WO2023280505A1 - A processing tool and a processing tool assembly - Google Patents

A processing tool and a processing tool assembly Download PDF

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Publication number
WO2023280505A1
WO2023280505A1 PCT/EP2022/065683 EP2022065683W WO2023280505A1 WO 2023280505 A1 WO2023280505 A1 WO 2023280505A1 EP 2022065683 W EP2022065683 W EP 2022065683W WO 2023280505 A1 WO2023280505 A1 WO 2023280505A1
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WO
WIPO (PCT)
Prior art keywords
coupling part
processing tool
identification marker
identification
tool
Prior art date
Application number
PCT/EP2022/065683
Other languages
French (fr)
Inventor
Micael BAUDIN
Jan Gravningsbråten
John Hammargren
Susanne Norgren
Original Assignee
Seco Tools Ab
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from EP21209065.8A external-priority patent/EP4116020A1/en
Application filed by Seco Tools Ab filed Critical Seco Tools Ab
Publication of WO2023280505A1 publication Critical patent/WO2023280505A1/en

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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23CMILLING
    • B23C5/00Milling-cutters
    • B23C5/16Milling-cutters characterised by physical features other than shape
    • B23C5/20Milling-cutters characterised by physical features other than shape with removable cutter bits or teeth or cutting inserts
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23BTURNING; BORING
    • B23B2260/00Details of constructional elements
    • B23B2260/104Markings, i.e. symbols or other indicating marks
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23BTURNING; BORING
    • B23B2270/00Details of turning, boring or drilling machines, processes or tools not otherwise provided for
    • B23B2270/36Identification of tooling or other equipment
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23CMILLING
    • B23C2210/00Details of milling cutters
    • B23C2210/66Markings, i.e. symbols or indicating marks

Definitions

  • the present invention relates to a processing tool and a processing tool assembly.
  • Processing tools used for processing a workpiece material such as metal, wood, rock, or stone are currently provided in a huge number of different variants with different properties such as materials and geometries.
  • the suitability of a specific processing tool for a specific process is highly dependent on its properties.
  • Processing tools with different properties may look very similar to each other for the human eye, which makes it difficult for an operator to decide whether a specific tool is suitable for a specific process or not.
  • the operator In order to decide the properties of a tool, the operator usually needs to find a serial or batch number provided on the tool packaging and manually type this number in to an online catalog where its properties are listed.
  • a processing tool comprising:
  • -a tool body comprising:
  • first coupling part extending between a first end and a second end, wherein the first end is disposed at the rear end surface, wherein the first coupling part being one of:
  • the first coupling part is adapted to be coupled to a second coupling part, wherein the first coupling part comprises a first identification marker comprising first identification information of the processing tool, and wherein the first identification marker is positioned at the first coupling part such that it is unexposed to the exterior of the processing tool, when the first coupling part is coupled to the second coupling part; and wherein the tool body comprises a second identification marker comprising second identification information of the processing tool, and wherein the second identification marker is positioned at, at least one of, the front end surface, the rear end surface, or the at least one side surface, such that it is exposed to the exterior of the processing tool, when the first coupling part is coupled to the second coupling part.
  • the first identification marker By arranging a first identification marker at the first coupling part, so that it is unexposed to the exterior of the processing tool when the first coupling part is coupled to the second coupling part, the first identification marker will be protected from the harsh environment surrounding the processing tool when performing, for example, rock drilling, and the risk of the first identification marker being damaged is reduced.
  • the second identification marker is used as the primary identification marker of the tool body and the first identification marker is used as a back-up identification marker in case the second identification marker becomes damaged or worn out.
  • the second identification information may be identical to the first identification information.
  • the second identification information may be different from the first identification information and both the first and second identification information are associated with the same tool body in a tool database.
  • the tool body may be a unique tool body, such that the specific tool may be identified.
  • the identification information may identify the type of tool body but not the unique tool body.
  • the processing tool is preferably at least any of a metal cutting tool, a wood cutting tool, or a rock drilling tool, e.g. a milling cutter, a metal drilling tool, a turning tool or a rock drill bit.
  • the processing tool body is commonly made of metal, such as steel.
  • the processing tool preferably comprises at least one processing element.
  • the processing element can be e.g. a cutting insert provided with a cutting edge for cutting a workpiece material, or a button or an insert for breaking a workpiece material.
  • the processing element is commonly made of metal or a harder material such as cemented carbide, cubic boron nitride (CBN), cermet, ceramic, or polycrystalline diamond (PCD).
  • the processing element can be arranged in the processing portion of the processing tool body by any common method known in the art, e.g. by brazing, "shrink-fitting", or by use of a screw.
  • the connecting tool unit can be, for example, a drill string rod, a computer numerical control (CNC) machine part, or an adapter/extension for connecting the processing tool to a machine unit.
  • the identification information can be e.g. an identification number identifying the tool body.
  • the first identification marker is preferably a one-dimensional or two dimensional optical machine readable code, such as a Quick Response code, a High Capacity Colored Two Dimensional Code, a European Article Number code, a DataMatrix code, or a MaxiCode.
  • a Quick Response code such as a Quick Response code, a High Capacity Colored Two Dimensional Code, a European Article Number code, a DataMatrix code, or a MaxiCode.
  • the first identification marker is incorporated into the coupling part by being etched, engraved, impressed, imprinted or painted to the first coupling part.
  • the second identification marker is incorporated into the tool body by being etched, engraved, impressed, imprinted or painted to the tool body.
  • the first identification marker is incorporated into the coupling part differently than the second identification marker is incorporated into the tool body.
