Insert tool packaging device

Abstract

Tool packaging device, in particular saw blade packaging device, with at least one thin-film packaging unit (12) having at least two main areas (14, 16), characterized by at least one spacer element (18, 20, 22, 24) by means of which, in at least one packaged state of the thin-film packaging unit (12), at least one free space (26) is produced between at least two sub-areas (52, 54) of the main areas (14, 16), which is provided for the storage of at least one tool (28), wherein the two main areas (14, 16) are connected by at least one fold line (34), wherein the spacer elements (22, 24) are provided to be glued onto the sub-area (54) of the main area (16).

Description

State of the art

[0001] A tool packaging device, in particular a saw blade packaging device, with at least one thin-layer packaging unit having at least two main areas, has already been proposed. Disclosure of the invention

[0002] The invention relates to a tool packaging device, in particular a saw blade packaging device, with at least one thin-film packaging unit having at least two main areas. "Provided for" is to be understood in particular as being specially designed and / or equipped. A "thin-film packaging unit" is to be understood in particular as a unit that, in at least one packaged state, is intended to package at least one item. In particular, the thin-film packaging unit is formed at least substantially from a thin-film material.A "thin-film" material is understood to mean, in particular, a material which, when unfolded in a plane, has at least one longitudinal extent, at least one transverse extent, and at least one thickness, wherein the magnitude of the longitudinal extent and the magnitude of the transverse extent are more than 15 times, preferably more than 20 times, and particularly more than 25 times, greater than the magnitude of the thickness. For example, the thin-film packaging unit can be made of paper or a thin-film plastic. In particular, the thin-film packaging unit is made of cardboard. A "cardboard" is understood to mean, in particular, a material that is at least partially made of a fibrous material. Preferably, the cardboard is made of at least two, and in particular several, layers of a fibrous material. Preferably, the several layers of fibrous material have at least substantially different thicknesses.Preferably, the multiple layers of fiber material are at least partially composed of different materials. In particular, the multiple layers of fiber material are pressed together. Preferably, the cardboard has a weight in the range of 150 g / m². 2 up to 600 g / m² 2The term "fiber material" shall be understood to mean, in particular, a material that is composed at least substantially of plant fibers. Preferably, the fiber material is composed of primary fibers and / or secondary fibers. Primary fibers can be, for example, wood, straw, and / or hemp. Secondary fibers can be, for example, recycled materials such as waste paper. The phrase "composed at least substantially of plant fibers" shall be understood to mean, in particular, that the fiber material consists of plant fibers to a mass percentage of more than 80%, preferably more than 85%, and especially more than 90%.The phrase "several layers of fiber material have at least substantially different thicknesses" is understood to mean, in particular, that each layer of fiber material spans an area when unfolded in a plane, and that at least one of these areas has a thickness that differs from another area by more than 60%, preferably more than 75%, and especially more than 90%. A "main area" is understood to mean, in particular, an area of ​​a unit, especially a thin-film packaging unit, which, when the unit is unfolded in a plane, forms at least substantially more than 15%, preferably more than 20%, and especially more than 25% of the unit's area in the plane.In this context, "at least substantially" is to be understood in particular as meaning that the deviation from a given value is in particular less than 25%, preferably less than 10% and most preferably less than 5% of the given value.

[0003] At least one spacer element is proposed, by means of which, in at least one packaged state of the thin-film packaging unit, at least a space is created between at least two sub-areas of the main areas, wherein the space is provided for the storage of at least one insert tool. A "spacer element" is understood to be, in particular, an element which, in at least one state of the spacer element, is designed to create a space between at least two further elements, in particular between two sub-areas of the main areas of the thin-film packaging unit. Specifically, the spacer element is designed to create a space between the at least two further elements.A "free space" shall be understood to mean, in particular, a space bounded by at least one, and in particular by at least two, elements, specifically by at least two and preferably by at least three sides. In particular, the free space comprises at least a lower bounding surface formed by at least one sub-area of ​​a main area, at least one upper bounding surface formed by a further sub-area of ​​a main area that is separate from the first sub-area of ​​the main area, and at least one lateral bounding surface formed by the spacer element. Preferably, the free space is provided for the storage of at least one insert tool. In particular, the height of the free space formed by the spacer element and oriented at least substantially perpendicular to the respective sub-area of ​​the main areas is at least substantially equal to the thickness of the insert tool.The term "height that is oriented at least substantially perpendicular" to the respective sub-area of ​​the main areas" means, in particular, that the height forms an angle with the respective sub-areas of the main areas that deviates from 90° by less than 10°, preferably less than 7°, and particularly less than 5°. The phrase "height of the clearance is at least substantially equal to a thickness" of the insert tool means, in particular, that a value of the height deviates from a value of the thickness of the insert tool by less than 6%, preferably less than 4%, and particularly less than 2%. An embodiment according to the invention advantageously allows the insert tool packaging device to be customized in a process-reliable manner. Furthermore, the appearance of the insert tool packaging device can advantageously be modified to meet customer requirements.Furthermore, a robust tool packaging device can be advantageously achieved, which can be easily handled in a packaging machine.

