PRE2018 3 Group3
The Dutch railway network is one of the most crowded railway networks on the planet [1]. An intercity leaves the station every 10 minutes. The Dutch trains are also very punctual; 90% of the trains are on time [2] with a 5 minute tolerance. This is a rare accomplishment among railway companies. However, there is a downside to all of this; when something does go wrong, it goes wrong big time. Because the railway network is so crowded, one delay can create a congestion and in turn this can cause huge delays.
A major cause for delay are leaves or snow on the train tracks. Trains crush the leaves beneath them, which makes the track slippery. Snow has the same effect and this is bad, because the braking distance increases tremendously. This can lead to dangerous situations. Railway companies (like the NS) try to avoid these risks by canceling their trains. However, this leads to some confusion and frustration of the travelers, since a delay caused by a couple of leaves on the tracks does not sound very dangerous.
We as a group think we can improve this sticky situation by introducing a robot to the Dutch railway network that is able to clean the tracks from obstacles like leaves and snow. This wiki describes the whole process of this project.
Group Members
Name | Study | ID Number |
---|---|---|
Max Hanssen | Industrial Design | 1257269 |
Jorick van Hekke | Electrical Engineering | 1225185 |
Suryanto Horlez | Computer Science | 1286714 |
Joeri Schults | Mechanical Engineering | 1266330 |
Jules Vaes | Mechanical Engineering | 1263196 |
Project information
The information about this project can be found by following this link: Project information
Concept
Our goal is to design a robot which is able to autonomously clean the railway tracks from different kinds of obstacles.
The robot should be able to clean the tracks autonomously, but it should have a camera installed so that an operator can inspect it from time to time (‘man-on-the-loop’). This is also important for exceptional cases in which the robot does not know what to do.
Initially, we did not know what the major problems on the train tracks were, so we decided to contact ProRail (the company in charge of the Dutch railway network). They told us that the main obstacles on the Dutch tracks are leaves and snow, so our robot should focus on addressing these issues.
The idea is to use sweepers to collect leaves and snow. The snow can be melted which makes it harmless for the tracks, while the leaves can be compressed and used as compost. At first we wanted the robot to combat rust as well, but ProRail said the following: “It is the case that the track is ridden every day so rust formation is actually not possible. In areas where fewer trains ride, empty trains are often used at night to prepare the track so that the formation of rust cannot actually occur or is prevented as much as possible.” Based on this statement, we decided that it was not worth focussing on.
Objectives
- The system must be able to navigate through the Dutch railway system autonomously
- The system must be able to recognize the different obstacles on the railway
- The system must be able to clean the railway from obstacles autonomously.
- For special occasions the system must alert the involved companies
- The system must provide a short-term solution for certain problems
- The system must avoid colliding with obstacles
- The system must be deployable at any time
- The system must not hinder the human operated train traffic
RPC's
Requirements
- The robot is autonomous, i.e. it can navigate autonomously through the Dutch railway system
- The robot is able to collect the waste (mainly leaves and snow) it removes
- The robot is able to differentiate different types of waste and sort them accordingly
Preferences
- The robot should be easy to maintain
- The robot should be lightweight
- The robot should be compact
- The robot should be cleaning as fast as possible
Constraints
- The robot has to clean in between train schedules, so it has a limited time window in which it can clean train tracks
- The robot cannot remove large objects like trees, debris or dead animals
USE aspects
Users
For this project the focus has been put on the railroads in the Netherlands. This decision was made, because it is only possible to design the product for one certain type of railroad system. At this stage designing a product which can be used globally by adapting to different types of railway systems is too advanced. Furthermore, the project would have too many potential users to focus on, as they will differ per country. Therefore, it was decided to stick to the Netherlands, as this is the country which we had the most experience with. Although it was decided to keep the focus in this specific area, there is still a wide variety of users. For this design there are people who can use and influence the design directly, as well as people who get influenced indirectly by the design. Hence, a distinction can be made between primary and secondary users. The term primary users will be used to refer to the group of users who are directly interacting with the design. The term secondary users will be used to refer to the group of users who are not directly in contact with the design but still affected by it. The distinction between these two different users will be made more clear by defining both groups.
