As the need for public transit increases around the world, the requirement to provide a clean environment for the customer is a high priority.
The transit cleaning unit is designed to clean the walls, overheads, and flooring of the subway systems worldwide. The transit cleaning unit provides an effective means of providing a clean environment for the benefit of the customers.
A transit cleaning unit can provide a means of cleaning the rail transit system maintaining a safe attractive tunnel and station environment. With the twenty-two hour per day schedule that is used in many cities, the allotted three hours does not provide adequate time in which to properly clean the needed areas. The ideal configuration is to have two working cars and two supply cars to enable more coverage. This approach will enable the crew operating the transit cleaning unit to complete the travel on one line in one direction and then at the end of the line, to operate the transit cleaning unit going on the other line facing the opposite direction.
During the three hours between operations, the transit cleaning unit may be utilized to operate. The transit cleaning unit can also be operated when single tracking is enforced during weekends and holidays. The transit cleaning unit is designed to provide a time saving means of cleaning the tunnel systems of the subways worldwide. The transit cleaning unit is able to clean the walls, overhead, flooring and insulators of the subway systems in a minimum amount of time.
The solenoid activated nozzles are controlled by a PLC that can accommodate the different modes of station locations, wall construction as in isolating nozzles when approaching station platforms. The first concept of the transit cleaning unit is a remolded transit rail car converted to the specifications outlined and is self-propelled by existing power from the third rail. It is also been observed that the cleanliness of the space between the rails in the stations is not acceptable. The requirement for a means to clean the insulators on the systems has been requested by the chief engineer of one of the major rail transit systems in the United States.
A transit cleaning unit is able to clean the walls, overhead, insulators third rail covers and flooring of the subway systems in a minimum amount of time. The transit cleaning unit is a rail car converted to the specifications outlined. The transit cleaning unit is self-propelled and systems are powered by third rail. The transit cleaning unit is programed through a PLC. In order to accomplish the most effective means of cleaning, it is recommended that the transit authority purchase two work cars and two supply cars. This will enable operations to continue when the cars come to the end of a certain line and return on the opposite track.
The transit cleaning unit utilizes a 5,000 pound per square inch (“PSI”) water pressure to remove the harmful dirt that gathers in the tunnels of the rail transit system. With the rise in commuters using the rail system on an increased rate, the transit cleaning unit will provide a safer environment in which the customers are not breathing the harmful particles from the accumulation of dirt on the overheads, walls, decking. The transit cleaning unit also provides a means of cleaning the insulators for the third rail system reducing down time due to maintenance and replacement.
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In some embodiments of the concepts and technologies disclosed herein, the high pressure manifold and frame 400 can be fed (e.g., via the supply lines and the nozzle manifold fittings 404) from one of the supply cars. The tanks in the supply car can run the entire length of the supply car, from the forward doors to the aft doors, in some embodiments. Due to the restriction of the door dimensions in order to allow access to the cars, the tanks can be constructed in some embodiments to be mounted on the sides of the car.
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In practice, water supply tanks are mounted on each side of a car internally. A three-way “T” fitting supplies a supply of water to the electric powered pump. The electric powered pump, mounted on the car flooring, supplies water to the electric powered on-demand hot water heater, which can be mounted on the car flooring. An electric powered on-demand hot water heater provides hot water to the high pressure washer. The 5,000 PSI high pressure water washer, mounted on the car flooring, receives hot water from the on-demand hot water heater to supply to the high pressure nozzles mounted on the track frames, which can be located on each side of the car.
A movable frame, mounted on the car flooring and including four ball bearing wheels, can house the high pressure nozzles that can deliver high pressure hot water to the walls. High pressure (5,000 PSI) nozzles can be mounted on the movable frame. A 3,000 PSI balanced double acting actuating cylinder mounted on the car flooring, and mounted to the nozzle frame, can provide extend/retract movement. Sequence micro-switches are mounted on the doors sending signals to the servo valves controlling the actuating cylinders. The transit cleaning unit 100 also can include flexible hoses, a four-way fitting, a hydraulic system, fill ports, and an operator station. The transit cleaning unit 100 operation can be controlled by a PLC. The programming of the PLC can be activated by light/laser sensors mounted on the work car.
In various embodiments, piping can route from the work car, through the car decking under the supply tanks, and forward of the middle doors that are non-operational. The hydraulic motor can enable the spring loaded actuator to extend and retract the piping and the cleaner for transport to the work site. The hydraulic motor will also enable one side of the car to retract the insulator cleaner when entering a station, and allowing the side that has the insulators too continue with the cleaning process. The hydraulic system for the hydraulic motor is mounted next to the middle doors on the work car. It is also connected to the PLC unit and operated through the laser sensors on the car alerting the motor to power on and off when approaching or leaving a station. The distance from the insulator to the inside nozzle piping must allow to operate with the grounding brackets installed. An option is to have the bottom of the piping have a “t” fitting installed to permit 45 degree nozzles installed to clean the fore and aft portions of the insulators. The piping can be either one inch or three-quarters of an inch in diameter. Installing the nozzles is to drill and tap the piping.
This application claims priority under 35 U.S.C. § 119(e) to U.S. Prov. Pat. App. No. 62/603,504, entitled “Transit Cleaning Unit,” filed Jun. 5, 2017, now expired.
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