DE4200824A1 - Dynamo-electric flywheel energy store - has rotor shaft with desired point of fracture which lies outside rotor bearings - Google Patents

Abstract

The flywheel energy store is arranged in an evacuated housing and includes a flywheel rotor. Permanent magnets are fixed to the rotor concentrically to a symmetric axis. A stator is concentric within the rotor to the symmetric axis on a rotor shaft. Windings are positioned opposite the permanent magnets according to whether the electric dynamo flywheel store is to be driven as a motor or as a generator. The rotor shaft (32) has a desired point of fracture (57) which lies outside the bearings (29,30,33,34,59,60) of the rotor (3). ADVANTAGE - Is safer with respect to damage due to e.g. corrosion of rotor bearings.

Description

The invention relates to a dynamo-electric swing Wheel memory according to the preamble of claim 1.

In the magazine "electric railways - eb" 87 (1989) Booklet 5, pages 135 to 140, is in the article "Magnet-Mo Gate drive for commercial vehicles and consumption and emissi onsoptimized local buses "a magnet dynamic Memory described. This magnetic dynamic memory is a rotating flywheel accumulator with an inte electric machine that can be used as needed Motor to load the storage or as a generator to ent loading the memory works. A serves as an energy source hollow cylindrical fiberglass rotor with vertica axis of rotation. The free interior of the rotor contains the Motor / generator unit through which the intake and delivery electrical energy. The rotor is mounted that no moving mechanical parts are led to the outside are. The housing is evacuated, which eliminates the air Exercise losses are reduced to a minimum. Further the flywheel storage has no gearbox and none running electrical parts. Usually is a such rotor is mounted on a shaft via roller bearings. If the rolling bearing fails, it is possible that the Eat bearings and therefore a more or less force conclusive connection between the rotor and the shaft  will be produced. With such bearing damage, it can In addition, the shaft pulls out of the housing or that the wave shears off. By eliminating the wave as Guide for the rotor is the energized rotor zer disturbs.

It is also known between the vehicle and the Flywheel storage elastic links with corresponding Suspension and damping to be provided in order to drive and loads on the rotor position in the event of accidents limit. In the known flywheel storage are for this purpose between the flywheel storage and a frame surrounding the flywheel storage four Large-volume spring damper elements arranged at 90 ° ment provided.

The object of the invention is a dynamoelectric To create flywheel storage that is safer compared Is damage or destruction.

This object is inventively in a genus dynamoelectric flywheel storage through the Features of the characterizing part of claim 1 ge solves.

Due to the inventive design of a vertical standing rotor shaft with a predetermined breaking point is enough that if the rotor is blocked by at for example, a bearing damage defines the rotor shaft tears off. The predetermined breaking point is arranged so that at a break in the section of the shaft on which the rotor ge is stored as a component is preserved. this section the shaft is provided with emergency bearings, so that the Ro defined gate can be braked. The emergency run camp consist of radial bearings in the radial direction are preferably lubricated with a solid lubricant. In  axial direction is between the housing and the forehead Side of the rotor shaft a bearing arranged, for example can only consist of a single ball.

Usually the driver notices one with an invented one dynamoelectric flywheel storage verse hen motor vehicle not the occurrence of damage or destruction of the rotor shaft or the rotor, because the dynamoelectric flywheel memory according to the invention is provided with a double-walled housing. For this The reason is the dynamoelectric according to the invention Flywheel storage with a sensor that the Occurrence of damage or destruction within of the housing. In the simplest embodiment the sensor indicates the wave break. This can be done happen that a tear line between the housing or a housing part and the rotor shaft is attached, which is separated when the rotor shaft is turned. On in this way a signal is generated which is sent to the driver of the Vehicle via optical and / or acoustic means will wear.

As in the prior art, the dy namoelectric flywheel storage both as a generator as well as being operated as a motor. The generator operation can also be switched on in the event of a malfunction Braking the rotor electrically by withdrawing power. This can automatically via a corresponding control and / or done manually by the driver. Preferably becomes the control by disconnecting the demolition pipe causes the rotor to brake, causing another Charge is prevented. Furthermore, the rotor can be in one Incident due to the supply of air to the evacuated Be braked inside the housing. Preferably the rotor is braked in the event of a malfunction the supply of a coolant that is in normal operation  to remove the ent between the rotor and the stator standing heat. Due to the high speeds of the Rotors that are between 15,000 and 30,000 revolutions per Minute in operation, it can slow down the cooling liquid to evaporate the cooling liquid and thus an increase in pressure in the housing come. To limit the resulting pressure, Ge housing as a separate or integrated component pressure valve arranged or formed.

