CN117810899A - Power transmission amount management equipment based on virtual power plant and operation method - Google Patents

Abstract

The invention belongs to the field of virtual power plants, and particularly relates to a power transmission capacity management device based on a virtual power plant and an operation method thereof, wherein the power transmission capacity management device comprises a cylinder I, a rotating ring and the like; the outside of the left part of the cylinder I is provided with a groove, and the inner circumference of the groove is connected with a rotating ring in a sliding way. The invention realizes that the wire core of the cable is extruded through the ring II and the ball, so that the wire core of the cable is contracted, the problem that the wire core of the cable is scattered to the periphery is solved, the wire core of the cable is straightened through the ring II and the ball under the condition of propping against the outer surface of the wire core of the cable, the wire core of the cable is prevented from being bent, the ring II is prevented from being compressed through the baffle I, the problem that the ring II tightly props against the wire core of the cable, the wire core of the cable is blocked by the ring II is solved, the upper part of the cylinder I is shielded through the baffle, and dust and other impurities are prevented from falling on the wire core part of the cable.

Description

Power transmission amount management equipment based on virtual power plant and operation method

Technical Field

The invention belongs to the field of virtual power plants, and particularly relates to power transmission capacity management equipment based on a virtual power plant and an operation method.

Background

Based on the prior art, the insulation layer at one end of the cable needs to be stripped before the cable is connected with the cable joint, so that the wire core part of the cable is exposed, and the cable is connected with the cable joint conveniently;

and because the existing cable connector is clamped with a small section of the cable core, the cable core of the cable is not completely attached to the cable connector for connection, namely, a section of the cable core is exposed, once the current transferred between the cable and the cable connector is overlarge, the current can be concentrated in a local area, and because the current density is high, the conductivity is reduced, heat is easy to generate, even sparks are easy to generate, so that current overload, short circuit or other potential safety hazards are caused.

Disclosure of Invention

In order to overcome the defects that after an insulating layer of a cable is stripped, a wire core of the cable is scattered to the periphery and the connection efficiency and connection quality of the cable and a cable joint are seriously affected, the invention provides power transmission capacity management equipment based on a virtual power plant and an operation method.

The technical scheme of the invention is as follows: the power transmission management equipment based on the virtual power plant comprises a cylinder I, a rotating ring, a fixed ring and a cable joint; the left part of the outer side of the cylinder I is provided with a groove, and the inner circumference of the groove is connected with a rotating ring in a sliding way; the rotating ring is rotationally connected with a fixed ring; the left part of the fixed ring is fixedly connected with a cable joint; the device also comprises a pushing mechanism, a conical barrel, a cylinder II, a circular ring II and balls; the cylinder I is connected with a pushing mechanism; the pushing mechanism is connected with a conical cylinder which is arranged in a funnel shape; the pushing mechanism is used for driving the conical cylinder to move; a groove is formed in the middle of the inner wall of the cylinder I, and a cylinder II is connected in the groove in a damping type sliding manner; the right part of the cylinder II is fixedly connected with a circular ring II; the ring II is rotationally connected with a plurality of balls.

In addition, it is particularly preferable that the right part of the conical cylinder is fixedly connected with a circular ring I, and the circular ring I is made of rubber material and is used for avoiding scratching the wire core part of the cable.

In addition, it is particularly preferred that the inner wall of the conical cylinder is fixedly connected with a baffle ring I, and the baffle ring I is used for limiting the circular ring II.

Furthermore, it is particularly preferred that the pushing mechanism comprises a sliding block, a round bar, an elastic member and a baffle plate; the cylinder I is connected with a sliding block in a sliding way; the upper part of the cylinder I is fixedly connected with a round rod; the round rod is connected with the sliding block in a sliding way; an elastic piece is sleeved outside the round rod, one end of the elastic piece is fixedly connected with the cylinder I, and the other end of the elastic piece is fixedly connected with the sliding block; a baffle is fixedly connected to the upper part of the cylinder I and positioned above the round rod, and the baffle is made of elastic materials; the right end of the baffle is fixedly connected with the sliding block.

