JP5169372B2 - Mesh body manufacturing equipment - Google Patents

Description

  The present invention relates to an apparatus for manufacturing a mesh-like body that can be used for a separator of a fuel cell, a filter of a radiator, and the like.

As a manufacturing apparatus of this kind of mesh-like body, a manufacturing apparatus that forms a mesh-like opening on a metal board by closing the second mold (pressing operation) with respect to the first mold is known. Yes (see Patent Document 1).
In this known technique, the first mold has a two-step shape (a straight two-stage blade). The second mold is also a two-step staircase that can face the first mold, and uneven blades are formed in a wave shape in the width direction in the first and second stages. The second-stage waveform is shifted by a half wavelength in the width direction with respect to the first-stage waveform (so-called staggered).
According to this known technique, the first die and the second die are closed and the metal board is clamped to form two upper and lower (staggered) cuts, and at the same time, the staggered cuts are closed. It can be expanded in a mesh shape with a pressing force of.
JP 2003-33824 A

However, in the above-described known technology, a plurality of press operations are required to produce a mesh body as a product (for example, to form a mesh on substantially the entire surface of a metal board).
However, it is only necessary to increase the number of steps in the manufacturing equipment, but this requires a significant change in the shape of the mold, and variations in the size of the cut for each step (caused by blade thickness dimension errors and installation errors) Variation) and product accuracy is extremely deteriorated. That is, in the configuration in which the cut is expanded by pressing as in the known art, the board portion around the cut is pulled and deformed by being pulled closer to the cut. At this time, if the size of the notch differs from stage to stage, the degree of extension around the board for each stage becomes uneven (so-called circumferential length difference), and for example, the board portion around the mesh may be distorted or cracked. The product accuracy will be extremely poor.
The present invention has been devised in view of the above points, and the problem to be solved by the present invention is to form a larger number of openings while keeping the extension of the metal board as constant as possible.

As means for solving the above problems, the mesh body manufacturing apparatus of the first invention includes a first inclined blade surface portion fixed to the first mold by closing the second mold with respect to the first mold. In this configuration, a mesh-like opening is formed in the metal board at the second inclined blade surface portion fixed to the second mold.
In the present invention, the metal board is sandwiched between the first inclined blade surface portion and the second inclined blade surface portion, and the metal board is expanded while being cut (opening is formed by a pressing force for closing the mold). Care should be taken not to cause distortion or the like in the body.

Therefore, in the present invention, the first mold and the second mold are closed, the first pressing surface portion elastically supported with respect to the first mold, and the second elastically supported with respect to the second mold. At the pressing surface portion, the board portion around both inclined blade surface portions is narrowed.
Then, the metal board is bent and deformed so as to face both inclined blade surface portions by both pressing surface portions, and then both pressing surface portions are moved in the elastic direction by the pressing force of mold closing. And (while maintaining the narrow pressure state of the board portion by both pressing surface portions as much as possible), the first inclined blade surface portion protruding from the first pressing surface portion and the second inclined blade surface portion protruding from the second pressing surface portion face each other The opening was formed by sandwiching the metal board formed into a shape.
In this way, even if the plurality of cuts provided in the metal board are expanded by the pressing force for closing the mold (for example, a mesh is formed on substantially the entire surface of the metal board), the degree of extension of the board portion is increased by both pressing surface portions. It can be as constant as possible.

A mesh-shaped body manufacturing apparatus according to a second aspect of the present invention is the mesh-shaped body manufacturing apparatus according to the first aspect of the present invention, wherein the first inclined blade surface portion has a wave-shaped first blade member and a first blade member. The wavy second blade members having an opposite phase to each other are alternately arranged in a step shape. Moreover, a 1st blade member and a 2nd blade member are arrange | positioned by the arrangement | positioning which can mesh | engage with a 1st inclination blade surface part in the above-mentioned 2nd inclination blade surface part.
And each blade member of a 1st inclination blade surface part and each blade member of a 2nd inclination blade surface part are meshed | engaged, and it expands, making a cut in a metal board. With such a configuration, by appropriately increasing or decreasing the number of first blade members and second blade members (number of blades), a desired number of openings can be formed relatively easily without changing the mold shape (for example, A mesh can be formed on substantially the entire surface of the metal board).

  According to the first aspect of the present invention, a mesh-like body with high product accuracy can be manufactured by forming a larger number of openings while keeping the extension degree of the metal board as constant as possible. In the second invention, a mesh-like body having a desired numerical aperture can be manufactured relatively easily.

