CN113285324B - High-altitude circuit breaking emergency communication equipment for power grid - Google Patents

Abstract

The invention relates to high-altitude circuit breaking emergency communication equipment, in particular to high-altitude circuit breaking emergency communication equipment for a power grid, which comprises a locking mechanism, a traveling linkage mechanism and an emergency communication mechanism, wherein the equipment can be arranged on a live wire and a zero wire of the power grid, can travel on the live wire and the zero wire, can apply an upward reasoning to the equipment to reduce the pressure of the live wire and the zero wire when the equipment travels on the live wire and the zero wire, can emergently communicate a circuit breaking part on the live wire or the zero wire, is connected with the traveling linkage mechanism, and is connected with the emergency communication mechanism.

Description

High-altitude circuit breaking emergency communication equipment for power grid

Technical Field

The invention relates to high-altitude open-circuit emergency communication equipment, in particular to high-altitude open-circuit emergency communication equipment for a power grid.

Background

When the high-altitude power grid is in emergency connection, manual connection is often needed, the operation difficulty is high, and the high-altitude power grid is dangerous, but no good high-altitude circuit-breaking emergency connection equipment exists in the market, so that the high-altitude circuit-breaking emergency connection equipment for the power grid is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing high-altitude open circuit emergency communication equipment for a power grid, the equipment can be arranged on a live wire and a zero line of the power grid, the equipment can move on the live wire and the zero line, the equipment can apply upward reasoning to the equipment to reduce the pressure of the live wire and the zero line when moving on the live wire and the zero line, and the equipment can carry out emergency communication on the open circuit part on the live wire or the zero line.

In order to solve the technical problems, the invention relates to high-altitude open circuit emergency communication equipment, in particular to high-altitude open circuit emergency communication equipment for a power grid, which comprises a locking mechanism, a traveling linkage mechanism and an emergency communication mechanism, wherein the equipment can be installed on a live wire and a zero line of the power grid, can travel on the live wire and the zero line, can apply an upward reasoning to the equipment to reduce the pressure of the live wire and the zero line when the equipment travels on the live wire and the zero line, and can perform emergency communication on open circuit parts on the live wire or the zero line.

The locking mechanism is connected with the advancing linkage mechanism and the emergency communicating mechanism.

As further optimization of the technical scheme, the high-altitude open-circuit emergency communication equipment for the power grid comprises a power shaft a, a friction wheel a, a belt a, a connecting shaft a, a reverse friction wheel b, a connecting shaft b, a lifting plate, a fixed end bottom plate, a rotating end bottom plate, a connecting plate a, a friction wheel b, a connecting shaft c, an arc limiting plate, a connecting plate b, a connecting plate c, a sliding arc plate, an arc shaft, an arc sliding rail, a spring, an equipment installation box, a zero line, a live line, a friction wheel c, a connecting shaft d and a connecting plate d, wherein the power shaft a is connected with the friction wheel a, the power shaft a is connected with a bearing of the connecting plate a and the equipment installation box in a sliding manner, the power shaft a is connected with the belt a in a friction manner, the friction wheel a is connected with the friction wheel c, and the belt a is connected with the connecting shaft a, the connecting shaft a is connected with a reverse friction wheel a, the connecting shaft a is connected with a bearing of an equipment installation box, the reverse friction wheel a is connected with a reverse friction wheel b in a friction way, the reverse friction wheel b is connected with a connecting shaft b, the connecting shaft b is connected with the bearing of the equipment installation box, the lifting plate is connected with a fixed end bottom plate in a sliding way, the lifting plate is connected with a rotating end bottom plate, the fixed end bottom plate is connected with a connecting plate a in a sliding way, the rotating end bottom plate is connected with the connecting plate a, the connecting plate a is connected with the equipment installation box, the friction wheel b is connected with a connecting shaft c, the friction wheel b is connected with an arc limiting plate, the connecting shaft c is connected with a connecting plate d bearing, the arc limiting plate is connected with the connecting plate b, the arc limiting plate is connected with the connecting plate c in a sliding way, the arc limiting plate is connected with an arc slide rail, the connecting plate b is connected with an arc shaft, and the connecting plate c is connected with a slide arc plate, connecting plate c and circular arc axle sliding connection, slip circular arc board and circular arc slide rail sliding connection, the spring housing is epaxial and spacing in connecting plate b and connecting plate c of circular arc, equipment fixing box and friction pulley c sliding connection, equipment fixing box is connected with connecting plate d, friction pulley c is connected with connecting axle d, connecting axle d and stiff end bottom plate sliding connection, connecting axle d is connected with rotatory end bottom plate.

