JP4870989B2 - WORKING TOOL AND WORKING TOOL DATA RECORDING DEVICE - Google Patents

Description

  The present invention relates to a surgical tool such as a scalpel or forceps equipped with a data carrier capable of recording data, a working tool such as a tool such as pliers and a spanner, and a data recording device for the working tool.

If data such as surgical tools such as scalpels and forceps, tools such as pliers, spanners, etc. are retained, data such as manufacturer name, model number, date of manufacture, serial number, etc., can be used at the time of shipment, sale, storage, etc. It is convenient for checking the number of tools and sorting and sorting.
In addition, for surgical tools such as scalpels and forceps, check that the specified type and number of tools have been prepared correctly before surgery, and that all tools have been correctly collected after surgery. In addition to the above-mentioned data, it is convenient for confirmation work if each tool holds recognition data such as individual IDs.

  Conventionally, as a method of holding data in a work tool, data consisting of letters, numbers, symbols, etc. is printed or stamped on a label or nameplate, and this is pasted directly on the work tool or pasted on its packing material. (See Patent Document 1).

JP 2004-54553 A

However, if a label or nameplate printed or engraved with data consisting of letters, numbers, symbols, etc. is affixed to the work tool, the label or nameplate may be damaged or dropped during transportation or work, resulting in data loss. There was a problem that it could not be read.
In addition, it takes time and effort to print or engrave data consisting of letters, numbers, symbols, etc. on labels and nameplates, and there is also a problem that reading errors occur because people read the data visually.

In particular, surgical tools such as scalpels and forceps are required to strictly manage before and after surgery whether they are disinfected, available in number, or prohibited from being used.
Therefore, in order to prevent erroneous reading of data visually, recently, a method in which a two-dimensional bar code is imprinted on a surgical instrument and data is automatically read by a reading device has been adopted.

However, in the method of imprinting a two-dimensional bar code, if blood or the like adheres to the surface, it cannot be read, or the tool made of stainless steel has a low hardness, so the imprint is worn out and disappears in a relatively short period of time. Since the reading direction is limited to one direction, it is necessary to read the surgical tools one by one, which takes time.
Moreover, since it is necessary to hold the surgical tool and align the direction during the reading operation, the operator is exposed to the risk of touching the blood and being infected with hepatitis.

In addition, a method of attaching the RFID data carrier to a work tool and managing it has also been studied, but if there is a metal in the vicinity, it is difficult for electromagnetic waves to read and write to the RFID data carrier to reach, and the RFID data carrier does not function, Since an ordinary RFID data carrier is covered with a synthetic resin exterior material and easily damaged when subjected to an impact from the outside, it is difficult to put a working tool to which the RFID data carrier is attached into practical use.
Furthermore, it is necessary to sterilize surgical tools. During this sterilization operation, tools are exposed to high temperatures and chemicals, but RFID data carriers covered with a synthetic resin outer packaging are heat and chemical resistant. There was a problem with the property, and it could not be used for such applications.

The present invention has been made in view of such conventional problems. The object of the present invention is to prevent the data carrier from being damaged or dropped during transportation, work, etc. The data carrier is not damaged even if it is exposed to the data, it is easy to write the data to the data carrier, the data can be read reliably and quickly, and the operator is exposed to dangers such as infection The object is to provide a working tool that is not necessary.
Another object of the present invention is to provide a working tool that can be easily mounted with a data carrier later without any special processing of the working tool.

  Furthermore, it is an object of the present invention to provide a data recording apparatus for a work tool that can write and read data on a data carrier mounted on the work tool.

In order to achieve the above-described object, the working tool of the present invention includes an IC chip mounting body in which an IC chip is joined to a coil antenna and integrated with each other inside upper and lower ceramic exterior materials configured to be fitted to each other. The IC chip mounting body is attached to the upper and lower ceramics by attaching and adhering a ceramic filler to the contact surfaces of the upper and lower ceramic exterior materials, and fitting and bonding the upper and lower ceramic exterior materials together. An RFID data carrier formed by covering with a ceramic exterior material is fitted and mounted in a mounting hole formed in a work tool.

