is a perspective view of a safety receptacle module according to another embodiment of the present application.

Fig. 17 is a top plan view of the safety receptacle module of fig. 16.

Fig. 18 is an electrical schematic diagram of the safety receptacle module of fig. 16.

Fig. 19 is a circuit diagram of the safety receptacle module of fig. 16.

Fig. 20 is a top view of a safety receptacle module according to another embodiment of the present application.

FIG. 21 is a cross-sectional view of a power strip according to the present application.

Fig. 22 is a cross-sectional view of a mechanical switch of the power strip of fig. 21.

Fig. 23 is a perspective view of a mobile cable drum according to the present application.

Fig. 24 is a schematic view of the thickness direction and width direction of the pins of the plug.

Fig. 25 is a schematic view of the insertion of the prongs into the retaining clip.

Fig. 26 is an isolated part view of the mechanical switch of fig. 22.

Fig. 27 is a side view of fig. 26.

Detailed Description

To assist those skilled in the art in understanding the subject matter claimed herein, specific embodiments thereof are described below in detail with reference to the accompanying drawings.

Fig. 1 is a perspective view of a safety receptacle module according to the present application. The safety socket module includes: a housing 1; an upper cover 3 covering the housing 1, the upper cover 3 being provided with a plurality of insertion holes 4; compartments 5, the number of which corresponds to the number of receptacles 4, each compartment 5 being arranged in the housing 1 below a corresponding receptacle 4 and the interior of which is accessible from outside the housing 1 via the receptacle 4; a sealing gasket 6 disposed between the compartments 5 and the upper cover 3 to seal the compartments 5 from liquid permeation from one compartment 5 to the other compartment 5. The upper cover 3 is provided with a live wire jack 41 corresponding to the live wire pin of the consumer plug and a neutral wire jack 42 corresponding to the neutral wire pin of the consumer plug. The safety jack module comprises a live compartment 51 disposed below the live jack in the housing 1 and a neutral compartment 52 disposed below the neutral jack in the housing. The upper cover 3 is provided with a waterproof pad 2 made of an insulating material. The waterproof pad 2 is configured to cover a portion of the upper cover 3 and expose the receptacle 4 for cooperation with a consumer plug to prevent water from entering the compartment 5 through a gap between the consumer plug and the upper cover 3 while blocking communication of water between the upper cover surface plug pins in the event that the consumer plug is inserted into the receptacle 4.

Fig. 2 is a perspective view of a safety receptacle module according to another embodiment of the present application. The difference from the embodiment of fig. 1 is that a multi-edge waterproof structure 27 is arranged on the upper cover 3, and the electrical appliance plug is provided with a waterproof insulating rubber mat which is used in cooperation with the multi-edge waterproof structure 27, so that the electrical appliance plug has stronger waterproof performance. Unsmooth and waterproof insulating rubber mat contact under the extrusion between the arris that many arriss waterproof construction 27 formed, can effectively prevent into water and advance water and remove between the unsmooth of difference, and then prevent under the condition that inserts jack 4 with electrical apparatus plug that water from getting into compartment 5 through the gap between electrical apparatus plug and the upper cover 3, block the UNICOM of water between the surface plug of upper cover 3 participates in simultaneously. Fig. 3 is a top view of the safety jack module of fig. 1 with the upper cover 3 removed for ease of description. The safety socket module includes: a waterproof electrical connection switch 7, which is arranged in the compartment 5 and is used for asynchronously controlling the closing and the opening of the circuit between the power supply and the plug of the electrical appliance; a lock member 10 is provided in the compartment and aligned with the receptacle for gripping the prongs of a consumer plug (not shown in the figures) and biasing the waterproof electrical connection switch 7 in the event that the prongs are inserted into the receptacle 4, and disengaging from the prongs and resetting the waterproof electrical connection switch 7 when the prongs are withdrawn from the receptacle 4. In a preferred form, the lock member is configured to cause standard deformation of the lock member and a standard distance of movement laterally or outwardly to bias the watertight electrical connection switch to switch on when the standard prong is inserted into the receptacle. In one embodiment, the standard pins are pins conforming to the standard specification, which mainly means that the width of the pins conforms to the standard specification, and further includes that the thickness of the pins conforms to the standard specification. In the first embodiment, the compartment 5 comprises a live compartment 51 and a neutral compartment 52, in each of which two watertight electrical connection switches 7 are arranged to form a four-switch controlled protection circuit, in the live compartment 51 and the neutral compartment 52. The connection part of the waterproof electrical connection switch 7 with other conductors in the bottom of the housing and the exposed part of the conductor are covered by waterproof insulating material to be waterproof treated, for example, the waterproof electrical connection switch 7 is connected with other parts by copper sheets, the contact part and the copper sheets are covered by pouring insulating material, or the waterproof electrical connection switch 7 is connected with other parts by insulated wires, and then the contact part is injection-molded by using insulating material. The connection portion of the lock member 10 with the other conductor in the bottom of the housing, and the portion of the conductor exposed to the outside, are subjected to waterproofing treatment by being covered with a waterproof insulating material (for example, covered by means of potting insulating material or connected by an insulated wire). The waterproof electrical connection switch 7 is connected with another waterproof electrical connection switch 7 or the lock member 10 by a conductor.

Figure 4 is a side view of the secure receptacle module of figure 1. The waterproof electric connection switch 7 comprises an isolation waterproof bin and a movable contact piece 13 and a static contact piece 14 which are arranged inside the isolation waterproof bin and are opposite to each other, the isolation waterproof bin is constructed into a full-sealing structure, the contact surface biased with the lock control component can be elastically deformed, and in a preferred scheme, the isolation waterproof bin is a waterproof capsule 12. The movable contact piece 13 is configured to contact the stationary contact piece 14 by the bias of the lock member 10 to turn on the waterproof electrical connection switch 7 when the pin is inserted into the insertion hole 4, and to be away from the stationary contact piece by the retraction of the lock member 10 to turn off the waterproof electrical connection switch 7 when the pin is pulled out from the insertion hole 4. In one solution, the standard-sized prong of the socket is inserted into the receptacle 4, the lock member 10 is deformed by said insertion, biasing the elastically deformable surface of the insulating waterproof compartment, the deformation of the elastically deformable surface causes it to bias the movable contact 13, which is moved by being biased and contacts the stationary contact 14 to switch on the waterproof electrical connection switch 7, and is moved away from the stationary contact by retraction of the lock member 10 to switch off the waterproof electrical connection switch 7 when the prong is extracted from the receptacle 4. For safety reasons, the movable contact piece 13 and the fixed contact piece 14 in the waterproof capsule 12 are not connected with the movable contact piece 13 and the fixed contact piece 14 in other waterproof capsules 12 in the same compartment 5 without connecting the movable contact piece 13 and the fixed contact piece 14 in the waterproof capsules 12 in other compartments 5. In a multi-switch control line, it is ensured that the line can only be accessed by joint triggering by the lock members 10 in different compartments. The conductive connecting piece 8 in the waterproof capsule is configured to pass through the bottom of the compartment 5 and the waterproof capsule 12 to provide electrical connection of the movable contact piece 13 and the static contact piece 14 to the lock control member 10 or other components, and the conductive connecting piece 8 in the waterproof capsule 12 may be an extension of the movable contact piece 13 or the static contact piece 14, i.e., the movable contact piece 13 or the static contact piece 14 is integrally formed with the corresponding conductive connecting piece 8, or the independent conductive connecting piece 8 is connected with the movable contact piece 13 or the static contact piece 14. The conductive connection 8 in the lock member 10 is configured to pass through the bottom of the compartment 5 to provide electrical connection of the lock member 10 to the movable contact 13 or the stationary contact 14 or other components, and the conductive connection 8 in the lock member 10 may be integrally formed with the lock member 10 or a separate conductive connection 8 may be connected to the lock member 10. The movable contact piece 13 and the fixed contact piece 14 are provided with contacts 9, the movable contact piece 13 and the fixed contact piece 14 are configured to contact with each other by means of the respective contacts 9, and the contacts 9 may be fixed to the movable contact piece 13 and the fixed contact piece 14 by welding.