To increase the life span are between two as a layer tion serving ball bearings two needle bearings spaced to each other between the rotor shaft and the rotor arranges. The needle bearings are in order Seat the ball bearings on the rotor shaft with play arranged to the rotor. The size of this game is so big measure that from a certain degree of wear of the ball bearing contact surfaces the corresponding contact surfaces of the Needle bearings come into engagement with the rotor.

The bearings are easily lubricated by the arrangement of at least one with lubricant impregnated sintered ring, the one above the upper ball bearing is arranged. The ball bearing points at its hardest inner ring a gutter-shaped collecting device for the down from the sinter ring during operation dripping lubricant. Matching is umlau the outer ring a shovel-like distribution device arranged, which accumulated in the catcher the lubricant back up into the bearing promotes. In another embodiment the arrangement is tion of the collecting device and the distribution device vice versa, so that on the fixed part the distribution device and on the rotating part the catchment device device is attached. A second drink with lubricant The sintered ring can be between the two roller bearings  be ordered. With the appropriate training from Channels or the like, it is possible that through the upper sintered ring next to the ball bearing and the one below roller bearings can be lubricated. In the same Lubricant can pass through from the second sintered ring an appropriate formation of channels through the Na reach the lower ball bearing. This too Ball bearing can with a fall arrester and a Distribution device for the lubricant may be provided.

To dissipate the dy Namoelectric flywheel storage heat generated a cooling circuit is provided. For this purpose, the Rotor shaft designed as a hollow shaft into which a coaxial arranged tube is inserted so that by the Coolant flowing through the pipe at the closed bottom end of the rotor shaft comes out of the tube and between the outer tube wall and the shaft surface upwards flows. The top of the shaft is between the tube and the cavity of the shaft sealed. Below the Seal runs a radially outward Boh tion or recess that in an axially extending Boh tion or recess opens. The axial bore leads to the back of magnetic sheets of the stator. On this The coolant flows past and on the back closing over another axial bore or recess back to the outside, for example in a heat rope shear in which the stored in the coolant Heat is dissipated. To enlarge the cooling surfaces the magnetic sheets are stepped or offset arranged to each other.

For the embodiment in which the cooling liquid for Braking the rotor in the event of a malfunction is the The predetermined breaking point is arranged so that the rotor breaks a connection between the cooling circuit and the  The interior of the rotor housing is created. Preferably this place trained there at a cross section reduction through the radial bore or recess for the cooling circuit already exists. Another Cross-sectional reduction can be brought about by a circumferential groove or notch in the amount of the radial Aus Take or bore on the outer surface of the rotor shaft is trained.

The flywheel consists of a fiber composite, in particular especially made of a glass fiber reinforced plastic (GRP), made of an aramid fiber reinforced plastic and / or a carbon fiber reinforced plastic (CFRP) is.

By designing the outer shell of the housing as part of the vehicle structure it is possible that the in the dynamoelectric flywheel storage Large forces over the housing into the vehicle structure can be forwarded. For example, the outer shell of the housing similar to a spare wheel recess in the floor pan of the vehicle. in the This housing is essential for security reasons formed approximately in the middle of the vehicle, so that at one Side, rear or frontal impact the housing is largely protected. The housing is also located approximately in the center of gravity of the vehicle, so that only a slight influence on vehicle movements on the Dynamoelectric flywheel memory according to the invention takes place.

In a preferred embodiment, the outer Ge housing closed by a lid-like part. The outer housing can be unproble to reduce weight be provided with openings. Within the outer case is an inner case,  where between the two housings or shells spring and / or damper elements are arranged. This feather and / or damper elements can be metallic, hydraulic, be pneumatic and / or elastomeric. By a correspond Adequate spatial distribution of the spring and / or damper elements and the coordination in spring / damping behavior can be targeted for all operating conditions and Force directions set the required properties len. So z. B. the inner case in a vertical direction be soft and stiff in the direction of travel. The Using several spring and / or damper elements can an easy setting of the desired dynamic egg properties. This results in a high level of redundancy if an element fails. Since the inner shell is none Must pick up point loads, they can be leakproof criteria are interpreted. Through the double-shell Build-up becomes a good insulation of body and air reached sound. The second, outer housing also serves as a second shield against both damage to the rotor as well as in a crash.

Embodiments of the invention are described below the drawings described by way of example. Here zei gene:

Fig. 1 is a sectional view from the side of the dynamo-electric flywheel storage means,

Fig. 2 is an enlarged view of a portion of the serving as cooling surfaces magnetic sheet rear and

Fig. 3 is a schematic diagram in section of the Wälzla geranordnung and the associated lubrication.