Furthermore, it is particularly preferred that a fixation system is also included; the cylinder I is connected with a fixing system; the fixing system comprises a sleeve, a fixing plate, a sliding rod, an elliptical head, a baffle ring II and a limiting block; threads are arranged on the outer side of the left part of the cylinder I; the outer side of the cylinder I is screwed with a sleeve; the inner side of the left part of the sleeve is provided with threads matched with the cylinder I; the left part of the cylinder I is fixedly connected with at least four fixing plates which are made of elastic materials; each fixed plate is connected with a sliding rod in a sliding way; an elliptical head is fixedly connected to the upper end of the sliding rod; the middle part of the sleeve is provided with a special-shaped groove, and the top of the inner wall of the special-shaped groove is fixedly connected with a baffle ring II; the left part of the inner wall of the cylinder I is fixedly connected with a limiting block, a plurality of vent holes are formed in the limiting block, and the limiting block is in a conical shape with the outer diameter gradually increasing from right to left.

In addition, it is particularly preferable that a plurality of through holes are annularly and equidistantly formed in the sleeve, and all the through holes penetrate through corresponding special-shaped grooves for radiating heat of the cable.

Furthermore, it is particularly preferred that each fixing plate is provided with a through hole for heat dissipation of the cable.

Furthermore, it is particularly preferred that a limiting system is also included; the rotating ring is connected with a limiting system; the limit system is connected with the fixed ring; the limiting system comprises a crank, an arc-shaped block and a supporting shaft; at least five cranks are rotatably connected to the left side of the rotating ring; each crank is rotatably connected with an arc-shaped block, and all the arc-shaped blocks form a ring shape together; each arc-shaped block is fixedly connected with a supporting shaft; all the support shafts are rotationally connected with the fixed ring.

Furthermore, it is particularly preferred that the inner side of the arcuate block is provided with a squeeze block for limiting the core portion of the cable.

A method of operating a virtual power plant-based power delivery management apparatus, comprising the steps of:

s1: the cable core is extruded through the ring II and the ball so that the cable core is contracted;

s2: straightening the wire core of the cable through the circular ring II and the ball;

s3: the limiting block is contracted and attached to the cable core, and the cable core is radiated through the vent hole on the limiting block, the through hole on the fixing plate and the through hole on the sleeve;

s4: the cable core is pressed against the cable core through all the extrusion blocks arranged on the inner sides of all the arc blocks.

The invention has the advantages and positive effects that:

(1) The cable core is extruded through the circular ring II and the ball, so that the cable core is contracted, the problem that the cable core is scattered to the periphery is avoided, the cable is limited through the right part of the cylinder I, the circular ring II and the ball move under the condition of propping against the outer surface of the cable core, and the circular ring II and the ball straighten the cable core, so that the cable core is prevented from bending;

(2) Through setting up of baffle I, avoid the toper section of thick bamboo to compress tightly ring II, make ring II tightly support the sinle silk of cable, lead to ring II to block the dead problem of sinle silk card of cable, shelter from the upper portion of drum I through the baffle, avoid impurity such as dust to fall in the sinle silk part of cable;

(3) The limiting block is contracted and attached to the cable core, and the cable core is radiated through the vent hole on the limiting block, the through hole on the fixing plate and the through hole on the sleeve, so that the problem that the cable core is overheated and has a safety accident is solved;

(4) The extrusion blocks arranged on the inner sides of all the arc-shaped blocks are used for propping against the cable core of the cable, so that the cable core is extruded to be similar to a cylinder shape, and the cable core part of the cable is conveniently connected with the cable connector.