The lock member 10 is made of a conductive material and includes a push paddle 101 disposed perpendicular to the bottom surface of the compartment and a fixing clip portion, and in a preferred embodiment, the lock member 10 is made of a conductive material by integral molding, and the fixing clip portion includes a pair of fixing clips 102. The conductor material may be phosphor bronze. The pushing pull piece 101 and the fixing clip part are perpendicular to each other. The push paddle 101 has a bend near the end with a first bend 104 against the waterproof electrical connection switch 7 and a second bend 105 towards the pin, the gap of the push paddle 101 being set to the size (distance b in fig. 24) that fits the width of the pin. When the pin is inserted into the jack 4, the pin touches the second bending part 105, and the distance of the transverse movement of the second bending part 105 is transferred to the movable contact piece 13 in the waterproof electric connection switch 7 through the interference of the first bending part 104 and the waterproof electric connection switch 7, and the distance just enables the movable contact piece 13 to be in good contact with the static contact piece 14. So that the push-on paddle 13 biases the movable contact 13 into contact with the stationary contact 14 only when a pin of a standard specified size is inserted into the jack, but does not bias the movable contact 13 into contact with the stationary contact 14 when a pin or other conductor of a non-standard specified size is inserted into the jack, functions as a shock protection, and resets when the pin is extracted from the jack 4.

As shown in fig. 25, the two fixing clip pieces 102 are opposed to each other, each fixing clip piece 102 is formed at an end portion with a bent portion 106 facing the pin, and a distance between the two fixing clip pieces 102 is set to a size (distance a in fig. 24) matching the thickness of the pin so that the pin is clamped by the fixing clip piece 102 through the bent portion 106 when inserted into the insertion hole 4, thereby preventing contact failure and being reset when the pin is pulled out from the insertion hole 4.

The bent portion of the fixing clip 102 is closer to the insertion hole 4 than the bent portion of the push paddle 101 to ensure that the pin is clamped by the pair of fixing clip 102 before pushing the push paddle when inserted into the insertion hole 4, preventing the generation of an arc.

Fig. 5 is a cross-sectional view of a waterproof electrical connection switch of a safety receptacle module according to another embodiment of the present application. The waterproof capsule 12 includes a capsule base 15 and a waterproof glue cover 16 secured to the capsule base 15. The waterproof glue cover 16 may be bonded to the capsule base 15 by a waterproof adhesive. The movable contact piece 13 and the static contact piece 14 are arranged inside the waterproof rubber sleeve 16 and fixed to the capsule base 15 by injection molding. The capsule base 15 is made of an insulating material by injection moulding. The waterproof rubber sleeve 16 is made of insulating, heat-resistant and friction-resistant elastic materials in an integrated manner, and the integrated manufacturing is realized in an integrated forming mode or can be welded into a whole through processes such as high frequency welding and the like.

The elastic material may be silicone rubber. The difference from the embodiment of fig. 4 is that an insulating elastic member 17 is provided between the movable contact piece 13 and the stationary contact piece 14 for assisting and correcting the deformation and rebound of the movable contact piece 13 and the stationary contact piece 14.

Fig. 6 is a top view of a secure receptacle module according to another embodiment of the present application. The difference with the embodiment of figure 3 is that the lock member 10 is made of a conductive material and comprises a push pick 101 hinged on the compartment 5 and a pair of fixing jaws 102 arranged perpendicularly to the bottom face of the compartment. The conductor material may be phosphor bronze. As shown in fig. 25, the fixing clip 102 is formed with a bent portion 106 toward the pin near the end, and the distance between the fixing clips 102 is set to a size (distance a in fig. 24) matching the thickness of the pin so that the pin is clamped by the fixing clip 102 through the bent portion 106 when inserted into the insertion hole 4, thereby preventing contact failure and being reset when the pin is pulled out from the insertion hole 4.

Figure 7 is a side view of the secure receptacle module of figure 6. The section of the push paddle 101 is configured in a substantially V-shape with a downward opening, the top end of which is a hinge point 103, one side being close to the jack 4 and the other side being covered with an insulating bush and abutting against the waterproof electrical connection switch 7. The angle of both side edges of the push paddle 101 is set to a size (distance b in fig. 24) that fits the width of the pin, so that the push paddle 101 biases the movable contact piece 13 into contact with the stationary contact piece 14 only in the case where a pin of a standard prescribed size is inserted into the jack 4, but fails to bias the movable contact piece 13 into contact with the stationary contact piece 14 in the case where a pin or other conductor of a non-standard prescribed size is inserted into the jack 4, and is reset by the rebound of the waterproof electrical connection switch 7 when the pin is pulled out from the jack 4. The lengths and angles of the two side edges of the push pick 101 and the shapes of the bent portions of the fixing clip pieces 102 are configured to ensure that the pin is clamped by the pair of fixing clip pieces 102 before being pushed to push the push pick 101 when being inserted into the insertion hole 4, thereby preventing the generation of electric arcs.

Fig. 8 is an electrical schematic diagram of the safety receptacle module of fig. 1. The live line (Lin) from the power supply is controlled in series via two waterproof electrical connection switches 7 (K1 and K2 in the figure) and then connected to the live line (Lout) of the pin. The neutral (N in) from the power supply is controlled in series via two waterproof electrical connection switches 7 (K3 and K4 in the figure) to connect to the neutral (N out) of the pin.

Fig. 9 is a circuit diagram of the safety receptacle module of fig. 1. The movable contact 13 (b 1 in the figure) of the first waterproof electrical connection switch K1 in the live compartment 51 is connected to the live line (L in the figure) of the power supply; the static contact 14 (a 1 in the figure) of the first waterproof electrical connection switch K1 is connected to the static contact 14 (a 2 in the figure) of the second waterproof electrical connection switch K2 in the neutral compartment 52; the movable contact 13 (b 2 in the figure) of the second waterproof electrical connection switch K2 is connected to the lock member 10 of the live compartment 51 which is in turn connected to the live (L in the figure) of the prong (and may also be connected to the lock member 10 of the neutral compartment 52, the lock member 10 in the respective neutral compartment 52 being equipotential with the live). In the present embodiment, the movable contact 13 (b 4 in the figure) of the fourth waterproof electrical connection switch K4 in the neutral compartment 52 is connected to the neutral of the power supply (N in the figure); the static contact 14 (a 4 in the figure) of the fourth waterproof electrical connection switch K4 is connected to the movable contact 13 (b 3 in the figure) of the third waterproof electrical connection switch K3 in the live compartment 51; the static contact 14 (a 3 in the figure) of the third waterproof electrical connection switch K3 is connected to the lock member 10 of the neutral compartment 52 which is in turn connected to the neutral (N in the figure) of the pin (and may also be connected to the lock member 10 of the live compartment 51, the lock member 10 of the respective live compartment 51 being equipotential with the neutral). It should be noted that in this embodiment, the connection lines between the movable contact and the fixed contact in the same waterproof electrical connection switch are interchangeable (for example, a1 and b1 are interchangeable), and the selection of the waterproof electrical connection switch can be changed as long as the waterproof electrical connection switch controlled by the lock control member of one line including two different compartments is satisfied, such as K1 and K4, and K3 and K2 are connected, so as to ensure that the live line and the neutral line can be connected only when the pins conforming to the standard are inserted into two jacks simultaneously. .