Fig. 1 shows the structure of a dynamoelectric flywheel memory 1. The dynamo-electric flywheel memory 1 , which is referred to below as shortly flywheel memory, consists essentially of a stator 2 and a rotor 3 , which are arranged in an evacuated housing 4 . Around the evacuated inner housing 4 , an outer housing 5 is provided which is integrated in the vehicle structure, for example in the floor panel 6 of the vehicle body. The force transmission between the outer and the inner housing 5 , 4 takes place by means of spring and / or damper elements 7 to 11 . These spring and / or damper elements can be designed as closed rings or as ring segments.

The rotor 3 is a flywheel, which is made in the present embodiment for safety reasons from a plastic-fiber composite. The part 12 forming the flywheel is an annular body with a coaxial, internal recess or opening 13 . Between the flywheel 12 and the opening 13 of the rotor 3 , a further annular part or a hub 14 is connected to the flywheel 12 , which is formed from two rings 15 and 16 in the embodiment shown. The rings 15 and 16 are shaped such that the annular part 14 has an upwardly open ringför shaped recess 19 in cross section.

On the lower end face 20 of part 16 , a ring-shaped permanent magnet 21 is arranged horizontally. A permanent magnet 22 of the same size, with opposite polarity, is fastened on the inner housing 4 opposite this permanent magnet 21 . The two permanent magnets 21 and 22 serve for the floating mounting of the rotor 3 in the housing 4 about an axis of symmetry 23 . Permanent magnets 24 made of circular segments are fastened to a surface 17 of the ring 15 directed towards the axis of symmetry 23 .

Compared to the permanent magnets 24 , windings 26 are attached to the stator 2 via magnetic sheets 28 . A gap 25 is formed between the permanent magnets 24 and the windings 26 .

The bearing of the rotor 3 takes place in the present embodiment via ball bearings 29 , 30 , which are arranged spaced apart from one another on a surface 31 of the ring 16 formed on the axis of symmetry 23 and on the other hand on a rotor shaft 32 . Between the ball bearings 29 , 30 needle bearings 33 , 34 are arranged in the present embodiment. The seat of the needle bearings 33 , 34 between the respective races or the common race 35 and the corresponding opposite surface of the rotor 3 , 16 is dimensioned so that the Nadella ger 33 , 34 only from a predetermined degree of wear of the ball bearings 29 , 30 in engagement come with the rotor 3 . Between the needle bearings 33 , 34 an annular clamping element 37 is arranged for the correct positioning of the Na dellager 33 , 34 in the axial direction. In the present embodiment, the bearings 29 , 30 and 33 , 34 are lubricated via a sintered ring 38 soaked with lubricant. Above an upper end face 40 of the annular part 14 , the sintered ring 38 is attached to the rotor 3 .

The rotor shaft 32 is attached to a rotationally symmetrical part 41 via rotationally symmetrical clamping elements 42 with, for example, a wedge-shaped cross section on the inner housing 4 . The rotor shaft 32 is seen with a blind bore or with a corresponding recess 43 , into which a coaxially arranged tube 44 leads to the end of the blind bore 43 . The tube is open at its lower end 45 . Between the outer tube wall 46 and the inner surface of the blind bore 43 , an annular gap 47 is formed as a riser for a cooling circuit. At the upper end 48 of the rotor shaft 32 below the clamping elements 42 at least one radially extending bore 49 is provided which passes through the rotationally symmetrical part 41 and opens into the annular gap 47 . Parallel to the symmetry axis 23 is a further bore or a channel 50 which leads into an annular gap 51 between the rear sides 52 of the magnetic plates 28 and the rotationally symmetrical part 41 . The sealing of the gap 51 he follows through seals 53 , 54 , in particular through O-rings. The coolant 55 leaves the flywheel accumulator 1 via a line 56 opening into the gap 51 .

The rotor shaft 32 is seen with a predetermined breaking point 57 , which in the present embodiment lies at the level of the bore or the channel 49 . The predetermined breaking point 57 has, as a further reduction in cross section, a circumferential groove 58 , the shape of which has a predetermined notch effect. Below the predetermined breaking point 57 , a first sliding bearing 59 is arranged in front of the upper end face 40 of the rotor ring 16 . Below the permanent magnet 21 , a second slide bearing 60 is seen in the inner housing 4 . The generally perpendicular rotor shaft is axially supported at its lower end 61 axially via a bearing 62 , this bearing being able to consist of only one ball 63 . The slide bearings 59 and 60 are preferably sintered bearings with a solid lubricant, which can be Teflon, for example. The plain bearings 59 , 60 are designed so that the rotor 3 can be braked from its maximum speed, which can be 30,000 revolutions per minute, to a standstill of the rotor. On the rotationally symmetrical part 41 or to the rotor shaft 32 is screwed a lid 64, between the lid 64 and the rotor shaft 32. Seals 65 and 66 are provided. Furthermore, seals 68 and 69 are provided above and below the point 67 at which the channel 49 opens into the shaft 32 .

