C O L L E C T O R F O R T R O L L EY B U S
OLD TECHNIQUES
Hitherto vehicles driven by electricity obtained from lines (trolley busses, other vehicles) are equipped with two arms, each with one sliding connector, to rest against each one wire. After a derailing the driver was forced to debark, and, by hand, with ropes attached to the ends of the arms, pull the arms down and aim the connectors until the wires again rest in their narrow and shallow groove. Such derailing have been common and have been time consuming and in urban traffic an obstacle to the traffic, even if the bus could move slowly with battery power. The interest for trolley busses has decreased or ceased.
NEW TECHNIQUES
This invention relates to current collectors and their connected components, which essentially eliminate these difficulties.
Alternate current is preferably used in a modern system for trolley busses. This facilitates the change of speed of reliable squirrel cage drive motors by means of f equency conversion and quick disconnection of load when needed. The distributed voltage can be high and the distance between the feeding transformers short. Further measuring and guiding tools for the collector are simpler. Batteries must always give spare power for signaling and should allow short movements.
COLLECTORS
The current collector, (below called the "collector"), is a unit including two or more connectors, probably not more than four, mechanically built together but insulated from each other, with every second one connected to each terminal. It is attached to the upper end of a parallelogram, (below called the "carrier"), for example consisting of two rigid poles, preferably tubes, connected in the corners of the plane of the parallelogram to two shorter poles. The corners are connected pivoted in the plane. The collector itself is affixed with bearings onto the aft crossbar. The movement of the collector upwards can be limited by a stop to slightly below the ends of the carrier poles. Thus these, not
the collector itself, can reach the perpendicular carrying wires for the wire pair if the collector has come to the side of the pair. There is further a stop for the collector so far below the carrier ends that these can't touch the carrying lines if the collector is correctly positioned 5 on the wire pair. The collector is equipped with a spring which presses it upwards hard enough, relative to the pressure upwards on the aft perpendicular pole of the carrier, to enable the collector to swing freely up or down between end stops during normal operation. By means of a suitable pressure from the collector on the wire pair a large sag can be tolerated and thus larger distances between the suspension points for the wire pair.
The perpendicular pole forward has bearings perpendicular to the length of the bus, either directly on the roof or on a guided sledge. Thus the collector is always perpendicular to the bus. The sledge is in normal service in an aft position. It can quickly be pulled forward one half to some meter to a forward position if the bus is situated where the collector is on a short line stretch without electrical connection, to give it power again. As an alternative to a sledge on guides the carrier itself can be shortened. As the collector is freely hinged, with springs, not essentially influencing the carrier, the pair of lines are influenced largely by the low mass of the collector, not by the larger mass of the carrier.
There is a risk during a derailing that the carrier or the collector can be hurt or that they pull the wire pair down or that arcs hurt. The collector can entirely leave its pair of wires because of large changes of course or litter on the wires. In such a case it should not be damaged itself because it is caught by for example perpendicular carrying lines.
Nor should it pull down the wire pair. This can be avoided mechanically by means of bent end parts on the collector or the parallelogram to push them down to a position where it doesn't pull the carrying lines down even if it is entirely fallen down in a full opening at the side of the wires.
The connectors of the collector are . preferably equipped with exchangeable contact surfaces of ordinary contact material. In order to attenuate singing sounds from the lines they can have soft seats of rubber like material.
Today there are known techniques, like detectors for the position in side and height of the collector and its carrier, means for moving the
carrier towards the side and in height and possibly a fairly simple industry computer. The traffic can then be made fast and with small disturbance to other traffic. The forward end of the carrier can be equipped with indicators for the height of the collector over the ground plane as defined by the four wheels. The indicator for height must probably only indicate three positions, when the carrier is on the roof of the vehicle, when well under the wire pair, and freely and spring- cushioned with the collector contacting the lines. THE FIRST STEP A first step according to this invention in its most elementary form is an electrically driven vehicle where the carrier is equipped with detectors indicating the pressure from the collector sideways against the carrier caused by the pressure against the wire pair by the connectors on the collector. If an axial displacement of the collector by the bearings on the carrier of one or two or more cm is allowed the indication can be simple with known indicators which can be contacts or which can give continuous indication for varying side pressure against the lines. The indicator guides a motor at the forward end of the carrier on the roof of the vehicle to keep the carrier and thus the collector out to the side so far that the mean side pressure on the lines is a πtin-ϋmum. This further decreases the risk for derailing.