As further optimization of the technical scheme, the invention relates to high-altitude open circuit emergency communication equipment for a power grid, wherein the advancing linkage comprises a power shaft b, an arc wheel, a friction wheel with a key, a pressing spring, a friction wheel I, a connecting shaft I, a propeller, a friction wheel II, a connecting shaft II, a connecting plate I, a connecting plate II, a linkage belt and a connecting plate III, the power shaft b is connected with the arc wheel, the power shaft b is connected with the friction wheel with the key in a sliding manner, the power shaft b is connected with a three-shaft bearing of the connecting plate, the arc wheel is connected with a zero line and a live line in a sliding manner, the pressing spring is sleeved on the power shaft b, and a limit position is connected with the arc wheel and the friction wheel with the key, the first friction wheel is connected with the first friction wheel with the keys, the first friction wheel is connected with the first connecting shaft, the first connecting shaft is connected with a propeller, the first connecting shaft is connected with a fixed end bottom plate bearing, the second friction wheel is connected with the second connecting shaft, the second friction wheel is connected with the arc wheel, the second connecting shaft is in threaded connection with the first connecting plate, the second connecting shaft is connected with a third connecting plate bearing, the first connecting plate is connected with the second connecting plate, the first connecting plate is connected with the fixed end bottom plate, the second connecting plate is connected with the second connecting plate, the linkage belt is in friction connection with the first two connecting shafts, and the third connecting plate is connected with the fixed end bottom plate.

As a further optimization of the technical scheme, the high-altitude open circuit emergency communication device for the power grid comprises a power shaft c, a friction column a, a friction plate, a metal current-conducting cone, a friction column b, a friction column c, a transmission shaft a, a friction column c, a mounting plate a, a mounting plate b, a mounting plate c and a mounting plate c, wherein the power shaft c is connected with the friction column a, the power shaft c is connected with the friction column b, the power shaft c is connected with the mounting plate b through a bearing, the friction column a is connected with the friction plate, the friction plate is connected with the metal current-conducting plate, the friction plate is connected with the mounting plate a in a sliding mode, the metal current-conducting plate is connected with the metal current-conducting cone, the friction column b is connected with the power shaft c, the friction column b is connected with the friction column c, the friction column c is connected with the transmission shaft a, the transmission shaft a is connected with the friction column c, the transmission shaft a is connected with the mounting plate c through a bearing, the friction column c is connected with another friction plate, the mounting plate a is connected with the mounting plate b, the mounting plate c is connected with a fixed end, the mounting plate c is connected with the fixing end, the mounting plate c is connected with the mounting plate c, and the fixing end.

As a further optimization of the technical scheme, the high-altitude open-circuit emergency communication equipment for the power grid is provided, wherein the power shaft a, the power shaft b and the power shaft c are provided with power sources and can rotate.

The high-altitude open-circuit emergency communication equipment for the power grid has the advantages that:

the invention relates to high-altitude open circuit emergency communication equipment for a power grid, which can be arranged on a live wire and a zero line of the power grid, can move on the live wire and the zero line, can apply upward reasoning to the equipment when moving on the live wire and the zero line to reduce the pressure of the live wire and the zero line, and can carry out emergency communication on open circuit parts on the live wire or the zero line.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic structural diagram of an overhead circuit-breaking emergency communication device for a power grid according to the present invention.

Fig. 2 is a schematic structural diagram of an overhead circuit-breaking emergency communication device for a power grid.

Fig. 3 is a first structural schematic diagram of the locking mechanism 1 of the high altitude circuit breaking emergency communication equipment for the power grid according to the present invention.

Fig. 4 is a structural schematic diagram of a locking mechanism 1 of the high altitude disconnection emergency communication equipment for the power grid.

Fig. 5 is a third structural schematic diagram of the locking mechanism 1 of the high altitude open circuit emergency communication equipment for the power grid.

Fig. 6 is a fourth structural schematic diagram of the locking mechanism 1 of the high altitude open circuit emergency communication equipment for the power grid.

Fig. 7 is a schematic structural diagram five of the locking mechanism 1 of the high altitude disconnection emergency communication equipment for the power grid.

Fig. 8 is a schematic structural diagram of the equipment installation boxes 1 to 21 of the high altitude disconnection emergency communication equipment for the power grid.

Fig. 9 is a first structural schematic diagram of the traveling linkage 2 of the high altitude disconnection emergency communication equipment for the power grid.