  Moreover, it is preferable to form a notch groove from the mounting hole to the outer periphery of the work tool. Thereby, when a radio wave is received, no short-circuit current is generated in the metal material, and data recorded on the RFID data carrier can be reliably read.

  The front and back surfaces of the RFID data carrier are preferably positioned flush with the front and back surfaces of the work tool or inside the front and back surfaces. Thus, even if another object collides with the work tool during transportation, work, or storage, the data carrier is not damaged or dropped out.

  Further, it is preferable that the axial direction of the coil antenna of the RFID data carrier is set substantially perpendicular to the surface of the work tool. As a result, electromagnetic wave communication between the work tool and the RFID device can be performed with high sensitivity.

  Further, when the mounting hole cannot be originally drilled in the work tool, when the RFID data carrier is mounted on the existing work tool, the RFID data carrier may be stored in the holding member and fixed to the work tool. Here, the holding member is preferably made of a heat resistant material. As a result, the RFID data carrier can be easily and reliably attached to the work tool.

  The working tool of the present invention is particularly preferably applied to surgical tools such as a scalpel and forceps.

  A data recording device for a work tool according to the present invention includes the work tool and an RFID device including an antenna, a controller, and a computer, and writes data to an RFID data carrier attached to the work tool by wireless communication. It is characterized by reading.

DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of a work tool equipped with an RFID data carrier of the invention will be described with reference to the drawings.
FIG. 1 is a front view of an embodiment of the working tool of the present invention, FIG. 2 is a plan view of an RFID data carrier, (B) is a side sectional view, and FIG. 3 is a component of the RFID data carrier. (A) is a plan view of the lower exterior material, (B) is a side cross-sectional view in a state where each member is separated, (C) is a plan view of the IC chip mounting body, FIG. 4 and FIG. FIG. 6 is a front view of another embodiment of the working tool of the present invention, FIG. 6A is a plan view of the RFID data carrier, FIG. 7B is a cross-sectional view taken along the line AA in a state where each member is separated, and FIG. FIG. 8 is a front view of another embodiment of the working tool of the present invention, FIG. 8A is a plan view of one embodiment of the holding member, and FIG. 8B is a side sectional view of a state in which the pressing portion is opened. ) Is a side sectional view in a state in which the pressing portion is closed, FIG. 9 is a side sectional view in a state where (A) is a plan view, and (B) is a state in which the divided body is separated, C) is a side cross-sectional view showing a state in which the divided bodies are in close contact, FIG. 10 is a side cross-sectional view in which each member is separated, and FIG. FIG. 4C is an enlarged side sectional view of a portion A in a state in which the protrusion is crushed, and FIG.

The working tool shown in FIG. 1 is a scalpel 1 that is a surgical tool, and the scalpel 1 includes a blade-like portion 2 and a grip portion 3.
A mounting hole 3 a is formed in the intermediate portion of the grip portion 3, and a narrow notch groove 3 b is formed from the mounting hole 3 a to the outer peripheral surface of the grip portion 3.

  Then, the RFID data carrier 51 is press-fitted into the mounting hole 3a from the surface side of the gripping part 3 of the knife 1 and is fitted into the mounting hole 3a, whereby the RFID data carrier 51 is placed in the middle part of the gripping part 3 of the knife 1. It is attached.

  In the present invention, as an RFID (Radio Frequency Identification) data carrier, an RFID data carrier 51 in which an ultra-small IC chip and an antenna for wireless communication are integrated and covered with a ceramic exterior material is used.

  As shown in FIGS. 2 and 3, the RFID data carrier 51 includes an IC chip mounting body 52 in which a coil antenna 53 formed by winding a conductive metal wire and an IC chip 54 are joined and integrated. And ceramic exterior materials 55 and 56 and a ceramic filler 57.