The best mode for carrying out the present invention will be described below with reference to FIGS.
Then, the direction of each member is determined based on the arrangement state of the manufacturing apparatus shown in FIG. 1. Appropriately attached to each figure. In each drawing, for convenience of explanation, the number of blade members may be thinned out to some extent.

The manufacturing apparatus 2 of the present embodiment includes a first mold 4F and a second mold 6S that can be closed with respect to each other with reference to FIG. The first mold 4F is provided with a first inclined blade surface portion 20f, and the second mold 6S is provided with a second inclined blade surface portion 20s (detailed configuration of each member will be described later). An opening is formed in the metal board BD by the inclined blade surface portions 20f and 20s by the pressing force for closing the mold. However, this causes a difference in the circumferential length of the metal board BD and the product accuracy of the mesh-like body is increased. May get worse.
Therefore, in the present embodiment, the pressing surface portions (40f, 40s, detailed configuration will be described later) provided on the first mold 4F and the second mold 6S, respectively, without causing a difference in circumference on the metal board BD as much as possible. The opening was formed with high accuracy. Hereinafter, each component will be described in detail.

[First type]
1st mold | type 4F (substantially rectangular fixed type | mold) is provided with the 1st inclination blade surface part 20f which shape | molds opening in metal board BD, and the below-mentioned 1st press surface part 40f with reference to FIG.1 and FIG.2.
(First inclined blade surface)
The first inclined blade surface portion 20f of the present embodiment is a substantially rectangular box fixed to the concave portion 12f of the first mold 4F (the concave portion at the center of the mold closing surface 4aF). The upper side of the first inclined blade surface portion 20f (the side facing the second mold 6S) has an inclined crank shape, and an upward inclined portion 22f is formed from the front side to the rear side.
A storage window portion 24f (detailed configuration will be described later) in which a first blade member 14 and a second blade member 16, which will be described later, are stored is formed in the inclined portion 22f.

  In addition, a pair of groove portions 26f and 26f are formed on the lower side of the first inclined blade surface portion 20f with reference to FIG. The pair of grooves 26f and 26f are formed in an upwardly inclined shape (an upwardly inclined shape corresponding to the inclined portion 22f) so as to gradually become deeper from the front side to the rear side of the first inclined blade surface part 20f. The pair of groove portions 26f and 26f are configured to traverse in an inclined manner while piercing both side walls 28f in the storage window portion 24f.

(Storage window)
And the storage window part 24f is a substantially rectangular through-hole provided in the center of the 1st inclination blade surface part 20f with reference to FIG.3 and FIG.4. The side wall 28f of the storage window 24f is cut out in a crank shape in the longitudinal section by the groove 26f described above, and a locking wall 29f is formed that extends perpendicularly to the surface of the side wall 28f.
The locking wall 29f is formed in an upwardly inclined shape from the front side to the rear side corresponding to the groove portion 26f, and a locking portion 18 of the first blade member 14 (latching of the second blade member 16 described later). The parts 18) are engaged and arranged alternately.
Then, by inserting a pressing member 34f, which will be described later, into the storage window portion 24f, the first inclined blade surface portion 20f is positioned and fixed to the first mold 4F.

(First blade member and second blade member)
Here, referring to FIG. 4, the first blade member 14 is a flat plate member having a wavy (sine wave with an amplitude A) blade tip formed on the upper end side thereof, and a lower portion of the first blade member 14 is projected on both sides to form a pair of engagement members. Stop portions 18 and 18 are provided. Further, the second blade member 16 (substantially the same shape as the first blade member 14) has a wavy cutting edge formed in the opposite phase to the first blade member 14 on the upper end side thereof.
The height dimension H1 of the first blade member 14 and the height dimension H2 of the second blade member 16 are the same, but the width dimension W1 of the first blade member 14 is greater than the width dimension W2 of the second blade member 16. Is also formed to be large and wide. Further, the thickness dimension of the first blade member 14 and the thickness dimension of the second blade member 16 are substantially the same dimension setting (maximum plate thickness dimension T), although there are some errors (see FIG. 5).