Fig. 10 is an electrical schematic diagram of a safety receptacle module according to another embodiment of the present application. The difference with the embodiment of fig. 8 is that the live line from the power source (L in) is controlled in series via three watertight electrical connection switches 7 (K1, K2 and K3 in the figure) and then connected to the live line of the pins (L out). The zero line (N in) from the power supply is controlled by a waterproof electric connection switch 7 (K4 in the figure) and then is connected to the zero line (N out) of the pin, so that the three waterproof electric connection switches of the live wire circuit are closed to be communicated with the live wire circuit only when the pin which meets the standard is inserted into the two jacks simultaneously.

Fig. 11 is a circuit diagram of the safety receptacle module of fig. 10. The static contact 14 (a 1 in the figure) of the first waterproof electrical connection switch K1 in the live compartment 51 is connected to the live line (L in the figure) of the power supply; the movable contact 13 (b 1 in the figure) of the first waterproof electrical connection switch K1 is connected to the stationary contact 14 (a 2 in the figure) of the second waterproof electrical connection switch K2 in the live compartment 51; the movable contact 13 (b 2 in the figure) of the second waterproof electric connecting switch K2 is connected to the static contact 14 (a 3 in the figure) of the third waterproof electric connecting switch K3 in the neutral compartment 52; the movable contact 13 (b 3 in the figure) of the third waterproof electrical connection switch K3 is connected to the lock member 10 of the live wire compartment 51 which in turn is connected to the live wire (L out in the figure) of the pin. In the present embodiment, the stationary contact 14 (a 4 in the figure) of the fourth waterproof electrical connection switch K4 in the neutral compartment 52 is connected to the neutral of the power supply (N in the figure); the movable contact 13 (b 4 in the drawing) of the fourth waterproof electrical connection switch K4 is connected to the lock member 10 of the neutral compartment 52 which is in turn connected to the neutral (N in the drawing) of the pin. It should be noted that other connection sequences also fall within the scope of the present application.

As can be seen from the contents of fig. 9 and 11, the present invention is directed to the 2-hole socket module, the connection control of the circuit is performed through a plurality of waterproof electrical connection switches, different numbers of waterproof electrical connection switches are selected according to different situations, and especially, at least 2 waterproof electrical connection switches controlled by different compartment lock control members are preferably used for the connection of the live wire circuit, so that the live wire circuit can be connected only when the pins which must meet the standard are inserted into 2 jacks.

Fig. 12 is a perspective view of a safety receptacle module according to another embodiment of the present application. The difference from the embodiment of fig. 1 is that the upper cover 3 is provided with a live wire jack 41 corresponding to the live wire pin of the consumer plug, a neutral wire jack 42 corresponding to the neutral wire pin of the consumer plug, and a ground wire jack 43 corresponding to the ground wire pin of the consumer plug. The safety outlet module comprises a live compartment 51 arranged below the live jack in the housing 1, a neutral compartment 52 arranged below the neutral jack in the housing 1 and a ground compartment 53 arranged below the ground jack in the housing 1.

Figure 13 is a top plan view of the secure receptacle module of figure 12. A total of four watertight electrical connection switches 7 are provided in the live compartment 51, the neutral compartment 52 and the earth compartment 53 to form a four-switch controlled protection circuit. Due to volume limitations of the interior space of the safety socket module, the four watertight electrical connection switches 7 may be provided in two in the live compartment 51, one in each of the neutral compartment 52 and the ground compartment 53, two in the neutral compartment 52, one in each of the live compartment 51 and the ground compartment 53, two in each of the ground compartment 53, and one in each of the live compartment 51 and the neutral compartment 52.

Fig. 14 is an electrical schematic diagram of the safety receptacle module of fig. 12. The live wire (lout) from the power supply is controlled in series via two watertight electrical connection switches 7 (K1 and K2 in the figure) and then connected to the lock member 10 (lout) in the live wire compartment 51. The neutral wire (N in) from the power supply is controlled via two watertight electrical connection switches 7 (K3 and K4 in the figure) to be connected to the lock member 10(N out) in the neutral compartment 52. The earth wire (E in) from the power supply is directly connected to the lock member 10(E out) of the earth wire compartment 53.

As can be seen from the content of fig. 14, the waterproof electrical connection switches 7 in the compartments of the present invention are distributed in the compartments, but do not necessarily participate in controlling the circuit of the compartment in which the waterproof electrical connection switches are located, such as the waterproof electrical connection switches 7 in the ground wire compartment 53, only occupy the space of the ground wire compartment 53, and actually participate in controlling the zero line.

Fig. 15 is a circuit diagram of the safety receptacle module of fig. 12. In this embodiment, the static contact 14 (a 1 in the figure) of the first waterproof electrical connection switch K1 in the neutral compartment 52 is connected to the live line (L in the figure) of the power supply; the movable contact 13 (b 1 in the figure) of the first waterproof electrical connection switch K1 is connected to the stationary contact 14 (a 2 in the figure) of the second waterproof electrical connection switch K2 in the live compartment 51; the movable contact 13 (b 2 in the figure) of the second waterproof electrical connection switch K2 is connected to the lock member 10 of the live wire compartment 51 which is in turn connected to the live wire (L out in the figure) of the prong. In the present embodiment, the static contact 14 (a 3 in the figure) of the third waterproof electrical connection switch K3 in the live compartment 51 is connected to the neutral line of the power supply (N in the figure); the movable contact 13 (b 3 in the figure) of the third waterproof electrical connecting switch K3 is connected to the stationary contact 14 (a 4 in the figure) of the fourth waterproof electrical connecting switch K4 in the ground compartment 53; the movable contact 13 (b 4 in the drawing) of the fourth waterproof electrical connection switch K4 is connected to the lock member 10 of the neutral compartment 52 which is in turn connected to the neutral (N in the drawing) of the pin. In the present embodiment, the ground wire (E in the drawing) of the power supply is directly connected to the ground wire (E out in the drawing) of the pin through the lock member 10 of the ground wire compartment 53. It should be noted that other connection sequences also fall within the scope of the present application.

Fig. 16 is a perspective view of a safety receptacle module according to a fourth embodiment of the present application. The difference from the embodiment of fig. 1 is that the upper cover 3 is provided with three live wire insertion holes 41 corresponding to the live wire pins of the consumer plug and one ground wire insertion hole 43 corresponding to the ground wire pin of the consumer plug.

Fig. 17 is a top plan view of the safety receptacle module of fig. 16. The safety outlet module comprises a first, second and third live compartment 511, 512, 513 in the housing 1, arranged below the three live jacks respectively, and a ground compartment 53 in the housing 1 arranged below the ground jacks. Two watertight electrical connection switches 7 are provided in each of the first, ground and third live compartments 511, 53, 513 to form a six-switch controlled protection circuit.

Fig. 18 is an electrical schematic diagram of the safety receptacle module of fig. 16. The first live wire from the power supply (L1 in) is controlled in series via two waterproof electrical connection switches 7 (K1 and K2 in the figure) and then connected to the first live wire of the pins (L1 out). The second live wire (L2 in) from the power supply is controlled in series via two waterproof electrical connection switches 7 (K3 and K4 in the figure) and then connected to the second live wire (L2 out) of the pins. The third live wire (L3 in) from the power supply is controlled in series via two waterproof electrical connection switches 7 (K5 and K6 in the figure) and then connected to the third live wire (L3 out) of the pins. The ground (E in) from the power supply is directly connected to the ground (E out) of the pin.

