COUPLING DEVICE FOR DETACHABLY CONNECTING A MEDICAL OR DENTAL INSTRUMENT TO A DRIVE UNIT OR A SUPPLY HOSE

Abstract

A coupling device for detachably connecting a medical or dental instrument to a drive unit or a supply hose for transfer of at least one of data, energy, a driving movement and a working medium between the drive unit or the supply hose and the instrument includes a first coupling element and a second coupling element. One of the coupling elements includes a coupling recess and the other includes a coupling protrusion insertable therein. One of the coupling elements includes a positioning element and the other includes an indentation into which the positioning element can be inserted to position the coupling elements in a defined angular position about a shared axis. One of the coupling elements includes a memory unit for storage of data and the other includes a transfer unit, so that data can be transferred from the memory unit by the transfer unit to the other coupling element.

Claims

1. A coupling device for detachably connecting a medical or dental handle element to a drive unit or a supply hose for transfer of at least one of data and energy between the drive unit or the supply hose and the handle element, comprising: a first coupling element provided on an end of the handle element facing the drive unit or supply hose when the handle element and the drive unit or supply hose are coupled together and a second coupling element provided on an end of the drive unit or supply hose facing the handle element when the handle element and the drive unit or supply hose are coupled together, wherein one of the first and second coupling elements comprises a coupling recess and the other of the first and second coupling elements comprises a coupling protrusion insertable into the coupling recess, and wherein one of the first and second coupling elements comprises a positioning element and the other of the first and second coupling elements comprises an indentation into which the positioning element can be inserted to position the coupling elements in a defined angular position about a shared axis relative to one another, wherein the positioning element comprises an electronically programmable memory element for storage of data and the indentation comprises or adjoins to a transfer unit, so that data can be transferred from the electronically programmable memory element of the one coupling element to the other coupling element by the transfer unit, and wherein the positioning element comprises a lug or protrusion, wherein at least a portion of the electronically programmable memory element is received within the lug or protrusion which extends from a coupling surface of one of the first or second coupling elements such that at least a portion of the lug or protrusion and at least a portion of the electronically programmable memory element received within the lug or protrusion are arranged to protrude axially beyond an outer sleeve of the respective first or second coupling element for data transfer to and from the electronically programmable memory element and are insertable in the indentation.

2. The coupling device according to claim 1, wherein the electronically programmable memory element is entirely housed within the lug or protrusion.

3. The coupling device according to claim 1, wherein the electronically programmable memory element has at least one electric contact which can be connected to an electric contact of the transfer unit, so that the data can be transferred in a hardwired operation.

4. The coupling device according to claim 3, wherein the electric contact of the electronically programmable memory element is disposed in an end surface of the positioning element, and the electric contact of the transfer unit is disposed in a base surface of the indentation.

5. The coupling device according to claim 1, wherein the electronically programmable memory element has at least one first coil and the transfer unit has at least one second coil for output and/or writing of the data.

6. The coupling device according to claim 5, wherein the at least one first coil and the electronically programmable memory element are disposed adjacent each other on a shared carrier circuit board in the positioning element.

7. The coupling device according to claim 5, wherein the at least one first coil and the electronically programmable memory element are disposed in a shared housing of the positioning element.

8. The coupling device according to claim 5, wherein the at least one first coil is disposed in or on at least one side wall or end surface of the positioning element, so that the at least one first coil of the positioning element can be coupled to the at least one second coil of the transfer unit.

9. The coupling device according to claim 5, wherein the at least one second coil of the transfer unit is disposed adjacent the indentation for the positioning element on at least one of the side walls or base surface of the indentation, so that the at least one second coil of the transfer unit can be coupled to the at least one first coil of the memory unit.

10. The coupling device according to claim 5, wherein the at least one first coil and the at least one second coil are surrounded by soft magnetic material for conducting and/or aligning the field lines of the magnetic field.

11. The coupling device according to claim 10, wherein the soft magnetic material comprises at least one of ferrite, nickel-zinc or manganese-zinc.

12. The coupling device of claim 5, wherein the at least one first coil and at least one second soil are surrounded by electrically nonconductive material to prevent weakening of the magnetic field due to self-generated and/or received foreign fields.