Fig. 10 is a second structural schematic diagram of the traveling linkage 2 of the high altitude disconnection emergency communication equipment for the power grid.

Fig. 11 is a third structural schematic diagram of the traveling linkage 2 of the high altitude disconnection emergency communication equipment for the power grid.

Fig. 12 is a fourth structural schematic diagram of the traveling linkage 2 of the high altitude disconnection emergency connection device for the power grid according to the present invention.

Fig. 13 is a first structural schematic diagram of the emergency communication mechanism 3 of the high altitude disconnection emergency communication equipment for the power grid.

Fig. 14 is a second structural schematic diagram of the emergency connection mechanism 3 of the overhead disconnection emergency connection device for a power grid according to the present invention.

Fig. 15 is a third schematic structural diagram of the emergency communication mechanism 3 of the high altitude circuit breaking emergency communication device for the power grid according to the present invention.

In the figure: a locking mechanism 1; a power shaft a1-1; a friction wheel a1-2; belts a1-3; connecting shafts a1-4; reverse friction wheels a1-5; reverse friction wheels b1-6; connecting shafts b1-7; 1-8 of a lifting plate; a fixed end bottom plate 1-9; 1-10 of a rotating end bottom plate; connection plates a1-11; friction wheels b1-12; connecting shafts c1-13; 1-14 arc limiting plates; connecting plates b1-15; connecting plates c1-16; 1-17 of sliding arc plates; arc axis 1-18; arc slide rails 1-19; 1-20 parts of a spring; 1-21 of an equipment installation box; 1-22 parts of zero line and live line; friction wheels c1-23; connecting shafts d1-24; connecting plates d1-25; advancing linkage 2; a power shaft b2-1; 2-2 of a circular arc wheel; 2-3 of a friction wheel with a key; pressing the spring 2-4; 2-5 parts of a first friction wheel; connecting shafts I2-6; 2-7 of a propeller; 2-8 parts of a second friction wheel; connecting shafts II 2-9; 2-10 parts of a first connecting plate; 2-11 parts of a second connecting plate; 2-12 parts of a second connecting plate; 2-13 of a linkage belt; connecting plates III 2-14; an emergency communication mechanism 3; a power shaft c3-1; a friction column a3-2; 3-3 of friction plates; 3-4 of a metal conductive plate; 3-5 parts of a metal conductive cone; 3-6 of friction column b; friction columns c3-7; a transmission shaft a3-8; 3-9 of a friction column; mounting plates a3-10; mounting plates b3-11; mounting plates c3-12; mounting plates c3-13.

Detailed Description

The first embodiment is as follows:

the invention relates to an overhead circuit-breaking emergency communication device, in particular to an overhead circuit-breaking emergency communication device for a power grid, which comprises a locking mechanism 1, a traveling linkage 2 and an emergency communication mechanism 3, and is described in the following with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14 and fig. 15.

