JP2015175194A - Reinforcement spacer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a resin reinforcement spacer excellent in workability when installed in a reinforcement.SOLUTION: A reinforcement spacer 100 is installed in a reinforcement. The resin reinforcement spacer 100 comprises a fitting part 20 having an insertion port 22 for inserting a first reinforcement of extending in one direction and a holding part 28 for holding the inserted first reinforcement and fitted to the first reinforcement, a pair of arm parts 40 provided so as to sandwich the holding part 28 and regulating rotation to the first reinforcement by abutting on a second reinforcement existing in the vertical direction to the one direction and a leg part 60 provided on the opposite side of the insertion port 22 side on the basis of the first reinforcement when viewed from the vertical direction and holding an interval between a form and the reinforcement.

Description

  The present invention relates to a reinforcing bar spacer.

  2. Description of the Related Art Conventionally, in reinforced concrete work in civil engineering and construction, a reinforcing bar spacer is used which is attached to a reinforcing bar to maintain the distance between the reinforcing bar and the formwork to ensure the cover thickness. As a spacer for a reinforcing bar, a spacer made of a cement or metal material has been used because of its compatibility with concrete. Recently, instead of these materials, resin-made ones that are lightweight and have excellent mass productivity and handleability have been proposed.

  By the way, since the reinforcing bar spacer is used by being mounted on the reinforcing bar, the fluidity of the concrete may be hindered. For this reason, there are cases where voids are generated in the concrete and cracks are caused. In order to avoid such a phenomenon, in Patent Document 1, as a reinforcing bar spacer made of resin, a reinforcing bar fitting part to be mounted on the reinforcing bar and a radially projecting outer periphery of the reinforcing bar fitting part are provided with the tip of the mold frame. A thing provided with a plurality of positioning projection parts contacted with the surface is proposed.

  In the reinforcing bar spacer of Patent Document 1, the covering thickness of the reinforcing bar when the plurality of positioning protrusions are in contact with any two adjacent positioning protrusions of the plurality of positioning protrusions to the mold frame. It is always formed to be equal. Such a shape makes it difficult for the flow of the aggregate of the concrete to be hindered, and the occurrence of cracks in the concrete can be sufficiently reduced.

Japanese Patent No. 4082709

  Since reinforced concrete is used for various applications, the reinforcing bar spacer is required to have excellent workability regardless of the type of structure. For example, in the case of a reinforced concrete such as a building or a bridge that requires high strength, the outer diameter of the reinforcing bar increases, the number of reinforcing bars increases, and the interval between the reinforcing bars decreases. On the other hand, since the cover thickness needs to ensure a predetermined size according to the use, the size of the reinforcing bar spacer is required to have a corresponding size. Here, when a conventional resin reinforcing bar spacer is used, the positioning protrusion that does not contact the mold may come into contact with the adjacent reinforcing bar, which may hinder the work. For this reason, it is calculated | required that it is the spacer for reinforcing bars which is excellent in workability | operativity, even if the number of reinforcing bars increases irrespective of the use of a reinforced concrete.

  This invention is made | formed in view of the said situation, and it aims at providing the resin-made spacer for reinforcing bars which is excellent in workability | operativity at the time of mounting | wearing to a reinforcing bar.

  The present invention is a reinforcing bar spacer that is mounted on a reinforcing bar and maintains a space between the reinforcing bar and the formwork, and includes an insertion port for inserting a first reinforcing bar that extends in one direction, and the inserted first reinforcing bar. A holding portion that holds the reinforcing bar is provided, and is provided so as to sandwich the holding portion and the fitting portion that fits the first reinforcing bar, and the rotation with respect to the first reinforcing bar extends in a direction perpendicular to the one direction. A pair of arm portions that are in contact with and regulate the existing second reinforcing bar, and provided on the opposite side of the insertion port side with respect to the first reinforcing bar when viewed from the vertical direction, The resin-made reinforcing bar spacer is provided.