The coil antenna 53 is formed by winding a conductive metal wire such as copper, aluminum, silver or the like in a coil shape.
As a result, the projection area is reduced as compared with the IC chip mounting body in which the coil antenna and the IC chip are arranged on the synthetic resin sheet, and the coil antenna 53 and the IC chip 54 are integrated to hold the shape. be able to.
Also, the RFID data carrier 51 using the coil antenna 53 has higher coil inductance accuracy, accurate tuning frequency, and lower coil electrical resistance than a general RFID data carrier using a synthetic resin sheet. Since it is low, the efficiency of the antenna circuit is high and the heat-resistant temperature is high.

The ceramic exterior materials 55 and 56 are obtained by firing a ceramic material such as alumina (Al ₂ O ₃ ), zirconia (ZrO ₂ · SiO ₂ ), silicon nitride (Si ₃ N ₄ ), and the like as shown in FIG. In addition, the upper and lower exterior materials 55 and 56 are adapted to be fitted to each other. The lower exterior material 55 is formed with a depressed portion 55a for accommodating the IC chip mounting body 52, and the upper exterior material 56 is provided with a protruding portion 56a fitted to the depressed portion 55a. It is formed.

As the ceramic filler 57, a ceramic cement material such as alumina cement or Portland cement is used.
As a result, the ceramic exterior members 55 and 56 are securely bonded to each other, and the IC chip mounting body 52 in which the coil antenna 53 and the IC chip 54 are joined and integrated is surely contained in the ceramic exterior members 55 and 56. Can be fixed.
Further, since the heat capacity becomes larger than that of the IC chip 54 alone by enclosing the IC chip mounting body 52 with the ceramic filler 57, the temperature rise with respect to the applied heat amount is suppressed and becomes uniform. An effect is obtained. Thereby, the heat resistance of the IC chip mounting body 52 can be improved.

  The RFID data carrier 51 is configured as described above, and is manufactured as follows.

  First, as shown in FIG. 3C, an IC chip 54 is joined to both ends of a coil antenna 53 in which a metal wire is wound in a coil shape, and the coil antenna 53 and the IC chip 54 are joined and integrated. The IC chip mounting body 52 is configured.

  Next, as shown in FIG. 3B, the IC chip mounting body 52 in which the coil antenna 53 and the IC chip 54 are joined and integrated is positioned in the depressed portion 55 a of the lower ceramic exterior material 55.

  On the other hand, the ceramic filler 57 is sufficiently applied and adhered to the entire lower surface of the upper ceramic exterior material 56.

  Next, the ceramic exterior material 56 is placed from above, and the projecting portion 56a of the ceramic exterior material 56 is fitted into the depressed portion 55a of the ceramic exterior material 55 as shown in FIG. The RFID data carrier 51 is configured by combining them.

As shown in FIG. 11, by performing wireless communication between the RFID data carrier 51 and the RFID device 71, data recorded on the RFID data carrier 51 can be read by the RFID device 71. Can be transmitted and written to the RFID data carrier 51.
Therefore, if the RFID data carrier 51 is attached to the work tool, various data such as a manufacturer name, a model number, a manufacturing date, a manufacturing number, etc., and an individual ID code for identifying each tool as necessary are provided. Etc. can be held together, and the data can be read or written as appropriate.

However, if a conductive material such as a metal material is present around the RFID data carrier 51, a short-circuit current is generated in the conductive material when an electromagnetic wave is received. Therefore, a necessary and sufficient electric field is not supplied to the RFID data carrier 51. It is said that data recorded on the RFID data carrier 51 cannot be read, and an on- metal (registered trademark) RFID data carrier and an in-metal (registered trademark) RFID data carrier have been developed as countermeasures.
However, on metal (registered trademark) RFID data carrier and in metal (registered trademark) RFID data carrier are limited to reading data from only one side. Is used only when it can be from one side.

For surgical tools such as scalpels and forceps, and tools such as tools such as pliers and spanners, reading and writing data is limited to one side. It cannot be read and is not practical.
Therefore, it is preferable to attach the RFID data carrier 51 to a working tool such as a surgical tool or a tool so that data can be read and written from both sides.

