JP5941415B2 - Connection plate for drawing and connecting concrete products - Google Patents

Description

  The present invention relates to a connection plate for relatively pulling and connecting two concrete products to be connected when connecting and installing concrete products such as gutter blocks.

  A connection plate for drawing and connecting concrete products and a lever (lever bar) used for drawing are disclosed in the following patent documents.

  This connecting plate has a horizontally long plate shape and has engaging grooves for engaging with protrusions protruding from the side surfaces of the concrete product in the vicinity of both ends in the horizontal direction. In addition, the lever for performing the pulling operation is such that an action point piece having a fulcrum part as an action point is fixed to the tip of a rod-like part as a force point, and a fulcrum piece having a fulcrum groove as a fulcrum is pivoted to the action point piece. The fulcrum piece is engaged with the protrusion of one concrete product, the fulcrum groove is engaged with the protrusion of the other concrete product, and the rod-like part is moved down so that the fulcrum piece moves relative to the action point piece. When both concrete products are rotated and pulled by the action of the lever, the protrusions of both the concrete products are engaged with the engaging grooves near both ends of the connection plate.

Japanese Patent No. 3618549 Japanese Patent No. 3980195 Japanese Patent No. 4080097

The conventional lever for drawing a concrete product has a complicated structure in which an action point piece having a fulcrum part is fixed to a rod-like part, and a fulcrum piece having a fulcrum groove is pivotally attached to the action point piece. .
It is an object of the present invention to make the lever a simple structure without a pivoting portion so that the lever can be manufactured easily and inexpensively.

[Claim 1]
The present invention has a horizontally long plate shape, a hole or groove that is a reaction force part for generating a reaction force at the time of drawing by engaging with a protrusion protruding from one side of a concrete product near one end in the horizontal direction. A guide groove that engages with a protrusion protruding from the side of the other concrete product and guides the protrusion at the time of drawing. A connecting plate having
Above the guide grooves, have a fulcrum portion which is notched downward from the connecting plate upper side, the fulcrum portion, with L-shaped or reverse L-shaped, its lower side being formed towards the outside A connecting plate for drawing and connecting concrete products.

In the present invention, the lever may have a rod shape having a support shaft formed at right angles to the axial direction thereof, and does not require a pivoting portion. A protrusion projecting from one side of the concrete product is engaged with the hole or groove of the reaction force portion, and the protrusion of the other concrete product is engaged with the lateral groove of the guide groove. Next, the lever shaft is engaged with the fulcrum, the tip of the lever is brought into contact with the protrusion engaged with the guide groove, and the protrusion is moved by rotating the lever with the protrusion as a fulcrum and the support shaft as an action point. While moving in the inner direction of the connecting plate along the guide groove, the two concrete products are relatively drawn together. When the protrusion moves to the upper end of the longitudinal groove of the guide groove, the concrete product is completely drawn and the drawing connection is completed. Further, the fulcrum part is L-shaped or inverted L-shaped, and the lower side thereof is formed outward, and when the lever is rotated to attract the concrete product, the support shaft of the lever is detached from the fulcrum part. There is no fear, and the lever can be rotated easily.

[Claim 2 ]
Further, according to the present invention, the guide groove is provided in a line symmetrical shape near both ends of the connection plate, the guide groove also serves as a reaction force portion, and the fulcrum portion is provided above both guide grooves. The connection plate according to claim 1 .

  In this way, the left and right guide grooves can be used as the reaction force part, so that the rotation direction when the lever is rotated to draw the concrete product can be freely selected.

[Claim 3 ]
In addition, the present invention has a horizontally long plate-like shape and is a reaction force portion for generating a reaction force at the time of drawing by engaging with a protrusion protruding from one concrete product side surface near one end in the horizontal direction. Guide groove that has a groove, has a horizontal groove near the other end, and a vertical groove that rises from the inner end of the horizontal groove, engages with a protrusion protruding from the other concrete product side, and guides the protrusion when pulled Of the connecting plate body having
The upper horizontal part protrudes from the upper end, the fulcrum part for inserting the tip of the lever is formed in the upper horizontal part, and the guide groove is provided in a line-symmetric shape near both ends of the connecting plate. A connecting plate for drawing and connecting concrete products , wherein the guide groove also serves as a reaction force portion, and the fulcrum portion is provided above both guide grooves .