  Since the reinforcing bar spacer of the present invention is made of resin, it is lightweight and has excellent handleability. Moreover, it has individually the leg part which maintains the space | interval of a reinforcing bar and a formwork, and the arm part which contact | abuts to a 2nd reinforcing bar and controls rotation with respect to a 1st reinforcing bar. For this reason, an operator can distinguish an arm part and a leg part easily, and can perform attachment to a reinforcing bar smoothly. And since a fitting part fits to a 1st reinforcing bar and an arm part controls rotation with respect to a 1st reinforcing bar, the number and size of a leg part holding a space with a formwork are reduced. be able to. As a result, at the time of mounting on the reinforcing bar, the interference between the leg portion and the reinforcing bar hardly occurs, and the mounting of the reinforcing bar spacer on the reinforcing bar can be performed smoothly and quickly.

  Since the reinforcing bar spacer of the present invention can reduce the number and thickness of the leg portions, the volume of the entire reinforcing bar spacer can be reduced. For this reason, the attachment work to a reinforcing bar can be performed efficiently irrespective of the use of a reinforced concrete. That is, the reinforcing bar spacer of the present invention has high versatility and excellent workability.

  The arm portion of the reinforcing bar spacer includes a tip portion that contacts the second reinforcing bar, and a connecting portion that connects the tip portion and the fitting portion, and the tip portion is more than the fitting portion and the connecting portion. It is preferable that the first reinforcing bar is configured to protrude in the longitudinal direction. This makes it possible to quickly and easily perform the mounting operation such that the arm portion comes into contact with the second reinforcing bar. Further, the overall volume of the rebar spacer can be further reduced while maintaining excellent workability as compared with the structure in which the entire arm portion is in contact with the second rebar.

  The fitting portion of the rebar spacer includes a guide portion that guides the insertion of the first rebar from the insertion port side along the insertion direction of the first rebar, and the holding portion by the elastic force. It is preferable to provide a support portion to be fixed in this order. Thus, when the fitting portion has the guide portion, the first rebar can be more easily inserted from the insertion port. In addition, since the fitting portion has the support portion, the reinforcing bar spacer can be more stably fixed to the first reinforcing bar.

  It is preferable that the number of leg portions of the reinforcing bar spacer is two or three. By reducing the number of legs in this way, the mounting operation becomes easier and workability can be further improved. Moreover, since it becomes possible to reduce the whole volume of the spacer for reinforcing bars, it contributes to the reduction of manufacturing cost and the cracking of concrete.

  ADVANTAGE OF THE INVENTION According to this invention, the spacer for reinforcing bars which is excellent in workability | operativity at the time of mounting | wearing with a reinforcing bar can be provided.

It is a perspective view of the spacer for reinforcing bars which concerns on one Embodiment of this invention. It is a front view of the spacer for reinforcing bars which concerns on one Embodiment of this invention. It is a side view of the spacer for reinforcing bars which concerns on one Embodiment of this invention. It is a top view of the spacer for reinforcing bars which concerns on one Embodiment of this invention. It is a schematic diagram which shows the usage example of the spacer for reinforcing bars which concerns on one Embodiment of this invention. It is a schematic diagram which shows another example of use of the spacer for reinforcing bars which concerns on one Embodiment of this invention. It is a front view of the spacer for reinforcing bars which concerns on another embodiment of this invention.

  In the following, preferred embodiments of the present invention will be described with reference to the drawings as the case may be. In the drawings, the same or equivalent elements are denoted by the same reference numerals, and redundant description is omitted.

  FIG. 1 is a perspective view of a reinforcing bar spacer 100 according to the present embodiment. The rebar spacer 100 is a resin spacer that is attached to the rebar and maintains the distance between the rebar and the formwork. The reinforcing bar to which the reinforcing bar spacer 100 is attached is, for example, a reinforcing bar for reinforced concrete used for a building or a bridge. There is no restriction | limiting in particular in the size of a reinforcing bar, The spacer 100 for reinforcing bars can be mounted | worn with the reinforcing bar of various sizes with an outer diameter of 10-32 mm, for example. For this reason, it has high versatility.

