JP2016084578A - Placing joint surface forming sheet and method of manufacturing the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve concrete quality on the periphery of a placing joint surface by securing bondability of the placing joint surface of concrete and urging or assisting discharge of moisture such as redundant water in the concrete on the periphery of the placing joint surface.SOLUTION: A placing joint surface forming sheet 1 is installed in a form 2 that forms a placing joint surface 3a of concrete 3. A large number of protrusions 12 are protruded to a front side from a flat part 1a of the placing joint surface forming sheet 1. A large number of permeable holes 1c smaller in diameter than the protrusion 12 are formed at intervals shorter than intervals among the protrusions 12, on the flat part 1a.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a joining surface forming sheet for forming irregularities on the joining surface, which is installed in a mold for forming a joining surface of concrete, and a method for producing the sheet, and more particularly to a vertical joining surface. The present invention relates to a suitable joining surface forming sheet and a manufacturing method thereof.

  When handing over concrete, it is a problem to ensure the bondability (including adhesion, water stoppage, shearing force transferability, etc.) between both the pre-cast and post-cast concrete. In particular, if the connecting surface is vertical, the bondability tends to be low. As a countermeasure example, in Patent Document 1, a resin sheet having a large number of protrusions is installed on the inner surface of a formwork for precast concrete. As a result, a large number of recesses are formed on the joint surface of the precast concrete. By filling these recesses with post-cast concrete, the bondability between the two concretes is ensured.

Japanese Patent No. 3774096

If the water-cement ratio can be reduced by draining excess water in the concrete around the joint surface, the quality of the concrete around the joint surface will be good.
On the other hand, the resin sheet disclosed in Patent Document 1 does not have a function of promoting or assisting moisture discharge in concrete.
In view of such circumstances, the present invention not only secures the joining property on the joint surface of the concrete, but also promotes or helps the drainage of excess water in the concrete around the joint surface, and consequently the periphery of the joint surface. The purpose is to improve the quality of concrete.

In order to solve the above problems, the product of the present invention is a joining surface forming sheet installed in a mold for forming a concrete joining surface,
A flat portion and a number of protrusions protruding from the flat portion;
Of the flat portion and the protrusion, at least the flat portion has a plurality of water-permeable holes having a smaller diameter than the protrusion formed at a smaller interval than the protrusion.
According to this joining surface forming sheet, the recess can be formed on the joining surface of the precast concrete by the projection. When the post-cast concrete enters into the concave portion, it is possible to improve the bondability between the two concretes. In addition, a water-permeable layer can be formed by the joining surface forming sheet between the precast concrete and the formwork during the setting curing of the precast concrete. Thereby, discharge | emission of water | moisture contents, such as surplus water around the joint surface in precast concrete, can be promoted or can be helped. As a result, the concrete quality around the joining surface can be improved.
In this specification, “many” includes “plurality”.

It is preferable that the protrusion has a polygonal frustum shape.
As a result, a plurality of creases are formed in the peripheral side portion of the protrusion substantially along the protrusion direction of the protrusion. These creases can increase the shape retention strength of the protrusions. Therefore, the projection can sufficiently withstand the concrete pouring pressure, and the recess can be reliably formed on the joining surface. As a result, it is possible to reliably ensure the bondability of the concrete at the joining surface.

It is preferable that a nonwoven fabric is laminated and integrated on at least the flat portion of the flat portion and the protrusion.
Thereby, the water-permeable layer by the joining surface formation sheet can be reliably formed between the precast concrete and the mold. As a result, it is possible to reliably promote or assist the discharge of moisture such as excess water around the joint surface in the precast concrete. The nonwoven fabric may be provided on the front side (side from which the protrusion protrudes) of the joining surface forming sheet, or may be provided on the back side.

Further, the method of the present invention is a method for producing a joining surface forming sheet installed in a mold for forming a concrete joining surface,
Forming a number of protrusions on the sheet portion that is the main portion of the joining surface forming sheet;
A needle assembly formed by arranging a large number of needles at intervals smaller than the protrusions, and forming a large number of water-permeable holes having a diameter smaller than that of the protrusions at least in the flat portion other than the protrusions and the protrusions in the sheet portion. Features.
According to the method of the present invention, a joining surface forming sheet including a large number of protrusions and water permeable holes can be obtained. By placing this joining surface forming sheet on the mold and then placing the precast concrete, the concave portions due to the protrusions can be formed on the joining surface of the precast concrete. When the post-cast concrete enters into the concave portion, it is possible to improve the bondability between the two concretes. In addition, a water-permeable layer can be formed by the joining surface forming sheet between the precast concrete and the formwork during the setting curing of the precast concrete. Thereby, discharge | emission of water | moisture contents, such as surplus water around the joint surface in precast concrete, can be promoted or can be helped. As a result, the concrete quality around the joining surface can be improved.