  • the first identification marker By arranging the first identification marker as a one-dimensional or two-dimensional optical machine-readable code, it is possible to arrange the first identification marker where it is partially surrounded by metal surfaces without affecting the readability of it. This is in contrast to the case where active identification markers, such as RFID chips, are used since the metal surfaces, in this case, causes interferences between the marker and the reading device used for reading the marker, resulting in difficulties reading the marker.
  • information regarding the unique processing tool can be achieved via e.g. a smartphone app with access to a tool database.
  • Said information can include e.g. geometrical data and/or data regarding the material composition of the processing tool body. Further information could be related to which type of processing element that is provided in the tool body and the material composition of said processing element.
  • the first identification marker is arranged at a surface of the first coupling part, and wherein the first identification marker comprises a plurality of first type modules and second type modules, each first type module being in level with the surface of the first coupling part surrounding the first identification marker, and each second type module comprising an indention with respect to said surface of the first coupling part, and wherein the second identification marker comprises a plurality of first type modules and second type modules, each first type module being in level with the surface of the front end surface, the rear end surface, or the at least one side surface surrounding the second identification marker, and each second type module comprising an indention with respect to said front end surface, rear end surface, or at least one side surface
  • the first type modules and the second type modules have the same module size.
  • the first type modules and the second type modules have the longest dimension of 0,5 mm or less, preferably 0,25 mm or less, more preferably 0,13 mm or less.
  • the second type modules have a depth of between 5 and 100 pm, preferably between 10 and 50 pm, more preferably between 15 and 45 pm with respect to the surface surrounding the first identification marker.
  • the first identification marker is positioned at the first coupling part such that it is positioned in an interface between the first coupling part and the second coupling part when the first coupling part is coupled to the second coupling part.
  • the first identification marker By arranging the first identification marker such that it will be positioned at an interface between the first coupling part and the second coupling part when they are coupled together, the first identification marker will become more unexposed, preferably completely unexposed, to the exterior of the processing tool when the processing tool is mounted to a connecting tool unit. The first identification marker will then be protected from the harsh environment surrounding the processing tool when performing, for example, rock drilling, and the risk of the first identification marker being damaged is reduced.
  • the second identification information is identical to the first identification information.
  • the identification process of the tool body is simplified, and one of the identification markers can be recreated from another of the identification markers, in case one would get worn out.
  • the first identification information comprises:
  • the second identification information comprises:
  • processing tool information By combining information regarding the unique processing tool identity and the location of the identification marker at the processing tool, a detailed determination of processing tool information can be made. For example, information regarding which placements of the identification markers are more or less suitable may be possible to determine if the locations of the identification markers are known, by comparing e.g. the amount of wear between different locations.
  • the second identification marker is arranged in a recess in the front end surface, the rear end surface, or the at least one side surface where the second identification marker is positioned.
  • the second identification marker By arranging the second identification marker in a recess in the front end surface, the rear end surface, or the at least one side surface where the second identification marker is positioned, the second identification marker will be better protected from the harsh environment surrounding the processing tool since the contact between the second identification marker and the workpiece material will be reduced. The risk of the second identification marker being worn out is thereby reduced.
  • the first coupling part has a length L extending between the first end and the second end; and wherein the first identification marker is, at least partly, located at a distance L-x from the first end, wherein x is 0-15% of L.
  • the risk of the first identification marker becoming damaged during operation of the processing tool is reduced.
  • the first identification marker comprises a plurality of indentions having a depth di
  • the second identification marker comprises a plurality of indentions having a depth d2, wherein d2 > di.
  • the second identification marker By having the indentions in the second identification marker arranged with a larger depth than the indentions in the first identification marker, the second identification marker will become more wear resistant than the first identification marker. Since the depths of the indentions in the first identification marker are smaller than the ones in the second identification marker, the process of providing the first identification marker at the first coupling part will be simplified compared to the process of providing the second identification marker at the front end surface, the rear end surface, or the at least one side surface. Accordingly, the second identification marker that is exposed to the harsh environment of the processing tool becomes more wear resistant while the process of marking the first coupling part becomes facilitated.
  • the second identification marker is positioned in a recess in any of the front end surface, the rear end surface, or the at least one side surface.
  • the first coupling part comprises a threaded portion, and wherein the first identification marker is arranged between the threaded portion and the second end.
  • the risk of the first identification marker becoming damaged during operation of the processing tool is reduced.
  • the tool body further comprises a flushing media channel having a flushing media inlet arranged in the first coupling part, and wherein the first identification marker is arranged between the threaded portion and the flushing media inlet.
  • the tool body comprises a plurality of flushing media channels, each having a flushing media inlet arranged in the first coupling part, and wherein the first identification means is arranged between the flushing media inlets.
  • the area surrounding the first identification marker will be constantly provided with flushing media during use of the processing tool, which will reduce the risk of residues of the workpiece material, e.g. rock crushings, to come in contact with the first identification marker. The risk of the first identification marker being damaged is thereby reduced.
  • the flushing media represents a fluid, either in liquid or gaseous form, and is intended to improve the processing conditions and the tool life, e.g. by flushing residues and crushings from the bore hole and maintain the desired drilling performance during drilling.
  • This type of fluid is also commonly designated as "coolant”, “cutting fluid”, “cutting oil”, or “lubrication fluid”.
  • a processing tool assembly comprising:
  • connecting tool unit comprises a second coupling part, wherein the second coupling part being one of:
  • the first identification marker By arranging the first identification marker so that it becomes unexposed to the exterior of the material processing tool assembly, the first identification marker will be protected from the harsh environment surrounding the material processing tool assembly when performing, for example, rock drilling, and the risk of the first identification marker being damaged is reduced.
  • the second identification marker By arranging the second identification marker so that it becomes exposed to the exterior of the material processing tool assembly, the reading of the second identification marker is facilitated, since the second identification marker is easily accessible for the operator.