Direction of the side angle of the carrier allows that the collector can be kept out almost abeam of the vehicle, for example up to 45° or 60°. The driver must, as formerly after derailing or sometimes for change of bus line, get out from the bus and pull the collector down from the wrong position , aim it to the correct position below the lines and release them.
When the side pressure from the collector on the carrier is too great, for instance when the carrier can't come further out, the driver can be warned in time by an optical or acoustic signal to take action. THE SECOND STEP
A second step means fast pulling down of the collector after a derailing which has caused lack of power, or quick switching off of the power if an arc occurs to avoid damage on lines or collector. A quick pulling down can be done by releasing a normally stretched spring, which afterwards is slowly stretched by means of a low power motor, or by a stronger electrical or for example hydraulic motor or piston. The driver must as formerly get out and make contact manually.
The fast pulling down is released when the collector during a predetermined time lacks power. Arcs are allowed only for the shortest time possible, preferably for less than one ac period, causing voltage to be disconnected electronically. This is suitably coordinated with the 5 equipment for transforming the line voltage to a variable voltage and frequency for the drive motors. Arcs ensue from current breaking, and happen also when the connector leaves the pair of wires and enters any surface free from voltage, for example because of strong cover by ice and further when the collector leaves the wires because of some defect. If for some reason an non expected long-living arc should develop the flaming causes specific current variations of much higher frequency than the line frequency, further specific sounds develop- Both can be used as indicators that the electronic breaking shall be done.
When the carrier is at an angle in height of a few degrees to the roof of the vehicle, it can be programmed or mechanically guided to come down in the direction of the vehicle before going down to the roof. THE THIRD STEP
A third step is that for a normal start of travel or after a quick pulling down the collector finds the correct position below the pair of wires and is lifted to contact the wires. This avoids time waste and traffic jams which hitherto caused the interest for trolley busses to cease. The driver can while still sitting give signals about pulling down, positioning sideways and lifting, and also parking the collector on the roof of the vehicle. He can read the result on an indicating table or a computer monitor or both.
For this reason the aft end of the carrier is equipped with two detectors symmetrically situated at the ends of the collector, which indicate the electromagnetic field around the pair of wires. The carrier is guided by these detectors until the indicated field is equal on both. It is, during continued fine adjustment of the position, brought up to put the connectors of the col ector each to its wire. In this case the driver must not debark and the stop can be short.
The indication of the field can be done by two capacitive detectors, one at each end of the collector or the carrier. They are preferably screened as to make the furthermost detector most screened off at a great distance from the pair of wires. Two detectors can guide the carrier trying to give both the same voltage, only or in combination with phase measurement. Inductive detectors can be used if the line in another point
is loaded to carry current. The general level of interference can be so high that the detectors get no clear indication when the collector is far from the wires. In order that this shall not hamper the guiding the collector can sweep from one side to the other, well below the wires, until the detectors come near enough to the wires and take action.
If the vehicle for some reason has stopped where the collector can't get voltage but voltage can be expected some distance forward, the end of the carrier at the roof of the vehicle can be brought forward say one half to some meter, until voltage is obtained. The carrier is then brought back to its aft position again.
If the vehicle shall be parked outdoors at freeze cold snow weather the sledge can be pulled all the way forward with the collector higher than the roof, it is then lowered and put backwards into a cover with rubber soft doors. Loss of voltage can be caused by ice on the lines. Light ice scrapers attached at each connector, maybe spring loaded upwards, can be put in operating position during the cold time of the year. Especially thick ice can be scraped if the roof end of the carrier is moved to and fro. When the bus line is forked the collector can be pressed to the correct side by the driver or via the vehicle computer, this by the same means which as described before kept the side pressure on the wires zero as an average. The side pressure can then be limited to the pressure needed to guide the carrier. When the vehicle has arrived to the correct pair of wires the functions return to keep the collector as an average at the middle of the pair. THE FOURTH STEP
A fourth step makes possible automatic steering at a given distance along a pair of wires. The distance is given by the horizontal angle of the carrier to the vehicle. The angle is kept constant as the detectors at the bearings of the collector for the side pressure from the pair of wires influence the steering to give these indicators on an average the same indicated pressure, as described before. The angle is indicated by detectors at the forward end of the carrier. The angle can be given by the driver for the moment but can also be set by other factors.