Therefore, in the work tool of the present invention, as shown in FIG. 1, the mounting hole 3 a is formed in the intermediate portion of the grip portion 3, and the narrow notch groove 3 b is formed from the mounting hole 3 a to the outer periphery of the grip portion 3. The RFID data carrier 51 is fitted in the mounting hole 3a.
By forming the cutout groove 3b, a short-circuit current is not generated in the metal material when electromagnetic waves are received, the data recorded on the RFID data carrier 51 can be read reliably, and the mounting hole 3a is formed. Thus, data can be read and written from both sides.
The cutout groove 3b may have any shape as long as it is formed from the mounting hole 3a to the outer periphery of the grip portion 3. If the notch groove 3b is filled with an adhesive or the like, the mechanical strength in the vicinity of the notch groove 3b can be increased.
Further, as shown in FIG. 1, the notch groove 3 b is preferably formed over the outer peripheral surface of the grip portion 3 on the opposite side to the cutting edge of the blade portion 2. With such a configuration, when the human body or the like is cut by the knife 1, a force acts in the direction in which the cutout groove 3b is closed, so that the RFID data carrier 51 is not easily detached from the mounting hole 3a.

In the RFID data carrier 51, the axial direction A of the coil antenna 53 is the direction having the best sensitivity to communication electromagnetic waves, that is, the antenna directing direction.
Therefore, when the RFID data carrier 51 is fitted into the mounting hole 3 a, the axial direction A of the coil antenna 53 is set substantially perpendicular to the front and back surfaces of the grip portion 3.
As a result, electromagnetic waves can be exchanged with high sensitivity between the knife 1 and the RFID device 61 disposed away from the knife 1.

When the RFID data carrier 51 is fitted into the mounting hole 3a, the front and back surfaces of the RFID data carrier 51 are positioned flush with the front and back surfaces of the grip portion 3 or inside the front and back surfaces.
As a result, the RFID data carrier 51 is not damaged or dropped out even if another object collides with the work tool during transportation, work or storage.

In order to write data to or read data from the RFID data carrier 51, an RFID device 71 as shown in FIG. 11 is used.
The RFID device 71 includes an antenna 72, a controller 73, and a computer 74, and communicates data and the like with the RFID data carrier 51 by an electromagnetic induction method.

  The controller 73 is connected to the antenna 72 and the computer 74 via a cable, and outputs a command to be transmitted to the RFID data carrier 51, for example, a data write command, a data read command, etc., to the antenna 72 according to an instruction from the computer 74. To do. In addition, data from the RFID data carrier 51 received by the antenna 72 is input.

Wireless communication is performed between the antenna 72 of the RFID device 71 and the coil antenna 53 of the RFID data carrier 51.
That is, the RFID apparatus 71 transmits power to be supplied to the RFID data carrier 51, data for writing, and other commands, and the RFID data carrier 51 transmits read data and other response signals.

As a frequency of the communication electromagnetic wave, a frequency can be appropriately selected from a long wave frequency to a short wave frequency suitable for the electromagnetic induction method according to a depth from the surface of the work tool to the surface of the RFID data carrier 51. In this example, a frequency of 13.56 MHz was used.
Then, when the communication state is confirmed by changing the distance between the antenna 72 of the RFID device 61 and the RFID data carrier 51, when the distance is 10 cm or less, data writing and reading can be performed reliably and with good workability. did it.
Note that the frequency of the communication electromagnetic wave is not limited to 13.56 MHz in this embodiment, and can be appropriately selected according to the application.

As described above, data such as a manufacturer name, a model, a manufacturing date, and a manufacturing number can be written in the RFID data carrier 51 before the female 1 is shipped.
Before the operation, the antenna 72 of the RFID device 71 is directed to the loaded knife 1 to read the data written on the RFID data carrier 51 to confirm that the knife 1 is as specified. it can.
In addition, if it is found that the patient has been infected with Jacob's disease etc. after the operation, it is possible to promptly treat the patient who has been operated with the tool used on the patient, and at the same time, the tool is banned in the database. If you do so, you can ban these tools later.

