Patent Application
20230417815
The present disclosure relates to a method for inspecting an insulation of a high voltage cable. Aspects relate to a system for inspecting an insulation of a high voltage cable.
High voltage (HV) cables generally include, from inside to outside: a conductor, an insulating layer, shield wires, and an outer sheath. In particular, an inner conductive layer is provided between the conductor and the insulating layer, and an outer conductive layer is provided on an outer side of the insulating layer. Processing of the HV cable is required for installing a HV cable accessory, like for example a cable termination or a cable joint. The processing includes peeling the outer conductive layer and may include subsequent grinding of the insulating layer, depending on the voltage rating of the cable. A conventional method of inspecting the processing result is a manual inspection of the insulating layer relying on tactile feedback, particularly by sliding a finger over the processed area. The quality of a manual inspection depends on the experience of the inspecting person.
Other conventional methods include measurement with a slide gauge or with a diameter tape. In general, conventional methods of inspecting the insulation of a HV cable after processing have limitations as to their reliability and replicability.
It is therefore an object of the present disclosure to overcome at least some of the above-mentioned problems in the prior art at least partially.
In view of the above, a method for inspecting an insulation of a high voltage cable is described. The method includes a data acquisition including scanning a surface of a high voltage cable's insulation by at least one laser scanner. The scanning includes moving the at least one laser scanner and the high voltage cable relative to each other along a length direction of the high voltage cable. The method further includes a data evaluation including: generating a 3-dimensional model of the scanned surface based on the acquired data.
According to an aspect, a system for inspecting an insulation of a high voltage cable is provided. The system includes an apparatus including at least one scanning assembly for scanning a surface of the high voltage cable. The apparatus further includes an attachment assembly configured for attaching the at least one scanning assembly to the high voltage cable. The at least one scanning assembly includes a linear axis and a laser scanner attached to the linear axis. The linear axis is configured to provide linear motion to the laser scanner. For evaluating data acquired by the at least one scanning assembly: the apparatus includes an electronic circuit configured to carry out the data evaluation of the method described herein, or the apparatus is connectable to a computer for transferring the acquired data to the computer and the system further includes a computer program product comprising instructions which, when the computer program product is executed by a computer, cause the computer to carry out the data evaluation of the method described herein.
Further advantages, features, aspects, and details that can be combined with embodiments described herein are evident from the dependent claims, claim combinations, the description, and the drawings.
The details will be described in the following with reference to the figures, wherein:
Reference will now be made in detail to the various embodiments, one or more examples of which are illustrated in each figure. Each example is provided by way of explanation and is not meant as a limitation. For example, features illustrated or described as part of one embodiment can be used on or in conjunction with any other embodiment to yield yet a further embodiment. It is intended that the present disclosure includes such modifications and variations. In particular, aspects relating to the systems described with regard to
Within the following description of the drawings, the same reference numbers refer to the same or to similar components. Generally, only the differences with respect to the individual embodiments are described. Unless specified otherwise, the description of a part or aspect in one embodiment can be applied to a corresponding part or aspect in another embodiment as well.
In the context of the present disclosure, a high voltage (HV) may be understood as a voltage higher than 1 kV for alternating currents or higher than 1.5 kV for direct currents. Additionally, a medium voltage (MV) may be defined as a voltage higher than 1 kV and lower than for example 35, 38, or 52 kV, particularly for alternating currents. Methods and systems according to the present disclosure can be especially suitable for HV cables and extra high voltage (EHV) cables. In this regard, the HV range is particularly to be understood as extending from voltages of at least 52 kV to voltages up to 170 kV. The EHV range is particularly to be understood as a range including voltages higher than 170 kV. The EHV range may extend up to e.g., 550 kV for alternating currents and up to e.g., 640 kV, 800 kV, or 1100 kV for direct currents.
The operation of a laser scanner may be summarized as follows: A laser line is projected onto a surface of the inspected object by an optical system and the reflected light is registered by a sensor matrix. Through the principle of laser line triangulation, distance as well as position information can be acquired from the surface of the object.
The method further includes, in a block 120, a data evaluation. The data evaluation includes, in a block 122, generating a 3-dimensional model of the scanned surface based on the acquired data.
According to an aspect, the scanned surface may include a full circumference of the high voltage cable. Scanning the complete processed cable area and particularly generating a corresponding complete 3D model is beneficial for defining tolerances for the insulation's state after processing. Quality assurance can thus be improved. In contrast, conventional methods of inspecting an insulation of a HV cable are based on a very limited number of measurement points. Moreover, a repeated measurement will typically occur at a different position of the insulating layer than the previous measurement. Conventional methods thus have limitations as to the replicability of their results.
