Classifications

• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
  • A61B17/16—Bone cutting, breaking or removal means other than saws, e.g. Osteoclasts; Drills or chisels for bones; Trepans
  • A61B17/1613—Component parts
  • A61B17/1626—Control means; Display units
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
  • A61B17/16—Bone cutting, breaking or removal means other than saws, e.g. Osteoclasts; Drills or chisels for bones; Trepans
  • A61B17/1613—Component parts
  • A61B17/162—Chucks or tool parts which are to be held in a chuck
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
  • A61B17/16—Bone cutting, breaking or removal means other than saws, e.g. Osteoclasts; Drills or chisels for bones; Trepans
  • A61B17/1613—Component parts
  • A61B17/1633—Sleeves, i.e. non-rotating parts surrounding the bit shaft, e.g. the sleeve forming a single unit with the bit shaft
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B90/00—Instruments, implements or accessories specially adapted for surgery or diagnosis and not covered by any of the groups A61B1/00 - A61B50/00, e.g. for luxation treatment or for protecting wound edges
  • A61B90/90—Identification means for patients or instruments, e.g. tags
  • A61B90/98—Identification means for patients or instruments, e.g. tags using electromagnetic means, e.g. transponders
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
  • A61B2017/00017—Electrical control of surgical instruments
  • A61B2017/00022—Sensing or detecting at the treatment site
  • A61B2017/00039—Electric or electromagnetic phenomena other than conductivity, e.g. capacity, inductivity, Hall effect
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
  • A61B2017/00831—Material properties
  • A61B2017/00876—Material properties magnetic
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
  • A61B2017/00973—Surgical instruments, devices or methods, e.g. tourniquets pedal-operated
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
  • A61B17/16—Bone cutting, breaking or removal means other than saws, e.g. Osteoclasts; Drills or chisels for bones; Trepans
  • A61B2017/1602—Mills

Definitions

• the invention relates to a surgical instrument, in particular a milling handpiece, and a tool for the surgical instrument.
• a tool such as a cutting drill or the like has a geometric coding in the area of its insertion shaft , for example has a bar coding.
• a reading device built into the tool holder (tool chuck) and aligned with the coding, such as an electronic, optical or mechanical sensor, signals corresponding to the coding are generated and sent to a control unit or evaluation unit of the machine tool for further processing.
• essentially three sections can be distinguished: a proximal coupling cut, a shaft section and at least one distal working end / etector.
• the shank section connects the coupling section to the working end of the tool.
• the working end is opposite the coupling section at the other end of the tool and is the functional part of the tool for engaging with a patient.
• Tools of the type referred to herein generally include tools, drills, burrs, and the like useful in the medical field. In this respect, however, there is no restriction to products of the aforementioned type specifically from the medical field.
• Both users and dealers or customers and manufacturers of such tools are adversely affected by this.
• a user or customer of such a tool cannot easily recognize, for example without looking at the label or the outer packaging, whether or not an intended tool is suitable for his specific application.
• a dealer or customer for example, usually cannot record which product stocks are still in a warehouse or consignment warehouse without an inventory. For example, a manufacturer cannot determine which products have been combined and / or used. Overloading of tools and possibly associated product damage cannot therefore be traced. Tailor-made logistics cannot be provided for the customer.
• electromotive, hydraulic or pneumatic drive handpieces are provided / equipped at their distal end section with a, as a rule, exchangeable spacer sleeve in order to be able to be tailored to the patient's anatomy, with their distal end being rich for rotatable and / or displaceable recording of the tool is prepared.
• the spacer sleeve has a small diameter, in order to be able to be introduced into the abdominal cavity of a patient, for example.
• a torque rod is also mounted in the spacer sleeve, which transmits a drive torque from the handpiece-internal drive motor to the tool.
• a spacer sleeve for a surgical instrument and preferably a surgical instrument with such a spacer sleeve is provided, the sleeve being designed at its distal end region to accommodate at least part of a tool, preferably rotatably .
• the sleeve has Signallei lines. The signal lines run axially along the sleeve.
• the spacer sleeve (or the surgical instrument) also has a magnetic memory readout device. The magnetic memory readout device is arranged on the sleeve.
• the Magnetspei cherauslese advocacy is electrically connected to the signal lines of the sleeve.
• the magnetic memory readout device is designed, based on a magnetic memory, to read out information about the tool contained in the magnetic memory.
• the magnetic memory surrounds or forms a perimeter of the part of the tool.
• the magnetic memory readout device is also designed to transmit the information read out via the signal lines of the sleeve to an evaluation unit.
• a tool according to the present invention has a tool information carrier, preferably a magnetic memory, which is arranged in the shank section of the tool and contains tool-specific information.
• a read-out device is arranged, which is designed to read out the tool information carrier and its information inserted in the spacer sleeve (already). sen.
• data transmission lines / signal lines are connected, which are laid in / on the spacer sleeve in de Ren longitudinal direction and preferably lead into a coupling section of the spacer sleeve with the handpiece. Via these signal lines, the readout device is connected to an evaluation unit, preferably in the handpiece, or can be connected to the handpiece by coupling the spacer sleeve.
• the information on the tool can be obtained automatically via the readout device and evaluated by the evaluation unit.
• the surgeon can accordingly be able to obtain information about the tool used / inserted into the spacer sleeve without prior inspection.
• the surgical instrument can be a surgical power tool, such as a milling handpiece.
• the instrument is understood herein as a surgical device provided for receiving and operating the tool.
• the sleeve can be made of an electrically non-conductive material. Furthermore, the material of the sleeve can be a hard material, for example ceramic.
• the magnetic memory can contain information linked to the tool in the form of a layer. This information can be stored on the layer in the form of a magnetization. This information can be arranged or stored at least in the circumferential direction or the direction of rotation of the tool.
• the magnetic memory can comprise a ferromagnetic layer, which can be seen for magnetization.
• the magnetic memory readout device can, for example, have a read head.
• the read head or the magnetic memory readout device can be formed from, when the tool is rotated along a (magnetic) track in the circumferential direction of the tool shaft, to receive this information in the form of signals and to forward it via the signal lines.
• These signals can be based on a magnetic field that changes due to the differently magnetized areas of the magnetic memory along the track. This magnetic field can produce different voltages in the reading head or the magnetic memory readout device. which can be forwarded as the information or signals via the signal lines.
