Coupling structure for a personal care device

Abstract

A personal care device like a shaving device (1) comprises a base structure (2) and a head structure (3). The head structure comprises a first coupling element (5) and at least a head support structure (4) configured to hold at least one treatment head (4). The base structure comprises a second coupling element (6). The coupling elements can releasably be coupled to each other for coupling the head structure to the base structure. By rotating the coupled coupling elements with respect to each other in a first rotational direction about a central axis (9), a first inclined surface (15) of at least one of the first and second coupling elements cooperates with a first co-operating surface (26) of the other of the first and second coupling elements thereby driving the first and second coupling elements away from each other in an axial direction extending parallel to the central axis.

Claims

1. A personal care device comprising: a head structure comprising a first coupling element and at least a head support structure configured to hold at least one treatment head, a base structure comprising a second coupling element, wherein the first and second coupling elements can be releasably coupled to each other for coupling the head structure to the base structure, the first coupling element of the head structure comprising: (i) a tubular part extending along a central axis, the tubular part being provided with a ring-shaped collar, the ring-shaped collar having a circular part extending over 180 degrees along the central axis, (ii) a first straight part and a second straight part connected to respective ends of the circular part, and (iii) a third straight part extending between the first and second straight parts, the third straight part being perpendicular to the first and second straight parts, wherein the circular part, the first straight part, the second straight part, and the third straight part of the first coupling element are each provided with a respective inclined external surface as seen in a plane extending radially with respect to the central axis, directed towards the second coupling element, and wherein the inclined external surface of the third straight part is comprised of a first inclined external surface and a second inclined external surface, the first inclined external surface being located on a left side of a plane (V) extending radially with respect to the central axis and perpendicularly with respect to the third straight part, and the second inclined external surface being located on a right side of the plane (V) extending radially with respect to the central axis and perpendicularly with respect to the third straight part, the second coupling element of the base structure comprising: (i) a tubular part extending along the central axis, wherein an internal diameter of the tubular part of the second coupling element is slightly larger than the external diameter of the tubular part of the first coupling element, wherein the tubular part is provided with a ring-shaped flange having a circular part extending over 180 degrees along the central axis, (ii) a first straight part, a second straight part and a third straight part, whereby the first and second straight parts are connected to respective ends of the circular part, wherein the circular part, the first straight part, the second straight part and the third straight part of the second coupling element are each provided on its inside with an internal inclined surface as seen in a plane extending radially with respect to the central axis, wherein the inclined surfaces on each of the first and second coupling elements are inclined in opposite directions relative to a tangential direction extending tangentially to the central axis, wherein at least one external inclined surface of the first coupling element of the head structure is configured to cooperate with at least one corresponding cooperating internal inclined surface of the second coupling element of the base structure, wherein the respective inclined surfaces of the second coupling element are directed towards the first coupling element of the head structure, wherein by rotating the first and second coupling elements with respect to each other in a first rotational direction about the central axis, the first external inclined surface of the third straight part of the first coupling element of the head structure cooperates with a first co-operating internal inclined surface of the second coupling element of the base structure thereby driving the first and second coupling elements away from each other in an axial direction extending parallel to the central axis, and wherein by rotating the coupling elements with respect to each other in a second rotational direction about the central axis, opposite to the first rotational direction, the second external inclined surface of the third straight part of the first coupling element of the head structure cooperates with a second co-operating internal inclined surface of the second coupling element of the base structure thereby driving the first and second coupling elements away from each other in said axial direction.

2. A personal care device according to claim 1, wherein the first and second co-operating surfaces of the second coupling element that cooperate with the first and second inclined surfaces of the first coupling element are also inclined.

3. A personal care device according to claim 2, wherein the first and second inclined surfaces and the first and second co-operating surfaces have corresponding inclinations.

4. A personal care device according to claim 1, wherein the first and second inclined surfaces are straight longitudinal surfaces extending tangentially with respect to a longitudinal reference plane extending in a reference radial direction to the central axis.

5. A personal care device according to claim 1, wherein the head structure, when coupled to the base structure, is solely supported by the coupling elements.

