NL1040393C2 - METHOD FOR PERFORMING AND REALTIME MONITORING WORK ON THE INFRASTRUCTURE OF NETWORK COMPANIES. - Google Patents

Description

Method for performing and real-time monitoring of work on the infrastructure of network companies

The present invention relates to a method for carrying out work on the network of network companies, such as network managers of electricity and gas and water companies, in a uniform, safe manner with the possibility of real-time remote monitoring.

When performing work on a network, for example connecting a home to the natural gas network or remedying malfunctions in an existing connection and all other work performed on networks, following strict protocols and safety regulations is an absolute condition. In addition to the quality of connections made to a network, such as being gas-tight for a gas connection, care must be taken, for example, during excavation work to ensure that pipes already underground are not damaged. To this end, the person who is to carry out the work, hereinafter also referred to as a convenience engineer, will have to study the data still known under the name KLIC. KLIC stood for Cables and Pipelines Information Center, which was based on self-regulation. Since 2008, the KLIC information is managed by the Land Registry and the Information Exchange Underground Networks Act, WION, applies. In accordance with this law, it is mandatory to submit a excavation report to the Land Registry Office for every 'mechanical soil stirring'. Cable and pipeline managers must have all their (underground) cables and pipelines digitally available within specified accuracy and must present them if Kadaster so requests.

The purpose of the law is to prevent danger or economic damage caused by damage to underground cables or pipes (water, electricity and gas pipes, telephone lines and oil pipes).

Until now, for checking compliance with the regulations when carrying out work on a network of a network manager, it is necessary that someone is present on site to check the engineer (s). This has a significant effect on costs.

The invention relates to a method which forces a fitter per step of his work, hereinafter also referred to as project step, or per part of a project step, to view the regulations associated with that step and to confirm that he has viewed those regulations and to recording all relevant information regarding the relevant step before it can proceed to the next step or to the next part of the step. In an embodiment of the method according to the invention, a fitter uses a mobile device, for example a so-called tablet PC, with which he can log in via the internet into a computer system of the client and into other relevant systems and databases, hereinafter also separately referred to collectively as the information system, to view information about or related to the work to be performed and to enter the information to be provided by him. The information system can also include programs in the 'cloud'.

The method makes it possible that, for example, a supervisor of the remote network manager can follow the work of one or more technicians in real time.

The method according to the invention will now be elucidated on the basis of a number of figures, which are examples of embodiments of screen images which a technician will see when applying the method to his tablet or other portable computer, hereinafter mainly referred to as tablet. An important feature of the method according to the invention relates to the use of GPS for determining and registering the correct location, date and time at different steps in the process.

As a first step, a technician will have to log into the information system via a login screen. After logging in, the engineer has rights in the information system up to the level that the client has assigned the engineer. This prevents unauthorized access. If desired, the invention provides that the technician identifies himself via biometric data, for example a fingerprint, with the aid of a mobile fingerprint scanner, or by an iris scan with the aid of an iris scanner.

The engineer is then assigned an assignment.

FIG. 1 is a schematic embodiment of a screen shot which a technician is shown as the first screen for a new job, also referred to as a project.

As can be seen in the left-hand column, this is the second assignment for a technician from a series of six assignments. In the actual screenshot, the status of this will be indicated under 'assignment'. Normally, assignment 1 will be executed before the technician starts with assignment 2. This is then indicated in the screen, but omitted in Fig. 1 because of the limited space. In the actual situation it will also be possible, for example, to display a drop-down menu under the designation 'assignment 2' in the left-hand column with a summary of sub-steps or of relevant instructions or regulations.

The screen also shows the address details of the location where the work is to be performed. The information system, comprising a computer system, whether or not in the cloud, for applying the method according to the invention comprises measures for automatically using GPS to compare the place where the fitter with his tablet is located and the address where he is working must perform. If these do not match, the engineer immediately receives an automated warning to alert him to the discrepancy that has been found.

This screen also gives a general description of the work, a summary of the necessary personal protective equipment (PPE) and tools and a report of details that the engineer must take into account. After studying this information, the technician can start the actual assignment via the 'START COMMAND' button.