• the evaluation unit can be a processing unit internal or external to the surgical instrument.
• the evaluation unit can be designed to evaluate / process the information or the signals.
• the processing unit can output the corresponding results from the evaluation of the information or the signals to a user of the surgical instrument via a user interface.
• the magnetic memory readout device can be located within a space defined by an outer jacket of the sleeve.
• the tool and the magnetic memory readout device can thus be accommodated together in the sleeve. Accordingly, the surgical instrument can be designed to save space.
• the magnetic memory readout device can comprise at least one magnetometer.
• the magnetometer can act as the reading head defined above.
• the sleeve can have at least one recess / cutout / window in its peripheral wall. Part of the magnetometer can be located in the recess.
• the breakout through opening
• the magnetometer can advantageously be a Hall sensor in the form of a surface mounted device (SMD) component. This allows the magnetometer to be easily inserted into the sleeve, for example by clamping it by hand.
• SMD surface mounted device
• the readout can take place when the surgical instrument is actuated (the drive motor recorded therein), for example via a toggle switch on the surgical instrument or an actuating device connected to the surgical instrument. Movement switch, for example a foot pedal.
• actuating device / actuating switch can be designed to operate the surgical instrument, in particular its motor.
• information about the currently used tool can be supplied to the user of the surgical instrument by simply actuating an actuating element connected to the surgical instrument, such as a foot pedal.
• the object defined above is achieved according to the invention in a device of the generic type in that a tool for a surgical instrument is provided.
• the tool comprises a part (tool shaft) intended to be received in a sleeve of a surgical instrument.
• the tool also comprises a data / information carrier, preferably a magnetic memory, especially in the form of a layer.
• the (magnetic) layer is designed to form a periphery of the part or to cover an outer side of the tool shank in its (entire) circumferential direction.
• the tool is designed to interact with the surgical instrument or its spacer sleeve according to the above definition in such a way that the magnetic memory is read out by means of a magnetic memory read-out device of the surgical instrument / the spacer sleeve. In this way, the information on the tool can be obtained and evaluated automatically. The surgeon can therefore be enabled to obtain information about the tool used without prior viewing.
• the magnetic memory can be designed to be pushed onto the part. This allows a modular magnetic memory to be provided in optional connection with the tool.
• the magnetic memory may have magnetized wire rings surrounding the perimeter of the part.
• the wire rings can be arranged offset to one another axially along the tool.
• the magnetic memory can have permanent magnets or pieces of wire.
• the permanent magnets or pieces of wire can be spaced apart from one another in the circumferential direction of the work and in the axial direction along the tool.
• the magnetic memory can have spherical permanent magnets. The spherical permanent magnets can be arranged offset to one another in the circumferential direction of the tool and in the axial direction along the tool.
• the signal lines can be made of (highly) conductive material such as copper, silver or gold.
• the sleeve is preferably set up for forwarding or transmitting electrical signals in an axial direction between a first (distal) axial end and a second (proximal) axial end of the sleeve and / or in a radial direction between an inner circumferential surface and an outer circumferential surface of the sleeve.
• an outer jacket surface of the sleeve has channels which extend over an entire axial length of the sleeve.
• the signal lines are preferably provided or arranged in the channels.
• the channels are preferably designed to be fine or filigree and produced by grinding or engraving, for example laser engraving.
• the channels are preferably metallized and coated with the highly conductive material to form the signal lines trainees.
• the signal lines are offset inward with respect to the outer jacket surface of the sleeve, so that the signal lines are only provided in a lower region of the groove.
• the signal lines are preferably completely sunk into the channels, so that the (outer) outer jacket surface of the sleeve is spaced apart from the signal lines in the radial direction of the sleeve.
• the signal lines should preferably not close flush with the outer jacket surface. but are located further inside. This ensures that the individual signal lines are electrically isolated from one another. This is particularly required, since an outer tube of a milling handpiece, in which the sleeve is preferably to be inserted and on which the sleeve rests directly, is often made of metal.
• an insulator is arranged over the signal lines.
• the mentioned electrical separation of the signal lines from one another can be improved if an insulator is also provided.
• the insulator can, for example, be an insert, for example made of silicone.
• the insulator can also be implemented, for example, by means of an adhesive layer. The additional insulation makes the surgical instrument, in particular the milling handpiece into which the sleeve is inserted, less sensitive to the ingress of conductive liquids (e.g. a saline solution).
• an advantageous embodiment is characterized in that an inner jacket surface of the sleeve has at least one signal line. If, in addition or as an alternative, signal lines are provided on the inner surface of the sleeve, electrical signals can be tapped off and forwarded or transmitted in the inner area. For example, metallized tracks (at least one metallized track) can be provided on the inner jacket surface. These metallized tracks can be connected to the magnetic memory readout device.
• the sleeve can have fine bores (micro-bores) which extend in the radial direction of the sleeve, and via which signal lines on the inner jacket surface can be connected to the respective signal lines on the outer jacket surface in an electrically conductive manner (for example by means of conductive material in the bores).
• the bores (micro-bores) preferably run between the channels on the outer circumferential surface and the signal lines on the inner circumferential surface.
• through-contacts are preferably created, which can also function as soldering eyes at the same time.
• wired components can also be integrated into the system, for example Capacitors.
• Soldering points for SMD components of the magnetic memory readout device can be provided on the inner circumferential surface. These can be connected accordingly to the signal lines inside.
• the signal lines can basically be brought into the sleeve at different depths. As a result, an at least partially very thin-walled sleeve can be realized. Furthermore, a large number of signal lines can be easily seen, which are introduced into the sleeve at different depths. This applies to signal lines attached to the outer jacket surface as well as to the inner jacket surface.
• the signal lines attached to the inner lateral surface are preferably located on the inner lateral surface of the sleeve itself and are not embedded.
• an electrical contact is connected to the corresponding signal line in an electrically conductive manner. This applies both to signal lines on the inner jacket surface and to signal cables on the outer jacket surface. If a plurality of signal lines is provided, it can be advantageous if a signal line is interrupted on one side (for example the inside) and is continued on the other side (for example the outside). This can be achieved via a conductive connection in a radial bore.
• an electrical contact / an electrical contact surface for a sensor or for another (electronic) component can be applied to the inner jacket surface of the sleeve, which is preferably electrically conductively connected to the corresponding signal lines applied to the inner jacket surface. This can be especially true for the magnetic memory readout device.