The needle is shorter than the height of the protrusion,
It is preferable that the needle assembly is pierced from the back side into the sheet portion after the protrusion is formed on the sheet portion so as to protrude to the front side.
Thereby, a water permeable hole can be reliably formed in the flat part among the flat part and protrusion of a sheet | seat part. As a result, the water permeable layer by the joining surface formation sheet can be reliably formed between the precast concrete and the formwork. By discharging the moisture in the concrete around the joint surface to the outside through this water permeable layer, the quality of the concrete around the joint surface can be improved. On the other hand, almost no water permeable holes can be formed in the protrusions. Thereby, the shape retention strength of the protrusion against the concrete pouring pressure can be surely exhibited, and the concave portion can be reliably formed on the concrete joining surface. As a result, it is possible to reliably secure the jointability between the concrete on the joining surface.

The needle assembly is combined with the sheet portion and the non-woven fabric in parallel with the sheet portion and the non-woven fabric being heat-bonded by a heat laminating apparatus including a non-woven fabric superimposed on the sheet portion and the needle assembly included in a press mold. It is preferable to pierce.
Accordingly, the water permeable holes can be formed in parallel with the lamination of the sheet portion and the nonwoven fabric, and the joining surface forming sheet can be efficiently produced. Moreover, the water | moisture content in concrete can be reliably discharged | emitted outside by passing the inside of a nonwoven fabric, after permeate | transmitting a water-permeable hole.

  ADVANTAGE OF THE INVENTION According to this invention, not only the joining property in the joint surface of concrete can be ensured but discharge | emission of the excess water in the concrete around a joint surface can be promoted or assisted. As a result, the concrete quality around the joint surface can be improved.

FIG. 1 is a front view of a joining surface forming sheet according to the first embodiment of the present invention. FIG. 2 is a longitudinal sectional view of the joining surface forming sheet taken along line II-II in FIG. FIG. 3 is a longitudinal cross-sectional view showing a concrete construction structure in a state where the joining surface forming sheet is installed on a mold and cast concrete is placed. Fig.4 (a) is front sectional drawing which shows explanatoryally the heat laminating apparatus in the state which inserted the sheet | seat part and the nonwoven fabric between the upper and lower press type | molds in the manufacturing process of the said joining surface formation sheet | seat. FIG. 4B is a front view illustratively showing the heat laminating apparatus in a state where the upper and lower press dies are closed. Fig.5 (a) is front sectional drawing which expands and shows the circular part Va of FIG. FIG. 5B is a plan view of the lower press-type needle along the line Vb-Vb in FIG. FIG. 6 is a longitudinal sectional view showing a joining surface forming sheet according to the second embodiment of the present invention. FIG. 7 is a longitudinal sectional view showing a joining surface forming sheet according to the third embodiment of the present invention. FIG. 8 is a longitudinal sectional view showing a joining surface forming sheet according to the fourth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 5 show a first embodiment of the present invention. As shown in FIG. 3, the joining surface forming sheet 1 is installed and used on the inner surface 2 a (surface facing the precast concrete 3 side) of the vertical mold 2.
In FIG. 3, the thickness of the joining surface forming sheet 1 is exaggerated with respect to the thickness of the mold 2.

  As shown in FIGS. 1 and 2, the joining surface forming sheet 1 includes a sheet portion 10 (main portion) and a nonwoven fabric 20. Although the material of the sheet | seat part 10 is a polypropylene, for example, it is not restricted to this, You may be comprised with other resin, such as polyethylene. The thickness of the sheet portion 10 is, for example, about 50 μm to 1 mm.

The sheet portion 10 has a flat portion 11 and a large number of projections 12, 12,. The flat portion 11 is flat so as to be along the vertical inner surface 2 a of the mold 2. The protrusion 12 protrudes from the flat portion 11 to the front side (the side opposite to the mold 2, in front of the paper surface in FIG. 1 and to the left in FIG. 2). The protrusion 12 is recessed when viewed from the back side. The arrangement pattern of the protrusions 12 is a square lattice pattern, but is not limited to this, and may be a triangular lattice pattern or a random layout.
The protrusion 12 has a shape retaining strength that can sufficiently withstand the casting pressure of the concrete 3.