The locking mechanism 1 is connected with the advancing linkage 2, and the locking mechanism 1 is connected with the emergency communication mechanism 3.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and fig. 15, and the present embodiment further describes the present embodiment, where the locking mechanism 1 includes a power shaft a1-1, a friction wheel a1-2, a belt a1-3, a connecting shaft a1-4, a reverse friction wheel a1-5, a reverse friction wheel b1-6, a connecting shaft b1-7, a lifting plate 1-8, a fixed end bottom plate 1-9, a rotating end bottom plate 1-10, a connecting plate a1-11, a friction wheel b1-12, a connecting shaft c1-13, an arc limiting plate 1-14, a connecting plate b1-15, a connecting plate c1-16, a sliding arc plate 1-17, a circular arc shaft 1-18, an arc slide rail 1-19, a spring 1-20, an equipment installation box 1-21, a zero line and live line 1-22, a friction wheel c1-23, a connecting shaft c 1-24, a connecting plate 1-25, a connecting plate d, a power shaft a1-1 is connected with a friction wheel a1-2, the power shaft a1-1 is connected with a connecting plate a1-11 bearing, the power shaft a1-1 is connected with an equipment installation box 1-21 in a sliding mode, the power shaft a1-1 is connected with a belt a1-3 in a friction mode, the friction wheel a1-2 is connected with a friction wheel c1-23 in a friction mode, the belt a1-3 is connected with a connecting shaft a1-4, the connecting shaft a1-4 is connected with a reverse friction wheel a1-5, the connecting shaft a1-4 is connected with the equipment installation box 1-21 bearing, the reverse friction wheel a1-5 is connected with a reverse friction wheel b1-6 in a friction mode, the reverse friction wheels b1-6 are connected with the connecting shafts b1-7, the connecting shafts b1-7 are connected with the equipment installation boxes 1-21 through bearings, the lifting plates 1-8 are connected with the fixed end bottom plates 1-9 in a sliding manner, the lifting plates 1-8 are connected with the rotating end bottom plates 1-10, the fixed end bottom plates 1-9 are connected with the connecting plates a1-11 in a sliding manner, the rotating end bottom plates 1-10 are connected with the connecting plates a1-11, the connecting plates a1-11 are connected with the equipment installation boxes 1-21, the friction wheels b1-12 are connected with the connecting shafts c1-13, the friction wheels b1-12 are connected with the arc limiting plates 1-14, the connecting shafts c1-13 are connected with the connecting plates d1-25 through bearings, and the arc limiting plates 1-14 are connected with the connecting plates b1-15, the arc limiting plates 1-14 are connected with the connecting plates c1-16 in a sliding manner, the arc limiting plates 1-14 are connected with the sliding arc plates 1-17 in a sliding manner, the arc limiting plates 1-14 are connected with the arc slide rails 1-19, the connecting plates b1-15 are connected with the arc shafts 1-18, the connecting plates c1-16 are connected with the sliding arc plates 1-17, the connecting plates c1-16 are connected with the arc shafts 1-18 in a sliding manner, the sliding arc plates 1-17 are connected with the arc slide rails 1-19 in a sliding manner, the springs 1-20 are sleeved on the arc shafts 1-18 and limited on the connecting plates b1-15 and the connecting plates c1-16, the equipment mounting boxes 1-21 are connected with the friction wheels c1-23 in a sliding manner, the equipment mounting boxes 1-21 are connected with the connecting plates d1-25, the friction wheels c1-23 are connected with the connecting shafts d1-24, a connecting shaft d1-24 is connected with a fixed end bottom plate 1-9 in a sliding manner, a connecting shaft d1-24 is connected with a rotating end bottom plate 1-10, equipment can be installed on a live wire and a zero wire of a power grid, a power shaft a1-1 rotates, the power shaft a1-1 rotates to drive a friction wheel a1-2 to rotate, the friction wheel a1-2 rotates to drive a friction wheel c1-23 to rotate, the friction wheel c1-23 rotates to drive a connecting shaft d1-24 to rotate, the connecting shaft d1-24 rotates to drive a rotating end bottom plate 1-10 to rotate, the rotating end bottom plate 1-10 rotates to drive a lifting plate 1-8 to rotate, the rotating end bottom plate 1-10 can be installed on the live wire 1-22 when rotating to be in contact with the fixed end bottom plate 1-9, and when the lifting plate 1-8 rotates to be in contact with a reverse friction wheel b1-6, the power shaft a1-1 rotates to drive the connecting shaft a1-4 to rotate through the belt a1-3, the connecting shaft a1-4 rotates to drive the reverse friction wheel a1-5 to rotate, the reverse friction wheel a1-5 rotates to drive the reverse friction wheel b1-6 to rotate, the reverse friction wheel b1-6 rotates to drive the connecting shaft b1-7 to rotate, the lifting plate 1-8 is also driven to convey to the upper part of the equipment when the reverse friction wheel b1-6 rotates, the lifting plate 1-8 is continuously driven to the upper part when the reverse friction wheel b1-6 rotates, the process is beneficial to the equipment arranged on the neutral line and the live line 1-22, the lifting plate 1-8 generates a frictional connection relation with the friction wheel b1-12 when rotating to be contacted with the friction wheel b1-12, and the friction wheel b1-12 rotates when the lifting plate 1-8 is conveyed upwards, when the friction wheels b1-12 rotate, the lifting plates 1-8 are pressed through the sliding arc plates 1-17, so that the lifting plates 1-8 are tightly contacted with the fixed end bottom plates 1-9, the process is beneficial to the fact that the lifting plates 1-8 are driven by the reverse friction wheels b1-6, and the connecting plates b1-15 continuously apply thrust to the sliding arc plates 1-17 under the action of the springs 1-20.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, and the embodiment further describes the embodiment, wherein the traveling linkage 2 includes a power shaft b2-1, a circular arc wheel 2-2, a keyed friction wheel 2-3, a compression spring 2-4, a friction wheel one 2-5, a connecting shaft one 2-6, a propeller 2-7, a friction wheel two 2-8, a connecting shaft two 2-9, a connecting plate one 2-10, a connecting plate two 2-11, a connecting plate two 2-12, a linkage belt 2-13, and a connecting plate three 2-14, the power shaft b2-1 is connected with the circular arc wheel 2-2, a power shaft b2-1 is connected with a friction wheel 2-3 with a key in a sliding way, the power shaft b2-1 is connected with a third connecting plate 2-14 bearing, an arc wheel 2-2 is connected with a zero line and a live line 1-22 in a sliding way, a compression spring 2-4 is sleeved on the power shaft b2-1, a limit position is connected with the arc wheel 2-2 and the friction wheel 2-3 with the key, a friction wheel I2-5 is connected with a connecting shaft I2-6, the connecting shaft I2-6 is connected with a propeller 2-7, the fixed end of the connecting shaft I2-6 is connected with a bottom plate 1-9 bearing, a friction wheel II 2-8 is connected with a connecting shaft II 2-9, a friction wheel II 2-8 is connected with the arc wheel 2-2, the connecting shaft II 2-9 is connected with the first connecting plate 2-10 thread, the second connecting shaft 2-9 is in bearing connection with the third connecting plate 2-14, the first connecting plate 2-10 is in bearing connection with the second connecting plate 2-11, the first connecting plate 2-10 is in connection with the first fixed end base plate 1-9, the second connecting plate 2-11 is in connection with the second connecting plate 2-12, the linkage belt 2-13 is in friction connection with the first two connecting shafts 2-6, the third connecting plate 2-14 is in connection with the first fixed end base plate 1-9, the equipment can advance on the live wire and the zero wire, the equipment can apply an upward reasoning to the equipment to reduce the pressure of the live wire and the zero wire when the equipment advances on the live wire and the zero wire, the power shaft b2-1 rotates to drive the arc wheel 2-2 to rotate, the arc wheel 2-2 rotates to advance on the zero wire and the live wire 1-22, and the friction wheel 2-8 rotates when the arc wheel 2-2 rotates, the second friction wheel 2-8 rotates to drive the second connecting shaft 2-9 to rotate, the second connecting shaft 2-9 drives the first connecting plate 2-10 to transversely slide when rotating, the bottom plate 1-10 at the rotating end moves and drives the second connecting plate 2-12 to move through the second connecting plate 2-11, the second connecting plate 2-12 drives the first friction wheel 2-3 with keys to slide on the power shaft b2-1 when moving, when the first friction wheel 2-3 with keys at one side contacts with the first friction wheel 2-5, the first friction wheel 2-3 with keys rotates to drive the first friction wheel 2-5 to rotate, the first friction wheel 2-5 rotates to drive the first propeller 2-7 to rotate through the first connecting shaft 2-6, and when the first propeller 2-7 rotates, a thrust is exerted on the bottom plate 1-9 at the fixed end through rotation, when the arc wheel 2-2 rotates reversely, the other friction wheel 2-3 with the key is driven to contact with the other side of the first friction wheel 2-5, the rotating direction of the first friction wheel 2-5 is unchanged, and the propeller 2-7 can apply thrust to the equipment when the arc wheel 2-2 moves forward.