Primary users
For this design, the group who buys, uses and introduces the design into its target scenario are considered as the primary users. Hence, the organisations who are responsible for the railway system in the Netherlands belong to this groups. Thus, only Prorail is the primary user, as they are the ones responsible and can make direct changes to the railway system. The NS can not be fully considered as a primary user, as they only make use of the railway system, but are not responsible for the railroad itself. Prorail are the ones responsible for the construction, maintenance, management and security of the railway system in the Netherlands. When a product with the aim to clean the railroads is used, Prorail is the main company to introduce, use, and interact with the product.
Secondary users
For this design, the people who get influenced positively or negatively by this design in an indirect way are considered as the secondary users. As mentioned above the NS is not considered as primary user, instead NS can be considered as a secondary user. They make use of the railway system in the Netherlands by transporting people from location to location with trains that drive on the railroads. Therefore, they will not be in direct contact with this design, as they will only get positively influenced but cannot influence the design itself directly. The use of the design on the railroads will be a great advantage to the NS, as it will make the railroads free and safe which reduces the delay for trains of NS.
In addition to NS, this reduction in delay also has a positive effect on the users of NS. These users are people who make use of the trains of NS as transportation to get to their destination as fast as possible. Although NS and Prorail are in charge of the trains and railways in the Netherlands, this group of travelers is important and can also be considered as secondary users.
Occasionally, trains of foreign companies such as Thalys or NMBS also make use of the railway system in the Netherlands. As a result, these foreign train companies can also be considered as secondary users. However, this group of users will not be further addressed, as the main focus is put on the companies NS and Prorail.
Society
Obstacles on the railroads, which cause a delay for many travelers, can be considered as a problem to society. In some occasions the delay can come up to major amounts of time or even cancellations of trains, which leads to missing important meetings or appointments. Moreover, this can form a challenge to the government, as the NS is a Dutch state-owned company. This means that the government has significant control over the NS through majority ownership. For this reason, one of the main aims of the government is to make transportation more accessible to its users. To be able to make transportation on railway more accessible, the delays of trains need to be taken care of. This design can help with solving this challenge to society. The design of this project can not fully solve the challenge of it, as there are many factors which have an influence on causing delays in transportation. However, this design will still have a positive impact on this relevant problem. It has the potential to play a big role in the future of railroad maintenance which is beneficial to society.
Enterprise
In the USE aspects, enterprise is considered to be the relevant companies that are connected to the project. The main aim for these enterprises is to make as much profit as possible. The previously discussed primary user Prorail can be seen as a relevant enterprise to this design. Although currently Prorail is still a government task organisation company that is part of NS, the Ministry of Infrastructure and Water is planning to make Prorail a public law independent administrative in 2021 [3]. As a result Prorail will become an organisation which conducts governmental tasks, while they are not under authority of the Dutch government. Hence, in the future Prorail will look at this design from a business perspective. They will only decide to make use of this design if it is profitable for the company. Unless they are forced by the government as they will be an independent administrative. Therefore, the design is required to be efficient in general, as well as cost-efficient so that Prorail will have good consequences from using the product.
Obstacles
Snow & ice
Problem
- In very cold periods like in the winter, snow and ice can build up on the tracks. The ice can block movable parts of the track and coat over the power lines or the third rail, preventing trains from drawing the power they need to run. Also icicles on bridges and tunnels can cause serious damage to passing trains. All these problems can cause the trains to have delays. https://www.networkrail.co.uk/feeds/keeping-trains-moving-snow-ice/
- When a train has to slow down as it approaches a station or set of points, snow can get compact on the rails and turn into solid ice. This not just clogs the point but also enables them from working and can coat the rails, disconnecting the trains from getting the needed power. Ice sheets are a risk for dislodging and damaging trains, the steel rails can freeze together when it gets to cold what makes the signals stay red preventing the trains to move. When snow drifts are deeper than 30cm , trains can no longer run safely unless they have snow ploughs.
