This invention relates to a device and method for energy storage and energy transformation.
Devices for energy storage and energy transformation are known in the practice in particular as ignition coils, which represent an energy-transmitting high-voltage source and in engines operating according to the spark ignition principle, are used to activate a spark plug, which in turn ignites the fuel mixture in the combustion chamber of the internal combustion engine. In such an energy storage device and transformer embodied as an ignition coil, comparatively low supply voltage electrical energy, normally from a direct current vehicle electrical system, is converted into high-voltage electrical energy at a desired point in time at which an ignition pulse is to be delivered to the spark plug.
To convert electrical energy into magnetic energy, the system current of the motor vehicle flows through a first coil, which is customarily a copper wire winding, as a result of which a magnetic field forms around this coil, the magnetic field having a specific direction and being a closed-line magnetic field. To deliver the stored electrical energy in the form of high-voltage pulses, the previously built-up magnetic field is forced to change its direction by cutting off the electric current, causing an electrical high voltage to be formed in a second coil, which is located physically close to the first coil and has a much higher number of turns. The conversion of the now electrical energy at the spark plug causes the previously built-up magnetic field to break down and the ignition coil to discharge. The design of the second winding makes it possible to set high voltage, spark current and spark duration in the ignition of the internal combustion engine as needed.
All ignition coils have an I core made of a ferromagnetic material such as iron, for example. The I core is thus a rod-shaped or rectangular iron core, the cross-section of which may be made up of lamellae of soft iron sheet. In the known related art, the placement of the coils and of the I core is subject to great variation; however, the coils are usually superposed radially and are positioned concentrically to the I core. It is also customary in practice to provide, in addition to an I core of this type, a peripheral core made of ferromagnetic material, which surrounds the longitudinal extent of the coils and is also described as an “O core” or “ferromagnetic circuit.” In order to reduce losses when building up and breaking down the magnetic field, this peripheral core is also normally a combination of layered iron lamellae.
In order to be able to install the windings or coils, the I core and the peripheral core of a ferromagnetic circuit may not be of one piece but instead must be assembled from different component parts. A typical configuration is the construction of an I core and an O core forming a closed O, the I core together with the windings surrounding it being inserted into the interior of the O core at the time the ignition coil is assembled so that the lamella stacks of the cores lie in one plane when installed.
In order to influence the magnetic field in a specific way, the ferromagnetic circuit is normally interrupted by spaces or air gaps, this being referred to as a “magnetic shear.” A permanent magnet may also be located in such a space, making a further increase in the magnetic energy possible under specific conditions. The system of such air gaps and permanent magnets is preferably located at the joints between the I core and the O core.
A problem with the known devices for energy storage and energy transformation designed as ignition coils is that assembly gaps which are based on the manufacturing tolerances and the insertion play for inserting the I core into the O core must be maintained in the design of the magnetically active core elements. These gaps may be incompatible with the gap dimensions desired based on energy considerations.
Thus, for example, when a permanent magnet is positioned at one end area of the I core between the I core and the O core, no air gap is desired between the permanent magnet and the O core. The air gap that must be provided for manufacturing reasons must be compensated by appropriate measures or derivative actions, which are reflected in the overall dimensions and ultimately in additional costs as well.
U.S. Pat. No. 7,212,092 to Bosch discloses a device for energy storage and transformation that overcomes some of the problems addressed above. Referring to
This invention is directed to a device for energy storage and transformation that allows an increased level of energy storable in an ignition coil, using a coil that has a permanent magnet inside of a primary magnetic core, with a second magnetic core that closes the magnetic path of the primary magnetic core.
In one embodiment of the invention, there is a device for energy storage and energy transformation, including a primary magnetic core with an enlarged section for storing energy; a secondary magnetic core forming a magnetic path with the primary magnetic core, wherein a gap is formed between each end of the secondary magnetic core and respective ends of the primary magnetic core; and a permanent magnet received in the primary magnetic core.