The fourth concrete implementation mode:

referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, the present embodiment further describes the first embodiment, the emergency communicating mechanism 3 includes a power shaft c3-1, a friction column a3-2, a friction plate 3-3, a metal conducting plate 3-4, a metal conducting cone 3-5, a friction column b3-6, a friction column c3-7, a transmission shaft a3-8, a friction column c3-9, a mounting plate a3-10, a mounting plate b3-11, a power shaft c3-12, and a mounting plate c3-13, the power shaft c3-1 is connected with the friction column a3-2, the power shaft c3-1 is connected with the friction column b3-6, a power shaft c3-1 is connected with a mounting plate b3-11 through a bearing, a friction column a3-2 is connected with a friction plate 3-3 through a friction mode, the friction plate 3-3 is connected with a metal current-conducting plate 3-4, the friction plate 3-3 is connected with a mounting plate a3-10 in a sliding mode, the metal current-conducting plate 3-4 is connected with a metal current-conducting cone 3-5, the friction column b3-6 is connected with the power shaft c3-1, the friction column b3-6 is connected with a friction column c3-7 through a friction mode, the friction column c3-7 is connected with a transmission shaft a3-8, the transmission shaft a3-8 is connected with a friction column c3-9, the transmission shaft a3-8 is connected with a mounting plate c3-13 through a bearing, the friction column c3-9 is connected with another friction plate 3-3 through a friction mode, the mounting plate a3-10 is connected with a mounting plate b3-11, the mounting plate b3-11 is connected with a mounting plate c3-12, the mounting plate c3-12 is connected with the mounting plate c3-13, the mounting plate a3-10 is connected with the fixed end bottom plate 1-9, the mounting plate b3-11 is connected with the fixed end bottom plate 1-9, the mounting plate c3-12 is connected with the fixed end bottom plate 1-9, the mounting plate c3-13 is connected with the fixed end bottom plate 1-9, the equipment can communicate the broken circuit part on the live wire or the zero line in an emergency, the power shaft c3-1 rotates to drive the friction column a3-2 to rotate, the power shaft c3-1 rotates to drive the transmission shaft a3-8 to rotate through the friction column b3-6 and the friction column c3-7, the transmission shaft a3-8 rotates to drive the friction column c3-9 to rotate in the reverse direction, when the friction column c3-9 and the friction column a3-2 rotate in the forward direction and in the reverse direction, the friction plate 3-3 on one side moves upwards, the friction plate 3-3 on the other side moves downwards, the friction plate 3-4 drives the metal current conducting plate 3-4 to move, the metal current conducting plate 3-5 moves, the metal current conducting plate 3-4 and the metal current conducting plate 3-5 cone is communicated with the live wire or the live wire-3-5 current conducting plate 22 when the live wire or the metal current conducting plate 22.