In the present invention, the lever may be a simple bar and does not require a pivot portion. A protrusion projecting from one side of the concrete product is engaged with the hole or groove of the reaction force portion, and the protrusion of the other concrete product is engaged with the lateral groove of the guide groove. Next, the tip of the lever is inserted downward from the fulcrum part, and is applied to the protrusion engaged with the guide groove, and the protrusion is moved by rotating the lever with the protrusion as a fulcrum and the fulcrum as an action point. While moving in the inner direction of the connecting plate along the guide groove, the two concrete products are relatively drawn together. When the protrusion moves to the upper end of the longitudinal groove of the guide groove, the concrete product is completely drawn and the drawing connection is completed. Furthermore, since the left and right guide grooves can be used as the reaction force portion, the direction of rotation when the lever is rotated to draw the concrete product can be freely selected.

[Claim 4 ]
Moreover, this invention is a connection board of Claim 3 in which the hole or groove | channel which is a 2nd reaction force part is provided in the outer side rather than the vertical groove of both guide grooves.

  The length of the connection plate can be shortened by using the hole or groove of the second reaction force part on the arbitrary side as the reaction force part.

[Claim 5]
In addition, the present invention has a horizontally long plate-like shape and is a reaction force portion for generating a reaction force at the time of drawing by engaging with a protrusion protruding from one concrete product side surface near one end in the horizontal direction. Guide groove that has a groove, has a horizontal groove near the other end, and a vertical groove that rises from the inner end of the horizontal groove, engages with a protrusion protruding from the other concrete product side, and guides the protrusion when pulled Of the connecting plate body having
A lower horizontal portion protrudes from the lower end, a fulcrum portion for inserting the tip of the lever is formed in the lower horizontal portion, and the guide groove is provided in a line symmetrical shape near both ends of the connecting plate. A connecting plate for drawing and connecting a concrete product , wherein the guide groove also serves as a reaction force portion .

In the present invention, the lever may be a simple bar and does not require a pivot portion. A protrusion projecting from one side of the concrete product is engaged with the hole or groove of the reaction force portion, and the protrusion of the other concrete product is engaged with the lateral groove of the guide groove. Next, the tip of the lever is inserted downward from the fulcrum, and a part of the lever is applied to the protrusion engaged with the guide groove, and the lever is rotated with the protrusion as a fulcrum and the fulcrum as an action point. Thus, the protrusion moves along the guide groove toward the inside of the connection plate, and the two concrete products are relatively drawn. When the protrusion moves to the upper end of the longitudinal groove of the guide groove, the concrete product is completely drawn and the drawing connection is completed. Furthermore, since the left and right guide grooves can be used as the reaction force portion, the direction of rotation when the lever is rotated to draw the concrete product can be freely selected.

[Claim 6 ]
Moreover, this invention is a connection board of Claim 5 in which the hole or groove | channel which is a 2nd reaction force part is provided in the outer side rather than the vertical groove of both guide grooves.

  The length of the connection plate can be shortened by using the hole or groove of the second reaction force part on the arbitrary side as the reaction force part.

[Claim 7 ]
In addition, the present invention has a horizontally long plate-like shape and is a reaction force portion for generating a reaction force at the time of drawing by engaging with a protrusion protruding from one concrete product side surface near one end in the horizontal direction. Guide groove that has a groove, has a horizontal groove near the other end, and a vertical groove that rises from the inner end of the horizontal groove, engages with a protrusion protruding from the other concrete product side, and guides the protrusion when pulled Of the connecting plate body having
From the end of a side of the said guide groove, said connecting plate main body and perpendicular fulcrum portion protruding is formed Rutotomoni, the connecting plate body is provided two opposite connection plates of the support part both It is a connection plate for drawing and connecting concrete products characterized by being formed by connecting main bodies .

