阅读说明：本技术 一种双直流电源系统的控制设备 (Control equipment of double-direct-current power supply system ) 是由 洪沧龙 于 2020-11-13 设计创作，主要内容包括：本发明提供了一种双直流电源系统的控制设备,其结构包括分线端子、网口、通电机构、接电块、外壳,分线端子后端通过卡扣固定于外壳前端下方,网口外壁完全固定于外壳左侧,通电机构下端外壁嵌套固定于外壳上端内壁,接电块下端通过螺钉固定于外壳上端,本发明在完成装配固定后,通过将通电线连接至接线插座,并通过螺钉穿过通电线并紧定至装配螺母,从而将通电线完全的固定至接线插座,在通电线推动接线插座进行连接装配,会使接线插座下降并且通过承载板推动开合机构的开启,并带动挡板开启对接线插座进行包裹,通过挡板的包裹紧固,避免了连接端口因凝露渗透入而造成接线插座潮湿,导致漏电情况的发生。(The invention provides a control device of a double direct current power supply system, which structurally comprises a branching terminal, a net port, a power-on mechanism, a power-on block and a shell, wherein the rear end of the branching terminal is fixed below the front end of the shell through a buckle, the outer wall of the net port is completely fixed on the left side of the shell, the outer wall of the lower end of the power-on mechanism is embedded and fixed on the inner wall of the upper end of the shell, and the lower end of the power-on block is fixed on the upper end of the shell through a screw, resulting in a leakage condition.)

1. The control equipment of the double-direct-current power supply system structurally comprises a branching terminal (1), a network port (2), a power-on mechanism (3), a power-on block (4) and a shell (5), wherein the rear end of the branching terminal (1) is fixed below the front end of the shell (5) through a buckle, the outer wall of the network port (2) is completely fixed on the left side of the shell (5), the outer wall of the lower end of the power-on mechanism (3) is fixed on the inner wall of the upper end of the shell (5) in an embedded mode, and the lower end of the power-on block (4) is fixed on the upper end of the shell (5) through;

the power-on mechanism (3) is equipped with and connects electric installation (31), assembly nut (32), builds in base (33), assembly casing (34), it is inside in assembly casing (34) upper end to connect the nested assembly of electric installation (31) lower extreme, assembly nut (32) lower extreme builds in and is fixed in assembly casing (34) upper end both sides, it is fixed in assembly casing (34) lower extreme to build in base (33) upper end.

2. The control device of a dual direct-current power supply system according to claim 1, characterized in that: inside wiring socket (a1), isolation mechanism (a2), bottom plate (a3) of being equipped with of power connection device (31), wiring socket (a1) lower extreme is fixed in isolation mechanism (a2) lower extreme through the buckle, isolation mechanism (a2) lower extreme is embedded to be fixed in bottom plate (a3) upper end.

3. The control device of a dual direct-current power supply system according to claim 2, characterized in that: isolation mechanism (a2) comprises loading board (b1), baffle (b2), assembly box (b3), mechanism that opens and shuts (b4), lifter (b5), loading board (b1) lower extreme welded fastening is in lifter (b5) upper end, baffle (b2) right side outer wall activity block in assembly box (b3) left side inner wall, mechanism that opens and shuts (b4) upper end is connected in lifter (b5) lower extreme through the bolt block, lifter (b5) middle section outer wall activity cooperation is in assembly box (b3) upper end inner wall.

4. The control device of a dual direct-current power supply system according to claim 3, characterized in that: opening and shutting mechanism (b4) comprises derived board (c1), arc dish (c2), reset spring (c3), double-layered spring board (c4), connecting axle (c5), derived board (c1) inner wall is embedded to be fixed in arc dish (c2) outer wall, arc dish (c2) upper end right side activity block is inside connecting axle (c5), reset spring (c3) right side welded fastening is in double-layered spring board (c4) left side, double-layered spring board (c4) outer wall interference is fixed in arc dish (c2) right side inner wall.

