The present invention relates to multiple power sources and their control for low speed/low power vehicles. The invention more particularly relates to battery powered low speed/low power vehicles with internal combustion engine (IC engine) for auxiliary power and an electronic control unit to smoothly switch between battery power and IC engine power.
Low speed vehicles are operated by either battery powered electric motors or small IC engines. Examples of battery powered low speed vehicles are golf carts, utility vehicles, wheel chairs and low speed scooters. Examples of IC engine powered low speed vehicles are scooters and utility vehicles. Battery powered vehicles have a limited range due to the limited power capacity of the battery and must be recharged over a long period of time after a few hours of use. Hence wheelchair users on vacation are very restricted on how far they can go. Similarly, utility vehicles designed for a few hours of normal use cannot be used for an extended period of time even temporarily. Gasoline powered vehicles have a much longer range, but cannot be used indoors due to air pollution and noise pollution. Hence wheelchairs and utility vehicles used in hospitals cannot use IC engines as the sole power source. IC engine powered vehicles may not be welcome in certain stretches of camp grounds and other areas due to noise pollution. Hence there is a need for dual powered hybrid low speed/low power vehicles that can run on battery where IC engines cannot be used and switched to IC engine power outdoors when battery power must be conserved for later use or when the battery power is low.
There are two types of hybrid vehicles, namely, series hybrid and parallel hybrid. In a series hybrid vehicle, battery powered electric motor drives the wheels of the vehicle. The IC engine is used to drive a generator, which supplies power directly to the electric motor or charges the battery when the state of charge falls below a predetermined value. In parallel hybrid vehicles, the electric motor and the engine can drive the vehicle independently or in combination, pursuant to the running conditions of the vehicle. Typically, the control strategy for such parallel hybrid vehicles utilize the electric motor to drive the vehicle at low loads, the IC engine to drive the vehicle at intermediate loads, and the IC engine—electric motor combination to drive the vehicle at high loads. A number of patents have been issued for hybrid vehicles and means of switching between a motor and an IC engine based on load demand and speed. These patents have generally been for automobiles where the speeds vary from 0 mph to 80 or 90 mph and where the different load scenarios as explained above are continuously encountered. Some of these patents are U.S. Pat. No. 4,335,429 “Control apparatus for engine/electric hybrid vehicle” issued to Shiro Kawakatsu, U.S. Pat. No. 4,923,025 “Hybrid electric/ICE vehicle drive system” issued to Clarence W. Ellers, U.S. Pat. No. 5,495,906 “Controller of hybrid electric vehicle” issued to Masayuki Furutani, U.S. Pat. No. 6054776 “Control apparatus of parallel hybrid electric vehicle” issued to Yasuo Sumi, U.S. Pat. No. 6,712,165 “Hybrid vehicle” issued to Akihito Okazaki, U.S. Pat. No. 6,840,341 “Parallel hybrid vehicle” issued to Masato Fujikawa, U.S. Pat. No. 6,857,985, “Hybrid vehicle system” issued to Cameron P. Williams, U.S. Pat. No. 6,883,626 “Hybrid vehicle and control method thereof” issued to Kazuo Aoki et. al., U.S. Pat. No. 6,907,950 “Hybrid vehicle system” issued to Ikurou Notsu et. al.
In the case of low speed vehicles, the speeds vary from 0 mph to about 10 or 15 mph. Hence only the low load scenario of the parallel hybrid vehicle is encountered. The complexities of simultaneously engaging the IC engine and the electric motor as solved in the above mentioned patents do not occur here. But the control system should respond to the environment of the vehicle and accordingly use either the electric motor or the IC engine.
The primary objective of the present invention is to come up with a simple low speed vehicle that overcomes the above mentioned deficiencies of range so that the user is not stranded in a place where there is no provision to recharge the battery powering the vehicle. Another objective is to keep the person mobile even if he/she does not have the time to get the battery recharged over an extended period of time. Yet another objective of the present invention is to keep the controls simple and easy to use.
