ES1295344U - Assembly for wireless power transfer on drive shafts (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Assembly configured to provide wireless power transfer between the chassis (2) of the motor vehicle and the propulsion shafts (1) that can rotate with respect to a rotation axis (R) to power a circuit (D), characterized in that it comprises the following: a wrap coil support (20) provided in annular cross-section to be held on the surface of the drive shaft (1) and carrying the secondary coil windings (S2) in its body; a plate coil support (10) comprising primary coil windings (S1) arranged to provide wireless power transmission between a chassis connection (30) for connection to the vehicle chassis (2) and the windings (S2) of secondary coils in the wrapper coil support (20); a power supply for powering the primary coil windings (S1) on said plate coil support (10). The assembly according to claim 1, characterized in that the face of the plate coil support (10) facing towards the wrapper coil support (20) is provided flat. 3. Assembly according to claim 1, characterized in that the face of the plate coil support (10) facing towards the wrapper coil support (20) is provided in a concave inclined manner. 4. Assembly according to any one of the preceding claims, characterized in that it comprises a primary router (11) provided on the surface of the plate coil support (10) that is oriented towards the wrapper coil support (20) and arranged so that it can be wound around the primary coil winding (S1) to provide guidance for the magnetic field formed in the primary coil winding (S1). 5. Assembly according to claim 4, characterized in that said primary router (11) is provided in the form of a circular or elliptical channel. 6. Assembly according to claim 4, characterized in that said primary router (11) is provided in the form of a circular or elliptical elevation. 7. Assembly according to any one of the preceding claims, characterized in that it comprises at least one secondary router (21) provided on the surface of the wrapping coil support (20) and arranged so that it can be wound on the winding (S2) secondary coil winding to provide guidance for the magnetic field formed in the secondary coil winding (S2). 8. Assembly according to claim 7, characterized in that said secondary router (21) is provided in the form of a circular or elliptical channel. 9. Assembly according to claim 7, characterized in that said secondary router (21) is provided in the form of a circular or elliptical elevation. 10. Assembly according to any one of the preceding claims, characterized in that it comprises a cover (22) arranged to protect the surface of the wrapping reel support (20) from external influences. 11. Assembly according to claim 1, characterized in that it comprises at least one primary connection arm (12) for connecting the plate coil support (10) to the chassis connection (30) and at least one arm (31) secondary connecting arm, provided in connection with the shaft connection (30) and connected to said primary connecting arm (12) by means of an adjustment screw (AV). 12. Assembly according to claim 11, characterized in that it comprises at least one adjustment slot (AY) provided on the surfaces of the primary and secondary connection arms (12, 31) in such a way as to allow the total height to change allowing a relative movement of the connecting arms with respect to each other. 13. Assembly according to claims 1 and 12, characterized in that it comprises at least one adjustment slot (AY) on the lateral surface of the plate coil support (10) to allow the plate coil support (10) to be move in the vertical direction, and an adjustment screw (AV) to connect the adjustment slot (AY) to one of the connecting arms. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Assembly for wireless power transfer on drive shafts

technical field

The invention relates to a system for providing wireless power transmission between rotating shafts, in particular drive shafts, and a fixed point, in particular the motor vehicle chassis.

prior art

Propshafts are the transmission elements used to power the vehicle by taking the rotational motion and power produced in the engine in motor vehicles from the engine or gearbox and transmitting it to the vehicle's differential.

It is not possible to provide various measurements on the shaft given the positioning of the drive shafts on the vehicle and therefore drive shaft designs are made based on the predictions or simulations provided based on the conditions and environment in which they are used. will use the vehicle. However, such methods are still not sufficient to fully reflect field conditions. Also, it is not possible to provide such measurements while the vehicle is in use. One of the main reasons for this is the difficulty in connecting sensors or measuring devices to the tree and powering these devices.

A wireless power transmission assembly is described in application TR2017/08500. Coil windings positioned on coil supports, one disposed on the drive shaft and the other on the hanger supporting the drive shaft, provide power transfer to each other. A sensor or measuring device positioned on the drive shaft may be powered by the power transmitted to the coil on the drive shaft. The designs are limited to this area since the transmission can only be provided in the area of the hanger.

Another assembly related to wireless power transmission for rotary shafts is described in document with publication number KR101365521B1. A coil connected to a fixed support provides power transfer with another coil provided on the rotating element. The connection of said coil to the rotating element is provided by means of the arms. These arms cause damage to the rotating element during connection. In parallel, the assembly leads to an increase in the area explored by the structure.

As a result, all the problems mentioned above have made it necessary to make an innovation in the relevant field.

Purpose of the invention

The present invention seeks to eliminate the aforementioned problems and to make a technical innovation in the relevant field.

