JP2021112154A - Boning tool - Google Patents

Abstract

To provide a boning tool which can easily remove a bone.SOLUTION: A boning tool 1 includes a first arm part 2, a second arm part 3, a first work part 4, and a second work part 5. The second arm part 3 is continuously provided to the first arm part 2 such as to be substantially mirror-symmetry with an interval from the first arm part 2 with a predefined virtual plane as a reference. The first work part 4 and the second work part 5 are configured to be substantially flat. The first work part 4 is continuously provided on the first arm part 2 on the side opposite to the second arm part 3, and the second work part 5 is continuously provided on the second arm part 3 on the side opposite to the first arm part 2 such as to be substantially mirror-symmetry with an interval from the first work part 4 with a virtual plane as a reference. A first slip-prevention region 4A is provided on a surface of the first work part 4 facing the second arm part 3, and a second slip-prevention region 5A is provided on a surface of the second work part 5 facing the first work arm part 2 and can be in contact with the first work part 4 in a substantially parallel state with the virtual plane.SELECTED DRAWING: Figure 1

Description

The present invention relates to a boning tool. More specifically, the present invention relates to a bone-removing tool for extracting small bones of a fish, for example.

One of the concerns when eating cooked fish is the presence of fish bones.
This is because if the fish you eat has bones, the bones of the fish will stick in your throat and your throat will hurt, which will hurt your enjoyable meal.

Also, if a fish bone sticks in your throat during a normal meal, it rarely sticks deeply, and if you gargle, continue eating, or continue your daily life, it will almost naturally occur. Will come off.

However, it may stab deeply in the throat, in which case it is necessary to have a doctor remove the stabbed bone, and if you continue to eat and swallow the fish bone, the fish bone is the cause. There are case reports that cause abdominal diseases, and it is desirable to remove fish bones as much as possible to provide fish dishes.

Therefore, various instruments for extracting bone have been proposed.
For example, Patent Document 1 describes the holding tool shown in FIG. The holding tool 101 described in Patent Document 1 has a substantially symmetrical V-shape as a whole and includes a pair of elastic holding pieces (110, 111) on the tip side.
Further, the one-side holding surface 110A is a flat surface, and the other-side holding surface 111A is a reduced plane cut out from the rear end side of the facing plane formed symmetrically with the one-side holding surface 110A.

That is, as shown in FIG. 5B, the other side holding surface 111A is a notched plane 111B that cuts the facing plane formed symmetrically with the one side holding surface 110A by the broken line at the upper end 111H and the lower end 111K. It is formed by cutting out.

Japanese Patent No. 64527773

However, in the sandwiching tool 101 described in Patent Document 1, when the sandwiching pieces (110, 111) are sandwiched, the upper end 111H serves as a protrusion and the opening at the tip becomes smaller to sandwich a short or small object to be held. On the other hand, it is necessary to hold the object to be held with a strong force so that the object to be held does not slip through.
If the object to be pinched is a fish bone, the bone will be cut if it is pinched with a strong force, and if the bone is cut, it will be more difficult to remove the bone.
In addition, in order to successfully extract bone without cutting it, some skill is required, and an instrument that can extract bone more easily has been required.

Further, as shown in FIG. 5B, since the holding pieces (110, 111) each extend from the tip to the base end, it is difficult to insert the holding pieces (110, 111) into the back of the fish body. On top of that, there is a problem that if you try to insert it, you will gouge the body of the fish and hurt the body of the fish.

The present invention has been devised in view of the above points, and an object of the present invention is to provide a bone removing tool capable of easily removing bone.

In order to achieve the above object, the watering tool of the present invention is substantially mirror-symmetrical with the first arm portion at a distance from the first arm portion with reference to a predetermined virtual plane. The second arm portion connected to the first arm portion is formed in a substantially flat plate shape, and is connected to the first arm portion on the side opposite to the second arm portion, and is connected to the first arm portion. The first working portion provided with the first non-slip region on the surface facing the second arm portion, and the first working portion formed in a substantially flat plate shape with the virtual plane as a reference. The second arm portion is connected to the side opposite to the first arm portion so as to be substantially mirror-symmetrical at intervals, and a second arm portion is provided on the surface facing the first arm portion. A non-slip region is provided, and a second working portion that can come into contact with the first working portion in a state substantially parallel to the virtual plane is provided.