• the sleeve consists of a large number of (at least two, preferably three or more) sleeves placed one inside the other. In other words, several sleeves should preferably be arranged in several layers. As a result, even more functions can advantageously be integrated into the sleeve and the installation space is used to the maximum.
• the sleeve preferably allows signals to be transmitted from distal to proximal and vice versa, that is, in the axial direction of the surgical instrument or the sleeve, and from the inside to the outside and vice versa, that is, in the radial direction of the surgical instrument or the sleeve.
• the invention relates to a handpiece with magnetic tool recognition, for example a surgical milling handpiece, which is equipped with automatic tool recognition, and the associated tool, which is equipped with a magnetic memory.
• the correct tool type and the associated lot number can be read out automatically from the magnetic memory.
• the work tool can be automatically recognized after the insertion process into the milling hand piece or when the foot pedal / hand control is pressed for the first time.
• the relevant data associated with the detection can be, for example: article number (and thus tool type), lot number, best-before date and the like.
• the customer or user of the surgical instrument can be shown which product is involved.
• Various display variants can be provided for this purpose. Additional information can be displayed depending on the tool and handpiece used.
• a control device also referred to herein as a control unit, of the surgical instrument automatically selects and / or sets the optimum rotational speed suitable for the tool. This saves input work for the customer or user of the surgical instrument.
• a preferred embodiment of the invention can comprise a handpiece with an integrated magnetic memory readout device.
• the handpiece can be in its distal Spacer sleeve includes a special miniaturized magnetic memory readout device.
• Another preferred embodiment can be a tool with an integrated Mag net memory.
• the tool has an integrated magnetic memory.
• the shaft of the tool can be made of a non-ferro magnetic steel and have a recess. The recess is only a few tenths of a millimeter deep.
• the shaft can be overmolded with a plastic magnetic layer carrier.
• a magnetizable oxide layer (as in the case of magnetic tapes), which is also referred to herein as a magnetic layer, can be applied to this.
• a thin layer of protective lacquer can be applied to protect the magnetic layer.
• the magnetic memory defined herein can contain at least the oxide layer or the oxide layer and the magnetic layer carrier and / or the protective lacquer.
• the layer thicknesses of the magnetic layer carrier, the magnetic layer and the protective lacquer can vary.
• the magnetic layer can, for example, be (only) a few hundredths of a millimeter thick (for example less than 100 ⁇ m or less than 50 ⁇ m).
• the protective lacquer layer can, for example, only be a few micrometers thick (for example less than 10 pm or less than 5 pm).
• one embodiment can provide a combination of a handpiece as a surgical instrument and the tool.
• the tool can be pushed into the shaft of the handpiece and locked.
• the magnetic memory readout device integrated in the handpiece can be arranged between the distal ball bearings and the proximal ball bearings of the shaft tip of the handpiece.
• the magnetic memory of the tool comes in close proximity to four Hallsenso ren, which are the magnetic memory readout device or a part of it.
• the Hall sensors and the capacitors which can be part of the Magnet shallausleseeinrich device or form them together, can be precisely positioned between a shaft tube of the hand-held device and the tool.
• to sign six signal lines can be used. These are used to connect the supply voltage (VCC and GND) as well as the four signal outputs of the Hall sensors with the evaluation electronics, also generally referred to herein as evaluation unit.
• the evaluation electronics can be located, for example, in the handle or in the control unit, where more space is available.
• the signal transmission / routing can take place through the shaft or the sleeve.
• a tool with a magnetizable / magnetized layer can be used. As in the case of the digital magnetic tapes of earlier tape recorders / data storage devices, this can be written or written to in multiple tracks.
• This can be a 7-track magnetic tape with an alphanumeric 6-bit code in accordance with DIN 66010, 66011 and 66013.
• the magnetic tape can be or be digitally written on with multiple tracks.
• the magnetic tape can have a storage density of up to 32 bits per millimeter. By using several tracks and of course by the length of the magnetic tape, the total amount of data that can be stored can be influenced. In this way, very large amounts of data can be stored on a magnetic tape.
• a special read head for example as part of the magnetic memory readout device, can be used to read out the magnetic tapes.
• Conventional reading heads can be too large for the very small distal installation space of current milling handpieces in order to be able to integrate them there.
• a special miniaturized Hall sensor can therefore be used as a read head to read out the magnetized layer on the tool.
• the tools can be written to directly after they have been produced. Writing / coding devices of any size can be used for this. Therefore, magnetization with a conventional write head is also possible here.
• the tools for a surgical milling handpiece require a very small amount of data for recognition.
• the article number and are sufficient save the LOT number on the tool. If this data is stored in a database, it is not even necessary to use an alphanumeric code. Therefore, the data or information about the tool can be saved in a purely binary manner. This also has the advantage that the tools are described in coded form and can thus be protected from imitations / forgeries.
• a 40 bit code can be used. 1,099,511, 628,000 different states can be saved with 40 bits. Without a check digit or other security features, this is a 13-digit number. When using the usual conversions, 549.755.813.900 can be saved in decimal format. A number of tools is well below this number, for example less than 5000 tools or less than 1000 tools or tool types. The lot number can be 8 digits long. Thus 5496 different tools and 99,999,999 different lot numbers can be saved. This means that a sufficient number of different tools can be mapped.
• the handpiece can have a drive with a rotation speed of approx. 80,000 rpm, which corresponds to 1.333 kHz.
• the selected miniature Hall sensor can have a readout rate of 20 kHz. At a maximum speed of 80,000 rpm, 15 bits per revolution can be recorded.
• the reduction to 10 bits can increase the security when reading out.
• Four tracks may be required for the 40 bits required.
• other storage volumes can also be achieved.
• the storage volume can be increased by reducing the reading speed or increasing the number of tracks.
• the required number of article numbers and / or LOT numbers can be permanently recorded during operation at maximum speed.
• one aspect can be the writing and reading of the tool with magnetic memory.
• the tool can have a magnetizable layer.
• the dimensions of the developed layer can be approximately 8 mm wide and approximately 7 mm, for example 7.44 mm, long / high.
• the magnetic layer can be written on four lanes with a binary code during production.
• Each track can contain 10 bits. This corresponds to a storage density of 1.34 bit / mm.