The main objective of the invention is to provide an alternative structure to systems arranged to provide wireless power transmission between drive shafts and the motor vehicle chassis.

In particular, another object of the invention is to increase the efficiency in the power transmission provided between the propeller shafts and the motor vehicle chassis.

Another object of the invention is to provide a positioning of the coil without any damage to the drive shaft.

Brief description of the invention

The present invention is an assembly configured to provide wireless power transfer between the motor vehicle chassis and propeller shafts that can rotate about an axis of rotation to power a circuit in order to achieve all of the stated objectives. mentioned above and which will emerge from the following detailed description. Accordingly, the present invention comprises a casing coil support provided in annular cross-section to be held on the surface of the drive shaft and carrying secondary coil windings in its body; a plate coil support comprising primary coil windings arranged to provide wireless power transmission between a chassis connection for connection to the vehicle chassis and the secondary coil windings on the wrap coil support; a power supply for powering the primary coil windings on said plate coil support.

In this way, it has become possible to mount the coil without damaging the drive shaft and to make designs that will allow measurement from every point on the shaft.

The face of the plate coil support facing towards the wrapper coil support is provided flat in a preferred embodiment of the invention.

The face of the plate coil holder facing towards the wrapper coil holder is provided in a concave inclined manner in another preferred embodiment of the invention.

A preferred embodiment of the invention comprises a primary router provided on the surface of the plate coil support facing towards the casing coil support and arranged so that it can be wrapped around the primary coil winding to provide magnetic field guidance. formed in the primary coil winding. In this way, the efficiency in power transfer is increased.

Said primary router is provided as a circular or elliptical channel in another preferred embodiment of the invention.

Said primary router is provided in the form of a circular or elliptical elevation in another preferred embodiment of the invention.

A preferred embodiment of the invention comprises a secondary router provided on the surface of the wrap coil support facing towards the plate coil support and arranged so that it can be wrapped around the primary coil winding to provide magnetic field guidance. formed in the primary coil winding. In this way, the efficiency in power transfer is increased.

Said secondary router is provided as a circular or elliptical channel in another preferred embodiment of the invention.

Said secondary router is provided in the form of a circular or elliptical elevation in another preferred embodiment of the invention.

A preferred embodiment of the invention comprises a cover arranged to protect the surface of the wrapper coil support from external influences.

A preferred embodiment of the invention comprises at least one primary connecting arm for connecting the plate coil support to the chassis connection and at least one secondary connecting arm provided in connection with the chassis connection and connected to said connecting arm. by means of an adjusting screw.

Another preferred embodiment of the invention comprises at least one adjustment slot provided in the surfaces of the primary and secondary link arms in such a way as to allow the overall height to change by allowing relative movement of the link arms relative to each other.

A preferred embodiment of the invention comprises at least one adjustment slot on the side surface of the plate coil support to allow the plate coil support to move in the vertical direction and an adjustment screw for connecting the adjustment slot and one of the connecting arms.

Brief description of the figures

Figure 1 shows the isometric view of the wireless transmission system of the invention.

Figure 1.A shows the side view section of the embodiment in Figure 1.

Figure 1.B shows the isometric view of an embodiment of the wireless transmission system of the invention. The cover is not shown in this illustration.

Figure 2 shows the isometric view of another embodiment of the wireless transmission system of the invention.

Figure 2.A shows the side view section of the embodiment in Figure 2.

Figure 3 shows the isometric view of an embodiment of the wireless transmission system of the invention. The cover is not shown in this illustration.

Figure 3.A shows the isometric view of one embodiment of the primary and secondary coil supports.

The drawings are not necessarily drawn to scale and details not necessary for an understanding of the present invention may be omitted. Furthermore, elements that are substantially identical or have substantially identical functions are indicated by the same number.

Description of the reference numbers in the figures

1. Drive shaft

2. Chassis

10. Plate coil holder

11. Primary router

12. Primary Link Arm

20. Wrapping coil support

21. Secondary router

22. Cover

30. Chassis connection

31. Secondary Link Arm

32. Body connection

321. Perpendicular part

322. Horizontal part

323. Vertical part

324. Chassis connecting element

33. Fastening element

51. Primary coil windings

52. Secondary coil windings

R. Axis of rotation

AV. Set screw

OH. adjustment slot

D.Circuit

Detailed description of the invention

An assembly for wireless power transfer in the propulsion shafts (1) object of the invention, is explained with examples that do not have any limiting effect, for a better understanding of the object in this detailed description.

The invention relates to an assembly configured to provide wireless power transfer between the motor vehicle chassis (2) and the propulsion shafts (1) that can rotate with respect to a rotation axis (R) to power a circuit ( D), and includes the following:

a wrap coil support (20) provided in annular cross-section to be held on the surface of the drive shaft (1) and carrying the secondary coil windings (S2) in its body;

a plate coil support (10) comprising primary coil windings (S1) arranged to provide wireless power transmission between a chassis connection (30) for connection to the vehicle chassis (2) and the windings (S2) of secondary coils in the wrapper coil support (20);

a power supply for powering the primary coil windings (S1) on said plate coil support (10).

