DE1563106C3 - DC starter generator - Google Patents

Description

The invention relates to a direct current starter generator according to the preamble of the claim.

Such a starter-generator is known from GB-PS 7 01 121 or from JA-Gbm 16 938/1964. A voltage regulator to prevent battery overcharging is provided there for charging a lead-acid battery. Such a regulator is expensive and not maintenance-free.

The object of the invention is to provide a direct current starter generator to create the output during generator operation without a voltage regulator Current limited to a designated level.

The solution to this problem consists in the characteristic Features of the claim.

The advantage of the invention lies in the simpler, cheaper and more reliable structure of the Plant and that immediately after starting the internal combustion engine, the battery removed Energy is supplied again with a high charging current. Until the operating temperature of the shunt field winding is reached the charging current strength then decreases to a constant value at which a Overcharging the battery is avoided.

In principle, this effect also occurs when the starter generator is in engine operation for is used for a purpose other than starting an internal combustion engine.

The drawing shows an embodiment of the invention, namely is

F i g. 1 is a plan view of the DC starter generator according to the invention with the removed Lid,

F i g. 2 is a circuit diagram of the electrical circuit used in the generator according to the invention,

F i g. 3 is a graph showing the initial output current is plotted against the speed immediately after starting the machine, and

F i g. 4 shows a graph in which the output current is plotted against the operating time.

The in F i g. 1 shown in a plan view starter generator 11 is provided with the usual lying in brush holders 71 brushes 70a and 70b, which can make contact with the commutator 59th The brushes are attached to the brush plate 73, which can be connected to the top of the generator housing, for example by screws (not shown).

From the brush plate, several support posts attached to it protrude upwards, on which a diode cooling surface 76 is attached by screws 77. A blocking diode 79 is attached to the cooling surface.

The entire device can be provided with a cover, which is not shown. An electromagnetic starter switch 80 is connected to the generator housing by a bracket 81 with screws 82.

According to FIG. 2, the brush 70a is connected to ground 84 via a wire 85. One pole of the battery 86 is connected to a wire 85 by a wire 87 .

One end of the series field winding is connected by a wire 88 to the brush 706, while the other end of the series field winding is connected by a wire 89 to a fixed contact piece 90 of the electromagnetic starter switch 80. One end of the shunt field winding is connected to the wire 85 by a wire 91 and the other end thereof is connected to the wire 89 by a wire 92 . This arrangement is a known type of connection for double circuit generators. The other pole of the battery 86 is connected to the other fixed contact piece 95 of the starter switch 80 via a wire 94. A blocking diode 79 is connected to wire 92 by wire 96 and to wire 94 by wire 97.

The starter switch 80 has a movable contact piece 99 which is actuated by an electromagnet 100. The electromagnet is in turn provided with an armature 101 to which the movable contact piece 99 is attached. A pull coil 102 operates the armature. One end of the pull coil 102 is connected by a wire 103 to the wire 94 coming from the battery, while the other end of the pull coil 102 is connected by a wire 104 to a fixed contact piece 105 of a manual control switch 106 . The switch 106 has a movable contact piece 107 which is connected to ground 109 by a wire 108 . The wire 104 is thus connected to the movable contact piece 107 and the wire 108 is connected to the fixed contact piece 105 when the switch 106 is closed.

Six poles are available for the field windings. The shunt field winding has per pole piece 125 turns. For the shunt field winding is a copper wire with a diameter of 0.64 millimeter used.

When the internal combustion engine with which the starter-generator works is to be started, the manual control switch 106 is closed, whereby the pull coil 102 is energized, which then pulls the armature 101 downwards. As a result of this movement of the armature, the movable contact piece 99 of the starter switch bridges the fixed contact pieces 90 and 95, as a result of which the starter-generator works as a motor and the internal combustion engine rotates and starts. When the manual control switch 106 is opened, the excitation of the electromagnet 100 is interrupted and the movable contact piece 99 moves away from the fixed ones

Contact pieces 90 and 95, whereby the starter switch 80 is opened. The generator effect now begins of the starter generator 11, which supplies power to the battery 86 via the respective connecting lines. The blocking diode 79 allows current to flow from the starter-generator to the battery, it prevents it but a reverse current flow from the battery to the starter generator. The starter switch 80 is open so that the current from the battery via the wire 94, the starter switch 80 and wire 89 cannot flow to the starter generator.

In Fig. 3, curve 120 indicates the output current of a conventional generator, while curve 121 the relationship between charging current and speed, i.e. H. i.e. the output current of a generator, indicating according to the invention. The internal combustion engine runs at a substantially constant Speed of 6000 revolutions per minute operated.

The magnetic field forces generated by the series and shunt field windings act on the charging current characteristic curve 120 in the opposite direction on the armature when charging current through the armature circuit flows. The counteraction of the series field to the shunt field is proportional to the charging current. When no current is flowing, there is little counteraction from the series field, but with increasing charging current the series field counteracts the shunt field to an increasing extent, whereby the characteristic curve of the charging current is flatter above the armature speed and ultimately remains approximately constant. .

The non-return valve is formed by the diode 79, which is connected in series with such polarity to the charging circuit is connected so that charging current can flow into the battery when the generator voltage is higher than the battery voltage is, and that the flow of current from the battery to the generator is interrupted when the generator voltage is lower than the battery voltage.

The curve 122 in FIG. 4 shows how the charging current decreases to a predetermined value over time. This occurs when the heating of the shunt field caused by the shunt current the winding resistance (temperature coefficient of resistance of copper) increases, which results in a reduction in the shunt current. The temperature-current stabilization of the shunt field winding is determined by the selection of the number of turns and the wire size and in turn determines the reduction in the charging current. For different The powers of starter-generators determine the shunt field development parameters, the Heat flow paths to the pole pieces, the yoke sections and the ambient temperature, the stabilization temperature the shunt field winding.

The higher charging current immediately after the start is advantageous because it uses the starting energy drawn from the battery replaced quickly. The strength of the charge then falls back to a safe, steady charge level. When Another advantage of the charging current control through temperature stabilization of the field winding turns out to be the Change in the charge amount due to the ambient temperature. At low ambient temperatures, at the chemical reactions in the battery take place with reduced strength, is a longer time to Achievement of temperature stabilization is required, and the stabilization temperature is lower, from which the result is a higher charging current, which compensates for the effects of the ambient temperature on the battery. The same applies to high ambient temperatures, at which the chemical activity of the battery increases is and the field temperature stabilization is achieved faster and at a higher temperature, whereby the charging current is further reduced.

For this purpose 2 sheets of drawings

Claims (1)

Claim: DC starter generator, especially for an internal combustion engine, with a double-circuit field winding, one output terminal of which has one pole of a battery and the other output terminal of which has a reverse current of the battery to the starter generator preventing blocking diode with the other pole of the battery is connected, as well as with a parallel to the blocking diode starter switch for optional Closing a circuit from the battery to the starter generator bypassing the Blocking diode in which the shunt field winding is made from a wire material with a positive temperature coefficient consists, characterized in that the wire size of the shunt field winding so small in relation to the desired output current and the operating temperature it is selected that within a certain period of time without using a controller Beginning of generator operation, a reduction in the excitation current and thus a stabilization of the Generator voltage and the battery charging current.