JP6339979B2 - Precast concrete foundation - Google Patents

Description

  The present invention comprises a plurality of blocks having a predetermined width, and when these blocks are connected to each other at the butted end faces or side surfaces, rising portions, that is, foundation beams for supporting the walls and pillars of the building are formed. It is related to the foundation material made from precast concrete.

  As foundations for buildings such as wooden houses, cloth foundations and solid foundations are well known. The fabric foundation is a foundation that supports a wall surface of a building provided in a band shape having a predetermined height, and the cross-sectional shape exhibits an inverted T time shape having a predetermined thickness. A so-called footing corresponding to a T-shaped horizontal bar is placed on the leveled concrete and buried in the ground to prevent subsidence, and the column and wall surface of the building are supported by the part corresponding to the vertical bar. It is like that. On the other hand, a solid foundation is composed of a so-called rising portion having a predetermined height that supports the wall surface of a building, and a plate-like bottom plate placed on the ground projected from the floor of the building, and these are integrally formed. Made of reinforced concrete. Conventionally, such cloth foundations and solid foundations are obtained by placing a formwork on a construction site and placing concrete, and such a construction method is costly and time consuming. . In recent years, it has become possible to see a construction method in which foundation materials made of block-shaped precast concrete with a predetermined width are manufactured in a factory, transported to a construction site, and foundation materials are obtained by joining the foundation materials together. It was. The precast concrete foundation material used in such a construction method has been proposed in various patent documents, but the present applicant has also proposed a predetermined precast concrete foundation material in Patent Document 1.

JP 2010-070903 A

  As shown in FIG. 4, the precast concrete foundation materials 51 and 52 described in Patent Document 1 are made of a block-like foundation material formed in a predetermined length. The base materials 51 and 52 are provided with joint rails 54 and 55 on their respective end surfaces or side surfaces, and are thereby connected. A joint rail 54 having a hollow box shape and a longitudinal slit 56 formed on the front surface is a female joint rail 54, and a base material provided with the female joint rail 54 is a female base material 51. It has become. The joint rail 55 protruding outward and having a predetermined length in the vertical direction is the male joint rail 55, and the base material provided with the male joint rail 55 is the male base material 52. ing. Both the female base material 51 and the male base material 52 are provided with shear coaters 58 and 58 below the end surfaces where the joint rails 54 and 55 are provided. The female base material 51 is provided with a height adjusting bracket 59 in the lower part thereof. A solid foundation is constructed from such precast concrete foundation materials 51 and 52 as follows. At the construction site, root cutting to dig the ground to a predetermined depth is carried out, crushed stones are spread and rolled, and concrete is placed thereon to form a leveled concrete with a predetermined thickness. In order to form the rising portion of the solid foundation, a plurality of female base materials 51 are arranged at a predetermined interval. Next, male base members 52 and 52 are inserted from above between adjacent female base members 51 and 51. Then, the male joint rail 55 is guided and inserted by the female joint rail 54 and stops at a position where it abuts on the lower end of the slit 56, so that the upper surface of the male base material 52 is brought into contact with the upper surface of the female base material 51. Align. A grout material is injected from the upper part of the connecting portion of the female base material 51 and the male base material 52 and filled in the shear cotter 58. If a bottom plate is formed by placing a bottom reinforcing bar on a leveled concrete to form a bottom plate, a solid foundation formed integrally with a rising portion composed of precast concrete foundation materials 51 and 52 is obtained.

  Formwork is also installed at the construction site by the precast concrete foundation materials 51 and 52 described in Patent Document 1 or by other precast concrete foundation materials that have not been explained but are proposed in other patent documents. Since there is no need to do this, the number of work processes is small and the construction cost is low. However, there is room for improvement. Specifically, there is a demand to obtain a larger joint strength related to the shear resistance with respect to the joint between adjacent precast concrete base materials 51 and 52. Since the foundation material made of precast concrete is joined by a shear cotter, the strength of the shear cotter is related to the joint strength.

