DE102011005591A1 - Commutation device for direct current machine e.g. starter device for internal combustion engine, has commutator and positive and negative brushes, which are made of materials having different copper content - Google Patents

Abstract

The commutation device comprises commutator (55) and positive and negative brushes (58). The positive brush is made of material having higher copper content than that of negative brush such as commutator (52). The contact pressure of commutator (52) is between 10-25 N/cm 2>. The contact pressure of positive bursh is 5 N/cm 2>.

Description

State of the art

DE 10 2007 058 903 A1 refers to a brush for powering electrical machines, in particular commutator machines. The brush comprises at least two brush sections wherein a cleaning agent section is present, which is one of at least two brush sections and has a proportion of cleaning agents which is higher than in at least one other brush section. The cleaning agent section extends at least partially over a cross section perpendicular to a wear direction of the brush.

DE 10 2007 063 333 A1 refers to a multi-layer brush. The multilayer brush essentially has a composite with a graphite part with a copper content and a layered structure. A first layer is provided with a high copper content and another layer with a comparatively low copper content, wherein the copper content of the first layer compared to the copper content of the second layer corresponds to a ratio of ≦ 3/2. The composite of graphite material and copper content is mixed with a lubricant.

DE 10 2008 001 702 A1 refers to an electrical machine, which is designed in particular as a commutator machine. The commutator machine has carbon brushes for powering a rotor, which interact with the blades of a commutator. The carbon brushes are provided continuously or in layer portions with various additives such as cleaning agents, lubricants, agents for increasing the ohmic resistance or for increasing the electrical conductivity and the like. At most half, but preferably less than half of all carbon brushes of the electric machine, have a significantly different from the other carbon brush portion of an additive.

US 2003/0080647 A1 refers to an electric machine having a commutator. Brushes rub on the surface of this commutator. Furthermore, the electric machine comprises an armature wherein the surface of the commutator is treated by means of a brush, which is the upstream of the other brushes, which are employed on the circumference of the commutator, seen in the direction of rotation of the commutator.

In DC machines, which have a commutator here, the carbon brushes take over the function of the current application and the transmission of the current from external terminals of the electrical machines to the commutator bars. The current transfer between brush and commutator is characterized by a contact resistance, which represents a significant proportion of the total ohmic losses of a DC machine. In essence, the size of the contact resistance is determined by the contact pairing, that is, by the materials used in the commutator bars and in the carbon brushes. While the commutator bars are usually made of copper, there are a variety of material compositions for the carbon brushes. For the contact resistance, the copper content of the carbon brushes plays an important role. The higher the copper content, the lower the contact resistance. Any increase in the copper content is prevented by the associated reduction in the lubricating effect and the resulting wear problem.

For the contact resistance also plays the contact pressure with which the brushes are pressed by means of springs to the commutator, an important role. The higher the contact pressure, the lower the contact resistance Any increase in the contact pressure is prevented by the associated increase in friction and the resulting wear problem.

Similar to the brush contact resistance, the brush voltage drop can be considered. The brush voltage drop characterizes the transition between brush and blade and has the same characteristics as the brush contact resistance.

According to the current state of the art, the same brush materials are used for plus brushes and minus brushes in a DC machine. Since the plus and minus brushes work as anodes or cathodes, the current transfer is based on different physical mechanisms. As a result, different contact resistances occur at plus and minus brushes with the same brush material. Thus, it is not possible to set a minimum brush loss at both Bürstenpolaritäten. Furthermore, according to the current state of the art for plus brushes and minus brushes in a DC machine each identical contact pressures are set.

Presentation of the invention

According to the invention, it is proposed to use in each case different brush materials for the formation of the carbon brushes, in particular the plus brush and the minus brush. By means of this procedure, the commutation conditions can be set specifically at both brush polarities so that overall, the efficiency of the electric machine can be increased without, however, negatively affecting the wear of the same.