13. The coupling device according to claim 12, wherein the electrically non-conductive material comprises at least one of plastic, silicone, resin, ceramic, adhesive, lacquer or glass.

14. The coupling device according to claim 1, wherein the positioning element comprises a housing made of a magnetically nonconductive and electrically nonconductive material at least in a region surrounding the electronically programmable memory element.

15. The coupling device according to claim 1, wherein the positioning element comprises a spring mount, so that the lug or protrusion of the positioning element and the electronically programmable memory element received therein can be displaced substantially in parallel with an axis of rotation of the respective first or second coupling element.

16. The coupling device according to claim 1, wherein the positioning element is designed to be releasable from the first or second coupling element into which the positioning element is insertable.

17. The coupling device according to claim 1, wherein the positioning element and the transfer unit have additional electric contacts and/or reading and/or writing devices for hardwired and/or wireless transfer of data, signals and/or energy between the first and second coupling elements.

18. A method of using the coupling device according to claim 1 for detachably connecting the handle element with the first coupling unit to a drive unit or supply hose having the second coupling unit.

19. The coupling device of claim 1, further comprising the medical or dental handle element for transfer of at least one of data or energy, and the drive unit or a supply hose, the first and second coupling elements being positioned at respective ends thereof to couple together the medical or dental handle element and the drive unit or supply hose.

20. The coupling device of claim 1, further comprising a first dental device and a second dental device, the first and second coupling elements being positioned at respective ends thereof to couple together the first dental device and the second dental device.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0029] FIG. 1 shows a first exemplary embodiment of the coupling device having a first coupling element on a medical, in particular dental, instrument and a second coupling element on a drive unit;

[0030] FIG. 2 shows a sectional diagram of the first exemplary embodiment of the coupling device from FIG. 1, with a memory unit having a memory element and an electric contact in the positioning element of the one coupling element and another electric contact as a transfer unit in the indentation to receive the positioning element in the other coupling element, in a partially installed state of the two coupling elements;

[0031] FIG. 3 shows a second exemplary embodiment of the coupling device, also in a sectional diagram, having a reading and/or writing device, in particular a first and second coil in the positioning element and in the indentation of the first and second coupling elements;

[0032] FIG. 4 shows a third exemplary embodiment of the coupling device having a first coil and a memory element disposed in its own housing in the positioning element;

[0033] FIG. 5 shows a fourth exemplary embodiment of the coupling device, where the first and second coils of the two coupling elements are surrounded by a soft magnetic material and a material that is not electrically conductive;

[0034] FIG. 6 shows a fifth exemplary embodiment of the coupling device, wherein the coupling elements each have an additional reading and/or writing device for wireless transmission of data, signals and/or energy from the one coupling element to the other coupling element.

DETAILED DESCRIPTION

[0035] FIG. 1 shows a coupling device 1 for detachably connecting a medical, in particular dental, instrument 2 (e.g., a handpiece or handle) to a drive unit 3 for transfer of data and/or energy, a drive movement and a working medium, in particular a fluid, between the drive unit 3 and the instrument 2. The coupling device 1 therefore has a first coupling element 4 in the form of a coupling recess 6 on the medical instrument 2 and a second coupling element 5, which is designed as a coupling protrusion 7 on the drive unit 3.

[0036] To position the two coupling elements 4, 5 in relation to one another in a defined angular position about their common axis 10 about which they can rotate freely up to a coupled state of the two coupling elements 4, 5 to align a media line 31 of the drive unit 3, in particular for light or at least one fluid, to the corresponding media line 32 on the medical instrument 2, the coupling device 1, in particular the first coupling element 4 with the coupling recess 6 on the instrument 2, has a positioning element 8, which preferably extends from the coupling surface of the first coupling element 4 in the opposite direction to the coupling recess 6. The positioning element 8 is preferably designed as a lug, a continuation or protrusion and can be inserted into an indentation 9 on the other coupling element 5. The positioning element 8 and the indentation 9 are designed in particular for a rotationally fixed connection of the two coupling elements 4, 5.