FIG. 5A shows a part of two simple precast concrete base materials 60, 60, which are joined to each other at their respective end faces. And the grout material is filled in the shear cotter 61 currently formed in the junction part, and the base materials 60 and 60 are integrated. The solidified body 61 made of a grout material filled in the sheacotter 61 has the shape shown in FIG. 5 (a), and the vertical section, that is, the XX section is shown in FIG. A cross section, that is, a YY cross section is shown in FIG. The strength of the shear cotter 61 is related to the joint strength of the base materials 60 and 60. The strength of the shear cotter 61 means an allowable shear force at the joint and is given by the following equation.
Q _j = min (Q _A , N _A ) 1 formula where Q _{j is} the allowable shear force (N) of the joint.
Q _A : Allowable shearing force (N) in vertical section of shear coater
N _A : Allowable compressive force (N) in horizontal section of shear coater
If the area of the vertical cross section of the shear coater 61 is S1 (= a × b), Q _A is given by the following equation.
Allowable shear stress of addition of Q A ₌ S1 × grout, N _A the area of the horizontal section and S2 are given by the following equation.
N _A = S2 × Allowable compressive stress degree of grout material By the way, considering that the allowable compressive stress degree of the cement-based cured body is much larger than the allowable shear stress degree, if the area S2 has a certain size, _A sufficiently large value can be obtained for the allowable compressive force NA in the horizontal section of the sheacotter. Therefore, in order to increase the strength Q _j of Shiakotta 61, in one set, it is important to increase the allowable shear force Q _j of the bonded portion, it can be seen that it is important to increase the area S1. In order to increase the area S1, the height b of the shear cotter 61 may be increased. FIG. 5 (o) shows base materials 60 ′ and 60 ′ having a sheer cotter 61 ′ having a height higher than that of the sheer cotter 61 shown in FIG. 5 (a). 'Since the intensity Q _j is larger underlying material 60' such Shiakotta 61, bonding strength of 60 'should increase. However, when the shear cotter 61 ′ is enlarged, the strength of the base materials 60 ′ and 60 ′ is adversely affected. When a shearing force is applied to the base members 60 ′ and 60 ′, the shearing force is also applied to the base members 60 ′ and 60 ′ themselves, but the surfaces 63 and 63 on which the maximum shearing stress is applied are shear coaters 61 ′. It becomes a 45 degree surface extended from the upper end and lower end of this. When the shear cotter 61 ′ is increased in the height direction, the area of the action surfaces 63 and 63 is reduced, and the shearing cotter 61 ′ is easily broken. When the base materials 60 'and 60' are broken, the shea cotter 61 'comes off or breaks. That is, if the height of the sheacotter 61 ′ is too high, the strength of the base materials 60 ′ and 60 ′ is adversely affected, and as a result, the bonding strength of the base materials 60 ′ and 60 ′ is weakened. From such a viewpoint, the height of the shear cotter 61 must be approximately 1/3 or less with respect to the height of the foundation material 60, that is, the foundation beam. Due to such restrictions, there is a problem that a sufficiently large bonding strength cannot always be obtained.

  Accordingly, the present invention provides a precast concrete foundation material in which the joint strength of the foundation materials to be joined to each other is sufficiently large in the foundation material made of precast concrete on which the foundation is constructed, whereby a strong foundation can be obtained. It is an object.

In order to achieve the above object, the present invention is configured as a foundation material made of precast concrete in which a rising portion of a foundation is formed. The base material is formed in a plate shape having a predetermined width and a predetermined height, and its end surface or a part of the side surface is formed as a joint portion to be joined to another base material. The joint is provided with a sheacotter filled with a grout material. The shearcotter is formed in a shape in which a plurality of protrusions of a certain height in the horizontal direction are arranged vertically at equal intervals, so that peaks and valleys of a predetermined height are alternately formed. . That is, it is formed in a wave shape. Thus, when the base material and the other base material are joined at the respective joints, the peaks and valleys formed from the projections of one shear coater are the valleys and peaks formed from the projections of the other shear coater. And a cavity filled with the grout material is formed in a wave shape having a constant thickness. Such a shear cotter is preferably provided in the entire height direction at the joint. The joint is provided with a joint rail so that it can be temporarily joined with a joint rail of other foundation material with play.