  • the processing tool can be e.g. a milling cutter, a metal drilling tool, a turning tool or a rock drill bit.
  • the connecting tool unit can be, for example, a drill string rod, a computer numerical control (CNC) machine part, or and adapter/extension for connecting the processing tool to a machine unit.
  • CNC computer numerical control
  • the second coupling part comprises a third identification marker comprising identification information of the connecting tool unit.
  • the connecting tool unit By arranging a third identification marker at the second coupling part, the connecting tool unit can be uniquely identified and information such as geometrical data and material data associated with the uniquely identified connecting tool unit becomes accessible to the operator. By reading both the first and the second identification marker, information regarding the processing assembly is accessible by the operator.
  • the third identification marker is unexposed to the exterior of the processing tool assembly.
  • the third identification marker By arranging the third identification marker so that it becomes unexposed to the exterior of the processing tool assembly, the third identification marker will be protected from the harsh environment surrounding the processing tool assembly when performing, for example, rock drilling, and the risk of the third identification marker being damaged is reduced.
  • Fig. 1 illustrates a first embodiment of a processing tool in form of a metal cutting tool
  • Fig. 2 illustrates a second embodiment of a processing tool in form of a rock drilling tool
  • Fig. 3 illustrates a cross-sectional view of the rock drilling tool of figure 2
  • Fig. 4 illustrates a cross-sectional view of the rock drilling tool of figure 2 in a mounted state
  • Fig. 5 illustrates a material processing tool assembly in form of a drill arrangement.
  • Figure 1 illustrates a processing tool in form of a metal cutting tool (100), more precisely, figure 1 illustrates a milling cutter.
  • the milling cutter (100) comprises a tool body (110) in form of a milling cutter body having a central longitudinal axis A.
  • the milling cutter body comprising a front end surface (115), a rear end surface (116), a side surface (117) connecting the front end surface (115) and the rear end surface (116), and a first coupling part (130), in form of a male coupling part, having a length L extending between a first end (118) disposed at the rear end surface (116), and a second end (119).
  • the first coupling part (130) is adapted to be coupled to a second coupling part in form of a female coupling part arranged at a connecting tool unit.
  • the connecting tool unit can be e.g. a computer numerical control (CNC) machine spindle, or an adapter/extension for connecting the milling cutter (100) to the machine spindle.
  • CNC computer numerical control
  • the first coupling part (130) comprises a threaded portion (133).
  • a first identification marker (140) in form of a DataMatrix code is arranged at the first coupling part (130).
  • the first identification marker (140) comprising first identification information of the milling cutter (100), which can be e.g. an identification number identifying the unique milling cutter body (110).
  • the milling cutter body (110) further comprises a second identification marker (150) in form of a DataMatrix code arranged at the side surface (117).
  • the second identification marker (150) comprises second identification information of the milling cutter (100), which can be e.g. an identification number identifying the unique milling cutter body (110).
  • the milling cutter (100) further comprises a plurality of processing elements (120) in form of cutting inserts provided with cutting edges (121) for cutting a workpiece material.
  • the cutting inserts (120) are provided with fourth identification markers (160, 161) in form of a DataMatrix codes.
  • the fourth identification markers (160, 161) comprise cutting insert identification data which can be e.g. an identification number identifying the unique cutting insert (120).
  • FIG. 2 illustrates a material processing tool (200) in form of a rock drilling tool, more precisely, figure 2 illustrates a rock drill bit.
  • the rock drill bit (200) comprises a processing tool body (210) in form of a drill bit body having a central longitudinal axis A.
  • the drill bit body (210) comprising a front end surface (215), a rear end surface (216), and a side surface (217) connecting the front end surface (215) and the rear end surface (216).
  • the drill bit body (210) comprises a second identification marker (250) in form of a DataMatrix code arranged at the side surface (217).
  • the second identification marker (250) comprises second identification information of the rock drill bit (200), which can be e.g. an identification number identifying the unique drill bit body (210).
  • the rock drill bit (200) further comprises a plurality of processing elements (220) in form of buttons for breaking the rock.
  • the buttons (220) are mounted in cavities in the tool body (210) where only the top part of the buttons (220) is extending from the front end surface (215).
  • the buttons (220) may be provided with fourth identification markers (not shown), which are preferably arranged at the part of the buttons (220) not being exposed to the exterior of the rock drill bit (200).
  • Figure 3 illustrates a cross-sectional view of the rock drilling tool illustrated in figure 2.
  • the drill bit body (210) further comprises a first coupling part (230), in the form of a female coupling part, having a length L, extending between a first end (218) disposed at the rear end surface (216), and a second end (219).
  • the first coupling part (230) is adapted to be coupled to a second coupling part in form of a male coupling part (430) arranged at a connecting tool unit (400).
  • the connecting tool unit (400) can be e.g. a drill string rod for connecting the rock drill bit to a hydraulically driven piston or to a further drill string rod if necessary.
  • the first coupling part (230) comprises a threaded portion (233).
  • a first identification marker (240) in form of a DataMatrix code is arranged at the first coupling part (230) between the threaded portion (233) and the second end (219).
  • the first identification marker (240) comprising first identification information of the rock drill bit (200), which can be e.g. an identification number identifying the unique drill bit body (210).
  • the drill bit body (210) further comprises a plurality of flushing media channels (280). Each of the flushing media channels (280) has a flushing media outlet (270) arranged in the front end surface (215) and a flushing media inlet (290) arranged in the first coupling part (230).
  • the first identification marker (240) is arranged between the threaded portion (233) and the flushing media inlets (290).
