CN116560027A - Virtual power plant communication terminal construction device - Google Patents

Abstract

The invention relates to the field of communication construction equipment, in particular to a communication terminal construction device of a virtual power plant. The invention provides a virtual power plant communication terminal construction device, which comprises a pipeline, an installation cylinder body and the like; the pipeline is connected with the installation cylinder. The buried pipeline comprises a pipeline and an installation cylinder body, the installation cylinder body is connected in the process of two adjacent pipelines by the construction assembly, when the traction ball head is blown to the right end of the next adjacent pipeline by the construction assembly, the traction ball head is clamped in a claw ring at the right end of the pipeline, so that the traction ball head cannot directly fly outwards from the end of the pipeline, the traction ball head is blown into the next adjacent pipeline from each pipeline in sequence by the construction assembly, the traction ball head pulls optical fibers to be paved in each pipeline in sequence, and the paving efficiency of the optical fibers is improved. The technical problem that workers cannot easily and quickly plug the traction ball head falling out of the pipeline and the optical fiber connected with the traction ball head into a fracture at the end part of the pipeline to influence the laying efficiency of the optical fiber is solved.

Description

Virtual power plant communication terminal construction device

Technical Field

The invention relates to the field of communication construction equipment, in particular to a communication terminal construction device of a virtual power plant.

Background

The virtual power plant is an internet of things technology for uniformly and coordinately controlling distributed power generation, demand side response and energy storage resources and responding to power grid dispatching instructions, and consists of tens to hundreds of power plants, and intelligent dispatching is performed by aggregating power generation information of communication terminals of global hydropower stations by utilizing novel technologies such as optical fiber communication and the like.

In the optical fiber construction work of a communication terminal, an underground buried pipeline is needed in advance, an optical fiber is blown into the buried pipeline through a blowing device, the head end of the optical fiber is connected with a traction ball head, the traction ball head pulls the optical fiber to move along the inside of the buried pipeline under the thrust of air flow to finish the optical fiber laying work, a plurality of fractures are arranged on the buried pipeline due to the limited blowing distance of the blowing device to the optical fiber, end fractures of two adjacent pipelines are communicated through connecting pipelines, the optical fiber calandria, an optical fiber blowing connector and an optical fiber laying method are described in patent CN116125616A, after the blowing device blows the traction ball head from one end fracture to the other end fracture of the pipeline, the traction ball head breaks away from the fracture of the end of the pipeline and flies outwards, a worker is required to pick up the traction ball head separated from the fracture of the pipeline and put the traction ball head into the end fracture of the next adjacent pipeline, the steps are repeated, the blowing device is controlled to blow the traction ball head from the one end fracture of the pipeline to the other end fracture of the pipeline, the traction ball head is continuously laid into each pipeline, and the optical fiber is continuously blown in sequence.

Because the size of the optical fiber is smaller, even if the end part of the optical fiber is provided with the traction ball head with the size far larger than that of the optical fiber, when the pipeline burying depth is deeper, workers are not easy to quickly plug the traction ball head falling out of the pipeline and the optical fiber connected with the traction ball head into the fracture at the end part of the pipeline, and the laying efficiency of the optical fiber is affected.

Disclosure of Invention

In order to overcome the defect that the size of the optical fiber and the traction ball head is limited, and workers are not easy to quickly plug the traction ball head falling out of a pipeline and the optical fiber connected with the traction ball head back into a fracture at the end part of the pipeline, and the laying efficiency of the optical fiber is affected, the invention provides a virtual power plant communication terminal construction device.

The invention relates to a virtual power plant communication terminal construction device, which comprises a buried pipeline and a construction assembly for performing installation work on an installation cylinder; the buried pipeline consists of a pipeline and an installation cylinder; the pipeline is buried underground; a mounting cylinder is connected between two adjacent pipelines; in the process of connecting the installation cylinder bodies in two adjacent pipelines by the construction assembly, the construction assembly blows the traction ball heads into the next adjacent pipeline from each pipeline in sequence, and the traction ball heads pull optical fibers to be paved in each pipeline in sequence; the right end of the pipeline is fixedly connected with a claw ring for capturing the traction ball head; a hollow pad is fixedly connected inside the claw ring; the construction assembly consists of a clamping mechanism and an air blowing assembly; the clamping mechanism is used for clamping the installation cylinder body and controlling the installation cylinder body to be installed in two adjacent pipelines; the clamping mechanism is connected with two blowing assemblies, and air flow is blown to the right side of the left end of the installation cylinder body through the two blowing assemblies on the clamping mechanism.