Thus, in order to achieve the above-mentioned object, the invention according to claim 1 is made of a precast concrete in which a plurality are joined together to form a rising portion of a foundation that supports a wall or a column of a building. The base material is formed into a plate shape having a predetermined width and a predetermined height, and a joining portion is formed on a part of the end surface or side surface of the base material. parts and adapted to be joined, the junction Shiakotta is provided grout is filled, the Shiakotta, the projection of a constant height in the lateral direction, a plurality of vertically equally spaced has coloration the lined shape, when said base member and said other basic materials are joined at each of the joint portions, ridges and valleys are formed from the protrusion of one of said Shiakotta, The other of the sheacotter Serial aligned respectively valleys crest Metropolitan formed from projections, whereby a cavity grout is filled, manufactured precast concrete, characterized in that is adapted to be formed into a wave shape having a predetermined thickness Constructed as a base material.
A second aspect of the present invention is the foundation material according to the first aspect, wherein the shear cotter is formed over substantially the entire height direction of the foundation material. The
The invention according to claim 3 is characterized in that, in the base material according to claim 1 or 2, the shear cotter includes a longitudinal groove having a predetermined depth that traverses the plurality of protrusions in the vertical direction. It is constructed as a precast concrete foundation material.
According to a fourth aspect of the present invention, in the base material according to any one of the first to third aspects, the joint portion is provided with a joint rail having a predetermined length, and is similarly provided on the other base material. It is constructed as a precast concrete base material characterized in that it is temporarily connected to the joint rail having play.
According to a fifth aspect of the present invention, in the foundation material according to the fourth aspect, the joint rail is formed by temporarily connecting the foundation material and the other foundation material when the foundation material and the other foundation material are temporarily coupled. It is constructed as a precast concrete foundation material that is characterized by its uniform height.

As described above, the present invention is configured as a base material made of precast concrete in which a plurality of members are joined together to form a rising portion of a foundation that supports the walls and pillars of a building. It is formed in a plate shape having a width and a predetermined height, and a joint portion is formed on an end surface or a part of a side surface thereof, and is joined to a joint portion formed on another base material . And the joint part is provided with a sheacotter filled with a grout material. According to the present invention, Shiakotta, the projection of a constant height in the lateral direction, equally spaced and caused a multiple ordered shape vertically, the basic material and other basic material in each of the joint Cavities filled with grout material by joining the crests and troughs formed from one sheacotter projection to the troughs and crests formed from the other sheacotter projection, respectively, when joined However, it is formed in a wavy shape with a constant thickness. When the grouting material is filled in this cavity and the base material and another base material are joined, the solidified body made of the grouting material is formed in a wave shape, so that it will act inside the base material as will be described in detail later. The working surface of the maximum shearing stress is distributed over a plurality of surfaces. If it does so, a maximum shear stress will become small and the fracture | rupture of a base material will be prevented. This eliminates the restriction on the height of the conventional shear cotter, that is, the restriction that it should be about 1/3 or less of the beam of the foundation beam. Therefore, according to the present invention, the height of the shear cotter can be freely selected, and a base material having high bonding strength can be provided. According to another invention, the shearcotter is formed over substantially the entire height of the base material. This is the case where the height of the sheacotter is the highest, but at this time the highest joint strength is obtained. According to another invention, the shear cotter includes a vertical groove having a predetermined depth that traverses the plurality of protrusions in the vertical direction. Then, when the grout material is filled and solidified, the longitudinal ribs are formed by the longitudinal grooves in the wavy solid body formed of a plurality of protrusions. This rib provides resistance to twisting, and further ensures that the bonding strength is increased. According to another invention, a joint rail having a predetermined length is provided at the joint, and the joint rail is temporarily coupled to each other in a state having play with joint rails similarly provided on other base materials. ing. Therefore, the construction of the foundation at the construction site becomes extremely easy. Further, since the base material is temporarily joined in a state having play, it is easy to inject the grout material. According to another invention, the height of the joint rail can be easily adjusted because the height of the base material and the other base material are aligned when the base material and the other base material are temporarily joined. The effect of becoming is obtained.

BRIEF DESCRIPTION OF THE DRAWINGS It is a perspective view which shows the base material which concerns on this Embodiment typically, The (a) is a perspective view which shows a female-type base material, The (a) is a male-type base material, respectively. It is the figure which expands and shows the junction part of the base material which concerns on this Embodiment, The (a) is a perspective view which shows the junction part of a female type | mold base material, The (a) shows the junction part of a male type | mold base material, respectively. FIG. It is sectional drawing which shows the state with which the grout material was filled into the part of the base material which concerns on this 2nd Embodiment joined mutually, and the shear cotter of these junction parts. It is a perspective view which shows the female type | mold base material and male type | mold base material of a prior art example. It is a figure which shows a prior art example, The (a) is sectional drawing which shows a part of a pair of base material mutually joined, The (a) is a perspective view of the solidified body which filled the grout material in the shear cotter, and solidified, (C) and (D) are cross-sectional views of the solidified body taken along the lines XX and YY, respectively, and (E) is a cross-sectional view showing a part of a pair of base materials joined together.