  The shape of the protrusion 12 is a regular hexagonal frustum shape (polygonal frustum shape) that is hollow and has no bottom. That is, the protrusion 12 has a top surface portion 12a and six oblique side surface portions 12b. The top surface portion 12a has a regular hexagonal (polygonal) planar shape. Each oblique side surface portion 12b has a trapezoidal planar shape. A fold line 12c serving as a ridge line is formed between the adjacent oblique side surfaces 12b and 12b. Six (plural) folds 12 c are arranged at equal intervals in the circumferential direction of the protrusion 12. Each fold line 12 c extends substantially along the protruding direction (height direction) of the protrusion 12. A protrusion inner chamber 12 d is formed inside the protrusion 12. The protrusion inner chamber 12d is opened to the back side of the protrusion 12 (concrete 3 side).

The diagonal length D ₁₂ (diameter of the circumscribed circle) of the bottom portion (continuous portion with the flat portion 11) of the protrusion 12 is, for example, about D ₁₂ = 5 mm to 30 mm.
How to arrangement pitch _{P 12} of the protrusions 12, 12 are both vertically and horizontally, for example, _P 12 = 10 mm to 100 mm approximately.
Inclination angle alpha ₁₂ with respect to the vertical plane of the swash side section 12b, for example, α ₁₂ = 45 ° ~80 ° C., preferably _{70 ° <α 12 ≦ 75 °} .
The projection height _{H 12} of the projections 12 is, for example, _H 12 = 3 mm to 20 mm approximately.
2 and 3, the thickness of the sheet portion 10 and thus the joining surface forming sheet 1 is exaggerated with respect to the size of the protrusion 12.

  As shown in FIG. 2, the nonwoven fabric 20 is arrange | positioned at the back surface (surface which faces the formwork 2, the right side in FIG. 2) of the sheet | seat part 10. As shown in FIG. Although the material of the nonwoven fabric 20 is a polypropylene, for example, it is not restricted to this, You may be comprised with other resin, such as polyethylene. The nonwoven fabric 20 allows permeation and permeation of water and gas, while preventing permeation and permeation of cement particles. The thickness of the nonwoven fabric 20 is, for example, about 50 μm to 1 mm.

  The nonwoven fabric 20 is generally flat. The nonwoven fabric 20 covers the entire back surface of the sheet portion 10. The overlapping part 21 (flat overlapping part) with the flat part 11 in the nonwoven fabric 20 is joined to the flat part 11 by thermal lamination. The flat overlapping portion 21 and the flat portion 11 constitute a flat portion 1 a of the joining surface forming sheet 1. A portion 22 (projection bottom surface portion) corresponding to the protrusion 12 in the nonwoven fabric 20 closes the opening to the back side of the protrusion inner chamber 12d.

A large number of water-permeable holes 1c are formed in the flat portion 1a and the protrusion bottom portion 22. The water permeable hole 1c of the flat part 1a penetrates the sheet part 10 and the nonwoven fabric 20 in the thickness direction. The water permeable hole 1c of the projection bottom surface portion 22 penetrates the nonwoven fabric 20 in the thickness direction. The size of each water-permeable hole 1c is much smaller than that of the protrusion 12, and is set to such an extent that it allows permeation of water and air and prevents permeation of cement particles. Moreover, the water-permeable hole 1c has a quadrangular frustum shape in which the cross-sectional area becomes smaller toward the front side (left side in FIG. 2). The diameter D _1c of the water permeable hole 1c on the front side surface of the sheet portion 10 is, for example, about D _1c = 10 μm to 500 μm.

The water permeable holes 1 c are uniformly distributed throughout the entire joining surface forming sheet 1 at intervals much smaller than the protrusions 12. Arrangement pitch _{P 1c} of permeability hole 1c is both vertically and horizontally, for example, about _P 1c = _100μm~1mm. The arrangement pattern of the water permeable holes 1c is a square lattice shape, but is not limited thereto, and may be a triangular lattice shape or the like, or may be a random arrangement.