T R A F F I C THE' FIFTH STEP
A fifth step is, on the country side with only few oncoming vehicles, to build one pair of wires only to save costs. The bus driver 5 who is in the best position, for instance in a downhill slope, lowers and pulls in his collector over the surface of the bus, all by pressing a knob. After the passage he orders the collector to contact the wires again. The meeting bus can for safety give a radio signal, either as a reminder or as an order to automatics, to avoid damage when meeting at great speed. Both busses can of course lower and pull the collectors in. As the carriers can be kept far out from the side of the vehicle, along a narrow road one pair of wires can be hung on reasonably short arms to be used by both traffic directions. The collectors can further be guided sideways by mechanical signals like the turning of the steering wheel, or by electrical signals, to cause them to be pushed towards the intended direction at bus line forks. The driver can have before him an indicating table which shows line directions and among other how to press the collector.
FIGURES
The trolley bus system will be described in connection with figures 1 and 2 :
Figure 1 shows a trolley bus from above and part of the collector with its attachment on the aft crossbar of the carrier. Figure 2 shows a collector with two connectors.
F I GU RE 1
Figure 1 shows a pair of conducting wires 1 , means 2 for hanging this on a carrying line 12 , a vehicle 3 and a collector 4. The collector is hung with bearings on the upper perpendicular pole 6 of the carrier 7 formed as a parallelogram, which in turn is affixed to the lower perpendicular pole 8. This is mounted on bearings 9 perpendicular to the length of the bus, either directly on the roof of the bus or on a sledge 10 which can be moved to and fro up to some meter in the length direction of the bus on a guide 11.
The collector 4 can, because of the pressure against the pair of wires 1 , be moved vertically between two positions in relation to the softly bent upper ends of the carrier 7 . One position is just below the
pole 6 , the other just below the upper side of the carrier 7 . It is pressed by a spring against the upper position. The carrier 7 in turn is pressed upwards by another spring in its lower end. The strengths of the springs are matched so, that in the case when the wires are in their standard height over the ground, the carrier can swing free between its end positions not to cause the double arm 7 to move considerably.
Because of some error the collector 4 may have lost the contact with the wires 1 leaving it without voltage. This causes electronically that the carrier 7 is pulled down automatically and quickly to a position below the wires 1 , not to hurt these or the carrying wires 12 nor to hurt itself. This is done by means of a motor or by a strong spring which is afterwards stretched by a small motor. When it is pulled down, the side position relative to the pair of wires 1 is felt electronically by indicators 13 on the outside of the upper ends of the carrier 7 . If the wires carry voltage the collector 4 is guided back below them and lifted to contact when the indicators 13 find the same field strength. The driver himself can switch the automatics for pulling down on and off. Means for moving the carrier upwards and sideways are in and at the sledge 10. Indicators for height and side of the collector are at its bearings 5 . Screened conductors 14 for power and indicators are suitably placed inside the length poles of the carrier. All results of measurements are processed in a computer. All the motors, indicators, the computer etc. are generally applications of known techniques.
F I G U R E 2
The wear surfaces of the connectors are suitably made slightly convex. The beam 21 is insulating and formed to be as light as possible, suitably made from glass reinforced polyester or corresponding. In order to allow high screw 23 pressures and thus low contact resistance to the conductors 24 it can be equipped with long nuts 26. The beam 21 has arms 25 fixed to the bearings 5 on the upper perpendicular arm 6 of the carrier 7. In order that the wire pair 1 shall easily glide into the groves there should be slanting top sides on the connector shoes 22.