Furthermore, additional data can be written to the RFID data carrier 51, partially rewritten, or erased as necessary.
For example, when surgical tools are managed in a hospital, it is convenient to perform confirmation work if additional recognition data such as individual IDs for identifying each tool is additionally held.

The working tool shown in FIG. 4 is a forceps 11 that is a surgical tool, and the forceps 11 includes a clamping part 12, a hook-like part 13, and a gripping part 14.
Further, a bulging portion 15 is formed inside the gripping portion 14, a mounting hole 15 a is formed in the bulging portion 15, and a narrow notch groove 15 b is formed from the mounting hole 15 a to the outer periphery of the bulging portion 15. It is formed.

  Then, the RFID data carrier 51 is attached to the grasping portion 14 of the forceps 11 by press-fitting the RFID data carrier 51 into the attachment hole 15a from the surface side of the grasping portion 14 of the forceps 11 and fitting into the attachment hole 15a. is there.

  As described above, the notch 15b functions to prevent a short-circuit current from being generated in the metal material when receiving electromagnetic waves, and changes in pressure due to thermal expansion and contraction during the molding of the metal material, or when a working tool is used. It also has the effect of absorbing the pressure change due to the pressing force in the, and prevents the RFID data carrier 51 from being damaged.

  As a wireless communication method between the RFID device 71 and the RFID data carrier 51, an electromagnetic coupling method, an optical communication method, and the like can be applied in addition to the above-described electromagnetic induction method. When the data carrier 51 is mounted, an electromagnetic coupling method that allows electromagnetic waves to pass therethrough is suitable.

  The directivity directions of the antenna 72 of the RFID device 71 and the coil antenna 53 of the RFID data carrier 51 are preferably matched to each other. However, since the directivity direction has an appropriate tolerance depending on the frequency used, the mounting state of the RFID data carrier 51 May be within the allowable range.

  The working tool shown in FIG. 5 is a forceps 21 that is a surgical tool, and the forceps 21 includes a sandwiching part 22, a hook-like part 23, and a gripping part 24. The RFID data carrier 61 is fixed.

Similar to the RFID data carrier 51 shown in FIGS. 2 and 3, the RFID data carrier 61 is formed by joining and integrating a coil antenna 53 formed by winding a conductive metal wire and an IC chip 54. The IC chip mounting body 52, the ceramic exterior materials 62 and 63, and the ceramic filler 57 are formed, but the ceramic exterior materials 62 and 63 are different in form.
As shown in FIG. 6, the ceramic exterior material 62 has a depressed portion 62a formed at the center thereof, and has an insertion hole 62c formed in the base end portion 62b. The fitting portion 62a is adapted to be fitted.

First, as shown in FIG. 6, the IC chip mounting body 52 is positioned in the recessed portion 62a of the ceramic exterior material 62, the ceramic exterior material 63 is fitted into the recessed portion 62a, and the ceramic exterior materials 62, 63 are placed. Are completely coupled to form the RFID data carrier 61.
Next, as shown in FIG. 5, the base end portion 62b of the RFID data carrier 61 is brought into contact with an appropriate portion not interfering with the work, such as the grip portion 24 of the forceps 21, and a machine screw 64 is inserted into the insertion hole 62c. The RFID data carrier 61 can be attached to the gripping portion 24 of the forceps 21 by being inserted and screwed into and fixed to a screw hole 24a previously formed in the gripping portion 24 of the forceps 21.

According to such a configuration, the work tool such as the forceps 21 does not need to have a special shape from the beginning, and the RFID data carrier 61 can be easily attached later by performing some processing on the ready-made work tool. Can do.
Further, the RFID data carrier 61 can be held at an appropriate distance from the work tool having conductivity, and can be set to a position where the RFID data carrier 61 is effectively irradiated with electromagnetic waves from the front and back.
Furthermore, when the work tool is discarded, if the RFID data carrier 61 is removed and collected from the work tool, the RFID data carrier 61 can be reused, and the cost can be reduced.