6. A personal care device according to claim 1, wherein the first coupling element and the second coupling element are configured to arrive from an uncoupled state into a coupled state relative to each other by driving the first and second coupling elements towards each other in a coupling direction opposite to the axial direction, and to arrive from the coupled state into the uncoupled state by driving the first and second coupling elements away from each other in the axial direction.

7. A personal care device according to claim 6, wherein the first and second inclined surfaces are inclined with respect to said plane extending perpendicularly with respect to the central axis such that the first coupling element and the second coupling element arrive from the coupled state into the uncoupled state by rotating the coupled coupling elements with respect to each other about the central axis in either the first or the second rotational direction over an angle smaller than 90.

8. A personal care device according to claim 6, wherein one of the first and second coupling elements comprises a spring element extending perpendicularly to the central axis for cooperation with a groove extending perpendicularly to the central axis and provided in the other of the first and second coupling elements for releasably retaining the coupling elements when coupled to each other.

9. A personal care device according to claim 1, wherein the first and second inclined surfaces of the first coupling element each include an obtuse angle with a tangential direction extending tangentially to the central axis, wherein the obtuse angle is between 95 and 140 degrees.

10. A personal care device according to claim 9, wherein a size of the obtuse angle partially determines a relation between an amount of torque applied in one of a clockwise or counterclockwise direction to move the coupling elements away from each other and a corresponding displacement in the axial direction.

11. A head structure in a personal care device having a coupling element for use in coupling to a base structure having a corresponding coupling element, the head structure configured to hold at least one treatment head, the coupling element of the head structure comprising: (i) a tubular part extending along a central axis, the tubular part being provided with a ring-shaped collar, the ring-shaped collar having a circular part extending over 180 degrees along the central axis, (ii) a first straight part and a second straight part connected to respective ends of the circular part, and (iii) a third straight part extending between the first and second straight parts, the third straight part being perpendicular to the first and second straight parts, wherein the circular part, the first straight part, the second straight part, and the third straight part of the first coupling element are each provided with an inclined external surface as seen in a plane extending radially with respect to the central axis, directed towards the corresponding coupling element of the base structure, wherein the inclined external surface of the third straight part is comprised of a first inclined external surface and a second inclined external surface, the first inclined external surface being located on a left side of a plane (V) extending radially with respect to the central axis and perpendicularly with respect to the third straight part, and the second inclined external surface being located on a right side of the plane (V) extending radially with respect to the central axis and perpendicularly with respect to the third straight part.

12. A head structure according to claim 11, wherein the first and second inclined surfaces of the first coupling element each include an obtuse angle with a tangential direction extending tangentially to the central axis, wherein the obtuse angle is between 95 and 140 degrees.

13. A head structure according to claim 12, wherein a size of the obtuse angle partially determines a relation between an amount of torque applied in one of a clockwise or counterclockwise direction to move the coupling elements away from each other and a corresponding displacement in the axial direction.

14. A base structure for use in coupling to a head structure having a corresponding coupling element in a personal care device, the base structure comprising a coupling element and a spring element, the coupling element of the base structure comprising: (i) a tubular part extending along the central axis, wherein the tubular part is provided with a ring-shaped flange having a circular part extending over 180 degrees along the central axis, (ii) a first straight part, a second straight part and a third straight part, whereby the first and second straight parts are connected to respective ends of the circular part, wherein the third straight part extends between the first and second straight parts and is perpendicular to the first and second straight parts, wherein the circular part, the first straight part, the second straight part and the third straight part of the base structure are each provided with a respective inclined internal surface as seen in a plane extending radially with respect to the central axis, directed towards the corresponding coupling element of the head structure, wherein the at least one inclined external surface of the coupling element of the base structure is configured to cooperate with at least one corresponding cooperating inclined external surface of the corresponding coupling element of the head structure, wherein the inclined internal surface of the third straight part of the base structure is comprised of a first inclined internal surface and a second inclined internal surface, the first inclined internal surface being located on a left side of the plane extending radially with respect to the central axis and perpendicularly with respect to the third straight part, and the second inclined internal surface being located on a right side of the plane extending radially with respect to the central axis and perpendicularly with respect to the third straight part, wherein the inclined surfaces of the coupling element of the base structure are inclined in an opposite direction to the corresponding coupling element of the head structure relative to a tangential direction extending tangentially to the central axis, wherein by rotating the coupling element of the base structure with respect to the corresponding coupling element of the head structure in a first rotational direction about the central axis, the first inclined internal surface of the third straight part of the coupling element of the base structure cooperates with a corresponding first inclined external co-operating surface of the coupling element of the head structure thereby driving the coupling element of the base structure away from the coupling element of the head structure in an axial direction extending parallel to the central axis, and wherein by rotating the coupling element of the base structure with respect to the corresponding coupling element of the head structure in a second rotational direction about the central axis, opposite to the first rotational direction, the second inclined internal surface of the third straight part of the coupling element of the base structure cooperates with a corresponding second inclined external co-operating surface of the coupling element of the head structure thereby driving the first and second coupling elements away from each other in said axial direction.