  The reinforcing bar used for the concrete for reinforcing bars usually has a first reinforcing bar extending in the vertical direction and a second reinforcing bar extending in the horizontal direction and orthogonal to the first reinforcing bar. The reinforcing bar spacer 100 can be suitably used around the intersection of the first reinforcing bar and the second reinforcing bar. Since the reinforcing bar spacer 100 is made of resin, it is lightweight, and when compared with the same cover thickness, it can be made smaller than a conventional reinforcing bar spacer made of resin. In addition, the reinforcing bar spacer 100 is excellent in mass productivity and can be attached to reinforcing bars of various sizes and has high versatility.

  FIG. 2 is a front view of the reinforcing bar spacer 100 of the present embodiment. The reinforcing bar spacer 100 extends from the fitting portion 20, a pair of arm portions 40 extending in the left-right direction in FIG. Two legs 60. FIG. 2 shows a state in which the first reinforcing bar 50 is fitted to the fitting portion 20.

  As shown in FIG. 2, the fitting portion 20 constitutes an outer frame of the fitting portion main body 21, and is fitted to the fitting portion main body 21 having a reverse C shape and the first reinforcing bar 50. 21 has an insertion port 22 into which the first reinforcing bar 50 is inserted, and a holding portion 28 that holds the reinforcing bar spacer 100 in contact with the fitted first reinforcing bar 50. The insertion opening 22 is formed in a size that allows the first reinforcing bar 50 to be inserted.

  The holding portion 28 has a partially arcuate curved surface that is curved along the peripheral surface of the first reinforcing bar 50. For this reason, the contact area of the holding | maintenance part 28 and the surrounding surface of the 1st reinforcing bar 50 can be enlarged. The fitting part 20 includes a guide part 25, a first support part 26, and a second support part 27. The guide part 25, the first support part 26, and the second support part 27 are each band-shaped, are arranged in this order from the insertion port 22 side, and extend toward the holding part 28. One ends of the guide portion 25, the first support portion 26, and the second support portion 27 are connected to the fitting portion main body 21. On the other hand, tip portions 27a, 26a, and 25a that are the other ends of the second support portion 27, the first support portion 26, and the guide portion 25 are close to the holding portion 28 in this order.

  The guide portion 25, the first support portion 26, and the second support portion 27 extend from the fitting portion main body 21 forming the insertion port 22 toward the holding portion 28, and are formed to be deformable. Yes. Each of the guide portion 25, the first support portion 26, and the second support portion 27 forms a pair, and is formed in a substantially C shape as shown in FIG. Each of the guide part 25, the first support part 26, and the second support part 27 is curved so as to be convex in the facing direction. Accordingly, when the reinforcing bar spacer 100 is fitted to the first reinforcing bar 50, the first reinforcing bar 50 can be easily moved from the insertion port 22 to the holding portion 28.

  Of the guide part 25, the first support part 26, and the second support part 27, the guide part 25 is provided closest to the insertion port 22. The guide portion 25 guides the insertion into the fitting portion 20 when the first rebar 50 is inserted from the insertion port 22. That is, when the first reinforcing bar 50 is inserted into the reinforcing bar spacer 100 from the insertion port 22, the first reinforcing bar 50 is directed toward the holding part 28 while the guide part 25 is expanded to the first reinforcing bar 50, and the first reinforcing bar 50 is moved to the first reinforcing bar 50. The reinforcing bar 50 reaches the holding portion 28 and is fitted into the fitting portion 20. At this time, the first support part 26 and the second support part 27 are pushed and expanded together with the guide part 25, and then the fitting part 20 is fitted to the first reinforcing bar 50.