• Each track can contain less than or a maximum of 20 bits (or 15 bits or 10 bits). This is much less than with conventional tape devices, which can increase reading reliability.
• the track width can be 1 mm and the track spacing (center-center) 2 mm. These values also ensure a high level of reading reliability.
• the four Hall sensors can be integrated into the spacer sleeve of the handpiece. De ren axial distance can correspond exactly to the track width or the track spacing. To save space, the sensors can be arranged opposite one another and offset. For example, two Hall sensors are arranged axially along the sleeve on an inner jacket of the same. Furthermore, the respective other two Hall sensors can be arranged on an opposite inner side of the sleeve parallel to the respective two Hall sensors. Furthermore, the pairs of Hall sensors can also be arranged offset from one another along an inner circumferential direction in a range between 90 ° and 180 °, for example between 100 and 170 ° or 110 ° and 160 °.
• the Hall sensors arranged next to one another in the axial direction along the sleeve can form a pair.
• the pairs can read out tracks 1 and 3 or 2 and 4 if there are four adjacent tracks.
• a (shortest) distance between the magnetic layer arranged on the tool and the respective Hall sensors can be less than 0.1 mm, for example less than 0.05 mm.
• the distance can be greater than 10pm. This can apply when the tool or the corresponding part thereof has been taken up in the milling handpiece and the milling handpiece is ready for use or in operation.
• cutouts also referred to herein as cutouts
• cutouts can be provided in order to insert the corresponding Hall sensors therein. let and ßern the interior space for the part of the tool to be picked up or to adjust a distance between the Hall sensor (s) and the part of the tool to be picked up.
• the Hall sensors are arranged on an inner wall of the spacer sleeve, for example, there can be no distance between the part of the tool to be picked up and the Hall sensors.
• the breakouts in the side wall of the sleeve can help.
• the conductor tracks can be embedded on an outside (on the circumstanceman tel) of the sleeve.
• the spacer sleeve can also contain the interconnection of the individual components of the magnetic memory readout device on the inside (on the inner jacket) of the sleeve. These can be connected to the conductor tracks, also called signal lines here, on the outside via small bores.
• the Hall sensors used can have a size of approximately 0.95 x 1.4 x 3.04 mm (housing). This can be a standard SMD component.
• a capacitor with a capacitance of 10 nF, for example, can be provided. This can have the dimensions 0.5 x 0.5 x 1 mm.
• connection pins of the Hall sensors are slightly bent so that they do not exceed the outer diameter of the spacer sleeve. Due to their small size, the capacitors fit on the inside of the spacer sleeve, for example without cutouts.
• the capacitors are arranged / connected as close as possible to the respective Hall sensor. This can be done by positioning it on the inside. For example, a line section between the respective capacitor and Hall sensor can be less than 3 mm (or 2 mm or 1 mm).
• the capacitor can be connected between VCC and GND. This allows the supply voltage VCC to be reserved / smoothed.
• a method can be provided, in particular the assembly of the magnetic memory readout device.
• the assembly also called SMT (English for: surface mounted technique)
• the components of the Magnetic memory readout device SMD technology can be used.
• the components can be held in position by means of a device and then soldered in the oven or by means of hot air.
• the interior of the spacer sleeve can be cast or encapsulated.
• the adhesive core placeholder for the tool shaft
• the tool shank can be the part of the tool provided to be received in the sleeve, with or without the magnetic memory.
• the magnetic memory can be inserted or arranged in a recessA / recess of the part of the tool intended to be received in the sleeve such that the magnetic memory is aligned with the tool, ie its peripheral surface, or both circumferences are the same.
• Variants of the magnetic memory readout device can be:
• Variant 1 Tool with slide-on magnetic storage. For easier assembly, it can be advantageous to design the magnetic memory so that it can be pushed open.
• - Variant 2 Tool with wire magnetic storage.
• a magnetized wire can be used to achieve greater magnetization.
• Each wire ring can correspond to a track.
• the magnetized bits can be arranged distributed along the wire ring, for example at regular intervals.
• - Variant 3 Tool with miniature magnets in cylinder shape. An even stronger magnetization can be made possible with individual magnetized pieces of wire or with small permanent magnets. These are either pressed in or glued in. In the case of pieces of wire, all holes can be filled. The mag netization then takes place using a writing instrument.
• the writing instrument may be able to adapt / change the magnetization according to the information about the tool. With permanent magnets, only the holes are filled according to the "unit bits”. The remaining holes "zero bits" remain empty or are filled with the protective varnish.
• the software means can be associated with programmed microprocessors or a general computer, an ASIC (English: Application Specific Integrated Circuit; in German: application-specific integrated circuit) and / or DSPs (English: Digital Signal Processors; in German: digital signal processors).
• ASIC Application Specific Integrated Circuit
• DSP Digital Signal Processors
• the processing unit, the evaluation unit, the motor unit, the control unit, the writing instrument, the magnetic memory readout device and / or the surgical instrument itself can partly be used as a computer, a logic circuit, an FPGA (Field Programmable Gate Array). Gate arrangement), a processor (for example comprising a microprocessor, a microcontroller (pC) or a vector processor) / core (in German: main memory, can be integrated in the processor or used by the processor) / CPU (English: Central Processing Unit; in German: cent- real processor unit; several processor cores are possible), an FPU (English: Floating Point Unit; in German: Floating Point Processor Unit), an NPU (English: Numeric Processing Unit; in German: Numerical Processor Unit), an ALU (English: Arithmetic Logical Unit; zu German: arithmetic-logical unit), a coprocessor (additional microprocessor to support a main processor (CPU)), a GPGPU (English: General Purpose Computation on Graphics Processing
• a component is “connected” to another component or is “connected” to it, this can mean that it is directly connected to it; It should be noted here, however, that there may be another component in between. On the other hand, if it means that a component is "directly connected” to another component, it is to be understood that there are no further components in between.