The fifth concrete implementation mode:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14 and 15, and the present embodiment further describes the first embodiment in which the power shaft a1-1, the power shaft b2-1 and the power shaft c3-1 are rotatable from a power source.

The working principle of the device is as follows: the equipment can be arranged on a live wire and a zero wire of a power grid, a power shaft a1-1 rotates, the power shaft a1-1 rotates to drive a friction wheel a1-2 to rotate, the friction wheel a1-2 rotates to drive a friction wheel c1-23 to rotate, the friction wheel c1-23 rotates to drive a connecting shaft d1-24 to rotate, the connecting shaft d1-24 rotates to drive a rotating end bottom plate 1-10 to rotate, the rotating end bottom plate 1-10 rotates to drive a lifting plate 1-8 to rotate, the equipment can be arranged on the live wire 1-22 and the zero wire when the rotating end bottom plate 1-10 rotates to be in contact with a fixed end bottom plate 1-9, the power shaft a1-1 rotates to drive the connecting shaft a1-4 to rotate through a belt a1-3 when the lifting plate 1-8 rotates to be in contact with a reverse friction wheel b1-6, the connecting shaft a1-4 rotates to drive the reverse friction wheel a1-5 to rotate, the reverse friction wheel a1-5 rotates to drive the reverse friction wheel b1-6 to rotate, the reverse friction wheel b1-6 rotates to drive the connecting shaft b1-7 to rotate, the lifting plate 1-8 is also driven to convey upwards when the reverse friction wheel b1-6 rotates, the lifting plate 1-8 is continuously driven upwards when the reverse friction wheel b1-6 rotates, the process is beneficial to the installation of equipment on a zero line and a live line 1-22, the lifting plate 1-8 is in frictional connection with the friction wheel b1-12 when the lifting plate 1-8 rotates to be in contact with the friction wheel b1-12, the friction wheel b1-12 drives the friction wheel b1-12 to rotate when being conveyed upwards, the lifting plate 1-8 is pressed by sliding the arc plate 1-17 when the friction wheel b1-12 rotates, the lifting plate 1-8 is in close contact with the fixed end bottom plate 1-9, the process helps the lifting plate 1-8 to be driven by the reverse friction wheel b1-6, the connecting plate b1-15 continuously applies thrust to the sliding arc plate 1-17 under the action of the spring 1-20, the equipment can advance on the live wire and the zero wire, the equipment can apply an upward reasoning to the equipment to reduce the pressure of the live wire and the zero wire when advancing on the live wire and the zero wire, the power shaft b2-1 rotates to drive the arc wheel 2-2 to rotate, the arc wheel 2-2 rotates to advance on the zero wire and the live wire 1-22, the friction wheel 2-8 rotates when the arc wheel 2-2 rotates, the friction wheel 2-8 rotates to drive the connecting shaft two 2-9 to rotate, when the connecting shaft II 2-9 rotates, the connecting plate I2-10 is driven to slide transversely, the rotating end base plate 1-10 moves and drives the connecting plate II 2-12 to move through the connecting plate II 2-11, the keyed friction wheel 2-3 is stirred to slide on the power shaft b2-1 when the connecting plate II 2-12 moves, when the keyed friction wheel 2-3 at one side is contacted with the friction wheel I2-5, the keyed friction wheel I2-3 rotates to drive the friction wheel I2-5 to rotate, the friction wheel I2-5 rotates to drive the propeller 2-7 to rotate through the connecting shaft I2-6, when the propeller 2-7 rotates, a thrust is exerted on the fixed end base plate 1-9 through rotation, when the arc wheel 2-2 rotates reversely, the other keyed friction wheel 2-3 is driven to be contacted with the other side of the friction wheel I2-5, at the moment, the rotation direction of a first friction wheel 2-5 is unchanged, namely a propeller 2-7 can apply thrust to equipment when an arc wheel 2-2 advances, the equipment can emergently communicate a broken circuit part on a live wire or a zero wire, a power shaft c3-1 rotates to drive a friction column a3-2 to rotate, the power shaft c3-1 rotates to drive a transmission shaft a3-8 to rotate through a friction column b3-6 and the friction column c3-7, the transmission shaft a3-8 rotates to drive the friction column c3-9 to rotate reversely, when the friction column c3-9 and the friction column a3-2 rotate forwards and reversely, the friction plate 3-3 on one side is driven to move upwards, the friction plate 3-3 on the other side moves downwards, the friction plate 3-3 moving downwards drives a metal conductive plate 3-4 to move, the metal conductive plate 3-4 moves to drive a metal conductive cone 3-5 to move, when the metal conductive cone 3-5 moves downwards, the metal conductive cone 3-5 is inserted into a live wire 1-22, and the live wire and the zero wire and the metal cone 3-5 and the power shaft can also communicate with a live wire 3-4 and the other metal conductive plate 3-22 in a reverse state.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (2)

