JP6961864B2 - Power engineering mounting aid - Google Patents

Description

The present invention relates to the field of power engineering technology, and specifically to a mounting assist device for power engineering.

Power engineering is a project related to electric power production, transportation, and distribution, and in a broad sense, it refers to a project that applies electricity as power or energy to different fields. The large-scale power system that appeared in the 20th century integrates the specifications of power generation, transmission, substation, distribution, and power consumption into one organic whole, and has the widest spatial span in the social material production sector, strict time adjustment, and extremely high hierarchy. It becomes a complicated physical engineering system.
In the process of overhead power transportation, a large cable wire drawing machine is generally used to pull the cable from the ground to a high altitude and fix it to an adjacent utility pole, but in the process of pulling a high-voltage cable, the copper core inside the cable is thick. Therefore, there are two problems. First, the thick copper core is easy to bend when towing the cable to high altitude, which poses a safety risk. Second, if the traction force on the cable is too large, the cables scattered on the ground will be entangled and difficult to unravel, and the cable will be wrinkled, resulting in a large power loss, which will affect the power transportation efficiency.

Chinese Patent Application Publication No. 210074717

An object of the present invention is to provide a mounting assist device for power engineering and to solve the above-mentioned conventional technical problems.

It is a mounting auxiliary device for electric power engineering, and includes a base plate, a traction device, a torsional repositioning device, and a cooperating device. The torsional repositioning device is attached to the central portion of the upper end, and the cooperative device is attached to the right end surface of the base plate.
The cooperating device includes a cooperating cylinder, a cooperating socket ring, a cooperating bush, a cooperating spring, a cooperating annular plate, a rearranging unit, and a pressure unit, and the cooperating socket ring is attached to the upper end of the cooperating cylinder. Are connected, rectangular holes are formed at equal intervals along the circumferential direction in the central portion of the cooperative bush, and the cooperative bush is slidably attached to the inside of the cooperative socket ring. The cooperative spring is attached to the outer wall at the right end of the bush, the cooperative annular plate is screwed to the right end of the cooperative bush, and the pressure units are provided at equal intervals on the inner wall at the left end of the cooperative bush. The organizing units are provided at equal intervals on the inner wall of the central portion of the cooperating bush, and the organizing units and the cooperating socket ring engage with each other.

The organizing unit includes a V-shaped link, a connecting plate, an arc ring, and an execution spring, and a central portion of the V-shaped link is attached to the rectangular hole in the cooperative bush by a pin roll. A steel ball that engages with the cooperative socket ring is movably provided at the upper end of the V-shaped link, the connection plate is attached to the lower end of the V-shaped link, and the lower end of the connection plate is attached. The arc-shaped ring is attached, the upper end of the connection plate is connected to the inner wall of the cooperation bush by the execution spring, and the V-shaped links cooperate with each other to swing left and right in the process of pulling the cable. As a result, the arc-shaped ring at the lower end can restore the creases of the cable to its original state.

The traction device includes a side plate, a position regulation roller, a support plate, a position regulation bush, a position regulation spring, an ejector pin, a U-shaped base, and a pressure rotary wheel, and the side plate is the base. The support plate is symmetrically provided at the upper end of the plate, the support plate is connected between the two side plates, the support plate is provided so as to be inclined between the two side plates, and the support plate is provided at the lower end of the support plate. A position-regulating bush is attached, the ejector pin is slidably attached to the inside of the position-regulating bush, and the position-regulating spring is provided inside the position-regulating bush. One end urges the inner wall of the lower end of the position restricting bush, the other end abuts on the lower end of the ejector pin, the upper end of the ejector pin is provided with the U-shaped base, and the U-shaped base is provided with the U-shaped base. , The pressure rotating wheel is attached by a bearing, and between the two side plates, two said position-regulating rollers are attached by a bearing, and the position-regulating rollers are located on both sides of the pressure rotating wheel, respectively. In the process in which the cable is wound around each of the two position-regulating rollers, the central portion of the cable is stretched by the pressure rotating wheel in a tension state, and the cable wire drawing machine pulls the cable, the pressure rotating wheel is used by the position-regulating spring. Reverts the bent part of the cable and reduces the safety risk in high-altitude transmission.