• FIG. 1a shows a schematic representation of a surgical instrument
• FIG. 1 b shows a schematic representation of a tool in a first perspective
• FIG. 1c shows a schematic representation of a tool in a second perspective
• FIG. 2a shows a schematic representation of a first variant of a user interface with information
• FIG. 2b shows a schematic representation of a second variant of a user interface
• FIG. 2c shows a schematic representation of a third variant of a user interface
• FIG. 3 shows a schematic representation of a sleeve of a surgical instrument
• FIG. 4a shows a schematic representation of a tool with magnetic storage in a first perspective
• FIG. 4b shows a schematic representation of a tool with magnetic storage in a second perspective
• FIG. 4c shows a schematic representation of a tool with magnetic storage in a third perspective
• FIG. 5a shows a schematic representation of a surgical instrument with a tool in longitudinal section
• FIG. 5b shows a schematic representation of a sleeve of a surgical instrument with a tool in longitudinal section
• FIG. 5c shows a schematic representation of part of a sleeve of a surgical instrument with a received tool in a longitudinal section
• FIG. 6 shows a schematic representation of a cross section through a surgical instrument with a received tool
• FIG. 7 is a schematic representation of a magnetic tape
• FIG. 8 is a schematic representation of a table of magnetic memories with typical data
• FIG. 9 shows a schematic representation of a magnetic memory in conjunction with magnetometers within the sleeve of a surgical instrument
• FIG. 10a shows a schematic representation of a sleeve with recesses and signal lines in a first perspective
• FIG. 10b shows a schematic representation of a sleeve with recesses and signal lines in a second perspective
• FIG. 11a shows a schematic representation of a Hall sensor as an SMD component
• FIG. 11b shows a schematic representation of a capacitor as an SMD component
• FIG. 12 shows a schematic representation of a sleeve with Hall sensors and capacitors
• FIG. 13 shows a schematic representation of a longitudinal section of a sleeve with Hall sensors and capacitors
• FIG. 14 shows a schematic representation of a first variant of a tool with a magnetic storage device
• FIG. 15a shows a schematic representation of a second variant of a tool with magnetic storage in a first perspective
• FIG. 15b shows a schematic representation of a second variant of a tool with magnetic storage in a second perspective
• FIG. 15c shows a schematic representation of a second variant of a tool with magnetic storage in a third perspective
• FIG. 15d shows a schematic representation of a second variant of a tool with magnetic storage in a fourth perspective
• FIG. 16a shows a schematic representation of a third variant of a tool with magnetic storage in a first perspective
• FIG. 16b shows a schematic representation of a third variant of a tool with magnetic storage in a second perspective
• FIG. 16c shows a schematic representation of a third variant of a tool with magnetic storage in a third perspective
• FIG. 16d shows a schematic representation of a third variant of a tool with magnetic storage in a fourth perspective
• FIG. 16e shows a schematic representation of a third variant of a tool with magnetic storage in a fourth perspective
• FIG. 16f shows a schematic illustration of a third variant of a tool with magnetic storage in a fourth perspective
• FIG. 16g shows a schematic representation of a third variant of a tool with magnetic storage in a fourth perspective
• FIG. 17a shows a schematic representation of a fourth variant of a tool with magnetic storage in a first perspective
• FIG. 17b shows a schematic representation of a fourth variant of a tool with magnetic storage in a second perspective
• FIG. 17c shows a schematic representation of a fourth variant of a tool with magnetic storage in a third perspective.
• spatially relative terms such as “below”, “below”, “lower” / “lower”, “above”, “upper (r) 7" upper “,” left “,” left / left ”,“ right ”,“ right / right ”and the like, are used to simply describe the relationship of an element or structure to one or more other elements or structures shown in the figures are shown.
• the spatially relative terms are intended to include other orientations of the component in use or in operation in addition to the orientation shown in the figures.
• the component can be oriented differently (rotated 90 degrees or in a different orientation), and the spatially relative descriptors used here can also be interpreted accordingly.
• the basic principle of the present invention is based on the Hall effect, which occurs in an electrical conductor through which current flows (provided by a supply voltage Vcc and ground GND), which is located in a magnetic field, with an electrical field being built up that leads to the direction of the current and to the magnetic field is perpendicular and that compensates for the Lorentz force acting on the electrons.
• a magnetic memory readout device is provided in a sleeve 4 of a surgical instrument 1.
• a tool 2 is provided which has a magnetic storage layer 8 which forms a periphery of the tool 2 or is arranged around the tool shaft 16 which rotates during operation of the surgical instrument 1 through engagement with a motor unit of the surgical instrument 1 .
• the magnetic storage layer 8 has information about the type / type of tool 2 in the form of magnetization, similar to a tape.
• the magnetic storage layer 8 rotates in accordance with the rotation of the tool 2, the magnetic storage layer 8 is moved past the magnetic storage readout device, for example in the form of Hall sensors 12. Based on the Hall effect, a voltage in the form of a (voltage) signal is induced in the magnetic memory readout device due to the variable electric or magnetic field caused by the rotation of the magnetic memory layer 8. This process can also be referred to as reading out here.
• This voltage signal is then forwarded via signal lines 13 to an evaluation unit, which processes the information on which the voltage signal is based on the tool 2 and can finally make it accessible to the user of the surgical instrument 1 via a user interface.
• FIGS. 1b and 1c show a schematic representation of a surgical instrument 1 in the form of a milling handpiece for receiving a tool 2 shown in FIGS. 1b and 1c in two different perspectives.
• the present disclosure can serve the purpose of actuating the milling handpiece of an associated foot pedal (not shown) to recognize what type / type of tool 2 it is.
• the surgical instrument 1 and the tool 2 each have three essential sections.
• the surgical instrument 1 has a connecting section 1.1 for connecting the handpiece to the corresponding electronic devices such as the control unit and user interface, a motor unit 1 .2 to provide the drive for the corresponding tool, which is connected to the tool interface unit 1 .3 which also includes the sleeve used herein, in particular the spacer sleeve.
• the tool 2 here has a handle section 2.1, a shaft section 2.2 and at least one working end / effector 2.3.
• the handle section 2.1 of the tool 2 can be designed to interact with the tool interface unit 1.3 or the spacer sleeve in such a way that these two elements are connected in a form-fitting or force-fitting manner.
• FIGS. 1a, 1b and 1c can have one or more optional additional features that correspond to one or more aspects of the embodiments described in connection with the proposed concept or below with reference to FIGS. 2a-17c are mentioned.
• FIGS. 2a, 2b and 2c show different variants of a user interface which is used to provide the user with the corresponding information about the tool 2 used.
• These user interfaces can each be in communication with or connected to the surgical instrument 1 in a wireless or wired manner.