  The reinforcing bar spacer 100 fitted to the first reinforcing bar 50 by the fitting part 20 is fixed so as to be rotatable with respect to the first reinforcing bar 50. At this time, the distal end portion 27 a of the second support portion 27 comes into contact with the first reinforcing bar 50 together with the holding portion 28. Therefore, the reinforcing bar spacer 100 is fixed to the first reinforcing bar 50 at the three points of the holding part 28 and the pair of tip parts 27a. The second support portion 27 is elastically deformed by contacting the first reinforcing bar 50. The reinforcing bar spacer 100 is stably fixed to the first reinforcing bar 50 by the elastic force accompanying the elastic deformation.

  The distal end portion 27a of the second support portion 27 is formed in a substantially C-shaped partial cylindrical shape. For this reason, the reinforcing bar spacer 100 can be stably attached to the first reinforcing bars 50 having various outer diameters. When the outer diameter of the first reinforcing bar 50 is increased, the distal end portion 27a of the second support portion 27 can contact the first reinforcing bar 52 with a curved surface (cylindrical inner wall surface). For this reason, the contact area between the first reinforcing bar and the tip portion 27a of the second support portion 27 can be increased.

  The first support portion 26 provided between the guide portion 25 and the second support portion 27 is in contact with the first rebar 50 in a state in which the rebar spacer 100 is fitted to the first rebar 50. It does not have to be in contact. The distal end portion 26 a of the first support portion 26 is provided farther from the holding portion 28 than the distal end portion 27 a of the second support portion 27. For this reason, when the outer diameter of the 1st reinforcing bar 50 is small, the front-end | tip part 26a of the 1st support part 26 and the 1st reinforcing bar 50 do not contact | abut.

  On the other hand, when the outer diameter of the first reinforcing bar 50 is increased, the second support portion 27 is further elastically deformed toward the outside, and the first reinforcing bar 50 has the tip end portion 26a of the first supporting portion 26 and the case. As a result, the distal end portion 25a of the guide portion 25 comes into contact. At this time, the reinforcing bar spacer 100 is supported by the holding portion 28, the pair of tip portions 27a, the pair of tip portions 26a, and in some cases, the pair of tip portions 25a. Accordingly, the reinforcing bar spacer 100 is more stably fixed to the first reinforcing bar 50 by the elastic force of the first support part 26 and the second support part 27 and, in some cases, the elastic force of the guide part 25. The Rukoto.

  The tip portions 26a of the pair of first support portions 26 provided to face each other are formed in a bowl shape so as to protrude in the facing direction. That is, the front end portion 26a is opposed to the above-mentioned so that the belt-shaped first support portion 26 that is connected to the fitting portion main body 21 and extends from the vicinity of the insertion opening 22 toward the holding portion 28 is substantially L-shaped. Bent in the direction.

  Since the 1st support part 26 has the above-mentioned shape, when fitting the reinforcing bar spacer 100 in the 1st reinforcing bar 50, the direction which leaves | separates from the holding part 28 to the reinforcing bar spacer 100 (FIG. 1), even if the first reinforcing bar 50 is separated from the holding part 28, the tip 26a of the first supporting part 26 is applied to the first reinforcing bar 50 or the second supporting part 27. It will abut. Accordingly, the upward movement of the reinforcing bar spacer 100 in FIG. 2 can be braked, and the detachment of the reinforcing bar spacer 100 from the first reinforcing bar 50 can be suppressed.

  The tip portions 25a of the pair of guide portions 25 provided to face each other are formed in a bowl shape so as to protrude in a direction opposite to the facing direction. That is, in the belt-shaped guide portion 25 extending from the vicinity of the insertion opening 22 toward the holding portion 28, the tip end portion 26a is bent in a direction opposite to the facing direction so as to be substantially L-shaped. For this reason, when the reinforcing bar spacer 100 is fitted to the first reinforcing bar 50, the distal end portion 25 a pushed and expanded on the first reinforcing bar 50 comes into contact with the first supporting part 26 and the first supporting part 26. Is also expanded in the same manner as the guide portion 25. Therefore, the fitting to the fitting portion 20 to the first reinforcing bar 50 can be easily performed. At this time, the expanded first support portion 26 contacts the second support portion 27, and the second support portion 27 is also expanded in the same manner as the guide portion 25 and the first support portion 26. May be.