  • Flushing media can be provided to the rock drill bit (200) via the connecting tool unit (400) in order to flush residues and crushings from the bore hole and maintain the desired drilling performance during drilling.
  • Figure 3 further illustrates said second coupling part (430) in form of male coupling part.
  • the connecting tool unit (400) is not illustrated in figure 3.
  • a third identification marker (440) in form of a DataMatrix code is arranged at the second coupling part (430).
  • the third identification marker (440) comprises connecting tool unit identification data which can be e.g. an identification number identifying the unique connecting tool unit (400).
  • Figure 4 illustrates a cross-sectional view of the rock drilling tool illustrated in figure 2 in a mounted state.
  • the first identification marker (240) is unexposed to the exterior of the rock drill bit (200) when the rock drill bit (200) is mounted to a connecting tool unit (400). Since flushing media is provided to the rock drill bit (200) via the connecting tool unit (400), and from the flushing media inlet (290) to the flushing media outlet (270) via the flushing media channel (280) during operation, crushings are prevented from entering the first coupling part (230) via the flushing media channel (280). This results in that the first identification marker (240) is unexposed to the exterior of the rock drill bit (200) when the rock drill bit (200) is coupled to a connecting tool part (400).
  • FIG 5 illustrates a processing assembly (300) in form of a drill assembly.
  • the drill assembly (300) comprises a rock drill bit (200) as illustrated in figure 2, and a connecting tool unit (400) in form of a drill string rod.
  • the drill string rod (400) comprises a front end (411) comprising said second coupling part (430).
  • the rock drill bit (200) and the drill string rod (400) being subsequently attached to each other in the direction of the central longitudinal axis A by coupling between the first coupling part (230) and the second coupling part (430).
  • the drill string rod (400) further comprises a rear end (412).
  • a third coupling part (450) is arranged at the rear end (412).
  • the third coupling part (450) is used to connect the drill string rod (400) to a hydraulically driven piston or to a further drill string rod in order to extend the drill assembly (300) if necessary.
  • the second identification marker (250) is exposed to the exterior of the drill assembly (300).

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Abstract

The invention relates to a processing tool (100,200) comprising a tool body (110,210) and a first coupling part (130,230), wherein the first coupling part (130,230) being one of a female coupling part (230); and a male coupling part (130), wherein the first coupling part (130,230) is adapted to be coupled to a second coupling part (430), and wherein the first coupling part (130,230) comprises a first identification marker (140,240) comprising first identification information of the processing tool (100,200), and wherein the first identification marker (140,240) is positioned at the first coupling part (130,230) such that it is unexposed to the exterior of the processing tool (100,200) when the first coupling part (130,230) is coupled to the second coupling part (430); and wherein the tool body (110,210) comprises a second identification marker (150,250) comprising second identification information of the processing tool (100,200), which is arranged such that it is exposed to the exterior of the processing tool (100,200), when the first coupling part (130,230) is coupled to the second coupling part (430). The invention also relates to a processing tool assembly (300).

Description

A processing tool and a processing tool assembly
TECHNICAL FIELD
The present invention relates to a processing tool and a processing tool assembly.
BACKGROUND
Processing tools used for processing a workpiece material, such as metal, wood, rock, or stone are currently provided in a huge number of different variants with different properties such as materials and geometries. The suitability of a specific processing tool for a specific process is highly dependent on its properties.
Processing tools with different properties may look very similar to each other for the human eye, which makes it difficult for an operator to decide whether a specific tool is suitable for a specific process or not. In order to decide the properties of a tool, the operator usually needs to find a serial or batch number provided on the tool packaging and manually type this number in to an online catalog where its properties are listed.
This is a very time consuming work which also includes a lot of potential risk factors. For example, it is easy that an incorrect number is entered in the catalog which results in incorrect information being given to the operator. Another problem is that the original package of the tool gets lost, which results in that the serial or batch number cannot be found. A further problem is that the catalog only provides general information on a tool type level. It does not provide specific information related to a unique individual tool.
As a result, there is a risk that an unsuitable tool is used for a specific process, which may result in a low quality of the workpiece material processed by the tool.
Attempts to solve this problem have been made by providing tools with information carriers in the form of radio frequency identification (RFID) chips which are mounted to the tools by use of special chip holding units. Such a solution is disclosed in EP 1369811 Al.
A problem with these solutions is that the RFID chip tends to break easily, resulting in that the information stored in the chip will be lost.
SUMMARY OF THE INVENTION
It is an object of the present invention to overcome, or at least partially overcome, said problem by introducing a processing tool and a processing tool assembly.
The object of the present invention is achieved by means of a processing tool comprising:
-a tool body comprising:
-a front end surface, -a rear end surface,
-at least one side surface connecting the front end surface and the rear end surface,
-a first coupling part extending between a first end and a second end, wherein the first end is disposed at the rear end surface, wherein the first coupling part being one of:
-a female coupling part; and
-a male coupling part; wherein the first coupling part is adapted to be coupled to a second coupling part, wherein the first coupling part comprises a first identification marker comprising first identification information of the processing tool, and wherein the first identification marker is positioned at the first coupling part such that it is unexposed to the exterior of the processing tool, when the first coupling part is coupled to the second coupling part; and wherein the tool body comprises a second identification marker comprising second identification information of the processing tool, and wherein the second identification marker is positioned at, at least one of, the front end surface, the rear end surface, or the at least one side surface, such that it is exposed to the exterior of the processing tool, when the first coupling part is coupled to the second coupling part.
By arranging a first identification marker at the first coupling part, so that it is unexposed to the exterior of the processing tool when the first coupling part is coupled to the second coupling part, the first identification marker will be protected from the harsh environment surrounding the processing tool when performing, for example, rock drilling, and the risk of the first identification marker being damaged is reduced.
