Disclosure of Invention
The technical problem is as follows:
the traditional socket and the plug are connected and separated in a troublesome way, and the connection between the socket and the plug is unstable, so that the stability of power utilization is poor, and the standby power consumption of an electric appliance is low.
In order to solve the problems, the embodiment designs a low-power-consumption quick-connection type energy-saving socket, which comprises a socket and an electrifying plug, wherein a disconnecting device is arranged in the electrifying plug, an electrifying plate is fixedly arranged on the right end surface of the electrifying plug, an electric wire is electrically connected to the left end surface of the electrifying plate, the other end of the electric wire is connected with electrical equipment, an electrifying block is electrically arranged on the right end surface of the electrifying plate, two electrifying cavities which are the same up and down are arranged in the socket, locking devices are circumferentially arranged on the upper and lower electrifying cavities, the locking devices are connected with the disconnecting device to lock and connect the electrifying plug and the socket, an electrifying block is rotatably arranged in the electrifying cavity, a plugging groove is arranged on the electrifying block, an extruding block is fixedly arranged on the right end surface of the electrifying block, an electrifying device is arranged on the right side of the electrifying, the extrusion block controls the power connection device to be connected with the insertion groove in an insertion mode, so that the insertion groove is powered on, a locking groove is formed in the power connection block, a reset device is arranged on the front side of the power connection cavity, and the locking groove is connected with the reset device in an insertion mode to lock the power connection block; the power-on plug is connected with the power connection block in an inserted mode and then rotates, the power-on plug is connected with the socket through the locking device, the power connection device enables the power-on plug to be powered on, and then electrical equipment is powered on through the wires for use.
Preferably, the upside connect to be equipped with bilateral symmetry's double insertion hole on the electric piece, the upside the circular telegram piece with double insertion hole grafting cooperation, the downside connect to be equipped with three jacks on the electric piece, the downside the circular telegram piece with three jack grafting cooperation, just double insertion hole with three jacks respectively with pass through conductor wire electric connection between the inserting groove.
The disassembly and assembly device comprises pressing grooves which are symmetrical up and down, the right sides of the pressing grooves are communicated with pressing rotating cavities, pressing rotating rods are rotatably arranged in the pressing rotating cavities, the left ends of the pressing rotating rods extend into the pressing grooves, rotating springs are fixedly arranged between the pressing rotating rods and the pressing rotating cavities, disassembly and assembly grooves are communicated with the right sides of the pressing rotating cavities, disassembly and assembly sliders are slidably arranged in the disassembly and assembly grooves, and one ends, close to each other, of the disassembly and assembly sliders are hinged to the pressing rotating rods; the disassembling groove and the locking device are clamped to connect the power-on plug and the socket, and the disassembling groove and the locking device can be separated by pressing the pressing rotating rod, so that the connection between the power-on plug and the socket is released.
The locking device comprises two arc rotating cavities which are staggered up and down, a locking sliding block is arranged in each arc rotating cavity in a sliding mode, a telescopic spring is fixedly arranged in each locking sliding block and between each locking sliding block and each arc rotating cavity, a locking sliding chute is arranged in each locking sliding block, a locking clamping block is arranged in each locking sliding chute in a sliding mode, a pressure spring is fixedly arranged between each locking clamping block and each locking sliding chute, a through groove is formed between each locking sliding chute and each arc rotating cavity in a communicating mode, a fixing block is fixedly arranged on one end wall, far away from the locking sliding block, of each arc rotating cavity, and each fixing block can penetrate through the corresponding through groove and extend into the corresponding locking; the locking clamping block can be inserted into the detaching groove, the electrified plug is connected with the locking sliding block, the electrified plug is rotated to enable the locking sliding block to rotate along with the electrified plug, at the moment, the fixing block extends into the locking sliding groove, the pressing rotating rod cannot drive the locking clamping block to exit from the detaching groove, and the electrified plug cannot be separated from the locking sliding block, so that the connection stability is guaranteed.