Here, the first arm portion and the second arm connected to the first arm portion so as to be substantially mirror-symmetrical with the first arm portion at a distance from the predetermined virtual plane as a reference. When a force is applied to the first arm portion and the second arm portion, the portions can bring each other closer to each other, or loosen the applied force to move them away from each other.

Further, it is formed in a substantially flat plate shape, is continuously provided on the side of the first arm portion opposite to the second arm portion, and has a first non-slip region on a surface facing the second arm portion. The first working part of the second arm part is formed in a substantially flat plate shape with the provided first working part, and is substantially mirror-symmetrical with the first working part at a distance from the virtual plane. It is connected to the side opposite to the arm part, a second non-slip area is provided on the surface facing the first arm part, and hits the first working part in a state substantially parallel to the virtual plane. The contactable second working part makes it easy to insert the first working part and the second working part into the back of the fish body, and the first working part and the second working part are deep into the fish body. Even if you insert it, it is hard to gouge the fish, so it is hard to hurt yourself.

Further, it is formed in a substantially flat plate shape, is continuously provided on the side of the first arm portion opposite to the second arm portion, and has a first non-slip region on a surface facing the second arm portion. The first working part of the second arm part is formed in a substantially flat plate shape with the provided first working part, and is substantially mirror-symmetrical with the first working part at a distance from the virtual plane. It is connected to the side opposite to the arm part, a second non-slip area is provided on the surface facing the first arm part, and hits the first working part in a state substantially parallel to the virtual plane. With the contactable second working portion, the fish bone can be pinched by the surface contact between the flat first non-slip area and the flat second non-slip area, and it is difficult to cut the bone.

Further, in the boning tool of the present invention, the thickness between the surface of the first working portion provided with the first non-slip region and the surface opposite to the first non-slip region is the first arm. The first inclined region, which is a region gradually decreasing toward the first tip edge portion, which is the edge portion of the first working portion on the opposite side of the portion, is the first inclined region of the first working portion. The thickness is provided on the surface opposite to the non-slip area, and the thickness between the surface of the second working portion provided with the second non-slip area and the surface opposite to the second non-slip area. The second inclined region, which is a region gradually decreasing toward the second tip edge portion, which is the edge portion of the second working portion opposite to the second arm portion, is the second. The configuration may be provided on the surface of the working portion opposite to the second non-slip region.

In this case, the first working unit and the second working unit are more than the first working unit not provided with the first inclined region and the second working unit not provided with the second inclined region. Easy to get into the body of fish.

Further, in the boning tool of the present invention, a surface substantially orthogonal to the surface of the first working portion provided with the first non-slip region is tapered toward the first tip edge portion. , The surface of the second working portion that is substantially orthogonal to the surface provided with the second non-slip region can be tapered toward the second tip edge portion.

In this case, the first working portion and the second working portion can be easily inserted deeply into the body of the fish.

Further, in the boning tool of the present invention, the first non-slip region is provided on the entire surface of the first working portion facing the second arm portion, and the second non-slip region is the second. The structure may be provided on the entire surface of the working portion facing the first arm portion.

In this case, the fish bones are larger than the configurations in which the first non-slip area and the second non-slip area are provided in a part of the first working part and a part of the second working part in the same area, respectively. Since the area of contact with the bone is large, it is easy to stably remove the bone.

Further, in the boning tool of the present invention, the length of the longest portion of the first working portion extending in substantially the same direction as the extending direction of the first arm portion and the length of the extending direction of the second arm portion are substantially the same. The length of the longest portion of the second working portion extending in the same direction can be configured to be at least 8 mm.

In this case, surface contact between the first non-slip region of the first working portion and the second non-slip region of the second working portion can be stably performed.

The bone removing tool according to the present invention can easily remove bone.