By arranging a second identification marker at any of the front end surface, the rear end surface, or the at least one side surface, such that it is exposed to the exterior of the processing tool, when the first coupling part is coupled to the second coupling part, the reading of the second identification marker is facilitated, since the second identification marker is easily accessible for the operator. Preferably, the second identification marker is used as the primary identification marker of the tool body and the first identification marker is used as a back-up identification marker in case the second identification marker becomes damaged or worn out. The second identification information may be identical to the first identification information. Alternatively, the second identification information may be different from the first identification information and both the first and second identification information are associated with the same tool body in a tool database. In some embodiments, the tool body may be a unique tool body, such that the specific tool may be identified. In some embodiments, the identification information may identify the type of tool body but not the unique tool body.
The processing tool is preferably at least any of a metal cutting tool, a wood cutting tool, or a rock drilling tool, e.g. a milling cutter, a metal drilling tool, a turning tool or a rock drill bit. The processing tool body is commonly made of metal, such as steel. The processing tool preferably comprises at least one processing element. The processing element can be e.g. a cutting insert provided with a cutting edge for cutting a workpiece material, or a button or an insert for breaking a workpiece material. The processing element is commonly made of metal or a harder material such as cemented carbide, cubic boron nitride (CBN), cermet, ceramic, or polycrystalline diamond (PCD). The processing element can be arranged in the processing portion of the processing tool body by any common method known in the art, e.g. by brazing, "shrink-fitting", or by use of a screw. The connecting tool unit can be, for example, a drill string rod, a computer numerical control (CNC) machine part, or an adapter/extension for connecting the processing tool to a machine unit. The identification information can be e.g. an identification number identifying the tool body.
The first identification marker is preferably a one-dimensional or two dimensional optical machine readable code, such as a Quick Response code, a High Capacity Colored Two Dimensional Code, a European Article Number code, a DataMatrix code, or a MaxiCode.
In some embodiments, the first identification marker is incorporated into the coupling part by being etched, engraved, impressed, imprinted or painted to the first coupling part. In some embodiments, the second identification marker is incorporated into the tool body by being etched, engraved, impressed, imprinted or painted to the tool body. In some embodiments, the first identification marker is incorporated into the coupling part differently than the second identification marker is incorporated into the tool body.
By arranging the first identification marker as a one-dimensional or two-dimensional optical machine-readable code, it is possible to arrange the first identification marker where it is partially surrounded by metal surfaces without affecting the readability of it. This is in contrast to the case where active identification markers, such as RFID chips, are used since the metal surfaces, in this case, causes interferences between the marker and the reading device used for reading the marker, resulting in difficulties reading the marker.
By reading the first identification marker by use of a reading device, information regarding the unique processing tool can be achieved via e.g. a smartphone app with access to a tool database. Said information can include e.g. geometrical data and/or data regarding the material composition of the processing tool body. Further information could be related to which type of processing element that is provided in the tool body and the material composition of said processing element.
The term "unexposed" is to be understood as workpiece residues are prevented from coming in contact with the first identification marker. The same meaning is applied to other unexposed parts.
The term "exposed" is to be understood as being accessible or readable by a reading device without having to disassemble the tool or decoupling the tool from a connecting tool unit which it is coupled to.
According to an embodiment, the first identification marker is arranged at a surface of the first coupling part, and wherein the first identification marker comprises a plurality of first type modules and second type modules, each first type module being in level with the surface of the first coupling part surrounding the first identification marker, and each second type module comprising an indention with respect to said surface of the first coupling part, and wherein the second identification marker comprises a plurality of first type modules and second type modules, each first type module being in level with the surface of the front end surface, the rear end surface, or the at least one side surface surrounding the second identification marker, and each second type module comprising an indention with respect to said front end surface, rear end surface, or at least one side surface
According to an embodiment, the first type modules and the second type modules have the same module size.
According to an embodiment, the first type modules and the second type modules have the longest dimension of 0,5 mm or less, preferably 0,25 mm or less, more preferably 0,13 mm or less.
According to an embodiment, the second type modules have a depth of between 5 and 100 pm, preferably between 10 and 50 pm, more preferably between 15 and 45 pm with respect to the surface surrounding the first identification marker.
According to an embodiment, the first identification marker is positioned at the first coupling part such that it is positioned in an interface between the first coupling part and the second coupling part when the first coupling part is coupled to the second coupling part.
By arranging the first identification marker such that it will be positioned at an interface between the first coupling part and the second coupling part when they are coupled together, the first identification marker will become more unexposed, preferably completely unexposed, to the exterior of the processing tool when the processing tool is mounted to a connecting tool unit. The first identification marker will then be protected from the harsh environment surrounding the processing tool when performing, for example, rock drilling, and the risk of the first identification marker being damaged is reduced.
According to an embodiment, the second identification information is identical to the first identification information.
By having the second identification information identical to the first identification information, the identification process of the tool body is simplified, and one of the identification markers can be recreated from another of the identification markers, in case one would get worn out.
According to an embodiment, the first identification information comprises:
-a processing tool identity; and
-information regarding the location of the first identification marker at the processing tool; wherein the second identification information comprises:
-the processing tool identity; and -information regarding the location of the second identification marker at the processing tool.
By combining information regarding the unique processing tool identity and the location of the identification marker at the processing tool, a detailed determination of processing tool information can be made. For example, information regarding which placements of the identification markers are more or less suitable may be possible to determine if the locations of the identification markers are known, by comparing e.g. the amount of wear between different locations.
According to an embodiment, the second identification marker is arranged in a recess in the front end surface, the rear end surface, or the at least one side surface where the second identification marker is positioned.
