Description and evolution
One of the main drivers of urban freight transport has been the continuedComponents
Urban freight distribution can include the following components, depending on the location of the urban area:Seaports
Seaports allow ships to dock and transfer people or cargo to or from land. Seaports handle a variety of goods including cargo shipped byAirports
Airports, and more specificallyWarehouses and distribution centers
A distribution center is a warehouse or other specialized building that receives, stores, and distributes goods to a variety of destinations such as retail stores, businesses, consumers, manufacturing facilities, or other distribution centers.Railways and railyards
Railroads haul a variety of goods such as intermodal containers, bulk goods, and other specialized cargo such as automobiles. In the United States, railroads are most commonly used to transport cargo over distances of 1,000 to 2,000 miles. Railroads are complemented by rail yards that allow freight from shippers to be trucked in, transferred onto railcars, and for trains to be assembled. There are three railroad classes in the United States: Class I, II, and III. According to the Association of American Railroads, Class I railroads had a minimum carrier operating revenue of $433.2 million in 2011. There are seven Class I railroads in the United States: BNSF Railway,Roads
In the United States,Benefits
The efficient and timely distribution of freight is critical for supporting the demands of modern urban areas. Without freight distribution, urban areas could not survive, grow, and flourish. Freight distribution also generates significant economic benefits. For example, the Bureau of Transportation Statistics (BTS) estimates that in 2012, the freight industry (defined as rail, water, truck, and pipeline transportation, support activities for transportation, couriers and messengers, and warehousing and storage) employed over 4.3 million people and paid total wages of almost $184 billion, for an average wage of over $42,000US annually. Furthermore, for-hire transportation services contributed $481 billion to U.S. gross domestic product in 2013.Challenges
There are a number of challenges resulting from urban freight distribution, including traffic congestion, environmental impacts, and land use conflicts. * The use of older trucks that emit a higher amount of emissions and have fewer safety features relative to newer trucks. * The prevalent use of diesel fuel in the goods movement industry generates NOx and PM2.5 emissions that can have significant air quality impacts. * Insufficient or inadequate truck parking and/or loading zones can result in illegal truck double parking, parking in bicycle lanes, or parking in center median lanes. * Conflicts between trucks and automobiles, pedestrians, and bicyclists can occur in dense urban areas due to high vehicle volume, inadequate arterial capacity, inadequate intersection turning radii for trucks, and/or the increasing implementation of "Complete Street" elements such as bicycle lanes. These conflicts can result in congestion, parking, and safety impacts. * The use of modern, longer trucks, particularly in highly dense urban areas or older industrial areas with inadequate intersection width can result in turning movement conflicts between trucks and other roadway users that can increase congestion, have safety impacts, and damage curbs, sidewalks, traffic signals, and signs. * Within urban areas, the length and frequency of freight trains have resulted in growing congestion, noise, air quality, and safety impacts at at-grade crossings where trains and roads intersect. As a result, local jurisdictions have taken the initiative to construct road/rail grade separations to eliminate these conflicts. Notable examples include the Alameda Corridor and Alameda Corridor East programs in southern California, and the Chicago Region Environmental and Transportation Efficiency Program (CREATE). * Land use conflicts can arise when goods movement facilities are located in close proximity to non-industrial land uses such as schools, residences, and parks. These conflicts can result in noise, air quality, and congestion impacts that may require significant mitigation measures. For example, the proposed Southern California International Gateway railyard that would be operated by the BNSF Railway just north of the Port of Los Angeles and Port of Long Beach would provide mobility and environmental benefits by enabling more intermodal containers to travel via rail instead of truck. However, the project has also generated protests and a lawsuit due to the proximity of the proposed facility to residential neighborhoods in West Long Beach, California. These issues affect not only the efficiency of freight distribution but also the quality of life of citizens and public health.Policy and planning