With reference to Figure 1, the drive shaft (1) is a longitudinally disposed structure at the bottom of motor vehicles and can rotate about a rotation axis (R) passing through its center.

There are various parts of the vehicle chassis (2) around the drive shaft (1). The chassis (2) shown in the figures may be provided in ways other than the extensions shown depending on the type and model of the vehicle.

A chassis connection (30) is connected to a suitable point on the chassis (2) and a plate coil support (10) is connected to the chassis connection (30). Said chassis connection (30) can be a structure that allows various and complex technical benefits as shown in the figures, or can simply be screw-like connection elements that connect the plate coil support (10) to the chassis ( two). The term "plate" used herein for the plate coil support 10 should not be taken to refer only to the flat plates. "Plate" structures in different geometries may also be used for the assembly of the invention, as will be explained below.

A wrapping reel support (20) is placed on the shaft (1). Said casing coil support (20) is preferably in the form of a cylindrical casing and can be connected directly to the shaft (1) without the need for a connecting element.

Said wrapper coil support (20) may be provided as a monolithic structure and may extend beyond the shaft (1). Furthermore, the wrapper coil support 20 can also be provided in the form of a structure consisting of at least two parts, and can be mounted on the shaft 1 by connecting these parts to each other on the shaft 1 correspondingly.

The plate and shell coil supports (10, 20) comprise primary and secondary coil windings (S1, S2), respectively, and said coil windings provide wireless power transfer by entering into an inductive relationship with each other. Furthermore, the assembly includes a power supply (not shown in the figures) to power the primary coil winding (S1).

Furthermore, a circuit (D) provided in the wrapper coil support (20) is arranged to be powered from said secondary coil windings (S2) in the assembly. The definition of circuit (D) in this document can mean any electronic device, or has been used in particular to refer to devices called sensors and measuring elements.

Referring to Fig. 1.A, secondary coil windings (S2) are provided on the wrapper coil support (20). A cover (22) is disposed over the secondary coil windings (S2). Preferably, the cover (22) is also in the form of an envelope. The main function of the cover (22) is to protect the wrapper coil support (20), in particular the secondary coil windings (S2) and the circuit (D). Said protection is very important for the useful life of the assembly due to the fact that the tree (1) is provided under the vehicle.

The plate coil support (10) is arranged as a flat plate, one side thereof facing towards the shaft (1). Primary coil windings (S1) are disposed on the plate coil support (10).

A primary router (11) is disposed on the surface of the plate coil support (10), as can be seen in Figure 1.B. Said primary router (11) is provided in a circular manner.

The primary router (11) is arranged in the form of a circular channel and the primary coil windings (51) are wound to this channel. Similarly, the primary router (11) may be provided in the form of a circular projection or elevation, and therefore the primary coil windings (S1) are wound on this circular projection or elevation.

Said primary router (11) can also be provided in elliptical geometry in addition to circular geometry.

Secondary routers 21 inclined in harmony with the surface are arranged on the surface of the wrapper coil support 20, referring to Figures 1.B, 3 and 3.A. Said secondary router (21) is provided in a circular manner.

The secondary router (21) is arranged in the shape of a circular channel and the secondary coil windings (52) are wound to this channel. Similarly, the secondary router (21) may be provided in the form of a circular projection or elevation, and accordingly the secondary coil windings (S2) are wound on this circular projection or elevation.

Said secondary router (21) can also be provided in elliptical geometry in addition to circular geometry.

The primary and secondary routers (11, 21) provided on the wrap coil plate and support (10, 20) improve the performance of wireless power transmission by regulating the direction of the magnetic field lines of the windings (S1, S2) of primary and secondary coil based on their geometry and therefore provide various advantages in terms of both power consumption and increase of the distance between the primary and secondary coil windings (S1, S2).

In figure 2 another advantageous embodiment is shown. The plate coil support (10) regulates the magnetic field direction of the primary coil windings (S1) which are provided in a concave structure, especially in an inclined concave structure. A similar wireless power transmission performance improvement is observed in this case.

Furthermore, as in Figure 3, an embodiment using the primary and secondary routers (11, 12) together with the plate coil support (10) in the inclined concave structure provides much better performance than its alternatives in terms of wireless power transmission.

The plate coil support (10) comprises a primary link arm (12), referring to figures 1.A and 2.A. Furthermore, the chassis link (30) comprises a secondary link arm (31). Said primary and secondary connecting arms (12, 31) extend towards each other and are positioned side by side, one inside the other or one on top of the other.