Fig. 19 is a circuit diagram of the safety receptacle module of fig. 16. The stationary contact 14 (a 1 in the figure) of the first watertight electrical connection switch K1 in the first live compartment 511 is connected to the first live (L1 in the figure) of the power supply; the movable contact 13 (b 1 in the figure) of the first watertight electrical connection switch K1 is connected to the stationary contact 14 (a 2 in the figure) of the second watertight electrical connection switch K2 in the third live compartment 513; the movable contact 13 (b 2 in the figure) of the second waterproof electrical connection switch K2 is connected to the lock member 10 of the first live wire compartment 511 which is in turn connected to the first live wire of the prong (L1 in the figure). In this embodiment, the static contact 14 (a 3 in the figure) of the third electrical and water connection switch K3 in the first live compartment 512 is connected to the second live line of the power supply (L2 in the figure); the movable contact 13 (b 3 in the figure) of the third watertight electrical connection switch K3 is connected to the stationary contact 14 (a 4 in the figure) of the fourth watertight electrical connection switch K4 in the second live compartment 512; the movable contact 13 (b 4 in the figure) of the fourth waterproof electrical connection switch K4 is connected to the lock member 10 of the second live wire compartment 512 which in turn is connected to the second live wire (L2 in the figure) of the pins. In this embodiment, the static contact 14 (a 5 in the figure) of the fifth waterproof electrical connection switch K5 in the second live compartment 512 is connected to the third live line of the power supply (L3 in the figure); the movable contact 13 (b 5 in the figure) of the fifth waterproof electrical connection switch K5 is connected to the stationary contact 14 (a 6 in the figure) of the sixth waterproof electrical connection switch K6 in the third live compartment 513; the movable contact 13 (b 6 in the figure) of the sixth waterproof electrical connection switch K6 is connected to the lock member 10 of the third live wire compartment 513 which is in turn connected to the third live wire (L3 in the figure) of the prong. In the present embodiment, the ground wire (E in the drawing) of the power supply is directly connected to the ground wire (E out in the drawing) of the pin through the lock member 10 of the ground wire compartment 53. It should be noted that other connection sequences also fall within the scope of the present application.

Fig. 20 is a top view of a safety receptacle module according to another embodiment of the present application. The difference to the embodiment of fig. 16 is that one waterproof electrical connection switch 7 is provided in each of the first and third live compartments 511, 513 and two waterproof electrical connection switches 7 are provided in each of the second and ground compartments 512, 53 to form a six-switch controlled protection circuit.

FIG. 21 is a cross-sectional view of a power strip according to the present application. The socket includes a socket housing 21; an external power line 23 externally connected to the socket housing; an internal power line 24 disposed in the row housing. One or more safety jack modules are embedded in the row housing 21. One or more of the safety receptacle modules in the bank may be safety receptacle modules having the same number of jacks or safety receptacle modules having different numbers of jacks. It should be noted that industrial four-jack safety jack modules cannot be arranged in the same row as two-jack and three-jack safety jack modules for safety reasons. The row housing 21 is configured to expose the upper cover 3 of the safety jack module. Each safety receptacle module is connected in parallel to an internal power line 24. The external power line 23 is connected to the internal power line 24 via a mechanical switch 25.

Fig. 22 is a cross-sectional view of a mechanical switch of the power strip of fig. 21. The mechanical switch 25 includes: a switch button 252 having a depressed position and a raised position; a push member 253 connected to the switch button 252; a waterproof capsule 254 is switched, which abuts against the pressing member 253. The switch waterproof capsule 254 internally includes a switch movable contact 255 and a switch stationary contact 256 opposed to each other. The switching movable contact 255 is connected to one of the external power line 23 and the internal power line 24, and the switching stationary contact 256 is connected to the other of the external power line 23 and the internal power line 24. The switch movable contact 255 is configured to contact the switch stationary contact 256 to communicate the external power line 23 and the internal power line 24 by the bias of the pushing member 253 when the switch knob 252 is in the depressed position, and to be away from the switch stationary contact 256 to disconnect the external power line 23 and the internal power line 24 by the retraction of the pushing member 253 when the switch knob 252 is in the raised position. Because the zero line of the power grid is mostly electrified in actual life, two mechanical switches are needed to respectively control the on and off of the live wire and the zero line when the power grid is plugged in and pulled out from water. In this embodiment, the mechanical switch 25 includes two switch water-proof capsules 254. One of the switch waterproof capsules 254 has its switch movable contact 255 connected to the live line of the external power line 23 and its switch stationary contact 256 connected to the live line of the internal power line 24, and the other switch waterproof capsule 254 has its switch movable contact 255 connected to the neutral line of the external power line 23 and its switch stationary contact 256 connected to the neutral line of the internal power line 24. Similar to the conductive connection member 8, the switch conductive connection member 258 is configured to pass through the switch waterproof capsule 254 to provide electrical connection of the switch movable contact 255 and the switch stationary contact 256 to other components. In a preferred embodiment, the mechanical switch further includes a mechanical switch upper cover 2511, a mechanical switch bottom cover 2510 and a switch waterproof capsule fixing plate 259, as shown in fig. 26 and 27, the switch conductive connecting member 258 is a conductor (insulated wire) covered with an insulating layer, connected to a contact in the switch waterproof capsule 254, and is injection-molded at the bottom of the switch waterproof capsule with an insulating material, so that the electrical connection portion has a waterproof function.

Fig. 23 is a perspective view of a mobile cable drum according to the present application. The mobile cable reel includes: a reel 31; baffles 32 disposed on opposite sides of the drum 31; a cable drum power line 33 wound around the outer periphery of the drum 31; a plurality of safety jack modules (the upper cover 3 is exposed in the figure) provided on the barrier 32; and a drain opening 34 provided on the barrier 32 and corresponding to the safety jack module.

In one embodiment, a secure receptacle module includes: a housing 1, an upper cover 3 covering the housing 1 and provided with a plurality of insertion holes 4, compartments 5 the number of which corresponds to the number of insertion holes 4, each compartment 5 being provided in the housing 1 below a corresponding insertion hole 4 and the interior of which is accessible from outside the housing 1 via the insertion hole 4; a waterproof electrical connection switch 7 provided in the compartment 5 for asynchronously controlling the closing and opening of the electrical circuit between the power supply and the consumer plug, a lock member 10 provided in the compartment 5 and aligned with the jack 4 for gripping the prong of the consumer plug and biasing the waterproof electrical connection switch 7 in the event that the prong is inserted into the jack 4, and disengaging from the prong and resetting the waterproof electrical connection switch 7 when the prong is pulled out of the jack 4. The bias is referred to as lateral or outboard compression. It may be a lateral or outward pressing that is generated by the pin moving and/or rotating the lock member 10 laterally and/or outward when the pin is inserted into the insertion hole 4. The waterproof electrical connection switch 7 includes an isolated waterproof compartment and a movable contact piece 13 and a stationary contact piece 14 which are disposed inside a waterproof capsule 12 to be opposed to each other. The insulating and waterproof case is constructed in a full-sealed structure, and the contact surface biased against the lock member 10 is elastically deformed. The movable contact piece 13 is configured to contact the stationary contact piece 14 by the bias of the lock member 10 to turn on the waterproof electrical connection switch 7 when the pin is inserted into the insertion hole 4, and to be away from the stationary contact piece 14 by the reset of the lock member 10 to turn off the waterproof electrical connection switch 7 when the pin is pulled out from the insertion hole 4.

According to an alternative embodiment, the safety jack module further comprises a sealing gasket 6 arranged between the compartments 5 and the upper cover 3 to seal the compartments 5 against penetration of liquid from one compartment 5 to the other compartment 5. The waterproof electric connection switch 7 is covered by waterproof insulating materials at the connecting part of the bottom of the shell 1 and other conductors and the exposed part of the conductor for waterproof treatment; and the connection portions of the lock member 10 with other conductors in the bottom of the case 1 and the portions of the conductors exposed to the outside are subjected to waterproof treatment by being covered with a waterproof insulating material. The waterproof electrical connection switch 7 is connected with another waterproof electrical connection switch 7 or the lock member 10 by a conductor.