[0004] Furthermore, it is proposed that the spacer element and the main areas be formed at least substantially from the same material. The phrase "at least substantially from the same material" is to be understood in particular as meaning that the spacer element and the main areas are formed from more than 60%, preferably more than 75%, and especially more than 90% of the same material.

[0005] In particular, the spacer element and the main areas are made of cardboard. An embodiment according to the invention advantageously results in a simple-to-manufacture insert tool packaging device.

[0006] Furthermore, it is proposed that the spacer element be designed to be glued to at least a portion of the main area. An embodiment according to the invention advantageously allows for a simplified process in a packaging machine by pre-gluing the insert tool packaging device at the supplier's site. Except for one final operation, the insert tool packaging device can be pre-glued at the supplier's site.

[0007] It is further proposed that the spacer element be formed integrally with at least one of the main areas. The phrase "integrally formed integrally with at least one of the main areas" is intended to mean, in particular, that the spacer element and the main area are formed at least substantially from one piece, and especially from the same piece. In particular, the spacer element and the main area are in direct contact with each other. The phrase "at least substantially from the same piece" is intended to mean, in particular, that the spacer element is formed from one piece to more than 60%, preferably more than 75%, and especially more than 90%, and that the main area is also formed from the same piece to more than 60%, preferably more than 75%, and especially more than 90%.In particular, the spacer element and the main area are formed from a single, continuous strip of the same material, for example, a strip of thin-film plastic, paper, and / or cardboard. An embodiment according to the invention advantageously results in a simple-to-manufacture insert tool packaging device.

[0008] Furthermore, it is proposed that the spacer element be connected to at least a sub-area of ​​the main area via at least one bend edge. A "bend edge" is understood to be, in particular, an edge designed to form a line that is at least substantially predefined and connects the spacer element and the sub-area of ​​the main area. Specifically, the bend edge is designed as an edge that, compared to the spacer element and the sub-area of ​​the main area, exhibits at least substantially a different material stability. For example, this differing material stability can be designed as a perforation, a groove, and / or a reduced wall thickness. In particular, the material stability is designed as an incision.Preferably, the incision has a cutting depth of at least substantially 50% of the wall thickness of the main region, thereby reducing the force required to buckle over the buckling edge by at least substantially 80% compared to buckling over a portion of the main region that is separate from a buckling edge. In this context, "at least substantially" means, in particular, that the deviation from a predetermined value is less than 25%, preferably less than 10%, and most preferably less than 5% of the predetermined value. The term "at least substantially predefined edge" means, in particular, an edge that is predefined to more than 60%, preferably more than 75%, and especially more than 90%.The phrase "the bending edge is designed as an edge which, compared to the spacer element and the sub-area of ​​the main area, exhibits at least a substantially different material stability" is to be understood in particular as meaning that the material stability of the bending edge and the material stability of the spacer element and the sub-area of ​​the main area differ by more than 50%, preferably by more than 65%, and particularly by more than 80%. An embodiment according to the invention advantageously allows for a simple pivotable mounting of the spacer element relative to the sub-area of ​​the main area.

[0009] Furthermore, it is proposed that the two main areas are connected by at least one folding line. A "folding line" is understood to be, in particular, a line of at least one unit, especially a thin-film packaging unit, designed to form an at least substantially predefined line that divides the at least one unit into at least two main areas and over which the at least one unit can be folded. Preferably, the at least one folding line is designed as a line over which the main areas are pivotably connected to one another. In particular, the folding line is designed as a line that, compared to the two main areas, exhibits at least substantially different material stability.For example, at least one differing material stability can be achieved through perforation, grooving, reduced wall thickness, and / or a predefined bending edge.