15. A base structure according to claim 14, wherein the first and second inclined surfaces of the first coupling element each include an obtuse angle with a tangential direction extending tangentially to the central axis, wherein the obtuse angle is between 95 and 140 degrees.

16. A base structure according to claim 15, wherein a size of the obtuse angle partially determines a relation between an amount of torque applied in one of a clockwise or counterclockwise direction to move the coupling elements away from each other and a corresponding displacement in the axial direction.

17. A coupling structure comprising at least a first coupling element and a second coupling element, wherein the coupling elements can be releasably coupled to each other, the first coupling element of the coupling structure comprising: (iv) a tubular part extending along a central axis, the tubular part being provided with a ring-shaped collar, the ring-shaped collar having a circular part extending over 180 degrees along the central axis, (v) a first straight part and a second straight part connected to respective ends of the circular part, and (vi) a third straight part extending between the first and second straight parts, the third straight part being perpendicular to the first and second straight parts, wherein the circular part, the first straight part, the second straight part, and the third straight part of the first coupling element are each provided with an inclined external surface as seen in a plane extending radially with respect to the central axis, directed towards the second coupling element, wherein the inclined external surface of the third straight part is comprised of a first inclined external surface and a second inclined external surface, the first inclined external surface being located on a left side of a plane (V) extending radially with respect to the central axis and perpendicularly with respect to the third straight part, and the second inclined external surface being located on a right side of the plane (V) extending radially with respect to the central axis and perpendicularly with respect to the third straight part, the second coupling element of the coupling structure comprising: (iii) a tubular part extending along the central axis, wherein an internal diameter of the tubular part of the second coupling element is slightly larger than the external diameter of the tubular part of the first coupling element, wherein the tubular part is provided with a ring-shaped flange having a circular part extending over 180 degrees along the central axis, (iv) a first straight part, a second straight part and a third straight part, whereby the first and second straight parts are connected to respective ends of the circular part, wherein the third straight part of the second coupling element extends between the first and second straight parts and is perpendicular to the first and second straight parts, wherein the circular part, the first straight part, the second straight part and the third straight part of the second coupling element are each provided on its inside with an inclined surface as seen in a plane extending radially with respect to the central axis, wherein the respective corresponding inclined surfaces on each of the first and second coupling elements are inclined in opposite directions relative to a tangential direction extending tangentially to the central axis, wherein the respective inclined surfaces of the second coupling element are directed towards the first coupling element of the coupling structure, wherein the coupling element of the second coupling element comprises a first co-operating surface configured to co-operate with the first inclined surface of the third straight part, wherein the coupling element of the second coupling element comprises a second co-operating surface configured to co-operate with the second inclined surface of the third straight part, wherein at least one inclined external surface of the second coupling element of the coupling structure is configured to cooperate with at least one corresponding cooperating inclined external surface of the corresponding first coupling element of the coupling structure, wherein by rotating the first and second coupling elements with respect to each other in a first rotational direction about the central axis, the first inclined surface of the third straight part of the first coupling element cooperates with a corresponding first co-operating portion of the inclined internal surface of the second coupling element thereby driving the first and second coupling elements away from each other in an axial direction extending parallel to the central axis, and wherein by rotating the first and second coupling elements with respect to each other in a second rotational direction about the central axis, opposite to the first rotational direction, the second inclined external surface of the third straight part of the first coupling element cooperates with a corresponding the second co-operating portion of inclined internal surface of the second coupling element thereby driving the first and second coupling elements away from each other in said axial direction.