• this provides a tool identification which is passed on to peripheral devices such as the user interface by means of data transmission and which is displayed to the end customer, i.e. the user, selected data relating to the information read out by the magnetic memory readout device.
• peripheral devices such as the user interface by means of data transmission and which is displayed to the end customer, i.e. the user, selected data relating to the information read out by the magnetic memory readout device.
• further data can be logged and further processed.
• These data can already be present on a data carrier assigned to the user interface or can be updated.
• the data and information about the tool 2 mentioned herein can in particular be an article number, a lot number, a batch number, a best-before date, an expiration date or maximum use date, material, dimensions and geometries, intended use, previous uses and duration of use, stock levels, etc.
• the information read out can be presented to the user of the tool 2.
• data from the tool 2 can be stored from the information read out and / or forwarded to the provider of the tool 2 will.
• the processes mentioned preferably run automatically, so that the data can in particular be automatically displayed and / or forwarded and / or stored in a database.
• a user can thus safely, easily, quickly and, in particular, automatically receive information about which tool 2 he is currently using or intends to use and / or connected to the surgical instrument 1 when using a specific medical technical tool such as the surgical instrument 1 without having to look through a label or packaging.
• a user can automatically and easily recognize whether the surgical instrument 1 used is suitable or unsuitable for a relevant application by actuating it once.
• the user can easily determine which stocks of the relevant tool 2 are still in his warehouse (possibly consignment warehouse) without having to carry out an inventory for this purpose.
• the surgical instrument 1 thus offers direct, automated tool recognition both for a user and for a provider (supply chain management (SCM), service, error analysis). It also allows any amount of additional data to be transmitted to the user and / or the provider. Product-related data can also be automatically and promptly noted in a patient file.
• SCM supply chain management
• FIG. 2a, 2b and 2c can have one or more optional additional features that correspond to one or more aspects that are related to the proposed The same concept or one or more embodiments described above (e.g. FIG. 1) or below (e.g. FIGS. 3-17c) are mentioned.
• FIG. 3 shows a schematic representation of a sleeve 4 of a surgical instrument 1.
• the sleeve 4 has a receiving opening 6 for the tool 2, which can be pushed into the sleeve 4 from the left.
• the tool 2 can be pushed into the sleeve 4 up to a fastening device 7.
• the fastening device 7 forms at least part of the tool interface unit 1 .3 or is this.
• To the left of the fastening device 7 is a ball bearing 5.
• the magnetic storage readout device which is decisive for the present invention, is arranged in the sleeve.
• another ball bearing 3 is net angeord.
• the ball bearings 3 and 5 can also be roller bearings in general.
• the purpose of the two ball bearings on the left 3 and right 5 next to the section of the sleeve 4 with the Mag net shalllese founded is to fix the part of the tool 2 accommodated in the sleeve 4 that functions as an axis or shaft.
• the two ball bearings on the left 3 and right 5 can absorb radial and / or axial forces and at the same time enable the rotation of the axis / shaft of the part of the work 2 accommodated in the sleeve 4.
• the magnetic memory readout device is niaturized in such a way that the part of the tool 2 provided for receiving in the sleeve 2 is spaced apart.
• FIG. 3 may have one or more optional additional features that correspond to one or more aspects that are in connection with the proposed concept or one or more above (z. B. Fig. 1 - 2c) or below ( 4a-17c) described embodiments are mentioned.
• FIGS. 4a, 4b and 4c show different views of a tool 2 with a magnetic memory 8.
• the magnetic memory 8 surrounds the tool 2 shown in FIGS.
• a deepening with a pre- A certain width can be provided along the circumference into which the magnetic memory 8 can be fitted.
• this depression can be larger than 0.1 mm and smaller than 0.4 mm.
• the magnetic memory 8 can optionally be designed as follows.
• a magnetic layer carrier 11 can first be applied into the depression.
• An oxide layer 10 is then applied as a magnetic layer to this magnetic layer carrier 11.
• a protective lacquer 9 is applied to protect the magnetic layer 10.
• the layer thicknesses of these three layers 9, 10, 11 can vary here. The total layer thickness of all three layers can correspond to a depth of the recess in order to provide a substantially smooth surface of the tool 2.
• the functionality of the magnetic storage is independent of the material of the tool.
• the shaft of the tool 2 or the tool 2 itself can be made of ferromagnetic and non-ferromagnetic material.
• FIGS. 4a, 4b and 4c may have one or more optional additional features that correspond to one or more aspects that are related to the proposed concept or one or more of the above (e.g. FIGS. 3) or the embodiments described below (e.g. FIGS. 5a-17c) are mentioned.
• FIGS. 5a, 5b and 5c show a surgical instrument 1 with a tool 2 received therein.
• FIG. 5a shows a schematic representation of a surgical instrument 1 with tool 2 in longitudinal section.
• Figure 5b shows a schematic representation of a sleeve 4 of a surgical instrument 1 with tool 2 in longitudinal section.
• FIG. 5c shows a schematic representation of part of a sleeve 4 of a surgical instrument 1 with a received tool 2 in a longitudinal section.
• the magnetic memory 8 can interact with the magnetic memory readout device in such a way that information can be output to the user interfaces shown in FIGS. 2a, 2b and 2c by means of the magnetic memory readout device.
• the magnetic memory readout device has a plurality of Hall sensors 12.
• the Hall sensors 12 can form at least part of the magnetic memory readout device or can be identified as such.
• the Hall sensors 12 are offset from one another in such a way that they can read out a different track located on the magnetic memory 8 of the tool 2.
• the Hall sensors 12 only need a supply voltage Vcc.
• This supply voltage Vcc can be smoothed by capacitors 15 connected upstream.
• the capacitors 15 can also be part of the magnetic memory readout device or form them together with the Hall sensors 12.
• the magnetic memory 8 rotates in the direction of rotation. This rotation can be triggered via a foot pedal that is directly or indirectly connected to the surgical instrument. This creates a time-varying magnetic field corresponding to a magnetization on the Magnetspei cher 8.
• These magnetic field changes contain the information about the tool 2 and can be recorded or read out via the Hall sensors 12 in the form of voltage changes.
• These voltage changes can also be understood as voltage signals which contain the information about the tool 2 in the form of voltage states.