Schematic perspective view (a) showing the first form of the boning tool to which the present invention is applied, and an enlarged outline of the first working part and the second working part of the first form of the boning tool to which the present invention is applied. It is an enlarged partial plan view (b). It is a schematic perspective view (a) and a schematic side view (b) which show the boning tool of the 2nd form to which this invention is applied. It is a schematic perspective view (a) and a schematic side view (b) which show the boning tool of the 3rd form to which this invention is applied. It is the schematic which shows an example of the state of removing the bone of a fish using the bone-removing tool of the 1st form to which this invention is applied. It is a schematic view (a) which shows the whole of the conventional holding tool, and the schematic enlarged view (b) of the tip part of the conventional holding tool.

Hereinafter, embodiments of the present invention will be described with reference to the drawings for the purpose of understanding the present invention.
FIG. 1 (a) is a schematic perspective view showing a water removal tool of the first form to which the present invention is applied, and FIG. 1 (b) is a first view of the first form of the water removal tool to which the present invention is applied. It is a schematic enlarged partial plan view which enlarged the working part and the 2nd working part.

The watering tool 1 of the first aspect of the present invention shown in FIG. 1 includes a first arm portion 2 extending in the longitudinal direction.

Further, the boning tool 1 of the present invention includes a second arm portion 3.
Here, the second arm portion 3 extends in the longitudinal direction.
Further, the second arm portion 3 is connected to the first arm portion 2 so as to be substantially mirror-symmetrical with the first arm portion 2 at a distance from the predetermined virtual plane.
Further, FIG. 1B shows a line 6 indicating a virtual plane.

Further, the first arm portion 2 is provided with a first curved portion 2A bent toward the side opposite to the second arm portion 3.
Further, the second arm portion 3 is provided with a second curved portion 3A bent toward the side opposite to the first arm portion 2.

By providing the first curved portion 2A and the second curved portion 3A to the first arm portion 2 and the second arm portion 3, respectively, the second arm portion of the first arm portion 2 is provided. The side opposite to 3 and the side of the second arm portion 3 opposite to the first arm portion 2 are brought close to each other.

Further, the boning tool 1 of the present invention includes a first working unit 4.
Here, the first working portion 4 is formed in a substantially flat plate shape, and is continuously provided on the side of the first arm portion 2 opposite to the second arm portion 3.
Further, the first non-slip region 4A is provided on the entire surface of the first working portion 4 facing the second arm portion 3.

Further, a first inclined region 4C is provided on the surface of the first working portion 4 opposite to the first non-slip region 4A.
Here, the first inclined region 4C has a thickness between the surface of the first working portion 4 provided with the first anti-slip region 4A and the surface opposite to the first anti-slip region 4A. Is a region that gradually becomes smaller toward the first tip edge portion 4B, which is the edge portion of the first working portion 4 on the side opposite to the first arm portion 2.

Further, the boning tool 1 of the present invention includes a second working portion 5.
Here, the second working portion 5 is formed in a substantially flat plate shape, and the second arm portion 3 is substantially mirror-symmetrical with the first working portion 4 at a distance from the virtual plane. It is continuously provided on the side opposite to the first arm portion 2.

Further, the second work portion 5 is provided with the second non-slip region 5A on the entire surface of the surface facing the first arm portion 2, and the first work is performed in a state substantially parallel to the virtual plane. It can come into contact with the portion 4.
That is, in the normal water removal tool 1 of the present invention, the first working unit 4 and the second working unit 5 face each other with the virtual plane 6 as shown in FIG. 1 (b).

Further, a second inclined region 5C is provided on the surface of the second working portion 5 opposite to the second non-slip region 5A.
Here, the second inclined region 5C has a thickness between the surface of the second working portion 5 provided with the second anti-slip region 5A and the surface opposite to the second anti-slip region 5A. Is a region that gradually becomes smaller toward the second tip edge portion 5B, which is the edge portion of the second working portion 5 on the side opposite to the second arm portion 3.

Further, the first non-slip region 4A and the second non-slip region 5A are regions in which the surface of the first working portion 4 and the surface of the second working portion 5 are treated to be non-slip, respectively. Specifically, the region is unevenly processed in a mesh shape, but it goes without saying that any treatment may be used as long as it is a treatment that makes it difficult to slip.