[0037] For identification of the medical instrument 2 to supply the working media automatically depending on the instrument 2, which is connected via the drive unit 3 to a dental unit, the positioning element 8 of the first coupling element 4 has a memory unit for storage of data, preferably instrument-related data. In addition to the memory unit, at least one electric contact 13 is disposed in or on the element 8 in this exemplary embodiment, this contact being connectable to an electric contact 14 of a transmission unit 12 in the indentation 9 on the other coupling element 5 so that the data, in particular instrument-related data, can be transferred in a hardwired operation.

[0038] FIG. 2 shows the coupling device 1 from FIG. 1 in a sectional diagram in a partially connected state of the two coupling elements 4, 5, where the coupling protrusion 7 on the second coupling element 5 is accommodated in the coupling recess 6 on the first coupling element 4, preferably the dental instrument 2. The positioning element 8 with the memory unit 11 of the first coupling element 4 is at least partially supported in a recess in the sleeve-shaped coupling part 33, in particular displaceably, and is prestressed by means of a spring 32 in relation to the indentation 9 on the other coupling part 5. The memory element 19 and the electric contact 14 of the memory unit 11 itself however are disposed outside of the sleeve-shaped coupling part 33 in the positioning element 8, so that these are accessible for the other coupling element 5 from several sides. The housing 27 of the positioning element 8, in particular the region surrounding the memory unit 11 is preferably made of a magnetically nonconductive and electrically nonconductive material, in particular a plastic, glass or ceramic.

[0039] The transfer of data and/or energy between memory unit 11, in particular between its memory element 19 and the transfer unit 12 which is preferably disposed in the indentation 9 of the other coupling element 5 takes place in a hardwired operation in this exemplary embodiment. The electric contacts 13, 14 are each mounted on the end surface 15 of the positioning element 8 and on the base surface 16 of the indentation 9 and/or are accessible for the corresponding contact 13, 14.

[0040] The electric contact 13 in the indentation 9 for receiving the positioning element 8 is preferably disposed on a carrier circuit board 22. The circuit board 22 itself is preferably designed in a ring shape with the coupling protrusion 7 extending through its central opening. In addition to the reading and/or writing device, in particular the electric contact 13, other electronic components may also be disposed on the circuit board 22, in particular those for data and/or energy transfer. A light source, in particular a light-emitting diode, is preferably soldered on the circuit board 22, with the media line 31 being designed as a window of the diode to transfer light from the drive unit 3 to the instrument 2. The electronic components, the transfer unit 12 and the circuit board 22 are preferably accommodated in a magnetically nonconductive and electrically nonconductive material, in particular plastic, glass or ceramic. This encapsulated unit encloses the coupling protrusion 7, which extends from the coupling base through the ring-shaped unit.

[0041] FIG. 3 shows a second exemplary embodiment of the coupling device 1, also in a sectional diagram, with a reading and/or writing device in the first and second coupling elements 4, 5, in particular with a first coil 17 in the positioning element 8 and a second coil 18 in the indentation 9. The positioning element 8 in this example is fixedly connected to the sleeve-shaped coupling part that surrounds the coupling recess 6. However, it is of course also possible with this exemplary embodiment as well as with all additional exemplary embodiments to prestress the positioning element 8 by means of a spring in relation to the indentation 9 on the other coupling part 5. Here again, the memory unit 11 and the memory element 19 and the coil 17 are disposed outside of the sleeve-shaped coupling part in the positioning element 8 of the first coupling element 4. The coil 17 is preferably disposed on the memory element 19, in particular between the memory element 19 and the lateral surface 23 of the positioning element 8. The coil 18 of the transfer unit 12 of the other coupling element 5 with the coupling protrusion 7 is applied to a carrier circuit board 22, which is preferably designed at least partially to be sleeve-shaped and is disposed in the lateral surface 24 of the indentation 9. The two coils 17, 18 are thus disposed one inside the other for inductive coupling in the installed state of the coupling device 1. This inductive coupling serves to supply energy to the memory unit 11 as well as serving the purpose of exchanging data. The data exchange takes place between the two coils 17, 18 in the high-frequency range or in the radio frequency range, where the memory unit 11 is designed as an RFID unit, in particular as an RFID label or a transponder consisting of an RFID chip 19 and a coil 17.

