Method, device, medium and equipment for correcting field vibration measurement result of overhead ground wire
By constructing and simplifying the theoretical deflection model, calculating the degree of deviation and correcting the amplitude, the accuracy problem of on-site vibration measurement results of overhead conductors and ground wires was solved, and more accurate measurements were achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- STATE GRID ZHEJIANG ELECTRIC POWER CO LTD
- Filing Date
- 2023-04-06
- Publication Date
- 2026-06-26
AI Technical Summary
In the existing technology, the accuracy of the field vibration measurement results of overhead conductors is affected by measurement errors caused by the offset of the vibration meter installation position.
By constructing a theoretical deflection model, simplifying the model, and calculating the degree of deviation, the amplitude of the vibration meter is corrected to obtain more accurate vibration measurement results.
It effectively corrects the problem of vibration meter measurement position offset caused by suspension clamps, damping clamps, vibration damper clamps and spacer clamps, and improves the accuracy of field vibration measurement results.
Smart Images

Figure CN116465483B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of vibration measurement result correction, and in particular to a method, apparatus, medium and equipment for correcting field vibration measurement results of overhead conductors. Background Technology
[0002] Field vibration measurement of overhead conductors under light wind is crucial for verifying the effectiveness of line vibration damping devices in practical applications. When conducting field vibration measurements, the vibration meter needs to be installed at a certain distance from the outlet of the conductor / ground wire suspension clamp, damping wire clamp, or vibration damper clamp. After installation, the amplitude of the conductor / ground wire relative to the clamp outlet at that location is measured. However, in practice, this installation method often causes the measurement position to shift, affecting the accuracy of the measurement results. For example, see... Figure 1 Taking the installation of a vibration meter at a suspension clamp as an example, the tangent point (LPC point) between the conductor and the arc of the suspension clamp outlet is aligned with the axis of the vibration meter roller. The vibration meter is fixed to the conductor by the vibration meter clamp. To prevent the ground wire from breaking due to excessive wear during use, aluminum tape is wrapped around the contact section between the ground wire and the suspension clamp during the overhead line construction phase for protection. This protection method has the problem that the length of the aluminum tape wrapped exceeds the length of the clamp, causing the vibration meter's measurement position to shift to the right. Alternatively, see... Figure 2 When installing a vibration meter at other types of clamps such as damping wires, vibration dampers, and spacers, there is a problem that the contact point between the vibration meter roller and the conductor is not at the edge of the clamp, and there is a certain distance between it and the right edge of the clamp. In other words, the measurement position of the vibration meter is also offset.
[0003] It can be seen that, as Figure 1 and Figure 2 The installation method shown often leads to measurement errors due to the offset of the measurement position, which in turn affects the accuracy of the vibration measurement results on site. Summary of the Invention
[0004] To address the aforementioned technical problems, this invention proposes a method, apparatus, medium, and equipment for correcting on-site vibration measurement results of overhead conductors. By constructing a theoretical deflection model, using the actual measured amplitude and the degree of deviation of the actual installation position from the theoretical installation position, the corrected amplitude is calculated, thereby improving the accuracy of on-site vibration measurement results.
[0005] To achieve the above objectives, embodiments of the present invention provide a method for correcting the field vibration measurement results of overhead conductors, including:
[0006] A theoretical deflection model of the overhead conductor and ground wire vibrates when the vibration meter is set at a preset theoretical installation position of the overhead conductor and ground wire is constructed, and the theoretical deflection model is simplified to obtain a simplified model.
[0007] The amplitude measured by the vibration meter set at the first position of the overhead conductor is obtained; wherein, the first position is a position on the overhead conductor at a predetermined first length from the clamping point exit of the clamp;
[0008] The corrected amplitude is obtained by calculating based on the degree to which the first position deviates from the theoretical installation position, the simplified model, and the amplitude.
[0009] Furthermore, the construction of a theoretical deflection model for the vibration of the overhead conductor when the vibration meter is installed at a preset theoretical installation position of the overhead conductor, and the simplification of the theoretical deflection model to obtain a simplified model, specifically includes: constructing an approximate differential equation for the deflection axis based on the deflection of the overhead conductor to obtain a first equation and a second equation; integrating both sides of the first equation to obtain a third equation; simultaneously solving the second equation and the third equation to calculate a fourth equation; simplifying the third equation and the fourth equation to obtain a fifth equation; integrating both sides of the fifth equation to obtain a sixth equation; and simplifying the sixth equation to obtain a seventh equation.