Further, the length of the longest portion of the first working portion 4 extending in substantially the same direction as the extending direction of the first arm portion 2 and the length of the longest portion extending in substantially the same direction as the extending direction of the second arm portion 3 The length of the longest portion of the extended second working portion 5 is at least 8 mm, specifically, for example, 10 mm.

That is, the lengths of the two surfaces of the first working portion 4 that are substantially orthogonal to the surface provided with the first non-slip region 4A in the direction substantially the same as the direction in which the first arm portion 2 extends. Is 10 mm.
Further, the lengths of the two surfaces of the second working portion 5 that are substantially orthogonal to the surface provided with the second non-slip region 5A in the direction substantially the same as the direction in which the second arm portion 3 extends. Is 10 mm.

Further, as shown in FIG. 1, the outer shape of the first working part 4 and the outer shape of the second working part 5 are substantially quadrangular.

Further, the area of the surface of the first working unit 4 provided with the first non-slip area 4A and the area of the surface of the second working unit 5 provided with the second anti-slip area 5A are substantially the same. Is.

In the boring tool of the present invention, the surface of the first working portion opposite to the first non-slip region does not necessarily have to be provided with the first inclined region, and the second working portion of the second working portion. A second inclined region may not necessarily be provided on the surface opposite to the second non-slip region.

However, a first inclined region is provided on the surface of the first working portion opposite to the first non-slip region, and the second working portion is provided on the surface opposite to the second non-slip region. If the second inclined region is provided, the first work portion is more than the first working portion not provided with the first inclined region and the second working portion not provided with the second inclined region. It is preferable because the part and the second working part can easily get into the body of the fish.

Further, in the boning tool of the present invention, the first non-slip region does not necessarily have to be provided on the entire surface of the first working portion facing the second arm portion, and the second slip does not have to be provided. The stop region does not necessarily have to be provided on the entire surface of the second working portion facing the first arm portion.

However, the first non-slip area and the second non-slip area are on the entire surface of the first working part facing the second arm part and on the first arm part of the second working part, respectively. If it is provided on the entire surface of the facing surface, it is preferable because it is easy to stably remove the bone.

Further, the length of the longest portion of the first working portion extending in substantially the same direction as the first arm portion extending and the second extending in substantially the same direction as the extending direction of the second arm portion. The length of the longest part of the working portion of is not necessarily at least 8 mm.

However, if the length of the longest part of the first working part and the length of the longest part of the second working part are such lengths, the first non-slip of the first working part It is preferable because surface contact between the region and the second non-slip region of the second working portion can be stably performed.

FIG. 2A is a schematic perspective view showing a second form of the boning tool to which the present invention is applied, and FIG. 2B is a schematic side view showing the second form of the boning tool to which the present invention is applied. It is a figure.

The boning tool 21 of the second embodiment of the present invention shown in FIG. 2 also includes a first arm portion 22 and a second arm portion 23 similar to the boning tool 1 of the first embodiment of the present invention.

Further, similarly to the boning tool 1 of the first aspect of the present invention, in the boning tool 21 of the second form of the present invention, the first arm portion 22 is provided with the first curved portion 22A, and the second A second curved portion 23A is provided on the arm portion 23 of the above.

Further, the boning tool 21 of the present invention includes a first working portion 24.
Here, the first working portion 24 is formed in a substantially flat plate shape, and is continuously provided on the side of the first arm portion 22 opposite to the second arm portion 23.
Further, although not shown, a first non-slip region is provided on the entire surface of the first working portion 24 facing the second arm portion 23.

Further, a first inclined region 24C is provided on the surface of the first working portion 24 opposite to the first non-slip region.
Here, the thickness of the first inclined region 24C is such that the thickness between the surface of the first working portion 24 provided with the first anti-slip region and the surface opposite to the first anti-slip region is increased. This is a region that gradually becomes smaller toward the first tip edge portion 24B, which is the edge portion of the first working portion 24 on the side opposite to the first arm portion 22.

Further, as shown in FIG. 2, the first tip edge portion 24B is formed on two surfaces of the first working portion 24 that are substantially orthogonal to the surface provided with the first non-slip region. It is tapered toward the surface, and the tapered region is the first tapered region 24D.
That is, as shown in FIG. 2, the outer shape of the first working portion 24 is a substantially triangular shape having the first tip edge portion 24B as an apex.