The predetermined breaking point 57 is provided in the event that the rotor 3 blocks, for example when the ball bearings 29 , 30 eat. When the rotor 3 is blocked, the rotor shaft 32 tears off at the intended breaking point 57 . The predetermined breaking point 57 is arranged so that a break between the cooling circuit 44 , 47 , 49 , etc. and an interior 70 of the inner housing 4 is Herge at break. Due to the prevailing negative pressure in the inner housing 4 , the cooling liquid, in particular special cooling water, flows into the inner housing 4 . The coolant also serves to brake and cool the rotor. Due to the heat generated during braking, steam can form and thus overpressure in the inner housing 4 . To compensate for the excess pressure, a bursting membrane or a pressure relief valve 71 can be arranged in the housing so that the steam pressure occurring in the event of damage can be reduced.

Below the predetermined breaking point 57 , a sensor 72 is arranged between the rotor shaft 32 and the rotationally symmetrical part 41 . The sensor 72 serves to indicate whether there is a damage, ie whether the rotor shaft 32 rotates with the rotor 3 after a break. In the vorlie embodiment, the sensor 72 is a thin electrical tear line. When the rotor shaft 32 is sheared off, this tear-off line 72 is cut off. As a result, an electrical circuit can be interrupted, which is used to indicate the event of damage and / or to enable the electrical drive for the rotor 3 .

The structure of the Schwungradspei chers 1 described above thus results in an emergency storage when blocking the rotor 3 , a cooling of the components in the rotor crash and a braking of the rotor 3 by the inflowing coolant.

A protective ring 74 is arranged opposite the outer surface 73 of the rotor 3 to protect the inner surface 75 of the inner housing 4 from bursting. The protective ring 74 is preferably made of a material with a low melting point in order to convert the stored energy into heat of fusion when the rotor 3 is braked in the event of damage. In the embodiment shown in FIG. 1, the protective ring 74 is provided with circumferential and spaced apart webs 76 . In another embodiment, the spaces 27 between the webs 76 may be filled with a material with a low melting point. As a rule, the protective ring 74 is made of light metal or plastic.

Between the inner housing 4 and the outer housing 5 , the spring and / or damper elements 7 to 11 are arranged. The number and position of the spring and / or damper elements depends on the specified operating conditions. In addition to the embodiment shown in FIG. 1, it is possible to provide only two spring and / or damper elements which have approximately the position of the spring or damper elements 8 and 10 . In another embodiment, it is possible to provide spring and / or damper elements as it corresponds to the position of the spring and / or damper elements 7 , 9 and 11 . There are also a variety of other possible combinations.

As shown in Fig. 1, the outer Ge housing 5 is constructed in two parts. A lower part 77 is part of the vehicle structure. The forces introduced by the machine 1 can thus be recorded over a large area. At the same time, the outer housing 5 contributes to the rigidity of the vehicle. The outer housing 5 may be hen verses for reasons of weight reduction with openings. An upper part 78 formed as a cover can be attached to the lower part 77 . The position and design of the cover 78 can be designed so that only small forces have to be absorbed by it. In another embodiment, the parts are interchanged ver, so that the lower part 77 is formed as a cover and the upper part 78 is part of the vehicle structure.

In FIG. 2 is a partial view of the magnetic plates 28 is shown. To generate a larger cooling surface, the ends of the magnetic surface projecting into the gap 51 of the cooling circuit are offset from one another.

Fig. 3 shows a schematic representation of the order and lubrication of the rotor bearing. In particular, it can be seen from FIG. 3 that on the rotating outer or races 79 , 80 of the ball bearings 29 , 30 a scoop and / or hook-shaped lubricant delivery device 81 , 82 is provided, each in a channel-shaped lubricant collecting device 83 , 84 protrudes. The lubricants dripping from the sintered rings 38 , 39 are conveyed upwards again by the conveying devices 81 , 82 , so that adequate lubrication is ensured. Through the formation of channels between the ball bearing 29 and the needle bearing 33 or the needle bearing 34 and the ball bearing 30 , an adequate distribution of the lubricant between the ball and needle bearings is achieved.