Furthermore, it is particularly preferred that the mounting cylinder comprises an inner cylinder, an outer cylinder and a first spring;

the right end of the pipeline is detachably connected with an inner cylinder; the left end of the inner cylinder body is provided with two through groove structures which are symmetrical front and back; the right end of the inner cylinder body is connected with an outer cylinder body in a sliding way through a spline groove structure; the right end of the outer cylinder body is detachably connected with the adjacent pipeline on the right side; a first spring is fixedly connected between the inner cylinder body and the outer cylinder body, and the first spring is sleeved on the outer surface of the inner cylinder body.

Furthermore, it is particularly preferred that the outer surface of the inner cylinder is rotatably connected with a first swivel; the outer surface of the outer cylinder body is rotationally connected with a second swivel; the left end of the inner cylinder body is screwed with adjacent pipelines through a thread structure; the right end of the outer cylinder body is screwed with adjacent pipelines through a thread structure; the thread structures of the inner cylinder body and the outer cylinder body are symmetrical.

In addition, it is particularly preferable that the through groove of the inner cylinder is opened in the screw structure of the left end.

Furthermore, it is particularly preferred that the clamping mechanism comprises a right clamping block, a right holding rod, a transverse sliding rod, a left clamping block, a left holding rod and a longitudinal sliding rod;

the right clamping block clamps the second swivel; the right clamping block is fixedly connected with a right holding rod; the right clamping block is connected with a transverse sliding rod in a sliding way; the left end of the transverse slide bar is fixedly connected with a left clamping block; the left clamping block clamps the first rotating ring; the left clamping block is fixedly connected with a left holding rod; the left side of the left clamping block is fixedly connected with a longitudinal sliding rod; the front side and the rear side of the longitudinal slide bar are respectively connected with adjacent blowing assemblies.

Furthermore, it is particularly preferred that the blowing assembly comprises a fixing rod, a second spring, a connecting block and a stopper;

the longitudinal slide bar is connected with a fixed bar in a sliding way; a second spring is arranged between the fixed rod and the longitudinal sliding rod, and the second spring is sleeved on the outer surface of the longitudinal sliding rod; the lower end of the fixed rod is fixedly connected with a connecting block; the connecting block is fixedly connected with a stop block, and the stop blocks of the two blowing assemblies are mutually clung; an air passage structure is arranged between the connecting block and the stop block; the right side of the connecting block is provided with a plurality of air outlet hole structures communicated with the air passage.

In addition, it is particularly preferred that the opposite sides of the two stoppers are both arranged in a semicircular arc structure, and the air outlet holes on the two stoppers together form an annular air outlet structure.

Furthermore, it is particularly preferred that the right and left clamping blocks are each composed of an upper fixing portion and a lower two claw hook portions; the lower claw hook parts of the right clamping block and the left clamping block are made of magnet materials.

Furthermore, it is particularly preferred that the right side of the inner cylinder is fixedly connected with a toothed ring through bolts; the right clamping block is connected with a driving component for driving the toothed ring to rotate; the driving assembly consists of a driving motor and a spur gear; a driving motor is arranged on the right clamping block; the output shaft of the driving motor is fixedly connected with a spur gear.

Furthermore, it is particularly preferred that the connection block is provided with an air flow sensor which opens the air duct.

The invention relates to a virtual power plant communication terminal construction device, which consists of a pipeline and an installation cylinder, wherein in the process of connecting the installation cylinder in two adjacent pipelines by a construction assembly, when the construction assembly blows a traction ball head to the right end of the next adjacent pipeline, the traction ball head is clamped in a claw ring at the right end of the pipeline, so that the traction ball head cannot directly fly outwards from the end of the pipeline, then the construction assembly blows the traction ball head into the next adjacent pipeline from each pipeline in sequence, and the traction ball head pulls optical fibers to be paved in each pipeline in sequence, thereby improving the paving efficiency of the optical fibers;

the technical problem that the working personnel are difficult to quickly plug the traction ball head falling out of the pipeline and the optical fiber connected with the traction ball head into the end fracture of the pipeline to influence the laying efficiency of the optical fiber due to the limitation of the sizes of the optical fiber and the traction ball head is solved.