Drawings

FIG. 1 is a schematic view of a first perspective construction of a virtual power plant-based power delivery management apparatus of the present invention;

FIG. 2 is a schematic view of a second perspective construction of a virtual power plant-based power delivery management apparatus according to the present invention;

FIG. 3 is a partial cross-sectional view of a virtual power plant-based power delivery management apparatus of the present invention;

FIG. 4 is a schematic view of the installation position of the conical cylinder of the power transmission management device based on the virtual power plant;

FIG. 5 is a cross-sectional view of a virtual power plant-based power delivery management apparatus ring II of the present invention;

FIG. 6 is a schematic perspective view of a power transmission management device fixing system based on a virtual power plant according to the present invention;

FIG. 7 is a schematic view of the installation position of the slide bar of the power transmission management equipment based on the virtual power plant;

fig. 8 is a schematic perspective view of a limiting system of a power transmission management device based on a virtual power plant according to the present invention.

In the figure: 1-cylinder I, 2-rotating ring, 3-fixed ring, 4-cable connector, 5-cable, 201-sliding block, 202-round bar, 203-elastic piece, 204-baffle, 205-conical cylinder, 2051-cylinder I, 2052-baffle I, 206-cylinder II, 207-cylinder II, 2071-ball, 301-sleeve, 3011-special-shaped groove, 302-fixed plate, 303-sliding bar, 304-elliptical head, 305-baffle II, 306-limiting block, 401-crank, 402-arc block and 403-supporting shaft.

Detailed Description

The objects, technical solutions and advantages of the present invention will become more apparent by the following detailed description of the present invention with reference to the accompanying drawings. It should be understood that the description is only illustrative and is not intended to limit the scope of the invention. In addition, in the following description, descriptions of well-known structures and techniques are omitted so as not to unnecessarily obscure the present invention.

Example 1

The power transmission amount management equipment based on the virtual power plant comprises a cylinder I1, a rotating ring 2, a fixed ring 3 and a cable joint 4 according to the figures 1-5; a groove is formed in the left part of the outer side of the cylinder I1, and a rotating ring 2 is connected in the groove in a sliding manner in the circumferential direction; the rotating ring 2 is rotatably connected with a fixed ring 3; the left part of the fixed ring 3 is fixedly connected with a cable connector 4;

the device also comprises a pushing mechanism, a conical barrel 205, a cylinder II 206, a circular ring II 207 and a ball 2071; the cylinder I1 is connected with a pushing mechanism; the pushing mechanism is connected with a conical barrel 205, and the conical barrel 205 is arranged in a funnel shape; the pushing mechanism is used for driving the conical cylinder 205 to move; a groove is formed in the middle of the inner wall of the cylinder I1, and a cylinder II 206 is connected in the groove in a damping type sliding manner; the right part of the cylinder II 206 is fixedly connected with a circular ring II 207; the ring II 207 is connected with a plurality of balls 2071 in an annular equidistant rotation manner.

The right part of the conical barrel 205 is fixedly connected with a circular ring I2051, and the circular ring I2051 is made of rubber and is used for avoiding scratching the wire core part of the cable 5.

The inner wall of the conical barrel 205 is fixedly connected with a baffle ring I2052, and the baffle ring I2052 is used for limiting the circular ring II 207.

The pushing mechanism comprises a sliding block 201, a round rod 202, an elastic piece 203 and a baffle 204; the cylinder I1 is connected with a sliding block 201 in a sliding way; the upper part of the cylinder I1 is fixedly connected with a round rod 202; the round bar 202 is in sliding connection with the sliding block 201; the outside of the round rod 202 is sleeved with an elastic piece 203, one end of the elastic piece 203 is fixedly connected with the cylinder I1, and the other end of the elastic piece 203 is fixedly connected with the sliding block 201; a baffle 204 is fixedly connected to the upper part of the cylinder I1 and positioned above the round rod 202, and the baffle 204 is made of elastic materials; the right end of the baffle 204 is fixedly connected with the sliding block 201.

