JP6247982B2 - Foam insulation for plastic formwork - Google Patents

Description

The present invention relates to a foamable heat insulator for a plastic mold used for a plastic mold.

  2. Description of the Related Art Conventionally, a wooden form made of a plywood and a reinforcing frame attached to the outer periphery of the plywood has been used. Since this wooden formwork has low durability, it is disposed of after several uses. Therefore, in recent years, plastic molds advantageous in durability have been proposed.

  By the way, when concrete is placed and hardened using the plastic formwork at a time when the temperature in winter is low, the temperature of the concrete suddenly drops, and cracks and cracks may occur. In order to solve this, in recent years, a form having a heat insulating effect has been proposed. This is comprised from the heat insulation board which consists of a synthetic resin foam, and the reinforcement piercing tree embedded in the ditch | groove formed in one surface of this heat insulation board (for example, refer patent document 1).

Japanese Patent No. 3441434

  Since the heat insulating plate of the mold of Patent Document 1 is composed of a large sheet made of synthetic resin foam, it is disadvantageous in terms of cost.

Accordingly, the present invention has been made in view of such circumstances, and provides a foamable heat insulator for a plastic mold that can be advantageous in terms of cost and can be easily accommodated in a plastic mold. Is an issue.

A foamable heat insulating body for a plastic mold according to the present invention includes a rectangular flat plate portion having a concrete placement surface, and peripheral ribs provided along four sides on the back side opposite to the concrete placement surface. A foamable heat insulating material for a plastic mold frame accommodated in the elongated ribs, comprising a partition rib for partitioning an interior surrounded by peripheral ribs into a number of elongated ribs. A plurality of slits for facilitating bending of the elongated block body when the elongated block body is received in the elongated ridge. formed in the said inter partition rib each other and between the peripheral rib and the partitioning rib includes a reinforcing rib connecting every predetermined interval, so as to correspond to reinforcing rib slit The slit is slightly larger than the reinforcing rib so as to be locked to the reinforcing rib, and the first slit is not locked to the reinforcing rib. And a second slit having a large dimension .

According to the present invention, when the elongated block body is accommodated in the elongated ridge, the elongated block body can be bent by the slit. Therefore, cracks and cracks are unlikely to occur in the elongated block body, and the elongated block body can be satisfactorily accommodated in the elongated ridge.
Further, the first slit having a size slightly larger than that of the reinforcing rib is engaged with the reinforcing rib, whereby the elongated block body can be reliably held on the reinforcing rib. Moreover, since the 2nd slit which has a bigger dimension than a 1st slit does not latch to a reinforcing rib, an elongate block body can be smoothly accommodated in an elongate ridge.

  Moreover, the foamable heat insulating body for plastic molds according to the present invention may include the first slits and the second slits alternately in the longitudinal direction of the elongated block body.

  As described above, the first slit and the second slit are alternately provided in the longitudinal direction of the elongated block body, so that the elongated block body is securely held by the reinforcing rib, and the elongated block body is formed into an elongated ridge. It can be stored smoothly.

  Further, in the foamable heat insulating body for a plastic mold according to the present invention, the peripheral rib and the partitioning rib are set at the same height from the flat plate portion, and the elongated block body is accommodated in the bag. You may be comprised in the height which protrudes from the said peripheral rib and the said partition rib in a state.

  As described above, if the elongated block body is set to a height protruding from the peripheral rib and the partition rib, it is possible to easily take out the elongated block body from the ridge while improving heat insulation.

As described above, according to the present invention, when the elongated block body is accommodated in the elongated ridge, the elongated block body can be bent by the slit. Therefore, cracks and cracks are unlikely to occur in the elongated block body, and the elongated block body can be satisfactorily accommodated in the elongated ridge. Therefore, it is possible to provide a foamable heat insulator for a plastic mold that can be advantageous in terms of cost and can be easily accommodated in a plastic mold.