The electric connection device comprises an electric connection cavity communicated with the electric connection cavity, an electric connection sliding block is arranged in the electric connection cavity in a sliding mode, first reset components are fixedly arranged on the electric connection sliding block in an up-down symmetrical mode, a plug-in electric block is electrically connected to the left end face of the electric connection sliding block, an electric connection wire is electrically connected to the right end face of the electric connection sliding block, the other end of the electric connection wire is electrically connected with an external commercial power, an L-shaped shifting rod is rotatably arranged in the electric connection cavity, the left end of the shifting rod extends into the electric connection cavity, the left end of the shifting rod can be abutted to the extrusion block, the front end of the shifting rod is abutted to the right end face of the electric connection sliding block, and; the electric connection block rotates to drive the shifting lever to rotate through the extrusion block, the electric connection block is connected with the insertion groove in an insertion mode, and the insertion groove is electrified through the electric connection wire.
Wherein, resetting means include with connect the communicating slide opening that resets of electric cavity, it is equipped with the slider that resets to slide in the slide opening that resets, the slider that resets can with locking groove joint, the slider front end that resets with it has set firmly coupling spring to reset between the slide opening, be equipped with the butt groove in the slider that resets, it is equipped with the manipulation chamber with external intercommunication to reset slide opening left side, it is equipped with the manipulation piece to manipulate the intracavity slip, it stretches into to manipulate the piece right-hand member the butt inslot, it extends to external space to manipulate the piece left end, it has set firmly the second subassembly that resets to manipulate piece front end face, the slider that resets with locking groove joint can with the position locking of electricity piece, press right the manipulation piece can make the slider that resets with the locking groove breaks away from, makes connect the electricity piece free rotation.
The invention has the beneficial effects that: according to the energy-saving socket, the power-off and the power-on of the power-on plug can be controlled through the rotation of the power-on plug, the operation is simple and convenient, when the power-on plug is not powered on, the stable connection between the electric equipment and the socket can be guaranteed through the disconnecting device, the power-on operation is convenient, the power-on stability during the power-on is improved, and secondly, even if the electric equipment is connected with the socket, the power-off plug can be in a power-off state, so that the standby power consumption during the connection between the electric equipment and the socket is reduced.
Detailed Description
The invention will now be described in detail with reference to fig. 1-5, for ease of description, the orientations described below will now be defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.
The invention relates to a quick-connection energy-saving socket with low power consumption, which is mainly used for the quick-connection type plug-in power-on work of the socket, and the invention is further explained by combining the attached drawings of the invention:
the invention relates to a low-power-consumption quick-connection type energy-saving socket, which comprises a socket 10 and an electrified plug 47, wherein a disconnecting device 601 is arranged in the electrified plug 47, an electrified plate 50 is fixedly arranged on the right end face of the electrified plug 47, the left end face of the electrified plate 50 is electrically connected with an electric wire 51, the other end of the electric wire 51 is connected with electrical equipment, an electrified block 48 is electrically arranged on the right end face of the electrified plate 50, two electric cavities 11 which are the same up and down are arranged in the socket 10, locking devices 602 are circumferentially arranged on the upper electric cavity 11 and the lower electric cavity 11, the locking devices 602 are connected with the disconnecting device 601 to lock and connect the electrified plug 47 with the socket 10, an electric connection block 12 is rotatably arranged in the electric cavity 11, an insertion groove 26 is arranged on the electric connection block 12, a pressing block 38 is fixedly arranged on the right end face of the electric connection block 12, and an electric connection device 603 is arranged on the, the extrusion block 38 abuts against the power connection device 603, the extrusion block 38 controls the power connection device 603 to be connected with the insertion groove 26 in an insertion manner, so that the insertion groove 26 is powered on, the power connection block 12 is provided with a locking groove 25, the front side of the power connection cavity 11 is provided with a reset device 604, and the locking groove 25 is connected with the reset device 604 in an insertion manner, so that the power connection block 12 can be locked; after the power-on plug 47 is plugged with the power-on block 12, the power-on plug 47 is rotated, the power-on plug 47 is connected with the socket 10 through the locking device 602, and the power-on device 603 powers on the power-on plug 47, so that the electrical equipment is powered on for use through the wire 51.
