DE69816874T2 - TRANSPORT SYSTEM - Google Patents

Abstract

A mass transit apparatus for an endless travelling path is known, consisting of consecutive vehicles, which are articulately connected in an endless configuration so that said vehicles can be folded to a side by side position from a linear position. In order to improve the speed reduction or acceleration ratio said vehicles connected to each other by means of distance beams (10) are pivotably connected to said vehicles (1) at points located at both end parts of said vehicles. Horizontal steering means (4, 15) are arranged to cause said vehicles to pivot horizontally from said linear position to said side by side position and in reverse along certain parts of said endless travelling path.

Description

The invention relates to a Mass transit system or a mass transit facility for an endless Roadway, with successive vehicles that are articulated are so that they are out a linear arrangement are pivotable into a position in that they stand side by side.

Such a local transport facility is from CH-A-582593 known to which the preamble of claim 1 relates.

Currently in various locations public transport facilities in operation around the world suffice not the transportation requirements more populated Cities. The main disadvantages are the manufacturing costs, waiting times, station intervals and above all to see that they are not profitable for the owner are. The long-term profitability of a transport system is for its survival essential.

This patent application relates to a Improvement of currently known basic solutions for continuous transportation of local transport users. The solution, which is based on the trains being horizontal Can be folded, avoids waiting times at stations, can the distance between the stations to less than half conventional Shorten underground traffic systems and significantly reduces manufacturing costs. Furthermore, it has in conjunction with constant speed transportation solutions, a customizable transportation capacity that the Market requirements from the lower end to a multiple of the maximum capacity conventional mass transit solutions equivalent.

The major cost savings are mainly due to smaller cross-sections of tunnels or less work achieved for increased solutions.

With a mass transit system the main factors are low costs, short waiting times and short ways for the passenger to the station. The technical solutions to reduce the Waiting times for local transport solutions exist in shorter intervals and travel distances between the trains. The solution in terms of shorter Ways for the passenger to the station exists at shorter intervals between the stations. With current technological concepts, this leads to complex constructions and higher Costs. A tolerable and effective solution must everyone three conditions are sufficient otherwise they are for the passenger and society are not fundamentally competitive. Speed is another important aspect for the passenger, but not the most important. The average speed is currently of motor vehicles in congested cities around 20 km / h or less. The average speed of current conventional underground mass transit systems is 35 km / h or less.

The cost of conventional mass transit systems are high compared to portable ticket prices, so the operation is usually subsidized. The main reason is the cost heavy and technically complicated trains and the high workload. The heavy concrete structures are used very little and are designed for the 40 tonne curb weight of each rail vehicle. At the current normal time of about 5 minutes on average between the trains and a train length From 100 m at 50 km / h, a bridge or tunnel is only 7.2 Used for seconds when the train passes over or through it while the bridge or the tunnel in the rest 293 seconds is not used. It can therefore be said that the degree of utilization 7.2 / 300 or 2.4%. Moreover is a heavy construction due to the high empty weight of the vehicles required. One can say that this relationship is one Efficiency of 10 t / 40 t = 25%. The combination results an overall infrastructure efficiency of up to 0.6%.

The invention aims to achieve a balanced and commercially adapted Behavior regarding the mentioned Factors achieved through continuous passenger transportation the infrastructure to avoid waiting times to use more efficiently and the ratio of passenger weight to to increase rolling curb weight. Furthermore, passenger safety compared to current Subway trains due to the lower maximum speed and avoiding the risk of passengers from trains entering the Platforms increased in the stations.

The invention is based on the basic ones and already known principles according to U.S. Patent 1603475 of October 9, 1926 and British Patent 1294395 on October 25, 1972, for a continuous speed reduction by means of foldable Feeding carriage. To the aforementioned To achieve goals and improvements, the invention has the in the following claims marked features, the main feature in which the vehicles articulated connecting spacer bars.

The spacer bar has two functions: you improves speed reduction or acceleration ratio a factor of 2 or more if the hinge points to the outside the basic length of the vehicle compartment. This will reduce the construction costs significantly reduced. The better speed change ratio means in practice that double or even higher Speed change ratio in Compared to known solutions, where no spacer bars are used can.

The invention can be applied in standalone configurations that function as local modes of transportation and feeders or distributors to typical transportation nodes such as underground and Bus stations serve in a transportation infrastructure that spans the entire city. It can also be used in a modified door arrangement for accelerating and decelerating passengers at boarding and alighting points in a constant-speed conveyor.

The following is based on the accompanying drawings a preferred embodiment described as an example.

1 shows a top view of a typical station arrangement. The vehicle compartment has been omitted for the sake of clarity.

2 FIG. 3 is a side view of a high speed section between stations with a typical vehicle layout.

3 Figure 3 is a side view of a low speed section with a train folded at the ends of the vehicle in a station.

4 represents a typical cross section at a point between two stations.

4.1 provides a detailed view of the 4 with wheel and chassis details.

5 represents a basic outline of the folding process at each station.

6 illustrates a top view of the load bearing frame of foldable vehicle frames and their associated spacer bars.