  Embodiments of the present invention will be described below. The basic material according to the present embodiment is a block made of precast concrete that is manufactured in advance at a factory, and as shown in FIGS. It consists of a mold base material 2. The male and female molds are determined by the type of joint rail described later, but the female base material 1 and the male base material 2 are joined together to form a rising portion of the foundation, that is, a foundation beam. ing. Although not shown in the drawing, in addition to these base materials 1 and 2, there is also a stand-alone base material that is not connected to other base materials and forms a rising portion independently. However, the description is omitted because it is not related to the present invention.

  Both the female base material 1 and the male base material 2 are formed in a plate shape with a predetermined length and a predetermined thickness, and are integrated with the upper surfaces 4 and 4 that support the pillars and walls of the building, and the concrete cast at the construction site. , And side surfaces 6, 6,... Having a large rectangular area, and end surfaces 7, 7. In the present embodiment, one end surface 7 of the female base material 1 is a joint 8 to which the male base material 2 is joined, but the other end surface 7 is not joined. . Instead, a part of the side surface 6 of the female base material 1 is a joint 8 that is joined to the male base material 2. In contrast, in the present embodiment, both end faces 7 and 7 of the male base material 2 are joint portions 8 and 8 that are joined to the female base material 1.

  Metal joint rails 10 and 10 made of metal are embedded in the joint portions 8 and 8 of the female base material 1. The female joint rail 10 is shown enlarged in FIG. 2A, but is formed in a box shape having a predetermined height and a substantially rectangular cross section. A slit 12 is formed on the front surface of the female joint rail 10 in the longitudinal direction or the vertical direction. When the lower end portion of the male joint rail described below comes into contact with the lower end portion of the slit 12, the heights of the upper surfaces 4 and 4 of the male and female base members 2 and 1 are aligned. The joint 8 is also provided with a shear cotter 14 according to the present embodiment having a shape unique to the present invention, which will be described later. Height adjustment fittings 15 and 15 are provided on the bottom surface 5 of the female base material 1. As a result, it is possible not only to stably install the female base material 1 during construction of the foundation, but also to achieve a desired height.

  Metal joint rails 17 and 17 made of metal are embedded in the joint portions 8 and 8 of the male base material 2. The male joint rails 17 and 17 are shown enlarged in FIG. 2A, but the exposed portions are formed in a shape like a railroad track. The male base material 2 is temporarily joined by inserting such a male joint rail 17 into the female joint rail 10 of the female base material 1. When the male joint rail 17 is inserted into the female joint rail 10, the male joint rail 17 is guided and inserted into the slit 12, but the male joint rail 17 is also at a stop position where the male joint rail 17 contacts the lower end of the slit 12. Is temporarily coupled to the female joint rail 10 with some play or with a gap. Thereby, when constructing the rising portion of the foundation, assembly or temporary coupling becomes easy.

  The shear cotter 14 according to the present embodiment will be described. The shear cotter 14 is provided at the joint 8 of the female base material 1 and at the joint 8 of the male base material 2. The sheacotter 14 has a shape in which a plurality of triangular prism-shaped protrusions 19, 19,... Laid sideways are arranged at equal intervals in the vertical direction. As a result, the crests formed by the protrusions 19 and the troughs between the protrusions 19 and 19 are alternately and continuously formed, and the cross-sectional shape cut vertically is a sawtooth shape. Or it has a wave shape. The height of the peak or the depth of the valley is preferably 10 to 20 mm. In the present embodiment, the protrusions 19 and 19 are formed in a triangular prism shape, but may have a trapezoidal shape or a smooth shape, and a plurality of protrusions may be continuously formed. What is necessary is just to become the shape arranged up and down. In the present embodiment, such a shear cotter 14 is provided so as to cover the entire joint 8, that is, substantially the entire height of the base materials 1 and 2. In the present embodiment, the shear cotter 14 is also formed with two longitudinal grooves 20 and 20. These vertical grooves 20, 20 are grooves that cross the protrusions 19, 19,... In the vertical direction, and the depth of the vertical grooves 20, 20 is the same as the depth of the valleys in the present embodiment. Such a shear cotter 14 is provided in the joint 8 of the female base material 1 and the joint 8 of the male base material 2, but is provided in the female base material 1 and the male base material 2. The sheacotter 14 is slightly different. Specifically, the sheer cotter 14 on the female base material 1 side and the sheer cotter 14 on the male base material 2 side are arranged such that the respective protrusions 19, 19,. As a result, when the female base material 1 and the male base material 2 are temporarily joined together, the peak and valley portions of the shear cotter 14 on the female base material 1 side are the trough portions of the shear cotter on the male base material 2 side. It will be consistent with Yamabe.