The torsional repositioning device includes a support base, a fixing bush, a position regulating unit, an activity roller, a drive motor, a drive gear, a torsion ring, and an obstruction ring. The fixing bushes are attached, the obstruction rings are provided on the outer walls at both ends of the fixing bushes, rectangular notches are formed at the upper ends of the fixing bushes, and the positions are formed at both ends of the fixing bushes. A regulation unit is provided, the active roller is slidably provided in the central portion of the fixed bush, locking teeth are provided on the outer wall of the active roller, and the inner wall of the active roller is provided with the above. Torsion rings are provided at equal intervals, rubber balls are provided on the inner wall of the torsion ring at equal intervals so that rubber balls can act, and the drive motor is attached to the rectangular notches in the fixed bush by a motor connection bracket. The drive gear is attached to the output shaft of the drive motor, the drive gear and the locking teeth of the activity roller are in mesh with each other, and the upper end of the output shaft of the drive motor is fixed by a bearing. It is attached to the outer wall of the rectangular notch in the bush. By the reciprocating rotation of the drive motor, the active roller inside is twisted reciprocally to rotate the coil wound inside, guaranteeing the smoothness of the outer wall in the coil, smoothing the wrinkles in the cable, and the cable after mounting. Power loss can be reduced.

Preferably, the position-regulating unit includes a position-regulating conical bush and an adjusting spring, the adjusting spring being externally attached to the outer wall of the position-regulating conical bush, and the inner wall of the position-regulating conical bush. Is provided with rubber balls at equal intervals and movably. The position-regulating unit allows the outer wall of the cable to be slippery and the outer wall of the cable to be uniformly passed through the position-regulating conical bush, causing the outer wall of the bent cable to shrink and become smooth.

Preferably, the pressure unit includes a pressure spring and a pressure arc ring, the pressure arc ring is connected to the lower end of the pressure spring, and a rubber ball is attached to the inner wall of the lower end of the pressure arc ring. Movable and evenly spaced. Due to the pressure spring, the pressure arc ring applies a constant axial pressure to the cable, and when the cable wire drawing machine pulls the cable to a constant height, the stability of the traction on the cable is not lowered by the gravity of the cable itself. Guarantee.

Preferably, rubber balls are movably and evenly spaced on the outer wall at the lower end of the arcuate ring. The rubber ball provided on the outer wall of the arc-shaped ring is convenient for promoting the rotation of the coil, improving the activity of the cable, and pulling the cable to a high altitude.

In the present invention, the cable is wound around two position-regulating rollers, and the central part of the cable is stretched in a tension state by a pressure rotating wheel. Reposition the bent part of the cable to reduce the safety risk that occurs during the high-altitude transmission process.

In the present invention, the V-shaped links cooperate with each other in the process of pulling the cable and swing left and right, and the arc-shaped ring at the lower end smoothes the creases in the cable and returns to the original structural state. In addition, the pressure arc ring gives a constant axial pressure to the cable by the action of the pressure spring, so that the cable is stable without being lowered by the gravity of the cable itself when the cable wire drawing machine pulls the cable to a certain height. It is guaranteed to be towed to a certain height.

The twisting / restoring device of the present invention rotates the coil wound inside by twisting the internal active roller reciprocatingly by the reciprocating rotation of the drive motor, guarantees the smoothness of the outer wall of the coil, and smoothes the wrinkles of the cable. Reduce the power loss of the cable after installation.

Each direction described in the present application is a direction when the device is viewed in the same direction as in FIG.

It is a front sectional view of the mounting auxiliary device of power engineering which concerns on this invention. It is sectional drawing of the torsional repositioning apparatus in this invention. It is sectional drawing of the cooperation device in this invention.

Hereinafter, the present embodiment will be described with reference to FIGS. 1 to 3. The technical contents of the embodiments of the present invention will be described clearly and completely. Obviously, the examples described below are only a part of the examples of the present invention and not all of them. Based on the examples of the present invention, those skilled in the art will include all examples obtained without creative effort within the scope of protection of the present invention.