5. The control device of a dual direct-current power supply system according to claim 4, characterized in that: the connecting shaft (c5) comprises elevating gear (d1), guide rail (d2), axis body (d3), magnetism and inhale ring (d4), kelly (d5), elevating gear (d1) assembles in axis body (d3) inside center completely, guide rail (d2) outer wall is embedded and fixed in the inside left side of axis body (d3), magnetism is inhaled the ring (d4) lower extreme and is fixed in the inside lower extreme of axis body (d3) through the buckle, kelly (d5) right side activity fit elevating gear (d1) lower extreme outer wall.

6. The control device of a dual direct-current power supply system according to claim 5, characterized in that: elevating gear (d1) comprises laminating piece (e1), push rod (e2), magnet holder (e3), connecting rod (e4), flitch (e5), laminating piece (e1) lower extreme is inlayed fixedly in connecting rod (e4) upper end, inside the nested assembly of push rod (e2) right-hand member in laminating piece (e1) left side, magnet holder (e3) upper end inner wall is fixed in connecting rod (e4) lower extreme outer wall through the screw thread, pole (e4) upper end welded fastening is in laminating piece (e1) lower extreme, flitch (e5) left side is inlayed fixedly in push rod (e2) left side.

Technical Field

The invention relates to the field of power supply systems, in particular to control equipment of a double-direct-current power supply system.

Background

The control equipment of the double-direct-current power supply system is double-path power supply applied to a power supply system, resistance values in a main circuit or a control circuit are changed according to a preset sequence, and current in the power supply system is controlled.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides control equipment of a double direct-current power supply system, which solves the problems that the wiring port of the equipment is usually exposed to the outer end, the equipment is arranged at a ventilation position, condensation in the air can cover the surface of the equipment in the early morning, partial condensation can cover the wiring port, the condensation covers the wiring port, the control equipment is easy to leak electricity, and the electronic equipment near the control equipment can be punctured due to the fact that the condensation covers the wiring port with a high probability.

Aiming at the above purpose, the invention is realized by the following technical scheme: the control equipment of the double-direct-current power supply system structurally comprises a branching terminal, a network port, a power-on mechanism, a power-on block and a shell, wherein the rear end of the branching terminal is fixed below the front end of the shell through a buckle;

the power-on mechanism is provided with a power-on device, an assembling nut, an embedded base and an assembling shell, the lower end of the power-on device is embedded and assembled inside the upper end of the assembling shell, the lower end of the assembling nut is fixedly embedded on two sides of the upper end of the assembling shell, the upper end of the embedded base is fixedly embedded on the lower end of the assembling shell, and the two assembling nuts are arranged and distributed on two sides of the upper end of the assembling shell relatively.

Preferably, the power connection device is internally provided with a wiring socket, an isolation mechanism and a bottom plate, the lower end of the wiring socket is fixed at the lower end of the isolation mechanism through a buckle, and the lower end of the isolation mechanism is fixedly embedded at the upper end of the bottom plate.

Preferably, the isolation mechanism comprises a bearing plate, two baffles, an assembly box, an opening and closing mechanism and a lifting rod, wherein the lower end of the bearing plate is welded and fixed at the upper end of the lifting rod, the outer wall of the right side of the baffle is movably clamped and connected with the inner wall of the left side of the assembly box, the upper end of the opening and closing mechanism is connected to the lower end of the lifting rod through a bolt in a clamping manner, the outer wall of the middle section of the lifting rod is movably matched and connected with the inner wall of the upper end of the assembly box, and the two baffles are of arc.

Preferably, the opening and closing mechanism comprises a derivative plate, an arc-shaped disc, a return spring, a spring clamping plate and a connecting shaft, wherein the inner wall of the derivative plate is fixedly embedded in the outer wall of the arc-shaped disc, the right side of the upper end of the arc-shaped disc is movably clamped in the connecting shaft, the right side of the return spring is welded and fixed on the left side of the spring clamping plate, the outer wall of the spring clamping plate is fixed on the inner wall of the right side of the arc-shaped disc in an interference manner, the arc-shaped disc is of a semicircular structure, the number of the arc-shaped discs.