It is a rear view of the formwork in the state where the foamable heat insulating material of the 1st embodiment of the present invention was inserted in the formwork. (A) is the sectional view on the AA line in FIG. 1, (b) is sectional drawing which shows the state which has fitted the foaming heat insulating body in the accommodating part of the formwork of (a). (A) is the BB sectional view taken on the line in FIG. 1, (b) is a perspective view of the foam heat insulating body accommodated in the accommodating part of the formwork of FIG. 3 (a). It is CC sectional view taken on the line in FIG. It is a rear view of the formwork of the state where the foamable heat insulating material of the 2nd embodiment of the present invention was inserted in the formwork of other composition. It is the DD sectional view taken on the line in FIG. (A) is the EE sectional view taken on the line in FIG. 5, (b) is a perspective view of the foam heat insulating body accommodated in the accommodating part of the formwork of FIG. 7 (a). It is the FF sectional view taken on the line in FIG.

  Hereinafter, one embodiment of a foamable heat insulating body for a plastic mold according to the present invention will be described with reference to FIGS.

<First embodiment>
FIG. 1 shows a view of a plastic mold 3 containing nine foaming heat insulators 1 and 2 and having heat insulation, as viewed from the back side. Since the mold 3 is vertically long and vertically long, only the upper half of the mold 3 is shown in FIG. 1, and the lower half is the same as the upper half.

  The mold 3 includes a rectangular (rectangular) flat plate portion 4 having a concrete placement surface 4a, and peripheral ribs 5 provided along four sides of the back surface 4b opposite to the concrete placement surface 4a, A large number (eight here) partitioning ribs for partitioning the interior surrounded by the peripheral ribs 5 into a large number (here, nine) elongate ridges 6, 7, 8, 9, 10, 11, 12, 13, 14 15, 16, 17, 18, 19, 20, 21, 22. The first rods 6, 14 at the two ends located at both ends in the left-right width direction have substantially the same lateral width (left-right width), and the seven second rods 7, 8, 9, 10, 11, 12, and 13 have substantially the same lateral width (horizontal width). The horizontal widths (left and right widths) of the first rods 6 and 14 are set larger than the horizontal widths (left and right widths) of the second rods 7, 8, 9, 10, 11, 12, and 13. The peripheral rib 5 and the partitioning ribs 15, 16, 17, 18, 19, 20, 21, 22 are configured at the same height. In addition, the length of the foam heat insulating bodies 1 and 2 accommodated in each of the cages 6, 7, 8, 9, 10, 11, 12, 13, 14 is configured to be the length over the entire vertical dimension of the mold 3. It may be any dimension (length), such as one-half dimension or one-third dimension of the upper and lower dimensions of the mold 3, but here each The elongate thing which can fill the coffin 6,7,8,9,10,11,12,13,14 with the one foaming heat insulating body 1 or 2 is demonstrated.

  The peripheral rib 5 includes four plate-like ribs, and includes an upper rib 5A, a lower rib (not shown), a left rib 5C, and a right rib 5D. And as shown in FIG. 1, many attachment holes H for attaching a hook bolt and a clip are formed in 5 A of upper side ribs, 5 C of left side ribs, and 5 D of right side ribs. Although not shown, a mounting hole is also formed in the lower rib.

  Each of the two foamable heat insulators 1 positioned at both ends in the left-right direction is composed of a first elongated block body configured to be smaller than the first rods 6 and 14 so as to be accommodated in the first rods 6 and 14. Yes. Each of the remaining seven foaming heat insulators 2 is accommodated in the second rods 7, 8, 9, 10, 11, 12, 13 so that the second rods 7, 8, 9, 10, 11, 12, It is comprised from the 2nd elongate block body comprised smaller than 13. FIG. The horizontal width (left-right width) of the first elongate block body 1 is set larger than the horizontal width (left-right width) of the second elongate block body 2. As the foamable heat insulators 1 and 2, polystyrene foam, polyethylene foam, polypropylene foam, rigid urethane foam, phenol foam, isocyanate foam, epoxy foam, and the like can be used. The expansion ratio can be freely changed as appropriate.