  In addition, the water-permeable hole 1c should just be formed in the flat part 11 of the sheet | seat part 10, and does not need to be formed in the nonwoven fabric 20. FIG. Even if there is no water permeable hole 1c, the nonwoven fabric 20 itself has water permeability. Moreover, it is preferable that the water-permeable hole 1c is not formed in the protrusion 12 of the sheet | seat part 10 as much as possible from a viewpoint of ensuring shape retention property.

The joining surface forming sheet 1 is manufactured and used as follows, for example.
<Protrusion formation process>
First, the protrusion 12 is formed on the sheet portion 10 by a vacuum forming apparatus or the like.
<Lamination and perforation process>
Next, as shown in FIG. 4, the sheet portion 10 and the nonwoven fabric 20 are thermally laminated by the thermal laminator 30.

  The thermal laminating apparatus 30 includes a pair of upper and lower press dies 31 and 32. These press dies 31 and 32 have heaters (not shown) built therein, and the press dies 31 and 32 are heated to a predetermined temperature. The mold surface portion 33 of the upper press die 31 is made of a heat resistant resin. A plurality of recesses 33 a are formed on the mold surface facing downward from the mold surface portion 33. The recess 33 a corresponds to the protrusion 12.

Further, the die surface portion of the lower press die 32 is constituted by a needle assembly 34. A large number of needles 35 project vertically from the upper surface of the needle assembly 34. As shown in FIG. 5, each needle 35 has, for example, a quadrangular pyramid shape. A large number of needles 35 are arranged vertically and horizontally in a square lattice pattern. The length L ₃₅ of the needle 35 is larger than the thickness of the flat portion 1a and smaller than the height H ₁₂ (FIG. 2) of the protrusion 12 (L ₃₅ <H ₁₂ ). Arrangement pitch _{P 35} of the needle 35 is consistent with the arrangement pitch _{P 1c} of permeable holes _{1c (P 35 = P 1c)} . Therefore, the needles 35 are arranged at a much smaller interval than the protrusions 12.

  In the laminating and perforating step, as shown in FIG. 4A, the sheet portion 10 and the nonwoven fabric 20 are inserted vertically between the upper and lower press dies 31, 32 of the thermal laminating apparatus 30. At this time, the sheet portion 10 is disposed on the upper side (the press die 31 side) of the nonwoven fabric 20 and the protrusion 12 is directed upward (the press die 31 side).

  Subsequently, as shown in FIG. 4B, the sheet part 10 and the nonwoven fabric 20 are sandwiched and pressed by the press dies 31 and 32. Thereby, the flat part 11 of the sheet | seat part 10 and the nonwoven fabric 20 can be heat-pressed. In addition, as shown in FIG. 5, the needle 35 pierces the nonwoven fabric 20 and the flat portion 11 of the sheet portion 10 from below (back side). Accordingly, the water permeable holes 1c can be formed simultaneously with the lamination and integration of the sheet portion 10 and the nonwoven fabric 20. Therefore, the joining surface forming sheet 1 can be manufactured efficiently.

By forming the needle 35 into a quadrangular pyramid shape, the pyramidal trapezoidal water-permeable hole 1c can be reliably formed in the sheet portion 10 and the nonwoven fabric 20, and the shape of the water-permeable hole 1c can be reliably maintained even after the needle 35 is pulled out. On the other hand, since the needle 35 is shorter than the height of the projection 12 (L ₃₅ <H ₁₂ ), the needle 35 does not pierce the projection 12 except for the vicinity of the bottom portion of the oblique side surface portion 12b (the portion close to the flat portion 11). . Accordingly, it is possible to avoid the formation of the water permeable hole 1c in the protrusion 12 except for the vicinity of the bottom of the oblique side surface portion 12b.

<Precast concrete placement process>
As shown in FIG. 3, the joining surface forming sheet 1 manufactured in this way is attached to the inner surface 2 a of the mold 2 with a tucker or the like. Then, the precast concrete 3 is placed. At this time, the vertical joining surface 3 a of the concrete 3 is defined by the mold 2. On the vertical joining surface 3a, a recess 3b is formed by the protrusion 12 of the joining surface forming sheet 1. The protrusion 12 has a firmness due to the fold line 12c on the circumferential side, and the shape retention strength is increased. Moreover, the water permeable holes 1 c are hardly formed in the protrusions 12. Therefore, the shape retention strength of the protrusions 12 can be sufficiently increased, and the protrusions 12 can be prevented from being crushed even when subjected to the casting pressure of the concrete 3. Thereby, the recessed part 3b can be reliably formed in the vertical joint surface 3a.