The power loss of the brushes can be reduced on the one hand by reducing the contact resistance or the brush voltage drop. On the other hand, improving the commutation conditions by avoiding over-commutation and sub-commutation results in smaller currents between the brushes and the commutator fins, which can also reduce power dissipation: By using different brush materials or material compositions, both the plus and minus brushes can be used favorable commutation conditions are achieved. In addition to a reduction of the commutation losses or an increase in the efficiency of the DC machine, this measure also makes it possible, in principle, to improve the wear behavior on the brush and commutator. Overall, the use of different brush materials on the plus brush and the minus brush represents an additional degree of freedom in the design of electrical machines with commutator.

When using the same brush materials and the same material compositions of plus and minus brushes arise due to the opposite polarities of the brush different brush voltage drops between brush and blade. Provided the material composition is the same, a significantly higher voltage drop occurs at the plus brush than at the minus brush.

By using plus brushes with higher copper content, the brush voltage drop at the plus brushes can be reduced. For example, a configuration is conceivable in which approximately the same brush voltage drop occurs due to different material compositions on the plus brush and the minus brush. By reducing the brush voltage drop or the brush contact resistance on the plus brush, a higher power can be achieved there, while at the same time the short circuit current increases.

By reducing the brush voltage drop at the plus brush, the power loss is significantly reduced. In contrast, due to the same brush voltage drop at the negative brush there, the associated power loss remains approximately constant over a wide current range. Deviations occurring are due to changed commutation conditions.

Advantages of the invention

The advantage of using different brush materials on the plus brush and the minus brush is that the commutation losses at the plus brush can be reduced without increasing the commutation losses at the minus brush. In particular, this makes it possible to find a suitable compromise between optimizing the power in the range of the maximum power without increasing the commutation losses in the no-load range.

Brief description of the drawings

With reference to the drawings, the invention will be described in more detail below.

It shows:

1 A longitudinal section through a trained as a starter electric machine,

2 the course of the brush voltage drop at the plus and minus brush, plotted against the current density,

3 Performance characteristics of an electric machine when using different materials for plus and minus brushes,

4 the course of the power loss at the plus brush, plotted against the current,

5 The course of power loss at the minus brush, plotted against the current.

variants

1 shows a longitudinal section through an electric machine designed as a starting device with commutator.

The starting device 10 has a starter motor 13 and a Vorspuraktuator 16 on, which is designed for example as a relay, in particular starter relay. The starter motor 13 and the electric Vorspuraktuator 16 are on a common drive end shield 19 attached. The starter motor 13 serves as a starter 22 drive it when in the sprocket 25 one in 1 Not shown internal combustion engine is eingespurt.

The starter motor 13 has a pole tube as a housing 28 on that on its inner circumference pole shoes 31 carries, each from a field winding 34 are wrapped. The pole shoes 31 in turn surround an anchor 37 the one from slats 40 built anchor package 43 and one in grooves 46 arranged armature winding 49 having. The anchor package 43 is on a drive shaft 44 pressed. At the Andrehritzel 22 opposite end of the drive shaft 44 is also a commutator 52 attached, among other things, from individual Kommutatorlamellen 55 is constructed. The commutator bars 55 are in known manner with the armature winding 49 electrically connected in such a way that when the commutator bars are energized 55 through carbon brushes 58 a rotary motion of the anchor 37 in the pole tube 28 results. One between the electric Vorspuraktuator 16 and the starter motor 13 arranged power supply 61 supplies both the carbon brushes when switched on 58 as well as the excitation winding 34 with electricity. The drive shaft 44 is commutator side with a shaft journal 64 in a plain bearing 67 supported, which in turn in a Kommutatorlagerdeckel 70 is held stationary. The commutator bearing cover 70 turn is by tie rods 73 that go beyond the circumference of the pole tube 28 are distributed (screws, for example, 2, 3 or 4 pieces) in the drive end shield 19 attached. It supports the pole tube 28 at the drive end plate 19 off and the commutator bearing cover 70 at the pole tube 28 ,

