DE20204507U1 - Coil carrier as an insulating material for an electrical coil - Google Patents

Description

Applicant: Grundfos &agr;/s

Poul Due Jensens Vej 7 - 11
DK-8850 Bjerringbro

Coil carrier made of insulating material for an electrical coil

Description

The invention is based on a coil carrier made of insulating material for an electrical coil according to the preamble of claim 1.

Stators are known for electric motors that are designed in the form of a stator ring consisting of a laminated core with a large number of pole legs attached to its inner circumference, each equipped with an electrical coil arrangement. Each electrical coil arrangement consists of a coil carrier made of insulating material with an electrical coil wound on it. The coil carrier itself consists of a hollow central body with a square cross-section and an end flange at each of its two ends, with the end flange that faces the stator ring when the coil carrier is mounted on the associated pole leg being wider than the other end flange at the other end of the central body. This is due to the fact that the wider end flange lies on a larger circumference of the stator ring. Examples of the prior art described above can be found in DE-IO 90 746 (explanatory document), DE-A-199 61 339 and EP-A-0 629 034 (publication documents). The electrical coil wound on the respective coil carrier has a trapezoidal circumference both in plan and side view. A trapezoidal outer contour of the coil - viewed from above - is advantageous for wound coil carriers arranged along a circular line because

Patent attorneys Wilcken &Vollnrjggn;...,

!8.03.2002

the existing space between the pole legs of the stator ring can be completely filled with the windings of the coils. However, the external trapezoidal shape in the upper and lower areas of the wound coil, i.e. when the coil is viewed from the side, is disadvantageous. Then the upper and lower outer winding layers of each coil are not securely positioned in their position because the axial length of the outer winding layers is shortened. These winding layers therefore only lie on one end flange of the coil carrier, namely the wider end flange, the upper end of which projects beyond that of the narrower end flange. The free ends of the outer winding layers tend to slip towards the smaller end flange, particularly during the final phase of the coil winding process, which means that the wound coil carrier must be handled particularly carefully during production until it is finally finished and installed in the stator, in order to prevent the outer winding layers of the coil from becoming loose and removed from their winding position. The latter can also occur during operation of the coil because the stator equipped with it is exposed to engine vibrations.

The object of the invention is to improve a coil carrier of the type mentioned in the introduction in such a way that slipping of the outer winding layers of the electrical coil wound on the coil carrier is avoided.

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The solution to this problem is specified in claim 1.

The design of the coil carrier according to the invention has the advantage that the winding of an electronic coil on it can be carried out with greater positional security with regard to the outer winding layers of the coil. The free end of the outer winding layers, i.e. those winding layers that are not attached to the narrower end flange of the

Patent Attorneys Wilcten & Vollriiarihi

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· .I. 19.03.2002

coil carrier no longer has the tendency to detach itself from its respective winding layer. The free end of the corresponding outer winding layers has, due to the convergent coil side of the corresponding upper and lower wall of the central body of the coil carrier, the forced tendency to now want to move in the direction of the wider end flange of the coil carrier, which is not possible, however, because the free end in question, i.e. the winding in question, itself rests against a winding and this in turn rests against a winding in front of it of the same winding layer and so on, until the other end of the winding layer in question rests against the wider end flange of the coil carrier. This secure positioning of the free end of the respective outer winding layers of the electrical coil improves in particular the automatic winding of the electrical coils in question here, i.e. makes it safer, and in particular the winding time is significantly shortened. A further advantage of the design of the coil carrier according to the invention is that the free end of the lateral outer winding layers can no longer slip in the direction of the narrower end flange, since there is no longer sufficient force acting in this direction. The finished coil can therefore be handled more easily in the further production process to equip a pole leg with a wound coil carrier and to mount such a pole leg on a stator ring without damaging the electrical coil on the coil carrier. Furthermore, the coil on the coil carrier can now better withstand the vibrations of a running electric motor.

The invention is explained in more detail below using an embodiment shown in the accompanying drawings.

Patent Attorneys Wilcken &

18.03.2002

Fig.

a top view of a stator for an electric motor,

Fig. 2

a perspective view of an example coil carrier,

Fig.3

a side view of the coil carrier according to Fig. 2 according to arrow A,

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Fig.4

Fig.5

an end view of the coil carrier according to Fig. 2,
a horizontal section along the line VV in Fig. 4,

Fig.6

a vertical section along the line Vl-Vl in Fig. 4,

15 Fig. 7

a vertical section similar to that in Fig. 6,

Fig.8

a perspective view of a modified embodiment of the coil carrier.

Fig. 1 shows a stator 1 for an electric motor, the stator having a stator ring 2 with a plurality of pole legs 3, which are mounted on the inside of the stator ring in the usual way. The pole legs 3 are each equipped with an electrical coil arrangement, each consisting of a coil carrier 4 made of insulating material and an electrical coil 5 wound on it. In Fig. 1, only some of the coil carriers 4 are shown with coils 5 indicated by dashed lines. It can be seen from this figure that the coil arrangements taper towards the center of the stator Γ, which is usually also intended.

