FR2492487A1 - EM clutch coupling diesel engine and alternator in standby generators - uses conical clutch with non-magnetic friction material and an overloaded coil to draw and hold halves together - Google Patents

Abstract

The clutch has an electromagnet coil is fitted onto the diesel engine output shaft and, once the diesel engine is started, is supplied by up to fifteen times normal voltage to increase the time rate of current build up. When the coil is energised the magnetic flux links the iron around the coil, passes across the air gap and through the mobile plate coupled to the alternator shaft, drawing the two together. The inside of the outer rim of the moving plate and the outside of the fixed element are cut as matching truncated cones with a taper of between 50 and 140 degrees, and the inside of the moving plate taper has a non-magnetic, resin, bonded copper friction block fitted, providing the friction coupling between engine and alternator. The clutch is used in an emergency stand-by electricity generating system.

Description

 The invention relates to an electromagnetic clutch, in particular for a standby generator, as well as a method for putting it into operation.

We know that a generator includes an alternator which supplies a regulated and stabilized voltage to any electrical equipment (equipment used in a hospital, radar, etc.). The alternator is normally driven by an electric motor powered by the sector, and it drives itself a flywheel connected by an electromagnetic clutch to an internal combustion engine, such as an engine
Diesel constantly preheated. In the event of interruption of the supply of electrical energy by the sector, the engine
Diesel is started; when synchronism is reached between its rotational speed and that of the alternator, the electromagnetic clutch is made operative by excitation of its induction coil and it drives the alternator by the diesel engine. The flywheel prevents significant alternator stopping or slowing down between stopping the electric motor and the moment when the diesel engine speed becomes sufficient.

 However, sometimes the Diesel engine cannot be started quickly, although it will be kept preheated. In this case, to avoid appreciable slowing down or even stopping of the alternator, the coil of the electromagnetic clutch is immediately excited pexlr to make this operative and to start the diesel engine by means of the torque supplied by the flywheel 'inertia. The torque transmitted by the clutch then varies very suddenly from zero to an extremely high value. For this reason, electromagnetic clutches with a single large diameter disc-shaped friction lining have so far been used, which are capable of transmitting very large torques.

 However, such clutches are very bulky. In addition, they do not support high rotational speeds, which in imitation of the rotational speeds of the alternator and of the diesel engine.

 Hitherto, "slow" alternators and diesel engines, that is to say having rotational speeds of the order of 1000 to 1500 revolutions / minute, have been used in such generator sets. There is, however, a tendency to replace them with alternators and “fast” diesel engines, having rotational speeds of the order of 3000 to 3600 revolutions / minute, which are much less expensive; The increase in the speed of rotation also results in a reduction in the size of the flywheel, which is advantageous in many aspects.

The need is therefore currently felt for an electromagnetic clutch, in particular for a standby generator, which, at the same time, can withstand high rotational speeds and transmit a torque capable of passing very suddenly from zero to a very important value, as it happens for starting an engine
Diesel.

 The invention provides for this purpose an electromagnetic clutch comprising a pole piece housing an induction coil, a movable armature capable of being attracted magnetically towards the pole piece when the coil is electrically supplied, and an annular friction lining between the piece pole and the movable armature, characterized in that said lining is in the form of a truncated cone, the axis of which coincides with the axis of rotation of the clutch and is suitable for engaging a frustoconical surface of angle at top equal to that of the garnish.

 The use of a friction lining which is not a flat disc, but a truncated cone, and which co-operates by friction with a frustoconical surface of a pole piece, allows, with equal dimensions, to multiply by a coefficient between 1.5 and 2 the maximum torque transmissible by one clutch.

 The invention also provides a method of operating an electromagnetic clutch, in particular for starting a diesel engine forming part of a standby generator, the clutch comprising a driven part connected to the drive shaft. motor output and a driving part integral with a flywheel, characterized in that the clutch induction coil is supplied with a continuous overvoltage during a time interval corresponding substantially to the engine starting period Diesel.

 According to another characteristic of the invention, the overvoltage can reach up to fifteen times the normal supply voltage of the coil, the duration of its intervention being between 0.5 and 15 seconds approximately.

 It is thus possible to increase the magnetic attraction force exerted on a movable frame of a clutch by a fixed pole piece housing an induction coil, while reducing the duration of establishment of the magnetic field. The torque transmitted by the clutch is simultaneously increased.

In the description which follows, given by way of example, reference is made to the appended drawings, in which
- Figure 1 shows schematically, in the form of blocks, a generator to which the invention is applicable; and
- Figure 2 is a half view, in longitudinal section, of an electromagnetic clutch according to the invention.