(First storage part and second storage part)
The side wall 28f of the storage window 24f has a washing plate shape (uneven shape) on the upper side of the groove 26f, and a plurality of vertically extending concave portions and convex portions are alternately arranged in parallel from the front side to the rear side.
That is, with reference to FIG. 5, a pair of concave portions arranged facing each other and a pair of convex portions arranged facing each other are alternately formed on both side walls 28f, 28f. The distance between the pair of recesses is substantially the same as the width dimension W1 of the first blade member 14 (the dimension in the width direction corresponding to the wave-shaped traveling direction). One storage portion 30f is provided. The corner portion of the first storage portion 30f is formed in a substantially arc-shaped recess (concave portion 31), and the first blade member 14 can be inserted with a moderate feeling.
The distance between the pair of convex portions is set to be approximately the same as the width dimension W2 of the second blade member 16, and the portion between the pair of convex portions serves as the second storage portion 32f. The second blade member 16 can be inserted into the second storage portion 32f, but the wide first blade member 14 cannot be inserted.

3 and 4, the first blade member 14 is inserted into the first storage portion 30f from the lower side of the storage window portion 24f. And the latching | locking part 18 of the 1st blade member 14 is engaged with the latching wall 29f, making the blade edge (wave shape) of the 1st blade member 14 protrude from the accommodation window part 24f.
Further, the second blade member 16 is inserted into the second storage portion 32f, and the cutting edge 18 of the second blade member 16 is locked to the locking wall 29f while protruding the blade edge (wave shape of opposite phase) from the storage window portion 24f. Engage with.
As described above, in the present embodiment, a plurality of the first blade members 14 and the second blade members 16 are arranged on one side of the storage window portion 24f in a bridging manner on the side walls 28f and 28f. At this time, since the wide first blade member 14 cannot be stored in the second storage portion 32f, the first blade member 14 and the second blade member 16 are inserted as much as possible (to prevent or reduce installation errors). can do.

Referring to FIG. 5, the first storage portion 30f and the second storage portion 32f are formed at substantially the same interval (equal pitch at a constant interval) from the front side to the rear side of the storage window portion 24f. These clearances C (storage thickness dimension) are set to a size (width) that is equal to or greater than the maximum plate thickness dimension T of the double-edged members 14 and 16. For this reason, the first blade member 14 is normally stored in the first storage portion 30f with a slight gap (clearance) in the thickness direction, and the second blade member 16 is slightly stored in the second storage portion 32f. It is stored with plenty of room.
In this way, the clearance C of the first storage portion 30f (second storage portion 32f) is set to a wide constant value. By doing so, even if there is a slight error in the thickness dimension of the first blade member 14 (thickness dimension of the second blade member 16), the plural blade members 14, 16 are alternately arranged at equal pitches. Become. For this reason, a plurality of cuts can be formed at equal pitches on the metal board BD by the double-edged members 14 and 16, and deterioration of product accuracy caused by a blade thickness dimension error or the like can be prevented or reduced. .

  By the way, in FIG. 5, the thickness dimension of the double-edged members 14 and 16 is slightly emphasized. The For this reason, for example, when the maximum plate thickness dimension T is set to 0.300 mm, the actual thickness dimension of the double-edged members 14 and 16 may vary by about 0.2975 mm to 0.2950 mm in consideration of some manufacturing errors. It becomes. In such a case, the clearance C (storage thickness dimension) of both storage portions 30f and 32f is set to an arbitrary constant value in the range of, for example, 0.3000 mm to 0.3050 mm. In this way, it is possible to reliably prevent or reduce deterioration of product accuracy caused by a blade thickness dimension error or the like.

(Presser member)
And with reference to FIG. 3, the 1st inclined blade surface part 20f is fixed to the recessed part 12f. In this recess 12f, a pressing member 34f (substantially rectangular convex member) that can be fitted into the storage window 24f of the first inclined blade surface portion 20f is erected, and the upper side thereof has a stepped shape. The height dimension of each step 36f of the pressing member 34f is set to be the same as the amplitude A of the double-edged members 14 and 16 (see FIG. 7).
Then, the pressing member 34f is inserted into the storage window portion 24f of the first inclined blade surface portion 20f. Then, the first blade member 14 and the second blade member 16 are supported by the pressing member 34f while being alternately disposed on the step 36f (step of amplitude A) of the pressing member 34f.
By positioning and fixing the first inclined blade surface portion 20f to the first mold 4F in this way, the blade edge of the first blade member 14 and the blade edge of the second blade member 16 have an amplitude A in the height direction in the storage window portion 24f. It shifts and protrudes in an inclined shape. The upper edge (phase 90 °) portion of the first blade member 14 protruding from the storage window 24f and the lower edge (phase 270 °) portion of the second blade member 16 are overlapped and alternately arranged (“ An example of “a configuration in which a plurality of openings are formed in a metal board”).