Further, the boning tool 21 of the present invention includes a second working portion 25.
Here, the second working portion 25 is formed in a substantially flat plate shape, and the second arm portion 23 is substantially mirror-symmetrical with the first working portion 24 at a distance from the virtual plane. It is continuously provided on the side opposite to the first arm portion 22.

Further, the second work portion 25 is provided with the second non-slip region 25A on the entire surface of the surface facing the first arm portion 22, and the first work is performed in a state substantially parallel to the virtual plane. It can come into contact with the portion 24.

Further, although not shown, a second inclined region is provided on the surface of the second working portion 25 opposite to the second non-slip region 25A.
Further, in the second inclined region as well as the first inclined region 24C, the surface of the second working portion 25 provided with the second anti-slip region 25A and the side opposite to the second anti-slip region 25A. This is a region where the thickness between the surface and the surface gradually decreases toward the second tip edge portion 25B, which is the edge portion of the second working portion 25 on the side opposite to the second arm portion 23. ..

Further, as shown in FIG. 2, the second tip edge portion 25B is formed on two surfaces of the second working portion 25 that are substantially orthogonal to the surface provided with the second non-slip region 25A. A taper is provided toward, and the tapered region is the second taper region 25D.
That is, as shown in FIG. 2, the outer shape of the second working portion 25 is a substantially triangular shape having the second tip edge portion 25B as an apex.

Further, the length of the longest portion of the first working portion 24 extending in substantially the same direction as the first arm portion 22 extends, and in substantially the same direction as the extending direction of the second arm portion 23. The length of the longest portion of the extended second working portion 25 is at least 8 mm, specifically, for example, 28 mm.

That is, the length of the portion corresponding to the base of the right triangle whose hypotenuse is the first tapered region 24D of the first working portion 24 is 28 mm, and the second tapered region 25D of the second working portion 25 is the hypotenuse. The length of the portion corresponding to the base of the right triangle is 28 mm.

Further, the area of the surface of the first working portion 24 provided with the first non-slip region and the area of the surface of the second working portion 25 provided with the second non-slip region 25A are substantially the same. be.

FIG. 3A is a schematic perspective view showing a third form of the boning tool to which the present invention is applied, and FIG. 3B is a schematic side view showing the third form of the boning tool to which the present invention is applied. It is a figure.

The boning tool 31 of the third form of the present invention shown in FIG. 3 also has the same first arm portion 32 and the same boning tool 21 of the first form of the present invention and the boning tool 21 of the second form of the present invention. A second arm portion 33 is provided.

Further, similarly to the boning tool 1 of the first aspect of the present invention and the boning tool 21 of the second form of the present invention, in the boning tool 31 of the third form of the present invention, the first arm portion 32 A first curved portion 32A is provided, and a second curved portion 33A is provided on the second arm portion 33.

Further, the boning tool 31 of the present invention includes a first working unit 34.
Here, the first working portion 34 is formed in a substantially flat plate shape, and is continuously provided on the side of the first arm portion 32 opposite to the second arm portion 33.
Further, although not shown, a first non-slip region is provided on the entire surface of the first working portion 34 facing the second arm portion 33.

Further, a first inclined region 34C is provided on the surface of the first working portion 34 opposite to the first non-slip region.
Here, the thickness of the first inclined region 34C is such that the thickness between the surface of the first working portion 34 provided with the first anti-slip region and the surface opposite to the first anti-slip region is increased. This is a region that gradually becomes smaller toward the first tip edge portion 34B, which is the edge portion of the first working portion 34 on the side opposite to the first arm portion 32.

Further, as shown in FIG. 3, the first surface of the first working portion 34, which is one of the two surfaces substantially orthogonal to the surface provided with the first non-slip region. The length in the same direction as the extending direction of the arm portion 32 is extremely longer than the length in the same direction as the extending direction of the first arm portion 32 on the other surface.
That is, as shown in FIG. 3, the outer shape of the first working portion 34 is a substantially right triangle with the first tip edge portion 34B as the hypotenuse.

