DE3933758A1 - ELECTROMAGNET - Google Patents

Abstract

An electromagnet, especially for use in pilot valves for the direct control of the quantity of fuel injected in fuel injection pumps, has a pot magnet (25) of soft magnetic material, an annular exciting coil (30) and an armature (29) arranged in front of the pot magnet with a working air gap. To improve the dynamic behaviour of the electromagnet (20), i.e. to obtain extremely short switching times, with a simple technical construction of the magnetic circuit, the pot magnet (25) and/or armature (29) made as a solid component has an even number of at least four radial slots (41) passing through the pot magnet (25) or the armature (29) over its entire axial length. Successive radial slots (41a, 41b) extend alternately from the outer or inner surface (321 or 311) and terminate there, leaving a solid section of material (42 or 43).

Description

State of the art

The invention is based on an electromagnet, especially for use in switching valves for direct Control of the fuel injection quantity Fuel injection pumps, which in the preamble of Claim 1 defined genus.

For fuel injection pumps with direct control of the Fuel injection quantity by means of an electromagnetic Switching valve is usually the per pump piston stroke metered amount of fuel into a pre-injection and a Main injection quantity divided depending on the load and Speed of the internal combustion engine in terms of time and mass Ratio can be very different. Important for that high-precision metering and therefore more stable for training Operating states of the internal combustion engine is on electromagnetic switching valve with extremely short  Switching times, i.e. with the application of a control pulse extremely low delay. Short switching times of the electromagnet are made by laminating the magnetic circuit achieved since this causes the formation of eddy currents in the Soft iron is reduced and thus the assembly and disassembly of the Magnetic flux in the magnetic circuit takes place much faster.

In the case of switching valves for fuel injection pumps, cup-shaped electromagnets are used because of the limited installation space. The sheet must therefore be made in the radial direction. In the case of a known electromagnet of the type mentioned at the beginning (US Pat. No. 2,498,702), the necessary lamination in the radial direction is achieved in that the magnet pot and possibly the magnet armature consist of a ring of soft iron sheet folded in the circumferential direction (see there FIGS. 1-3). will be produced. After folding, the ring is tapped on the outside, so that the outer connections of the individual folding strips are separated, and held together with an outer cover. Because of the outwardly increasing diameter of the folded ring, the individual folding strips are designed with different radial lengths. Such a manufacturing process is very complex and accordingly expensive.

Advantages of the invention

The electromagnet according to the invention with the characteristic Features of claim 1 has the advantage that the magnetic circuit of the electromagnet inexpensively in Solid construction manufactured and then with the slots according to the invention can be provided. This is cost-saving, as all of them with a laminated magnetic pot or Magnetic armature required labor-intensive Manufacturing measures, such as insulation of the folding strips, Parting, grinding to a rotationally symmetrical dimension,  Fastening by means of an outer shell, etc., is not necessary. By the slitting becomes a meandering path for the Eddy currents created, reducing the eddy current resistance of the magnetic circuit is significantly increased. Already at the smallest number of four in total, preferably by 90 ° Circumferential angle staggered slots demonstrated that a significant improvement in Dynamics of the electromagnet compared to an electromagnet is achieved with a solid magnetic pot. With a total of 12 Slits in the massive magnetic pot, each by 30 ° offset from each other, could be the same dynamic Improvement can be achieved, as the known Electromagnet with a magnetic pot that is laminated in the radial direction having. Depending on the degree of dynamic desired Improving the electromagnet can both the number also the length of the slots - or the width of the remaining web of material - can be varied.

drawing

The invention is illustrated in the drawing Exemplary embodiments in the description below explained in more detail. Show it

Fig. 1 a longitudinal section of a pump electromagnetic switching valve for a fuel injection,

FIGS. 2 to 4 each show a plan view of a pot magnet in the solenoid of the switching valve in Fig. 1 in accordance with three exemplary embodiments.

Description of the embodiments

The solenoid valve 10 shown in longitudinal section in FIG. 1, which works in conjunction with a fuel injection pump and defines the start and end of delivery of the fuel injection, is known and its structure and mode of operation in connection with a fuel injection pump designed as a pump nozzle in DE- OS 35 23 536. It has a valve body 11 which contains a valve chamber 12 and an axial guide 13 for an electromagnetically actuated valve needle 14 . The valve needle 14 cooperates with a valve seat 15 which surrounds a valve opening 16 . The valve opening 16 divides the valve chamber 12 into a high-pressure and a low-pressure section, which are each connected to a high-pressure bore 17 and low-pressure bore 18 . Both bores 17 , 18 open into the end face of the valve body 11, which is designed as a sealing surface. When the solenoid valve 10 is mounted on a housing nozzle of a pump nozzle, the front openings of the bores 17 , 18 are covered by congruent openings of corresponding bores in the housing nozzle. The valve body 11 and the housing connector are connected by means of a union nut 19 .

