JP6932086B2 - Concrete surface hardness measuring instrument and concrete surface hardness measuring method - Google Patents

Description

The present invention relates to a concrete surface hardness measuring instrument and a concrete surface hardness measuring method.

After placing the concrete, the surface of the concrete is finished with a wooden trowel, a gold trowel, or the like according to the hardness of the concrete to be condensed. The time to start finishing the concrete surface after placing the concrete is determined by the sense of the plasterer. Therefore, a technique for quantitatively evaluating the hardness of the surface of the cast concrete has been proposed.

For example, Patent Document 1 describes a handle that is gripped by hand, a shaft member that protrudes from the handle, a penetration needle that is provided at the tip of the shaft member and penetrates into concrete, and a penetration needle that is provided on the shaft member and penetrates into concrete. A concrete penetration resistance tester including a load cell that detects a received load and a control unit that calculates a penetration resistance obtained by dividing the load detected by the load cell by the cross-sectional area of the penetration needle is disclosed. In this penetration resistance tester for concrete, the penetration needle receives a load by pushing the handle vertically downward to penetrate the inside of the concrete, and the load is detected by the load cell. The degree of hardening of concrete is quantitatively evaluated by measuring the penetration resistance of concrete.

Japanese Unexamined Patent Publication No. 2014-102204

By the way, it is desired that the equipment used at the construction site has as simple a structure as possible, but the structure of the above-mentioned penetration resistance tester for concrete is complicated because it is equipped with a load cell and a control unit. ..

Therefore, an object of the present invention is to provide a concrete surface hardness measuring instrument and a concrete surface hardness measuring method capable of measuring the hardness of the surface of cast concrete with a simpler structure.

According to the present invention, a contact portion placed on the surface of the cast concrete and brought into contact with the surface of the concrete, a guide portion extending upward from the contact portion, and a guide portion extending in the vertical direction along the guide portion are guided. It is a concrete surface hardness measuring instrument provided with a weight portion that can change between a state in which the weight is weighted on the contact portion and a state in which the weight is not weighted on the contact portion.

According to this configuration, in the concrete surface hardness measuring instrument, the contact portion is placed on the surface of the cast concrete and brought into contact with the concrete surface, and the weight portion is vertically extended along the guide portion extending upward from the contact portion. By being guided and changing between the state where the weight of the weight is weighted on the contact part and the state where the weight of the weight is not weighted on the contact part, the load on the concrete surface by the contact part is adjusted. NS. As a result, while adjusting the load on the concrete surface by the contact part, the hardness of the surface of the cast concrete is measured with a simpler configuration based on the degree of penetration of the contact part into the concrete. be able to.

In this case, a plurality of weight portions separated from each other in the vertical direction are provided, and each of the plurality of weight portions is guided in the vertical direction along the guide portion while each of the weight portions adjacent to each other can be brought into contact with each other. It is preferable that the state in which the weight of the weight portion is weighted on the contact portion and the state in which the weight of the weight portion is not weighted on the contact portion can be freely changed.

According to this configuration, the weight portions are separated into a plurality of weight portions in the vertical direction, and each of the plurality of weight portions can be brought into contact with each other in the vertical direction along the guide portion. Since it is possible to change between a state in which the weight of the weight portion is weighted on the contact portion and a state in which the weight of the weight portion is not weighted on the contact portion, the weight of the contact portion is applied to the contact portion among the plurality of weight portions. By changing the number of weight portions weighted with, the load on the concrete surface by the contact portion can be adjusted more finely.

Further, it is preferable that the weight portion is connected to a suspension portion that suspends the weight portion so that the weight of the weight portion is not weighted to the contact portion.

According to this configuration, since the weight portion is connected to the suspension portion that suspends the weight portion so that the weight of the weight portion is not weighted to the contact portion, the weight portion is connected by the suspension portion. The weight of the weight portion is not applied to the contact portion simply by suspending the contact portion, and it becomes easy to adjust the load on the concrete surface by the contact portion.