  As shown in FIGS. 1, 3 (a), 3 (b), and FIG. 4, the first elongate block body 1 is a flat plate located at both ends in the longitudinal direction and having a height lower than the mounting hole H. 1A and 1A (only one is shown in the figure) and an inclined surface 1S which is located between both end portions 1A and 1A and becomes higher from the width direction outer end toward the width direction inner end. And a main body portion 1B having a substantially triangular shape. At both ends in the longitudinal direction of the main body 1B, inclined surfaces 1R that are higher toward the center in the longitudinal direction are formed. In addition, the inner end surface 1b in the left-right width direction of the main body 1B is recessed so that a gap N1 is formed between the partition ribs 15 and 22, and a finger is put into the gap N1 so that the upper end of the main body 1B 1T can be easily grasped. The flat end portions 1A and 1A and the portion 1B1 lower than the mounting hole H in the main body 1B are defined as outer portions located on the peripheral rib 5 side. Further, a portion 1B2 that is higher than the attachment hole H in the main body 1B is an inner portion that is separated from the peripheral rib 5.

  As shown in FIGS. 1, 2 (a), (b) and FIG. 4, the second elongate block body 2 is a flat plate located at both ends in the longitudinal direction and having a height lower than the mounting hole H. Both end portions 2A and 2A (only one is shown in the figure), and a rectangular main body portion 2B located between both end portions 2A and 2A and formed higher than both end portions 2A and 2A. ing. Inclined surfaces 2R, 2R (only one of them is shown in the figure) are formed at both ends in the longitudinal direction of the main body 2B. The inclined surfaces 2R, 2R gradually rise upward from both end portions 2A, 2A. The both end portions 2A and 2A constitute an outer portion located on the peripheral rib 5 side. Further, an inner portion separated from the peripheral rib 5 is formed from the main body portion 2B.

  Moreover, the 1st elongate block body 1 and the 2nd elongate block body 2 are comprised in the height which protrudes from the peripheral rib 5 and the partition ribs 15-22. Thereby, while the heat insulation effect can be enhanced, it is easy to take out the foaming heat insulations 1 and 2 from the flanges 6 to 14. The foaming insulation 1 and 2 are taken out when the foaming insulation is replaced with a new foaming insulation, but the foaming insulation 1 and 2 are also taken out when no insulation is required. It can also be left.

  As described above, since the left and right width of the first elongate block body 1 is set to be larger than the left and right width of the second elongate block body 2, the inclined surface 1S of the main body 1B of the first elongate block body 1 (see FIG. 4) can be set relatively gently, and a space M in which the hook bolt and the clip can be reliably inserted into the mounting hole H can be secured. Therefore, as shown in FIGS. 1 and 4, by using the space M, the clip K can be easily and quickly inserted into the holes H, H of the adjacent molds 3, 3 in the left-right direction. Both molds 3 and 3 can be quickly connected with the clip K. In addition, while providing the heat insulating effect by providing the flat plate-like end portions 1A and 1A, the thickness of the foamable heat insulator increases from the outer side in the width direction toward the inner side in the width direction by the substantially triangular main body 1B. Thus, the heat insulation effect can be enhanced.

  A large number (10 in FIG. 1) of first reinforcing ribs are connected to the mold 3 at predetermined intervals in the longitudinal direction between the peripheral ribs 5C or 5D adjacent in the left-right direction and the partitioning ribs 15 or 22. 23 and the adjacent ribs 15, 16 or 16, 17 or 17, 18 or 18, 19 or 19, 20 or 20, 21, or 21, 22 in the left-right direction are connected at predetermined intervals in the longitudinal direction. A large number (10 in FIG. 1) of second reinforcing ribs 24 are provided. As shown in FIG. 4, the first reinforcing rib 23 located on the right side has one end portion 23 </ b> A located at one end in the left-right direction and rising up to the height of the partitioning rib 15, and one end portion 23 </ b> A located at the other end in the left-right direction. The other end portion 23B that rises to the vicinity of the height and the height between the both end portions 23A and 23B and the height of the partition rib 15 and the peripheral rib 5 (here, less than half the height) are configured. Intermediate portion 23C. The second reinforcing ribs 24 positioned second from the right are positioned between the both end portions 24A and 24A and the both end portions 24A and 24A that are positioned at both ends in the left-right direction and rise up to the height of the partitioning ribs 16 and 17. An intermediate portion 24B configured to have a height lower than the height of the partition ribs 16 and 17 (here, a height of half or less) is provided. The other first reinforcing ribs 24 not described have the same configuration.