By arranging the second identification marker in a recess in the front end surface, the rear end surface, or the at least one side surface where the second identification marker is positioned, the second identification marker will be better protected from the harsh environment surrounding the processing tool since the contact between the second identification marker and the workpiece material will be reduced. The risk of the second identification marker being worn out is thereby reduced.
According to an embodiment, the first coupling part has a length L extending between the first end and the second end; and wherein the first identification marker is, at least partly, located at a distance L-x from the first end, wherein x is 0-15% of L.
By having the first identification marker arranged as far away as possible from the first end, the risk of the first identification marker becoming damaged during operation of the processing tool is reduced.
According to an embodiment, the first identification marker comprises a plurality of indentions having a depth di, and wherein the second identification marker comprises a plurality of indentions having a depth d2, wherein d2 > di.
By having the indentions in the second identification marker arranged with a larger depth than the indentions in the first identification marker, the second identification marker will become more wear resistant than the first identification marker. Since the depths of the indentions in the first identification marker are smaller than the ones in the second identification marker, the process of providing the first identification marker at the first coupling part will be simplified compared to the process of providing the second identification marker at the front end surface, the rear end surface, or the at least one side surface. Accordingly, the second identification marker that is exposed to the harsh environment of the processing tool becomes more wear resistant while the process of marking the first coupling part becomes facilitated.
According to an embodiment, the second identification marker is positioned in a recess in any of the front end surface, the rear end surface, or the at least one side surface. By arranging the second identification marker in a recess machined in any of the front end surface, the rear end surface, or the at least one side surface, the risk of the second identification marker being worn out is reduced since the risk of the second identification marker coming in contact with the workpiece material is reduced.
According to an embodiment, the first coupling part comprises a threaded portion, and wherein the first identification marker is arranged between the threaded portion and the second end.
By arranging the first coupling part with a threaded portion, a stable mounting is achieved between the processing tool and a connecting tool unit.
By having the first identification marker arranged as far away as possible from the first end, the risk of the first identification marker becoming damaged during operation of the processing tool is reduced.
According to an embodiment, the tool body further comprises a flushing media channel having a flushing media inlet arranged in the first coupling part, and wherein the first identification marker is arranged between the threaded portion and the flushing media inlet.
According to an embodiment, the tool body comprises a plurality of flushing media channels, each having a flushing media inlet arranged in the first coupling part, and wherein the first identification means is arranged between the flushing media inlets.
By having the first identification marker arranged in close proximity to the flushing media inlets, the area surrounding the first identification marker will be constantly provided with flushing media during use of the processing tool, which will reduce the risk of residues of the workpiece material, e.g. rock crushings, to come in contact with the first identification marker. The risk of the first identification marker being damaged is thereby reduced.
The flushing media represents a fluid, either in liquid or gaseous form, and is intended to improve the processing conditions and the tool life, e.g. by flushing residues and crushings from the bore hole and maintain the desired drilling performance during drilling. This type of fluid is also commonly designated as "coolant", "cutting fluid", "cutting oil", or "lubrication fluid".
The object of the present invention is further achieved by means of a processing tool assembly, comprising:
-a processing tool as disclosed above; and
-a connecting tool unit; wherein the connecting tool unit comprises a second coupling part, wherein the second coupling part being one of:
-a male coupling part adapted to be coupled to the female coupling part of the processing tool; and -a female coupling part adapted to be coupled to the male coupling part of the processing tool; wherein the first coupling part is coupled to the second coupling part, and wherein the first identification marker is unexposed to the exterior of the processing tool assembly, and wherein the second identification marker is exposed to the exterior of the processing tool assembly.
By arranging the first identification marker so that it becomes unexposed to the exterior of the material processing tool assembly, the first identification marker will be protected from the harsh environment surrounding the material processing tool assembly when performing, for example, rock drilling, and the risk of the first identification marker being damaged is reduced.
By arranging the second identification marker so that it becomes exposed to the exterior of the material processing tool assembly, the reading of the second identification marker is facilitated, since the second identification marker is easily accessible for the operator.
The processing tool can be e.g. a milling cutter, a metal drilling tool, a turning tool or a rock drill bit.
The connecting tool unit can be, for example, a drill string rod, a computer numerical control (CNC) machine part, or and adapter/extension for connecting the processing tool to a machine unit.
According to an embodiment, the second coupling part comprises a third identification marker comprising identification information of the connecting tool unit.
By arranging a third identification marker at the second coupling part, the connecting tool unit can be uniquely identified and information such as geometrical data and material data associated with the uniquely identified connecting tool unit becomes accessible to the operator. By reading both the first and the second identification marker, information regarding the processing assembly is accessible by the operator.
According to an embodiment, the third identification marker is unexposed to the exterior of the processing tool assembly.
By arranging the third identification marker so that it becomes unexposed to the exterior of the processing tool assembly, the third identification marker will be protected from the harsh environment surrounding the processing tool assembly when performing, for example, rock drilling, and the risk of the third identification marker being damaged is reduced.
BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 illustrates a first embodiment of a processing tool in form of a metal cutting tool, Fig. 2 illustrates a second embodiment of a processing tool in form of a rock drilling tool, Fig. 3 illustrates a cross-sectional view of the rock drilling tool of figure 2 Fig. 4 illustrates a cross-sectional view of the rock drilling tool of figure 2 in a mounted state, Fig. 5 illustrates a material processing tool assembly in form of a drill arrangement.
DETAILED DESCRIPTION
The disclosed embodiments will now be described more fully hereinafter with reference to the accompanying drawings, in which certain embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided by way of example so that the disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like reference numbers refer to like elements throughout. The elements illustrated in the drawings are not necessary according to scale. Some elements might have been enlarged in order to clearly illustrate those elements.