  A method for constructing a solid foundation using the female base material 1 and the male base material 2 according to the present embodiment will be described. In a construction site, as is conventionally known, root cutting is performed to dig a predetermined range of ground to a predetermined depth. Next, rolling work is performed in which crushed stones are laid down on the ground ground and pressed with a ramma. Concrete is placed on the crushed crushed stone layer to form a leveled concrete having a predetermined thickness with a predetermined horizontal accuracy. After the leveled concrete has solidified, the female base materials 1, 1,... According to the present embodiment are arranged at predetermined intervals apart from each other as rising portions of the solid foundation. This interval is set to be equal to or slightly wider than the width of the male base material 2. Next, the male base material 2 is inserted from above between the adjacent female base materials 1 and 1. When the male joint rail 17 is inserted into the female joint rail 10 and locked, the height of the male base material 2 becomes equal to the height of the female base material 1. As a result, the female base materials 1, 1,... And the male base materials 2, 2,.

  FIG. 3 shows a part of the temporarily joined female base material 1 and male base material 2, but the protrusions 19, 19,... As a result, the peak of one shear cotter 14 is aligned with the valley of the other shear cotter 14, and the valley of one shear cotter 14 is aligned with the peak of the other shear cotter 14. Since they are aligned in this way, the cavities formed from the respective shear coaters 14 and 14 of the female base material 1 and the male base material 2 are formed in a wave shape having a constant thickness. This thickness is given by the sum of the width d between the sheer cotters 14 and 14 and the height h of the peak of the sheer cotter 14. As described above, the preferable height h of the crest is 10 to 20 mm, and the width d between the sheacotters 14 and 14 is about 0 to 10 mm, so the thickness of the cavity is 10 to 30 mm. The grout material 21 is injected. Then, the grout material 21 is filled in the cavities, that is, the sheacotters 14 and 14. Since the thickness of the cavity is constant and there is a sufficient gap of 10 to 30 mm, the grout material 21 flows smoothly and fills the corners of the sheacotters 14 and 14. As a result, the female base material 1 and the male base material 2 are joined.

  On the leveled concrete, bottom reinforcing bars are arranged in a grid and connected to each other using a connecting cable or the like. Although not shown in the drawing, since predetermined reinforcing bars are projected from the bottom surfaces 5 and 5 of the female and male base materials 1 and 2, they are connected to the bottom reinforcing bars. Concrete is cast to form the bottom plate. When the grout material 21 and the concrete are solidified, a solid solid foundation in which the bottom plate and the rising portion are integrated is obtained.

Since the female mold and the male mold base materials 1 and 2 according to the present embodiment include the shearcotters 14 and 14 having a shape unique to the present invention, they have a strong bonding force. First, since the shear coaters 14 and 14 are provided over the entire joint 8, that is, over the entire height direction of the female mold and the male mold base materials 1 and 2, the joint allowance given by the above-described one set is provided. The shear force _Qj is sufficiently large. And the grout material 21 solidified by the sheacotters 14 and 14 is formed in a wave shape having a constant thickness as shown in FIG. That is, the shape of the solidified grout material 21 is wavy in the female and male base materials 1 and 2. Then, when a shearing force is applied to the female and male base materials 1 and 2, the action surfaces 23, 23,... Of the maximum shear stress acting on the female and male base materials 1 and 2 are female and male. The base materials 1 and 2 are dispersed on a plurality of surfaces. As a result, shear failure of the female mold and the male mold base materials 1 and 2 is prevented. Thus female type according to the present embodiment, the male basic material 1 and 2, large allowable shear force Q _j at the junction Shiakotta 14, 14, and the female, the shear of the male basic materials 1 Since destruction can be prevented, it can be said that it has strong bonding strength.