Further, the boning tool 31 of the present invention includes a second working portion 35.
Here, the second working portion 35 is formed in a substantially flat plate shape, and the second arm portion 33 is substantially mirror-symmetrical with the first working portion 34 at a distance from the virtual plane. It is connected to the side opposite to the first arm portion 32.

Further, the second work portion 35 is provided with the second non-slip region 35A on the entire surface of the surface facing the first arm portion 32, and the first work is performed in a state substantially parallel to the virtual plane. It can come into contact with the portion 34.

Further, although not shown, a second inclined region is provided on the surface of the second working portion 35 opposite to the second non-slip region 35A.
Further, in the second inclined region as well as the first inclined region 34C, the surface of the second working portion 35 provided with the second anti-slip region 35A and the side opposite to the second anti-slip region 35A. This is a region where the thickness between the surface and the surface gradually decreases toward the second tip edge portion 35B, which is the edge portion of the second working portion 35 on the side opposite to the second arm portion 33. ..

Further, as shown in FIG. 3, a second surface of the second working portion 35, which is one of the two surfaces substantially orthogonal to the surface provided with the second non-slip region 35A. The length in the same direction as the extending direction of the second arm portion 33 is extremely longer than the length in the same direction as the extending direction of the second arm portion 33 on the other surface.
That is, the outer shape of the second working portion 35 is a substantially right triangle similar to a trapezoid, with the second tip edge portion 35B as the hypotenuse.

Further, the length of the longest portion of the first working portion 34 extending in substantially the same direction as the extending direction of the first arm portion 32, and substantially the same direction as the extending direction of the second arm portion 33. The length of the longest portion of the extended second working portion 35 is at least 8 mm, specifically, for example, 10 mm.

That is, one of the extremely long surfaces of the first working portion 34, which is substantially orthogonal to the surface provided with the first non-slip region, in the direction substantially the same as the direction in which the first arm portion 32 extends. The length is 10 mm.
Further, one of the extremely long surfaces of the second working portion 35 that is substantially orthogonal to the surface provided with the second non-slip region 35A, in substantially the same direction as the direction in which the second arm portion 33 extends. The length of is 10 mm.

Further, the area of the surface of the first working portion 34 provided with the first non-slip region and the area of the surface of the second working portion 35 provided with the second non-slip region 35A are substantially the same. be.

Further, as a modification of the boning tool of the present invention shown in FIG. 1, a direction in which the first arm portion is substantially orthogonal to the extending direction, that is, the longitudinal direction and passes through two opposing edges of the first arm portion. That is, the length of the first working portion in the same direction as the lateral direction can be made longer than the length of the first arm portion in the lateral direction.

At this time, neither of the two facing edges of the first working portion other than the first tip edge portion is located in substantially the same plane as the two facing edges of the first arm portion. (Approximately T-shaped) or one of the two opposing edges of the first working portion other than the first tip edge is one of the two opposing edges of the first arm. It is located in substantially the same plane as the edge, and the other edge of the two opposing edges of the first working portion is the other edge of the two opposing edges of the first arm. It is possible to have a configuration (substantially L-shaped) that is not located in substantially the same plane.

Next, a method of using the boning tool of the present invention will be described.
FIG. 4 is a schematic view showing an example of a state in which a fish bone is extracted using the bone-removing tool of the first embodiment to which the present invention is applied.

A boning worker who intends to pull out the small bone 41 of the cut fish fillet 40 uses his hand 42 to hold the first arm portion 2 and the second arm portion 3 of the boning tool 1 of the present invention as shown in FIG. Have.

Then, the first working portion 4 and the second working portion 5 of the boning tool 1 of the present invention are directed toward the small bone 41, and the first arm portion 2 and the second arm portion 3 are pushed with the fingers of the hand 42 to perform the first. The arm portion 2 and the second arm portion 3 of the above are brought close to each other.
At this time, one surface of the first working unit 4 provided with the first anti-slip area 4A and one surface of the second working unit 5 provided with the second anti-slip area 5A are also close to each other. ..

Then, surface contact between one surface of the first working unit 4 provided with the first anti-slip area 4A and one surface of the second working unit 5 provided with the second anti-slip area 5A. The small bone 41 is sandwiched by.