18. A coupling structure according to claim 17, wherein the first and second inclined surfaces of the first coupling element each include an obtuse angle with a tangential direction extending tangentially to the central axis, wherein the obtuse angle is between 95 and 140 degrees.

19. A coupling structure according to claim 18, wherein a size of the obtuse angle partially determines a relation between an amount of torque applied in one of a clockwise or counterclockwise direction to move the coupling elements away from each other and a corresponding displacement in the axial direction.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows a perspective view of a shaving device according to the invention,

(2) FIG. 2 shows a perspective view of a part of the shaving device as shown in FIG. 1,

(3) FIG. 3A shows a perspective view of a first embodiment of two cooperating coupling elements according to the invention, in an uncoupled position,

(4) FIG. 3B shows a schematic top view of one of the two cooperating coupling elements as shown in FIG. 3A,

(5) FIGS. 4A-4D show perspective views of two coupling elements as shown in FIG. 3, in several steps during coupling of the two coupling elements,

(6) FIGS. 5A and 5B show a perspective view and a cross section of two coupling elements as shown in FIG. 3, in a coupled position,

(7) FIG. 6 shows a perspective view of a second embodiment of two cooperating coupling elements according to the invention, in an uncoupled position,

(8) FIGS. 7A-7B show perspective views of two coupling elements as shown in FIG. 6, in two steps during coupling of the two coupling elements,

(9) FIG. 8 shows a perspective view of two coupling elements as shown in FIG. 6, in a coupled position.

(10) In the drawings, like reference numerals refer to like elements.

DESCRIPTION OF PREFERRED EMBODIMENTS

(11) FIGS. 1 and 2 show respectively a perspective view of a shaving device 1 and a part thereof as an example of a personal care device according to the invention.

(12) The shaving device 1 comprises a base structure 2 and a head structure 3. The head structure 3 supports and retains three head support structures 4 for rotary shaving heads 4 as an example of a treatment head. The head structure 3 comprises a first coupling element 5, whilst the base structure 2 comprises a second coupling element 6. The first coupling element 5 is partly inserted into the second coupling element 6 and is retained in the second coupling element 6 by means of a spring element 7. Such kind of shaving device 1 is known from EP2086729B1 and will not further be explained.

(13) The shaving device 1 according to the invention differs from the shaving device 1 as described in EP2086729B1, mainly by the design and function of the coupling elements 5, 6.

(14) FIGS. 3A-5B show several views of a first embodiment of two cooperating coupling elements 5, 6 of the shaving device 1 according to the invention.

(15) The first coupling element 5 comprises a tubular part 8 extending along a central axis 9. The tubular part 8 is provided with a ring-shaped collar 10. The ring-shaped collar 10 has a circular part 11 extending over 180 degrees along the central axis 9, straight parts 12, 13 connected to both ends of the circular part 11, and a straight part 14 extending between the straight parts 12, 13. The straight part 14 extends perpendicular to the straight parts 12, 13. The circular part 11 and the straight parts 12, 13, 14 are each provided on its outside with an inclined surface 15. Seen in a plane extending radially with respect to the central axis 9, the inclined surface 15 includes an obtuse angle A (see FIG. 5B) with a plane extending perpendicular to the central axis 9. The obtuse angle A is for example in a range between 95 and 140 degrees. The inclined surfaces 15 are directed towards the second coupling element 6.

(16) FIG. 3B shows a schematic top view of the first coupling element 5, with the straight part 14 provided with the inclined surface 15. A first inclined surface 15A of the inclined surface 15 is located on a left side whilst a second inclined surface 15B of the inclined surface 15 is located on a right side of a plane V extending radially with respect to the central axis 9 and perpendicularly to the straight part 14.