<Curing process>
After placing the concrete 3, it is cured and cured. Here, a water permeable layer formed by the joining surface forming sheet 1 can be formed between the concrete 3 and the mold 2. Therefore, during the curing period, as shown by the thick arrow line in FIG. 3, the moisture w around the vertical joint surface 3 a in the concrete 3 is transferred from the water-permeable holes 1 c of the joint surface forming sheet 1 to the joint surface forming sheet. You can get into one. Further, the moisture w can be discharged to the outside through the inside of the nonwoven fabric 20 or between the joining surface forming sheet 1 and the inner surface 2a of the mold 2. Thereby, the water cement ratio W / C of the concrete 3 around the vertical joint surface 3a can be reduced, and as a result, the quality of the concrete 3 can be improved.

<Removal of formwork to post-cast concrete placing process>
After the precast concrete 3 is hardened, the mold 2 and the joining surface forming sheet 1 are removed. Then, post-cast concrete (not shown) is placed. The post-cast concrete contacts the vertical joint surface 3a and enters the recess 3b. As a result, it is possible to improve the bondability (including adhesion, waterstop, shearing force transferability, etc.) of both concretes on the vertical joint surface 3a.

Next, another embodiment of the present invention will be described. In the following embodiments, the same reference numerals are given to the drawings for the same configurations as those already described, and the description thereof is omitted.
FIG. 6 shows a second embodiment of the present invention. In the joining surface forming sheet 1 </ b> B of the second embodiment, a protrusion lining portion 23 is provided at a portion corresponding to the protrusion 12 in the nonwoven fabric 20. The shape of the protrusion lining portion 23 is the same regular hexagonal frustum shape (polygonal frustum shape) as that of the protrusion 12. A large number (a plurality) of projection covering portions 25 are arranged in the vertical and horizontal directions at the same intervals as the projections 12. Therefore, the sheet part 10 and the nonwoven fabric 20 have a similar shape. The nonwoven fabric 20 is disposed on the back side of the sheet portion 10, and the protrusion lining portion 23 is overlapped on the back side of the protrusion 12 of the sheet portion 10. Further, the water permeable holes 1 c are also formed in the protrusions 12 and the protrusion lining 23. Thereby, the water permeability of the joining surface forming sheet 1B can be further increased.
In FIG. 6, the water permeable hole 1 c is formed only in the top surface portion 12 c of the top surface portion 12 c and the oblique side surface portion 12 b of the protrusion 12, but the water permeable hole 1 c is also formed in the oblique side surface portion 12 b. Good.

  FIG. 7 shows a third embodiment of the present invention. In the joining surface forming sheet 1C of the third embodiment, the nonwoven fabric 20 is laminated not on the back side surface of the flat portion 11 of the sheet portion 10 but on the front side surface (the surface facing the concrete 3, the left side surface in the figure). Yes. An escape hole 24 is formed in a portion of the nonwoven fabric 20 corresponding to the protrusion 12. The protrusion 12 protrudes to the front side from the nonwoven fabric 20 through the escape hole 24. The protrusion inner chamber 12d is open to the back side (right side in the figure).

  FIG. 8 shows a fourth embodiment. 4th Embodiment is a modification of 3rd Embodiment, and it replaces with the relief hole 24 in the part corresponding to the processus | protrusion 12 in the nonwoven fabric 20 of the joining surface formation sheet 1D, and the processus | protrusion coating | coated part 25 is formed. . The protrusion covering portion 25 has the same regular hexagonal frustum shape (polygonal frustum shape) as the protrusion 12. A large number (a plurality) of projection covering portions 25 are arranged in the vertical and horizontal directions at the same intervals as the projections 12. Therefore, the sheet part 10 and the nonwoven fabric 20 are similar. The nonwoven fabric 20 is disposed on the front side of the sheet portion 10 and covers the protrusion covering portion 25 so as to overlap the front side of the protrusion 12 of the sheet portion 10.