In the present invention, the lever may be a simple bar and does not require a pivot portion. A protrusion projecting from one side of the concrete product is engaged with the hole or groove of the reaction force portion, and the protrusion of the other concrete product is engaged with the lateral groove of the guide groove. Next, the protrusion is connected along the guide groove by inserting the tip of the lever between the fulcrum and the protrusion engaged with the guide groove, and turning the lever with the protrusion as a fulcrum and the fulcrum as an action point. While moving in the direction of the board, the two concrete products are drawn relatively together. When the protrusion moves to the upper end of the longitudinal groove of the guide groove, the concrete product is completely drawn and the drawing connection is completed. Further, the connection plate main body has a configuration excluding the fulcrum portion of the connection plate of claim 10. By doing in this way, the intensity | strength and rigidity of a fulcrum part can be improved. It is also possible to form two connecting plate main bodies and fulcrum portions facing each other by bending one plate into a U-shape in plan view.

  In the present invention, the lateral groove of the guide groove does not necessarily have to be completely horizontal, and may have an angle of 50 ° or less with respect to the horizontal line. The longitudinal groove of the guide groove does not necessarily have to be vertical, and may be an angle of 30 ° or less with respect to the vertical line.

  By using the connecting plate of the present invention to draw and connect the concrete product, the lever can be made into a simple structure without a pivoting portion, and the lever can be manufactured easily and inexpensively.

  In the present invention, the position of the fulcrum part and the shape of the lever tip part are appropriately designed so that the protruding part of the concrete product can smoothly move along the guide groove and reach the upper end of the vertical groove. desirable. For example, in FIG. 6, the fulcrum where the fulcrum part 11 comes into contact with the support shaft 62 is on the right side of the L-shaped ascending opening (between the horizontal groove and the vertical groove) of the guide groove 2. When the is pushed, the tip portion 61 moves to lift the protrusion 70 (in other words, to move the fulcrum portion 11 downward), so that the protrusion 70 moves smoothly from the lateral groove of the guide groove 2 to the upper end of the vertical groove.

It is the front view and side view of 1 A of connection boards. It is a front view of the connection board 1B. It is a front view of connection board 1C. It is the front view of the lever 6, and a side view. It is explanatory drawing of concrete product drawing by the connection board 1C. It is explanatory drawing of concrete product drawing by the connection board 1C. It is explanatory drawing of concrete product separation by the connection board 1C. It is a front view, a top view, and a side view of the connection plate 1D. It is a perspective view of connection board 1D. It is the front view of the lever 6, and a side view. It is explanatory drawing of concrete product drawing by the connection board 1D. It is explanatory drawing of concrete product drawing by the connection board 1D. It is the front view of the connection board 1E, a bottom view, and a side view. It is a perspective view of the connection board 1E. It is the front view of the lever 6, and a side view. It is explanatory drawing of concrete product drawing by the connection board 1E. It is explanatory drawing of concrete product drawing by the connection board 1E. It is a front view, a rear view, a top view, and a side view of the connection plate 1F. It is a perspective view of the connection board 1F. It is the front view of the lever 6, and a side view. It is explanatory drawing of concrete product drawing by the connection board 1F. It is explanatory drawing of concrete product drawing by the connection board 1F.

  FIG. 1 shows a front view on the left side and a side view on the right side of the connection plate 1A. The connecting plate 1A has a horizontally long plate shape, and a reaction force portion 3 for generating a reaction force at the time of pulling by engaging with a protrusion protruding from one concrete product side surface toward one end (left) in the horizontal direction. (Hole). A guide groove 2 is provided on the other end (right) side. The guide groove 2 has a horizontal groove and a vertical groove rising from the inner end of the horizontal groove, engages with a protrusion protruding from the other side of the concrete product, and guides the protrusion when pulled. Above the guide groove 2, there is a fulcrum part 11 cut out downward from the upper side of the connection plate. The fulcrum part 11 is formed in an L shape by a vertical groove cut out downward from the upper side of the connection plate and a horizontal groove cut out from the lower end of the vertical groove toward the outer horizontal direction.

  FIG. 2 is a front view of the connection plate 1B. The connecting plate 1B has the same configuration as the connecting plate 1A except that the reaction force portion 3 is a groove. Thus, the reaction force part 3 may be a hole or a groove.

