PRE2017 3 Groep3

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Subject

Window cleaning robots

Objectives

  • Literature study of current window cleaning robots and USE aspects regarding window cleaning robots.
  • To develop an efficient cleaning algorithm that cleans a window which satisfies certain requirements on cleaning speed, water consumption, energy consumption.

Users

Window washing companies that can use window cleaning robots to improve their services. The considered scenario is that these companies are hired by private individuals to clean the windows of their houses. The faster and cheaper these companies can accomplish this, the more profit they can make. A major help for this purpose would be to develop an algorithm that determines how to clean the windows of a house in the most efficient way possible when the dirt distribution on the windows is taken into account.

The user needs need to be determined in order to develop the model.

State-of-the-art

The list below gives an overview of the summaries of the articles which have been studied. The articles are divided into subcategories.

Window cleaning robot design

Issues encountered while performing cleaning task

Movement over façade

Movement over window

Acceptance of robots and engagement with robots

Figures belonging to the summaries will be added later.

Approach

  1. Literature study of current window cleaning robots and USE aspects regarding window cleaning robots
  2. Analysis of the user and user needs
  3. To develop an algorithm that models one side of a house and the separate windows within this side, for which the most efficient cleaning trajectory is developed and where the dirt distribution on the window is taken into account. The numbers for the efficiency, water consumption and energy consumption obtained from this model can then be compared to the predetermined standard based on the performance of current window cleaning systems on the market.


Planning, milestones & deliverables

Week Goal Milestones Deliverables
1
  • Finish work plan
  • Finish literature study and SotA
Finished literature study and SotA
  • Work plan
  • Summaries of articles
2
  • Confirm definitive subject and project goal
  • Adapt the project planning
Clear and measurable project goal
  • Project planning
3
  • Divide the possible approaches to window-cleaning algorithms, and research them
  • Start the basis of the algorithm/ simulation
  • Precisely anylise users and user needs
  • Create a list of precise measurables and ways to achieve these numbers
  • Research potential simulation programs and get handy with the coding skills needed
Clear vision of the project to all members and a definitive goal and approach to the problem
  • Sheet of potential algorithms with their pro and cons
  • Definitive program in which model simulations will be done
4
  • Check whether algorithm satisfies the requirements, preferences, and constraints of the group, adapt the algorithm accordingly.
  • Choose a definitive algorithm approach and start the programming of the simulation
Definitive algorithm which can be simulated and results in the measurables wanted. (close to completion simulation)
  • Finished or close to finished programmed model simulation
5
  • Analysis of the simulation; expected results, satisfying results?
  • Further improvements to the algorithm.
  • Start writing report
Finished and analyzed model.
  • Measurables compared to expectations.
6
  • Start report work; divide chapters into; introduction, theory, algorithm, simulation, results, conclusion, future improvements and appendices.
Finished report
  • Correct report and simulation
7 Buffer time for last details and unexpected issues.


Task division

Week What? Who?
1
  • Finish work plan
  • Finish literature study and SotA (Everybody searches 5 articles, reads them and summarizes them)
  • Everybody together
  • Everybody
2
  • Finish analysis of the user and user needs
  • Edit project planning and update wiki with references
  • Finish SotA
  • Lars, Kylian
  • Ibrahim, Jorick
  • Ezra
3
  • Specify the model design
  • Program a basic window in Netlogo
  • Research implementation of water usage
  • Research implementation of energy usage
  • Coaching questions + update planning and division of tasks on wiki
  • Kylian
  • Lars
  • Ibrahim
  • Ezra
  • Jorick
4
  • Start modeling the motion planning of the robot into Netlogo
  • Research comparisson values for the robots results
  • Write report about the first half of the project
  • Lars, Jorick, Kylian
  • Ezra, Ibrahim
  • Ezra, Ibrahim
5
  • Analysis of the simulation results, compare to controll values
  • Improve and possibly expand algorithm
  • Write about algortihm
  • Re-check wether all defined needs, preferences and requirements are satisfied by the model
  • Jorick, Ibrahim
  • Lars, Kylian
  • Ezra
  • Ezra,
6
  • Finish model
  • Compare final results from model with controll values
  • Finish report
  • Lars, Jorick
  • Kylian, Ibrahim
  • Everybody
7 ... ...