[0010] The phrase "at least substantially predefined line" is understood to mean, in particular, a line that is predefined to more than 60%, preferably to more than 75%, and especially to more than 90%. The phrase "that the folding line is designed as a line which, compared to the two main areas, exhibits at least substantially differing material stability" is understood to mean, in particular, that the material stability of the folding line and the material stability of the two main areas differ by more than 50%, preferably by more than 65%, and especially by more than 80%. An embodiment according to the invention advantageously results in a simple-to-manufacture and simple-to-fold insert tool packaging device.

[0011] It is further proposed that the thin-film packaging unit include at least one protective unit designed to cover at least one area of ​​the insert tool, at least in the packaged state. A "protective unit" is understood to mean, in particular, a unit that, in at least one state of the thin-film packaging unit, especially in the packaged state, is designed to cover at least one area of ​​at least one insert tool, in particular at least one machining area of ​​the insert tool. Specifically, the protective unit is intended to protect an operator during handling of the thin-film packaging unit. Preferably, the protective unit protects the operator from injury caused by at least one insert tool located within the thin-film packaging unit during handling.In particular, the protective unit protects the operator from cuts caused by the processing area, preferably a cutting edge, of the insert tool stored in the thin-film packaging unit. An embodiment according to the invention advantageously achieves safe and harmless storage of the insert tool within the thin-film packaging unit. In particular, it advantageously protects the operator from injury when handling the thin-film packaging unit.

[0012] In a further embodiment of the invention, a device for manufacturing an insert tool packaging device according to the invention is proposed. An embodiment according to the invention advantageously enables the insert tool packaging device to be manufactured quickly, reproducibly, and precisely.

[0013] In a further embodiment of the invention, a method for manufacturing an insert tool packaging device according to the invention is proposed. An embodiment of the invention advantageously allows the insert tool packaging device to be manufactured reproducibly.

[0014] In a further embodiment of the invention, a system comprising at least one insertion tool and an insertion tool packaging device according to the invention is proposed. An embodiment according to the invention advantageously allows at least one insertion tool to be packaged in an insertion tool packaging device according to the invention. drawing

[0015] Further advantages will become apparent from the following description of the drawings. The drawings illustrate two exemplary embodiments of the invention. The drawings, the description, and the claims contain numerous features in combination. A person skilled in the art will expediently consider the features individually and combine them into meaningful further combinations.

[0016] They show: Fig. 1 a tool packaging device according to the invention in an unpackaged state in a top view and Fig. 2 an alternative embodiment of the insert tool packaging device according to the invention in a pre-packaged state. Description of the exemplary implementations

[0017] Fig. Figure 1 shows in an unpacked state in a top view the insert tool packaging device 10 according to the invention, in particular a saw blade packaging device, with a thin-film packaging unit 12 having two main areas 14, 16, and with four spacer elements 18, 20, 22, 24 by means of which, in at least one packaged state of the thin-film packaging unit 12, a free space 26 is produced between two sub-areas 52, 54 of the main areas 14, 16, which is provided for the storage of five insert tools 28. Main area 14 comprises spacer elements 18, 20, a lower part 74, and an upper part 72. Main area 14 comprises spacer elements 22, 24, a lower part 74, and an upper part 72. The respective sub-areas 52, 54 of the respective main areas 14, 16 each comprise the upper part 72 and the lower part 74 of the respective main areas 14, 16. The packaged state of the thin-film packaging unit 12 is shown in the Fig. 1 and Fig. 2 not shown. Based on a Fig. In the pre-packaged state shown in Figure 2, the function of the thin-layer packaging unit 12 in the packaged state can be well explained, since the free space 26 and the insertion tools 28 are well represented.

[0018] How Fig. As shown in Figure 1, the spacer elements 18 and 20 are integrally formed with the main section 14 of the main sections 14 and 16. The spacer elements 18 and 20 are each connected to the subsection 52 of the main section 14 via a bend edge 30 and 32, respectively. The respective bend edge 30 and 32 are aligned parallel to a longitudinal extension 38 of the main section 14. The spacer elements 18 and 20, and thus the bend edges 30 and 32, are arranged on opposite sides of the subsection 52 of the main section 14 with respect to a transverse direction 40. The spacer element 18 has a width 42. The spacer element 20 has a width 44. A value of the width 42 of the spacer element 18 is less than a value of the width 44 of the spacer element 20.By adding the width 42 of the spacer element 18, the width 44 of the spacer element 20, and a distance 46 parallel to the transverse direction 40 between the bend edges 30, 32, a transverse extent 48 of the main area 14 can be calculated. The width 44 of the spacer element 20 is in the Fig. In the embodiment shown in Figure 1, the distance is 10 mm. The distance 46 between the bend edges 30, 32 is 80 mm. Similarly, the spacer elements 22, 24 are formed integrally with the main area 16 of the main areas 14, 16. The spacer element 24 has a width 42. The spacer element 22 has a width 44.