In the United States, urban freight policy and planning is conducted at the federal, state, regional, and local levels. At the federal level, freight planning and policy is guided by the Fixing America's Surface Transportation Act (FAST) that establishes the National Multimodal Freight Policy and National Freight Strategic Plan. In addition, the FHWA Office of Freight Management and Operations conducts freight research, develops analytical tools and data, and organizes freight professional development programs. At the state level, state Departments of Transportation (DOTs) are primarily responsible for planning, designing, constructing, and maintaining the highway system within the state. As part of the FAST Act, states were given additional roles and responsibilities for freight planning. States are now required to establish a State freight advisory committee as well as develop a comprehensive State freight plan. Freight planning at the regional level is conducted by Metropolitan Planning Organizations (MPOs). MPOs are required in urbanized areas with a population greater than 50,000 and are mandated by the federal government to develop plans for transportation, growth management, hazardous waste management and air quality. An MPO must have a "continuing, cooperative and comprehensive" (3C) transportation planning process that results in plans and programs consistent with the comprehensively planned development of its corresponding urbanized area. The two primary roles of an MPO are to prepare the Regional Transportation Plan (RTP) and Transportation Improvement Program (TIP). The RTP presents a 20-year transportation vision for the region and provides a long-term investment framework for addressing the region's transportation and related challenges. The RTP addresses all modes of transportation including highway and transit projects, as well as high-speed regional transport. Projects must be included in the RTP to be eligible for state and federal funding. The TIP is a listing of proposed transportation projects to be funded through a variety of federal, state and local sources over the next six years in the respective region. In addition, some MPOs convene freight advisory committees that bring together public and private sector representatives to plan for freight in the region. One example is the Delaware Valley Regional Planning Commission Goods Movement Task Force. Counties and local cities are primarily responsible for design, construction, and maintenance of the local roadway network within a county or city. This includes capacity enhancements, pavement maintenance, sidewalks, street lighting, signals, and signage. From a freight perspective, cities also designate local truck routes, Surface Transportation Assistance Act (STAA) terminal access routes, and parking and loading zones. In some cases, counties also collect and allocate locally generated tax revenue for transportation projects.Strategies
A variety of strategies exist and have been proposed or implemented by governments and private industry that help address the challenges of urban freight distribution. The range of strategies includes infrastructure, operational, technological, and policy:Infrastructure
* Construction of dedicated truck lanes or truck climbing lanes to reduce congestion and improve safety * Physical infrastructure improvements such as lane or intersection widening to reduce conflicts between trucks and other users of the roadway * Construction of road/rail grade separations to remove conflicts between freight trains and vehicular traffic * Increased investment in highway, rail, and transit infrastructure maintenance that will result in significant congestion, safety, and economic benefits. Currently, the Federal Highway Administration estimates that $170 billion in capital investment would be needed on an annual basis to significantly improve conditions and performance.Operational
* Designating truck routes and truck parking/loading zones to better facilitate goods movementand reduce conflicts * Inland distribution centers to reduce congestion in dense urban areas * Extended business operating hours to allow night-time delivery of goodsTechnological
* The use of information and communication technologies such asPolicy
* Restricting truck delivery to off-peak hours to minimize congestion and maximize use of existing infrastructure * Financial assistance, fees, and taxes (e.g., cordon pricing, congestion charges, area licensing, etc., as in London, Stockholm and Milan) * Truck weight or size restrictions, as appropriateLand use/facility design
* Better land use planning to locate freight facilities away from residential neighborhoods or in a manner that minimizes conflicts with adjacent land uses * Improved freight facility design so as to reduce the impacts of those facilities to the surrounding community. This could include sufficient onsite truck parking and loading docks, landscaping, building materials, lighting design to reduce light impacts, buffer zones, and noise control policies and/or procedures. * Provision of truck parking and/or loading zones to facilitate local delivery of goodsRefrigerated freight
Consumers enjoy a best quality of life due to economic and societal changes, which imply several modifications in consumption. In fact, they can afford to consume more perishable products for example. Apart from that, the government has developed policies of "security of quality" and the regulation, obligating to add new products that need to be transported in refrigerated vehicles to the existing list. It is also obligatory to control the temperature of those vehicles during the delivery. Societal and legal requirements have obliged suppliers and transport companies to resort more frequently to the refrigerated urban freight distribution. The use of refrigerated transportation improved the quality of the service provided but it also implies high negative impacts for the urban environment and citizens' quality of life. The traditional system of refrigeration consumes more combustible, so it increases the emissions. Noise due to the refrigeration system and the type of combustible used can also be a problem in urban zones.Technology used
