Difference between revisions of "High-Speed Rail Safety"

From MIT Technology Roadmapping
Jump to navigation Jump to search
Line 42: Line 42:
| Operation cost || $/train || Operational cost for a round-trip of a train
| Operation cost || $/train || Operational cost for a round-trip of a train
|}
|}
== Alignment with Company Strategic Drivers ==
'''Strategic Driver:''' To develop a safe, comfortable, and punctual high-speed train system that can stop as quickly as possible to minimize the possibility of collision and derailment.
'''Alignment and Targets:''' The HSR Technology Roadmap will target a dedicated track-guided system with powerful brake that can decelerate at 1.5m/s^2 and an obstacle sensor system that can detect and respond to any dangerous obstacle immediately. This driver is currently aligned with the HSR technology roadmap.
The continuous goal for the railway business is to develop a safe and convenient train system that is attractive to potential passengers.  In the context of safety, the braking time should be as short as possible without injuring passengers due to a too intense jerk (jerk is the derivative of acceleration).  The simplest way to reduce the braking time is to reduce speed.  This approach is accepted by passengers when the train is traveling under bad conditions, such as heavy rain or mechanical troubles.  Also, the total weight (vehicle weight + passengers’ weight) of the train would affect the braking time.  In this context, reducing capacity would contribute to reduced braking time.  However, operating at reduced profitability and efficiency, by reducing operational speed and capacity, would negatively affect the attractiveness of the system to passengers.
== Positioning of Company vs. Competition ==
The figure below shows a summary of several types of high-speed rail systems, derived from public data. The Shinkansen in Japan has the largest capacity in the world and these trains are formally operated at a fixed number of cars.  In Europe and China, the number of cars can change flexibly based on regions’ needs and the types of models.  This flexibility better supports variabilities in demand but affects the operating cost and makes driving the vehicle more difficult.  Typically, operational speed is capped by sharpness of curves and the strength of track components and infrastructure.  China Railway has the highest operational speed supported by newer track and infrastructure and fewer sharp curves.  However, unconventional systems such as maglev and hyper-loop, using totally different propulsion and guiding systems, enables trains to be operated at much higher speeds. The SCMaglev is now under construction in Japan and operating in test mode, while Hyper-loop systems are still in a concept phase and need further development to their core system.  The table below also shows that the Acela Express is less efficient compared to other high-speed rail systems, with lower speed, less capacity, and heavier vehicles.
[[File:hsr.png|Positioning of High Speed Rail ]]

Revision as of 12:36, 5 November 2019

Roadmap Overview

High Speed Rail Overview

High-Speed Rail is a type of passenger rail transportation system that operates at high-speed with high voltage electricity. With respect for the multiple definitions for high-speed rail, the International Union of Railways defines high-speed rail as systems of rolling stock and infrastructure which regularly operate at or above 250 km/h on new tracks, or 200 km/h on existing tracks. Figure 8, above, shows the basic components of high-speed rail system. Rolling stock that obtain electricity from cable (as shown, or ground-based rail) as a power is operated by a driver who follows signals and communicates with one or more control centers. The dedicated or specifically upgraded tracks guide the train.

DSM Allocation

DSM showing integration with other supporting and enabling technology roadmaps

The DSM shows that the 2HSR is part of the mass transportation system in large context. It requires 3TVT Train Vehicle Technology, 3ELM Electricity Management, 3STM Structure Management, and 3TCS Traffic Control System. In addition, these level 3 technologies require level 4 technologies that are consist of 4 DRS Driving System of the vehicle such as motor, 4VHB Body of vehicles, 4CTS control system of the vehicle, 4PWG power generator or power plant of electricity, 4HVT technology for transmitting high voltage electricity, 4CIV converter and inverter inside the vehicle, 4TRF transforming electricity to appropriate voltage, 4TRM maintenance of tracks, 4CES maintenance of civil engineering structures such as bridges and tunnels, 4PRC route control system, 4EDP data processing unit, 4MAC technology for monitoring and communicating data.

Roadmap Model using OPM

OPM of High Speed Rail


The OPM describes the decomposition and primary function of HSR system. The level 1 decomposition of the system is Driver, Rolling Stock, Control Center and Infrastructure. Rolling Stock consists of physical components such as bogie and body. The main components of control center are Operator and Operation system that support drivers by providing information from several data sources and calculating the signal pattern. Infrastructure, such as tracks and signals, is the foundation of the system that physically and electrically support the operation.

Figures of Merit

Figure of Merit Units Description
Maximum speed km/hour Maximum operational speed of trains
Frequency # of trains/hour Number of operated trains per hour
Weight kg Weight of train
Brake force N Force to stop the train
Brake stopping distance m Distance that it takes to come to a complete stop
Capacity people/train Number of passengers carried by train
Strength of Body N/mm^2 Strength against crash
CO2 emission t/train/km Amount of CO2 emitted by electricity generation used for operating one train
Construction cost $/km Initial cost for constructing total railway system per 1 km
Operation cost $/train Operational cost for a round-trip of a train

Alignment with Company Strategic Drivers

Strategic Driver: To develop a safe, comfortable, and punctual high-speed train system that can stop as quickly as possible to minimize the possibility of collision and derailment.

Alignment and Targets: The HSR Technology Roadmap will target a dedicated track-guided system with powerful brake that can decelerate at 1.5m/s^2 and an obstacle sensor system that can detect and respond to any dangerous obstacle immediately. This driver is currently aligned with the HSR technology roadmap.

The continuous goal for the railway business is to develop a safe and convenient train system that is attractive to potential passengers. In the context of safety, the braking time should be as short as possible without injuring passengers due to a too intense jerk (jerk is the derivative of acceleration). The simplest way to reduce the braking time is to reduce speed. This approach is accepted by passengers when the train is traveling under bad conditions, such as heavy rain or mechanical troubles. Also, the total weight (vehicle weight + passengers’ weight) of the train would affect the braking time. In this context, reducing capacity would contribute to reduced braking time. However, operating at reduced profitability and efficiency, by reducing operational speed and capacity, would negatively affect the attractiveness of the system to passengers.

Positioning of Company vs. Competition

The figure below shows a summary of several types of high-speed rail systems, derived from public data. The Shinkansen in Japan has the largest capacity in the world and these trains are formally operated at a fixed number of cars. In Europe and China, the number of cars can change flexibly based on regions’ needs and the types of models. This flexibility better supports variabilities in demand but affects the operating cost and makes driving the vehicle more difficult. Typically, operational speed is capped by sharpness of curves and the strength of track components and infrastructure. China Railway has the highest operational speed supported by newer track and infrastructure and fewer sharp curves. However, unconventional systems such as maglev and hyper-loop, using totally different propulsion and guiding systems, enables trains to be operated at much higher speeds. The SCMaglev is now under construction in Japan and operating in test mode, while Hyper-loop systems are still in a concept phase and need further development to their core system. The table below also shows that the Acela Express is less efficient compared to other high-speed rail systems, with lower speed, less capacity, and heavier vehicles.

Positioning of High Speed Rail