When the cable 5 is smoothed out: because the insulating layer at one end of the cable 5 needs to be stripped before the cable 5 is connected with the cable connector 4, the wire core part of the cable 5 is exposed so as to facilitate the connection between the cable 5 and the cable connector 4, in the process, the wire core of the cable 5 is extremely easy to be pressed to the wire core of the cable 5 when the insulating layer of the cable 5 is stripped, the wire core of the cable 5 is scattered around to further seriously affect the connection efficiency and the connection quality of the cable 5 and the cable connector 4 after the insulating layer of the cable 5 is stripped, in order to solve the problems, after the insulating layer of the cable 5 is stripped, the cable 5 is manually threaded into the cylinder I1 from right to left, and the wire core part of the cable 5 sequentially passes through the conical cylinder 205, the circular ring II 207 and the cylinder II 206, at the moment, the wire core part of the cable 5 is positioned in the conical cylinder 205 and the cylinder II 206 and the insulating layer of the cable 5 is positioned at the right of the conical cylinder 205, the cable 5 is limited by the right part of the cylinder I1, then the sliding block 201 is manually pushed to slide left along the round rod 202, the elastic piece 203 is compressed, the sliding block 201 moves and drives the conical cylinder 205 to move, the conical cylinder 205 touches the circular ring II 207, at the moment, the inner cone of the conical cylinder 205 extrudes the circular ring II 207, the circular ring II 207 is deformed by inward contraction, the circular ring II 207 is deformed to drive the right part of the cylinder II 206 to be deformed by contraction, and meanwhile, the circular ring II 207 is deformed to drive all the balls 2071 to move against the outer surface of the wire core of the cable 5, so that the balls 2071 move against the outer surface of the wire core of the cable 5, and the wire core of the cable 5 is extruded by the circular ring II 207 and the balls 2071, so that the wire core of the cable 5 is contracted, and the problem that the wire core of the cable 5 is scattered all around is avoided is solved;

the right part of the cylinder I1 is used for limiting the cable 5, and then the circular ring II 207 and the ball 2071 move under the condition of propping against the outer surface of the cable 5 wire core, and the circular ring II 207 and the ball 2071 straighten the cable 5 wire core, so that the phenomenon that the cable 5 wire core is bent is avoided;

and through setting up of baffle ring I2052, when toper section of thick bamboo 205 removes extrusion ring II 207, baffle ring I2052 can block ring II 207, after ring II 207 contacted baffle ring I2052, ring II 207 no longer inwards shrink deformation, thereby avoid toper section of thick bamboo 205 to compress tightly ring II 207, make ring II 207 tightly support the sinle silk of cable 5, lead to the problem that ring II 207 blocked the sinle silk of cable 5, through setting up of ring I2051, avoid toper section of thick bamboo 205 to remove the time and the sinle silk of cable 5 takes place great friction, lead to the problem of damaging the sinle silk of cable 5, and when slider 201 removes, baffle 204 takes place deformation along with the removal of slider 201, when slider 201 moves through the elasticity of elastic component 203 and resets, baffle 204 can take place folding deformation, and then shelter from the upper portion of drum I1 through baffle 204, avoid impurity such as dust to fall in the sinle silk portion of cable 5.

Example 2

On the basis of the embodiment 1, according to the figures 6-7, a fixing system is also included; the cylinder I1 is connected with a fixing system; the fixing system comprises a sleeve 301, a fixing plate 302, a sliding rod 303, an elliptical head 304, a baffle ring II 305 and a limiting block 306; threads are arranged on the outer side of the left part of the cylinder I1; the outer side of the cylinder I1 is screwed with a sleeve 301; the inner side of the left part of the sleeve 301 is provided with threads matched with the cylinder I1; four fixing plates 302 are fixedly connected to the left part of the cylinder I1, and the fixing plates 302 are made of elastic materials; each fixed plate 302 is connected with a sliding rod 303 in a sliding way; an elliptical head 304 is fixedly connected to the upper end of the sliding rod 303; the middle part of the sleeve 301 is provided with a special-shaped groove 3011, and the top of the inner wall of the special-shaped groove 3011 is fixedly connected with a baffle ring II 305; the left part of the inner wall of the cylinder I1 is fixedly connected with a limiting block 306, a plurality of vent holes are formed in the limiting block 306 in an annular equidistant mode, and the limiting block 306 is in a conical shape with the outer diameter gradually increasing from right to left.