Drawings

Fig. 1 is a schematic perspective view illustrating the structure of the present invention according to an embodiment;

FIG. 2 is a schematic perspective view of a pipe and mounting cylinder according to an embodiment of the present invention;

FIG. 3 is a partial exploded view of a pipe and mounting cylinder depicting the present invention according to an embodiment;

FIG. 4 is a schematic perspective view of a jaw ring and hollow mat according to an embodiment of the present invention;

fig. 5 is a schematic view showing a construction assembly perspective structure according to an embodiment of the present invention;

fig. 6 is a partial perspective view illustrating a construction assembly according to an embodiment of the present invention;

FIG. 7 is a schematic perspective view illustrating a connecting block and a stopper according to an embodiment of the present invention;

FIG. 8 is a cross-sectional view of a connection block and stop block according to an embodiment of the present invention;

fig. 9 is a schematic view illustrating a first construction state according to an embodiment of the present invention;

fig. 10 is a schematic view illustrating a second construction state according to an embodiment of the present invention;

fig. 11 is a schematic view illustrating a third construction state according to an embodiment of the present invention.

Reference numerals: the device comprises a pipeline, a 10-traction ball head, a 11-claw ring, a 12-hollow cushion, a 21-inner cylinder, a 211-through groove, a 212-first swivel, a 22-outer cylinder, a 221-toothed ring, a 222-second swivel, a 23-first spring, a 31-right clamping block, a 311-right holding rod, a 32-transverse sliding rod, a 33-left clamping block, a 331-left holding rod, a 34-longitudinal sliding rod, a 40-air passage, a 41-fixed rod, a 42-second spring, a 43-connecting block, a 44-stop dog, a 441-air outlet hole, a 51-driving motor, a 52-spur gear and a 6-air flow sensor.

Detailed Description

The invention is further described below with reference to the drawings and examples.

Example 1

The utility model provides a virtual power plant communication terminal construction device, as shown in figures 1-8, comprising a buried pipeline and a construction assembly for performing installation work on an installation cylinder; the buried pipeline consists of a pipeline 1 and an installation cylinder; a plurality of pipelines 1 are buried underground; each two adjacent pipelines 1 are connected with a mounting cylinder; in the process of connecting the installation cylinder bodies in two adjacent pipelines 1 by the construction assembly, the construction assembly blows the traction ball heads 10 into the next adjacent pipeline 1 from each pipeline 1 in sequence, and the traction ball heads 10 pull optical fibers to be paved in each pipeline 1 in sequence; the right end of each pipeline 1 is fixedly connected with a claw ring 11 for capturing the traction ball head 10, and when the construction assembly blows the traction ball head 10 to the right end of the next adjacent pipeline 1, the traction ball head 10 is clamped in the claw ring 11 at the right end of the pipeline 1; a hollow pad 12 is fixedly connected in each claw ring 11, and the hollow pad 12 is made of rubber material, so that the traction ball head 10 can smoothly pass through the hollow pad 12 before being clamped into the claw ring 11 under the blowing of air flow; the construction assembly consists of a clamping mechanism and an air blowing assembly; the clamping mechanism is used for clamping the installation cylinder body and controlling the installation cylinder body to be installed in two adjacent pipelines 1; the clamping mechanism is connected with two blowing assemblies, and the two blowing assemblies on the clamping mechanism are used for blowing air flow to the right at the left end of the installation cylinder body, so that the traction ball head 10 is blown into the next adjacent pipeline 1 from the claw ring 11 to the right.

As shown in fig. 3, the mounting cylinder includes an inner cylinder 21, an outer cylinder 22, and a first spring 23; the right end of the pipeline 1 is detachably connected with an inner cylinder 21; the left end of the inner cylinder 21 is provided with two through grooves 211 which are symmetrical in front and back, after the clamping mechanism controls the blowing component to enter the through grooves 211, the traction ball head 10 clamped in the claw ring 11 is blown to the right, and the traction ball head 10 pulls the optical fiber to enter the right adjacent pipeline 1; the right end of the inner cylinder 21 is provided with an outer cylinder 22 through a spline groove structure; the right end of the outer cylinder 22 is detachably connected with the right adjacent pipeline 1; the outer surface of the inner cylinder 21 is sleeved with a first spring 23, and two ends of the first spring 23 are respectively clung to the inner cylinder 21 and the outer cylinder 22.