FIG. 2 shows a schematic embodiment of a first screen shot for the first step of the project. The first sub-step of this project step comprises viewing the connection sketch by clicking on the 'VIEW SKETCH' button and confirming that the connection sketch has been viewed by clicking on the 'OK' button. When the 'VIEW SKETCH' button is clicked, the technician receives an image, for example as a so-called pop-up, of the sketch on his screen. An embodiment of such a display is shown schematically in Fig. 3. After studying the sketch, the technician can click on the 'CLOSE' button and return to the screen shown in Fig. 2.

As can be seen in the exemplary embodiment shown in Fig. 2, the following sub-step comprises viewing the deposition instruction. The method always comprises the confirmation that a (sub) step has been carried out. After confirmation, a check mark appears on the screen, for example in a green color.

The method comprises the application of measures that prevent a technician from starting the next (sub) step before the previous one has been correctly completed.

FIG. 4 and FIG. 5 schematically represent what the fitter sees when he goes through the next two sub-steps according to the screen shown in FIG. FIG. 4 gives a schematic example of a table which normally contains relevant Codata and FIG. 5 is a highly abstracted schematic example of a cadastral sketch with information about the underground pipes and cables present in the area concerned for the KLIC excavation report. If the technician does not have a KLIC number, he can find out via the screen how he can obtain a KLIC number. The engineer can then go to the next step via the 'CONTINUE' button.

With the codata that the engineer has to send, fraud cannot be made thanks to a GPS link to the location where the engineer is with his tablet.

FIG. 6 is a schematic exemplary embodiment of the screen shot of the first screen associated with step 2. In this screen a description is given of the work to be performed. The engineer must then, with his tablet, first take one or more photos of the existing situation and upload these photos to the system. The method comprises the possibility of deleting added photos, for example because they appear to be blurred or otherwise have no added value according to the technician on closer inspection. However, at least one photo must be permanently saved, after which the next action can only be taken.

FIG. 7 shows a rough, sketchy example of a photograph of excavation work in which a person is standing in a dug pit. The person taking the photo can choose between saving or deleting the photo via buttons on the screen.

FIG. 8 shows an exemplary embodiment of a following screenshot, still associated with step 2, with a detailed description of the work. In this example, as a replacement of a gas meter and a service pipe, the fitter must take photographs of the existing situation, namely the existing gas meter, the state of (part of) the existing service pipe and the assembly of exposed after digging. underground pipes and cables at the location of the service pipe connection. These photos are added and can therefore also be viewed directly by a remote supervisor. Based on this, the supervisor can intervene, if necessary or desirable, by contacting the engineer by telephone and discussing the situation. In an extreme case, the supervisor can stop the work. The invention provides that before the meter is replaced, the fitter enters the meter readings in the screen and takes such a picture of the existing meter that the meter readings and the meter's EAN code are legible.

FIG. 9 shows an exemplary embodiment of the first screen of step 3. This is the screen that leads the engineer to the work plan and the parts. The engineer must read the work plan and then confirm that he has read it.

On the right side of the screen, the technician can view the pictures he has taken and saved at any time. On the right-hand side of the screen, the time to be spent on the work to be performed is also indicated. The method according to the invention comprises of automatically keeping track of the elapsed time from the start of the order and calculating it against the time available according to the schedule.

FIG. 10 shows a schematic exemplary embodiment of a screenshot of the work instructions, whereby documents, for example PDF documents, can be called up from this screen with details of / explanations of the work instructions. The viewing of those documents must also be confirmed in order to have a high degree of certainty that the technician knows well what to do. The work instructions may also include visual material. The work instructions may also have a link with national safety regulations.

FIG. 11 shows diagrammatically an exemplary embodiment of a screen associated with step 5, in which illustrations of the materials associated with the installation of a gas connection of the PeKo type are shown. The technician will have to check whether he has the required materials in his possession and must confirm this by touching an 'OK' key on the screen.

FIG. 12 shows diagrammatically an exemplary embodiment of a screen associated with step 6 with regard to the prescribed and inspected tool. This step prevents the use of defective tools.

FIG. 13 relates to a schematic exemplary embodiment of the screen associated with step 7, testing an installation. If the test result is not good, the system guides the engineer to the action to be taken according to the method. As a final point in step 7, as evidence in this example, a photo should be made of a printout of the press result. The exemplary embodiments shown in FIG. 14, FIG. 15 and FIG. screen images belonging to steps 8, 9 and 10 speak for themselves and require no further explanation.