[0010] Furthermore, the first equation is specifically equation (1), and the second equation is specifically equation (2):
[0011]
[0012] M(x)=F(Lx) (2)
[0013] The third-party program is specifically defined as formula (3):
[0014]
[0015] The fourth equation is specifically equation (4):
[0016]
[0017] Where y is the deflection at the preset second position next to the clamp of the overhead conductor, F is the force on the overhead conductor at the second position next to the clamp, x is the length of the push arm of the vibration meter, M is the torque applied to the overhead conductor by the clamp, dx is the infinitesimal element of the overhead conductor, L is the length of the overhead conductor affected by its stiffness, C is the constant obtained after integration, θ is the rotation angle at the end of the cantilever beam, and EI is the stiffness of the overhead conductor.
[0018] Furthermore, the fifth equation is specifically equation (5):
[0019]
[0020] The sixth equation is specifically equation (6):
[0021]
[0022] The seventh equation is specifically equation (7):
[0023]
[0024] Where y is the deflection at the preset second position next to the clamp of the overhead conductor, F is the force on the overhead conductor at the second position next to the clamp, x is the length of the push arm of the vibration meter, M is the torque applied to the overhead conductor by the clamp, dx is the infinitesimal element of the overhead conductor, L is the length of the overhead conductor affected by its stiffness, C is the constant obtained after integration, θ is the rotation angle at the end of the cantilever beam, and EI is the stiffness of the overhead conductor.
[0025] Furthermore, the step of calculating the corrected amplitude based on the degree of deviation of the first position from the theoretical installation position, the simplified model, and the amplitude specifically includes: calculating the eighth equation based on the seventh equation; obtaining the deviation distance of the contact point of the roller of the vibration meter from the clamp on the overhead conductor; and calculating the corrected amplitude based on the deviation distance, the amplitude, and the eighth equation.
[0026] Furthermore, the eighth equation is specifically equation (8):
[0027]
[0028] Where y2 is the amplitude, y1 is the corrected amplitude, and Δx is the deviation distance.
[0029] This invention also provides a device for correcting the field vibration measurement results of overhead conductors, comprising:
[0030] The theoretical model construction module is used to construct a theoretical deflection model of the overhead conductor when the vibration meter is set at a preset theoretical installation position of the overhead conductor, and to simplify the theoretical deflection model to obtain a simplified model.
[0031] An amplitude measurement module is used to obtain the amplitude measured by a vibration meter located at a first position on the overhead conductor; wherein, the first position is a position on the overhead conductor at a predetermined first length from the clamping point exit of the clamp.
[0032] The correction module is used to calculate the corrected amplitude based on the degree to which the first position deviates from the theoretical installation position, the simplified model, and the amplitude.
[0033] This invention also provides a computer-readable storage medium storing a computer program that, when executed by a processor, implements the steps of the above-described method for correcting the field vibration measurement results of overhead conductors and ground wires.
[0034] This invention also provides a computer device, including a processor, a memory, and a computer program stored in the memory and configured to be executed by the processor. When the processor executes the computer program, it implements the steps of the above-described method for correcting the field vibration measurement results of overhead conductors.
[0035] In summary, the present invention has the following beneficial effects:
[0036] By employing the embodiments of the present invention, the problem of the vibration meter's measurement position shifting when using suspension clamps, damping clamps, anti-vibration hammer clamps, and spacer bar clamps can be addressed. The amplitude measured by the vibration meter can be corrected, thereby effectively correcting the field vibration measurement results of overhead conductors and ground wires to obtain more accurate field vibration measurement results, and thus better verifying the effectiveness of the line vibration damping device in practical applications. Attached Figure Description
[0037] Figure 1 This is a schematic diagram illustrating the background technology of a method for correcting the field vibration measurement results of an overhead conductor provided by the present invention;
[0038] Figure 2 This is another schematic diagram of the background technology of the method for correcting the field vibration measurement results of an overhead conductor provided by the present invention;
[0039] Figure 3 This is a flowchart illustrating an embodiment of a method for correcting field vibration measurement results of overhead conductors provided by the present invention.