As shown in fig. 3, a first swivel 212 is rotatably connected to the outer surface of the inner cylinder 21; the outer surface of the outer cylinder 22 is rotatably connected with a second swivel 222; the left end of the inner cylinder 21 is screwed with the adjacent pipeline 1 through a thread structure; the right end of the outer cylinder 22 is screwed with the adjacent pipeline 1 through a thread structure; the thread structures of the inner cylinder 21 and the outer cylinder 22 are symmetrical; only after the clamping mechanism clamps the first swivel 212 and the second swivel 222, the outer cylinder 22 is driven to rotate manually or by means of a tool, and the outer cylinder 22 can synchronously drive the inner cylinder 21 to rotate, so that the threaded structures of the inner cylinder 21 and the outer cylinder 22 are screwed into adjacent pipelines 1 respectively; the through groove 211 of the inner cylinder 21 is formed in the threaded structure at the left end, and after the threaded structure of the inner cylinder 21 is screwed into the pipeline 1, the through groove 211 of the inner cylinder 21 can be hidden into the pipeline 1.

As shown in fig. 2 and 6, the clamping mechanism comprises a right clamping block 31, a right holding rod 311, a transverse slide rod 32, a left clamping block 33, a left holding rod 331 and a longitudinal slide rod 34; the right clamp block 31 clamps the second swivel 222; the right clamping block 31 is fixedly connected with a right holding rod 311; the right clamping block 31 is connected with a transverse sliding rod 32 in a sliding way; the left end of the transverse slide bar 32 is fixedly connected with a left clamping block 33 through a bolt; the left clamp block 33 clamps the first rotating ring 212; the left clamping block 33 is fixedly connected with a left holding rod 331; the left side of the left clamping block 33 is fixedly connected with a longitudinal slide bar 34; the front side and the rear side of the longitudinal slide bar 34 are respectively connected with adjacent blowing components; the right clamping block 31 and the left clamping block 33 are composed of an upper fixing part and a lower two claw hook parts; the lower claw hook parts of the right clamping block 31 and the left clamping block 33 are made of magnet materials, so that the fixing effect of the magnetic attraction and clamping of the first swivel 212 and the second swivel 222 of the right clamping block 31 and the left clamping block 33 is improved.

As shown in fig. 6 to 8, the blowing assembly includes a fixing rod 41, a second spring 42, a connection block 43, a stopper 44, and a gas flow sensor 6; a fixed rod 41 is connected on the longitudinal slide rod 34 in a sliding way; a second spring 42 is fixedly connected between the fixed rod 41 and the longitudinal slide rod 34, and the second spring 42 is sleeved on the outer surface of the longitudinal slide rod 34; the lower end of the fixed rod 41 is fixedly connected with a connecting block 43 through a bolt; a stop block 44 is fixedly connected to the connecting block 43, the stop blocks 44 of the two blowing assemblies are mutually clung, and a gap between a left pipeline and the sphere 10 is blocked by matching the two stop blocks 44 with the hollow pad 12; an air passage 40 structure is arranged between the connecting block 43 and the stop block 44; the right side of the connecting block 43 is provided with a plurality of air outlet holes 441 which are communicated with the air passage 40; the connection block 43 is provided with an air flow sensor 6 which is communicated with the air passage 40, the air flow sensor 6 monitors the flowing state of the air flow flowing through the air passage 40 at any time, and whether the traction ball head 10 flowing through the optical fiber reaches the claw ring 11 flowing through the pipeline 1 is judged through the flowing state change of the air flow flowing through the air passage 40.

The pre-assembly work of the communication terminal construction device of the virtual power plant comprises the following steps:

the installation cylinder needs to be assembled to the construction assembly before being installed between the adjacent two pipes 1.

Firstly, a worker holds the right holding rod 311 and the left holding rod 331 and pulls the two fixing rods 41 to move away from each other, the two fixing rods 41 respectively drive the connecting blocks 43 and the stop blocks 44 connected with the fixing rods to pull outwards, the fixing rods 41 drive the second springs 42 to stretch, then the worker controls the right holding rod 311 and the left holding rod 331 to move the construction assembly, the left clamping block 33 and the right clamping block 31 are respectively clamped on the first rotating ring 212 and the second rotating ring 222, and the left clamping block 33 and the right clamping block 31 respectively magnetically attract the first rotating ring 212 and the second rotating ring 222 through lower side claw hooks of the magnet materials.