 We first refer to Figure 1 which schematically shows a generator. This group comprises an electric motor 10 supplied with electric energy by the network, in the conventional manner, and the output shaft of which drives an alternator 11 intended to produce a regulated and stabilized supply voltage of any electrical appliance, by example a device used in a hospital, a radar; etc. On the alternator output shaft 11 is fixed a flywheel 12 integral in rotation with a driving part 13 of an electromagnetic clutch 14. The driven part 15 of this clutch is integral in rotation with the shaft Diesel engine output 16.

 Under normal conditions, the alternator is driven in rotation by the electric motor 10 supplied with energy.

The flywheel 12 and the driving part 13 of the electromagnetic clutch 14 are also driven in rotation, while the driven part 15 and the output shaft of the engine
Diesel 16 does not rotate. The diesel engine 16 is however constantly preheated, so that it can be started very quickly. In the event of a breakdown of the electric motor 10 or of interruption of the supply of energy, the diesel engine 16 is started and, when the speed of rotation of its output shaft is substantially equal to that of the alternator 11, c 'that is to say that of the flywheel 12 and the driving part 13 of the clutch 14, this clutch is coupled, so that the alternator 11 is rotated by the diesel engine 16, by through the clutch 14 and the flywheel 12.

 As indicated above, it sometimes happens that, for whatever reason, the diesel engine 16 cannot be started immediately. In this case, the electromagnetic clutch 14 is immediately coupled, so that it transmits to the engine Diesel 16 the torque provided by the flywheel 12, which has the effect of starting the Diesel 16 engine very suddenly.

 Referring now to Figure 2, which shows a half view, in longitudinal section, of an electromagnetic clutch 14 according to the invention.

 This clutch 14 comprises a cylindrical sleeve 20, suitable for being connected to the flywheel 12 to be driven in rotation about the axis 21. An annular piece 22, for example of mild steel, forms the movable frame of a electromagnet and is mounted integral in rotation with the sleeve 20 and free in translation relative to the latter, so as to be driven in rotation by the sleeve 20 and to be able to slide along the latter, parallel to the axis 21. Opposite the movable frame 22 is an annular piece 23 of mild steel, having two cylindrical walls 24 and 25 of common axis 21, which are joined together, opposite the movable frame 22, by an annular wall bottom 26 perpendicular to the axis 21.

 In the annular space limited by the cylindrical walls 24, 25 and by the annular wall 26, is housed an induction coil 27 whose supply conductors 28 pass through the bottom wall 26 and are connected to an energy source electric by a device 29 with double brush.

 The pole piece 23 is fixed, for example by welding, to a cylindrical sleeve 30, axially aligned with the sleeve 20 and suitable for being connected to the output shaft of a diesel engine in this example.

 A piece 31 of non-magnetic metal, for example bronze1 is fixed to the front end of the sleeve 30, opposite the end of the sleeve 20, to reduce the losses of magnetic flux. Another annular part 32 of non-magnetic metal, for example bronze, is used for fixing on the sleeve 20 the internal peripheral edge of a disc 33 made of spring steel, the external peripheral edge of which is fixed by screws 34 at the periphery. of the movable frame 22. The disc 33 serves as a means of returning the movable frame 22 to the decoupling position of the electromagnetic clutch 14.

 The screws 34 for fixing the external periphery of the disc 33 also serve for fixing, on the face of the movable frame 22 which is oriented towards the pole piece 23, of an annular piece 35 having a frustoconical internal bearing 36 whose the top is located on the axis of rotation 21 on the side of the sleeve 20. On this frustoconical bearing surface 36 is fixed, for example by gluing and riveting, a friction lining 38 with a wall of substantially constant thickness and itself having the shape of a truncated cone whose apex is located on the axis of rotation 21 on the side of the sleeve 20. The angle at the apex of this truncated cone is advantageously between 500 and 14 in.

 This friction lining is intended to engage, during coupling of the clutch, a corresponding frustoconical surface 39 of an annular part 40 fixed by screws or studs 41 on a peripheral annular flange 42 of the pole piece 23. The top of the frustoconical surface 39 is also located on the axis of rotation 21 on the side of the sleeve 20 and its apex angle is equal to that of the lining 38 or of the frustoconical bearing 36.

 The friction lining 38, made of non-magnetic material, must be able to withstand very sudden and very significant forces, and is advantageously made of an asbestos fabric reinforced with red copper, impregnated with a binder of synthetic resin.

 As the cylindrical walls 24 and 25 of the pole piece 23 are surrounded internally and externally with pieces of non-magnetic material preventing the passage of magnetic flux, the path of the magnetic flux generated by the coil 27 when it is supplied with electrical energy is limited to the contour 43 drawn in dotted lines. This avoids losses of magnetic flux in the vicinity of the movable armature 22 and the pole piece 23.

This electromagnetic clutch 14 operates in the following manner
When the coil 27 is not supplied with electrical energy, the return disc 33 keeps the movable armature away from the pole piece 23, so that the friction lining 38 carried by the movable armature 22 is separated of the frustoconical surface 39 of the part 40 Solidary in rotation of the p -; - this polar 23.