The foregoing objective is attained by having an IC engine on standby and having an electronic control unit monitor the charge left in the battery. For vehicles used strictly outdoors such as golf carts, the control unit automatically starts the IC engine when the battery charge falls below a predetermined level. Irrespective of the type of hybrid vehicle, it executes a series of maneuvers to start the IC engine to power the vehicle and recharge the battery. For vehicles used both indoors and outdoors, the control unit warns the user of low charge on the battery. If the user instructs the electronic control unit to switch to IC engine mode, the control unit execute a series of operations to start the IC engine and power the vehicle as well as charge the battery.
In the ensuing description, the phrase ‘engine’ refers to IC engines running on a multitude of fuels such as gasoline, diesel, biogas, methanol, liquid petroleum gas (LPG) etc.
In this respect, before explaining at least one embodiment of the invention in detail, it is to be understood that the invention is not limited in its application to the details of construction and to the arrangements of the components set forth in the following description or illustrated in the drawings. The invention is capable of other embodiments and of being practiced and carried out in various ways. Also, it is to be understood that the phraseology and terminology employed herein are for the purpose of description and should not be regarded as limiting.
As such, those skilled in the art will appreciate that the conception, upon which this disclosure is based, may readily be utilized as a basis for the designing of other structures, methods and systems for carrying out the several purposes of the present invention. It is important, therefore, that the claims be regarded as including such equivalent constructions insofar as they do not depart from the spirit and scope of the present invention.
The numbering is kept consistent across
When the IC engine is running, the mode relay is in the “Charge’ mode. The DC motor acts as a DC generator, producing electricity. It charges the battery through the voltage regulator 8. The voltage regulator is connected to the battery via an overcharge protection relay 21. This relay trips when the battery is fully charged. The ignition relay 14 controls power to the spark plug 15 in the IC engine. The choke solenoid 18 is connected to the carburetor choke cable. It is used to ‘choke’ the engine for cold start. When the choke relay 16 is energized, the solenoid is activated via the temperature sensor switch 17. When the engine is hot, the temperature sensor switch trips and interrupts power to the solenoid, thereby preventing the choke from engaging. The starter motor 20 is powered by the starter relay 19. When the starter motor is energized, it turns the crankshaft of the engine and starts the engine. The electronic control unit in
If the vehicle is outdoors when the low voltage alarm goes off, the user can press the ‘Start Engine’ button 25. When the control unit gets this signal, it stops the buzzer from sounding an alarm. It operates the choke relay 16 to choke the engine for start. If the engine is hot, the temperature sensor switch 17 prevents the choke from being activated. The control unit then energizes the ignition relay 14. This will complete the electrical circuit for the spark plug. It switches the mode relay 13 to ‘Charge’ mode. It then operates the starter relay 19 for a few seconds. This activates the starter motor 20, which cranks the engine. A few seconds after the starter relay is deenergized, the control unit checks the input from the engine RPM sensor 22. If there is no signal from the sensor, the control unit energizes the starter motor again for a few seconds. This process is repeated till there is an input from the engine RPM sensor. When the engine reaches normal operating temperature, the temperature sensor 17 trips the solenoid 18 and releases the choke. Once the engine is running, the control unit starts monitoring the battery voltage through battery voltage sensor 24. The user can see the charge level by looking at the charge level indicator 32. When the battery voltage exceeds a predetermined high voltage, the control unit trips the overcharge protection relay 21 to protect the battery. But the engine continues to run. When the user wants to cut off the engine, he can press the ‘Stop Engine’ button 26. When the control unit gets the ‘Stop Engine’ signal, it trips the ignition relay to stop the spark plug from firing. This stops the engine. It then switches the mode relay to the ‘Run’ mode. It switches off the choke relay.
When the battery voltage is above the predetermined low voltage, if the user needs extra power to climb an incline, or if the user decides to conserve battery power for later use indoors, he can switch to engine power by pressing the ‘Start Engine’ button. In this case also, as before, the control unit will go though the above mentioned procedure to start the engine and charge the battery to full capacity. The engine, as above will continue to run even after the battery is fully charged till the user presses the ‘Stop Engine’ button.