Then, the operator controls the right holding rod 311 to approach to the left holding rod 331, the right holding rod 311 drives the first rotating ring 212 to push the inner cylinder 21 to move towards the outer cylinder 22, the inner cylinder 21 drives the first spring 23 to compress, as shown in fig. 9, the installation cylinder is in a contracted state, the operator moves the installation cylinder clamped by the construction assembly between two adjacent pipelines 1, after the threaded structure of the outer cylinder 22 aligns with the pipeline 1 positioned on the right side, the left holding rod 331 is loosened, the compressed first spring 23 pushes the inner cylinder 21 to pop up leftwards, the threaded structure of the inner cylinder 21 aligns with the pipeline 1 positioned on the left side, then the operator rotates the outer cylinder 22, the outer cylinder 22 drives the inner cylinder 21 to rotate, and simultaneously two ends of the first spring 23 respectively push the threaded structures of the inner cylinder 21 and the outer cylinder 22 to be respectively extruded between the two pipelines 1, so that local areas of the threaded structures of the inner cylinder 21 and the outer cylinder 22 are locked into the two pipelines 1 in advance.

After that, the worker releases the two fixing rods 41, and the stretched second spring 42 drives the fixing rods 41 and the connecting blocks 43 and the check blocks 44 connected with the fixing rods to move and reset, so that the connecting blocks 43 and the check blocks 44 are respectively inserted into the inner cylinder 21 through the through grooves 211, as shown in fig. 2, the two check blocks 44 are mutually clung, the air outlet holes 441 on the two check blocks 44 face to the right, the assembly work of assembling the installation cylinder on the construction assembly is completed, and the pre-assembly work of locking the thread structure local area of the installation cylinder into the pipeline 1 is completed.

The optical fiber laying work of the communication terminal construction device of the virtual power plant:

before the pre-assembly work of the virtual power plant communication terminal construction device is performed, a worker plugs the traction ball head 10 fixed at the head end of light into the left end of the first pipeline 1, the worker blows air flow from the left end of the pipeline 1 to the right by using the blower, the traction ball head 10 pulls the optical fiber to be paved along the pipeline 1 to the right under the pushing of the air flow, the strength of the air flow blown into the pipeline 1 is weakened to the right in sequence, after the traction ball head 10 passes through the hollow pad 12 of the pipeline 1 to the right, the traction ball head 10 is clamped into the claw ring 11 at the right end of the pipeline 1, and the worker turns off the blower.

Then, the worker connects the air blower with the air flow sensor 6 installed on the air duct 40 through the pipeline, moves the air blower to the position between the right end of the pipeline 1 and the left end connection position of the next pipeline 1, performs the pre-assembly work of the communication terminal construction device of the virtual power plant on the two adjacent pipelines 1 according to the steps, locks the partial areas of the thread structures of the installation barrels into the two pipelines 1 respectively, inserts the two stop blocks 44 into the inner barrel 21 through the through grooves 211 respectively and is positioned at the left side of the traction ball head 10 together, at the moment, the worker starts the air blower again, the air blower sequentially conveys the air flow into the air flow sensor 6 and the air duct 40 through the pipeline, the air flow in the air duct 40 is blown out rightward through the air outlet 441, the traction ball head 10 is successfully pulled out rightward from the claw ring 11 under the thrust of the air flow, and enters the next adjacent pipeline 1 along the installation barrel, and sequentially weakens the air flow strength blown into the pipeline 1 rightward along with the suction ball head 10 passing through the hollow pad 12 of the pipeline 1, the traction ball head 10 is blocked into the claw ring 11 at the right end of the pipeline 1, and the worker stops the air blower.

Then, the worker pulls the two fixing rods 41 to move away from each other, the two fixing rods 41 respectively drive the connecting blocks 43 and the stop blocks 44 connected with the fixing rods to be pulled out from the inner cylinder 21, the fixing rods 41 drive the second springs 42 to stretch, then the worker rotates the outer cylinder 22 again, the outer cylinder 22 drives the inner cylinder 21 to rotate, meanwhile, the two ends of the first springs 23 respectively push the threaded structures of the inner cylinder 21 and the outer cylinder 22 to be completely extruded between the two pipelines 1 respectively, the through grooves 211 of the inner cylinder 21 are left hidden to the inside of the adjacent pipelines 1, as shown in fig. 11, locking work for fixing the installation cylinder between the two pipelines 1 is completed, then the worker controls the right holding rod 311 and the left holding rod 331 to move the construction assembly, and the left holding block 33 and the right holding rod 31 are pulled out from the first rotating ring 212 and the second rotating ring 222 respectively, so that the separation work for pulling out the construction assembly from the installation cylinder is completed.