  FIG. 3 is a front view of the connection plate 1C. In the connection plate 1C, the guide grooves 2 are provided in a line (vertical line) symmetrical shape near both ends of the connection plate. The guide groove 2 has a horizontal groove and a vertical groove rising from the inner end of the horizontal groove, and further has a vertical groove rising from the outer end of the horizontal groove, but there may be no vertical groove rising from the outer end of the horizontal groove. The two left and right guide grooves 2 also serve as reaction force portions. As will be described later, any one can be used as a reaction force portion and the other can be used as a guide groove. A fulcrum part 11 is provided above both the left and right guide grooves. The shape of the left and right fulcrum portions is also a line (vertical line) symmetrical shape.

  FIG. 4 is an example of a lever used when the concrete plates are pulled (and pulled apart) by the connection plates 1A to 1C, and a front view is shown on the right side and a side view is shown on the left side. The lever 6 is formed with a tip portion 61 in which two plates are fixed in parallel at the tip of a rod-shaped portion 60 of a round pipe, and the two plates are connected to form a support shaft 62. The support shaft 62 is provided in a direction perpendicular to the longitudinal direction of the lever 6.

  5 and 6 are explanatory views of drawing of the concrete product (side groove block) by the connecting plate 1C. FIG. 5 and FIG. 6 show that the projection 70 protruded from the side surface of one (left side) concrete product 7 is engaged with the vertical groove outside the guide groove 2 on the left side of the connecting plate 1C and the other concrete product. The protrusion 70 protruded from the seven side surfaces is engaged in the lateral groove of the guide groove 2 on the right side of the connection plate 1C. The connecting plate 1 </ b> C is inserted between two parallel plates of the tip portion 61 of the lever 6, the support shaft 62 is inserted into the right fulcrum portion 11, and the tip portion 61 is brought into contact with the right protrusion 70.

  When the lever 6 is rotated in the direction of the arrow (clockwise) from the upper stage of FIG. 5 and the state of FIG. 6, the support shaft 62 and the fulcrum portion 11 become fulcrums, and the contact portion between the right projection 70 and the lever tip portion 61 becomes the action point. The right protrusion 70 moves along the guide groove 2 toward the inner side of the connecting plate, and the concrete products 7 and 7 are relatively drawn as shown in the lower part of FIG. When the right projection 70 moves to the upper end of the inner vertical groove of the right guide groove 2, the drawing is completed. At this time, the contact portion between the left protrusion 70 and the guide groove 2 becomes a reaction force, and the left guide groove acts as a reaction force portion.

  The protrusion 70 of the concrete product is obtained by screwing a bolt to an anchor nut embedded in the concrete product so that its head protrudes from the concrete surface. After the drawing is completed, the protrusion bolts are tightened to fix the connecting plate 1C to the concrete surface, and the operation is completed.

  In addition to the above, the protrusions 70 of the concrete product are embedded in concrete with bolts exposed with their heads exposed (embedded), rebars with concrete exposed with their ends exposed (embedded). Although various configurations are possible, the above-described embodiment is most preferable.

  FIG. 7 is an explanatory view of the separation of the concrete product by the connecting plate 1C. When the lever 6 is rotated in the direction of the arrow (counterclockwise) from the state in the upper part of the figure, the support shaft 62 and the fulcrum portion 11 of the lever serve as a fulcrum, and the contact portion between the right projection 70 and the lever tip 61 serves as an action point. The right projection 70 moves along the guide groove 2 toward the outside of the connection plate, and the concrete products 7 and 7 are relatively pulled apart as shown in the lower part of FIG.

  The concrete product drawing and pulling operations have been described for the connection plate 1C, but the connection plates 1A and 1B are similarly performed by engaging the protrusion 70 of the left concrete product with the reaction force portion 3. Can do.

  8 and 9 relate to the connection plate 1D, and a top view is shown on the upper left side of FIG. 8, a front view is shown on the lower left side, and a side view is shown on the right side. The connection plate 1D has a horizontally long plate-like main body 10, and guide grooves 2 are formed near both ends in the lateral direction. The guide groove 2 has a horizontal groove and a vertical groove rising from the inner end of the horizontal groove, and has a line (vertical line) symmetrical shape. One guide groove 2 acts as a reaction force part for generating a reaction force at the time of drawing by engaging with a protrusion protruding from one concrete product side surface, and the other guide groove is the other concrete product side surface. The projection is engaged with the projection, and the projection is guided when being pulled. The lateral groove of the guide groove 2 is inclined by about 45 ° with respect to the horizontal line.