The sleeve 301 is provided with a plurality of through holes at equal intervals, and all the through holes penetrate through the corresponding special-shaped grooves 3011 for radiating the heat of the cable 5.

Each fixing plate 302 is provided with a through hole for radiating heat from the cable 5.

The lower end of the sliding rod 303 is cut into an inclined shape, so that the contact area between the sliding rod 303 and the limiting block 306 is increased.

When the cable 5 is compacted: because the existing cable connector 4 is clamped with a small section of the cable 5 wire core, and the cable 5 wire core is not completely attached to the cable connector 4, namely, a section of the cable 5 wire core is still exposed outside, once the current transmitted between the cable 5 and the cable connector 4 is overlarge, the current is concentrated in a local area, heat is easily generated due to high current density and reduced conductivity, even sparks are generated, current overload, short circuit or other potential safety hazards are caused, in order to solve the problems, the sleeve 301 is loaded on the outer side of the cylinder I1 in advance, threads on the inner side of the sleeve 301 are connected with threads on the outer side of the cylinder I1, as shown in the figure, a sliding rod 303 is taken as an example, the sleeve 301 is manually twisted, the sleeve 301 moves leftwards, the sleeve 301 moves, the sliding rod 304 is pressed by the special-shaped groove 3011 in the downward extrusion force of the elliptical head 304, the elliptical head 304 moves downwards, the elliptical head 304 is further moved downwards along the fixed plate 302, the lower end of the sleeve 303 touches the outer wall of the limiting block 306, and gradually moves leftwards along with the sleeve 301, the sliding rod 306 gradually, the compression force of the sliding rod 306 is gradually increases the inner wall of the limiting block 306, and further the cable 306 is further compressed inwards, and the cable 306 is deformed gradually, and the inner wall of the limiting block 306 is further deformed gradually is deformed, so that the limiting block 5 is pressed against the inner wall 306 is deformed, and the limiting block 5 is deformed;

and because the external diameter of the limiting block 306 gradually increases from right to left, when the sleeve 301 continues to move leftwards, the sleeve 301 moves to drive the baffle ring II 305 to move, so that the baffle ring II 305 butts against the elliptical head 304, at the moment, the elliptical head 304 does not move downwards any more, the elliptical head 304 is driven to move leftwards by the movement of the baffle ring II 305, the elliptical head 304 moves to drive the sliding rod 303 to move, the fixing plate 302 is compressed, the through hole on the fixing plate 302 is extruded, the sliding rod 303 moves to extrude the left part area of the limiting block 306, the left part of the limiting block 306 deforms and contracts inwards, and the inner wall of the whole limiting block 306 butts against the wire core of the cable 5, so that the limiting block 306 is further attached to the wire core of the cable 5;

and, when the sinle silk of cable 5 produces heat, through the air vent on stopper 306, the through-hole on the fixed plate 302 and the through-hole on sleeve 301 dispel the heat to the sinle silk of cable 5, and when the sinle silk of cable 5 overheated, reverse torsion sleeve 301 by the manual work again, make sleeve 301 move to the right, and then make all parts that are connected remove, and then make fixed plate 302 reset, the through-hole in the fixed plate 302 will resume the original state this moment, the left portion of stopper 306 no longer supports the sinle silk of cable 5 simultaneously, thereby the heat that the sinle silk produced of messenger's cable 5 can be quick dispel, thereby promote the sinle silk radiating efficiency to cable 5, avoid the sinle silk of cable 5 to take place the problem of incident because of overheated.

Example 3

On the basis of the embodiment 2, according to fig. 8, a limiting system is further included; the rotating ring 2 is connected with a limiting system; the limit system is connected with the fixed ring 3; the limiting system comprises a crank 401, an arc-shaped block 402 and a supporting shaft 403; five cranks 401 are rotatably connected to the left side of the rotary ring 2; each crank 401 is rotatably connected with an arc block 402, and all the arc blocks 402 form a ring shape together; each arc-shaped block 402 is fixedly connected with a supporting shaft 403; all support shafts 403 are rotatably connected to the stationary ring 3.