  The female mold and the male mold base materials 1 and 2 according to the present invention can be implemented in various forms without being limited to the above embodiment. First, in the present embodiment, it has been described that the sheer cotters 14 and 14 are provided over the entire surface of the joint 8, that is, over the entire height direction, but it is not always necessary to do so. The height of the shear cotters 14, 14 can be set freely. However, in the shear coaters 14 and 14 according to the present invention, the working surface of the maximum shear stress in the female and male base materials 1 and 2 is dispersed, thereby making it larger than 1/3 of the height of the joint 8. Is possible. Therefore, in order to obtain the effect of the present invention, the height of the shear cotters 14 and 14 should be larger than 1/3 of the height of the joint portion 8, and preferably 1/2 or more. . In the shear cotter 14, two vertical grooves 20 are provided in the present embodiment, but the number of the vertical grooves 20 is not limited. Further, the longitudinal groove 20 is not necessarily essential.

  The sheacotters 14 and 14 according to the present embodiment are a female base material 1 and a male base material 2, and the protrusions 19 and 19 are displaced from each other up and down, thereby the male base material 1 and the female base material. It has been described that when the material 2 is joined, the peak portion of one shear cotter 14 is aligned with the valley portion of the other shear cotter 14, and the valley portion of one shear cotter 14 is aligned with the peak portion of the other shear cotter 14. However, in the female base material 1 and the male base material 2, the vertical positions of the protrusions 19, 19,. In this case, the peak part of one sheer cotter 14 and the peak part of the other sheer cotter 14 are aligned with the valley part of one sheer cotter 14 and the valley part of the other sheer cotter 14, respectively. That is, in the cavity formed by one sheer cotter 14 and the other sheer cotter 14, narrow constricted portions where the ridges and ridges are aligned and wide portions where the valleys and the valleys are aligned are alternately formed. . The width of the constricted portion is important in the injection of the grout material, and the constricted portion should be secured, for example, about 10 mm so that the grout material is smoothly filled.

  The embodiment of the present invention can be modified in other points. For example, the female and male joint rails 10 and 17 can be deformed. These shapes are not limited to the above-described shapes, and may be any shapes as long as they can be temporarily coupled to each other. Furthermore, the joint rail may not be provided in the joint portion 8 of the female mold and the male mold base materials 1 and 2. This is because the grout material may be directly injected and joined without temporary bonding.

  The female and male foundation materials 1 and 2 according to the present embodiment can also be used for the construction of a cloth foundation by placing concrete as a footing on the bottom surfaces 6 and 6.

DESCRIPTION OF SYMBOLS 1 Female base material 2 Male base material 4 Upper surface 6 Side surface 7 End surface 8 Joint part
DESCRIPTION OF SYMBOLS 10 Female joint rail 12 Slit 14 Shear cotter 15 Height adjustment metal fitting 17 Male joint rail 19 Protrusion 21 Grout material

Claims (5)

A plurality of precast concrete foundation materials that are joined together to form a rising part of the foundation that supports the walls and pillars of the building,
The base material is formed in a plate shape having a predetermined width and a predetermined height, and a joining portion is formed on an end surface or a part of the side surface so as to be joined to the joining portion formed on another base material. And
The joint is provided with a sheacotter filled with grout material,
The Shiakotta, the projection of a constant height in the lateral direction, and caused a multiple ordered shape vertically at equal intervals,
When the base material and the other base material are joined to each other at the joint portions, a peak portion and a valley portion formed from the projections of one of the sheercotters are formed from the projections of the other shearcotter. A base material made of precast concrete, characterized in that the cavities that are aligned with the valleys and the peaks and are filled with the grout material are formed in a wave shape with a constant thickness .   The foundation material according to claim 1, wherein the shear cotter is formed over substantially the entire height direction of the foundation material.   The foundation material according to claim 1 or 2, wherein the shear cotter includes a longitudinal groove having a predetermined depth that crosses the plurality of protrusions in the vertical direction.   The base material according to any one of claims 1 to 3, wherein the joint portion is provided with a joint rail having a predetermined length, and has play with the joint rail provided similarly to other base materials. A precast concrete foundation material characterized by being temporarily joined together in a state. 5. The base material according to claim 4, wherein when the base material and the other base material are temporarily connected, the joint rail is configured such that the heights of the base material and the other base material are aligned. Precast concrete foundation material characterized by that.

Images