- https://www.networkrail.co.uk/running-the-railway/looking-after-the-railway/delays-explained/snow-and-ice/
Solution
Bleach,Salt
Using these products we can lower the rate of freezing cause during the freezing and melting process some water molecules freeze while others melt, replacing each other in a state of equilibrium, while when one of these products are added in the mixture it disrupts this equilibrium. https://sciencing.com/way-melt-ice-heat-5505463.html
Laser
CO2 Lasers can be used to melt ice and snow with a wavelength of 10.6 μm ,which ice strongly absorbs, to drill (via melting) through ice. The resulting drilling speed is measured at several irradiation intensities, ice-snow densities, and beam angles relative to the horizontal axis. The speed increases nearly in proportion to the laser intensity. https://www.sciencedirect.com/science/article/pii/S0165232X15002116
snow plough
A snow plough can be used to clear the train rails when there is more than 30cm of snow, we could use this one the robot to make it possible to clear the rails for other trains, at the moment this is already installed on normal trains when the snow is higher than 30cm. https://www.networkrail.co.uk/feeds/keeping-trains-moving-snow-ice/
Leaves
Problem
In the Autumn trees will drop their leaves which might land on the railway. At first the leaves will not cause any trouble, but during the day they will cause problems. If the leaves which landed on the railhead become moist and heavily compressed by the passing trains, they will result in a low-friction coating. Due to this low-friction coating the railway becomes slippery and the wheels of the train starts to block when it is starting to brake. Due to this blocking one side wheels will experience more wear than the other sides which results in “square-wheels” [4]. These “square-wheels” need to be repaired in workshop which costs time and money. Due to the malfunctioning and repairing of the train wheels less trains will be deployed on trajects which is not preferred by the travellers. Another problem due to the low-friction coating is that it can take up to 800 meters extra to come to a total stop [5].
Solutions
Leaf blower
A leaf blowers is used to blow loose leaves away from their initial position. This could be useful for the trains because they can blow the leaves away from the railhead. But this is not an option anymore. Due to the high compressing the leafy moist is stuck to the railway, therefore the leaf blower is not able to blow the leafy moist away [4].
Laser
Lasers are used for all kind of operations but when operating at a wavelength of 1064 nm it becomes useful for the railway. Due to a carefully designed optical set-up of mirrors and lenses the laser was able to produce a series of pulses, 25.000 per second, at this wavelength which cleared the track from debris. The highly compressed leaves on the railway absorbs the pulses, each with a temperature of 5.000 Celsius degrees. Due to this high temperature the leaves heats up rapidly which causes it to expand and lift of the railway [5].
Pressure washer
A pressure washer is used to clean object from a dirty layer which is stuck to the surface. Therefore the pressure washer can be used to remove the compressed layer of leaves from the railway. An example of a product which is already tested is the Nilfisk-ALTO developed by Nilfisk-Advance for the Banedanmark, the railway organization in Denmark. The Nilfisk-ALTO has a 7000 liter water tank and operates at a pressure of 500 bar and sprays 40 L/min. The wagon achieved to clean the railway from the leaves when it runs at an operating speed of 45 km/h [6].
Traction Gel Applicator
Traction gel applicator (TGA) is a substance which consists out of sand, metal particles and starch [7] . The TGA system consists of a sensor and 50 meters further the cabinet. The cabinet contains the electronics, a pump, a delivery hose, the substance and is solar powered. The sensor, which gets triggered by the wheels of the train, sends a signal to the cabinet that a train is coming. The pump of the cabinet then places some TGA on the railhead via a delivery hose. When the train passes the cabinet the TGA gets stuck on the wheels and this gives the train more traction for a short distance, 60 to 200 meters [8]. Due to this short distance the TGA cabinets are typically placed at the entries and exits of a train station [9].