  In the connecting plate 1D, the holes of the second reaction force portion 30 are further provided outside the longitudinal grooves of both guide grooves. The second reaction force portion 30 may be a groove.

  The connection plate 1 </ b> D has an upper horizontal portion 4 projecting from the upper end of the plate-shaped main body 10, and a fulcrum portion 40 for inserting the tip of the lever into the upper horizontal portion 4. The fulcrum part 40 may be a notch having an arbitrary shape in addition to the holes shown in FIGS. In the embodiment of the figure, two are provided on both sides, but this is not necessarily required, and one may be provided in the center depending on the shape of the tip of the lever.

  FIG. 10 is an example of a lever used when a concrete product is pulled by the connection plate 1D, and a front view is shown on the right side and a side view is shown on the left side. The lever 6 is obtained by fixing a plate-like tip portion 61 having a thin tip to the tip of a rod-like portion 60 of a round pipe.

  11 and 12 are explanatory views of the drawing of the concrete product by the connecting plate 1D. 11 and FIG. 12, the projection 70 projected from the side surface of one (left side) concrete product 7 is engaged with the hole of the second reaction force portion 30 on the left side of the connection plate 1D and the other concrete product 7 is engaged. The protrusion 70 protruded from the side surface is engaged in the lateral groove of the guide groove 2 on the right side of the connection plate 1D. And the front-end | tip part 61 of the lever 6 is inserted in the fulcrum part 40 of connection board 1D, and it is made to contact the protrusion 70 on the right side.

  When the lever 6 is rotated in the direction of the arrow (clockwise) from the upper stage of FIG. 11 and the state of FIG. 12, the contact portion between the tip of the lever and the fulcrum 40 is a fulcrum, and the contact between the protrusion 70 on the right and the lever tip 61 The right projection 70 moves along the guide groove 2 toward the inner side of the connection plate, and the concrete products 7 and 7 are relatively drawn as shown in the lower part of FIG. When the right projection 70 moves to the upper end of the inner vertical groove of the right guide groove 2, the drawing is completed. At this time, the contact portion between the left protrusion 70 and the second reaction force portion 30 generates a reaction force.

  The protrusion 70 projected from the side surface of the left concrete product 7 can be engaged with the left guide groove 2 instead of engaging with the hole of the second reaction force portion 30 on the left side of the connection plate 1D. In this case, the contact portion between the left protrusion 70 and the guide groove 2 becomes a reaction force, and the left guide groove acts as a reaction force portion. The use of the left second reaction force portion 30 as the reaction force portion can shorten the length of the connecting plate and reduce the material cost compared to the use of the left guide groove 2.

  13 and 14 relate to the connection plate 1E, with a front view on the upper left side of FIG. 13, a bottom view on the lower left side, and a side view on the right side. The connection plate 1E has a horizontally long plate-like main body 10, and guide grooves 2 are formed near both ends in the lateral direction. The guide groove 2 has a horizontal groove and a vertical groove rising from the inner end of the horizontal groove, and has a line (vertical line) symmetrical shape. One guide groove 2 acts as a reaction force part for generating a reaction force at the time of drawing by engaging with a protrusion protruding from one concrete product side surface, and the other guide groove is the other concrete product side surface. The projection is engaged with the projection, and the projection is guided when being pulled. The lateral groove of the guide groove 2 is inclined by about 10 ° with respect to the horizontal line.

  In the connection plate 1E, the holes of the second reaction force portion 30 are further provided outside the longitudinal grooves of both guide grooves. The second reaction force portion 30 may be a groove.

  The connection plate 1 </ b> E has a lower horizontal portion 5 protruding from the lower end of the plate-shaped main body 10, and a fulcrum portion 50 for inserting the tip of the lever into the lower horizontal portion 5. The fulcrum part 50 may be a notch having an arbitrary shape in addition to the holes as shown in FIGS.

  FIG. 15 is an example of a lever used when a concrete product is pulled by the connection plate 1D, and a front view is shown on the left side and a side view is shown on the right side. The lever 6 is obtained by fixing a plate-like tip portion 61 to the tip of a rod-like portion 60 of a round pipe. The tip portion 61 has a hook-like portion 63, and the tip end portion of the tip portion 61 is narrowed.