According to an alternative embodiment, the insulating waterproof compartment is a waterproof capsule 12 comprising a capsule base 15 and a waterproof rubber sleeve 16 fixed to the capsule base 15. The movable contact piece 13 and the fixed contact piece 14 are disposed inside the waterproof rubber cover 16 and the capsule base 15 is formed by injection molding while the movable contact piece 13 and the fixed contact piece 14 are fixed to the capsule base 15. An insulating elastic member 17 is disposed between the movable contact piece 13 and the stationary contact piece 14 for assisting and correcting deformation and rebound of the movable contact piece 13 and the stationary contact piece 14. The movable contact piece 13 and the static contact piece 14 are provided with contacts 9. The movable contact piece 13 and the stationary contact piece 14 are configured to contact each other by means of respective contacts 9.

According to an alternative embodiment, the capsule seat 15 is made of insulating material by means of injection moulding. The waterproof rubber sleeve 16 is integrally made of an insulating, heat-resistant, and friction-resistant elastic material.

According to an alternative embodiment, a waterproof pad 2 made of an insulating material is provided on the upper cover 3. The waterproof pad 2 is configured to cover a portion of the upper cover 3 and expose the receptacle 4 for cooperation with a consumer plug to prevent water from entering the compartment 5 through a gap between the consumer plug and the upper cover 3 while blocking communication of water between the plug pins on the surface of the upper cover 3 in the case where the consumer plug is inserted into the receptacle 4.

According to an alternative embodiment, the upper cover 3 is provided with a polygonal waterproof structure 27 made of insulating material for cooperating with a rubber mat mounted on the consumer plug to prevent water from entering the compartment 5 through a gap between the consumer plug and the upper cover 3 in case the consumer plug is inserted into the jack 4, while blocking the communication of water between the plug pins on the surface of the upper cover 3.

According to an alternative embodiment, between the live line of the power supply and the lock member 10 in the compartment 5 of the safety socket module corresponding to the live line, there are connected in series at least two watertight electrical connection switches 7 controlled by the lock members 10 in the different compartments 5. At least one waterproof electrical connection switch 7 is connected in series between the neutral line of the power supply and the lock control member 10 in the compartment 5 of the safety socket module corresponding to the neutral line.

According to an alternative embodiment, there are at least two waterproof electrical connection switches 7 in series between the live wire of the power supply and the lock member 10 in the compartment 5 of the safety socket module corresponding to the live wire, controlled by the lock member 10 in a different compartment 5, and at least two waterproof electrical connection switches 7 in series between the neutral wire of the power supply and the lock member 10 in the compartment 5 of the safety socket module corresponding to the neutral wire, controlled by the lock member 10 in a different compartment 5.

According to an alternative embodiment, the upper cover 3 is provided with a live socket 41 corresponding to the live pin of the consumer plug and a neutral socket 42 corresponding to the neutral pin of the consumer plug. The safety outlet module comprises a live compartment 51 disposed in the housing 1 below the live jack 41 and a neutral compartment 52 disposed in the housing 1 below the neutral jack 42. Two waterproof electrical connection switches 7 are provided in the live compartment 51 and the neutral compartment 52, respectively, to form a four-switch controlled protection circuit.

According to an alternative embodiment, the upper cover 3 is provided with a live jack 41 corresponding to the live pin of the consumer plug, a neutral jack 42 corresponding to the neutral pin of the consumer plug and a ground jack 43 corresponding to the ground pin of the consumer plug. The safety outlet module comprises a live compartment 51 disposed below the live jack 41 in the housing 1, a neutral compartment 52 disposed below the neutral jack 42 in the housing 1 and an earth compartment 53 disposed below the earth jack 43 in the housing 1. A total of four watertight electrical connection switches 7 are provided in the live compartment 51, the neutral compartment 52 and the earth compartment 53 to form a four-switch controlled protection circuit.

According to an alternative embodiment, the upper cover 3 is provided with three live wire sockets 41 corresponding to the live wire pins of the consumer plug and one ground wire socket 43 corresponding to the ground wire pins of the consumer plug. The safety jack module comprises a live compartment 51 disposed in the housing 1 below the corresponding live receptacle 41 and a ground compartment 53 disposed in the housing 1 below the ground receptacle 43. Between the lock members 10 in the live and live compartments 51 of the power supply there are connected in series at least two watertight electrical connection switches 7 controlled by the lock members 10 in the different compartments 5. A total of six watertight electrical connection switches 7 are provided in the live compartment 51 and the earth compartment 53 to form a six-switch controlled protection circuit.

According to an alternative embodiment, the lock member 10 is made of conductive material by means of integral moulding and comprises a push paddle 101 arranged perpendicularly to the bottom face of the compartment 5 and a fixing clip portion comprising a pair of fixing jaws 102; the pushing shifting piece 101 and the plane of the fixed clamp part are vertical to each other; the push paddle 101 has a bend near the end with a first bend 104 against the waterproof electrical connection switch 7 and a second bend 105 towards the pin, the gap of the push paddle 101 being dimensioned to fit the width of the pin. When the pin is inserted, the pin touches the second bending part 105, the distance of the transverse movement of the second bending part 105 is abutted to the waterproof electric connection switch 7 through the first bending part 104 and is transmitted to the movable contact piece 13 in the waterproof electric connection switch 7, and the distance just enables the movable contact piece 13 to be in good contact with the static contact piece 14. So that the push-type plectrum 101 only biases the movable contact piece 13 to contact the fixed contact piece 14 under the condition that the pins with the standard specified size are inserted into the jack 4, but cannot bias the movable contact piece 13 to contact the fixed contact piece 14 under the condition that the pins or other conductors with the standard specified size are inserted into the jack 4, plays a role of electric shock prevention, and resets when the pins are pulled out from the jack 4;

the two fixing jaws 102 are opposed to each other, each fixing jaw 102 is formed with a bent portion 106 facing the pin near the end, and the distance between the two fixing jaws 102 is set to a size that fits the thickness of the pin so that the pin is clamped by the fixing jaw 102 through the bent portion 106 when inserted into the insertion hole 4 to prevent contact failure and is reset when the pin is pulled out from the insertion hole 4. The bending angle and shape of the bending portion 106 can be adjusted by a required clamping degree, for example, the clamping force of the tip bending portion 106 is larger than that of the smooth bending portion 106, and the clamping degree can be adjusted by selecting the proper bending portion 106 in practical use.

According to an alternative embodiment, the bent portion 106 of the fixed jaw 102 is closer to the insertion hole 4 than the bent portion 106 of the push paddle 101 to ensure that the pin is clamped by the pair of fixed jaws 102 before being pushed against the push paddle 101 when inserted into the insertion hole 4, preventing the pin from arcing during insertion.

According to an alternative embodiment, the lock member 10 is made of a conductive material and comprises a push paddle 101 formed in a separate body placed on the compartment 5 and a pair of fixing jaws 102 arranged perpendicularly to the bottom face of the compartment 5.

According to an alternative embodiment, the section of the pusher paddle 101 is configured in a substantially V-shape open downwards, with the top end being a hinge point 103, one side being close to the receptacle 4 and the other side being covered with an insulating bush and abutting against the waterproof electrical connection switch 7. The angle of the two side edges of the push paddle 101 is set to a size that fits the width of the pin, so that the push paddle 101 biases the movable contact piece 13 into contact with the stationary contact piece 14 only in the case where a pin that meets the standard specification size is inserted into the jack 4, and cannot bias the movable contact piece 13 into contact with the stationary contact piece 14 in the case where a pin or other conductor that does not meet the standard specification size is inserted into the jack 4, to play a role of electric shock prevention, and to reset when the pin is pulled out from the jack 4. The two fixing jaws 102 are opposed to each other, each fixing jaw 102 is formed with a bent portion 106 facing the pin near the end, and the distance between the two fixing jaws 102 is set to a size that fits the thickness of the pin so that the pin is clamped by the fixing jaw 102 through the bent portion 106 when inserted into the insertion hole 4 to prevent contact failure and is reset when the pin is pulled out from the insertion hole 4.