As shown in FIGS. The traction device 2 is attached to the base plate 1, the twisting / restoring device 3 is attached to the central portion of the upper end of the base plate 1, and the cooperating device 4 is attached to the right end surface of the base plate 1.
The traction device 2 includes a side plate 21, a position regulation roller 22, a support plate 23, a position regulation bush 24, a position regulation spring 25, an ejector pin 26, a U-shaped base 27, and a pressure rotary wheel 28. , The side plate 21 is provided symmetrically at the upper end of the base plate 1, the support plate 23 is connected between the two side plates 21, and the support plate 23 is the two side plates 21. The position regulating bush 24 is attached to the lower end of the support plate 23, and the ejector pin 26 is slidably attached to the inside of the position regulating bush 24. The position regulating spring 25 is provided inside the position regulating bush 24, and one end of the position regulating spring 25 urges the inner wall of the lower end of the position regulating bush 24 and the other end is attached to the lower end of the ejector pin 26. The U-shaped base 27 is provided at the upper end of the ejector pin 26, and the pressure rotating wheel 28 is attached to the U-shaped base 27 by a bearing, and is between the two side plates 21. The two position-regulating rollers 22 are attached by bearings, and the position-regulating rollers 22 are located on both sides of the pressure rotating wheel 28, respectively. In the process in which the cable is wound around each of the two position-regulating rollers 22, the central portion of the cable is stretched in a tension state by the pressure rotating wheel 28, and the cable wire drawing machine pulls the cable, the position-regulating spring 25 causes the cable to be pulled. The pressure rotating wheel 28 repositions the bent portion of the cable, reducing the safety risk in high-altitude transmission.

The torsional repositioning device 3 includes a support base 31, a fixing bush 32, a position regulating unit 33, an activity roller 34, a drive motor 35, a drive gear 36, a torsion ring 37, and an obstruction ring 38. The fixed bush 32 is attached to the upper end of the support base 31, the obstruction rings 38 are provided on the outer walls at both ends of the fixed bush 32, and a rectangular notch is provided at the upper end of the fixed bush 32. The position regulating unit 33 is provided at both ends of the fixed bush 32, and the active roller 34 is slidably provided at the center of the fixed bush 32 to form an outer wall of the active roller 34. Are provided with locking teeth, the twist rings 37 are provided on the inner wall of the active roller 34 at equal intervals, and rubber balls are provided on the inner wall of the twist ring 37 so as to be active and at equal intervals. The drive motor 35 is attached to the rectangular notch in the fixed bush 32 by a motor connection bracket, and the drive gear 36 is attached to the output shaft of the drive motor 35. The locking teeth of the roller 34 are meshed with each other, and the upper end of the output shaft of the drive motor 35 is attached to the outer wall of the rectangular notch in the fixed bush 32 by a bearing. By the reciprocating rotation of the drive motor 35, the active roller 34 inside is twisted reciprocally to rotate the coil wound inside, guaranteeing the smoothness of the outer wall of the coil, smoothing the wrinkles in the cable, and after mounting. The power loss of the cable can be reduced. The position-regulating unit 33 includes a position-regulating conical bush 331 and an adjusting spring 332, and the adjusting spring 332 is externally mounted on the outer wall of the position-regulating conical bush 331, and the position-regulating conical bush 331 is provided. Rubber balls are movably provided on the inner wall of the above at equal intervals. The position-regulating unit 33 makes the outer wall of the cable slippery and allows the outer wall of the cable to be uniformly passed through the position-regulating conical bush 331, causing the outer wall of the bent cable to shrink and become smooth.