  16 and 17 are explanatory views of the drawing of the concrete product by the connecting plate 1E. FIG. 16 and FIG. 17 show that the projection 70 projected from the side surface of one (left side) concrete product 7 is engaged with the hole of the second reaction force portion 30 on the left side of the connection plate 1E and the other concrete product 7 is engaged. The protrusion 70 protruded from the side surface is engaged in the lateral groove of the guide groove 2 on the right side of the connection plate 1E. And the most advanced part 61 of the lever 6 is inserted in the fulcrum part 50 of the connection board 1E, and the hook-shaped part 63 is engaged with the protrusion 70 on the right side.

  When the lever 6 is rotated in the direction of the arrow (counterclockwise) from the upper stage of FIG. 16 and the state of FIG. 17, the contact part between the tip of the lever and the fulcrum part 50 is a fulcrum, and the contact between the right protrusion 70 and the lever flange 63 The right protrusion 70 moves along the guide groove 2 toward the inner side of the connection plate, and the concrete products 7 and 7 are relatively drawn as shown in the lower part of FIG. When the right projection 70 moves to the upper end of the inner vertical groove of the right guide groove 2, the drawing is completed. At this time, the contact portion between the left protrusion 70 and the second reaction force portion 30 generates a reaction force.

  The protrusion 70 protruded from the side surface of the left concrete product 7 can be engaged with the left guide groove 2 instead of engaging with the hole of the second reaction force portion 30 on the left side of the connection plate 1E. In this case, the contact portion between the left protrusion 70 and the guide groove 2 becomes a reaction force, and the left guide groove acts as a reaction force portion. The use of the left second reaction force portion 30 as the reaction force portion can shorten the length of the connecting plate and reduce the material cost compared to the use of the left guide groove 2.

  18 and 19 relate to the connection plate 1F, and a rear view is shown on the upper left side, a top view is shown on the middle stage, a front view is shown on the lower stage, and a side view is shown on the right side. The connecting plate 1F is provided with two connecting plate main bodies 10 having a horizontally long plate shape facing each other, and has a fulcrum portion 12 formed by connecting both connecting plate main bodies 10 together. Therefore, the fulcrum part 12 projects in a direction perpendicular to the main body 10 from the end of the main body 10 on the side where the guide groove is present. In the case of this embodiment, both the connecting plate main body 10 and the fulcrum portion 12 are formed by bending a single metal plate.

  The main body 10 has a reaction force portion 3 (hole) for generating a reaction force at the time of pulling by engaging with a protrusion protruding from one side of the concrete product on one side (left) in the horizontal direction. A guide groove 2 is provided on the other end (right) side. The guide groove 2 has a horizontal groove and a vertical groove rising from the inner end of the horizontal groove, engages with a protrusion protruding from the other side of the concrete product, and guides the protrusion when pulled.

  FIG. 20 is an example of a lever used when the concrete product is pulled by the connection plate 1F, and a front view is shown on the right side and a side view is shown on the left side. The lever 6 is obtained by fixing a plate-like tip portion 61 having a thin tip to the tip of a rod-like portion 60 of a round pipe.

  FIGS. 21 and 22 are explanatory views of the drawing of the concrete product by the connecting plate 1F. 21 and 22 show that the protrusion 70 projected from one (left side) side surface of the concrete product 7 is engaged with the hole of the reaction force part 3 on the left side of the connecting plate 1F and the other concrete product 7 side surface. The protrusion 70 protruding from the engagement is engaged in the lateral groove of the guide groove 2 on the right side of the connection plate 1F. And the front-end | tip part 61 of the lever 6 is inserted between the fulcrum part 12 and the protrusion 70 between the two connection board main bodies 10, and the front-end | tip part 61 is made to contact the action point 12 and the protrusion 70. FIG.

  When the lever 6 is rotated in the direction of the arrow (clockwise) from the state shown in the upper part of FIG. 21 and FIG. 22, the contact part between the projection 70 and the tip part 61 serves as an action point, and the contact part between the fulcrum part 12 and the tip part 61 serves as a fulcrum. The right protrusion 70 moves along the guide groove 2 toward the inside of the connection plate, and the concrete products 7 and 7 are relatively attracted as shown in the lower part of FIG. When the right projection 70 moves to the upper end of the inner vertical groove of the right guide groove 2, the drawing is completed. At this time, a reaction force is generated at the contact portion between the left protrusion 70 and the reaction force portion 3.