[0040] Figure 4 This is a schematic diagram of an embodiment of an overhead conductor ground wire field vibration measurement result correction device provided by the present invention. Detailed Implementation
[0041] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0042] See Figure 3 This is a flowchart illustrating an embodiment of the method for correcting field vibration measurement results of overhead conductors provided by the present invention. The method includes steps S1 to S3, as follows:
[0043] S1. Construct a theoretical deflection model of the overhead conductor when the vibration meter is set at a preset theoretical installation position of the overhead conductor, and simplify the theoretical deflection model to obtain a simplified model.
[0044] It should be noted that, see Figure 1 When the clamp is a suspension clamp, the theoretical installation position is when the overhead conductor is not covered with aluminum tape. The vibration meter is fixed to the overhead conductor by the vibration meter clamp, and the connection between the vibration meter and the vibration meter clamp is connected to the roller of the vibration meter by a push arm. The roller is fixed at the clamping point outlet of the suspension clamp.
[0045] Or see Figure 2 When Δx is zero, that is, when the clamp is a damping wire clamp, a vibration damper clamp, or a spacer bar clamp, the theoretical installation position is when the roller of the vibration meter is fixed at the clamping point outlet of the clamp, and the contact point between the roller of the vibration meter and the overhead ground wire coincides with the clamping point outlet of the clamp.
[0046] As an improvement to the above scheme, the construction of a theoretical deflection model of the overhead conductor when the vibration meter is installed at a preset theoretical installation position of the overhead conductor, and the simplification of the theoretical deflection model to obtain a simplified model, specifically includes: constructing an approximate differential equation of the deflection axis based on the deflection of the overhead conductor to obtain a first equation and a second equation; integrating both sides of the first equation to obtain a third equation; simultaneously solving the second equation and the third equation to calculate a fourth equation; simplifying the third equation and the fourth equation to obtain a fifth equation; integrating both sides of the fifth equation to obtain a sixth equation; and simplifying the sixth equation to obtain a seventh equation.
[0047] Preferably, the first equation is specifically equation (1), and the second equation is specifically equation (2):
[0048]
[0049] M(x)=F(Lx) (2)
[0050] The third-party program is specifically defined as formula (3):
[0051]
[0052] The fourth equation is specifically equation (4):
[0053]
[0054] Where y is the deflection at the preset second position next to the clamp of the overhead conductor, F is the force on the overhead conductor at the second position next to the clamp, x is the length of the push arm of the vibration meter, M is the torque applied to the overhead conductor by the clamp, dx is the infinitesimal element of the overhead conductor, L is the length of the overhead conductor affected by its stiffness, C is the constant obtained after integration, θ is the rotation angle at the end of the cantilever beam, and EI is the stiffness of the overhead conductor.
[0055] Preferably, the fifth equation is specifically equation (5):
[0056]
[0057] The sixth equation is specifically equation (6):
[0058]
[0059] The seventh equation is specifically equation (7):
[0060]
[0061] Where y is the deflection at the preset second position next to the clamp of the overhead conductor, F is the force on the overhead conductor at the second position next to the clamp, x is the length of the push arm of the vibration meter, M is the torque applied to the overhead conductor by the clamp, dx is the infinitesimal element of the overhead conductor, L is the length of the overhead conductor affected by its stiffness, C is the constant obtained after integration, θ is the rotation angle at the end of the cantilever beam, and EI is the stiffness of the overhead conductor.
[0062] It is understandable that the second position is any position on the overhead conductor near the clamp. The second position is a variable quantity, so that the relevant equations can be constructed by selecting sufficiently dense positions.
[0063] For example, x is the length of the push arm of the vibration meter, which is 89 mm.
[0064] S2, obtain the amplitude measured by the vibration meter set at the first position of the overhead conductor; wherein, the first position is a position on the overhead conductor at a predetermined first length from the clamping point outlet of the clamp;
[0065] S3, calculate the corrected amplitude based on the degree to which the first position deviates from the theoretical installation position, the simplified model, and the amplitude.
[0066] As an improvement to the above solution, the step of calculating the corrected amplitude based on the degree of deviation of the first position from the theoretical installation position, the simplified model, and the amplitude specifically includes: calculating the eighth equation based on the seventh equation; obtaining the deviation distance of the contact point of the roller of the vibration meter from the clamp on the overhead conductor; and calculating the corrected amplitude based on the deviation distance, the amplitude, and the eighth equation.