  In addition, a large number of slits 25 and 26 are formed on the bottom of the first elongate block body 1 and the bottom of the second elongate block body 2 for facilitating bending when accommodated in the elongate troughs 6 to 14. . Each slit 25 or 26 is formed so as to extend in the left-right width direction of the elongated block body 1 or 2, and is formed at a predetermined interval in the longitudinal direction of the elongated block body 1 or 2. Each slit 25 or 26 is formed to correspond to the first reinforcing rib 23 or the second reinforcing rib 24. Each slit 25 or 26 is locked to the first slit 25A or 26A that is locked to the first reinforcing rib 23 or the second reinforcing rib 24, and to the first reinforcing rib 23 or the second reinforcing rib 24. The second slit 25B or 26B is not provided.

  In other words, the longitudinal dimension of the elongated block body of the first slit 25A or 26A is such that the first slit 25A or 26A is locked to the first reinforcing rib 23 or the second reinforcing rib 24. The rib 23 or the second reinforcing rib 24 is configured to have a size slightly larger than the size in the longitudinal direction of the elongated block body. Specifically, as shown in FIGS. 3A and 3B, the first slit 25 </ b> A of one first elongated block body 1 is slightly smaller than the first reinforcing rib 23 having a rectangular cross section. The first slit 25A enters the first reinforcing rib 23 and is locked therewith. Further, the second slit 25B of the first elongated block body 1 is formed in a slit in which a trapezoidal space far larger than the rectangular first reinforcing rib 23 having a vertically long cross section is formed, and the second slit 25B. However, it only covers the first reinforcing rib 23 and does not engage with the first reinforcing rib 23. Further, the first slit 26A of the other second elongated block body 2 is formed in a slit in which a trapezoidal space slightly larger than the rectangular second reinforcing rib 24 having a vertically long cross section is formed. The slit 25 </ b> A enters the second reinforcing rib 24, and the narrow space at the upper end of the first slit 25 </ b> A is locked to the upper end of the second reinforcing rib 24. In addition, the second slit 26B of the second elongated block body 2 has a rectangular section 26b having a large dimension in the longitudinal direction and a rectangular section 26b that is horizontally long (long in the longitudinal direction of the heat insulating body 2) and the upper ends of the corner sections 26b. And a trapezoidal trapezoidal portion 26c extending upward from the second reinforcing rib 24. The second reinforcing rib is formed simply by covering the second reinforcing rib 24 with the second slit 26B. Do not lock to 24. These first slits 25A or 26A and second slits 25B or 26B are alternately provided in the longitudinal direction of the first elongated block body 1 or the second elongated block body 2.

  Therefore, the 1st elongate block body 1 (or 2nd elongate block body 2) is provided with the slit 25 (or slit 26), and the 1st elongate block body 1 or the 2nd elongate block body 2 is made into the eaves 6-14. The first elongate block body 1 (or the second elongate block body 2) can be bent at the slit 25 (or the slit 26) when being accommodated. 2B shows a state where the second elongate block body 2 is bent by the slit 26 by a two-dot chain line in FIG. Therefore, the first elongate block body 1 or the second elongate block body 2 is hardly cracked or cracked and can be satisfactorily accommodated in the ridges 6 to 14.

  When the first elongate block body 1 or the second elongate block body 2 is accommodated in the flanges 6 to 14, the first slit 25A or 26A is locked to the first reinforcing rib 23 or the second reinforcing rib 24. Thus, the elongated first elongated block body 1 or the second elongated block body 2 can be securely held by the mold 3. Further, when the first elongate block body 1 or the second elongate block body 2 is accommodated in the flanges 6 to 14, the second slit 25 </ b> B or 26 </ b> B is engaged with the first reinforcement rib 23 or the second reinforcement rib 24. Therefore, the first elongate block body 1 or the second elongate block body 2 can be smoothly accommodated in the ridges 6-14. Further, the first slits 25A or 26A and the second slits 25B or 26B are alternately provided in the longitudinal direction of the first elongated block body 1 or the second elongated block body 2, whereby the first slits 25A or 26A and the first slits 25A or 26A are provided. The first elongate block body 1 or the second elongate block body 1 or the second elongate block body 2 is securely held by the mold 3 by the engagement with the reinforcing rib 23 or the second reinforcing rib 24. The elongated block body 2 can be smoothly accommodated in the ridges 6-14.