(17) At each location L on the first and second inclined surface 15A, 15B, a tangential direction T extends perpendicularly to a radial direction between the central axis 9 and the location L. The first inclined surface 15A includes an obtuse angle with the tangential direction T. Since the inclined surface 15 includes an obtuse angle A with a plane extending perpendicularly to the central axis 9 as well as with a radial direction R extending radially to the central axis 9, the obtuse angle of the first inclined surface 15A with the tangential direction T will be different at different locations L on the first inclined surface 15A.

(18) In the same manner, the second inclined surface 15B includes an obtuse angle with the tangential direction T, which will be different at different locations L on the second inclined surface 15B.

(19) As will be clear from FIG. 3B, at each location L on the first inclined surface 15A the obtuse angle between the first inclined surface 15A and the tangential direction T is located on a side of the inclined surface 15 directed towards the central axis 9, whilst at each location L on the second inclined surface 15B the obtuse angle between the second inclined surface 15B and the tangential direction T is located on a side of the inclined surface 15 directed away from the central axis 9. Accordingly the first and second inclined surfaces 15A, 15B are inclined in opposite directions relative to said tangential direction T.

(20) At a distance of the collar 10, the tubular part 8 is provided on its outside with two grooves 16 extending parallel to each other and perpendicular to the central axis 9. One of the grooves 16 extends parallel to the straight part 14. Each groove 16 comprises sloped surfaces 17, 18. An end 19 of the tubular part 8 near the grooves 16 is bevelled.

(21) The second coupling element 6 comprises a tubular part 20 extending along the central axis 9. The internal diameter of the tubular part 20 of the second coupling element 6 is slightly larger than the external diameter of the tubular part of the first coupling element 5. The tubular part 20 is provided with a ring-shaped flange 21. The ring-shaped flange 21 has a circular part 22 extending over 180 degrees along the central axis 9, straight parts 23, 24 connected to both ends of the circular part 22, and a straight part 25 extending between the straight parts 23, 24. The straight part 25 extends perpendicular to the straight parts 23, 24. The circular part 22 and the straight parts 23, 24, 25 are each provided on its inside with an inclined surface 26. Seen in a plane extending radially with respect to the central axis 9, the inclined surface 26 includes an obtuse angle A (see FIG. 5B) with a plane extending perpendicularly to the central axis 9. The inclined surfaces 26 are directed towards the first coupling element 5.

(22) At a distance of the flange 21, the tubular part 20 is provided with two slits 27 extending parallel to each other and perpendicular to the central axis 9. One of the slits 27 extends parallel to the straight part 25.

(23) At an end of the tubular part 20 near the slits 27, the tubular part 20 is provided with a notch 28 and a recess 29 located between the notch 28 and the straight part 24.

(24) A spring element 7 is connected to the second coupling element 6. The spring element 7 is U-shaped and comprises two leg portions 30 extending parallel to each other and a bridge portion 31 extending between the two leg portions 30. The leg portions 30 and bridge portion 31 extend perpendicular to the central axis 9. The leg portions 30 are located in the slits 27 of the tubular part 20 and extend partially through the slits 27 into a cylindrical-shaped space 32 bounded by the tubular part 20.

(25) The bridge portion 31 of the spring element 7 is located in the recess 29 between the notch 28 and the straight part 24.

(26) The coupling and uncoupling of the coupling elements 5, 6 will now be explained with reference to the FIGS. 4A-4D. As will be explained in detail in the following, the first coupling element 5 and the second coupling element 6 are configured to arrive from an uncoupled state into a coupled state relative to each other by driving the first and second coupling elements 5, 6 towards each other in the axial direction along the central axis 9, and to arrive from the coupled state into the uncoupled state by driving the first and second coupling elements 5, 6 away from each other in the axial direction along the central axis 9.