[0019] The main areas 14 and 16 each have a longitudinal extent 38 of less than 250 mm. However, it is also conceivable that main areas 14 and 16 each have a greater longitudinal extent. The longitudinal extent 38 is 247 mm in each case. The two main areas 14 and 16 are connected by a fold line 34. The two main areas 14 and 16 together have a total transverse extent 50 of less than 200 mm. However, it is also conceivable that main areas 14 and 16 have a greater total transverse extent. The total transverse extent 50 is 198.5 mm. An arrangement of the main areas 14 and 16, and thus of the spacer elements 18, 20, 22, and 24, is symmetrical with respect to the fold line 34. Only the design of the respective sub-areas 52, 54 of the main areas 14, 16 differs.Thus, spacer element 24 is arranged in a mirror-symmetrical manner with respect to spacer element 18, and spacer element 22 is arranged in a mirror-symmetrical manner with respect to spacer element 20. Specifically, spacer elements 18 and 24 each have a width of 42, and spacer elements 20 and 22 each have a width of 44. Spacer element 22 is connected to sub-section 54 of main section 16 via a fold edge 56. The fold edge 56 is arranged symmetrically with respect to the fold edge 32. Spacer element 24 is connected to sub-section 54 of main section 16 via a fold edge 58. The fold edge 58 is arranged symmetrically with respect to the fold edge 30. A transverse extent 48 of the main area 16 is equal to the transverse extent 48 of the main area 14. In addition, a distance 46 of the fold edges 56, 58 is equal to the distance 46 of the fold edges 30, 32.

[0020] The spacer elements 18, 20, 22, 24 and the main sections 14, 16 are made of the same material. Both the spacer elements 18, 20, 22, 24 and the main sections 14, 16 are made of cardboard. A length 62 of each spacer element 18, 24, oriented parallel to a longitudinal direction 60, is at least substantially 80% of the longitudinal extent 38 of the respective main section 14, 16. The spacer elements 18, 24 are rectangular and are connected with respect to the longitudinal direction 60 in the lower part 74 of the respective main section 14, 16 to the respective subsection 52, 54 of the respective main section 14, 16. A length 64 of the respective spacer elements 20, 22 in a respective contact area to the respective sub-areas 52, 54 of the main areas 14, 16 is at least substantially 96% of the longitudinal extent 38 of the respective main areas 14, 16.The spacer elements 20, 22 are connected centrally to the respective sub-areas 52, 54 of the main areas 14, 16. A length 66 of the respective spacer elements 20, 22 in a contact area between the spacer elements 20, 22 is at least substantially 90% of the longitudinal extent 38 of the respective main areas 14, 16. The length 66 of the respective spacer elements 20, 22 in the contact area between the spacer elements 20, 22 corresponds to an extent of the fold line 34. The fold line 34 is arranged centrally to the respective main areas 14, 16. The length of the spacer elements 20, 22 decreases continuously and uniformly from both sides from the contact area to the respective sub-areas 52, 54 of the main areas 14, 16, where the spacer elements 20, 22 have a length of 64, up to the contact area of ​​the spacer elements 20, 22 among themselves, where the spacer elements 20, 22 have a length of 66.

[0021] The two main areas 14, 16 each have a suspension opening 68, which is arranged in the respective sub-area 52, 54 of the main areas 14, 16. The suspension openings 68 of the respective main areas 14, 16 are aligned parallel to the transverse direction 40 and arranged symmetrically with respect to the fold line 34. The suspension openings 68 of the respective main areas 14, 16 are located in an upper part 72 of the respective main area 14, 16 with respect to the longitudinal direction 60 and centrally within the respective main area 14, 16 with respect to the transverse direction 40.

[0022] The main area 16 has a perforation 70 oriented in the transverse direction 40, which separates the main area 16, the upper part 72, and the lower part 74. Similarly, the main area 14 has a contact line 86, which lies on an imaginary continuation of the perforation 70 and separates the main area 14 into the upper part 72 and the lower part 74. In the packaged state of the thin-film packaging unit 12, the perforation 70 lies on the contact line 86. The suspension openings 68 are each located in the upper part 72 of the respective main areas 14 and 16.