In drive direction closes to the anchor 37 a sun wheel 80 on, the part of a planetary gearbox 83 is. The sun wheel 80 is from several planet gears 86 surrounded, usually three planet wheels 86 that by rolling bearings 89 on axle journal 92 are supported. The planet wheels 86 roll in a ring gear 95 off that in the pole tube 28 is stored outside. Towards the output side closes to the planetary gears 86 a planet carrier 98 on, in which the axle journal 92 are included. The planet carrier 98 will turn into an interim storage 101 and a slide bearing arranged therein 104 stored. The interim storage 101 is designed pot-shaped, that in this both the planet carrier 98 as well as the planet wheels 86 are included. Furthermore, in the cup-shaped intermediate storage 101 the ring gear 95 arranged that ultimately through a lid 107 opposite the anchor 37 closed is. Also the interim storage 101 supports with its outer circumference on the inside of the pole tube 28 from. The anchor 37 indicates that of the commutator 52 opposite end of the drive shaft 44 another shaft journal 110 on, who also in a plain bearing 113 is included. The plain bearing 113 in turn is in a central hole of the planet carrier 98 added. The planet carrier 98 is integral with the output shaft 116 connected. The output shaft 116 is with her from the interim storage 101 opposite end 119 in another camp 122 , which in the drive end shield 19 is fixed, supported.

The output shaft 116 is divided into different sections: So follows the section that is in the plain bearing 104 of the interim storage 101 is arranged, a section with a straight toothing 125 (Internal toothing), the part of a shaft-hub connection 128 is. The shaft-hub connection 128 allows in this case the axially rectilinear sliding of a driver 131 , The driver 131 is a sleeve-like extension, which is integral with a cup-shaped outer ring 132 a freewheel 137 connected is. The freewheel 137 (Richtgesperre) further includes an inner ring 140 that is radially inward of the outer ring 132 is arranged. Between the inner ring 140 and the outer ring 132 are clamp bodies 138 arranged. The clamp body 138 prevent in cooperation with the inner ring 140 and the outer ring 132 a relative rotation between the outer ring 132 and the inner ring 140 in a second direction. In other words: the freewheel 137 allows a circumferential relative movement between the inner ring 140 and the outer ring 132 only in one direction. In this embodiment, the inner ring 140 integral with the starter pinion 22 and its helical toothing 143 (External helical teeth) executed. The starter pin 22 Alternatively, it can be designed as a straight-toothed pinion. Instead of electromagnetically excited pole shoes 31 with excitation winding 34 could also permanent magnetically excited poles are used.

The electric Vorspuraktuator 16 or the linearly movable armature 168 In addition, they also have the task of using a tension element 187 one in the drive end plate 19 rotatably arranged lever 190 to move. The lever 190 , usually designed as a fork lever, engages two discs with two "tines" not shown here 193 and 194 on its outer circumference, around an entrained between these driver ring 197 to the freewheel 137 towards the resistance of the spring 200 to move and thereby the starter pinion 22 in the sprocket 25 einzuspuren.

Subsequently, the Einspurmechanismus will be discussed. The electric Vorspuraktuator 16 has a bolt 150 on, which is an electrical contact and in the case of being installed in the vehicle at the positive pole of a starter battery, which is not shown here, is connected. The bolt 150 is through a lid 153 passed. A second bolt 152 provides a connection for the electric starter motor 13 that's about the power supply 61 (thick wire) is supplied. The lid 153 closes a housing 156 made of steel, which by means of several fasteners 159 For example, screws, on the drive end plate 19 is attached. In the electric Vorspuraktuator 16 is a push device 160 to exert a tensile force on the fork lever 190 and a switching device 161 arranged. The pushing device 160 has a winding 162 and the switching device 161 a winding 165 , The winding 162 of the pusher 160 and the winding 165 the switching device 161 each effect in the on state, an electromagnetic field, which flows through various components. The shaft-hub connection 128 can take place with a spur gear 125 also be equipped with a steep thread toothing. There are the combinations possible, after which a) the starter pinion 22 is helical and the shaft-hub connection 128 a straight toothing 125 b) the starter pinion 22 is helical and the shaft-hub connection 128 indicates a steep thread toothing or c) the starter pinion 22 is straight-toothed and the shaft-hub connection 128 has a steep thread toothing.