  Further, when the reinforcing bar spacer 100 is fitted to the first reinforcing bar 50, an external force in a direction away from the holding portion 28 (upward direction in FIG. 2) acts on the reinforcing bar spacer 100, and the first reinforcing bar. Even if the holding portion 28 is separated from the 50, the first support portion 26 comes into contact with the distal end portion 25 a of the guide portion 25. Thus, the first support portion 26 and the guide portion 25 cooperate to brake the upward movement of the reinforcing bar spacer 100 in FIG. In this manner, not only the second support portion 27 but also the first support portion 26 and the guide portion 25 can sufficiently suppress the detachment of the rebar spacer 100 from the first rebar 50.

  The pair of arm portions 40 are provided so as to sandwich the holding portion 28 in the fitting portion 20. The arm portion 40 extends in the left-right direction in FIG. 2 and abuts on a second rebar 70 provided so as to be orthogonal to the first rebar 50, thereby reinforcing the rebar with the first rebar 50 as the center. The spacer 100 has a function of restricting the rotation of the spacer 100. The angle α formed by the arm portion 40 and the fitting portion main body 21 is preferably an acute angle, for example, 60 to 85 ° C. With such an angle α, in the front view as shown in FIG. 2, the arm portion 40 can be formed in a substantially linear shape, the structure is simplified, mass production is facilitated, and the arm portion 40 is facilitated. The volume of can be reduced.

  FIG. 3 is a side view of the reinforcing bar spacer 100 when viewed from the direction in which the second reinforcing bar 70 extends. The arm part 40 includes a tip part 40 a that contacts the second reinforcing bar 70, and a connecting part 40 b that connects the tip part 40 a and the fitting part 20. As shown in FIG. 3, the distal end portion 40 a protrudes in the longitudinal direction of the first reinforcing bar 50 (leftward in FIG. 3) from the fitting portion 20. In this way, the lower surface of the distal end portion 40 a of the arm portion 40 is in contact with the second reinforcing bar 70.

  The arm portion 40 may be configured such that not only the distal end portion 40 a but also the connecting portion 40 b abuts on the second rebar 70, but only the distal end portion 40 a abuts on the second rebar 70. Is preferred. Thereby, the volume of the arm part 40 can be made small. Further, when the first reinforcing bar 50 is fitted to the fitting part 20, the arm part 40 is inclined with respect to the second reinforcing bar 70, and one arm part 40 has the second reinforcing bar 70 on its upper surface. When the other arm portion 40 comes into contact with the second rebar 70 on its lower surface (twisted position), the rebar spacer is centered on the first rebar 50. By rotating 100, it is possible to easily correct the positional relationship such that both arm portions 40 are in contact with the second reinforcing bar 70 on the lower surface.

  There is no restriction | limiting in particular in the size of the arm part 40, What is necessary is just a size which can control rotation centering on the 1st reinforcing bar 50. FIG. It is preferable that the shortest distance from the distal end portion 40a of the arm portion 40 to the first reinforcing bar 50 is shorter than the shortest distance from the distal end portion 60a of the leg portion 60 to the first reinforcing bar 50. Accordingly, even when the number of reinforcing bars is large and the reinforcing bars are closely assembled, the attaching / detaching operation of the reinforcing bar spacer 100 to the reinforcing bars can be further facilitated.

  FIG. 4 is a view of the reinforcing bar spacer 100 of FIG. 2 as viewed from above (the leg 60 side). The distal end portion 40a of the arm portion 40 has a flat plate shape. As a result, the contact area between the second reinforcing bar 70 and the arm portion 40 is increased, and the rotation of the reinforcing bar spacer 100 around the first reinforcing bar 50 can be sufficiently restricted.