On the valve body 11, a valve cover 21 is mounted, which is screwed by means of a cap-like sleeve 22 on the valve body. 11 An electromagnet 20 for actuating the valve needle 14 is clamped between the valve body 11 and the valve cover 21 and, when the electromagnet 20 is de-energized, bears against a stroke stop 24 in the valve cover 21 under the action of a valve opening spring 23 . In this position, the valve needle 14 lifts off the valve seat 15 with the valve opening 16 released . The electromagnet 20 has a magnet pot 25 of soft magnetic material with captive annular exciting coil 30, an end face of the magnet pot 25 covering ring-shaped yoke 26 and a magnetic cup 25, leaving an inner air gap 27 and the yoke 26 opposite leaving an outer air gap 28, in cross-section T-shaped magnet armature 29 , which is firmly connected to the valve needle 14 and on which the valve opening spring 23 is supported. The magnet pot 25 has an outer hollow cylindrical pot wall 31 , an inner, hollow cylindrical pot core 32 and a pot wall 31 and pot core 32 integrally connecting the pot bottom 33 . The hollow cylindrical pot core 32 is seated on a nozzle 34 on the valve body 11 . In the annular space 35 delimited between the pot wall 31 and the pot core 32 , there is the excitation coil 30 , which is wound on a bobbin 36 made of insulating material and the two winding ends of which are each connected to a connection contact 37, 38 , which as a connector 39 , 40 on the top of the Project valve cover 21 axially.

As can be seen in FIG. 2, the magnetic pot 25 made of solid, soft magnetic material has eight radial slots 41 which penetrate the magnetic pot 25 in its full axial length, two groups of differently shaped radial slots 41 a and 41 b being present. Both groups of radial slots 41 a and 41 b are nested one inside the other so that a radial slot of group 41 b follows a radial slot of group 41 a in the circumferential direction. The radial slots of the group 41 a pass from the outer surface 311 of the outer cup wall 31 made, extending almost to the inner lateral surface 321 of the pot core 32 and terminate there, leaving a material web 42nd The radial slots of the group 41 b go from the inner circumferential surface 321, extending to near the outer surface 311 and terminating to leave a material web 43rd

Successive radial slots 41 are offset from one another by the same circumferential angle, here by 45 °. This arrangement of the radial slots 41 enforces a meandering course of the eddy currents, as indicated by dash-dotted lines in FIG. 2 and indicated by arrows. Due to this forced course of the eddy currents, the eddy current resistance of the magnetic pot 25 is significantly increased, thus the build-up and breakdown of the magnetic flux in the magnetic circuit is considerably accelerated, so that the electromagnet 20 has extremely short switching times.

The magnetic pot 25 shown in plan view in FIG. 3 has a total of twelve radial slots 41 , which are distributed uniformly over the circumference of the magnetic pot 25 in the two groups of differently designed radial slots 41 a, 41 b. The radial slots 41 a and 41 b are formed as in Fig. 2. With this design of the magnetic pot 25 with a total of twelve radial slots 41 , the same dynamic improvement of the electromagnet as compared to an electromagnet with an unslotted solid magnetic pot is obtained, as is usually achieved with known electromagnets with a radially laminated magnetic pot.

Depending on the degree of the desired dynamic improvement of the electromagnet 20 compared to one with an unslotted solid magnetic pot, both the number and the length of the radial slots 41 - or the width of the remaining material webs 42 , 43 - can be varied. The number of radial slots 41 is always an even number, but at least four. FIG. 4 shows a magnetic pot 25 which has a total of six radial slots 41 , the radial slots 41 a of one group only reaching as far as the pot core 32 and the radial slots 41 b of the other group only reaching as far as the pot wall 31 . The remaining material webs 42 , 43 are therefore substantially larger than in the magnetic pot 25 according to FIG. 2 and correspond to the radial width of the pot core 32 or pot wall 31 . The dynamic behavior of an electromagnet 20 equipped with this magnetic pot 25 is significantly worse than that of an electromagnet 20 with a magnetic pot 25 according to FIG. 2 or 3, but may be desirable in certain applications.

The invention is not restricted to the exemplary embodiments described. To further improve the dynamic behavior, it is therefore advantageous to also slit the magnet armature 29 and the yoke 26 in the same manner as described for the magnet pot 25 . However, it is not necessary to provide the same number of slots in magnet armature 29 and / or yoke 26 as in magnet pot 25 . The slots open out in the same way as described for the magnetic pot 25 alternately in the inner and outer lateral surface of the magnet armature 29 or yoke 26 , while a material web remains on the respective other lateral surface.

Claims (3)

1.Electromagnet, in particular for use in switching valves for direct control of a fuel injection quantity in fuel injection pumps with a solid magnetic pot made of soft magnetic material, which has an outer hollow cylindrical pot wall, an inner, coaxial hollow cylindrical pot core and a pot wall and pot core integrally connecting the pot bottom, with a Annular excitation coil, which lies in the annular space delimited by the pot wall and pot core, and with a hollow cylindrical magnet armature opposite the magnet core on its free end face with working air gap distance, characterized in that the magnet pot ( 25 ) and / or the magnet armature ( 29 ) has an even number of at least four radial slots ( 41 ) which penetrate the magnetic pot ( 25 ) or magnet armature ( 29 ) each in full axial length, and that successive radial slots ( 41 a, 41 b) in the circumferential direction alternately from the Ä the outer or inner lateral surface ( 311 or 321 ) extend, each extend to close to the inner or outer lateral surface ( 321 or 311 ) and each end there while leaving a web of material ( 42 or 43 ). 2. Electromagnet according to claim 1, characterized in that the radial webs ( 41 ) are arranged offset from one another by the same circumferential angle. 3. Electromagnet according to claim 1 or 2, characterized in that the magnetic pot ( 25 ) is covered by an annular yoke ( 26 ) resting on the free end face of the hollow cylindrical pot wall ( 31 ), to which the magnet armature ( 29 ) while leaving another working air gap ( 28 ) opposite, and that the yoke ( 26 ) is slotted in the same way as the magnetic pot ( 25 ) and / or the magnet armature ( 29 ).