Finally, the worker repeats the above work, sequentially connects each installation cylinder between two adjacent pipelines 1, and sequentially blows the traction ball head 10 from the right end of each pipeline 1 into the right end of the next pipeline 1, and simultaneously, the traction ball head 10 pulls the optical fiber to pass through each pipeline 1 successively, so as to complete the laying work of the optical fiber in the pipeline 1.

In the process that the air blower conveys air flow into the air flow sensor 6 and the air duct 40 through the pipeline, the air flow sensor 6 monitors the conveyed air flow intensity in real time, so that the phenomenon that when the air flow pushes the traction ball head 10 to move along the pipeline 1, when the air flow intensity is weakened, a worker cannot perceive that the traction ball head 10 stops in the pipeline 1 and misuses the blowing work of the traction ball head 10 to finish, the worker needs to move back and forth between two installation areas which are hundreds of meters apart, and the integral laying efficiency of the optical fiber is affected is avoided.

Example 2

As shown in fig. 1 to 8, on the basis of embodiment 1, opposite sides of the two stoppers 44 are both in semicircular arc structures, and the air outlet holes 441 on the two stoppers 44 together form an annular air outlet structure, so that when the traction ball head 10 is blown through the annular air outlet, the traction ball head 10 is subjected to uniform air flow thrust everywhere, and the traction ball head 10 is smoothly pushed out from the claw ring 11.

The claw ring 11 is made of plastic materials, the two stop blocks 44 are inserted into the inner cylinder 21 and are positioned at the left side of the traction ball head 10, air flows form an annular air outlet structure through the air outlet holes 441, uniformly blow on the traction ball head 10, push the traction ball head 10 to move rightwards from the claw ring 11, avoid large-amplitude swing caused by uneven air flow received by the traction ball head 10, and improve the right break-away efficiency of the traction ball head 10 from the claw ring 11.

Example 3

As shown in fig. 1 to 8, on the basis of embodiment 1, the right side of the inner cylinder 21 of this embodiment is fixedly connected with a toothed ring 221 by bolts; the right clamping block 31 is connected with a driving component for driving the toothed ring 221 to rotate; the driving assembly consists of a driving motor 51 and a spur gear 52; the right clamping block 31 is connected with a driving motor 51 through bolts; the output shaft of the driving motor 51 is fixedly connected with a spur gear 52; when the spur gear 52 is meshed with the toothed ring 221, the output shaft of the driving motor 51 drives the spur gear 52 to drive the toothed ring 221 to rotate.

When the worker needs to rotate the outer cylinder 22, the first spring 23 pushes the threaded structures of the inner cylinder 21 and the outer cylinder 22 to squeeze into the space between the two pipelines 1, the output shaft of the driving motor 51 drives the spur gear 52 to rotate, the spur gear 52 is meshed with the toothed ring 221 to drive the outer cylinder 22 to rotate, manual intervention needed by the worker is reduced, and the installation efficiency of the worker for controlling the construction assembly is improved.

The above embodiments are provided to illustrate the technical concept and features of the present invention and are intended to enable those skilled in the art to understand the content of the present invention and implement the same, and are not intended to limit the scope of the present invention. All equivalent changes or modifications made in accordance with the spirit of the present invention should be construed to be included in the scope of the present invention.

Claims (10)

1. A virtual power plant communication terminal construction device comprises a buried pipeline;

the buried pipeline consists of a pipeline (1) and an installation cylinder; the pipeline (1) is buried underground; a mounting cylinder is connected between two adjacent pipelines (1);

the method is characterized by also comprising a construction assembly for carrying out installation work on the installation cylinder;

in the process of connecting the installation cylinder bodies in two adjacent pipelines (1) by the construction assembly, the construction assembly blows the traction ball heads (10) into the next adjacent pipeline (1) from each pipeline (1) in sequence, and the traction ball heads (10) pull optical fibers to be paved in each pipeline (1) in sequence; the right end of the pipeline (1) is fixedly connected with a claw ring (11) for capturing the traction ball head (10); a hollow pad (12) is fixedly connected in the claw ring (11); the construction assembly consists of a clamping mechanism and an air blowing assembly; the clamping mechanism is used for clamping the installation cylinder body and controlling the installation cylinder body to be installed in two adjacent pipelines (1); the clamping mechanism is connected with two blowing assemblies, and air flow is blown to the right side of the left end of the installation cylinder body through the two blowing assemblies on the clamping mechanism.