Most of the food that needs to be refrigerated is transported by road through the use of vehicles equipped with an isolated structure. Many factors are evaluated during the design of the units for refrigerated food transportation, for example: * The weather conditions * The indoor climatic conditions * The properties of the insulation system that will be used * The possible infiltration of air and moisture, etc. The refrigeration system used to transport food is based on vapor compression that ensures the maintenance of certain conditions such as temperature in function of the quantity and type of food transported. The units that use this technique can work at full thus allowing controlled transport of refrigerated loads.Energy consumption and environmental impact
The energetic efficiency of the refrigerated boxes of the modes of transport has more importance depending on the region of the world. The rise in combustible prices and the environment evolution are other aspects that companies need to take into account. The combustible consumption depends on the refrigerated system which has to be in relation with the kind of goods transported (refrigerated products as fruit and vegetables can travel at a 0 °C temperature and frozen products need a temperature lower than 20 °C). The contamination is due to a combination of factors such as the pattern use of the refrigeration system, the type of product transported, the exposition to the sun, the density of the refrigerant, the setting of the control system such as modulation and the activation/deactivation of the compressor. In some cases, energy consumption for the distribution of fresh food can be higher than for the transportation of frozen food, because of stricter controls in terms of product and because it breath more air to keep the uniform temperature during the distribution.Transport through a passive-cooling system
According to a study (A. Ghirardi, 2003), the exportation and the distribution of fruit and vegetables are affected by the high cost of the environmental impact. The systems and technologies currently used are expensive, not compatible with the environment and not sustainable. The transit time is a central aspect in export operations, and it has to take into account multiple factors, even imponderable as the quality of the product at destination. The passive refrigeration system allow to solve the problem of quality preserving, making the time of surrender compatible with the combined transport and independent of the energy source during the running, allowing also the use modes of transport without electrical connection. An examination of the critical factors of refrigerated transport and characteristics of the passive refrigeration system emerges a synergy capable of solving the key aspects, and in particular: * Coefficient of deterioration of the products obtained from the combination of factors such temperature, relative humidity and ventilation. These parameters are maintained in optimal conditions in the vehicle equipped with a passive refrigeration system that guarantee a longer life for the product that it transport compared to the traditional refrigeration mechanisms. * Competitive costs for the transport For distribution in urban areas, the saturation of the traffic and the propensity of cities to limit the flow of vehicles for goods distribution require the optimization of the logistics and distribution chain. This optimization is realizable by employing passive-cooling container units that are independent of loading and transport and allow the use of the same mode, also non-refrigerated, for the distribution using only one mode to deliver its order to the stores, keeping the products at an optimum temperatures and consistent with autonomy.See also
* Modes of transport * Green procurement * Emission standard *Projects related to urban freight distribution
* Best Urban Freight Solution (BESTUFS) * Emission Free Refrigerated Urban Distribution (EFRUD)References
Studies carried out on urban freight distribution
* Ogden (1992), offered one of the first studies on urban freight movements * Garrido and Regan (2000) defined a general framework for freight demand models * Routhier and Aliii (2001) made a comparison of methods developed and results obtained in urban goods movements * Allen and Aliii (2003), Browne and Alliii (2001) * Kohler (1999): in Germany, they focused on piloting city logistics schemes * Russo, F. and Comi, A. (2010). A modelling system to simulate goods movements at an urban scale. In Transportation 37 (6), DOI: 10.1007/s11116-010-9276-y, Springer Science+Business Media, LLC, 987 - 1009. * Nuzzolo et al. (2010). Politiche della Mobilità e Qualità delle Aree Urbane, Guida Editori, Naples, Italy. * Russo, F. and Comi, A. (2011). Measures for sustainable freight transportation at urban scale: expected goals and tested results in Europe. In Journal of Urban Planning and Development 137 (2), DOI: 10.1061/(ASCE)UP.1943-5444.0000052, American Society of Civil Engineers (ASCE), 142–152. * Comi, A., Delle Site, P., Filippi, F. and Nuzzolo, A. (2012). Urban Freight Transport Demand Modelling: a State of the Art. In European Transport/Trasporti Europei 2012 (51), ISTIEE, Trieste, Italy * Taniguchi E., Thompson R.G., Yamada T. (1999) Modelling city logistics. City Logistics I (Taniguchi E., Thompson R.G., eds.), Institute of Systems Science Research, Kyoto * Russo F., Comi A. and Polimeni A. (2008) Urban freight transport and logistics: Retailer's choices. In: Innovations in City Logistics (E. Taniguchi And R. G. Thompson eds.), Nova Science Publishers, Hauppauge Ny (USA), 2008, * Russo, F. (2013) Modelling behavioral aspects of urban freight movements. In: Freight Transport Modelling (M. Ben-Akiva, H. Meersman, E. Van de Voorde eds.), Emerald Group Publishing. * Polimeni A., Russo F. and Vitetta A (2010). Demand and routing models for urban goods movement simulation. European Transport/Trasporti Europei, vol. 46 (3); pp. 3–23.External links