  In the connection plate 1F, two main bodies 10 are not necessarily required, but the strength and rigidity of the fulcrum portion can be increased by using two main bodies 10.

  The material of the connection plate of the present invention is preferably a metal plate such as a steel plate. The metal plate can be easily and inexpensively manufactured by cutting or punching a metal plate with a press and bending the metal plate as necessary.

1A, 1B, 1C, 1D, 1E, 1F Connection plate 10 Connection plate body 11 Support point portion 12 Support point portion 2 Guide groove 3 Reaction force portion 30 Second reaction force portion 4 Upper horizontal portion 40 Support point portion 5 Lower horizontal portion 50 Support point portion 6 Lever 60 Bar-shaped part 61 Tip part 62 Support shaft 63 Gutter-shaped part 7 Concrete product 70 Projection

Claims (7)

It has a horizontally long plate shape, has a hole or groove that is a reaction force part for generating a reaction force at the time of drawing by engaging with a protrusion protruding from one side of the concrete product near one end in the horizontal direction, A connecting plate having a lateral groove and a longitudinal groove rising from the inner end of the lateral groove near the other end, engaging with a protrusion protruding from the other concrete product side surface, and having a guide groove that guides the protrusion when pulled There,
Above the guide grooves, have a fulcrum portion which is notched downward from the connecting plate upper side, the fulcrum portion, with L-shaped or reverse L-shaped, its lower side being formed towards the outside A connection plate for drawing and connecting concrete products. The guide groove is provided in a line-symmetrical shape near both ends of the connection plate, the guide groove also serves as a reaction force unit, according to claim 1, wherein the fulcrum portion is provided above both of the guide grooves Connection board. It has a horizontally long plate shape, has a hole or groove that is a reaction force part for generating a reaction force at the time of drawing by engaging with a protrusion protruding from one side of the concrete product near one end in the horizontal direction, A connecting plate main body having a lateral groove and a longitudinal groove rising from the inner end of the lateral groove near the other end, and having a guide groove that engages with a protrusion protruding from the side of the other concrete product and guides the protrusion when pulled of,
The upper horizontal part protrudes from the upper end, the fulcrum part for inserting the tip of the lever is formed in the upper horizontal part, and the guide groove is provided in a line-symmetric shape near both ends of the connecting plate. A connecting plate for pulling and connecting concrete products , wherein the guide groove also serves as a reaction force portion, and the fulcrum portion is provided above both guide grooves . The connection plate according to claim 3 , wherein the hole or groove that is the second reaction force portion is provided outside the longitudinal groove of both guide grooves. It has a horizontally long plate shape, has a hole or groove that is a reaction force part for generating a reaction force at the time of drawing by engaging with a protrusion protruding from one side of the concrete product near one end in the horizontal direction, A connecting plate main body having a lateral groove and a longitudinal groove rising from the inner end of the lateral groove near the other end, and having a guide groove that engages with a protrusion protruding from the side of the other concrete product and guides the protrusion when pulled The lower horizontal portion protrudes from the lower end, the fulcrum portion for inserting the tip of the lever is notched in the lower horizontal portion, and the guide groove has a line symmetrical shape near both ends of the connecting plate. A connection plate for pulling and connecting concrete products , wherein the guide groove is also provided as a reaction force portion . The connection plate according to claim 5 , wherein the hole or groove which is the second reaction force portion is provided outside the longitudinal groove of both guide grooves. It has a horizontally long plate shape, has a hole or groove that is a reaction force part for generating a reaction force at the time of drawing by engaging with a protrusion protruding from one side of the concrete product near one end in the horizontal direction, A connecting plate main body having a lateral groove and a longitudinal groove rising from the inner end of the lateral groove near the other end, and having a guide groove that engages with a protrusion protruding from the side of the other concrete product and guides the protrusion when pulled of,
From the end of a side of the said guide groove, said connecting plate main body and perpendicular fulcrum portion protruding is formed Rutotomoni, the connecting plate body is provided two opposite connection plates of the support part both A connection plate for attracting and connecting concrete products characterized by being formed by connecting main bodies .

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