(27) If a user wants to couple the first coupling element 5 of the head structure 3 to the second coupling element 6 of the base structure 2, he will place the first coupling element 5 above the second coupling element 6 and roughly align the central axis 9 of the first coupling element 5 with the central axis 9 of the second coupling element 6 (see FIG. 4A). He will than move the first coupling element 5 in a direction indicated by arrow P1 towards the second coupling element 6, whereby the tubular part 8 is inserted into the cylindrical space 32 bounded by the tubular part 20. The bevelled end 19 facilitates placing by seeking the location of the cylindrical shaped space 32. He will continue until the collar 10 abuts against the flange 21 (see FIG. 4B). The user will rotate the first coupling element 5 in a direction indicated by double arrow P2 along the central axis 9 with respect to the second coupling element 6 (see FIG. 4C). He will continue to rotate the first coupling element 5 until he sees and feels that the circular parts 11, 22, the straight parts 12, 23; 13, 24; 14, 25 are aligned (see FIG. 4D) and the inclined surfaces 15, 26 thereof can be moved further towards each other in the direction indicated by arrow P1 until the inclined surfaces 15, 26 are in abutment. During the movement in the direction indicated by arrow P1, the bevelled end 19 of the first coupling element 5 will force the leg portions 30 of the spring element 7 apart. The leg portions 30 of the spring element 7 will snap into the grooves 16 of the tubular part 8 as soon as the tubular part 8 as moved far enough into the tubular part 20. The spring element 7 retains the first and second coupling elements 5, 6 in the coupled position. This coupled position is shown in FIGS. 5A and 5B.

(28) If a relatively large pulling force is exerted on the head structure 3 in an axial direction parallel to the central axis 9, the leg portions 30 of the spring element 7 will slide along the sloped surface 18 of the groove 16 and will be moved out of the groove 16 and the first coupling element 5 can easily be moved out of engagement with the second coupling element 6.

(29) If a torque is exerted between the head structure 3 and the base structure 2, in for example a clockwise direction indicated by double arrow P2, the inclined surface 15 of the straight part 14 will be forced in a direction indicated by arrow P3 against the co-operating inclined surface 26 of the straight part 25. Due to this force, the inclined surface 15 will be moved in a direction indicated by arrow P4, extending parallel to the central axis 9 and away from the second coupling element 6. The same cooperation will occur between the other inclined surfaces 15, 26. During this movement, the spring element 7 will be disengaged from the grooves 16 in the same manner as described above. The first coupling element 5 will be driven by the cooperating inclined surfaces 15, 26 in the direction indicated by arrow P4, until the coupling elements 5, 6 are in the position as shown in FIG. 4C, in which the coupling elements 5, 6 are freely rotatable with respect to each other. Due to the uncoupling of the coupling elements 5, 6 under influence of the torque, no damage will occur on the head structure 3 and the base structure 2. To prevent damage of the coupling elements 5, 6 as a result of said torque, an inclination of the inclined surface 15, i.e. the obtuse angle A, is selected such that the first coupling element 5 and the second coupling element 6 arrive from the coupled state into the uncoupled state by rotating the coupled coupling elements 5, 6 with respect to each other about the central axis over an angle smaller than 90, preferably smaller than 45, and more preferably smaller than 30.

(30) It is noted that, instead of the first and second coupling elements 5, 6 comprising the spring element 7 and the slits 27 as described here before, other types of coupling elements may be used which are configured to arrive from an uncoupled state into a coupled state relative to each other by driving the coupling elements towards each other in the axial direction along the central axis, and to arrive from the coupled state into the uncoupled state by driving the coupling elements away from each other in the axial direction along the central axis. Examples of such alternative coupling elements are snap connections and snap couplings which are well known to the skilled person.

(31) FIGS. 6-8 show several views of a second embodiment of two cooperating coupling elements 35, 36 of the shaving device 1 according to the invention.

(32) The first coupling element 35 comprises a tubular part 38 extending along a central axis 9. The tubular part 38 is provided with a collar 40. The collar 40 comprises a first circular part 41 extending over about 180 degrees along the central axis 9 and a second circular part 42 extending over about 60 degrees along the central axis 9. The first and second circular parts 41, 42 are separated by open spaces 43 extending over about 60 degrees along the central axis 9. On both ends of the first and second circular parts 41, 42 near the open spaces 43, the first and second circular parts 41, 42 are provided with an inclined surface 45, 46. The inclined surface 45, 46 includes an obtuse angle B (see FIG. 6) with a top side 47 of the collar 40. The top side 47 extends perpendicular to the central axis 9. Furthermore, the inclined surface 45, 46 includes the obtuse angle B with a tangential direction T extending tangential to the central axis 9 and from the respective inclined surface 45, 46. The obtuse angle B is for example in a range between 95 and d 140 degrees. The inclined surface 45, 46 are inclined in opposite directions. The inclined surfaces 45, 46 are directed towards the second coupling element 36.