The inner side of the arc-shaped block 402 is provided with a squeeze block for limiting the core portion of the cable 5.

The elastic member 203 is a spring.

When clamping the cable 5: when the cable 5 is connected with the cable connector 4, the cable 5 is limited by the circular ring II 207 and the limiting block 306, then the cable 5 is driven to continuously move left by the manual work, so that the wire core of the cable 5 passes through the middle of all the arc-shaped blocks 402, and the initial state of all the arc-shaped blocks 402 is in an open state, as the wire core of the cable 5 is extruded by all the balls 2071, a circle of groove is formed on the outer side of the wire core of the cable 5, so as to influence the connection quality of the cable 5 and the cable connector 4, in order to solve the problem, at the moment, the wire core of the cable 5 is far away from the cable connector 4 and is limited by the limiting block 306, the cylinder II 206 and the circular ring II 207, then all the cranks 401 are driven to rotate by the manual work, the cranks 401 are driven to rotate by the rotating ring 2, the corresponding arc-shaped blocks 402 are driven to axially shrink inwards by the corresponding supporting shafts 403, and all the arc-shaped blocks 402 are driven to rotate and are combined together to form a ring shape, and the extrusion blocks arranged on the inner side of all the arc-shaped blocks 402 are pressed against the wire core of the cable 5, so that the wire core of the cable 5 is pressed against the wire core of the cable 5, and the cable connector 5 is connected with the wire core similar to the cable connector 4.

A method of operating a virtual power plant-based power delivery management apparatus, comprising the steps of:

s1: the wire core of the cable 5 is extruded through the circular ring II 207 and the ball 2071, so that the wire core of the cable 5 is contracted;

s2: straightening the wire core of the cable 5 through the circular ring II 207 and the ball 2071;

s3: the wire core of the cable 5 is contracted and attached to the limiting block 306, and the heat of the wire core of the cable 5 is dissipated through the vent holes on the limiting block 306, the through holes on the fixing plate 302 and the through holes on the sleeve 301;

s4: the cable 5 core is extruded by all extrusion blocks arranged on the inner sides of all the arc blocks 402 against the cable 5 core.

The foregoing is merely exemplary of the present invention and is not intended to limit the present invention. All equivalents and alternatives falling within the spirit of the invention are intended to be included within the scope of the invention. What is not elaborated on the invention belongs to the prior art which is known to the person skilled in the art.

Claims (10)

1. The utility model provides a power transmission capacity management device based on virtual power plant, includes drum I (1), swivel becket (2), solid fixed ring (3) and cable joint (4); a groove is formed in the left part of the outer side of the cylinder I (1), and a rotating ring (2) is connected in the groove in a sliding way in the circumferential direction; the rotating ring (2) is rotationally connected with a fixed ring (3); the left part of the fixed ring (3) is fixedly connected with a cable joint (4); the method is characterized in that: the device also comprises a pushing mechanism, a conical cylinder (205), a cylinder II (206), a circular ring II (207) and a ball (2071); the cylinder I (1) is connected with a pushing mechanism; the pushing mechanism is connected with a conical barrel (205), and the conical barrel (205) is arranged in a funnel shape; the pushing mechanism is used for driving the conical cylinder (205) to move; a groove is formed in the middle of the inner wall of the cylinder I (1), and a cylinder II (206) is connected in the groove in a damping type sliding manner; the right part of the cylinder II (206) is fixedly connected with a circular ring II (207); the ring II (207) is rotatably connected with a plurality of balls (2071).

2. The virtual power plant-based power delivery management apparatus of claim 1, wherein: the right part of the conical barrel (205) is fixedly connected with a circular ring I (2051), and the circular ring I (2051) is made of rubber and is used for avoiding scratching the wire core part of the cable (5).

3. The virtual power plant-based power delivery management apparatus of claim 1, wherein: the inner wall of the conical barrel (205) is fixedly connected with a baffle ring I (2052), and the baffle ring I (2052) is used for limiting a circular ring II (207).