Figure 1 illustrates a processing tool in form of a metal cutting tool (100), more precisely, figure 1 illustrates a milling cutter. The milling cutter (100) comprises a tool body (110) in form of a milling cutter body having a central longitudinal axis A. The milling cutter body comprising a front end surface (115), a rear end surface (116), a side surface (117) connecting the front end surface (115) and the rear end surface (116), and a first coupling part (130), in form of a male coupling part, having a length L extending between a first end (118) disposed at the rear end surface (116), and a second end (119). The first coupling part (130) is adapted to be coupled to a second coupling part in form of a female coupling part arranged at a connecting tool unit. The connecting tool unit can be e.g. a computer numerical control (CNC) machine spindle, or an adapter/extension for connecting the milling cutter (100) to the machine spindle. When mounted to the machine spindle, the machine spindle will make the milling cutter rotating in a direction R around the central longitudinal axis A. The first coupling part (130) comprises a threaded portion (133). A first identification marker (140) in form of a DataMatrix code is arranged at the first coupling part (130). The first identification marker (140) comprising first identification information of the milling cutter (100), which can be e.g. an identification number identifying the unique milling cutter body (110). The milling cutter body (110) further comprises a second identification marker (150) in form of a DataMatrix code arranged at the side surface (117). The second identification marker (150) comprises second identification information of the milling cutter (100), which can be e.g. an identification number identifying the unique milling cutter body (110). The milling cutter (100) further comprises a plurality of processing elements (120) in form of cutting inserts provided with cutting edges (121) for cutting a workpiece material. The cutting inserts (120) are provided with fourth identification markers (160, 161) in form of a DataMatrix codes. The fourth identification markers (160, 161) comprise cutting insert identification data which can be e.g. an identification number identifying the unique cutting insert (120).
Figure 2 illustrates a material processing tool (200) in form of a rock drilling tool, more precisely, figure 2 illustrates a rock drill bit. The rock drill bit (200) comprises a processing tool body (210) in form of a drill bit body having a central longitudinal axis A. The drill bit body (210) comprising a front end surface (215), a rear end surface (216), and a side surface (217) connecting the front end surface (215) and the rear end surface (216). The drill bit body (210) comprises a second identification marker (250) in form of a DataMatrix code arranged at the side surface (217). The second identification marker (250) comprises second identification information of the rock drill bit (200), which can be e.g. an identification number identifying the unique drill bit body (210). The rock drill bit (200) further comprises a plurality of processing elements (220) in form of buttons for breaking the rock. The buttons (220) are mounted in cavities in the tool body (210) where only the top part of the buttons (220) is extending from the front end surface (215). The buttons (220) may be provided with fourth identification markers (not shown), which are preferably arranged at the part of the buttons (220) not being exposed to the exterior of the rock drill bit (200).
Figure 3 illustrates a cross-sectional view of the rock drilling tool illustrated in figure 2. The drill bit body (210) further comprises a first coupling part (230), in the form of a female coupling part, having a length L, extending between a first end (218) disposed at the rear end surface (216), and a second end (219). The first coupling part (230) is adapted to be coupled to a second coupling part in form of a male coupling part (430) arranged at a connecting tool unit (400). The connecting tool unit (400) can be e.g. a drill string rod for connecting the rock drill bit to a hydraulically driven piston or to a further drill string rod if necessary. The first coupling part (230) comprises a threaded portion (233). A first identification marker (240) in form of a DataMatrix code is arranged at the first coupling part (230) between the threaded portion (233) and the second end (219). The first identification marker (240) comprising first identification information of the rock drill bit (200), which can be e.g. an identification number identifying the unique drill bit body (210). The drill bit body (210) further comprises a plurality of flushing media channels (280). Each of the flushing media channels (280) has a flushing media outlet (270) arranged in the front end surface (215) and a flushing media inlet (290) arranged in the first coupling part (230). The first identification marker (240) is arranged between the threaded portion (233) and the flushing media inlets (290). Flushing media can be provided to the rock drill bit (200) via the connecting tool unit (400) in order to flush residues and crushings from the bore hole and maintain the desired drilling performance during drilling. Figure 3 further illustrates said second coupling part (430) in form of male coupling part. The connecting tool unit (400) is not illustrated in figure 3. A third identification marker (440) in form of a DataMatrix code is arranged at the second coupling part (430). The third identification marker (440) comprises connecting tool unit identification data which can be e.g. an identification number identifying the unique connecting tool unit (400).
Figure 4 illustrates a cross-sectional view of the rock drilling tool illustrated in figure 2 in a mounted state. In figure 4 it can be seen that the first identification marker (240) is unexposed to the exterior of the rock drill bit (200) when the rock drill bit (200) is mounted to a connecting tool unit (400). Since flushing media is provided to the rock drill bit (200) via the connecting tool unit (400), and from the flushing media inlet (290) to the flushing media outlet (270) via the flushing media channel (280) during operation, crushings are prevented from entering the first coupling part (230) via the flushing media channel (280). This results in that the first identification marker (240) is unexposed to the exterior of the rock drill bit (200) when the rock drill bit (200) is coupled to a connecting tool part (400).
Figure 5 illustrates a processing assembly (300) in form of a drill assembly. The drill assembly (300) comprises a rock drill bit (200) as illustrated in figure 2, and a connecting tool unit (400) in form of a drill string rod. The drill string rod (400) comprises a front end (411) comprising said second coupling part (430). The rock drill bit (200) and the drill string rod (400) being subsequently attached to each other in the direction of the central longitudinal axis A by coupling between the first coupling part (230) and the second coupling part (430). The drill string rod (400) further comprises a rear end (412). A third coupling part (450) is arranged at the rear end (412). The third coupling part (450) is used to connect the drill string rod (400) to a hydraulically driven piston or to a further drill string rod in order to extend the drill assembly (300) if necessary. As can be seen in the figure, the second identification marker (250) is exposed to the exterior of the drill assembly (300).