<Second embodiment>
Next, 2nd embodiment of the foamable heat insulating body for plastic molds which concerns on this invention is described based on FIGS. The foamable heat insulator of the second embodiment is configured such that both the left and right width dimensions and the height dimension are larger than those of the first embodiment.

  FIG. 5 shows a view of a plastic mold 29 that contains seven foaming heat insulators 27 and 28 and has heat insulating properties, as viewed from the back side. Since the mold frame 29 has a vertically long shape in the vertical direction, only the upper half of the mold frame 29 is shown in FIG. 5, and the lower half is the same as the upper half.

  The mold frame 29 includes a rectangular (rectangular) flat plate portion 30 having a concrete placement surface 30a, and peripheral ribs 31 provided along the four sides of the back surface 30b opposite to the concrete placement surface 30a. A large number (six here) of partition ribs 39, 40 for partitioning the interior surrounded by the peripheral ribs 31 into a large number (here, seven) of elongated eaves 32, 33, 34, 35, 36, 37, 38. 41, 42, 43, 44. The two first rods 32, 38 located at both ends in the left-right width direction have substantially the same lateral width (left-right width), and the five second rods 33, 34, 35, 36, and 37 have substantially the same lateral width (horizontal width). The horizontal widths (left and right widths) of the first rods 32 and 38 are set to be larger than the horizontal widths (left and right widths) of the second rods 33, 34, 35, 36, and 37. The peripheral rib 31 and the partitioning ribs 39, 40, 41, 42, 43, 44 are configured to have the same height. Similarly to the first embodiment, a long one that can fill each of the cages 32, 33, 34, 35, 36, 37, and 38 with a single foamable heat insulator 27 or 28 will be described below.

  The peripheral rib 31 includes four plate-like ribs, and includes an upper rib 31A, a lower rib (not shown), a left rib 31C, and a right rib 31D. As shown in FIG. 1, a large number of attachment holes H for attaching hook bolts and clips are formed in the upper rib 31A, the left rib 31C, and the right rib 31D. Although not shown, a mounting hole is also formed in the lower rib.

  Each of the two foamable heat insulators 27 located at both ends in the left-right direction is composed of a first elongated block body having a lateral width (left-right width) accommodated in the first rods 32 and 38. Each of the remaining five foamable heat insulators 28 is composed of a second elongated block body having the same lateral width (left-right width) accommodated in the second rod 33, 34, 35, 36, 37. The lateral width (left-right width) of the first elongated block body 27 is set to be larger than the lateral width (left-right width) of the second elongated block body 28. As the foam heat insulators 27 and 28, polystyrene foam, polyethylene foam, polypropylene foam, hard urethane foam, phenol foam, isocyanate foam, epoxy foam, or the like can be used. The expansion ratio can be freely changed as appropriate.

  As shown in FIGS. 5, 7 (a), (b), and FIG. 8, the first elongate block body 27 is located at both ends in the longitudinal direction and has a flat plate shape having a height lower than the mounting hole H. Both end portions 27A and 27A (only one is shown in the figure) and an inclined surface 27S which is located between both end portions 27A and 27A and becomes higher from the width direction outer end toward the width direction inner end. And a main body portion 27B having a substantially triangular shape. Inclined surfaces 27R are formed at both ends in the longitudinal direction of the main body 27B so as to increase toward the center in the longitudinal direction. In addition, the inner end surface 27b in the left-right width direction of the main body 27B is inclined so that a gap N2 is formed between the ribs 39 or 44 for partitioning, and a finger is put into the gap N2 so that the upper end of the main body 27B The part can be easily grasped. The flat end portions 27A and 27A and the portion 27B1 lower than the mounting hole H in the main body portion 27B are outer portions located on the peripheral rib 31 side. In addition, a portion 27B2 that is higher than the attachment hole H in the main body 1B is an inner portion that is separated from the peripheral rib 31.