Moreover, with conventional methods for inspecting a high voltage cable's insulation, particularly manual measurements on a limited number of positions, irregularities such as indentations, scratches, cavities, or elevations in or on the insulation surface can be overlooked. This poses a security risk, for example because air gaps could develop or lubricants like silicone oil could enter indentations, scratches, or cavities in the insulating material. The irregularities can also cause partial discharges that contribute to aging and damage of insulating material. The methods and systems according to the present disclosure, providing a 3D model of the insulation's surface, can mitigate the risk of overlooking such irregularities or other faults in the insulation.
According to an aspect, generating the 3-dimensional model may include combining measurement data from at least e.g., two or three laser scanners. As an example, measurement data from two, three or four laser scanners may be combined. By combining measurement data from at least two laser scanners, data from a full circumference of the HV cable can be included in the 3-dimensional model.
As to this, generating the 3-dimensional model may additionally or alternatively include: combining measurement data from at least two scans performed by one laser scanner at different positions along a circumference of the HV cable. As an example, measurement data from two, three or four scans performed by one laser scanner may be combined.
According to an aspect, the data evaluation may further include, in block 124, comparing the generated model with a reference 3-dimensional model. In particular, the generated model is examined for deviations from the reference model. A judgement about the state of the insulation surface can thus be made, based on a replicable measurement. It is made possible to define standard tolerances for the state of HV cable's insulation surface after processing.
The reference 3-dimensional model may be a partly predefined model of a surface of a high voltage cable's insulation. The partly predefined model may be adjusted based on the acquired data. For example, a diameter of the partly predefined model may be adjusted based on the acquired data.
The diameter of the partly predetermined model may be adjusted based on at least one of: a minimum diameter and a maximum diameter of the high voltage cable determined from the acquired data.
According to an aspect, the data evaluation may further include, in block 126, determining a state of the insulation of the high voltage cable, particularly of the insulation's surface, according to predefined criteria. The judgment of processing result quality can thus be based on a replicable inspection method. The determination of the state of the insulation may include calculating distance values between points of the generated 3-dimensional model and the reference 3-dimensional model.
According to an aspect, the data evaluation may further include an identification of irregularities on the surface of the insulation of the high voltage cable according to predefined criteria. The irregularities particularly include any of: indentations, scratches, cavities, or elevations. The identification may be automatic. Security risks associated with irregularities on the insulation's surface can thus be revealed. The method concludes in a block 130.
Methods and system according to the present disclosure can provide an improved quality of processing during HV accessory installation, including type testing. The fast and reliable evaluation of processing result quality can lead to reductions of the time required for HV accessory installation. A further advantage is that if a scan shows that the surface of an HV cable already has the required level of quality after a peeling process, subsequent grinding may be omitted. Thus, time and effort may be saved.
According to an aspect, the scanned surface area has a length of at least for example 0.1, 0.2, or 0.3 m along a main direction of extension of the high voltage cable. The length may be smaller than for example 1.0, 0.75, or 0.6 m. Generally, a length of the processed cable section, i.e. the section where the outer conductive layer is removed, depends on the accessory to be installed on the cable. The length may be for example 0.3 m or 1.5 m. It is nonetheless possible to use the same methods and systems for these different cases, because only a section of approximately 0.5 m is particularly important for the electric properties.
The at least one scanning assembly 210 includes a linear axis 212 and a laser scanner 214 attached to the linear axis 212. The linear axis 212 is configured to provide linear motion to the laser scanner 214. The linear axis may include a guide rail and a motor, particularly a servomotor.
The apparatus 200 further includes an attachment assembly 220 configured for attaching the at least one scanning assembly 210 to the HV cable 250. The attachment assembly may include at least one pair of legs attached to the linear axis 212. As depicted, the attachment assembly 220 may include for example respectively one pair of legs 222 attached on each end of the linear axis 212. The legs 222 particularly hold the scanning assembly 210 at an appropriate distance from the HV cable 250.
For evaluating data acquired by the scanning assembly 210, the apparatus 200 further includes an electronic circuit configured to carry out the data evaluation of the method described with regard to
In embodiments, the apparatus includes a plurality of laser scanners, for example at least two, three, or four laser scanners. The plurality of laser scanners is configured to jointly scan a full circumference of the HV cable. As an example, three laser scanners may be positioned respectively 120° apart along a circumferential direction of the cable. As another example, four laser scanners may be positioned respectively 90° apart along a circumferential direction of the cable.
In embodiments, the attachment assembly 220 may include a strap 224 for attaching the at least one pair of legs to the HV cable. As shown in the depicted embodiment, the attachment assembly 220 may include respectively one strap 224 attached to each of the pairs of legs 222. In an assembled state, the strap 224 may lead around the HV cable 250 for attaching the pair of legs 222 to the HV cable 250.
| Number | Date | Country | Kind |
|---|---|---|---|
| 22180574.0 | Jun 2022 | EP | regional |