2. A virtual power plant communication terminal construction apparatus according to claim 1, wherein the installation cylinder comprises an inner cylinder (21);

the right end of the pipeline (1) is detachably connected with an inner cylinder (21); the left end of the inner cylinder body (21) is provided with two through grooves (211) which are symmetrical in front-back; the right end of the inner cylinder body (21) is connected with an outer cylinder body (22) in a sliding way through a spline groove structure; the right end of the outer cylinder body (22) is detachably connected with the pipeline (1) adjacent to the right side; a first spring (23) is arranged between the inner cylinder body (21) and the outer cylinder body (22), and the first spring (23) is sleeved on the outer surface of the inner cylinder body (21).

3. A virtual power plant communication terminal construction device according to claim 2, wherein the outer surface of the inner cylinder (21) is rotatably connected with a first swivel (212); the outer surface of the outer cylinder body (22) is rotatably connected with a second swivel (222); the left end of the inner cylinder body (21) is screwed with the adjacent pipeline (1) through a thread structure; the right end of the outer cylinder body (22) is screwed with the adjacent pipeline (1) through a thread structure; the thread structures of the inner cylinder body (21) and the outer cylinder body (22) are symmetrical.

4. A virtual power plant communication terminal construction device according to claim 3, characterized in that the through groove (211) of the inner cylinder (21) is provided in the screw structure at the left end.

5. A virtual power plant communication terminal construction apparatus according to claim 3, wherein the clamping mechanism comprises a right clamping block (31);

the right clamping block (31) clamps the second swivel (222); a right holding rod (311) is fixedly connected on the right clamping block (31); a transverse sliding rod (32) is connected on the right clamping block (31) in a sliding way; the left end of the transverse slide bar (32) is fixedly connected with a left clamping block (33); the left clamping block (33) clamps the first rotating ring (212); a left holding rod (331) is fixedly connected on the left clamping block (33); the left side of the left clamping block (33) is fixedly connected with a longitudinal slide bar (34); the front side and the rear side of the longitudinal slide bar (34) are respectively connected with adjacent blowing components.

6. A virtual power plant communication terminal construction apparatus according to claim 5, wherein the air blowing assembly comprises a fixing rod (41);

a fixed rod (41) is connected on the longitudinal slide rod (34) in a sliding way; a second spring (42) is fixedly connected between the fixed rod (41) and the longitudinal slide rod (34), and the second spring (42) is sleeved on the outer surface of the longitudinal slide rod (34); the lower end of the fixed rod (41) is fixedly connected with a connecting block (43); a stop block (44) is fixedly connected on the connecting block (43), and the stop blocks (44) of the two blowing assemblies are mutually clung; an air passage (40) structure is arranged between the connecting block (43) and the stop block (44); the right side of the connecting block (43) is provided with a plurality of air outlet holes (441) which are communicated with the air passage (40).

7. The construction device for a communication terminal of a virtual power plant according to claim 6, wherein the opposite sides of the two stoppers (44) are each provided with a semicircular arc structure, and the air outlet holes (441) of the two stoppers (44) together form an annular arrangement of air outlet structures.

8. A virtual power plant communication terminal construction apparatus according to claim 5, wherein the right and left blocks (31, 33) are each composed of an upper fixing portion and a lower two claw hook portions; the lower claw hook parts of the right clamping block (31) and the left clamping block (33) are made of magnet materials.

9. A virtual power plant communication terminal construction device according to claim 2, characterized in that the right side of the inner cylinder (21) is fixedly connected with a toothed ring (221) through bolts; the right clamping block (31) is connected with a driving component for driving the toothed ring (221) to rotate; the driving assembly consists of a driving motor (51) and a spur gear (52); a driving motor (51) is arranged on the right clamping block (31); the output shaft of the driving motor (51) is fixedly connected with a spur gear (52).

10. A virtual power plant communication terminal construction apparatus according to claim 6 or 7, wherein the connection block (43) is provided with an air flow sensor (6) for communicating with the air duct (40).