Instead of the RFID data carrier 61, a holding member 31 as shown in FIG. 7 may be used. As shown in FIGS. 7 and 8, the holding member 31 is formed by connecting the pressing portions 32 and 33 of the two front and back bodies by a tubular portion 34.
The pressing portions 32 and 33 have window holes 32a and 33a formed in the center thereof, and narrow cutout grooves 32b and 33b are formed from the window holes 32a and 33a to the outer periphery, and screw holes 32c are formed at appropriate positions. , 33c. The inner diameters of the window holes 32 a and 33 a are slightly smaller than the outer diameter of the RFID data carrier 51.
In addition, it is preferable to shape | mold the holding member 31 from the heat resistant material which can endure also at the time of a high temperature sterilization process, and it is preferable to shape | mold especially from stainless steel etc. with high rust prevention property.

First, as shown in FIG. 8B, the pressing portions 32 and 33 are separated from each other and opened, and as shown in FIG. 7, the tubular portion 34 is obstructed by the work such as the grip portion 24 of the forceps 21. It is placed in an appropriate part where it does not become, and is pinched.
Next, as shown in FIG. 8C, the RFID data carrier 51 is disposed inside the pressing portions 32 and 33, the pressing portions 32 and 33 are brought into close contact with each other, and then the machine screw 35 is screwed. The RFID data carrier 51 can be mounted on the gripping portion 24 of the forceps 21 and the like by fixing the holding member 31 firmly by screwing the holes 32c and 33c into the pressing portions 32 and 33.

According to such a configuration, the work tool such as the forceps 21 does not need to have a special form from the beginning, and the ready-made work tool is not specially processed, and the RFID data carrier 51 can be easily attached later. be able to.
Further, since the RFID data carrier 51 is accommodated in the holding member 31, the RFID data carrier 51 can be sufficiently protected from mechanical shock.
Furthermore, when discarding the work tool, the holding member 31 can be removed from the work tool and the RFID data carrier 51 can be collected. Therefore, the collected holding member 31 and the RFID data carrier 51 can be reused, and the cost can be reduced. Can be reduced.

Instead of the holding member 31, a holding member 36 as shown in FIG. 9 may be used. As shown in FIG. 9, the holding member 36 includes two divided bodies 37 and 37, and the divided body 37 includes a pressing portion 38 and an arc portion 39.
The pressing portion 38 has a window hole 38a formed at the center thereof, a narrow notch groove 38b is formed from the window hole 38a to the outer periphery, and a screw hole 38c is formed at an appropriate position. The inner diameter of the window hole 38a is slightly smaller than the outer diameter of the RFID data carrier 51.
The holding member 36 is also preferably formed from a heat-resistant material that can withstand even during high-temperature sterilization treatment, and particularly preferably formed from stainless steel or the like having high rust prevention properties.

First, as shown in FIG. 9B, the pressing portions 38, 38 of the divided bodies 37, 37 are separated from each other and opened, and the RFID data carrier 51 is arranged at the position of the pressing portions 38, 38.
Next, as shown in FIG. 9C, the arc portions 39, 39 are positioned at appropriate portions such as the gripping portion 24 of the forceps 21 that do not interfere with the work, and are held between the pressing portions 38, 38. Are closely attached to each other and closed, and then the pressing portion 38, 38 is firmly attached by screwing the small screw 35 into the screw holes 38c, 38c, and the holding member 41 is fixed. For example, the RFID data carrier 51 can be mounted.

  Even with such a configuration, the RFID data carrier 51 can be easily mounted later, similarly to the holding member 31, and the RFID data carrier 51 can be sufficiently protected from mechanical shock, and the collected holding member 36 can be protected. In addition, the RFID data carrier 51 can be reused, and the cost can be reduced.

Instead of the holding member 31, a holding member 41 as shown in FIG. As shown in FIG. 10, the holding member 41 includes an installation body 42 and a grip body 43, and the installation body 42 includes a placement portion 44 and an arc portion 45.
The mounting portion 44 has a depressed portion 44a formed at the center thereof, and three protruding portions 44b are formed around the depressed portion 44a. In addition, a window hole 44c is formed at the center thereof, and a narrow notch groove 44d is formed from the window hole 44c to the outer periphery. Furthermore, screw holes 44e are formed at appropriate positions. The inner diameter of the window hole 44c is slightly smaller than the outer diameter of the RFID data carrier 51. On the other hand, screw holes 43 a are also formed at appropriate positions of the gripping body 43.
The holding member 41 is also preferably formed from a heat-resistant material that can withstand high-temperature sterilization treatment, and particularly preferably formed from stainless steel or the like having high rust prevention properties.