The present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.
For example, the numerical ranges such as the thickness of the sheet portion 10 and the height of the protrusions 12 shown in the embodiment are merely examples, and the present invention is not limited to these numerical ranges.
The shape of the protrusion 12 is not limited to a hexagonal frustum, but may be a triangular frustum shape, a quadrangular frustum shape, or a pentagonal frustum shape, or a heptagonal or more polygonal frustum shape, The shape is not limited to a polygonal frustum, and may be a truncated cone shape or a cylindrical shape.
The nonwoven fabric 20 may be omitted. The joining surface forming sheets 1, 1 </ b> B to 1 </ b> D may be configured only by the sheet portion 10. The nonwoven fabric 20 may be laminated on both surfaces of the sheet portion 10.
The shape of the needle 35 is not limited to a quadrangular pyramid shape, and may be another polygonal pyramid shape such as a hexagonal pyramid or a conical shape. The distal end portion of the needle 35 may be sharp, and the proximal end portion of the needle 35 may be cylindrical.
The shape of the water-permeable hole 1c is not necessarily limited to the square frustum shape, and may be another polygonal frustum shape such as a hexagonal frustum shape, a frustum shape, or a cylindrical shape.
The connecting surface does not necessarily have to be vertical.

  You may combine the original structure of each embodiment mutually. For example, in the first, third, and fourth embodiments, similarly to the second embodiment, the water permeable holes 1c may be formed in the protrusions 12 from the viewpoint of improving water permeability and the like.

The manufacturing method of the joining surface formation sheet | seat 1,1B-1D is not limited to the method of embodiment, It can change suitably. For example, instead of simultaneously forming the water permeable holes 1c and laminating and integrating the sheet portion 10 and the nonwoven fabric 20 (thermal lamination), the sheet portion 10 and the nonwoven fabric 20 are formed after the water permeable holes 1c are formed in the sheet portion 10. May be laminated and integrated, and the water permeable hole 1c may be formed after the sheet portion 10 and the nonwoven fabric 20 are laminated and integrated. The protrusions 12 may be formed after the formation of the water permeable holes 1c. Alternatively, the sheet portion 10 and the nonwoven fabric 20 may be integrated and the water permeable holes 1c may be formed simultaneously with the formation of the protrusions 12.
In FIG. 5, the press dies 31, 32 of the heat laminating apparatus 30 may be arranged upside down.

  While the sheet portion 10 and the nonwoven fabric 20 are continuously or intermittently fed from the roll, the formation of the protrusions 12, thermal lamination, and perforation of the water permeable holes 1c may be performed sequentially or concurrently.

  The present invention can be applied to, for example, construction of a vertical joint surface of a concrete structure.

1,1B-1D Joint surface forming sheet 1a Flat part 1c Permeation hole 2 Formwork 3 Precast concrete (concrete)
3a Vertical joint surface (joint surface)
10 Seat (main part)
12 Protrusions 20 Non-woven fabric 30 Thermal laminating apparatus 31, 32 Press die 34 Needle assembly 35 Needle

Claims (6)

A joining surface forming sheet installed in a formwork that forms a concrete joining surface,
A flat portion and a number of protrusions protruding from the flat portion;
A joining surface forming sheet, wherein at least the flat portion of the flat portion and the protrusion has a plurality of water-permeable holes having a diameter smaller than that of the protrusion at a smaller interval than the protrusion.   The joining surface forming sheet according to claim 1, wherein the protrusion has a polygonal frustum shape.   The joining surface forming sheet according to claim 1 or 2, wherein a nonwoven fabric is laminated on at least the flat portion of the flat portion and the protrusion. A method for producing a joining surface forming sheet installed on a mold for forming a concrete joining surface,
Forming a number of protrusions on the sheet portion that is the main portion of the joining surface forming sheet;
A needle assembly formed by arranging a large number of needles at intervals smaller than the protrusions, and forming a large number of water-permeable holes having a diameter smaller than that of the protrusions at least in the flat portion other than the protrusions and the protrusions in the sheet portion. A method for producing a joining surface forming sheet. The needle is shorter than the height of the protrusion,
The method for producing a joining surface forming sheet according to claim 4, wherein after forming the protrusions on the sheet portion so as to protrude to the front side, the needle assembly is inserted into the sheet portion from the back side.   The needle assembly is combined with the sheet portion and the non-woven fabric in parallel with the sheet portion and the non-woven fabric being heat-bonded by a heat laminating apparatus including a non-woven fabric superimposed on the sheet portion and the needle assembly included in a press mold. The manufacturing method of the joining surface formation sheet of Claim 4 or 5 characterized by the above-mentioned.

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