1. The utility model provides an emergent intercommunication equipment that opens circuit with high altitude for electric wire netting, includes locking mechanism (1), advances linkage (2), emergent intercommunication mechanism (3), its characterized in that: the locking mechanism (1) is connected with the traveling linkage (2), and the locking mechanism (1) is connected with the emergency communication mechanism (3);

the locking mechanism (1) comprises a power shaft a (1-1), a friction wheel a (1-2), a belt a (1-3), a connecting shaft a (1-4), a reverse friction wheel a (1-5), a reverse friction wheel b (1-6), a connecting shaft b (1-7), a lifting plate (1-8), a fixed end bottom plate (1-9), a rotating end bottom plate (1-10), a connecting plate a (1-11), a friction wheel b (1-12), a connecting shaft c (1-13), an arc limiting plate (1-14), a connecting plate b (1-15), a connecting plate c (1-16), a sliding arc plate (1-17), an arc shaft (1-18), an arc sliding rail (1-19), a spring (1-20), an equipment mounting box (1-21), a null line and live line (1-22), a friction wheel c (1-23), a connecting shaft d (1-24), a connecting plate d (1-25), the power shaft a (1-1) is connected with the friction wheel a (1-2), the power shaft a (1-1) is connected with the connecting plate a (1-1) and the bearing (1-11), a power shaft a (1-1) is in friction connection with a belt a (1-3), a friction wheel a (1-2) is in friction connection with a friction wheel c (1-23), the belt a (1-3) is connected with a connecting shaft a (1-4), the connecting shaft a (1-4) is connected with a reverse friction wheel a (1-5), the connecting shaft a (1-4) is in bearing connection with an equipment installation box (1-21), the reverse friction wheel a (1-5) is in friction connection with a reverse friction wheel b (1-6), the reverse friction wheel b (1-6) is connected with a connecting shaft b (1-7), the connecting shaft b (1-7) is in bearing connection with the equipment installation box (1-21), a lifting plate (1-8) is in sliding connection with a fixed end bottom plate (1-9), the lifting plate (1-8) is connected with a rotating end bottom plate (1-10), the fixed end bottom plate (1-9) is in sliding connection with a connecting plate a (1-11), the rotating end bottom plate (1-10) is connected with a connecting plate a (1-11) through a connecting plate (1-11), and the connecting shaft a connecting plate (1-11) is connected with a connecting plate (1-12), the friction wheel b (1-12) is connected with the arc limiting plate (1-14), the connecting shaft c (1-13) is connected with the connecting plate d (1-25) through a bearing, the arc limiting plate (1-14) is connected with the connecting plate b (1-15), the arc limiting plate (1-14) is connected with the connecting plate c (1-16) in a sliding manner, the arc limiting plate (1-14) is connected with the sliding arc plate (1-17) in a sliding manner, the arc limiting plate (1-14) is connected with the arc sliding rail (1-19), the connecting plate b (1-15) is connected with the arc shaft (1-18), the connecting plate c (1-16) is connected with the sliding arc plate (1-17), the connecting plate c (1-16) is connected with the arc sliding arc shaft (1-18) in a sliding manner, the sliding arc plate (1-17) is connected with the arc sliding rail (1-19), the spring (1-20) is sleeved on the arc shaft (1-18) and limited on the connecting plate b (1-15) and the connecting plate c (1-16), the equipment mounting box (1-21) is connected with the friction wheel c (1-25) and the connecting plate c (1-21-1-16), the connecting shafts d (1-24) are connected with the fixed end base plates (1-9) in a sliding manner, and the connecting shafts d (1-24) are connected with the rotating end base plates (1-10);