Preferably, the connecting shaft comprises a lifting device, a guide rail, a shaft body, a magnetic attraction ring and a clamping rod, wherein the lifting device is completely assembled in the center of the inside of the shaft body, the outer wall of the guide rail is fixedly embedded in the left side of the inside of the shaft body, the lower end of the magnetic attraction ring is fixed at the lower end of the inside of the shaft body through a buckle, the right side of the clamping rod is movably matched with the outer wall of the lower end of the lifting device, and the clamping rod is of an arc-shaped structure and can be attracted.

Preferably, the lifting device comprises an attaching block, a push rod, a magnetic seat, a connecting rod and an attaching plate, wherein the lower end of the attaching block is fixedly embedded at the upper end of the connecting rod, the right end of the push rod is embedded and assembled inside the left side of the attaching block, the inner wall of the upper end of the magnetic seat is fixed on the outer wall of the lower end of the connecting rod through threads, the upper end of the rod is fixedly welded at the lower end of the attaching block, the left side of the attaching plate is fixedly embedded and clamped at the left side of the push rod, the attaching block is of an inverted triangular structure, and the push rod and the attaching plate are arranged.

Advantageous effects

Compared with the prior art, the invention has the following beneficial effects:

after the assembly and fixation are completed, the electrified wire is connected to the wiring socket, passes through the electrified wire through the screw and is tightly fixed to the assembly nut, so that the electrified wire is completely fixed to the wiring socket, the wiring socket is pushed to be connected and assembled at the electrified wire, the wiring socket is lowered, the opening and closing mechanism is pushed to be opened through the bearing plate, the baffle plate is driven to be opened to wrap the wiring socket, and the moisture of the wiring socket caused by the penetration of condensation into the connecting port is avoided through the wrapping and fastening of the baffle plate, so that the electricity leakage condition is avoided.

Drawings

Fig. 1 is a schematic structural diagram of a control device of a dual dc power supply system according to the present invention.

Fig. 2 is a schematic front view of the energizing mechanism of the present invention.

FIG. 3 is a schematic diagram of a partial sectional structure of the power connection device of the present invention.

Fig. 4 is a right-side structural schematic view of the isolation mechanism of the invention.

Fig. 5 is a schematic structural diagram of the opening and closing mechanism of the invention.

Fig. 6 is a schematic sectional view of the inventive connecting shaft.

Fig. 7 is a schematic structural diagram of the lifting device of the present invention.

In the figure: a distributing terminal-1, a net mouth-2, a power-on mechanism-3, a power-on block-4, a shell-5, a power-on device-31, an assembly nut-32, an embedded base-33, an assembly shell-34, a wiring socket-a 1, an isolation mechanism-a 2, a bottom plate-a 3, a bearing plate-b 1, a baffle-b 2, an assembly box-b 3 and an opening and closing mechanism-b 4, lifting rod-b 5, derivative plate-c 1, arc-shaped disc-c 2, return spring-c 3, clamping spring plate-c 4, connecting shaft-c 5, lifting device-d 1, guide rail-d 2, shaft body-d 3, magnetic suction ring-d 4, clamping rod-d 5, attaching block-e 1, push rod-e 2, magnetic seat-e 3, connecting rod-e 4 and attaching plate-e 5.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it is obvious that the described embodiments are some, not all embodiments of the present invention, and all other embodiments obtained by those skilled in the art without creative efforts based on the embodiments of the present invention belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Example 1