First, as shown in FIG. 10 (A), the installation body 42 and the gripping body 43 are separated from each other, and the RFID data carrier 51 is placed in the depressed portion 44a, as shown in FIGS. 10 (B) and 10 (C). The protrusion 44b is crushed by a press or the like so that the RFID data carrier 51 cannot be escaped.
Next, as shown in FIG. 10 (D), the circular arc portion 45 and the gripping body 43 are positioned and held at an appropriate place such as the gripping portion 24 of the forceps 21 that does not interfere with the work, and the small screw 35 is attached. If the installation body 42 and the gripping body 43 are firmly brought into close contact with each other by screwing into the screw holes 43a and 44e and the holding member 41 is fixed, the RFID data carrier 51 can be mounted on the gripping portion 24 of the forceps 21 or the like. .

  Even with such a configuration, the RFID data carrier 51 can be easily attached later, similarly to the holding member 31, and the RFID data carrier 51 can be sufficiently protected from mechanical shocks. 51 can be reused, and the cost can be reduced.

  The holding members 31, 36, and 41 can adopt various shapes corresponding to the shape of the work tool to be fixed, and the fixing position can be fixed inside or outside the grip portion 24, As long as it does not get in the way, it can be fixed at appropriate places.

By the way, the IC chip mounting body 52 is protected by ceramic exterior materials 55 and 56, and has a sufficient strength against an impact or the like. However, the coil antenna 53 and the IC chip 54 incorporated in the IC chip mounting body 52 are secured. Since it is an electronic component, it is impossible that it will not fail at all.
Therefore, even if the IC chip mounting body 52 breaks down and internal data cannot be read, information for identification is printed on the surface with a laser marker so that the RFID data carrier 51 can be identified. is there.
The ceramic material has an HV hardness of about 1350, and has a hardness 4 to 5 times that of the stainless steel material forming the work tool, so that the printing by the laser marker does not easily disappear.

  When the RFID data carrier 51 is damaged and cannot be read or written, the damaged RFID data carrier 51 is replaced with a new RFID data carrier 51 on which no data is written, and the correct information is stored in the internal IC chip mounting body 52. The procedure is described with reference to FIG.

First, the code 58 printed on the surface of the damaged data carrier 51 is read and input to the computer 76 by the keyboard 75. This code 58 is transmitted as an index for search to the server 77, and the data written in the data carrier 51 is inquired and acquired. Next, based on the data acquired from the server 77, new data is obtained by the RFID device 71. At the same time that data is written on the carrier 51 ', the code 58' printed on the surface of the new data carrier 51 'is transmitted to the server 77 to update the database.

By the above procedure, the same information as the data written in the damaged data carrier 51 is written in the new data carrier 51 ', and the information in the server 77 is also updated to the data of the new data carrier 51'.
As the code 58, it is convenient to use a unique number (UID) normally written in the IC chip mounting body 52.

  As described above, in the working tool of the present invention, a mounting hole is formed in the working tool, a notch groove is formed from the mounting hole to the outer periphery of the working tool, and the RFID data carrier is fitted into the mounting hole. Therefore, it is possible to reliably read / write data recorded on the RFID data carrier without causing a short-circuit current in the metal material when receiving electromagnetic waves, and to read / write data from both sides of the work tool. it can.

  Also, the front and back surfaces of the RFID data carrier are positioned flush with the front and back surfaces of the work tool or inside the front and back surfaces, and the RFID data carrier is fitted into the mounting hole. Even if other objects collide, the data carrier will not be damaged or dropped.