  As shown in FIGS. 5, 6, and 8, the second elongate block body 28 is located at both ends in the longitudinal direction and has flat plate end portions 28 </ b> A and 28 </ b> A (having a height lower than the mounting hole H). In the figure, only one of them is shown), and a rectangular main body 28B located between both end portions 28A and 28A and formed higher than both end portions 28A and 28A is provided. Inclined surfaces 28R and 28R (only one of them is shown in the figure) are formed at both ends in the longitudinal direction of the main body 28B so as to gradually rise upward from both end portions 28A and 28A. The both end portions 28A and 28A constitute an outer portion located on the peripheral rib 31 side. Further, an inner portion that is separated from the peripheral rib 31 is formed from the main body portion 28B.

  Further, the first elongate block body 27 and the second elongate block body 28 are configured to have a height protruding from the peripheral rib 31 and the partition ribs 39 to 44. Thereby, it is easy to take out the foaming heat insulators 27 and 28 from the eaves 32 to 38 while improving the heat insulating effect. The foaming insulators 27 and 28 are taken out when the foaming insulator is replaced with a new foaming insulator. However, the foaming insulators 1 and 2 are taken out even when the insulation is not required. It can also be left.

  As described above, since the left and right width of the first elongate block body 27 is set larger than the left and right width of the second elongate block body 28, the angle of the inclined surface 27S of the main body portion 27B of the first elongate block body 27 is set. Can be set relatively gently, and a space M in which the hook bolt and the clip can be reliably inserted into the mounting hole H can be secured. Therefore, as shown in FIG. 8, by using the space M, the clip K can be easily and quickly inserted into the holes H, H of the adjacent molds 29, 29 in the left-right direction. 29, 29 can be quickly connected. Moreover, the thickness of the foamable heat insulating material increases from the outer end in the width direction toward the inner end in the width direction by the substantially triangular main body portion 27B while providing the heat insulating effect by providing the flat plate-like end portions 27A and 27A. Thus, the heat insulation effect can be enhanced.

  A number of first reinforcing ribs (11 in FIG. 5) are connected to the mold frame 29 at predetermined intervals in the longitudinal direction between the peripheral ribs 31C or 31D adjacent to each other in the left-right direction and the partitioning ribs 39 or 44. 45 and a plurality of (11) second reinforcing ribs 46 (2 from the left) that connect the partition ribs 39, 40 or 41, 42, 43, 44 adjacent to each other in the left-right direction at predetermined intervals in the longitudinal direction. Although the second reinforcing rib 46 is illustrated only in the second, the fourth and sixth from the left are the same, and therefore the second reinforcing rib 46 is not illustrated in the fourth and sixth from the left. ) And a large number of (11) third reinforcing ribs 47 (only the third from the left) that connect the partitioning ribs 40, 41, 42 or 42, 43 adjacent in the left-right direction at predetermined intervals in the longitudinal direction. The third reinforcing rib 47 is shown in FIG. Are the same, the fifth from the left and a not shown) the third reinforcing rib 47. As shown in FIG. 8, the first reinforcing rib 45 is located on one end side in the left-right direction and rises to the vicinity of the height of the partitioning ribs 39 and 44, and the same from the one end 45 </ b> A to the peripheral rib 31. And a main body portion 45B that is connected at a height and is configured to have a height lower than the height dimension of the partition ribs 39 and 44 and the peripheral rib 31 (here, a height of half or less). The second reinforcing ribs 46 are positioned at both ends in the left-right direction and rise up to the height of the partitioning ribs 39, 40, and between the both end portions 46A, 46A and from the height of the partitioning ribs 39, 40. And an intermediate portion 46B having a lower height (here, less than half the height). The third reinforcing ribs 47 are located at both ends in the left-right direction and rise to the height of the partitioning ribs 40, 41, and between the both end portions 47A, 47A and between the partitioning ribs 40, 41. And an intermediate portion 47B configured to have a height lower than the height (here, less than half the height). Since the second reinforcing rib 46 and the third reinforcing rib 47 have the same configuration, only the second reinforcing rib 46 will be described below.