As shown in fig. 1 to 5, the present invention provides a control device of a dual dc power supply system, which structurally includes a distribution terminal 1, a network port 2, a power-on mechanism 3, a power-on block 4, and a housing 5, wherein the rear end of the distribution terminal 1 is fixed below the front end of the housing 5 by a buckle, the outer wall of the network port 2 is completely fixed on the left side of the housing 5, the outer wall of the lower end of the power-on mechanism 3 is fixed on the inner wall of the upper end of the housing 5 in an embedded manner, and the lower end of the power-on block 4 is fixed on the upper end of;

the electrifying mechanism 3 is provided with an electrifying device 31, an assembling nut 32, an embedded base 33 and an assembling shell 34, the lower end of the electrifying device 31 is embedded and assembled inside the upper end of the assembling shell 34, the lower end of the assembling nut 32 is embedded and fixed on two sides of the upper end of the assembling shell 34, the upper end of the embedded base 33 is embedded and fixed on the lower end of the assembling shell 34, the assembling nut 32 is provided with two assembling nuts, the assembling nuts are distributed on two sides of the upper end of the assembling shell 34 relatively, the assembling positions of the electrifying wires assembled when the assembling nuts 32 are assembled relatively are fixed in parallel, and the problem that the circuit contact is poor or the copper sheets are broken due to.

The power connection device 31 is internally provided with a wiring socket a1, an isolation mechanism a2 and a bottom plate a3, the lower end of the wiring socket a1 is fixed at the lower end of the isolation mechanism a2 through a buckle, and the lower end of the isolation mechanism a2 is fixedly embedded at the upper end of the bottom plate a 3.

The isolation mechanism a2 comprises a bearing plate b1, a baffle b2, an assembly box b3, an opening and closing mechanism b4 and a lifting rod b5, the lower end of the bearing plate b1 is welded and fixed to the upper end of the lifting rod b5, the right outer wall of the baffle b2 is movably clamped and connected to the left inner wall of the assembly box b3, the upper end of the opening and closing mechanism b4 is connected to the lower end of the lifting rod b5 through a bolt in a clamping manner, the middle outer wall of the lifting rod b5 is movably matched and connected to the inner wall of the upper end of the assembly box b3, the baffle b2 is of an arc-shaped structure, the two baffle b2 are arranged, the two baffle b3 are oppositely assembled to two ends of the assembly.

The opening and closing mechanism b4 is composed of a derivative plate c1, an arc-shaped disc c2, a return spring c3, a clamping spring plate c4 and a connecting shaft c5, the inner wall of the derivative plate c1 is fixedly embedded in the outer wall of the arc-shaped disc c2, the right side of the upper end of the arc-shaped disc c2 is movably clamped inside the connecting shaft c5, the right side of the return spring c3 is fixedly welded to the left side of the clamping spring plate c4, the outer wall of the clamping spring plate c4 is fixedly interference-fixed to the inner wall of the right side of the arc-shaped disc c2, the structure of the arc-shaped disc 2 is a semicircular structure, two parts are arranged, the combination is a disc structure, and the outer wall of the structure can be smoothly transited when moving contact pushes the tail end of the baffle.

The following examples are set forth: the rear end of a shell 5 of the equipment is assembled and fixed through screws, after the equipment is fixed, a control network can be inserted and clamped into a net port 2, a plurality of sections of external wires are connected to the upper end of a branch terminal 1, after the external wires are connected, an interface of a power-on circuit is nested and assembled on the outer wall of a power-on mechanism 3, the interface pushes a wiring socket a1 by pushing the power-on circuit, the interface is completely clamped and assembled into a wiring socket a1, the interface can be fixed to the upper end of a wiring socket a1 through the fixation of bolts, when the interface is assembled to a wiring socket a1, the wiring socket a1 is pushed to move downwards, the wiring socket a1 pushes a bearing plate b1 to drive a lifting rod b5 to move downwards through the sinking of the wiring socket a1, after the lifting rod b5 moves downwards, an opening and closing mechanism b4 can be directly pressed, after an opening and closing mechanism b4 is pressed, the opening is used as the center, the arc-shaped disc c2 drives the derivative plate c1 to be opened outwards, the inner part of the baffle b2 is pushed through the opened derivative plate c1, after the baffle b2 is pushed, the baffle b2 is guided along through holes formed in two ends of the assembly box b3, after the baffle b2 is guided, the upper end of the baffle b2 is gradually closed, the baffle b2 can be attached to and cover the connection position of the wiring socket a1 and the interface, and is attached to the surface of the wiring socket a1, the connection position of the wiring socket a1 and the interface is closed, and condensation is prevented from flowing into the interface.