At the stations, passengers enter the slowly moving vehicles 1 through doors 2 , which are featured in one or both ends of the vehicle, from the platform 3 out. The speed of the vehicles in the boarding or alighting sections with a large distance between the rails 4 is chosen so that a safe transition either directly from a stationary platform or, if desired, from a continuously moving belt 5 that is moving at or almost the same speed as the sideways moving vehicles is guaranteed. The speed is in the range of 0.7 to 1.5 m / s. The end doors close after a certain time 2 , and the vehicles start to slowly unfold and accelerate in the main direction of travel. The acceleration force required to accelerate the curb weight of the vehicle can be provided by energy stored in springs that are designed to be in the hinge points 7 generate a torque that in turn generates an acceleration force in the adjacent hinge points. This acceleration force has the same direction as the main direction of travel.

The acceleration force required in the main direction of travel for the variable passenger load can be generated by a power transmission device, for example regulated linear induction motors 8th that are attached to the substructure in the acceleration and braking sections. These linear induction motors 8th generate a contactless acceleration force in the main direction of travel on each reaction plate 9 that under each vehicle 1 is mounted. The one for every vehicle 1 individually required reaction force is set so that there are minimal forces between the rail 4 and the flange 15 result. For this purpose sensors are along the rail 4 Arranged in the braking and acceleration sections, the control device for the linear induction motors 8th supply the actual value of the force exerted on the side of the rail. By setting the through the linear induction motors 8th generated acceleration force in such a way that it corresponds to the mass of passengers in each individual vehicle and is proportional to the side between the rails 4 and the wheel flange 5 applied forces are minimized.

This is due to the maximum width B of the vehicle and the distance between three successive pivot points 7 Certain speed increase ratio is denoted by L. The speed change ratio is L / B. It should be noted that the hinge points outside the ends of the vehicle cabin 11 can lie. The distance between the centers of the hinge points at each end of the spacer bar 10 is by the distance L _v between two hinge points 7 at each end of the vehicle frame 13 and the width B of the vehicle 1 certainly. It is equal to the root of (L _v ² + B ² ). With a 1 m wide vehicle and a distance of 6 meters between the articulation points of the chassis 13 the speed change ratio is 12.08.

The length of the vehicle cabin 11 can be chosen so that it corresponds to the expected passenger volume. With a cabin size of 1 × 5 m and 4 standing people per m ² , the capacity is 50,000 people per hour in each direction at a driving speed of 10 m / s. The number of seated passengers is around 5 - 8 seats per car, which corresponds to 12,000 - 21,000 seated passengers per hour and direction.

By the passengers, the curb weight of the vehicle 1 and the spacer bar 10 Vertical load is generated via swiveling wheel frames 12 that on the chassis 13 on opposite sides and at each end of the chassis 13 are attached to the rails 4 transfer. Any wheel frame 12 is with two wheels 14 provided, and each wheel 14 has the wheel rim on each side 16 a wheel flange 15 , The purpose of the flanges 15 is the generation of the folding of the vehicles 1 required torsional and managerial forces in the sections outside the station areas as well as the generation of reaction forces to forces that are not caused by the power transmission device, such as the linear induction motors 8th , in the acceleration and deceleration sections, in which the Spurwei te increases or decreases, be balanced.

After acceleration, each vehicle travels at a constant speed until the next station is reached with a deceleration folding section, in which the folding and its corresponding deceleration in the direction of travel takes place. The function of the invention is reversed here compared to the acceleration sequence. The braking forces are generated by means of a power transmission device, for example by the linear induction motors 8th that over the reaction plates 9 under the chassis 13 on each vehicle during the folding sequence that takes place in the area where the distance between the rails 4 enlarged, applies a braking force.

The details of the described Device can changed in many ways be without the in the claims leave defined scope of the invention. For example the energy absorption medium can be a hydraulic medium. The Horizontal control means could at the pivot point of the vehicles in the form of a gear and a rack be arranged instead of the rails and wheels shown. The illustrated Induction motor assembly can be any known type to which Braking and accelerating vehicles.

Claims (5)

Local traffic facility for an endless lane, with successive vehicles ( 1 ), which are articulated so that they can be pivoted from a straight line arrangement into a position in which they stand next to one another, the vehicles being connected by spacer rods ( 10 ) are articulated at points that are at both end parts ( 7 ) of the vehicles, and with horizontal control means ( 4 . 15 ) are arranged such that the vehicles can be pivoted horizontally along certain parts of the endless road from the linear position into the position in which they stand next to one another and vice versa, characterized in that linear induction motor arrangements ( 8th ) are provided, part of the arrangements being arranged along the endless road and with second parts ( 9 ) which interacts under each vehicle ( 1 . 13 ) are attached to brake and accelerate the vehicles. Local transport device according to claim 1, characterized in that the induction motor arrangements induction means ( 8th ) and reaction plates ( 9 ), wherein the induction means are arranged along the endless roadway in their longitudinal center line and the reaction plates are attached under each vehicle. Local transport device according to claim 1, wherein the energy absorbent are arranged in connection with one of the pivot points around the absorb all or part of the kinetic energy of the vehicles, when they are swiveled into the position in which they are next to each other stand. After-traffic device according to claim 2, wherein the energy storage means Feathers are. Local transport device according to claim 1, wherein the control means rails ( 4 ) on which the wheels ( 14 ) located near the pivot points between the vehicles and the bars, with the wheels having flanges on both sides of the wheel rim.