In another embodiment of the invention, there is a device for energy storage and transformation in an ignition coil, including a coil that has a permanent magnet received in a primary magnetic core, and a second magnetic core that closes a magnetic path of the primary magnetic core.
In still another embodiment of the invention, there is a method for storing and transforming energy, including receiving a permanent magnet in a primary magnetic core; forming a magnetic path using a secondary magnetic core with the primary magnetic core, wherein a gap is formed between each end of the secondary magnetic core and respective ends of the primary magnetic core; and storing energy in an enlarged area of the primary magnetic core.
In one aspect of the invention, the enlarged area includes two saturation sections which store energy during coil charging.
In another aspect of the invention, the saturation sections are defined by a distance from the permanent magnet to an inner edge of the primary magnetic core.
In still another aspect of the invention, the primary magnetic core is shaped substantially as an E.
In yet another aspect of the invention, the secondary magnetic core is shaped substantially as an I.
In one aspect of the invention, the device is an ignition coil of an ignition system of a motor vehicle.
These and other features and advantages of this invention will become more apparent to those skilled in the art from the detailed description of a preferred embodiment. The drawings that accompany the detailed description are described below.
This invention is directed to a device for energy storage and transformation that allows an increased level of energy storable in an ignition coil, using a coil that has a permanent magnet inside of a primary magnetic core, with a second magnetic core that closes the magnetic path of the primary magnetic core.
Advantageously, with an arrangement in accordance with the invention, an increased level of storable energy may be realized in an ignition coil having specific geometrical dimensions of the magnetic core, which dimensions are typically driven by the room or size identified on the engine to allocate the respective ignition coil. As a result, engine sizes may be downsized, along with reduced energy consumption and lower emissions.
This invention provides higher storage energy capability in a given space for an ignition coil for an internal combustion engine. Referring to
According to this aspect of the invention, the permanent magnet is located inside the magnetic core in order to increase energy performance (energy levels) and to avoid magnetic saturation of the core material during normal operating conditions of the engine. In a standard coil, on the other hand, in which a permanent magnet is allocated between two separate parts of the magnetic core, a variation of current flowing in the primary winding with respect to time is nearly linear, as shown in
Referring to
Magnetic core component 25 accommodates two end sides of the magnetic core component 10 with air gaps 13 and 14, which parts are reduced to the minimum allowed by cutting process tolerances, but not at zero in the preferred embodiment. The distance 8 and geometry of the enlarged area (the magnetic core area between 16 and 7) of the magnetic core component 10 enable the coil to operate at optimal efficiency. For these features, the dimensions of slot 15, the distance 8 and the size of the enlarged area between 16 and 7 are significant in this respect. In operation, the small areas 16 and 7 of magnetic core component 10 below permanent magnet 20 are magnetically saturated by the magnetic field generated by the permanent magnet 20 and then operate as air gaps during the beginning of coil primary charging. During coil charging, the magnetic field generated by the primary winding (opposite of that generated by the permanent magnet) takes out from magnetic saturation areas 16 and 7, which become available for energy storage (reversible process). Higher non-linearity of the primary current curve versus time may be obtained with a smaller distance between the permanent magnet and lamination edge (distance 8). An alternative solution to forming small areas, not magnetized below the permanent magnet 20, is to locally stress the material until ferromagnetic properties are lost (irreversible process). Localized stress on the material can be performed by thermal or mechanical processes as understood by the skilled artisan.
This aspect of the present invention therefore allows higher energy stored in the coil by means of the non-linearity of the curve of the primary current versus time, without the constraint of requiring zero gaps at the interface of the primary and second coils.
The foregoing invention has been described in accordance with the relevant legal standards, thus the description is exemplary rather than limiting in nature. Variations and modifications to the disclosed embodiment may become apparent to those skilled in the art and do come within the scope of the invention. Accordingly, the scope of legal protection afforded this invention can only be determined by studying the following claims.
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