  In addition, when a mounting hole cannot be drilled in the work tool, or when an RFID data carrier is mounted on an existing work tool, a different type of RFID data carrier or a holding member that can store an RFID data carrier can be used. The RFID data carrier can be easily and reliably attached to the tool.

  Furthermore, even if the data written by the failure of the RFID data carrier cannot be read, the data can be correctly transferred to the new RFID data carrier by reading the code printed on the surface.

  In the work tool data recording device of the present invention, the data of the RFID data carrier attached to the work tool can be read and written without directly contacting the work tool. Can be recorded on work tools.

It is a front view of one Example of the working tool of this invention. (A) of the RFID data carrier is a plan view, and (B) is a side sectional view. FIG. 2A is a plan view of a lower exterior material, FIG. 2B is a side cross-sectional view of each member separated, and FIG. 2C is a plan view of an IC chip mounting body. . It is a front view of the other Example of the working tool of this invention. It is a front view of the other Example of the working tool of this invention. (A) of the RFID data carrier is a plan view, and (B) is a cross-sectional view taken along line AA in a state in which each member is separated. It is a front view of the other Example of the working tool of this invention. (A) of one Example of a holding member is a top view, (B) is a sectional side view of the state which opened the pressing part, (C) is a sectional side view of the state which closed the pressing part. (A) of the other Example of a holding member is a top view, (B) is a sectional side view of the state which separated the division body, (C) is a sectional side view of the state which stuck the division body. (A) of other embodiments of the holding member is a side sectional view in a state where each member is separated, (B) is an enlarged sectional side view of the A portion, and (C) is an enlarged sectional side view of the A portion in a state in which the protruding portion is crushed. (D) is a sectional side view of the state where the gripping body is in close contact. It is a schematic block diagram of the data recording device of a working tool. It is explanatory drawing which shows the procedure which replaces | exchanges a data carrier and transfers data.

Explanation of symbols

1 female 3 gripping part 3a mounting hole 3b cutout groove 11 forceps 14 gripping part 15a mounting hole 15b cutout groove 31 holding member 32b, 33b cutout groove 36 holding member 38b cutout groove 41 holding member 44d cutout groove 51 RFID data carrier 52 IC chip mounting Body 53 Coil antenna 54 IC chip 55, 56 Ceramic exterior material 61 RFID data carrier 62, 63 Ceramic exterior material 71 RFID device 72 Antenna 73 Controller 74 Computer

Claims (8)

An IC chip mounting body in which an IC chip is joined to a coil antenna and integrated is housed in upper and lower ceramic exterior materials configured to be fitted to each other , and is placed on the contact surface of the upper and lower ceramic exterior materials. An RFID data carrier in which the IC chip mounting body is covered with the upper and lower ceramic exterior materials by attaching a ceramic filler and fitting and bonding the upper and lower ceramic exterior materials together. A working tool characterized by being fitted and mounted in a mounting hole formed in the tool.   The work tool according to claim 1, wherein a notch groove is formed from the mounting hole to an outer periphery of the work tool.   The work tool according to claim 1 or 2, wherein the front and back surfaces of the RFID data carrier are positioned flush with or inside the front and back surfaces of the work tool.   4. The work tool according to claim 1, wherein the axial direction of the coil antenna of the RFID data carrier is set substantially perpendicular to the surface of the work tool.   The working tool according to claim 1, wherein the working tool is a surgical tool such as a knife or forceps. An IC chip mounting body in which an IC chip is joined to a coil antenna and integrated is housed in upper and lower ceramic exterior materials configured to be fitted to each other , and is placed on the contact surface of the upper and lower ceramic exterior materials. An RFID data carrier formed by covering the IC chip mounting body with the upper and lower ceramic exterior members by attaching a ceramic filler and fitting and bonding the upper and lower ceramic exterior members together. A working tool characterized in that the holding member is freely fixed to the working tool.   The work tool according to claim 6, wherein the holding member is made of a heat resistant material. A work tool according to claim 1 and an RFID device comprising an antenna, a controller, and a computer, wherein data is written to and read from an RFID data carrier mounted on the work tool by wireless communication. Data recording device for working tools.

Images