Example 2

As shown in fig. 5, the opening and closing mechanism b4 is composed of a derivative plate c1, an arc-shaped disc c2, a return spring c3, a clamping spring plate c4 and a connecting shaft c5, an inner wall of the derivative plate c1 is fixedly embedded in an outer wall of the arc-shaped disc c2, a right side of an upper end of the arc-shaped disc c2 is movably engaged with the inside of the connecting shaft c5, a right side of the return spring c3 is fixedly welded to a left side of the clamping spring plate c4, an outer wall of the clamping spring plate c4 is fixedly interference-fixed to a right inner wall of the arc-shaped disc c2, the arc-shaped disc c2 is in a semicircular structure, two arc-shaped discs are provided, and after the combination is in a disc structure, the outer wall of the structure can be smoothly transited when the.

As shown in fig. 6 to 7: the connecting shaft c5 is composed of a lifting device d1, a guide rail d2, a shaft body d3, a magnetic attraction ring d4 and a clamping rod d5, the lifting device d1 is completely assembled in the center inside the shaft body d3, the outer wall of the guide rail d2 is fixedly embedded in the left side inside the shaft body d3, the lower end of the magnetic attraction ring d4 is fixedly fastened at the lower end inside the shaft body d3 through a buckle, the right side of the clamping rod d5 is movably fitted with the outer wall of the lower end of the lifting device d1, the clamping rod d5 is of an arc-shaped structure, the material of the clamping rod d5 can be attracted by magnetic force, the clamping rod d5 is more easily pushed by the arc-shaped structure to move and rotate, and can.

The lifting device d1 comprises an attachment block e1, a push rod e2, a magnetic seat e3, a connecting rod e4 and a flitch e5, the lower end of the attachment block e1 is fixedly embedded at the upper end of a connecting rod e4, the right end of the push rod e2 is assembled inside the left side of the attachment block e1 in a nested manner, the inner wall of the upper end of the magnetic seat e3 is fixedly arranged on the outer wall of the lower end of the connecting rod e4 through threads, the upper end of the rod e4 is fixedly welded at the lower end of the attachment block e1, the left side of the flitch e5 is fixedly embedded and clamped at the left side of the push rod e2, the attachment block e1 is of an inverted triangular structure, push rods e2 and the flitch e5 are arranged at the two ends of the attachment block, the two ends of the inverted triangular structure can adapt to the radian existing in an assembly empty slot, and the problem.

The following examples are set forth: after the interface is completely fixed, the derived block arranged at the upper end of the arc-shaped disc c2 can slide on the inner wall of the guide rail d2 by changing the structure and the position of the arc-shaped disc c2, and move, when the derived block slides to the middle section of the guide rail d2, the clamping rod d5 is pushed, so that the clamping rod d5 rotates inwards, the derived block can reach the bottom end of the guide rail d2 through the clamping rod d5 by rotating the clamping rod d5, after the clamping rod d5 rotates, the tail end of the clamping rod d5 can be attracted and attached to the upper end of the magnetic seat e3 by attraction of the magnetic seat e3, and when the clamping rod d5 moves by pushing of the derived block, the lifting device d1 can be pushed upwards to move the attached block e1 upwards, the push rod e2 is pushed by the spring inside the attached block e1, and the attached plate e5 is pushed by the push rod e2, so that the attached plate e5 can be tightly attached to the empty slot 1, after the interface is disassembled, the resetting of the arc-shaped disc c2 enables the clamping rod d5 to be opened again, the magnetic seat e3 is attracted through the magnetic ring d4, the lifting device d1 slides downwards, and the clamping rod d5 is attracted through the magnetic seat e3, so that the mechanism is reset.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.