Sweeper
A sweeper can be used to remove dirt from surfaces. The brushes can be made out of metal or pig’s bristles. For a train the brushes are made out of steel and the sweeper operates at a high torque which makes it possible to remove snow, coal, stones, dust, sand, leaves, trash and dirt from the railway [10]. When the high-speed rail is left out the maximum speed a train can achieve in the Netherlands is 160 km/h [11]. This means that the brushes have to rotate at a speed higher than 160 km/h. For this research a minimum speed of 200 km/h is a requirement for the brushes. A common diameter for the broom is 915 mm, the broom diameter of the Dymax rail sweeper is equal to 915 mm[12] and the diameter of the KM90/120 is also equal to 915 mm[13]. Therefore the brush diameter of the robot is fixed at 915 mm. Most motors have their speed specification in rotations per minute (RPM). The speed in km/h of the motor depends on the diameter of the, in this case, the diameter of the brushes. The diameter is fixed at 915 mm and the minimum speed is 200 km/h therefore the minimum RPM can be calculated using the following equation
v = d x RPM x 0.001885 (1)
where v is the speed in km/h, d is the diameter in cm and RPM is the speed in rotations per minute. Using 200 km/h and 915 mm for the diameter a minimal RPM of 1160 is needed to operate at a sufficient speed. When searching for already used rail sweepers the RPM is too low to use in our robot. After some research the LSRPM 132 M permanent magnet synchronous motor (PMSM) was found which has the following important specifications in the operation range of 1500 RPM[14]:
- Rated power P_n = 12 kW
- Efficiency η = 92.0 %
- Rated torque T = 69 Nm
- Rated current I = 21 A
- Weight = 49 kg
The sizes are shown in picture ???. The RPM of a motor can be obtained using the following equation
RPM =P/T (2)
where P is the power in Watts and T is the torque in Nm. Filling in the data of the LSRPM 132 M a RPM of 1660 is obtained. Converting this RPM into km/h using (1) gives 286.44 km/h. This is a high enough speed to operate which means that the motor is also able to operate at a lower RPM which consumes less power, this also results in a lower required current.
Rust
(Contacted prorail not really a critical problem)
Conclusion
Discussion
Literature search
Sources
- ↑ Ramaekers, P., De Wit, T., & Pouwels, M. (2009, February 27). Hoe druk is het nu werkelijk op het Nederlandse spoor? CBS.
- ↑ NS jaarverslag 2017 https://www.nsjaarverslag.nl/jaarverslag-2017/resultaten4/a1054_Punctualiteit
- ↑ Kamerbrief 19 oktober 2018, Omvorming ProRail, October 2018. Retrieved from https://www.internetconsultatie.nl/wet_publiekrechtelijke_omvorming_prorail/document/3990
- ↑ 4.0 4.1 A.Pel (2016) Die rotblaadjes op het spoor; waarom doen ze niets? https://www.metronieuws.nl/nieuws/binnenland/2016/11/die-rot-blaadjes-op-het-spoor-waarom-doen-ze-niets
- ↑ 5.0 5.1 Railway Technology (2007) Tackling a Leafy Issue https://www.railway-technology.com/features/feature1457/
- ↑ Nilfisk (2010) High pressure washer on track https://www.nilfisk.com/en/news/Pages/HPW_on_wheels.aspx
- ↑ Prorail (2013) Sandite: slim recept tegen blad op het spoor https://www.prorail.nl/nieuws/sandite-slim-recept-tegen-blad-op-het-spoor
- ↑ DIPOSTEL, Datasheet: Traction gel http://dipostel.com/wp-content/uploads/2017/01/gel-de-traction_ang.pdf
- ↑ jsdrail, Traction Gel Applicators http://www.jsdrail.com/engineering/traction-gel-applicators/9.htm
- ↑ Railroad Tools and Solutions (LLC), Rail Sweeper http://www.rrtoolsnsolutions.com/PowerTools/rail-sweeper.asp
- ↑ Nederlandse Spoorwegen (NS), Hogesnelheidslijn https://www.ns.nl/over-ns/dossier/hogesnelheidslijn
- ↑ Dymaxinc, Dymax rail sweeper for skid steers https://dymaxinc.com/attachments/dymax-rail-sweepers/
- ↑ Overaasen Snowremoval Systems, Railroad Brushes (KM90, 2KM90H and KM120H) https://www.overaasen.no/railroad_equipment/brushes/railroad_brush/
- ↑ LSRPM - Dyneo, Permanent magnet synchronous motor 3 to 350 kW - 1500 to 5500 RPM http://www.leroy-somer.com/documentation_pdf/4936_en.pdf