2 the course of the brush voltage drop can be seen on a plus brush and a minus brush, each plotted against the current density.

According to the diagram 2 it can be seen that the course of the brush voltage drop 206 about the current density 208 is applied. When using the same brush materials and the same material compositions of plus brushes and minus brushes arise due to the opposite polarity of the plus brushes and the minus brushes different brush voltage drops 206 between the brushes 58 and lamellae 55 of the commutator 52 , The representation according to 2 It can be seen that here with the same material composition for plus brush and minus brush compare the course of the voltage drop 202 , for a plus brush significantly higher voltage drops occur compared to the course 204 the voltage drop for a minus brush. If a first brush material is used in plus brushes, which has a higher copper content compared to a second brush material for use on a minus brush, the corresponding brush voltage drop can be achieved 206 at the plus brush, which is made of the first brush material, which in particular has a higher copper content, significantly reduce. Due to the different material compositions of the first brush material and the second brush material, it is possible to brush on the plus brushes and the minus brushes 58 approximately the same brush voltage drop 206 adjust. Effects of a reduced brush voltage drop on the plus brush can be approximated to the diagram in 2 be removed. In a variant 1, the courses 202 . 204 the brush voltage drops 206 shown as characteristics. During the course 202 applies to the plus brush, the course refers 204 on the brush voltage drop on a minus brush.

In a variant 2, the brush voltage drop at the plus and at the minus brush is in each case due to the course 204 given for the voltage drop to plus and minus brush.

3 shows performance characteristics of a DC machine when using different material composition (copper content) in plus and minus brushes.

Will the in 2 illustrated course 204 , which is the course of the voltage drop of a minus brush and applies below as the reference brush voltage drop profile for variant 2, associated with a corresponding power characteristic, this results in 3 as a second performance characteristic 210 , In variant 2, the brush voltage drop 206 on plus and minus brush each through the course 204 according to 2 given. At the in 3 shown first characteristic 210 which is a first absolute maximum 212 by using the first brush material, which in particular has a higher copper content, the brush voltage drop 206 or the brush contact resistors on the plus brush reduced, so seen overall, a higher level of performance is achieved. The performance 221 is in the diagram according to 3 over the stream 224 applied. The first characteristic 210 in which the first absolute maximum 212 is a first short-circuit current 214 assigned.

In contrast, in the illustration according to 3 for Variant 1, a first performance characteristic 216 applied. In variant 1, the same material is used for the plus and the minus brushes. For the brush voltage drop, the gradients arise 204 for the minus and the course 202 for the plus brushes. This results in the course of the performance curve with the lower power, compare reference numerals 216 , In contrast, a higher proportion of copper is used according to variant 2 for the negative brush, so that the course of the brush transition voltage 204 for plus and minus brush sets and thus the performance according to the performance curve 210 can be increased.

The first performance curve corresponding to variant 1 216 also includes a first absolute maximum 218 , which, however, below the second maximum 212 is located, further a first short-circuit current 220 , also below the value for the second short-circuit current 214 the second power characteristic 210 , In variant 2, ie use of a plus brush of first brush material, which has a higher copper content, are both the second absolute maximum 212 as well as the second short-circuit current 214 higher than the corresponding values 218 respectively. 220 for the first characteristic 216 , the corresponds to the first variant, ie when using identical brush materials to plus and minus brush.

The carbon brushes 58 For example, they can be designed as two-layer brushes. The two-layer brushes comprise a power layer having a high conductance and a commutating layer having a lower conductance. The copper content of the material of the at least one plus brush - for example formed as a two-layer brush - is only increased in the power layer. Furthermore, with respect to the contact pressure of the plus and minus brushes to the commutator 55 of the commutator 52 to note the following: The at least one brush of carbon brushes 58 is applied to the commutator blades with a higher contact pressure 55 adjusted, which is preferably in a range between 15 N / cm ² and 30 N / cm ² . The at least one minus brush of carbon brushes 58 is preferably a contact pressure, which is between 10 N / cm ² and 25 N / cm ² , wherein the plus brush generally speaking, preferably with a by at least 5 N / cm ² higher contact pressure to the commutator 55 of the commutator 52 is pressed.