  In addition, a large number of slits 48 and 49 are formed on the bottom of the first elongated block body 27 and the bottom of the second elongated block body 28 to facilitate folding when accommodated in the elongated flanges 32 to 38. . Each slit 48 or 49 is formed so as to extend in the left-right width direction of the elongated block body 27 or 28 and is formed at a predetermined interval in the longitudinal direction of the elongated block body 27 or 28. Each slit 48 or 49 is formed to correspond to the first reinforcing rib 45 or the second reinforcing rib 46. Each slit 48 or 49 is locked to the first slit 48A or 49A that is locked to the first reinforcing rib 45 or the second reinforcing rib 46, and the first reinforcing rib 45 or the second reinforcing rib 46. The second slit 48B or 49B is not provided.

  In other words, the length in the longitudinal direction of the elongated block body of the first slit 48A or 49A is such that the first slit 48A or 49A is engaged with the first reinforcing rib 45 or the second reinforcing rib 46. The rib 45 or the second reinforcing rib 46 is configured to have a dimension slightly larger than the dimension in the longitudinal direction of the elongated block body. Specifically, as shown in FIGS. 7A and 7B, the first slit 48A of one of the first elongated blocks is slightly more than the first reinforcing rib 45 having a rectangular cross section. The slit is formed with a large vertically long trapezoidal space. The first slit 48A enters the first reinforcing rib 45, and the upper end of the first slit 48A and the upper end of the first reinforcing rib 45 are engaged. Stop. In addition, the second slit 48B of the first elongated block body 27 has a rectangular section 48b having a large dimension in the longitudinal direction and a rectangular section 48b that is horizontally long (long in the longitudinal direction of the heat insulator 27) and the upper end of the square section 48b. The trapezoidal trapezoidal portion 48c extending upward from the second slit 48B only covers the first reinforcing rib 45 and does not engage with the first reinforcing rib 45. The first slit 49A of the other second elongated block body 28 is formed in a slit in which a trapezoidal space slightly larger than the rectangular second reinforcing rib 46 whose section is vertically long is formed, and the first slit 49A. Enters the second reinforcing rib 46 and the narrow space at the upper end of the first slit 49 </ b> A is locked to the upper end of the second reinforcing rib 46. In addition, the second slits 49B of the second elongate block body 28 are rectangular rectangular portions 49b having a large cross-section in the longitudinal direction and having a horizontally long cross section (long in the longitudinal direction of the heat insulator 28) and the upper ends of the square portions 49b. And a trapezoidal trapezoidal portion 49c extending upward from the second reinforcing rib 46. The second reinforcing rib simply covers the second reinforcing rib 46 by the second slit 49B. 46 is not locked. The first slits 48A or 49A and the second slits 48B or 49B are alternately provided in the longitudinal direction of the first elongated block body 27 or the second elongated block body 28. In FIG. 6, the square part 49b of the ninth second slit 49B from the right is larger in the longitudinal direction than the square part 49b of the other second slit 49B.

  Therefore, the first elongate block body 27 (or the second elongate block body 28) includes the slit 48 (or the slit 49), so that the first elongate block body 27 or the second elongate block body 28 is turned into the flanges 32 to 38. When accommodated, the first elongate block body 27 (or the second elongate block body 28) can be bent at the slit 48 (or the slit 49) (similar to FIG. 2B). Not shown). Therefore, the first elongate block body 27 or the second elongate block body 28 is hardly cracked or cracked and can be satisfactorily accommodated in the ridges 39 to 44.

  Further, when the first elongate block body 27 or the second elongate block body 28 is accommodated in the flanges 39 to 44, the first slit 48A or 49A is locked to the first reinforcing rib 45 or the second reinforcing rib 46. Thus, the elongated first block body 27 or the second elongated block body 28 can be securely held by the mold 29. Further, when the first elongate block body 27 or the second elongate block body 28 is accommodated in the flanges 39 to 44, the second slits 48B or 49B are engaged with the first reinforcing rib 45 or the second reinforcing rib 46. Therefore, the first elongate block body 27 or the second elongate block body 28 can be smoothly accommodated in the ridges 39 to 44. Furthermore, the first slit 48A or 49A and the second slit 48B or 49B are alternately provided in the longitudinal direction of the first elongated block body 27 or the second elongated block body 28, whereby the first slit 48A or 49A and the first slit 48A or 49A and the first slit 48A or 49A are provided. The first elongate block body 27 or the second elongate block body 27 or the second elongate block body 27 can be securely held on the mold 29 by the engagement with the reinforcing rib 45 or the second reinforcing rib 46. The elongated block body 28 can be smoothly accommodated in the flanges 39 to 44.