Beneficially, the bilateral-symmetric double-jack 14 is disposed on the upper-side power connection block 12, the upper-side power connection block 48 is in plug-in fit with the double-jack 14, the lower-side power connection block 12 is disposed with the three-jack 13, the lower-side power connection block 48 is in plug-in fit with the three-jack 13, and the double-jack 14 and the three-jack 13 are electrically connected to the plug-in slot 26 through the conductive wire 27.
According to the embodiment, the following detailed description is provided for the disconnecting device 601, where the disconnecting device 601 includes pressing grooves 58 that are symmetrical up and down, the right sides of the pressing grooves 58 are communicated with each other to form a pressing rotating cavity 55, the pressing rotating cavity 55 is rotatably provided with a pressing rotating rod 56, the left end of the pressing rotating rod 56 extends into the pressing groove 58, a rotating spring 57 is fixedly arranged between the pressing rotating rod 56 and the pressing rotating cavity 55, the right side of the pressing rotating cavity 55 is communicated with a disconnecting groove 52, a disconnecting slider 53 is slidably arranged in the disconnecting groove 52, and one end of the disconnecting slider 53, which is close to each other, is hinged to the pressing rotating rod 56; the detachable groove 52 is connected with the locking device 602 in a clamping manner, so that the power-on plug 47 can be connected with the socket 10, and the detachable groove 52 can be separated from the locking device 602 by pressing the pressing rotating rod 56, so that the power-on plug 47 is disconnected with the socket 10.
According to an embodiment, a detailed description is given below on a locking device 602, where the locking device 602 includes two arc-shaped rotating cavities 15 staggered up and down, a locking slider 16 is slidably disposed in each arc-shaped rotating cavity 15, a telescopic spring 22 is fixedly disposed between each locking slider 16 and each arc-shaped rotating cavity 15, a locking chute 17 is disposed in each locking slider 16, a locking fixture block 18 is slidably disposed in each locking chute 17, a pressure spring 19 is fixedly disposed between each locking fixture block 18 and each locking chute 17, a through groove 20 is communicated between each locking chute 17 and each arc-shaped rotating cavity 15, a fixing block 24 is fixedly disposed on one end wall of each arc-shaped rotating cavity 15 away from each locking slider 16, and each fixing block 24 can penetrate through the through groove 20 and extend into each locking chute 17; the locking fixture block 18 can be inserted into the detaching groove 52, the electrified plug 47 is connected with the locking slide block 16, the electrified plug 47 is rotated to enable the locking slide block 16 to rotate along with the electrified plug, at the moment, the fixing block 24 extends into the locking slide groove 17, the pressing rotating rod 56 is pressed to prevent the locking fixture block 18 from being driven to exit from the detaching groove 52, and the electrified plug 47 cannot be separated from the locking slide block 16, so that the connection stability is guaranteed.
According to an embodiment, a detailed description is given below of an electric device 603, where the electric device 603 includes an electric cavity 29 communicated with the electric cavity 11, an electric slider 33 is slidably disposed in the electric cavity 29, first reset components 37 are symmetrically and fixedly disposed on the electric slider 33, a plug-in electric block 35 is electrically connected to a left end surface of the electric slider 33, an electric wire 32 is electrically connected to a right end surface of the electric slider 33, the other end of the electric wire 32 is electrically connected to an external commercial power, an L-shaped shift lever 30 is rotatably disposed in the electric cavity 29, a left end of the shift lever 30 extends into the electric cavity 11, a left end of the shift lever 30 can abut against the extrusion block 38, a front end of the shift lever 30 abuts against a right end surface of the electric slider 33, and a torsion spring 31 is fixedly disposed between the right end surface of the shift lever 30 and the electric cavity 29; the rotation of the electric connection block 12 can drive the shift lever 30 to rotate through the extrusion block 38, so that the electric connection block 35 is connected with the insertion groove 26 in an insertion manner, and the insertion groove 26 is powered on through the electric connection wire 32.