There is at least one adjustment slot (AY) in the primary and secondary link arms (12, 31). Preferably, multiple in-line adjustment slots (AY) are provided in both connecting arms. Furthermore, it is possible to use an adjustment groove (AY) provided in the form of a longitudinal groove.

The position of the plate coil holder (10) is adjusted according to the shaft (1) by moving the primary and secondary connecting arms (12, 31) relative to each other, and the adjusting screw (AY) is set and tightened. into the appropriate hole and the position of the plate coil holder (10) is fixed after the appropriate position is provided. Accordingly, the plate coil holder 10 can move in the direction of the horizontal arrow in Fig. 1.A. The distance adjustable plate coil holder 10 is extremely advantageous especially in trial use.

Similarly, adjustment grooves (AY) arranged in the vertical direction may be arranged on the side surface of the plate coil holder (10) as shown in Fig. 1.A. The adjustment slot (AY) is connected through said adjustment screws (AV) to one of the connecting arms, preferably to the primary connecting arm (12). The plate coil holder (10) is moved in the direction of the arrow in Fig. 1.A and its position is adjusted.

The chassis connection (30) is configured in a connection body (32) in a preferred embodiment of the invention. Preferably, a fastening element (33) is positioned between the body (32) and the chassis (2). The connection body (32) is located in the front part of the chassis (2). A horizontal part (322) is provided at the end of a perpendicular part (321) extending from the connecting body (32), and a vertical part (323) is provided at the end of the horizontal part (322). The vertical part (323) remains at the rear of the chassis (2). A chassis connection element (324) connects the chassis connection (30) to the chassis (2) passing through the vertical part (321), the chassis (2) and the connection body (32).

The scope of protection of the invention is specified in the appended claims and cannot be limited to what is explained for the purpose of illustration in this detailed description. It is evident that a person skilled in the art can provide similar embodiments in view of the facts mentioned above without departing from the main subject of the invention.

Claims (13)

1. Assembly configured to provide wireless power transfer between the chassis (2) of the motor vehicle and the propulsion shafts (1) that can rotate with respect to a rotation axis (R) to power a circuit (D), characterized because it includes the following: a wrap coil support (20) provided in annular cross-section to be held on the surface of the drive shaft (1) and carrying the secondary coil windings (S2) in its body; a plate coil support (10) comprising primary coil windings (S1) arranged to provide wireless power transmission between a chassis connection (30) for connection to the vehicle chassis (2) and the windings (S2) of secondary coils in the wrapper coil support (20); a power supply for powering the primary coil windings (S1) on said plate coil support (10). An assembly according to claim 1, characterized in that the face of the plate coil support (10) facing towards the wrapper coil support (20) is provided flat. Assembly according to claim 1, characterized in that the face of the plate coil support (10) facing towards the wrapper coil support (20) is provided in a concave inclined manner. Assembly according to any one of the preceding claims, characterized in that it comprises a primary router (11) provided on the surface of the plate coil support (10) facing towards the wrapper coil support (20) and arranged so which can be wound around the primary coil winding (S1) to provide guidance for the magnetic field formed in the primary coil winding (S1). Assembly according to claim 4, characterized in that said primary router (11) is provided in the form of a circular or elliptical channel. Assembly according to claim 4, characterized in that said primary router (11) is provided in the form of a circular or elliptical elevation. Assembly according to any one of the preceding claims, characterized in that it comprises at least one secondary router (21) provided on the surface of the wrapping coil support (20) and arranged so that it can be wound on the coil winding (S2). secondary to provide guidance for the magnetic field formed in the secondary coil winding (S2). Assembly according to claim 7, characterized in that said secondary router (21) is provided in the form of a circular or elliptical channel. Assembly according to claim 7, characterized in that said secondary router (21) is provided in the form of a circular or elliptical elevation. 10. Assembly according to any one of the preceding claims, characterized in that it comprises a cover (22) arranged to protect the surface of the wrapper coil support (20) from external influences. Assembly according to claim 1, characterized in that it comprises at least one primary connection arm (12) for connecting the plate coil support (10) to the chassis connection (30) and at least one connection arm (31) secondary, provided in connection with the shaft connection (30) and connected to said primary connection arm (12) by means of an adjustment screw (AV). 12. Assembly according to claim 11, characterized in that it comprises at least one adjustment slot (AY) provided on the surfaces of the primary and secondary connection arms (12, 31) in such a way as to allow the total height to change allowing movement relative of the connecting arms to each other. 13. Assembly according to claims 1 and 12, characterized in that it comprises at least one adjustment groove (AY) on the lateral surface of the plate coil support (10) to allow the plate coil support (10) to move in vertical direction, and an adjustment screw (AV) to connect the adjustment slot (AY) to one of the connecting arms.