Work on the model

Setup of the model

For the setup of the model (the concept, assumptions and simplification, etc.), we would like to refer to the report, see the section below.

Current state of the model (week 3)

In this week a window is programmed on which a random dirt distribution appears. See the figure below.

V1model.JPG

Current state of the model (week 4)

Text

Work on the report

The current state of the report can be seen by using the following link: [1].

Water Consumption

In order to create a realistic model for the robot algorithm, water usage should be implemented. There are a few decisions and assumptions that have to be made in order to create a strategy for the water consumption. Firstly the water supply; Moon[1] presents a table in which the water consumption of existing window cleaning robots are shown, the majority of these robots use ten to hundreds of liters of water per hour to do their job. In comparison to a window cleaner worker who uses approximately 5 liters of water an hour. This difference is not shocking, because the efficiency of the window cleaning robots are much higher, the robots clean more surfaces and use more water an hour. Yet this difference is also due to the size of the robots. For example the BFMR robot, which is thoroughly analyzed by Moon, has a size of 1600x1970x545 mm, weighs about 300 kg and uses 8.7-10.8 L/Hour. The majority of the window cleaning robots that have high use and performance are often too big to clean smaller windows.

One of the decisions in our model is that the window cleaning robot will have small dimensions and will be used for the normal citizens windows. This assumption will lead to a robot of small weight and consequently to a robot which has less water usage and efficiency. In order to have a realistic measure to tackle the issue of planning efficiency, the modelled robot should use at least the amount of water a window cleaner uses in default cleaning mode (continuous zig zags without confirmation of fully cleanliness). In Moons analyzes five window cleaners cleaned a surface of 626.4 m2 in 2 hours including preparation time and intermission time. This would mean that a single window cleaner would clean approximately 62.5 m2 an hour using 5 liters of water. The strategy of window cleaners is prominently cleaning from top to bottom measuring cleanliness by eye. Due to this the best way to tackle the water consumption is by equaling the model-robots water consumption in default mode to a window cleaner abilities. This means that the model-robot should use 5/62.5 = 0.08 L of water per m2 per hour as a constant value. This value indicates that if the robot is preforms one lap of zig zags on top of an area of 62.5 m2 the robot should use 5 L total and preform this in 1 hour. To note is that this value does NOT include double laps due to levels of dirtiness.

The reason why the abilities of a window cleaner are set as a default for the robot are: The cleaning strategy will now determine whether the robot will be more efficient than an average window cleaner; if the robot has to make double laps the time taken will be longer than the average window cleaner.


Coaching Questions

Coaching Questions Group 3

The links below refer to pages with the coaching questions of each week.