According to the embodiment, the following detailed description is made on the reset device 604, the reset device 604 includes a reset sliding hole 39 communicated with the power receiving cavity 11, a reset sliding block 40 is slidably disposed in the reset sliding hole 39, the reset sliding block 40 can be connected with the locking groove 25 in a snap-fit manner, a connection spring 41 is fixedly disposed between the front end of the reset sliding block 40 and the reset sliding hole 39, a butting groove 42 is disposed in the reset sliding block 40, an operation cavity 43 is disposed on the left side of the reset sliding hole 39 and communicated with the outside, an operation block 44 is slidably disposed in the operation cavity 43, the right end of the operation block 44 extends into the butting groove 42, the left end of the operation block 44 extends to the outside space, a second reset assembly 45 is fixedly disposed on the front end face of the operation block 44, the reset sliding block 40 and the locking groove 25 are connected in a snap-fit manner to lock the position of the power receiving block 12, and the operation block 44 is pressed rightwards to separate the reset sliding block 40 from the locking groove 25, so that the electrification block 12 rotates freely.
The following describes in detail the usage steps of a low power consumption quick-connect energy saving socket in the present disclosure with reference to fig. 1 to 5:
when the device is used, the position of the electrifying block 48 is aligned with the three jacks 13, the electrifying plug 47 is inserted into the electrifying cavity 11, the locking clamping block 18 extends into the disassembling groove 52 to connect the electrifying plug 47 with the locking slide block 16, at the moment, the electrifying plug 47 is not electrified, then the electrifying plug 47 is rotated to drive the locking slide block 16 to rotate, so that the fixing block 24 extends into the locking chute 17, the electrifying block 12 rotates along with the rotation of the electrifying plug 47, the pressing block 38 presses the shift lever 30 to rotate clockwise when looking down, the electrifying slide block 33 moves leftwards to enable the inserting electric block 35 to be inserted into the inserting groove 26, the inserting groove 26 is electrified, the three jacks 13 are electrified through the conducting wire 27, so that the electrifying block 48 is electrified with the electric wire 51 for the use of electric equipment, at the moment, the rear end of the resetting slide block 40 extends into the locking groove 25 to fix the position of the electrifying block 12, and ensure the, when the power consumption equipment needs to be disconnected, the operating block 44 is pressed rightwards, the reset slider 40 moves forwards to be separated from the locking groove 25, the locking slider 16 rotates reversely under the action of the elastic restoring force of the telescopic spring 22, the power connection block 12 and the power connection plug 47 are driven to rotate reversely to the initial position, the extrusion block 38 is separated from the shift lever 30, the shift lever 30 recovers to the initial position under the action of the torsion spring 31, the plug-in electric block 35 is separated from the plug-in groove 26, the three jacks 13 are powered off, the power failure of the power consumption equipment is controlled, the power connection can be disconnected without separating the power connection plug 47 from the power connection block 12, the power connection plug 47 is ensured to be stably connected with the power connection block 12, the next power connection use is convenient, when the power connection plug 47 needs to be pulled off, the rotating rod 56 is pressed oppositely, the two opposite disconnecting sliders 53 move backwards, the locking fixture block 18 is pushed to exit from the disconnecting groove 52, and then the power-on plug 47 is pulled out to the left.
The invention has the beneficial effects that: according to the energy-saving socket, the power-off and the power-on of the power-on plug can be controlled through the rotation of the power-on plug, the operation is simple and convenient, when the power-on plug is not powered on, the stable connection between the electric equipment and the socket can be guaranteed through the disconnecting device, the power-on operation is convenient, the power-on stability during the power-on is improved, and secondly, even if the electric equipment is connected with the socket, the power-off plug can be in a power-off state, so that the standby power consumption during the connection between the electric equipment and the socket is reduced.
In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.