The application also discloses a row of inserting includes: the power distribution system comprises a power strip housing, an external power line externally connected to the power strip housing, and an internal power line arranged in the power strip housing. The safety socket module is embedded in the socket shell. The row housing is configured to expose the upper cover 3 of the safety jack module. Each safety receptacle module is connected in parallel to an internal power line. The external power line is connected to the internal power line through a mechanical switch.

According to an alternative embodiment, the mechanical switch comprises: a switch button 252 having a depressed position and a raised position, a push member 253 connected to the switch button 252, and a switch waterproof capsule 254 abutting against the push member 253. The switch waterproof capsule 254 internally includes a switch movable contact 255 and a switch stationary contact 256 opposed to each other. The switching movable contact 255 is connected to one of the external power line and the internal power line, and the switching stationary contact 256 is connected to the other of the external power line and the internal power line. The switch movable contact 255 is configured to contact the switch stationary contact 256 to communicate the external power line and the internal power line by the bias of the pressing member 253 when the switch knob 252 is in the pressed position, and to be away from the switch stationary contact 256 to disconnect the external power line and the internal power line by the retraction of the pressing member 253 when the switch knob 252 is in the lifted position.

According to an alternative embodiment, the mechanical switch comprises two pockets of switch waterproofing gel 254. One of the switch waterproof capsules 254 has its switch movable contact 255 connected to the live line of the external power line and its switch stationary contact 256 connected to the live line of the internal power line. The other switch waterproof capsule 254 has a switch movable contact 255 connected to the neutral line of the external power line and a switch stationary contact 256 connected to the neutral line of the internal power line. Each of the switch waterproof capsules 254 controls the closing and opening of one line.

By virtue of the above technical features, when using the safety jack module, the power strip and the mobile cable reel according to the present application, the insertion of a single jack with a conductor does not cause an electric shock nor an electrification in water, either in a general environment or in water. In the above environment, all jacks are plugged simultaneously with a plurality of conductors, so long as the width and length of the conductors are smaller than the national standard dimensions, there is no risk of electrical contact and short circuits. Before inserting the jack with electrical apparatus plug, waterproof electrical connection switch disconnection, water can get into among safety socket module and the row of inserting through the jack, but can not take place the short circuit. After the plug is inserted into the jack, the waterproof electric connection switch is switched on, but because the plug is sealed by the waterproof pad or the multi-edge waterproof structure between the electric appliance plug and the upper cover, external water cannot enter the safety socket module, and simultaneously, the water communication between the plug pins on the surface of the upper cover is blocked, so that the phenomena of short circuit and electric leakage cannot occur. Therefore, according to the safe socket module of this application, insert row and remove the cable drum and possess waterproof function, can use under the water logging condition.

In one embodiment, as shown in fig. 5, the waterproof electrical connection switch of this embodiment includes: the isolating waterproof bin is constructed into a full-sealing structure and is provided with at least one flexible surface capable of generating elastic deformation, the movable contact piece 13 is constructed to generate deformation to contact the static contact piece 14 when the flexible surface is extruded by external force so as to switch on the waterproof electric connection switch, and the movable contact piece 13 resets after the external force is withdrawn, is far away from the static contact piece 14 and is disconnected from the waterproof electric connection switch.

In one arrangement, as shown in figures 4 and 7, the waterproof electrical connection switch is mounted in its entirety as a separate electrical connection switch in the compartment 5 of the socket, the flexible face is configured such that when a prong of a standard width or standard width and thickness is inserted into the receptacle, the prong acts on the lock member 10 to bias the flexible face to a standard deformation, the movable contact 13 is configured to move laterally or outwardly the standard deformation by a standard deformation distance to bias the stationary contact 14 to switch on the waterproof electrical connection switch when the flexible face is deformed, and to move the movable contact away from the stationary contact 14 to switch off the waterproof electrical connection switch when the standard deformation of the flexible face is restored, and the lock member 10 is configured to cause the standard deformation of the lock member 10 and generate a standard movement laterally or outwardly to bias the waterproof electrical connection switch to switch on when the standard prong is inserted into the receptacle.

In one scheme, as shown in fig. 4 and 7, the isolated waterproof bin is a waterproof capsule 12 and comprises a capsule base 15 and a waterproof rubber sleeve 16 fixed on the capsule base 15; the movable contact piece 13 and the fixed contact piece 14 are provided inside the waterproof rubber cover and fixed to the capsule base 15, the movable contact piece 13 and the fixed contact piece 14 are provided with the contacts 9, and the movable contact piece 13 and the fixed contact piece 14 are configured to contact each other by means of the respective contacts 9. In one scheme, as shown in fig. 5, an insulating elastic member 17 is disposed between the movable contact piece 13 and the fixed contact piece 14 to assist and correct deformation and rebound of the movable contact piece 13 and the fixed contact piece 14. In one scheme, as shown in fig. 4 and 7, the waterproof electric connection switch is provided with a conductive connecting piece 8, and a movable contact piece 13 or a static contact piece 14 in the isolation waterproof bin is integrally formed with the corresponding conductive connecting piece 8; or the movable contact piece 13 or the static contact piece 14 in the isolated waterproof bin is electrically connected with the corresponding independent conductive connecting piece 8. In one scheme, the conductive connecting piece 8 is an insulated wire, a movable contact piece 13 or a static contact piece 14 in the isolation waterproof bin is connected with one end of the corresponding insulated wire, the connecting part is subjected to injection molding to form a capsule base 15, and the other end of the insulated wire penetrates out of the capsule base 15. In one solution, the conductive connection 8 of the waterproof electrical connection switch is configured to make the electrical circuit of the same compartment 5 conductive when the waterproof electrical connection switch is switched on, by being electrically connected with the lock member 10 of the compartment 5 for plugging in the pins; and/or the conductive connection member 8 of the waterproof electrical connection switch is configured to electrically connect with the lock member 10 for the plug pin of the other compartment 5 to conduct the circuit of the other compartment 5 when the waterproof electrical connection switch is turned on. In one solution, the waterproof electrical connection switch is waterproofed by covering the connection with other conductors at the bottom of the compartment 5 and the exposed part of the conductor with a waterproof insulating material.

In one aspect, as shown in fig. 21 to 22 and 26 to 27, there is described a waterproof mechanical switch based on the waterproof electrical connection switch, including: a switch button 252 having a pressed position and a lifted position, a push member 253 connected to the switch button 252, a switch waterproof capsule 254 abutting against the push member 253, wherein the switch waterproof capsule 254 internally includes a switch movable contact 255 and a switch stationary contact 256 opposing each other; the switching movable contact 255 is connected to one of the external power line and the internal power line, and the switching stationary contact 256 is connected to the other of the external power line and the internal power line; and the switch movable contact 255 is configured to contact the switch stationary contact 256 to communicate the external power line and the internal power line by the bias of the pressing member 253 when the switch knob 252 is in the pressed position, and to be away from the switch stationary contact 256 to disconnect the external power line and the internal power line by the retraction of the pressing member 253 when the switch knob 252 is in the lifted position. In one version, the mechanical switch includes two switch waterproof capsules 254; one of the switch waterproof capsules has a switch movable contact 255 connected to the live line of the external power line and a switch stationary contact 256 connected to the live line of the internal power line; and the switch movable contact 254 of another switch waterproof capsule is connected to the zero line of the external power line, and the switch static contact 256 thereof is connected to the zero line of the internal power line; each of the switch waterproof capsules 254 controls the closing and opening of one line.

The waterproof electrical connection switch in the present embodiment may be supplemented by corresponding structures in other embodiments, and the lock control member and the like in the present embodiment may be supplemented by or replaced by corresponding structures in other embodiments.