the advancing linkage (2) comprises a power shaft b (2-1), an arc wheel (2-2), a friction wheel with a key (2-3), a compression spring (2-4), a friction wheel I (2-5), a connecting shaft I (2-6), a propeller (2-7), a friction wheel II (2-8), a connecting shaft II (2-9), a connecting plate I (2-10), a connecting plate II (2-11), a connecting plate II (2-12), a linkage belt (2-13) and a connecting plate III (2-14), wherein the power shaft b (2-1) is connected with the arc wheel (2-2), the power shaft b (2-1) is in sliding connection with the friction wheel with the key (2-3), the power shaft b (2-1) is in bearing connection with the connecting plate III (2-14), the arc wheel (2-2) is in sliding connection with a live wire (1-22), the compression spring (2-4) is sleeved on the power shaft b (2-1), the connecting shaft and the arc wheel (2-2) is connected with the friction wheel (2-5), the friction wheel (2-5) is connected with the friction wheel (2-5), the connecting shaft I (2-6) is connected with the propeller (2-7), the connecting shaft I (2-6) is connected with a bearing of the fixed end bottom plate (1-9), the friction wheel II (2-8) is connected with the connecting shaft II (2-9), the friction wheel II (2-8) is connected with the arc wheel (2-2), the connecting shaft II (2-9) is in threaded connection with the connecting plate I (2-10), the connecting shaft II (2-9) is in bearing connection with the connecting plate III (2-14), the connecting plate I (2-10) is connected with the connecting plate II (2-11), the connecting plate I (2-10) is connected with the fixed end bottom plate (1-9), the connecting plate II (2-11) is connected with the connecting plate II (2-12), the linkage belt (2-13) is in friction connection with the connecting shaft I (2-6), and the connecting plate III (2-14) is connected with the fixed end bottom plate (1-9);

the emergency communication mechanism (3) comprises a power shaft c (3-1), a friction column a (3-2), a friction plate (3-3), a metal conductive plate (3-4), a metal conductive cone (3-5), a friction column b (3-6), a friction column c (3-7), a transmission shaft a (3-8), a friction column c (3-9), a mounting plate a (3-10), a mounting plate b (3-11), a mounting plate c (3-12) and a mounting plate c (3-13), wherein the power shaft c (3-1) is connected with the friction column a (3-2), the power shaft c (3-1) is connected with the friction column b (3-6), the power shaft c (3-1) is connected with the mounting plate b (3-11) through a bearing, the friction column a (3-2) is connected with the friction plate (3-3), the friction plate (3-3) is connected with the metal conductive plate (3-4), the friction plate (3-3) is connected with the mounting plate a (3-10), the metal column (3-4) is connected with the friction column (3-6) through a sliding connection, the friction column (3-6) is connected with the friction column (3-6), the friction column c (3-7) is connected with the transmission shaft a (3-8), the transmission shaft a (3-8) is connected with the friction column c (3-9), the transmission shaft a (3-8) is in bearing connection with the mounting plate c (3-13), the friction column c (3-9) is in friction connection with the other friction plate (3-3), the mounting plate a (3-10) is connected with the mounting plate b (3-11), the mounting plate b (3-11) is connected with the mounting plate c (3-12), the mounting plate c (3-12) is connected with the mounting plate c (3-13), the mounting plate a (3-10) is connected with the fixed end bottom plate (1-9), the mounting plate b (3-11) is connected with the fixed end bottom plate (1-9), the mounting plate c (3-12) is connected with the bottom plate (1-9), and the mounting plate c (3-13) is connected with the fixed end bottom plate (1-9).

2. The overhead circuit breaking emergency communication equipment for the power grid as claimed in claim 1, wherein: the power shaft a (1-1), the power shaft b (2-1) and the power shaft c (3-1) are provided with power sources and can rotate.

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