[0067] Preferably, the eighth equation is specifically equation (8):
[0068]
[0069] Where y2 is the amplitude, y1 is the corrected amplitude, and Δx is the deviation distance.
[0070] It should be noted that the derivation process of equation (8) is as follows: The length of the push arm of the vibration meter is 89mm. According to equation (7), y1 and y2 can be calculated as follows:
[0071]
[0072]
[0073] Therefore, the ratio of y2 to y1 is:
[0074]
[0075] The length L of the overhead conductor affected by its stiffness in the above formula cannot be determined, but the length of L must be much greater than 0.089 and Δx. Therefore, relative to the denominator L, the numerators 0.089 and Δx can be ignored. Thus, the above formula can be simplified to formula (8).
[0076] Accordingly, see Figure 4 The present invention also provides a field vibration measurement result correction device for overhead conductors and ground wires, which can realize all the processes of the field vibration measurement result correction method for overhead conductors and ground wires provided in the above embodiments.
[0077] This invention provides a device for correcting the field vibration measurement results of overhead conductors, comprising:
[0078] The theoretical model construction module 101 is used to construct a theoretical deflection model of the overhead conductor when the vibration meter is set at a preset theoretical installation position of the overhead conductor, and to simplify the theoretical deflection model to obtain a simplified model.
[0079] The amplitude measurement module 102 is used to acquire the amplitude measured by the vibration meter set at the first position of the overhead conductor; wherein, the first position is a position on the overhead conductor at a predetermined first length from the clamping point outlet of the clamp;
[0080] The correction module 103 is used to calculate the corrected amplitude based on the degree to which the first position deviates from the theoretical installation position, the simplified model, and the amplitude.
[0081] This invention also provides a computer-readable storage medium storing a computer program that, when executed by a processor, implements the steps of the above-described method for correcting the field vibration measurement results of overhead conductors and ground wires.
[0082] This invention also provides a computer device, including a processor, a memory, and a computer program stored in the memory and configured to be executed by the processor. When the processor executes the computer program, it implements the steps of the above-described method for correcting the field vibration measurement results of overhead conductors.
[0083] The computer device in this embodiment includes a processor, a memory, and a computer program stored in the memory and executable on the processor, such as a field vibration measurement result correction program for overhead conductors. When the processor executes the computer program, it implements the steps in the above-described embodiments of the field vibration measurement result correction methods for overhead conductors, for example... Figure 1 The steps S1 to S3 are shown. Alternatively, when the processor executes the computer program, it implements the functions of each module / unit in the above-described device embodiments, such as steps 101 to 103.
[0084] For example, the computer program may be divided into one or more modules / units, which are stored in the memory and executed by the processor to complete the present invention. The one or more modules / units may be a series of computer program instruction segments capable of performing a specific function, which describe the execution process of the computer program in the computer device.
[0085] The computer device may be a desktop computer, laptop, handheld computer, or cloud server, etc. The computer device may include, but is not limited to, a processor and memory. Those skilled in the art will understand that the schematic diagram is merely an example of a computer device and does not constitute a limitation on the computer device. It may include more or fewer components than illustrated, or combine certain components, or different components. For example, the computer device may also include input / output devices, network access devices, buses, etc.
[0086] The processor can be a Central Processing Unit (CPU), or other general-purpose processors, digital signal processors (DSPs), application-specific integrated circuits (ASICs), field-programmable gate arrays (FPGAs), or other programmable logic devices, discrete gate or transistor logic devices, discrete hardware components, etc. The general-purpose processor can be a microprocessor or any conventional processor. The processor is the control center of the computer device, connecting various parts of the computer device via various interfaces and lines.
[0087] The memory can be used to store the computer programs and / or modules. The processor implements various functions of the computer device by running or executing the computer programs and / or modules stored in the memory and by calling data stored in the memory. The memory may mainly include a program storage area and a data storage area. The program storage area may store the operating system, at least one application program required for a function (such as sound playback function, image playback function, etc.), etc.; the data storage area may store data created according to the use of the mobile phone (such as audio data, phonebook, etc.). In addition, the memory may include high-speed random access memory, and may also include non-volatile memory, such as hard disk, memory, plug-in hard disk, smart media card (SMC), secure digital (SD) card, flash card, at least one disk storage device, flash memory device, or other volatile solid-state storage device.