References

[1] Akinfiev,T. Armada,M. & Nabulshi,S. (2009). Climbing cleaning robot for vertical surfaces. Industrial Robot: An International Journal, Vol. 36 Issue: 4 pp.352-357.
[2] Barbut,O. (2008). Window Cleaning Robot ASME Design Competition. Department of Mechanical Engineering Toronto.
[3] Choi,Y. & Jung,K. (2011 November 26). WINDORO: The World's First Commercialized Window Cleaning Robot for Domestic Use. Pohang Institute of Intelligent Robotics Korea.
[4]Choi,Y-H. Lee,J-Y. Lee,J-D. & Lee,K-E. (2012 November 29).SMART WINDORO V1.0: Smart Window Cleaning Robot. Korea Institute of Robot & Convergence.
[5] Chu,B. Jung,K. Han,C. & Hong,D.(2010 August). A Survey of Climbing Robots: Locomotion and Adhesion. Department of Mechanical Engineering South Korea.
[6] Galceran,E. & Carreras,M.(2013 August 5).A survey on coverage path planning for robotics. University of Girona Spain.
[7] Gandhinathan, R. & Ambigai, R. (2016). Design and Kinematic Analysis of Tethered Guiding Vehicle (TGV) for façade window cleaning. Department of Mechanical Engineering India.
[8] Gerstmayr-Hillen,L et al. (2013 January 17). Dense topological maps and partial pose estimation for visual control of autonomous cleaning robot. Computer Engineering Group , Faculty of Technology Germany.
[9] Imoaka,N. Roh,S. Yusuke,N. & Hirose,S. (2010 October 22). SkyScraper-I: Tethered Whole Windows Cleaning Robot. Design of Moving Mechanisms and Preliminary Experiments Taiwan.
[10] Jiang,J. Zhang,Y. & Zhang,S. (2014).Implementation of glass-curtain-wall cleaning robot driven by double flexible rope. Industrial Robot: an International Journal, Vol.41 Issue: 5 pp.429-438.
[11] Katsuki,Y. Ikeda,T. & Yamamoto,M. (2011 September 30). Development of a High Efficiency and High reliable Glass Cleaning Robot with a Dirt Detect Sensor.
[12] Lee,J. Choi,Y. & Lee,J. (2013 November 2). Calculation of Optimal Magnetic Force for Automatic Control Magnetic Force of the Window Cleaning Robot. Korea Institute of Robot and Convergence Korea.
[13] Lee,S. Kang,M. & Han,C. (2012 December). Sensor Based Motion Planning and Estimation of High-rise Building Façade Maintenance Robot. Department of Mechatronics Engineering South Korea.
[14] Leidner,D. & Beetz,M. (2016 November 17). Inferring the Effects of Wiping Motions based on Haptic Perception.
[15] Lui,J. Tanaka,K. Bao,L M. & Yamaura,I.(2005 October 3).Analytic modeling of suction cups used for window-cleaning robots. Department of Functional Machinery and Mechanics Japan.
[16] Liu,J. Jiang,H. Li,Z. & Hu,H. (2009). A Small Window-Cleaning Robot for Domestic Use. Jiangnan University China.
[17] Liu, J. et al. (2011 May 9). A Gecko Inspired Fluid Driven Climbing Robot. Institute Of Mechatronic Control Engineering Zhejiang University.
[18] Lupetti,M L. Rosa,S. & Ermacora,G. From a Robotic Vacuum Cleaner to a Robot Companion: Acceptance and Engagement in Domestic Environments.
[19] Moon,S M. Shin,C Y. Huh,J. Won,K. & Hong,D. (2015 January). Window Cleaning System with Water Circulation for Building Façade Maintenance Robot and Its Efficiency Analysis. School of Mechanical Engineering South Korea.
[20] Nguyen,D. & Shimada,A. (2013). A Path Motion Planning For Humanoid Climbing Robot. Shibuara Institute of Technology Japan.
[21] Nishi,A. A wall climbing robot for inspection use. Miyazaki University Japan.
[22] Palleja,T. Transanchez,M. Teixido,M. & Palacin,J. (2009 August 11). Modeling floor-cleaning coverage performance of some domestic mobile robots in a reduced scenario. Department of Computer Science Spain.
[23] Seo,K. Cho,S. Kim,T. Kim,H S. & Kim, J. (2013 August 15). Design and stability analysis of a novel wall-climbing robotic platform (ROPE RIDE). Mechanism and Machine Theory pp.189-208.
[24] Zanele,G N M. (2011 June). Motion Planning Algorithms for Autonomous Robots in Static and Dynamic Environments. University of Johannesburg.
[25] Zhou,Q. & Li,X. (2016). Experimental comparison of drag-wiper and roller-wiper glass-cleaning robots. Industrial Robot: An International Journal, Vol.43 Issue:4, pp409-420.