[0042] FIG. 4 shows a third exemplary embodiment of the coupling device 1 with a first and second coupling element 4, 5 having a memory unit 11 with a first coil 17 and a memory element 19 which are disposed in a shared housing 21 in the positioning element 8. The housing 21 as well as the components disposed therein, in particular the memory 19 and coil 17, together for an RFID unit, which is accommodated in the positioning element 8, preferably by means of an injection-molding process.

[0043] Alternatively, the memory 19 and the coil 17 may be disposed in a housing 21 made of glass, plastic, ceramic or metal. The coil 18 of the transfer unit 12 is disposed on a carrier circuit board 22 in the region of the base surface of the indentation 9 to receive the positioning element 8. The two coils 17, 18 are thus disposed directly side by side or opposite one another in a coupled state of the two coupling elements 4, 5, in particular in an arrangement of the coupling protrusion 7 in the coupling recess 6. Particularly reliable data exchange and/or energy exchange is/are achieved in this way.

[0044] FIG. 5 shows a fourth exemplary embodiment of the coupling device 1, wherein the first and second coils 17, 18 of the two coupling elements 4, 5 are surrounded by a soft magnetic material 25 and an electrically nonconductive material 26. The coil 17 in the positioning element 8 is positioned on the memory element 19, which is in turn disposed on a carrier circuit board 20. The carrier circuit board 20 preferably comprises an electrically insulating material, for example, plastic, glass or ceramic. The coil 18 of the transfer unit 12 of the other coupling element 5 is also disposed on such a carrier circuit board 22. To permit a particularly good and interference-free energy transfer and data transfer, according to a preferred exemplary embodiment, the coil 18 of the transfer unit 12 disposed in the indentation 9 and also the memory unit 11 in the positioning element 8 are surrounded by a soft magnetic material 25, in particular ferrite, nickel-zinc or manganese-zinc for conducting and/or aligning the field lines of the magnetic field in the direction of the first or second coil 17, 18 and/or surrounded by an electrically nonconductive material 26, in particular plastic, silicone, resin, ceramic, adhesive, lacquer or glass to prevent weakening of the magnetic field due to self-generated and/or received foreign fields. The electrically nonconductive material 26 preferably encloses the coil 18 and the memory unit 11 on all sides. In this exemplary embodiment, the two components 18, 11 have both materials 25, 26 on at least three sides, wherein the soft magnetic material 25 is designed here in particulate form and each is embedded in the other material 26.

[0045] FIG. 6 shows a fifth exemplary embodiment of the coupling device 1 where the coupling elements 4, 5 each have another reading and/or writing device 28, 29 for wireless transfer of data, signals and/or energy from one coupling element to the other coupling element. The reading and/or writing device 28, 29 here is also disposed in the positioning element 8 and in the indentation 9 of the transfer unit 12, next to the electric contacts 13, 14 for data and/or energy exchange between the memory element 19 of the memory unit 11 and the transfer unit 12.

[0046] As already shown in FIGS. 1 and 2, the electric contacts 13, 14 are each mounted on end surface of the positioning element 8 and on the base surface of the indentation 9 and are accessible for the corresponding contact 13, 14. The coils 28, 29 for additional transfer of data, signals and/or energy are preferably disposed one inside the other in an installed state of the coupling device 1. To do so, the coil 29 is preferably disposed between the memory element 19 and the lateral surface of the positioning element 8 and the coil 28 of the transfer unit 12 of the other coupling element 5 is preferably disposed in the lateral surface of the indentation 9.

[0047] An electric line 34 preferably extends from the coil 29 to an electronic component in the medical, in particular dental, instrument, which is preferably connected to the coupling element 4. The coils 28, 29 here serve the purpose of energy transfer, preferably for a light source in the instrument and/or for transfer of data, in particular of measured data such as, for example, sensor data for torques, temperatures and/or for transfer of signals such as, for example, root canal positioning signals from the electronic component such as, for example, a sensor or an evaluation unit to a dental unit.

[0048] The present invention is not limited to the exemplary embodiments described here but instead includes all embodiments which apply and contain the principle logical function principle of the invention. In addition, all the features of all the exemplary embodiments described and depicted here may be combined with one another.