[0023] The thin-film packaging unit 12 has five protective units 36, which are designed to cover an area of ​​the insert tools 28 in the packaged state. The protective units 36 are each connected to a part of the main area 14 by a fold line 76. In the Fig. 1 and Fig. For the sake of clarity, only one of the protective units 36 and one of the fold lines 76 are provided with reference symbols. The protective units 36 are arranged centrally in the main area 14 and aligned parallel to the longitudinal direction 60. Since the respective lower part 74 of the main areas 14, 16 has a greater extent parallel to the longitudinal direction 60 than the respective upper part 72, the protective units 36 are arranged in the lower part 74 of the main area 14. Furthermore, the protective units 36 each have a lower end with respect to the longitudinal direction 60, with four of the five lower ends of the protective units 36 being arranged on a connecting line 78 parallel to the transverse direction 40. The protective units 36 each have a different extent along the longitudinal direction 60. The extent of the protective units 36 increases continuously in the transverse direction 40. In the Fig. In the unpackaged state shown in Figure 1, the protective units 36 are arranged in a plane spanned by the main area 14. In the Fig. In the pre-packaged state shown in Figure 2, as well as in the packaged state not shown, the protective units 36 enclose an angle between excluding 0° and including 90° with the plane spanned by the main area 14, depending on the packaging state of the thin-layer packaging unit 12.

[0024] The main area 16 has two viewing windows 80, 82. A lower end of viewing window 82 lies on the connecting line 78. The viewing window 82 is designed such that all five protective units 36, and thus all five insertion tools 28, are visible through the viewing window 82 in the packed state. In particular, all five protective units 36, in the packed state, can extend through the viewing window 82 by means of a pivotable mounting on the part of the main area 14 achieved via the respective folding lines 76. The geometry of the viewing window 82 can be freely chosen. In particular, the extent of the viewing window 82 decreases continuously in the transverse direction 40, just as the extent of the protective units 36 increases continuously in the transverse direction 40.

[0025] The viewing window 80 is shaped like a square. The viewing window 80 is located in an upper region of the lower part 74 of the main region 16 with respect to the longitudinal direction 60, and in a region of the lower part 74 of the main region 16 that corresponds to the fold line 34 with respect to the transverse direction 40. In the packaged state of the thin-film packaging unit 12, the viewing window 80 is designed to make a region of an inserting tool 28 visible. In particular, in the packaged state of the thin-film packaging unit 12, a shaft of one of the inserting tools 28, especially the inserting tool 28 that corresponds to the fold line 34 with respect to the transverse direction 40, is visible through the viewing window 80.

[0026] The in Fig. The embodiment of the insert tool packaging device 10 shown in Figure 1 differs from the one shown in Figure 1. Fig. The embodiment of the insert tool packaging device 10 shown in 2 differs only in two respects, which is why identical reference numerals are used in the following. Firstly, the device differs in Fig. 1 shown embodiment of the insert tool packaging device according to the invention from the one in the Fig. 2. In the exemplary embodiment of the insert tool packaging device 10 according to the invention, the geometry of the protective units 36 and the viewing window 82 is shown. Furthermore, in the exemplary embodiment of the Fig. 1 in contrast to the embodiment of the Fig. 2. Perforation 70 and installation line 86 are present.

[0027] The Fig. Figure 2 shows the insert tool packaging device 10 in its pre-packaged state. Furthermore, in Fig. Figure 2 shows a system with five insert tools 28 and the insert tool packaging device 10 according to the invention. To remove the unpackaged state of the Fig. To achieve the packaged state of the thin-film packaging unit 12, the spacer elements 22, 24 are first folded over their respective fold edges 56, 58 onto the sub-area 54 of the main area 16 such that the spacer elements 22, 24 lie flat on the sub-area 54 of the main area 16. In the packaged state, the spacer elements 22, 24 are glued to the sub-area 54 of the main area 16. Thus, the spacer elements 22, 24 are designed to be glued to the sub-area 54 of the main area 16. Similarly, the spacer elements 18, 20 are designed to be glued to the sub-area 52 of the main area 14. In the Fig. In the embodiment shown in Figure 2, the spacer elements 18 and 20 are glued to the sub-area 52 of the main area 14, and the spacer element 24 is glued to the sub-area 54 of the main area 16. The spacer element 22 is glued to the spacer element 20 after being folded around the fold line 34.