(33) At a distance of the collar 40, the tubular part 38 is provided on its outside with two grooves 16 extending parallel to each other and perpendicular to the central axis 9. Each groove 16 comprises sloped surfaces 17, 18.

(34) An end 19 of the tubular part 38 near the grooves 16 is bevelled.

(35) The second coupling element 36 comprises a tubular part 50 extending along the central axis 9. The internal diameter of the tubular part 50 of the second coupling element 36 is slightly larger than the external diameter of the tubular part 38 of the first coupling element 35. The tubular part 50 is provided with a first flange 51 and a second flange 52, each extending over about 60 degrees along the central axis 9. The first and second flanges 51, 52 are separated by open spaces 53, 54. The open space 53 extends over about 60 degrees along the central axis 9, whilst the open space 54 extends over about 180 degrees along the central axis 9.

(36) On both ends of the first and second flanges 51, 52 near the open spaces 53, 54 the first and second flanges 51, 52 are provided with an inclined surface 55, 56. The inclined surface 55, 56 includes an obtuse angle B (see FIG. 6) with a plane perpendicular to the central axis 9. Furthermore, the inclined surface 55, 56 includes the obtuse angle B with a tangential direction T extending tangential to the central axis 9 and from the respective inclined surface 55, 56. The inclined surface 55, 56 are inclined in opposite directions. The inclined surfaces 45, 46 are directed towards the first coupling element 35.

(37) The dimensions of the first and second circular parts 41, 42 and the spaces 43 of the first coupling element 35 and the first and second flanges 51, 52 of the second coupling element 36 are such that they match with each other as can be seen in the FIGS. 7B and 8.

(38) The coupling and uncoupling of the coupling elements 35, 36 will now be explained with reference to the FIGS. 7A and 7B. As will be explained in detail in the following, the first coupling element 35 and the second coupling element 36 are configured to arrive from an uncoupled state into a coupled state relative to each other by driving the first and second coupling elements 35, 36 towards each other in the axial direction along the central axis 9, and to arrive from the coupled state into the uncoupled state by driving the first and second coupling elements 5, 6 away from each other in the axial direction along the central axis 9.

(39) If a user wants to couple the first coupling element 35 of the head structure 3 to the second coupling element 36 of the base structure 2, he will place the first coupling element 35 above the second coupling element 36 and will roughly align the central axis 9 of the first coupling element 35 with the central axis 9 of the second coupling element 36 (see FIG. 7A). He will than move the first coupling element 35 in a direction indicated by arrow P1 towards the second coupling element 36 whereby the tubular part 38 is inserted into the tubular part 50. He will continue until the collar 40 abuts against the flanges 51, 52. The user will then rotate the first coupling element 35 in a direction indicated by double arrow P2 along the central axis 9 with respect to the second coupling element 36. He will continue to rotate the first coupling element 35 until he sees and feels that the circular parts 41, 42 are aligned with the flanges 51, 52. The inclined surfaces 45, 46; 55, 56 can then be moved further towards each other in the direction indicated by arrow P1 until the inclined surfaces 45, 55; 46, 56 are in abutment. During the movement in the direction indicated by arrow P1, the bevelled end 19 of the first coupling element 35 will force the leg portions 30 of the spring element 7 apart. The leg portions 30 of the spring element 7 will snap into the grooves 16 of the tubular part 38 as soon as the tubular part 8 as moved far enough into the tubular part 50. The spring element 7 retains the first and second coupling elements 35, 36 in the coupled position. This coupled position is shown in FIGS. 7B and 8.

(40) If a relatively large pulling force is exerted on the head structure 3 in an axial direction parallel to the central axis 9, the leg portions 30 of the spring element 7 will slide along the sloped surface 18 of the groove 16 and will be moved out of the groove 16 and the first coupling element 35 can easily be moved out of engagement with the second coupling element 36.