In one embodiment, it is described separately that the lock member is configured to cause a standard deformation of the lock member and a standard movement laterally or outwardly to bias the waterproof electrical connection switch to switch on when the standard prong is inserted into the receptacle. Compared with a scheme that the conductor directly acts on the electric connection switch without the locking component, the scheme of the embodiment has higher requirement on the standard property of the conductor, and the possibility that the waterproof electric connection switch is conducted by a pin which is not a plug is extremely low, so that the scheme that the pin is connected with a power supply and is realized by the locking component which causes the standard movement can lead to better anti-touch performance.

In one solution, the prong is disengaged from the lock control member when the prong is pulled out of the insertion hole, so that the lock control member is no longer deformed and is away from the waterproof electrical connection switch, and the waterproof electrical connection switch is reset. In one version, the standard pins are pins of a plug having a standard width or a standard thickness or both.

In one solution, as shown in fig. 4, the lock member 10 is made of a conductor material and includes a push paddle 101 and a fixing clip portion arranged perpendicularly to the bottom surface of the compartment 5, the fixing clip portion including a pair of fixing jaws 102; the pushing shifting piece 101 and the plane of the fixed clamp part are vertical to each other; the push paddle 101 has a bend near the end with a first bend 104 against the waterproof electrical connection switch and a second bend 105 towards the pin, the gap of the push paddle 101 being dimensioned to fit the width of the pin, such that the push paddle 101 biases the movable contact piece 13 into contact with the stationary contact piece 14 only if a pin of a standard specified size is inserted into the jack, but fails to bias the movable contact piece into contact with the stationary contact piece 14 if a pin or other conductor of a non-standard specified size is inserted into the jack and resets when the pin is extracted from the jack; and as shown in fig. 25, two fixing jaws 102 are opposed to each other, each fixing jaw 102 is formed with a bent portion 106 facing the pin near an end portion, and a distance between the two fixing jaws 102 is set to a size fitting the thickness of the pin so that the pin is gripped by the fixing jaw 102 through the bent portion 106 when inserted into the insertion hole and is reset when the pin is extracted from the insertion hole. In one arrangement, the bent portion of the fixed jaw 102 is closer to the insertion hole than the bent portion of the push paddle 101 to ensure that the pin is clamped by the pair of fixed jaws 102 before pushing the push paddle 101 when inserted into the insertion hole.

In one solution, as shown in fig. 7, the lock member 10 is made of a conductor material and includes a push paddle 101 formed in a separate body placed on the compartment 5 and a pair of fixing jaws 102 arranged perpendicular to the bottom surface of the compartment 5; the section of the pushing poking sheet 101 is configured into a roughly V-shaped structure with a downward opening, the top end of the pushing poking sheet is a hinge point 103, one side edge is close to the jack, and the other side edge is covered with an insulating bush and abuts against a waterproof electric connection switch; the angle of both side edges of the push paddle 101 is set to a size that fits the width of the pin, so that the push paddle 101 biases the movable contact piece 13 into contact with the stationary contact piece 14 only in the case where a pin that meets the standard specification size is inserted into the jack, and cannot bias the movable contact piece 13 into contact with the stationary contact piece 14 in the case where a pin or other conductor that does not meet the standard specification size is inserted into the jack, and is reset when the pin is pulled out of the jack; and as shown in fig. 4, two fixing clips 102 are opposed to each other, each fixing clip 102 is formed with a bent portion 106 facing the pin near an end portion, and a distance between the two fixing clips 102 is set to a size fitting the thickness of the pin so that the pin is gripped by the fixing clip 102 through the bent portion 106 when inserted into the insertion hole and is reset when the pin is extracted from the insertion hole. In one arrangement, the bent portion of the fixed jaw 102 is closer to the insertion hole than the contact portion of the push paddle 101 with the pin, so as to ensure that the pin is clamped by the pair of fixed jaws 102 before being pushed to push the push paddle 101 when being inserted into the insertion hole.

In one solution, the lock member 10 is provided in the compartment 5 and aligned with the insertion holes, the number of compartments 5 corresponds to the number of insertion holes, each compartment 5 formed in the casing is provided below the corresponding insertion hole, and the inside of the compartment 5 is accessible from the outside of the casing via the insertion holes.

The lock member in the present embodiment may be supplemented by the corresponding structure in the other embodiments, and the structure such as the waterproof electrical connection switch in the present embodiment may be supplemented by or replaced by the corresponding structure in the other embodiments.

In one embodiment, as shown in fig. 13, which separately recites a first three-hole safety receptacle, comprising a housing 1, a top cover 3 covering the housing and provided with three jacks 4, the top cover being provided with one live jack corresponding to a live pin of a consumer plug, one neutral jack corresponding to a neutral pin of a consumer plug and one ground jack corresponding to a ground pin of a consumer plug, compartments 5, the number of which corresponds to the number of jacks, each compartment 5 formed in the housing 1 being disposed below a corresponding jack and the interior of the compartment 5 being accessible from the outside of the housing 1 via the jacks, the compartment 5 comprising a live compartment 51 disposed below the live jack in the housing 1, a neutral compartment 52 disposed below the neutral jack in the housing and a ground compartment 53 disposed below the ground jack in the housing, a waterproof electrical connection switch 7, it sets up in the compartment as independent electric connection switch, a closed and disconnection for circuit between control power and the electrical apparatus plug, 51 sets up two waterproof electric connection switches in the live wire compartment, set up a waterproof electric connection switch in zero line compartment 52, set up a waterproof electric connection switch in the ground wire compartment 53, waterproof electric connection switch's switch structure is enclosed in the inside of the confined space that waterproof material formed, and when waterproof electric connection switch place the jack of compartment 5 inserts the base pin, the base pin acts on waterproof electric connection switch and makes the switch structure contact and close, and when all waterproof electric connection switches in each compartment 5 are closed, with electrical apparatus and power switch-on.

In this embodiment is also separately described a second three-hole safety socket comprising a housing 1, a top cover 3 covering the housing and provided with three jacks 4, the top cover being provided with one live jack corresponding to the live pin of a consumer plug, one neutral jack corresponding to the neutral pin of a consumer plug and one ground jack corresponding to the ground pin of a consumer plug, compartments 5, the number of which corresponds to the number of jacks, each compartment 5 formed in the housing 1 being provided below a corresponding jack and the interior of the compartment 5 being accessible from the outside of the housing 1 via the jacks, the compartment 5 comprising a live compartment 51 provided below the live jack in the housing 1, a neutral compartment 52 provided below the neutral jack in the housing and a ground compartment 53 provided below the ground jack in the housing, a waterproof electrical connection switch 7 provided in the compartment as a separate electrical connection switch, a closed and disconnection for controlling power and with the circuit between the electrical apparatus plug, set up a waterproof electrical connection switch in the live wire compartment 51, set up two waterproof electrical connection switches in the zero line compartment 52, set up a waterproof electrical connection switch in the ground wire compartment 53, waterproof electrical connection switch's switch structure is enclosed in the inside of the confined space that waterproof material formed, and when inserting into participating in at the jack of waterproof electrical connection switch place compartment 5, it makes the switch structure contact and be closed to participate in the effect on waterproof electrical connection switch, and when all waterproof electrical connection switches in each compartment 5 are closed, with electrical apparatus and power switch-on.