Step 11 concerns, as shown in Fig. 17, the completion notification of the work.

FIG. 18 shows a schematic embodiment of the screen in which the data of the new meter, a sketch of the new connection and an overview of the materials used can be entered. The sketch of the new connection can, for example, be entered by means of a photograph of a hand-made sketch as schematically shown in Fig. 19.

FIG. 20 relates to a schematic representation of a screen of an exemplary embodiment of the method according to the invention for the step of removing old materials, cleaning up the workplace and updating the codata. At least one photo of the tidy workplace must be added.

The invention provides that the method can be divided into steps and sub-steps in a different way than the one followed in the exemplary embodiment discussed. In a preferred embodiment, the method comprises the steps shown in the block diagram shown in Fig. 21. These steps do not always have to be followed in the order shown schematically in FIG. Some steps can take place at a different time. There are also steps, in particular steps that take place in an automated manner, which cannot take place simultaneously but simultaneously.

The first step shown in Fig. 21, also referred to as step A, comprises identifying and authorizing the fitter who will perform the work.

This can be done in various ways, including for example by having him log in by entering a personal user name and login code / password or by using, for example, a mobile fingerprint scanner or an iris scanner. When a technician logs in, a database in which, based on training and certifications, the powers of technicians are registered, it is checked whether a technician is authorized to perform the intended work.

The second step, step B, comprises determining location, date and time with the aid of GPS and the comparison thereof with the address data according to the order.

Step C includes viewing and / or sending location-related information such as Codata, a KLIC digger notification, etc.

Step D includes viewing the work plan, followed by step E viewing and applying work instructions.

In multiple steps in the process, including the work instructions, the fitter is obliged to view the work-related rules with, for example, any associated national safety rules and to confirm that he has viewed them before continuing the process.

Step E includes releasing the installation.

The remaining steps speak for themselves. What is not shown in the diagram is the fact that the invention provides that the method by the fitter at various relevant moments in the process of making video recordings, including photos or video images, of, for example, the situation before starting work, also called the old situation, and the situation after his work has been completed, also called the new situation. Such photos, which are provided with location data, date and time thanks to the GPS link, can serve multiple purposes, including recording a situation for future work (repair, modification, etc.) and checking the work of the technician, both afterwards as real-time remote.

Furthermore, the method comprises the possibility of using image material, including photos and video images, in the instruction material.

In the claims, the part of the infrastructure of a network company on which a technician carries out work will also be referred to as 'installation'.

The method offers a supervisor the possibility to prevent the continuation of the activities remotely by blocking the possibility for a technician to go to the screen associated with a next step or sub-step.

The exemplary embodiments of the method according to the invention discussed in this description and shown in the figures are only some of the many possible embodiments within the scope of the invention and should therefore be regarded as non-limitative.

Claims (8)

A method for carrying out work on the infrastructure of network companies, characterized in that the method comprises the use of a portable computer with communication means by a fitter and the following steps: a. Identification of a fitter; b. using GPS to determine the location of the technician and the date and time; c. viewing and / or sending location-related information related to the work to be performed; d. viewing work instructions and consulting related rules; e. release of work performed; f. the recording of visual material of the installation or a part thereof in the old situation and the new situation and of steps or sub-steps belonging to the work on the installation and making this material accessible via storage in an information system. Method according to claim 1, characterized in that the identification of a technician comprises entering a user name and password and / or a biometric scan. Method according to claim 1 or 2, characterized in that the location-bound information to be viewed and / or transmitted according to the method comprises codata and / or KLIC data. Method according to one or more of the preceding claims, characterized in that the regulations related to the work instructions comprise national safety regulations. Method according to one or more of the preceding claims, characterized in that the method of confirming the completion of the previous step or sub-step for being able to continue a step or being able to start to a next step or sub-step. Method according to one or more of the preceding claims, characterized in that the work instructions for the fitter comprise visual material, including photos or video images. Method according to one or more of the preceding claims, characterized in that a remote supervisor can prevent the continuation of the work by blocking a next step or sub-step to be started by the fitter. An information system for applying the method according to one or more of claims 1-7.