The distal end portion 40 a of the arm portion 40 protrudes in the longitudinal direction of the first reinforcing bar 50 from the side surface of the fitting portion 20. The thickness L ₁ of the fitting part 20 is preferably smaller than the protruding length L ₂ of the arm part 40. Thus, the rotation of the reinforcing bar spacer 100 around the first reinforcing bar 50 can be sufficiently suppressed while reducing the volume of the reinforcing bar spacer 100.

  As shown in FIG. 3, when viewed from the longitudinal direction of the second reinforcing bar 70 extending in a direction perpendicular to the direction in which the first reinforcing bar 50 extends, the leg portion 60 is based on the first reinforcing bar 50. As described above, it is provided on the side opposite to the insertion port 22 side. That is, the leg portion 60 is disposed above the first reinforcing bar 50, and the insertion port 22 is disposed below the first reinforcing bar 50. Thus, since the insertion port 22 and the leg part 60 are provided so that the 1st reinforcement 50 may be pinched | interposed, when inserting the 1st reinforcement 50 from the insertion opening 22, the leg part 60 becomes obstructive. In addition, the first rebar 50 can be easily fitted to the fitting portion 20. Moreover, since both the leg part 60 and the arm part 40 are located above the 2nd reinforcing bar 70, attachment to a reinforcing bar can be performed easily.

  As shown in FIG. 2, the leg portion 60 is provided on the side opposite to the insertion port 22 side when the holding portion 28 is viewed as a reference or when the pair of arm portions is viewed as a reference. The leg portion 60 starts from the holding portion 28 and extends radially in a direction substantially opposite to the direction from the holding portion 28 toward the insertion port 22. The leg portion 60 is formed in an inverted C shape as shown in FIG. The tip 60a of the leg 60 abuts on the concrete formwork 80 when the reinforcing bar spacer 100 is attached to the reinforcing bar. By changing the distance from the holding portion 28 to the distal end portion 60a of the leg portion 60, the distance between the reinforcing bars (the first reinforcing bar 50 and the second reinforcing bar 70) and the formwork 80 can be adjusted.

  In the present embodiment, the number of the leg portions 60 is two, but the number of the leg portions 60 is not particularly limited, and may be one or three or more, for example. However, from the viewpoint of achieving both excellent workability and mass productivity of the reinforcing bar spacer 100 at a high level, two or three are preferable, and two are more preferable. When there are two leg portions 60, the angle β formed by the pair of leg portions 60 is 40 to 40 from the viewpoint of controlling the distance between the reinforcing bar and the formwork 80 with high accuracy and miniaturizing the reinforcing bar spacer 100. The angle is preferably 80 °, and more preferably 50 to 70 °.

  The angle γ formed by the leg portion 60 and the arm portion 40 is preferably larger than the angle β. Thereby, it becomes easy for an operator to grip the outside of the leg portion 60, and the workability of attaching the reinforcing bar spacer 100 to the reinforcing bar can be further improved. For example, the angle γ is preferably 60 to 80 °, and more preferably 65 to 75 °.

  The leg part 60 may become thin as it goes to the front-end | tip part 60a. In addition, the leg portion 60 may be provided with reinforcing portions 62 and 64 in order to improve the rigidity of the leg portion. As shown in FIGS. 2 and 3, the reinforcing portion 62 has a pyramid shape that narrows from the holding portion 28 toward the distal end portion 60 a. The reinforcing portion 64 is formed in a fin shape on the peripheral edge portion of the leg portion 60. By providing such reinforcing portions 62 and 64, it is possible to maintain high rigidity even if the volume of the resin reinforcing bar spacer 100 is reduced, and deformation due to external force or the like can be suppressed.

  FIG. 5 is a view of the reinforcing bar spacer 100 as viewed from the direction (one direction) in which the first reinforcing bar 50 extends, and shows a state when the reinforcing bar spacer 100 is attached to the reinforcing bar. The fitting part 20 of the reinforcing bar spacer 100 is fitted to the first reinforcing bar 50 and is urged by the holding part 28 by the second support part 27. Accordingly, the reinforcing bar spacer 100 is restrained from moving upward with respect to the first reinforcing bar 50. Therefore, fluctuations in the distance between the reinforcing bar spacer 100, the first reinforcing bar 50, and the second reinforcing bar 70 can be suppressed.