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Fig. 2 shows the coil carrier, generally designated 4, in perspective. This coil carrier consists of a

Patent Attorneys WÜcken &. VollnSanri

19.03.2002

hollow central body 6 with a square cross-section and a first flange 7 at one end and a second, wider end flange 8 at the other end of the central body. The hollow central body 6 is open at both of its flange ends so that the wound coil carrier can be pushed onto a pole leg 3. The hollow central body 6 in turn consists of two lateral walls 9 and 10 which are parallel to one another and an upper end wall 11 and a lower end wall 12. The wider end flange 8, the greater width of which can be clearly seen in Fig. 4 compared to that of the narrower flange 7, has two electrical terminal units 8a at its upper end, as will become clear.

As can be clearly seen from Fig. 3, for example, the upper wall 11 and the lower wall 12 of the hollow central body 6 each have an inclined coil side 11a and 12a respectively. These inclined coil sides 11a and 12a converge towards one another in the direction of the wider end flange 8 of the coil carrier 4. Preferably, these two coil sides converge symmetrically to one another. Preferably, a convergence angle α in the range from 15° to 65° is selected.

The significance of the inclined coil sides 11a and 12a is clear from Figures 6 and 7. In these figures, as well as in Fig. 5, it is shown that the coil body 4 is wound with an electrical coil 5. In Figures 6 and 7, two straight lines 14 and 15 can be seen, one line being thought to be applied to the upper and the lower area of the coil, respectively, with these lines each running parallel to the center line 1o of the coil carrier 4. The parallel course of these lines 14 and 15 to the center line 16 results from a preferred convergence angle α of approximately 20° for the inclined coil sides 11a and 12a of the relevant walls 11 and 12 of the center body 6 of the coil carrier 4. It can be seen very clearly from Figures 6 and 7 that due to the inclined coil sides of the walls 11, 12, the

Patent attorneys Wilcken & ^v oiliyiqnr>_###

19.03.2002

individual winding layers of the coil 5 also run at an incline here and that the outer winding layers, which are shorter than the underlying winding layers due to the winding scheme according to Fig. 5, have a tendency to move in the direction of the wider end flange 8. This retention effect for the outer winding layers of the coil 5 caused by the inclination of the coil side 11a, 12a of the upper and lower walls 11,12 of the coil carrier 4
also has a positive effect on the side sections of the respective outer winding layers on the side walls 9 and 10 of the central body 6 according to Fig. 5. As a result, the outer winding layers in these side areas of the electrical coil 5 will not slip towards the narrower end flange 7. The secure position of the shorter outer winding layers of the coil 5 is thus also ensured in these coil areas.

As can best be seen from Fig. 2, the wider end flange 8 of the coil carrier 4 can have two clamping units 8a at one end, which are arranged next to one another at the same height and are relatively close to one another. Each unit 8a has the form of a housing that is open at the top, the housings being equipped with conventional electrical contact elements (not shown) for contacting one end section 5a of the electrical coil 5. On their mutually facing side walls 8b, the housings each have an insertion slot 8c that is open towards the open housing end and into which the relevant end section 5a of the winding wire of the electrical coil 5 is clamped. On their mutually facing side walls, the two housings can also be provided with a further insertion slot for the same purpose, so that each housing has a pair of insertion slots (Fig. 2) that are arranged parallel to the wider end flange 8. Due to the arrangement of the insertion slots 8c in the side walls 8b of the clamping units 8 which are perpendicular to the end flange 8

Patent Attorneys Wilcken

19.03.2002

This results in a very good stationary end positioning of the end sections 5a of the electrical coil 5 and a simpler electrical connection (wiring) of the respective flushed coil carrier 4 on the stator ring 2.

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In order to ensure that the coil carrier 4 described above can also be securely positioned on the pole leg 3 of the stator 1 with respect to its convergent coil sides, the upper and lower walls of the coil carrier, if these walls have the same or essentially the same thickness, are provided with molded-on spacers on their side facing away from the respective convergent coil side. These spacers can consist, for example, of at least one rib or other projections.

In Figures 4, 5 and 6, ribs are provided, each wall 11 or 12 being provided with, for example, two longitudinal ribs 17, each extending from one end flange 7 to the other end flange 8 of the central body 6. However, it is also sufficient for the or each rib to extend only partially between the two end flanges.

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Fig. 7 shows an alternative of a rib as a spacer. In this case, the upper wall 11 of the hollow central body 6 is provided with a downwardly directed transverse rib 18 and the lower wall 12 of the central body is provided with an upwardly directed transverse rib 18, in the region of the narrower end flange 7, such that the transverse ribs 18 are flush with this end flange.