With regard to the copper content, it should be noted that the material of the at least one plus brush has a copper content of 45% to 65% and that of the minus brush has a copper content of 35% to 55%. The copper content of the material of the at least one plus brush must be at least 5 percentage points higher than that of the material of the at least one minus brush of the carbon brushes 58 ,

The representations according to the 4 and 5 In each case, power losses to the plus or minus brush are plotted against the current intensity.

4 shows that the power loss corresponding to the first loss performance curve 226 for the plus brush according to variant 1 increases exponentially, while according to a second power loss curve 228 in a plus brush according to variant 2, ie made of a first brush material, with a higher copper content and different from the second brush material of the negative brush, the power loss at higher currents can be more than halved.

From the illustration according to 4 shows that due to the higher loss of power loss at the plus brush by the invention proposed invention, a more significant reduction of the same can be achieved compared to a power loss reduction at the minus brush.

The improvement of the power loss, ie its reduction in the negative brush can be the loss line course 222 , applied over the stream 224 according to the minus brush 5 remove. Both curves ie 230 and 232 , which characterize the first loss performance curve at the minus brush for variant 1 and the second loss performance curve at the minus brush for variant 2, run for average currents up to 600 amps approximately parallel to each other and are characterized by a uniform increase. Only for higher currents is the second loss performance curve 232 on the minus brush according to variant 2 slightly larger than the first power loss curve 230 on the minus brush according to variant 1. This slightly higher. Power loss history 232 according to 5 for the negative brush at currents above 600 amps is essentially due to the changed commutation conditions.

The advantages of using different brush materials, i. H. of the first brush material for the at least one plus brush and the second brush material different therefrom for the at least one minus brush lie in that the commutation losses at the plus brush can be reduced without significantly increasing the commutation losses at the minus brush. In particular, the inventively proposed solution makes it possible to easily find a suitable compromise between an optimization of the power in the region of the maximum power without an increase in a commutation loss in the no-load range.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102007058903 A1 [0001]
• DE 102007063333 A1 [0002]
• DE 102008001702 A1 [0003]
• US 2003/0080647 A1 [0004]

Claims (8)

Commutation device ( 55 . 58 ) for a DC electric machine, in particular a starting device ( 10 ) for internal combustion engines, with a commutator ( 55 ), brushes ( 58 ), and the at least one plus brush and at least one minus brush comprise, characterized in that the at least one plus brush is made of a first brush material which is different from a second brush material from which the at least one minus brush is made. Commutation device according to claim 1, characterized in that the first brush material for the at least one plus brush has a higher copper content than the second brush material for the at least one minus brush. Commutation device according to one of the preceding claims, characterized in that the material of the at least one plus brush has a copper content of 45% to 65% and that of the minus brush a copper content of 35% to 55%. Commutation device according to one of the preceding claims, characterized in that the copper content of the material of the at least one plus brush is at least 5 percentage points higher than that of the material of the at least one minus brush. Commutation device according to one of the preceding claims, characterized in that the at least one plus brush and the at least one minus brush are each designed as two-layer brushes having a layer with high conductance (power layer) and a layer with lower conductance. Commutation device according to the preceding claim, characterized in that the copper content of the material of the at least one plus brush in the power layer is increased. Commutation device according to one of the preceding claims, characterized in that the at least one plus brush with a higher contact pressure, preferably in a range between 15 N / cm ² and 30 N / cm ² to the commutator ( 52 ) is pressed, as the at least one minus brush, preferably with a contact pressure between 10 N / cm ² and 25 N / cm ² at the circumference of the commutator ( 52 ) is employed. Commutation device according to one or more of the preceding claims, characterized in that the plus brush with a by at least 5 N / cm ² higher contact pressure to the circumference of the commutator ( 52 ) is employed.

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