  The arm portion 40 abuts from the first reinforcing bar 50 side to the second reinforcing bar 70 whose tip 40a is orthogonal to the first reinforcing bar 50 and is opposed to the side surface of the fitting portion 20. ing. The second reinforcing bar 70 is arranged farther from the holding unit 28 than the first reinforcing bar 50. When the arm part 40 of the reinforcing bar spacer 100 is fitted to the first reinforcing bar 50, the second reinforcing bar 70 and the tip 40a of the arm part 40 come into contact with each other. You may be comprised so that it may elastically deform upwards.

  As a result, in a state where the reinforcing bar spacer 100 is mounted on the reinforcing bar, a force that the arm portion 40 urges the second reinforcing bar 70 acts, and the rotation of the reinforcing bar spacer 100 around the first reinforcing bar 50 is performed. The movement can be fully regulated. Therefore, in the state where the reinforcing bar spacer 100 is attached to the reinforcing bar, it is possible to sufficiently suppress the fluctuation of the interval between the mold 80 and the reinforcing bars 50 and 70 due to the reinforcing bar spacer 100 rattling. Note that the force by which the second support portion 27 urges the first rebar 50 against the holding portion 28 is larger than the force by which the arm portion 40 urges the second rebar 70. It can suppress that the 1st reinforcing bar 50 leaves | separates.

  As shown in FIG. 5, when viewed from the longitudinal direction of the first reinforcing bar 50, the arm part 40 and the leg part 60 of the reinforcing bar spacer 100 are located above the second reinforcing bar 70. That is, the arm part 40 and the leg part 60 are provided on the side opposite to the insertion port 22 side with the second reinforcing bar 70 as a reference. By having such a structure, when mounting on a reinforcing bar, the arm part 40 and the leg part 60 are suppressed from interfering with surrounding reinforcing bars, and the mounting work on the reinforcing bar can be facilitated.

  FIG. 6 is a view showing a state when the reinforcing bar spacer 100 is fitted to the first reinforcing bar 52. The first reinforcing bar 52 has a larger outer diameter than the first reinforcing bar 50. When the holding portion 28 is formed so as to be in close contact with the first reinforcing bar 50 having a small outer diameter, when the holding portion 28 is fitted to the first reinforcing bar 52, the holding portion 28 is interposed between the holding portion 28 and the first reinforcing bar 52. A slight gap occurs. However, not only the distal end portion 27a of the second support portion 27 but also the distal end portion 26a of the first support portion 26 and the distal end portion 25a of the guide portion 25 in the state in which the first reinforcing bar 52 is fitted are the first. It contacts the rebar 52.

  Thus, since the reinforcing bar spacer 100 is in contact with the first reinforcing bar 52 at multiple points, it is stably fixed to the first reinforcing bar 52. Furthermore, the 2nd support part 27, the 1st support part 26, and the guide part 25 are contact | abutting with the 1st reinforcing bar 52 in the state elastically deformed. As a result, an elastic force acts on the first reinforcing bar 52, so that it is sufficient that the reinforcing bar spacer 100 is detached from the first reinforcing bar 52 or moved along the first reinforcing bar 52. Can be suppressed. The reinforcing bar spacer 100 can be attached to reinforcing bars of various sizes, and is excellent in versatility.

  FIG. 7 is a front view showing another embodiment of the reinforcing bar spacer. The reinforcing bar spacer 101 of FIG. 7 is different from the reinforcing bar spacer 100 according to the above embodiment in that it has a fitting portion 20b. Specifically, the fitting portion 20 b is different from the reinforcing bar spacer 100 in that it includes a third support portion 29 instead of the guide portion 25, the first support portion 26, and the second support portion 27. The third support part 29 has a function of guiding the first reinforcing bar 50 when the reinforcing bar spacer 101 is fitted to the first reinforcing bar 50, and a front end part after being fitted to the first reinforcing bar 50. 29 a abuts on the first reinforcing bar 50 and has a function of supporting the reinforcing bar spacer 101. In this way, the reinforcing bar spacer 101 is fixed to the first reinforcing bar 50.