[0088] Wherein, if the modules / units integrated into the computer device are implemented as software functional units and sold or used as independent products, they can be stored in a computer-readable storage medium. Based on this understanding, all or part of the processes in the methods of the above embodiments of the present invention can also be implemented by a computer program instructing related hardware. The computer program can be stored in a computer-readable storage medium, and when executed by a processor, it can implement the steps of the various method embodiments described above. The computer program includes computer program code, which can be in the form of source code, object code, executable files, or certain intermediate forms. The computer-readable medium can include: any entity or device capable of carrying the computer program code, recording media, USB flash drives, portable hard drives, magnetic disks, optical disks, computer memory, read-only memory (ROM), random access memory (RAM), electrical carrier signals, telecommunication signals, and software distribution media, etc.
[0089] In summary, the present invention has the following beneficial effects:
[0090] By employing the embodiments of the present invention, the problem of the vibration meter's measurement position shifting when using suspension clamps, damping clamps, anti-vibration hammer clamps, and spacer bar clamps can be addressed. The amplitude measured by the vibration meter can be corrected, thereby effectively correcting the field vibration measurement results of overhead conductors and ground wires to obtain more accurate field vibration measurement results, and thus better verifying the effectiveness of the line vibration damping device in practical applications.
[0091] Through the above description of the embodiments, those skilled in the art can clearly understand that the present invention can be implemented by means of software plus necessary hardware platforms, and of course, it can also be implemented entirely by hardware. Based on this understanding, all or part of the technical solution of the present invention that contributes to the background art can be embodied in the form of a software product. This computer software product can be stored in a storage medium, such as ROM / RAM, magnetic disk, optical disk, etc., and includes several instructions to cause a computer device (which may be a personal computer, server, or network device, etc.) to execute the methods described in various embodiments or some parts of the embodiments of the present invention.
[0092] The above description represents the preferred embodiments of the present invention. It should be noted that those skilled in the art can make various improvements and modifications without departing from the principles of the present invention, and these improvements and modifications are also considered to be within the scope of protection of the present invention.
Claims
1. A method for correcting field vibration measurement results of overhead conductors, characterized in that, include: A theoretical deflection model of the overhead conductor and ground wire vibrates when the vibration meter is set at a preset theoretical installation position of the overhead conductor and ground wire is constructed, and the theoretical deflection model is simplified to obtain a simplified model. Obtain the amplitude measured by a vibration meter set at a first position on the overhead conductor; wherein, the first position is a position on the overhead conductor at a predetermined first length from the clamping point exit of the clamp; The corrected amplitude is calculated based on the degree to which the first position deviates from the theoretical installation position, the simplified model, and the amplitude. The process of constructing a theoretical deflection model of the overhead conductor when the vibration meter is installed at a preset theoretical installation position of the overhead conductor, and simplifying the theoretical deflection model to obtain a simplified model, specifically includes: constructing an approximate differential equation of the deflection axis based on the deflection of the overhead conductor to obtain a first equation and a second equation; integrating both sides of the first equation to obtain a third equation; simultaneously solving the second equation and the third equation to calculate a fourth equation; simplifying the third equation and the fourth equation to obtain a fifth equation; integrating both sides of the fifth equation to obtain a sixth equation; and simplifying the sixth equation to obtain a seventh equation. The first equation is specifically equation (1), and the second equation is specifically equation (2): (1) (2) The third-party program is specifically defined as equation (3): (3) The fourth equation is specifically equation (4): (4) in, y The deflection at a predetermined second position next to the clamp of the overhead ground wire. F The force exerted on the overhead ground wire at the second position next to the clamp is [the force]. x The length of the push arm of the vibration meter is 89 mm. M The torque applied to the overhead ground wire by the clamp. dx This is a micro-element of the overhead ground wire. L The length of the overhead ground wire affected by its stiffness. C The constant obtained after integration, θ For the end rotation angle of the cantilever beam, EI The stiffness of the overhead ground wire; The fifth equation is specifically equation (5): (5) The sixth equation is specifically equation (6): (6) The seventh equation is specifically equation (7): (7) in, y The deflection at a predetermined second position next to the clamp of the overhead ground wire. F The force exerted on the overhead ground wire at the second position next to the clamp is [the force]. x The length of the push arm of the vibration meter is [length missing]. M The torque applied to the overhead ground wire by the clamp. dx This is a micro-element of the overhead ground wire. L The length of the overhead ground wire affected by its stiffness. C The constant obtained after integration, θ For the end rotation angle of the cantilever beam, EI The stiffness of the overhead ground wire; The step of calculating the corrected amplitude based on the degree of deviation of the first position from the theoretical installation position, the simplified model, and the amplitude specifically includes: Based on the seventh equation, the eighth equation is calculated; The deviation distance between the contact point of the roller of the vibration meter and the clamp on the overhead conductor is obtained. Based on the deviation distance, the amplitude, and the eighth equation, the corrected amplitude is calculated; The eighth equation is specifically equation (8): (8) in, The amplitude, The corrected amplitude. The deviation distance is mentioned.