 When the coil 27 is energized, the movable armature 22 is attracted inagnetically to the pole piece 23 and moves along the axis 21 by elastically deforming the return disc 33. The friction friction 38 is applied! on the truncated surface 39 of the part -a, so that the sleeve 30 is rotated by the sleeve 20, by means of the movable frame 22, the friction lining 38, the part 40 and the pole piece 23.

 Due to the frustoconical shapes of the friction lining 38 and the corresponding engagement surface 39 of the part 40, the displacement of the movable armature 22 towards the pole piece 23 results in a wedging effect between the friction lining and the part 40. This frustoconical shape of the lining also makes it possible, for the same radial size, to increase the contact surface between the lining and the part 40. These two effects combined result in an increase in the maximum value of the torque of rotation transmissible by the electromagnetic clutch 14. It will be specified by way of example, that the maximum transmissible value of the torque is multiplied by a coefficient equal to approximately 1.66 when the angle at the top of the truncated cone formed by the friction lining 38 is 800.

 The value of the maximum transmissible torque can be further increased and the response time of the electromagnetic clutch 14 can be reduced if the coil 27 is supplied with an overvoltage several times greater than its normal supply voltage, for a period of relatively short time.

For example, the coil 27 can be supplied with an overvoltage which can reach fifteen times the nominal supply voltage (330 volts instead of 24 volts) during a time interval between approximately 0 5 and 15 seconds, which makes it possible to multiply by 1 3 the value of the torque transmissible by the clutch and divide by 7 or 8 the time of establishment of the magnetic field, and therefore the response time of the clutch.

 By combining these two characteristics of the invention (frustoconical shape of the friction lining and supply by an overvoltage of the induction coil>, it is possible, by keeping the same clutch size, to multiply by 2 the torque transmissible by this clutch, This result is particularly interesting in the case where the clutch is used in the manner shown in FIG. 1, that is to say in a standby generator.

 As the rotation speed of the clutch must be relatively high (for example of the order of 30O at 3600 revolutions / minute), the frustoconical bearing surface 3t3 on which the friction lining 38 is fixed advantageously ends with a perpendicular flange 44 on which is supported the upper end edge of the trim. This rim 44 holds the lining 38 in place with respect to the centrifugal force.

Claims (13)

 1. Electromagnetic clutch, comprising a pole piece housing an induction coil, a movable armature capable of being attracted magnetically towards the pole piece when the coil is electrically supplied, 7 and an annular friction lining between the pole piece and the arma mobile structure characterized in that said lining is in the form of a truncated cone, the axis of which coincides with the axis of rotation of the clutch and is capable of engaging a frustoconical surface with an angle at the top equal to that of the lining.  2. Clutch according to claim 1, characterized in that the friction lining is fixed on a frustoconical surface of a support piece and is held with respect to the centrifugal force by an annular flange of said support piece.  3. Clutch according to claim 1 or 2, characterized in that said lining is fixed, by means of the support piece, on the movable frame.  4. Clutch according to one of the preceding claims, characterized in that said lining is made of non-magnetic material.  5. Clutch according to claim 4 characterized in that the lining consists of an asbestos fabric reinforced with red copper, impregnated with a synthetic resin binder.  6. Clutch according to one of the preceding claims, characterized in that the angle at the top of the truncated cone formed by the lining is between approximately 50 and 1400.  7. Clutch according to one of the preceding claims, characterized in that the movable frame is associated with a return means in the rest position or decoupling, consisting of a spring steel disc.  8. Clutch according to one of the preceding claims, for an emergency generator set characterized in that the movable armature is integral in rotation with a flywheel driven by an alternator and the pole piece is integral in rotation with the output shaft of a diesel engine.  9. Clutch according to claim 8, characterized in that, during the diesel engine starting period, the coil is supplied by an overvoltage which can reach fifteen times its nominal supply voltage, for a period of 0.5 to 15 about seconds.  10. Method for putting an electromagnetic clutch into operation, in particular for starting an engine Diesel part of an emergency generator; the clutch comprising a driven part connected to the output shaft of the engine and a soldier driven part of a flywheel driven in rotation characterized in that it consists in supplying the induction coil of the clutch by a continuous overvoltage during a time interval corresponding substantially to the starting period of the diesel engine.  11. Method according to claim 10, characterized in that the over voltage can reach fifteen times the normal supply voltage of the coil.  12. Method according to claim 10 or 11, characterized in that the coil is supplied by the overvoltage for a period of between approximately 0.5 and 15 seconds.  13. Method according to one of reyendications 10 to 12, characterized in that it consists in providing, between the driving part and the driven part, a friction lining in the form of a truncated cone whose angle at the apex is included between about 50 and 1409.