Claims

1. A processing tool (100,200) comprising:
-a tool body (110,210) comprising:
-a front end surface (115,215),
-a rear end surface (116,216),
-at least one side surface (117,217) connecting the front end surface (115,215) and the rear end surface (116,216), and
-a first coupling part (130,230) extending between a first end (118,218) and a second end (119,219), wherein the first end (118,218) is disposed at the rear end surface (116,216) wherein the first coupling part (130,230) being one of:
-a female coupling part (230); and -a male coupling part (130); wherein the first coupling part (130,230) is adapted to be coupled to a second coupling part (430), characterized in that the first coupling part (130,230) comprises a first identification marker (140,240) comprising first identification information of the processing tool (100,200), and wherein the first identification marker (140,240) is positioned at the first coupling part (130,230) such that it is unexposed to the exterior of the processing tool (100,200) when the first coupling part (130,230) is coupled to the second coupling part (430); and in that the tool body (110,210) comprises a second identification marker (150,250) comprising second identification information of the processing tool (100,200), and wherein the second identification marker (150,250) is positioned at, at least one of, the front end surface (115,215), the rear end surface (116,216), or the at least one side surface (117,217), such that it is exposed to the exterior of the processing tool (100,200), when the first coupling part (130,230) is coupled to the second coupling part (430).
2. The processing tool (100,200) according to claim 1, wherein the first identification marker (140,240) is positioned at the first coupling part (130,230) such that it is positioned in an interface between the first coupling part (130,230) and the second coupling part (430) when the first coupling part (130,230) is coupled to the second coupling part (430).
3. The processing tool (100,200) according to any of claim 1 or 2, wherein the second identification information is identical to the first identification information.
4. The processing tool (100,200) according to any of claim 1 or 2, wherein the first identification information comprises:
-a processing tool identity; and
-information regarding the location of the first identification marker (140,240) at the processing tool (100,200); wherein the second identification information comprises:
-the processing tool identity; and
-information regarding the location of the second identification marker (150,250) at the processing tool (100,200).
5. The processing tool (100,200) according to any of the preceding claims, wherein the second identification marker (150,250) is arranged in a recess in the front end surface (115,215), the rear end surface (116,216), or the at least one side surface (117,217) where the second identification marker (150,250) is positioned.
6. The processing tool (100,200) according to any of the preceding claims, wherein the first coupling part (130,230) has a length L extending between the first end (118,218) and the second end (119,219), and wherein the first identification marker (140,240) is, at least partly, located at a distance L-x from the first end (118,218), wherein x is 0-15% of L.
7. The processing tool (100,200) according to any of the preceding claims, wherein the first identification marker (140,240) comprises a plurality of indentions having a depth di, and wherein the second identification marker (150,250) comprises a plurality of indentions having a depth d2, wherein d2>di.
8. The processing tool (100,200) according to any of the preceding claims, wherein the second identification marker (150,250) is positioned in a recess in any of the front end surface (115,215), the rear end surface (116,216), or the at least one side surface (117,217).
9. A processing tool assembly (300) comprising:
-a processing tool (100,200) according to any of claims 1-8, and -a connecting tool unit (400); wherein the connecting tool unit (400) comprises a second coupling part (430), wherein the second coupling part (430) being one of:
-a male coupling part (430) adapted to be coupled to the female coupling part (230) of the processing tool (100,200); and
-a female coupling part adapted to be coupled to the male coupling part (130) of the processing tool (100,200); wherein the first coupling part (130,230) is coupled to the second coupling part (430), and wherein the first identification marker (140,240) is unexposed to the exterior of the processing tool assembly (300), and wherein the second identification marker (150,250) is exposed to the exterior of the processing tool assembly (300).
10. The processing tool assembly (300) according to claim 9, wherein the second coupling part (430) comprises a third identification marker (440) comprising identification information of the connecting tool unit (400).
11. The processing tool assembly (300) according to claim 10, wherein the third identification marker (440) is unexposed to the exterior of the processing tool assembly (300).
PCT/EP2022/065683 2021-07-06 2022-06-09 A processing tool and a processing tool assembly WO2023280505A1 (en)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
EP21184032.7 2021-07-06
EP21184032 2021-07-06
EP21209065.8 2021-11-18
EP21209065.8A EP4116020A1 (en) 2021-07-06 2021-11-18 A processing tool and a processing tool assembly

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Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP1369811A1 (en) 2002-06-06 2003-12-10 Big Daishowa Seiki Co., Ltd. Information system
EP1735521A1 (en) * 2004-04-15 2006-12-27 Varco I/P, Inc. A component used in the formation, construction, repair and production phase of a well bore and a method for identifying same
US20150363710A1 (en) * 2014-06-11 2015-12-17 Superior Drilling Products, Inc. Methods and systems for tracking inventory
EP3760828A1 (en) * 2019-07-05 2021-01-06 Sandvik Mining and Construction Tools AB Drill bit

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP1369811A1 (en) 2002-06-06 2003-12-10 Big Daishowa Seiki Co., Ltd. Information system
EP1735521A1 (en) * 2004-04-15 2006-12-27 Varco I/P, Inc. A component used in the formation, construction, repair and production phase of a well bore and a method for identifying same
US20150363710A1 (en) * 2014-06-11 2015-12-17 Superior Drilling Products, Inc. Methods and systems for tracking inventory
EP3760828A1 (en) * 2019-07-05 2021-01-06 Sandvik Mining and Construction Tools AB Drill bit

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