2. A device for correcting the field vibration measurement results of an overhead conductor, characterized in that, include: The theoretical model construction module is used to construct a theoretical deflection model of the overhead conductor when the vibration meter is set at a preset theoretical installation position of the overhead conductor, and to simplify the theoretical deflection model to obtain a simplified model. An amplitude measurement module is used to obtain the amplitude measured by a vibration meter located at a first position on the overhead conductor; wherein, the first position is a position on the overhead conductor at a predetermined first length from the clamping point exit of the clamp. The correction module is used to calculate the corrected amplitude based on the degree to which the first position deviates from the theoretical installation position, the simplified model, and the amplitude. The process of constructing a theoretical deflection model of the overhead conductor when the vibration meter is installed at a preset theoretical installation position of the overhead conductor, and simplifying the theoretical deflection model to obtain a simplified model, specifically includes: constructing an approximate differential equation of the deflection axis based on the deflection of the overhead conductor to obtain a first equation and a second equation; integrating both sides of the first equation to obtain a third equation; simultaneously solving the second equation and the third equation to calculate a fourth equation; simplifying the third equation and the fourth equation to obtain a fifth equation; integrating both sides of the fifth equation to obtain a sixth equation; and simplifying the sixth equation to obtain a seventh equation. The first equation is specifically equation (1), and the second equation is specifically equation (2): (1) (2) The third-party program is specifically defined as formula (3): (3) The fourth equation is specifically equation (4): (4) in, y The deflection at a predetermined second position next to the clamp of the overhead ground wire. F The force exerted on the overhead ground wire at the second position next to the clamp is [the force]. x The length of the push arm of the vibration meter is 89 mm. M The torque applied to the overhead ground wire by the clamp. dx This is a micro-element of the overhead ground wire. L The length of the overhead ground wire affected by its stiffness. C The constant obtained after integration, θ For the end rotation angle of the cantilever beam, EI The stiffness of the overhead ground wire; The fifth equation is specifically equation (5): (5) The sixth equation is specifically equation (6): (6) The seventh equation is specifically equation (7): (7) in, y The deflection at a predetermined second position next to the clamp of the overhead ground wire. F The force exerted on the overhead ground wire at the second position next to the clamp is [the force]. x The length of the push arm of the vibration meter is [length missing]. M The torque applied to the overhead ground wire by the clamp. dx This is a micro-element of the overhead ground wire. L The length of the overhead ground wire affected by its stiffness. C The constant obtained after integration, θ For the end rotation angle of the cantilever beam, EI The stiffness of the overhead ground wire; The step of calculating the corrected amplitude based on the degree of deviation of the first position from the theoretical installation position, the simplified model, and the amplitude specifically includes: Based on the seventh equation, the eighth equation is calculated; The deviation distance between the contact point of the roller of the vibration meter and the clamp on the overhead ground conductor is obtained. Based on the deviation distance, the amplitude, and the eighth equation, the corrected amplitude is calculated; The eighth equation is specifically equation (8): (8) in, The amplitude, The corrected amplitude. The deviation distance is mentioned.
3. A computer-readable storage medium having a computer program stored thereon, characterized in that, When the program is executed by the processor, it implements the method for correcting the field vibration measurement results of overhead conductors as described in claim 1.
4. A computer device, characterized in that, It includes a processor, a memory, and a computer program stored in the memory and configured to be executed by the processor, wherein the processor executes the computer program to implement the method for correcting the field vibration measurement results of overhead conductors as described in claim 1.