The waterproof electrical connection switch according to another embodiment can be used independently in the socket according to this embodiment, and the waterproof electrical connection switch is closed by inserting the plug pin into the insertion hole, thereby controlling the plug pin to be connected to the power supply. For both of the three-hole safety sockets of this embodiment, it is possible to close one waterproof electrical connection switch by inserting a conductor in one compartment, however, if it is desired to close two waterproof electrical connection switches, the conductor inserted into the jack must have great similarity to a standard pin to be realized, and this possibility is extremely low to make the two waterproof electrical connection switches conductive by a pin other than a plug, so that a scheme in which the two waterproof electrical connection switches are closed to connect the pin to the power source will result in better anti-electric-shock performance. Therefore, if two waterproof electric connection switches are arranged in each compartment, the electric shock resistance is better. However, the three-jack socket is limited by the constraints of arrangement of jacks, pitch of the jacks and the like in the standard of the three-jack socket, two waterproof electric connection switches are arranged in one of the live wire compartment or the zero wire compartment, and the other compartments are provided with one waterproof electric connection switch, so that the electric shock resistance is improved as much as possible under the condition that the standard is met.

In one solution, in order to overcome the defect that the connection of the live wire and the neutral wire with the plug pin cannot be controlled by two switches respectively under the condition that the standard is required to be met, the following solution is further proposed: the live wire of the power supply is connected with the components in the live wire compartment 51, two waterproof electric connection switches positioned in different compartments are connected in series between the components in the live wire compartment 51 and the live wire compartment 51, the components in the live wire compartment 51 are constructed to be connected with the live wire pin through the components when the live wire plug hole is inserted into the live wire pin, and the live wire pin is communicated with the live wire of the power supply through the waterproof electric connection switches in the two different compartments; the power supply zero line is connected with components in the zero line compartment 52, and another two waterproof electric connection switches located in different compartments are connected in series between the components in the power supply zero line and the zero line compartment 52, the components in the zero line compartment 52 are constructed to be connected with the zero line pin through the components when the zero line jack is inserted into the zero line pin, and the zero line pin is connected with the power supply zero line through the waterproof electric connection switches in the different compartments. In the scheme, the connection of the live wire and the zero wire which have high requirements on electric shock prevention and the pins is controlled by two chambers and two switches, the socket not only has the advantage that the electric shock prevention performance can be improved by arranging two switches in one of the three compartments, but also has the conduction possibility under the condition that at least two compartments are provided with conductor insertion jacks, and the electric shock prevention performance of the socket is further improved.

In one approach, a specific internal circuit configuration is described for the first three-jack mount jack, which improves the shock resistance in the case of a three-jack standard. The live power line is accessed by a waterproof electric connection switch in the live compartment 51 and is connected with a component in the live compartment 51, the waterproof electric connection switch in the live compartment 51 is connected with the waterproof electric connection switch in the ground compartment 53 in series, the component in the live compartment 51 is configured to be connected with the live pin through the waterproof electric connection switch when the live pin is inserted into the live jack, and the live pin is communicated with the live power line through the waterproof electric connection switches in the live compartment 51 and the ground compartment 53; the power supply zero line is accessed by the waterproof electric connection switch in the zero line compartment 52 to be connected with the component in the zero line compartment 52, just waterproof electric connection switch in the zero line compartment 52 establishes ties another waterproof electric connection switch in the live wire compartment 51, and the component in the zero line compartment 52 is constructed and is passed through when the zero line jack inserts the zero line and participates in, and participates in with the zero line and the switch-on of power supply zero line through the waterproof electric connection switch in zero line compartment 52 and the live wire compartment 51.

In one approach, a specific internal circuit configuration is described for the second three-jack mount socket, which improves the shock resistance in the case of a three-jack socket standard. The power supply neutral wire is accessed by a waterproof electric connection switch in the neutral wire compartment 52 and is connected with a component in the neutral wire compartment 52, the waterproof electric connection switch in the neutral wire compartment 52 is connected with the waterproof electric connection switch in the ground wire compartment 53 in series, the component in the neutral wire compartment 52 is constructed to be connected with the neutral wire pin through the component when the neutral wire plug hole is inserted with the neutral wire plug, and the neutral wire plug pin is connected with the power supply neutral wire through the waterproof electric connection switches in the neutral wire compartment 52 and the ground wire compartment 53; the live power is accessed by the waterproof electrical connection switch in the live wire compartment 51 to be connected with the component in the live wire compartment 51, and another waterproof electrical connection switch in the waterproof electrical connection switch series connection zero line compartment 52 in the live wire compartment 51, the component in the live wire compartment 51 is constructed to be inserted the live wire and is participated in through the component connection live wire when participating in at the live wire jack, and participates in the live wire with the live power switch-on through the waterproof electrical connection switch in zero line compartment 52 and the live wire compartment 51.

In one scheme, the connecting part of the waterproof electric connection switch and other conductors in the bottom of the shell and the exposed part of the conductor are covered by waterproof insulating materials for waterproof treatment, and the waterproof electric connection switch is connected with another waterproof electric connection switch or a component through the conductor.

The structures such as the waterproof electrical connection switch, the lock member, and the like in the present embodiment may be supplemented or replaced with the corresponding structures in the other embodiments.

Although the application is illustrated and described herein with reference to specific embodiments, the application is not intended to be limited to the details shown. Rather, various details of the application may be modified within the scope and equivalents of the claims.

Claims (7)

1. A lock control member, characterized by being provided in a compartment and aligned with an insertion hole, for gripping a prong of a consumer plug and biasing a waterproof electrical connection switch (7) in a case where the prong is inserted into the insertion hole (4), and disengaging from the prong and resetting the waterproof electrical connection switch (7) when the prong is pulled out from the insertion hole (4).

2. A lock control member according to claim 1, characterized in that the prong is disengaged from the lock control member when the prong is pulled out of the insertion hole (4), so that the lock control member is no longer deformed and is away from the waterproof electrical connection switch (7), resetting the waterproof electrical connection switch (7).

3. A lock member according to any one of claims 1-2, characterized in that the lock member (10) is made of a conductor material and includes a push paddle (101) and a fixing clip portion arranged perpendicularly to the bottom surface of the compartment, the lock member (10) being made of a conductor material by integral molding, the fixing clip portion including a pair of fixing jaws (102), the push paddle (101) and the fixing clip portion lying in planes perpendicular to each other, the push paddle (101) having a bend near an end portion, the bend having a first bend (104) abutting against the waterproof electrical connection switch (7), and having a second bend (105) facing the pin, a gap of the push paddle (101) being set to a size fitting the width of the pin.

4. A lock control member according to claim 3, characterized in that the bent portion of the fixing jaw (102) is located closer to the insertion hole than the bent portion of the push paddle (101) to ensure that the pin is gripped by the pair of fixing jaws (102) and then pushed against the push paddle (101) when inserted into the insertion hole.

5. A lock component according to any one of claims 1-2, characterized in that the lock component (10) is made of a conductor material and includes a push paddle (101) hinged to the compartment (5) and a pair of fixing jaws (102) arranged perpendicularly to the bottom surface of the compartment, the fixing jaws (102) being formed near the ends with a bend (106) towards the pin, the distance between the fixing jaws (102) being dimensioned to match the thickness of the pin such that the pin is gripped by the fixing jaws (102) through said bend (106) when inserted into the plug hole (4) and is reset when the pin is pulled out of the plug hole (4), the cross-section of the push paddle (101) being configured in a substantially V-shape with a downward opening, the top end of which is a hinge point (103), one side being close to the plug hole (4), the other side being covered with an insulating bush and abutting against the waterproof electrical connection switch (7), the included angle of the two side edges of the pushing poking sheet (101) is set to be matched with the width of the pin.

6. A lock control member according to claim 5, characterized in that the bent portion of the fixing jaw (102) is located closer to the insertion hole than the contact portion of the push paddle (101) with the pin, to ensure that the pin is gripped by the pair of fixing jaws (102) and then pushed against the push paddle (101) when inserted into the insertion hole.

7. A lock member according to any one of claims 1-2, characterized in that the lock member is provided in the compartment (5) and aligned with the insertion holes, the number of compartments (5) corresponds to the number of insertion holes, each compartment (5) formed in the casing is provided below the corresponding insertion hole, and the inside of the compartment (5) is accessible from the outside of the casing via the insertion holes.

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