[0028] To position the insertion tools 28 in the thin-film packaging unit 12, the protective units 36 must first be removed from the one in Fig. In the pre-packaged state of the thin-film packaging unit 12 shown in Figure 1, the protective units 36 are folded out in the plane defined by the main area 14, so that the protective units 36 form an angle between 0° excluding and 90° inclusive with the plane defined by the main area 14. After the protective units 36 form an angle between 0° excluding and 90° inclusive with the plane defined by the main area 14, the respective insert tools 28 can be placed in the resulting opening 88. The insert tools 28 are positioned under the erected protective units 36 to protect an operator of the insert tool packaging device 10 from a processing area, preferably a cutting edge, of the insert tools 28. Of the five openings 88 in total, one is located in the Fig. For clarity, only one is shown with a reference mark. The protective units 36 are then folded in the opposite direction to the previous direction onto the area of ​​the insertion tools 28. In the packaged state, the protective units 36 are placed onto an area of ​​the insertion tools 28 inserted in the thin-film packaging unit 12.

[0029] To transition from the pre-packaged state to the packaged state, the sub-section 54 of the main section 16 must be folded around the crease 56. To keep the thin-film packaging unit 12 in the packaged state, it is designed to be completely glued, except for the space 26, which is intended for storing the insert tools 28. Thus, after folding the sub-section 54 of the main section 16 around the crease 56, the main section 16 is glued to the main section 14 and the spacer elements 18, 20, 22, 24 already glued to the sub-sections 52 and 54 of the main sections 14 and 16, excluding the space 26 from being glued. Accordingly, in the packaged state, the sub-areas 52, 54 of the main areas 14, 16 are separated on two sides each by two glued-on-one spacer elements 18, 24 and 20, 22.The resulting free space 26 has a height oriented perpendicular to the sub-areas 52, 54 of the main areas 14, 16, and thus perpendicular to the transverse direction 40 and the longitudinal direction 60, which corresponds to the thickness of the insert tools 28. Consequently, the insert tools 28 are pressed firmly into position in the packaged state, thus preventing them from slipping within the thin-film packaging unit 12. However, it is also conceivable that the free space 26 has a height oriented perpendicular to the sub-areas 52, 54 of the main areas 14, 16, and thus perpendicular to the transverse direction 40 and the longitudinal direction 60, with a dimension that would appear sensible to a person skilled in the art.

[0030] In Fig. Figure 1 further shows, schematically in dashed lines, a device 84 according to the invention for manufacturing the insert tool packaging device 10 according to the invention. The device 84 uses a method for manufacturing the insert tool packaging device 10 according to the invention. After manufacturing, the insert tool packaging device 10 assumes a position in the Fig. 1. The form shown.

Claims

[1] Tool packaging device, in particular saw blade packaging device, with at least one thin-layer packaging unit (12) having at least two main areas (14, 16), characterized by at least one spacer element (18, 20, 22, 24) by means of which, in at least one packaged state of the thin-film packaging unit (12), at least one free space (26) is produced between at least two sub-areas (52, 54) of the main areas (14, 16), which is provided for the storage of at least one insert tool (28), wherein the two main areas (14, 16) are connected by at least one fold line (34), wherein the spacer elements (22, 24) are provided to be glued onto the sub-area (54) of the main area (16). [2] Insert tool packaging device according to claim 1, characterized by , that the spacer element (18, 20, 22, 24) and the main areas (14, 16) are formed at least substantially from the same material. [3] Insert tool packaging device according to claim 1 or 2, characterized by , that the spacer element (18, 20) is intended to be glued onto at least a partial area (52) of the main area (14). [4] Tool packaging device according to one of the preceding claims, characterized by , that the spacer element (18, 20) is formed in one piece with at least one main area (14) of the main areas (14, 16). [5] Insert tool packaging device according to claim 4, characterized by , that the spacer element (18, 20) is connected via at least one bend edge (30, 32) to at least one sub-area (52) of the main area (14). [6] Tool packaging device according to one of the preceding claims, characterized bythat the thin-layer packaging unit (12) has at least one protective unit (36) which is designed to cover at least one area of ​​the insertion tool (28) at least in the packaged state. [7] Device for manufacturing a tool packaging device (10) according to any one of claims 1 to 6. [8] Method for manufacturing a tool packaging device (10) according to any one of claims 1 to 6. [9] System comprising at least one insertion tool (28) and an insertion tool packaging device (10) according to any one of claims 1 to 6.

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