Another alternative for an internal spacer is shown in Fig. 8. In this case, wedge-shaped spacer projections 19 are provided which project inwards towards the cavity of the central body 6 and extend within the cavity of the central body 6 from the narrower end flange 7 to the wider end flange 8 and in their

Patent attorneys Wilcken & Vollmbnri

19.03.2002

·

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are wedge-shaped in the direction of extension. Furthermore, the projections 19 are formed integrally with the upper wall 11 and the lower wall 12.

It can be seen in particular from Fig. 7 that the coil carrier 4 provided with the coil 5 can be arranged on a pole leg 3 in a secure position with respect to its inclined sides 11a, 12a or inclined walls 11 and 12 due to the described spacers 18, or 17 and 19. This can also be achieved with loose spacers (not shown) which are inserted into the corresponding cavities between the inclined walls 11, 12 and the respective pole leg 3 located in the hollow central body 6 .

According to Fig. 8, the coil carrier 4 can also consist of two individual components 20 and 21. In this embodiment, the coil carrier is divided transversely, i.e. divided horizontally, so that it consists of an upper component 20 and a lower component 21. The upper component 20 thus has the upper wall 11 with its inclined coil side 11a, while the lower component 21 has the lower end wall 12 with its inclined coil side 12a. Otherwise, the two components are constructed as described above. Alternatively, it is also possible to design or provide the coil carrier 4 to be divided vertically, i.e. the division plane then runs between the two mutually parallel side walls 9 and 10 and through the two inclined coil sides 11a and 12a.

Patent attorneys wilcken & Vollmond

19.03.2002

Claims (11)

1. Coil carrier made of insulating material for an electrical coil for the pole leg of the stator of an electric motor, wherein the coil carrier has a hollow central body which carries the coil and is open at both ends and a first end flange at one end thereof and a second, wider end flange at the other end thereof, and the central body consists of two lateral walls which are parallel to one another and of an upper and a lower wall, characterized in that the coil side ( 11a ) of the upper wall ( 11 ) and the coil side ( 12a ) of the lower wall ( 12 ) of the hollow central body ( 6 ) converge towards one another in the direction of the wider end flange ( 8 ) of the central body. 2. Coil carrier according to claim 1, characterized in that the coil side ( 11 a) of the upper wall and the coil side ( 12 a) of the lower wall of the central body ( 6 ) converge symmetrically to one another. 3. Coil carrier according to claim 1 or 2, characterized in that the convergence angle (a) enclosed between the two convergent coil sides ( 11 a, 12 a) of the walls ( 11 , 12 ) of the hollow central body ( 6 ) is selected such that a straight line ( 14 , 15 ) extending in the longitudinal direction of each of these coil sides and intended to be applied to the free end of the outer winding layers of the winding sections of the electrical coil ( 5 ) on these coil sides runs parallel to the center line ( 16 ) of the hollow central body ( 6 ). 4. Coil carrier according to claim 3, characterized in that the convergence angle has a value between 15° and 35°. 5. Coil carrier according to one of claims 1 to 4, characterized in that the upper and lower walls ( 11 , 12 ) of the hollow central body ( 6 ) are each provided on their side facing away from the convergent coil side ( 11a , 12a ) with molded-on spacer means ( 17 , 18 , 19 ) for a secure positioning of the coil carrier ( 4 ) on the stator's pallet arm with respect to the convergent coil sides. 6. Coil carrier according to claim 5, characterized in that the upper and lower walls ( 11 , 12 ) of the hollow central body ( 6 ) each have an equal or substantially equal wall thickness and that the spacer means consist of at least one molded rib ( 17 , 18 ) on each of these two walls. 7. Coil carrier according to claim 6, characterized in that each rib ( 17 ) on each of the two walls ( 11 , 12 ) extends as a longitudinal rib between the two end flanges ( 7 , 8 ) of the hollow central body ( 6 ). 8. Coil carrier according to claim 6, characterized in that a rib ( 18 ) is provided as a transverse rib at that end of the two walls ( 11 , 12 ) which is located on the first, narrower end flange ( 7 ) of the hollow central body ( 6 ), and that the two transverse ribs are aligned with this end flange. 9. Coil carrier according to one of claims 1 to 8, characterized in that it consists of two individual components ( 20 , 21 ). 10. Coil carrier according to claim 9, characterized in that the one component ( 20 ) has the upper wall ( 11 ) with its convergent coil side ( 11a ) and the other component ( 21 ) has the lower wall ( 12 ) with its convergent coil side ( 12a ). 11. Coil carrier according to one of claims 1 to 10, characterized in that the wider end flange ( 8 ) of the coil carrier ( 4 ) is provided at one end with two clamping units ( 8a ) arranged next to one another and spaced apart from one another, each of which has a housing open at the top with electrical contact elements therein for electrically contacting one end section ( 5a ) of the winding wire of the electrical coil ( 5 ), and that the two housings are each provided at least on their side walls ( 8b ) facing one another with an insertion slot ( 8c ) open towards the open housing end for the relevant end section ( 5a ) of the winding wire of the electrical coil 5 .