  The third support portion 29 has both the function of guiding the first reinforcing bar 50 and the function of supporting the reinforcing bar spacer 101 on the first reinforcing bar 50, so that the structure of the fitting portion 20b can be simplified. . By adopting such a simple structure, the volume of the reinforcing bar spacer 101 can be further reduced. Moreover, since the fitting part 20b has a simple structure, the filling property of concrete can fully be made favorable.

  The material for the reinforcing bar spacers 100 and 101 is not particularly limited as long as it is made of resin, and for example, general resins such as polyethylene, polypropylene, polystyrene, polyester, and polyvinyl chloride can be used. Among these, polypropylene is preferable from the viewpoint of having appropriate rigidity and elasticity in the attaching / detaching operation of the reinforcing bar spacers 100 and 101 and reducing the manufacturing cost.

  As mentioned above, although preferred embodiment of this invention was described, this invention is not limited to the said embodiment. For example, the guide part, the first support part, and the second support part provided in the fitting part 20 are not necessarily essential. For example, the insertion port 22 of the fitting unit main body 21 may be brought close to the holding unit 28 so that the tip of the fitting unit main body 21 and the holding unit 28 come into contact with the first reinforcing bars 50 and 52. Further, the number and shape of the leg portions are not particularly limited, and for example, a reinforcing portion may be formed between the leg portions 60 and the leg portions may be fan-shaped. Further, the shape of the arm part is not particularly limited, and for example, the connecting part 40b may be projected forward like the tip part 40a.

  ADVANTAGE OF THE INVENTION According to this invention, the spacer for reinforcing bars which is excellent in workability | operativity at the time of mounting | wearing with a reinforcing bar can be provided.

  20, 20b ... fitting part, 21 ... fitting part main body, 22 ... insertion port, 25 ... guide part, 25a ... tip part, 26 ... first support part, 26a ... tip part, 27 ... second support part , 27a ... tip part, 28 ... holding part, 29 ... third support part, 29a ... tip part, 40 ... arm part, 40a ... tip part, 40b ... coupling part, 50, 52 ... rebar (first rebar) , 70 ... Reinforcing bars (second reinforcing bars), 60 ... Legs, 60a ... Tip parts, 62, 64 ... Reinforcing parts, 80 ... Formwork, 100, 101 ... Spacer for reinforcing bars.

Claims (4)

Reinforcing bar spacers attached to the reinforcing bars,
An insertion port for inserting a first reinforcing bar extending in one direction, and a holding part for holding the inserted first reinforcing bar, and a fitting part that fits into the first reinforcing bar;
A pair of arm portions that are provided so as to sandwich the holding portion, and that regulate the rotation of the first reinforcing bars in contact with a second reinforcing bar that extends in a direction perpendicular to the one direction;
When viewed from the vertical direction, the first reinforcing bar is used as a reference, and the resin reinforcing bar is provided on the side opposite to the insertion port side and includes a leg portion that holds a space between the mold and the reinforcing bar. Spacer. The arm portion includes a tip portion that contacts the second reinforcing bar, and a connecting portion that connects the tip portion and the fitting portion.
The rebar spacer according to claim 1, wherein the tip portion is configured to protrude in a longitudinal direction of the first rebar from the fitting portion and the connecting portion.   The fitting portion fixes the first rebar to the guide portion that guides the insertion of the first rebar from the insertion port side along the insertion direction of the first rebar and the holding portion. The spacer for reinforcing bars according to claim 1 or 2, comprising a support portion in this order.   The spacer for reinforcing bars according to any one of claims 1 to 3, wherein the number of the leg portions is two or three.

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