The cooperating device 4 includes a cooperating cylinder 41, a cooperating socket ring 42, a cooperating bush 43, a cooperating spring 44, a cooperating annular plate 45, a rearranging unit 46, and a pressure unit 47, and the cooperating cylinder 41. The cooperating socket ring 42 is connected to the upper end of the cooperating socket ring 42, and rectangular holes are formed at equal intervals along the circumferential direction in the central portion of the cooperating bush 43. The cooperating bush 43 is slidably attached, the cooperating spring 44 is exteriorized on the outer wall at the right end of the cooperating bush 43, and the cooperating annular plate 45 is screwed onto the right end of the cooperating bush 43. The pressure units 47 are provided at equal intervals on the leftmost inner wall of the cooperative bush 43, and the rearranging units 46 are provided at equal intervals on the inner wall of the central portion of the cooperative bush 43. The cooperating socket ring 42 engages with each other. The rearranging unit 46 includes a V-shaped link 461, a connecting plate 462, an arc ring 463, and an execution spring 464, and the central portion of the V-shaped link 461 is formed by a pin roll in the cooperative bush 43. A steel ball that is attached to a rectangular hole and engages with the cooperative socket ring 42 is movably provided at the upper end of the V-shaped link 461, and the connection plate 462 is provided at the lower end of the V-shaped link 461. The arc-shaped ring 463 is attached to the lower end of the connecting plate 462, and the upper end of the connecting plate 462 is connected to the inner wall of the cooperative bush 43 by the executing spring 464, and the lower end of the arc-shaped ring 463 is attached. Rubber balls are movably provided on the outer wall at equal intervals. The rubber ball provided on the outer wall of the arcuate ring 463 is convenient for promoting the rotation of the coil, improving the activity of the cable, and pulling the cable to a high altitude, and in the process of pulling the cable, the V-shape. When the links 461 cooperate with each other and swing to the left and right, the arc-shaped ring 463 at the lower end can restore the creases of the cable to the original state. The pressure unit 47 includes a pressure spring 471 and a pressure arc ring 472, and the pressure arc ring 472 is connected to the lower end of the pressure spring 471, and the inner wall of the lower end of the pressure arc ring 472 is connected to the inner wall of the lower end. Rubber balls are movable and provided at equal intervals. By the pressure spring 471, the pressure arc ring 472 applies a constant axial pressure to the cable, and when the cable wire drawing machine pulls the cable to a constant height, the traction on the cable is performed without being lowered by the gravity of the cable itself. Guarantee stability.

At the time of operation, one end of the cable is manually wound around two position-regulating rollers 22, the central part of the cable is stretched by a pressure rotating wheel 28, and the cable is pulled inside the active roller 34 and the cooperating bush 43, respectively. It is passed through the inside and fixed to a conventional cable wire drawing machine, and the cable is towed to a certain height by the cable wire drawing machine. The position is restored, the drive motor 35 is rotated, and the reciprocating rotation of the drive motor 35 causes the internal active roller 34 to be twisted reciprocally to rotate the coil wound inside, ensuring the smoothness of the outer wall of the coil and in the cable. The bent portion at the end is further processed by the cooperating device 4 to improve the quality of the outer wall of the cable.

Claims (6)