(First pressing surface)
And the 1st press surface part 40f is a substantially rectangular member arrange | positioned by the type | mold closing surface 4aF with reference to FIG. The upper side (the side facing the second mold 6S) has an inclined crank shape in a side view corresponding to the first inclined blade surface portion 20f, and includes a front lower step surface 42f, a rear upper step surface 46f, and It is comprised by the inclined surface 44f to connect.
The inclined surface 44f has the same inclination angle as the first inclined blade surface portion 20f (inclined portion 22f) described above. An opening 45f (substantially rectangular through hole) leading to the first mold 4F side is formed at a substantially central position of the inclined surface 44f. The first inclined blade surface portion 20f is housed and disposed in the opening 45f, whereby the first pressing surface portion 40f is disposed around the first inclined blade surface portion 20f.

The first pressing surface portion 40f is disposed on a plurality of elastic members 10f (typically gas springs) provided around the center of the first mold 4F (recessed portion 12f) with reference to FIG. When the mold is closed, each of the elastic members 10f is elastically contracted, whereby the first pressing surface portion 40f is moved to the first mold 4F side (moved in the elastic direction) (see FIG. 6).
And this 1st press surface part 40f is arrange | positioned upwards rather than the 1st inclination blade surface part 20f by providing a some clearance gap between 1st type | molds 4F. As a result, normally, the first inclined blade surface portion 20f is brought into a storage state in which it does not protrude from the opening 45f. And it is set as the structure which the 1st inclined blade surface part 20f protrudes from the opening part 45f because the 1st press surface part 40f moves to an elastic direction.

Then, the metal board BD is positioned and arranged between the plurality of shaft members 43f provided on the upper surface 46f. The metal board BD is disposed so as to straddle the inclined surface 44f (first inclined blade surface portion 20f) and supported by a pair of support arms 47f and 47f (columnar shape) on the lower step surface 42f side. The shaft member 43f protruding from the upper surface 46f is housed in a housing hole 43s of the second mold 6S described later when the mold is closed.
The pair of support arms 47f and 47f are erected via an elastic member 11f on an insertion hole (reference numeral omitted) formed in the lower step surface 42f. When the first mold 4F and the second mold 6S are closed, the elastic member 11f is elastically compressed by the pressing force of the mold closing, so that the pair of support arms 47f and 47f are accommodated in the insertion holes, respectively. This is a configuration.

[Second type]
The 2nd type | mold 6S (substantially rectangular movable type | mold) of a present Example is provided with the 2nd inclined blade surface part 20s and the 2nd press surface part 40s with reference to FIG. And since the 2nd type | mold 6S is provided with the basic composition substantially the same as the above-mentioned 1st type | mold 4F, a common structure etc. attaches | subjects a corresponding code | symbol and abbreviate | omits detailed description.
(Second inclined blade surface)
The second inclined blade surface portion 20s has an inclined crank shape whose upper surface can face the first inclined blade surface portion 20f. The first blade member 14 (second blade member 16) is disposed in the first storage portion 30s (second storage portion 32s) in the storage window portion 24s of the second inclined blade surface portion 20s.
These blade members 14 and 16 are inserted into the storage portions 30s and 32s, respectively, so as to be able to mesh with the first inclined blade surface portion 20f (both blade members 14 and 16) (see FIG. 7).

(Second pressing surface)
In addition, referring to FIG. 1, the second pressing surface portion 40 s is disposed on the mold closing surface 6 a S so as to surround the second inclined blade surface portion 20 s. The lower side of the second pressing surface portion 40s (the side facing the first mold 4F) is composed of a front upper step surface 46s, a rear lower step surface 42s, and an inclined surface 44s. It is possible to face the pressing surface portion 40f.
The second pressing surface portion 40s is disposed on a plurality of elastic members 10s provided around the center of the second mold 6S (recessed portion 12s). When the mold is closed, each of the plurality of elastic members 10s is elastically contracted, whereby the second pressing surface portion 40s is moved toward the second mold 6S (moved in the elastic direction) (see FIG. 6).
The second pressing surface portion 40s is disposed below the second inclined blade surface portion 20s by disposing the second pressing surface portion 40s with a slight gap between the second mold surface 6S. Usually, the second inclined blade surface portion 20s does not protrude from the opening 45s, and the second pressing surface portion 40s moves in the elastic direction so that the second inclined blade surface portion 20s protrudes from the opening 45s.