  In addition, a concave groove 28M continuous in the longitudinal direction is formed in the left and right central portion of the bottom of the second elongated block body 28, so that the weight of the second elongated block body 28 can be reduced. Further, by forming a concave groove 28M in the bottom of the second elongated block body 28, ribs 50 and 51 are formed on the upper surface of the flat plate portion 30 so as to protrude along the longitudinal direction of the heat insulator (see FIGS. 5 and 8). ) In the concave groove 28M, it is possible to avoid the bottom of the second elongated block body 28 from coming into contact with the ribs 50 and 51.

  The present invention is not limited to the two embodiments described above, and various modifications can be made without departing from the scope of the present invention.

  In the second embodiment, the concave groove 28M is formed at the bottom of the second elongated block body 28, but the concave groove may be omitted and the bottom of the second elongated block body 28 may be formed flat.

  Moreover, in the said 1st and 2nd embodiment, although the cross section comprised the 1st elongate block bodies 1 and 27 in the triangle shape, you may comprise in any shapes, such as trapezoid shape and step shape. That is, the shape of the first elongate block body can be freely changed as long as the hook bolt and the clip can be inserted into the mounting hole H.

  In addition, the number and size of the foam heat insulators shown in the first and second embodiments can be changed according to the formwork.

  1, 2, 27, 28 ... foaming insulation, 1A, 2A ... both end portions (outer portion), 1B, 2B ... main body portion (inner portion), 1R ... inclined surface, 1S ... inclined surface, 1T ... upper end portion, DESCRIPTION OF SYMBOLS 1b ... Inner end surface, 1R, 2R ... Inclined surface, 3,29 ... Formwork, 4,30 ... Flat plate part, 4a ... Concrete placement surface, 4b ... Back surface, 5,31 ... Peripheral rib, 5A ... Upper rib, 5C ... left side rib, 5D ... right side rib, 6-14 ... scissors, 15-22 ... partitioning rib, 23, 24 ... reinforcing rib, 23A ... one end part, 23B ... other end part, 23C ... middle part, 24A ... both ends Part, 24B ... Intermediate part, 25, 26 ... Slit, 26b ... Square part, 26c ... Trapezoid part, 32-38 ... Spear, 39-44 ... Partitioning rib, 45-47 ... Reinforcing rib, 48, 49 ... Slit, 50, 51 ... Rib, H ... Mounting hole, K ... Clip, M ... Spare Scan, N1, N2 ... gap

Claims (3)

A rectangular flat plate portion having a concrete placement surface, a peripheral rib provided along the four sides on the back side opposite to the concrete placement surface, and an interior surrounded by the peripheral rib for dividing into a plurality of elongated ridges A foamable heat insulating material for a plastic mold housed in the elongate bag of a plastic mold frame provided with partition ribs,
A plurality of slits are formed at the bottom of the elongate block body to facilitate bending of the elongate block body when the elongate block body is received in the elongate fold. Forming ,
Reinforcing ribs that connect between the partitioning ribs and between the peripheral ribs and the partitioning rib at predetermined intervals, the slits are formed so as to correspond to the reinforcing ribs, A first slit having a size slightly larger than the reinforcing rib so as to be engaged with the reinforcing rib, and a second slit having a size larger than the first slit so as not to be engaged with the reinforcing rib. And a foamable heat insulating material for plastic molds. The foamable heat insulating body for plastic molds according to claim 1 , wherein the first slits and the second slits are alternately provided in the longitudinal direction of the elongated block body. The peripheral rib and the partitioning rib are set at the same height from the flat plate portion, and are configured to protrude from the peripheral rib and the partitioning rib in a state where the elongated block body is accommodated in the flange. The foamable heat insulating body for plastic molds according to claim 1 or 2 , wherein

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