Claims (14)

1. Dynamoelectric flywheel accumulator, which is arranged in an evacuated housing, the flywheel accumulator consisting of a rotor provided with a flywheel, to which concentric magnets are attached to an axis of symmetry, with a stator, which is concentric with the axis of symmetry on a rotor shaft within the rotor is provided, with corresponding windings in relation to the permanent magnets being designed to operate the dynamo-electric flywheel storage as a motor or as a generator, characterized in that the rotor shaft ( 32 ) has a predetermined breaking point ( 57 ) which is outside of a bearing ( 29 , 30 ; 33 , 34 ; 59 , 60 ) of the rotor ( 3 ). 2. Dynamoelectric flywheel storage according to claim 1, characterized in that the main bearing of the rotor ( 3 ) consists of two spaced-apart ball bearings ( 29 , 30 ) and that if necessary an additional storage comes after a corresponding wear of the main bearing, the two voneinan the spaced needle bearing ( 33 , 34 ) and that further emergency bearing in the event of a break egg ner rotor shaft ( 32 ) at the predetermined breaking point ( 57 ) is seen before, which consists of two correspondingly arranged plain bearings ( 59 , 60 ). 3. Flywheel accumulator according to claims 1 or 2, characterized in that the lubrication of the bearings ( 29 , 30 ; 33 , 34 ) via appropriately arranged and lubricated sintered rings ( 38 , 39 ) he follows. 4. Flywheel accumulator according to one or more of the preceding claims, characterized in that a sensor ( 72 ) for displaying damage, in particular a break in the rotor shaft ( 32 ) and possibly for braking the rotor, below the predetermined breaking point ( 57 ) is provided. 5. Flywheel accumulator according to one or more of the preceding claims, characterized in that the braking of the rotor ( 3 ) in the event of a break in the rotor shaft ( 32 ) by the supply of a coolant ( 55 ) from a cooling circuit into an interior ( 70 ) of the inner housing ( 4 ). 6. Flywheel accumulator according to one or more of the preceding claims, characterized in that a pressure relief valve ( 71 ) is provided at least in the inner housing ( 4 ). 7. Flywheel storage according to one or more of the preceding claims, characterized in that the cooling circuit consists of a coaxially arranged tube ( 44 ) which projects into a blind bore or recess ( 43 ) formed in the rotor shaft ( 32 ) that between the The outer wall ( 46 ) of the tube ( 44 ) and the inner surface of the cutout ( 43 ) have an annular gap ( 47 ) as a riser in which the cooling liquid ( 55 ) rises up to a radially formed channel ( 49 ) that axially parallel, a channel ( 50 ) leads into an annular gap ( 51 ) into which the ends of the magnetic sheets ( 28 ) protrude and that a line ( 56 ) runs outwards. 8. Flywheel storage according to one or more of the preceding claims, characterized in that on the lower end face ( 20 ) of an annular hub ( 14 ) an annular permanent magnet ( 21 ) be fastened that compared to this permanent magnet ( 21 ) an equal-sized permanent magnet ( 22 ) on the inner housing ( 4 ) is fastened in such a way that the repulsive effect of the permanent magnets ( 21 , 22 ) results in a floating support bearing of the rotor ( 3 ). 9. Flywheel memory according to one or more of the preceding claims, characterized in that the flywheel ( 12 ) made of a fiber-reinforced plastic, in particular in a composite construction, is Herge. 10. Flywheel accumulator according to one or more of the preceding claims, characterized in that on the inner surface ( 75 ) of the inner housing ( 4 ) a protective ring ( 74 ) relative to the outer surface ( 73 ) of the rotor ( 3 ) is arranged. 11. Flywheel accumulator according to one or more of the preceding claims, characterized in that the inner housing ( 4 ) is surrounded by an outer housing ( 5 ) and that between the two housings ( 4 , 5 ) spring and / or damping elements ( 7th to 11 ) are arranged. 12. Flywheel accumulator according to one or more of the preceding claims, characterized in that the outer housing ( 5 ) is part of the vehicle structure. 13. Flywheel accumulator according to one or more of the preceding claims, characterized in that the housing ( 5 ) consists of a lower part ( 77 ) and an upper part ( 78 ), a part ( 77 ) essentially for receiving the in the forces generated by the flywheel memory ( 1 ) and the other part ( 78 ) covers the opposite part ( 77 ). 14. Flywheel accumulator according to one or more of the preceding claims, characterized in that the spring and / or damper elements ( 7 to 12 ) are arranged and designed such that the required properties can be set specifically for all operating conditions and directions of force.