Further, the small bone 41 is sandwiched between the flat first non-slip area 4A of the first working part 4 and the flat second non-slip area 5A of the second working part 5, and the small bone 41 is a fish fillet. Extract from 40.

In the example shown in FIG. 4, a method for extracting a small bone 41 existing at a relatively shallow position of the fish fillet 40 is described, but when extracting a small bone existing at a relatively deep position of the fish fillet 40, the method is described. The first working part 4 and the second working part 5 are inserted into the fish fillet 40 to sandwich the small bones, and the small bones are pulled out in the sandwiched state.

As described above, since the boning tool of the present invention includes the first working part and the second working part, it is easy to insert the first working part and the second working part into the back of the fish body. In addition, the fish bone can be pinched by the surface contact between the flat first non-slip region of the first working portion and the flat second non-slip region of the second working portion, and it is difficult to cut the bone.

Therefore, the bone-removing tool of the present invention can easily remove bone.

1 Boneless tool 2 1st arm part 2A 1st curved part 3 2nd arm part 3A 2nd curved part 4 1st working part 4A 1st non-slip area 4B 1st tip edge 4C 1st Inclined area 5 2nd working part 5A 2nd non-slip area 5B 2nd tip edge 5C 2nd inclined area 6 Line showing virtual plane 21 Boneless tool 22 1st arm part 22A 1st curved part 23 2nd arm part 23A 2nd curved part 24 1st working part 24B 1st tip edge part 24C 1st inclined area 24D 1st tapered area 25 2nd working part 25A 2nd non-slip area 25B 2nd tip edge 25D 2nd taper area 31 Bolting tool 32 1st arm 32A 1st bend 33 2nd arm 33A 2nd bend 34 1st working part 34B 1st Tip edge 34C 1st tilted area 35 2nd working part 35A 2nd non-slip area 35B 2nd tip edge 40 Fish fillet 41 Small bone 42 Hands

Claims (5)

The first arm part and
With reference to a predetermined virtual plane, a second arm portion connected to the first arm portion so as to be substantially mirror-symmetrical with a distance from the first arm portion, and
It is formed in a substantially flat plate shape, is continuously provided on the side of the first arm portion opposite to the second arm portion, and has a first non-slip region on a surface facing the second arm portion. The first working part provided with
The side of the second arm portion opposite to the first arm portion so as to be formed in a substantially flat plate shape and substantially mirror-symmetrical with the first working portion at a distance from the virtual plane. A second non-slip region is provided on the surface facing the first arm portion, and the first working portion can be brought into contact with the first working portion in a state substantially parallel to the virtual plane. A watering tool with a second working section. The thickness between the surface of the first working portion provided with the first non-slip region and the surface opposite to the first non-slip region is the side opposite to the first arm portion. The first inclined region, which is a region gradually decreasing toward the first tip edge portion, which is the edge portion of the first working portion, is the first non-slip region of the first working portion. It is provided on the side opposite to the area and
The thickness between the surface of the second working portion provided with the second anti-slip region and the surface opposite to the second anti-slip region is the side opposite to the second arm portion. The second inclined region, which is a region gradually decreasing toward the second tip edge portion, which is the edge portion of the second working portion, is the second anti-slip region of the second working portion. The watering tool according to claim 1, which is provided on the surface opposite to the area. A surface of the first working portion that is substantially orthogonal to the surface provided with the first non-slip region is tapered toward the first tip edge portion.
The watering according to claim 2, wherein a surface of the second working portion that is substantially orthogonal to the surface provided with the second non-slip region is tapered toward the second tip edge portion. Ingredients. The first non-slip region is provided on the entire surface of the first working portion facing the second arm portion.
The water removal tool according to claim 1, claim 2 or claim 3, wherein the second non-slip region is provided on the entire surface of the second working portion facing the first arm portion. The length of the longest portion of the first working portion extending in substantially the same direction as the extending direction of the first arm portion and the length of the longest portion extending in substantially the same direction as the extending direction of the second arm portion. The watering tool according to claim 1, claim 2, claim 3 or claim 4, wherein the length of the longest portion of the second working portion is at least 8 mm.

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