It is a mounting auxiliary device for power engineering.
Includes a base plate (1), a traction device (2), a torsional repositioning device (3), and a cooperating device (4).
The traction device (2) is attached to the left end surface of the base plate (1).
The torsional repositioning device (3) is attached to the central portion of the upper end of the base plate (1).
The cooperating device (4) is attached to the right end surface of the base plate (1).
The cooperating device (4) includes a cooperating cylinder (41), a cooperating socket ring (42), a cooperating bush (43), a cooperating spring (44), a cooperating annular plate (45), and an organizing unit (46). And the pressure unit (47),
The cooperative socket ring (42) is connected to the upper end of the cooperative cylinder (41).
Rectangular holes are formed at equal intervals along the circumferential direction in the central portion of the cooperation bush (43).
The cooperation bush (43) is slidably attached to the inside of the cooperation socket ring (42).
The cooperation spring (44) is externally attached to the outer wall at the right end of the cooperation bush (43).
The cooperative annular plate (45) is screwed to the right end of the cooperative bush (43).
The pressure units (47) are provided at equal intervals on the inner wall at the left end of the cooperative bush (43).
The organizing units (46) are provided at equal intervals on the inner wall of the central portion of the cooperation bush (43).
The organizing unit (46) and the cooperating socket ring (42) are engaged with each other and
The organizing unit (46) includes a V-shaped link (461), a connecting plate (462), an arc ring (463), and an execution spring (464).
The central portion of the V-shaped link (461) is attached to the rectangular hole in the cooperative bush (43) by a pin roll.
A steel ball that engages with the cooperative socket ring (42) is movably provided at the upper end of the V-shaped link (461).
The connection plate (462) is attached to the lower end of the V-shaped link (461).
The arc-shaped ring (463) is attached to the lower end of the connection plate (462).
The upper end of the connecting plate (462) is connected to the inner wall of the cooperating bush (43) by the executing spring (464).
A mounting aid for power engineering that is characterized by this. The traction device (2) includes a side plate (21), a position regulating roller (22), a support plate (23), a position regulating bush (24), a position regulating spring (25), and an ejector pin (26). , A U-shaped base (27), and a pressure rotating wheel (28).
The side plate (21) is symmetrically provided on the upper end of the base plate (1).
The support plate (23) is connected between the two side plates (21).
The support plate (23) is provided so as to be inclined between the two side plates (21).
The position restricting bush (24) is attached to the lower end of the support plate (23).
The ejector pin (26) is slidably attached to the inside of the position regulating bush (24).
The position-regulating spring (25) is provided inside the position-regulating bush (24).
One end of the position-regulating spring (25) urges the inner wall of the lower end of the position-regulating bush (24), and the other end abuts on the lower end of the ejector pin (26).
The U-shaped base (27) is provided at the upper end of the ejector pin (26).
The pressure rotating wheel (28) is attached to the U-shaped base (27) by a bearing.
Between the two side plates (21), the two position-regulating rollers (22) are attached by bearings.
The position limiting rollers (22) are located on both sides of the pressure rotating wheel (28), respectively.
The mounting auxiliary device for power engineering according to claim 1. The torsional repositioning device (3) includes a support base (31), a fixed bush (32), a position regulating unit (33), an active roller (34), a drive motor (35), and a drive gear (36). And the twist ring (37) and the obstruction ring (38).
The fixing bush (32) is attached to the upper end of the support base (31).
The obstruction rings (38) are provided on the outer walls at both ends of the fixed bush (32).
A rectangular notch is formed at the upper end of the fixed bush (32).
The position regulating unit (33) is provided at both ends of the fixed bush (32).
The active roller (34) is slidably provided at the center of the fixed bush (32).
Locking teeth are provided on the outer wall of the active roller (34).
The twist rings (37) are provided at equal intervals on the inner wall of the active roller (34).
Rubber balls are operably provided on the inner wall of the twist ring (37) at equal intervals.
The drive motor (35) is attached to the rectangular notch in the fixed bush (32) by a motor connection bracket.
The drive gear (36) is attached to the output shaft of the drive motor (35).
The drive gear (36) and the locking teeth of the active roller (34) are in mesh with each other.
The upper end of the output shaft in the drive motor (35) is attached by a bearing to the outer wall of the rectangular notch in the fixed bush (32).
The mounting auxiliary device for power engineering according to claim 1. The position-regulating unit (33) includes a position-regulating conical bush (331) and an adjusting spring (332).
The adjusting spring (332) is externally attached to the outer wall of the position-regulating conical bush (331).
Rubber balls are movably provided at equal intervals on the inner wall of the position-regulating conical bush (331).
The mounting auxiliary device for power engineering according to claim 3. The pressure unit (47) includes a pressure spring (471) and a pressure arc ring (472).
The pressure arc ring (472) is connected to the lower end of the pressure spring (471).
Rubber balls are movably and equidistantly provided on the inner wall of the lower end of the pressure arc ring (472).
The mounting auxiliary device for power engineering according to claim 1. Rubber balls are movably and equidistantly provided on the outer wall at the lower end of the arc-shaped ring (463).
The mounting auxiliary device for power engineering according to claim 1.

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