[Manufacture of mesh-like body]
With reference to FIG. 6, the first mold 4F and the second mold 6S are closed. The boards around the inclined blade surface portions 20f and 20s are formed by the first pressing surface portion 40f elastically supported by the first die 4F and the second pressing surface portion 40s elastically supported by the second die 6S. Narrow the part.
Then, the metal board BD is bent and deformed so as to face both the inclined blade surface portions 20f and 20s by the pressing surface portions 40f and 40s (in this embodiment, the metal board BD is bent and deformed into an inclined crank shape). By doing so, the clearance between the two inclined blade surface portions 20f and 20s and the metal board BD is made constant in advance.
Then, both pressing surface portions 40f and 40s are moved in the elastic direction by the pressing force of closing the mold (while maintaining the narrow pressure state of the board portions around both inclined blade surface portions). By doing so, the first inclined blade surface portion 20f protrudes from the opening 45f, and the second inclined blade surface portion 20s protrudes from the opening 45s.

Next, referring to FIG. 7, the metal board BD facing the first inclined blade surface portion 20 f protruding from the first pressing surface portion 40 f and the second inclined blade surface portion 20 s protruding from the second pressing surface portion 40 s. Pinch. Then, the both inclined blade surface portions 20f and 20s (the first blade member 14 and the second blade member 16) are engaged with each other to make a plurality of cuts.
At this time, since the first blade member 14 and the second blade member 16 are arranged at substantially the same pitch on the first inclined blade surface portion 20f (second inclined blade surface portion 20s), a plurality of substantially uniform metal boards BD are provided. Incisions can be formed. Then, the metal board BD is clamped by both the inclined blade surface portions 20f and 20s and a plurality of cuts are made, and then the metal board BD is opened up and down by a mold closing pressing force to open in a mesh shape (in this embodiment, the metal board The entire surface is mesh-like).

Referring to FIG. 8, the mesh body MD manufactured in this way (mesh body MD having a mesh substantially on the entire surface) has very high product accuracy with almost no distortion or the like in the board portion around the mesh. Become.
The mesh-like body MD of the present embodiment can be used as various products such as a separator for a fuel cell, a heat-sink for turning off the front of a vehicle, or a filter for a radiator, by appropriately making it flat or cylindrical. In particular, a product having a smaller standard dimension such as a separator for a fuel cell for a vehicle is required to have a higher product accuracy of the mesh-like body. Therefore, the mesh-like body MD of this embodiment can be preferably used.

As described above, according to the manufacturing apparatus of the present embodiment, even when the opening is formed in the metal board BD by the pressing force for closing the mold, the degree of extension of the metal board BD is made as constant as possible by the both pressing surface portions 40f and 40s. can do. For this reason, according to the present embodiment, the degree of extension of the board portion around the mesh becomes substantially uniform (with almost no circumferential length difference), and the mesh body MD with high product accuracy can be manufactured.
In this embodiment, the number of first blade members 14 and second blade members 16 (number of blades) can be increased or decreased as appropriate. Therefore, a desired numerical aperture can be formed relatively easily without significantly changing the mold shape. In particular, in the present embodiment, since the mesh is formed on substantially the entire surface of the metal board BD in a single mold closing operation (by pressing operation), the mesh body MD can be manufactured in a very short time.

In the manufacturing apparatus (blade member arrangement structure) of the present embodiment, the first blade member 14 and the second blade member 16 are housed and disposed in the housing portions 30f and 32f, respectively. The effect of errors was reduced as much as possible. For this reason, the mesh-like body MD with high product accuracy can be manufactured by forming a larger number of openings while keeping the size of the cut and the like as constant as possible.
Furthermore, in this embodiment, since the width dimensions of the blade members 14 and 16 are made different, these installation errors can be prevented or reduced, and the product accuracy of the mesh-like body MD can be ensured more reliably.

The apparatus for manufacturing a mesh-like body of the present embodiment is not limited to the above-described examples, and can take other various embodiments.
(1) In the present embodiment, the first blade member 14 and the second blade member 16 are arranged on the both inclined blade surface portions 20f and 20s at an equal pitch (a configuration in which the size of the cut is made as constant as possible). . Unlike this, the first inclined blade surface portion is stepped, the second inclined blade surface portion is stepped, and staggered uneven blades are provided in the width direction thereof (that is, a configuration of a known technique in which “metal” Another example of “a configuration in which a plurality of openings are formed in a board” may be employed.