• a signal output of the Hall sensors 12 can each be connected to a signal line 13 of the sleeve 4 in such a way that a signal can be forwarded to a processing unit or evaluation unit externally or internally by the surgical instrument 1.
• One of the user interfaces can then be supplied with the necessary information about the tool 2 and thus communicated to the user of the surgical instrument 1.
• Fig. 5a, 5b and 5c Management may have one or more optional additional features that correspond to one or more aspects related to the proposed concept or one or more above (e.g., FIGS. 1 - 4c) or below (e.g., FIG 6-17c) are mentioned.
• FIG. 6 shows a schematic representation of a cross section through a surgical instrument 1 with a received tool 2.
• the surgical instrument 1 has a shaft tube 14 surrounding the sleeve 4.
• the signal lines 13 are housed or embedded in the sleeve 4 or in the shaft tube 14 with a first diameter 18.
• the first diameter 18 can be in a range from 5 to 6 mm, in particular approximately 5.6 mm. So that the signal lines 13 are not short-circuited, the sleeve 4 or the shaft tube 14 must be made of a non-conductive material, for example ceramic. So that the signal lines 13 get into the interior or the inner jacket of the sleeve 4, holes (not shown) are provided, which continue the signal lines 13 on the inner jacket of the sleeve 4.
• these signal lines 13 applied there are connected to the components of the magnetic memory readout device, in particular the capacitors 15 and the Hall sensors 12.
• This connection can be a solder connection on the inner jacket of the sleeve 4.
• two Hall sensors 12.1 and 12.2 are arranged on the left inner side of the sleeve 4 and two Hall sensors 12.3 and 12.4 are arranged on the right inner side of the sleeve 4.
• the capacitors 15 are in direct electrical connection with the Hallsenso Ren 12 and smooth the input signal of the supply voltage Vcc.
• the tool shank 16 of the tool 2 is arranged in the space between the components of the magnetic memory readout device.
• FIG. 6 thus shows the case during operation or shortly before operation.
• a diameter of the tool shank 16 can range from 2 to 3 mm, in particular about 2.37 mm.
• the Hall sensors 12 can be arranged in such a way that they do not protrude beyond an outer diameter of the sleeve 4.
• the individual signal lines 13 can have different functions and are not limited to the number six, as shown in FIG. At least one signal line 13 is provided for the supply voltage Vcc. If there is an increased power requirement, a plurality of signal lines 13 can also be provided for the supply voltage Vcc. In particular, this can also define the ground connection GND.
• a ground connection GND is also sufficient. If there are several signal lines 13 as the supply voltage Vcc, the requirement on signal lines 13 for the ground GND can also increase.
• four signal lines 13 are also shown as a communication line for each one of the Hall sensors 12. Thus, for example, at least three signal lines 13 can be present in the sleeve 4 in order to ensure the function of the Hall sensor 12, in particular power supply and communication. If further Hall sensors 12 are present, the number of signal lines 13 can increase proportionally.
• FIG. 6 may have one or more optional additional features that correspond to one or more aspects that may be used in connection with the proposed concept or one or more above (e.g. FIGS. 1-5c) or below ( 7-17c) described embodiments are mentioned.
• FIG. 7 shows a schematic representation of a magnetic tape.
• This example is a 7-track magnetic tape with an alphanumeric 6-bit code, which has a parity bit 19 for checking, two zone bits 20 and four numeric bits 21.
• a magnetic tape can be attached along the circumference of the tool 2 to function as a magnetic memory 8 in bit alignment according to the 6-bit code.
• DIN standards for example DIN 66010, 66011, 66013, for example, can be used for this.
• the embodiment may have one or more optional additional features that correspond to one or more aspects related to the proposed concept or one or more above (e.g., FIGS. 1-6) or below (e.g., FIGS 9-17c) are mentioned.
• FIG. 9 shows a schematic representation of a magnetic memory 8 in conjunction with magnetometers in the form of Hall sensors 12.1, 12.2, 12.3, 12.4 within the sleeve 4 of a surgical instrument 1.
• the magnetic memory 8 is shown here exemp larisch rolled out flat. Specifically, the number of bits is indicated from bottom to top (i.e. along the circumference of tool 2 when in use).
• a track for one of the Hall sensors 12 is arranged in such a way that it rotates directly past the corresponding Hall sensor 12 during operation.
• the individual tracks are shown by way of example by means of arrows. In this example, each track contains 10 bits.
• the adjacent tracks (from left to right) have a center-to-center distance that corresponds to the center-to-center distance of the Hall sensors 12 provided for these tracks (opposite one another).
• the center-to-center distance can be at least twice a track width or at least double a track width.
• the center-to-center distance of Hall sensors 12 lying next to one another in the axial direction can correspond to at least four times a track width.
• the number of tracks here also corresponds to the number of Hall sensors 12 used.
• one of the Hall sensors 12 can be provided precisely for one of the tracks on the magnetic memory 8.
• adjacent tracks are not read by adjacent Hall sensors 12.1, 12.2 or Hall sensors 12.3, 12.4 due to space, but rather by opposing Hall sensors 12.1, 12.3 or 12.2, 12.4.
• the Hall sensors 12 do not necessarily have to be located directly opposite one another on the inner circumferential surface of the sleeve 4, but they must be arranged offset to one another along the inner circumferential direction of the sleeve 4.
• Hall sensors 12 that are not next to one another in the axial direction can be arranged offset in the inner circumferential direction of the sleeve 4.
• 12.2; 12.3, 12.4 be arranged offset to one another in the inner circumferential direction of the sleeve 4.
• the pairs can, for example, directly opposite on an inner lateral surface of the Sleeve 4 can be arranged.
• the Hall sensors 12 of the respective pairs of Hall sensors (12.1, 12.2; 12.3, 12.4) can be arranged one behind the other or next to one another in the axial direction of the sleeve 4.
• FIG. 9 may have one or more optional additional features that correspond to one or more aspects related to the proposed concept or one or more above (e.g. FIGS. 1-8) or below (e.g., FIGS. 10a-17c) are mentioned.
• FIG. 10a shows a schematic representation of a sleeve 4 with recesses 22 and signal lines 13 in a first perspective.
• the same sleeve 4 is shown in a different perspective in Figure 10b.