4. The virtual power plant-based power delivery management apparatus of claim 1, wherein: the pushing mechanism comprises a sliding block (201), a round rod (202), an elastic piece (203) and a baffle plate (204); a sliding block (201) is connected on the cylinder I (1) in a sliding way; a round rod (202) is fixedly connected to the upper part of the cylinder I (1); the round rod (202) is in sliding connection with the sliding block (201); an elastic piece (203) is sleeved outside the round rod (202), one end of the elastic piece (203) is fixedly connected with the cylinder I (1), and the other end of the elastic piece (203) is fixedly connected with the sliding block (201); a baffle plate (204) is fixedly connected to the upper part of the cylinder I (1) and positioned above the round rod (202), and the baffle plate (204) is made of elastic materials; the right end of the baffle plate (204) is fixedly connected with the sliding block (201).

5. The virtual power plant-based power delivery management apparatus of claim 4, wherein: the device also comprises a fixing system; the cylinder I (1) is connected with a fixing system; the fixing system comprises a sleeve (301), a fixing plate (302), a sliding rod (303), an elliptical head (304), a baffle ring II (305) and a limiting block (306); threads are arranged on the outer side of the left part of the cylinder I (1); the outside of the cylinder I (1) is screwed with a sleeve (301); the inner side of the left part of the sleeve (301) is provided with threads matched with the cylinder I (1); at least four fixing plates (302) are fixedly connected to the left part of the cylinder I (1), and the fixing plates (302) are made of elastic materials; each fixed plate (302) is connected with a sliding rod (303) in a sliding way; an elliptical head (304) is fixedly connected to the upper end of the sliding rod (303); the middle part of the sleeve (301) is provided with a special-shaped groove (3011), and the top of the inner wall of the special-shaped groove (3011) is fixedly connected with a baffle ring II (305); a limiting block (306) is fixedly connected to the left part of the inner wall of the cylinder I (1), a plurality of vent holes are formed in the limiting block (306), and the limiting block (306) is in a conical shape with the outer diameter gradually increasing from right to left.

6. The virtual power plant-based power delivery management apparatus of claim 5, wherein: a plurality of through holes are formed in the sleeve (301) in an annular equidistant mode, and all the through holes penetrate through corresponding special-shaped grooves (3011) and are used for radiating heat of the cable (5).

7. The virtual power plant-based power delivery management apparatus of claim 5, wherein: each fixing plate (302) is provided with a through hole for radiating heat of the cable (5).

8. The virtual power plant-based power delivery management apparatus of any one of claims 5-7, wherein: the device also comprises a limit system; the rotating ring (2) is connected with a limiting system; the limit system is connected with the fixed ring (3); the limiting system comprises a crank (401), an arc-shaped block (402) and a supporting shaft (403); at least five cranks (401) are rotatably connected to the left side of the rotating ring (2); each crank (401) is rotatably connected with an arc block (402), and all the arc blocks (402) form a ring shape together; each arc-shaped block (402) is fixedly connected with a supporting shaft (403); all the support shafts (403) are rotatably connected with the fixed ring (3).

9. The virtual power plant-based power delivery management apparatus of claim 8, wherein: the inner side of the arc-shaped block (402) is provided with a squeezing block for limiting the wire core part of the cable (5).

10. A method of operating a virtual power plant-based power delivery management apparatus, characterized in that the method of operating uses the virtual power plant-based power delivery management apparatus of claim 9, comprising the steps of:

s1: the wire core of the cable (5) is extruded through the circular ring II (207) and the ball (2071), so that the wire core of the cable (5) is contracted;

s2: straightening the wire core of the cable (5) through the circular ring II (207) and the ball (2071);

s3: the wire core of the cable (5) is contracted and attached to the limiting block (306), and the heat of the wire core of the cable (5) is dissipated through the vent hole on the limiting block (306), the through hole on the fixing plate (302) and the through hole on the sleeve (301);

s4: the cable (5) core is extruded through all extrusion blocks arranged on the inner sides of all the arc blocks (402) to prop against the cable (5) core.