(2) In the present embodiment, the double-edged members 14 and 16 are inserted over substantially the entire surface of the storage window 24f. The number of blade members 14 and 16 (the number of blades) can be appropriately changed. For example, the blade members 14 and 16 can be inserted in the front half or the rear half of the storage window 24f. In addition, the storage window portion 24f can be alternately provided with a portion where the blade members 14, 16 are inserted and a portion where the blade members 14, 16 are not inserted.
Further, in the present embodiment, the example in which the two-blade members 14 and 16 have sinusoidal cutting edges (an example in which a more accurate cut can be formed) has been described. The cutting edge may have any wave shape as long as it can form, for example, staggered cuts on the metal board, and various shapes such as a square wave (uneven shape) and a triangular wave may be employed. it can.

(3) In the present embodiment, the plate-like metal board BD is used. However, for example, the belt-like metal board BD may be sequentially fed to the manufacturing apparatus 2.
(4) In the present embodiment, the example in which the both-blade members 14 and 16 in the first inclined blade surface portion 20f are supported using the pressing member 34f (single member) which is a convex member has been described. Unlike this, a pair of pressing members 34f, 34f (triangular plate pieces) that can be fitted into the groove 26f of the first inclined blade surface portion 20f may be used.
Further, in this embodiment, the example in which the pressing member 34f is provided with the staircase 36f (an example in which the double-edged members 14 and 16 are more reliably supported) has been described. The pressing member 34f only needs to have a shape capable of supporting the double-edged members 14 and 16, and may be, for example, a triangular shape having a smooth inclined surface.
(5) In the present embodiment, an example (a more reasonable example) in which the first storage unit 30f and the second storage unit 32f are provided in communication with each other has been described with reference to FIG. Unlike this, a partition may be provided between the first storage portion 30f and the second storage portion 32f so that the blade members 14 and 16 are alternately and alternately inserted.
(6) In this embodiment, the example of the manufacturing apparatus 2 that closes the mold vertically (in the vertical direction) has been described. However, the present invention is not limited to this. For example, the first mold 4F and the second mold 6S are erected. Then, the mold may be closed from the front and rear (horizontal direction). The first mold 4F may be a movable mold, while the second mold 6S may be a fixed mold.

It is a longitudinal cross-sectional view of a manufacturing apparatus. It is a partially transparent perspective view of a 1st type. It is a partially transparent perspective view which decomposed | disassembled and showed the 1st inclination blade surface part. It is the figure which combined the IV-IV line longitudinal cross-sectional view of FIG. 3, and the schematic front view of the blade member. It is the front view which expanded a part of 1st inclination blade surface part. It is the schematic of a mesh-shaped body manufacturing process. It is a schematic longitudinal cross-sectional view of a 1st blade member and a 2nd blade member. (A) is a perspective view which shows a metal board, (b) is a perspective view which shows a mesh-like body.

Explanation of symbols

BD Metal board MD Mesh body 2 Manufacturing device 4F First mold 6S Second mold 10 Elastic member 14 First blade member 16 Second blade member 20f First inclined blade surface portion 20s Second inclined blade surface portion 24 Storage window portion 30 First Storage part 32 Second storage part 40f First pressing surface part 40s Second pressing surface part

Claims (2)

By closing the second mold with respect to the first mold, a mesh-shaped body manufacturing apparatus that forms a mesh-shaped opening on a metal board to form a mesh-shaped body,
The manufacturing apparatus includes a first inclined blade surface portion fixed to the first mold and a second inclined blade surface portion fixed to the second mold so that the metal board is sandwiched and expanded while making a cut. With
A first pressing surface portion elastically supported with respect to the first mold by closing the first mold and the second mold, and a second pressing elastically supported with respect to the second mold After narrowing the board portion around the both inclined blade surface portions at the surface portion and bending the two inclined blade surface portions so as to face each other,
The first inclined blade surface portion protruding from the first pressing surface portion and the second pressing surface portion by moving the first pressing surface portion and the second pressing surface portion in the elastic direction by the pressing force of the mold closing, respectively. An apparatus for manufacturing a mesh-like body having a configuration in which the metal board is clamped by the protruding second inclined blade surface portion. On the first inclined blade surface portion, the wave-shaped first blade member and the wave-shaped second blade member having an opposite phase to the first blade member are alternately arranged in a step shape,
By disposing the first blade member and the second blade member in an arrangement in which the second inclined blade surface portion can mesh with the first inclined blade surface portion,
The mesh-like body according to claim 1, wherein each blade member of the first inclined blade surface portion and each blade member of the second inclined blade surface portion are engaged with each other, and the metal board is expanded while being cut. manufacturing device.

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