(41) If a relatively large torque is exerted between the head structure 3 and the base structure 2, in for example a clockwise direction indicated by double arrow P2, the inclined surfaces 45 of the part 41, 42 will be forced in a direction indicated by arrow P3 against the co-operating inclined surface 55 of the flanges 51, 52. Due to this force, the inclined surfaces 45 will be moved in a direction indicated by arrow P4, extending parallel to the central axis 9 and away from the second coupling element 36. During this movement, the spring element 7 will be disengaged from the grooves 16 in the same manner as described above. The first coupling element 35 will be driven by the cooperating inclined surfaces 45; 55 in the direction indicated by arrow P4, until the coupling elements 35, 36 are in the position in which the coupling elements 35, 36 are freely rotatable with respect to each other. Due to the uncoupling of the coupling elements 35, 36 under influence of the torque, no damage will occur on the head structure 3 and the base structure 2. To prevent damage of the coupling elements 35, 36 as a result of said torque, an inclination of the inclined surfaces 45, 46, i.e. the obtuse angle B, is selected such that the first coupling element 35 and the second coupling element 36 arrive from the coupled state into the uncoupled state by rotating the coupled coupling elements 35, 36 with respect to each other about the central axis 9 over an angle smaller than 15, and more preferably smaller than 10.

(42) In case that a torque is applied in a counter-clockwise direction, the inclined surfaces 46 will slide along the inclined surfaces 56.

(43) The obtuse angle between the first inclined surface with the tangential direction T might be the same or different from the obtuse angle between the second inclined surface with the tangential direction T.

(44) If a user wants to uncouple the coupling elements, he may apply a pulling force in axial direction at one coupling element to disengage the spring 7 from the groove 27 or he may apply a relatively large torque about the central axis 9. He can also apply such a pulling force as well as such a torque.

(45) Due to the specific shape of the collars 10, 40 and the ring-shaped flange 21 respectively the flanges 51, 52, the first and second coupling elements 5, 6; 35, 36 can be connected to each other in only one specific orientation with respect to each other. For a user this specific orientation is clearly visible and the user will get tactile feedback when connecting the coupling elements to each other.

(46) The flanges and circular parts form protrusions, which fit in recesses formed by the spaces between the flanges and the circular parts, wherein the coupling elements can only be coupled to each other if each protrusion is located in the correct recess.

(47) It is also possible that due to the shape, dimensions and locations of the protrusions and recesses the coupling elements can be coupled to each other in two or more different orientations with respect to each other, wherein in each orientation the coupling elements are correctly coupled to each other.

(48) It is possible to use the coupling elements for coupling parts of a personal care device of another type than the shaving device described here before, for example a trimmer, brush or shaving head, or for coupling parts in such kind of personal care devices like grooming devices.

(49) The person skilled in the art will realize that the present invention is by no means limited to the preferred embodiments. Other variations to the disclosed embodiments can be understood and effected by those skilled in the art in practicing the claimed invention, from a study of the drawings, the disclosure, and the appended claims.

(50) In the claims, the word comprising does not exclude other elements or steps, and the indefinite article a or an does not exclude a plurality. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage. Any reference signs in the scope should not be construed as limiting the scope of the claims.

LIST OF REFERENCE SIGNS

(51) 1 shaving device 2 base structure 3 head structure 4 head support structure 4 rotary shaving head 5 first coupling element 6 second coupling element 7 spring element 8 tubular part 9 central axis 10 ring-shaped collar 11 circular part 12 straight part 13 straight part 14 straight part 15 inclined surface 15A first inclined surface 15B second inclined surface 16 groove 17 sloped surface 18 sloped surface 19 end 20 tubular part 21 ring-shaped flange 22 circular part 23 straight part 24 straight part 25 straight part 26 inclined surface 27 slit 28 notch 29 recess 30 leg portion 31 bridge portion 32 cylindrical-shaped space 35 first coupling element 36 second coupling element 38 tubular part 40 collar 41 first circular part 42 second circular part 43 open space 45 inclined surface 46 inclined surface 47 top side 50 tubular part 51 first flange 52 second flange 53 open space 54 open space 55 inclined surface 56 inclined surface A angle B angle L locations P1 arrow P2 arrow P3 arrow P4 arrow R radial direction T tangential direction V plane