• the recesses 22 are holes in the sleeve 4 or in the side wall of the sleeve 4. There are therefore holes as Aussparun gene 22 so that the Hall sensors 12 can be attached easily. The holes are made so large that a main body of the respective Hall sensors fits into them. Directly next to or at the holes are pins for connecting the Hall sensor 12 to the signal lines 13. These pins are introduced into further recesses 23 on an outer jacket of the sleeve 4. These are not designed as holes. This is because the recesses 23 are used for electrical connection to the signal lines 13. This also means a mechanical connection, for example in the form of a solder, which connects the respective Hall sensors 12 electrically and mechanically to the pins in the recesses 23.
• the signal lines 13 lead from the pins of the recesses 23 via bores to an inner surface of the sleeve 4. There, the signal lines 13 run in the axial direction of the sleeve 4 along the inner surface and in the inner circumferential direction of the sleeve 4. The signal lines 13 also lead via further bores to the channel-shaped signal lines 13, as shown in Figure 10b. These run only along one axial direction of the sleeve 4, so that communication between the surgical instrument 1 and a peripheral device, for example the evaluation unit or the user interface, is provided via the sleeve 4. Further details and aspects are mentioned in connection with the embodiments described above or below. The embodiment shown in FIGS. 10a and 10b may have one or more optional additional features that correspond to one or more aspects related to the proposed concept or one or more above (e.g. FIGS. 1-9 ) or embodiments described below (e.g. FIGS. 11a-17c) are mentioned.
• FIG. 11a shows a schematic representation of a Hall sensor 12 as an SMD component.
• the Hall sensor 12 has three connections, a connection for the voltage supply Vcc, a connection for the ground GND and a voltage signal output. These can optionally be provided on the Hall sensor 12 or preset.
• the Hall sensor 12 can be brought into engagement with the pins of the recess 23 by means of the connections.
• the connections can be bent accordingly, so that a force fit with the recesses 23 or with the pins of the recesses 23 is created. Solder can also be applied here to ensure the electrical and mechanical connection.
• a capacitor 15 is used in conjunction with the Hall sensor 12. This is shown in Figure 11b as an SMD component.
• the Kon capacitor 15 has exactly two connections and has no preferred direction. The capacitor 15 can thus be attached or soldered to signal lines 23 running on the inner lateral surface.
• the size, for example the height, of the capacitor 15 is smaller than the size of the Hall sensor 12, for example at least less than a wall thickness of the slee
• FIG. 12 shows a sleeve 4 with Hall sensors 12 and capacitors 15 attached to it with the associated signal lines 13.
• the sleeve is also shown in longitudinal section with components 12 and 15 in FIG. So that the components 12, 15 remain in their position, the soldering can be carried out on the one hand in an oven or by means of hot air.
• the interior of the sleeve 4 can be potted with a non-conductive material.
• a dummy tool can be used as a spacer for the actual tool 2 so that the space for this remains free during casting. This allows the service life of the components 12, 15 to be increased.
• the dummy tool can have a larger circumference than the tool shank of the tool stuff 2. This difference can be in a range from 2% up to 25%. Preferably in the range from 10% to 20%
• FIGS. 11a, 11b, 12 and 13 may have one or more optional additional features that correspond to one or more aspects related to the proposed concept or one or more of the above (e.g. FIG. 1 - 12) or embodiments described below (e.g. FIGS. 14-17c) are mentioned.
• FIGS. 14 to 17c show different embodiments of the tool 2 with a magnetic storage device 8.
• FIG. 14 shows a schematic representation of a first variant of a tool 2 with a magnetic storage device 8.
• the magnetic storage device 8 can be detachably connected to the tool 2, in the form of a magnetic storage sleeve 81.
• the tool 2 and the magnetic storage device 8 can be delivered separately.
• the Mag net organizer 8 can be viewed as part of the tool 2.
• the tool 2 can be adapted in such a way that a part of the tool 2 provided for the magnetic memory 8 has a circumference correspondingly reduced to the thickness of the magnetic memory 8 or its jacket thickness.
• an inner jacket diameter of the magnetic memory 8 can correspond approximately to a diameter of the part of the tool 2 seen for the magnetic memory 8.
• FIG. 14 may have one or more optional additional features that correspond to one or more aspects related to the proposed concept or one or more above (e.g., FIGS. 1-13) or below ( e.g., FIGS. 15a-17c) are mentioned.
• FIG. 15a, 15b and 15c show different views of a second variant of a tool 2 with a magnetic memory 8.
• FIG. 15d shows a schematic representation of the magnetic memory 8 as provided in the second variant.
• a plurality of magnetized wire rings 82 can be arranged next to one another at a predetermined distance in the axial direction of the tool 2. The distance can correspond to the center-to-center distance defined above.
• the wire rings 82 can be cast or encapsulated in a plastic 11 which at least partially covers the wire rings.
• the plastic 11 can be poured into a recess in such a way that the plastic 11 is flush with the tool 2.
• Figs. 15a, 15b, 15c and 15d may have one or more optional additional features that correspond to one or more aspects related to the proposed concept or one or more of the above (e.g. Fig 1-14) or embodiments described below (e.g. FIGS. 16a-17c) are mentioned.
• FIGS. 16a to 16g show schematic representations of a third variant of a tool 2 with a magnetic memory 8.
• the magnetic memory 8 is provided in the form of small permanent magnets as a permanent magnet arrangement 83 or can have pieces of wire that can be written on.
• the permanent magnets can be arranged differently along a circumferential direction of the magnetic storage device 8, see FIGS. 16d to 16g, for example included or not included (according to the bit pattern provided for the information about the tool 2).
• the pieces of wire these can be written on or not written on, that is to say magnetized or not magnetized. In this way, the information about the tool can be integrated into the magnetic memory 8.
• FIGS. 16a-16g may have one or more optional additional features that correspond to one or more aspects related to the proposed concept or one or more above (e.g., FIGS. 1-15d ) or the embodiments described below (e.g. FIGS. 17a-17c) are mentioned.
• FIGS. 17a, 17b and 17c show schematic representations of a fourth variant of a tool 2 with a magnetic storage device 8.
• the magnetic storage device 8 has a particular one Arrangement of spherical magnets 84.
• the magnets can be attached to the tool 2 or to the tool 2 at predetermined positions.
• the bit pattern is obtained by writing with a writing device, which magnetizes the spherical magnets 84 in accordance with the bit pattern provided for the information about the tool 2.

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• 2020
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