On the other hand, in the present invention, a contact portion placed on the surface of the cast concrete and brought into contact with the surface of the concrete, a guide portion extending upward from the contact portion, and a guide portion extending in the vertical direction along the guide portion are separated. Each of the plurality of weight portions is guided in the vertical direction along the guide portion while each of the weight portions adjacent to each other can be brought into contact with each other, and the weight of the weight portion is brought to the contact portion. It is a concrete surface hardness measuring method using a concrete surface hardness measuring instrument that can change between a state in which is weighted and a state in which the weight of the weight is not weighted on the contact portion, and is any one of a plurality of weights. The weight of the gripped weight portion and the weight portion above the gripped weight portion is not weighted on the contact portion, and the contact portion is below the gripped weight portion. While the weight of the weight is weighted, the contact is placed on the surface of the cast concrete and brought into contact with the surface of the concrete, based on the degree of entry of the contact into the concrete. , This is a concrete surface hardness measuring method for measuring the hardness of the concrete surface.

Further, in the present invention, a contact portion placed on the surface of the cast concrete and brought into contact with the surface of the concrete, a guide portion extending upward from the contact portion, and a guide portion extending in the vertical direction along the guide portion are separated. Each of the plurality of weight portions is guided in the vertical direction along the guide portion while each of the weight portions adjacent to each other can be brought into contact with each other, and the weight of the weight portion is brought to the contact portion. It is possible to change between a state in which the weight is weighted and a state in which the weight of the weight is not weighted on the contact portion, and in each of the plurality of weight parts, the weight of the weight is not weighted on the contact portion. It is a concrete surface hardness measuring method using a concrete surface hardness measuring instrument in which a hanging part for suspending a weight portion is connected so as to be such that one of a plurality of weight portions is suspended by the suspension portion. As a result, the weight of the suspended weight portion and the weight portion above the suspended weight portion is not weighted on the contact portion, and the weight below the suspended weight portion is not weighted on the contact portion. While the weight of the part is weighted, the contact part is placed on the surface of the cast concrete and brought into contact with the surface of the concrete, based on the degree of penetration of the contact part into the concrete. This is a concrete surface hardness measuring method for measuring the hardness of the concrete surface.

According to the concrete surface hardness measuring instrument and the concrete surface hardness measuring method of the present invention, the hardness of the surface of the cast concrete can be measured with a simpler configuration.

(A) is a side view showing the concrete surface hardness measuring instrument of the first embodiment, (B) is a plan view of (A), (C) is a bottom view of (A), and (D). Is a cross-sectional view taken along line α of (A), (E) is a side view showing a contact portion and a guide portion of (A), and (F) is a plan view showing a weight portion of (A). (G) is a plan view showing the stopper of (A). (A), (B) and (C) are side views which show the concrete surface hardness measuring method using the concrete surface hardness measuring instrument of 1st Embodiment. (A) is a side view showing the concrete surface hardness measuring instrument of the second embodiment, (B) is a plan view of (A), (C) is a bottom view of (A), and (D). Is a cross-sectional view taken along line β of (A), (E) is a cross-sectional view taken along line γ line (A), (F) is a cross-sectional view taken along line δ of (A), and (G) is (G). A is a cross-sectional view taken along line ε, (H) is a cross-sectional view taken along line ζ of (A), and (I) is a cross-sectional view taken along line η of (A). (A) is a bottom view showing a contact portion of the concrete surface hardness measuring instrument of the second embodiment, (B) is a plan view of (A), and (C) is a cross-sectional view taken along the line θ of (A). (D) is a cross-sectional view taken along the line ι of (A), (E) is a bottom view showing a weight portion of the concrete surface hardness measuring instrument of the second embodiment, and (F) is (E). (G) is a cross-sectional view taken along the line κ of (E), and (H) is a cross-sectional view taken along the line λ of (E). (A), (B), (C), (D), (E) and (F) are side views showing a concrete surface hardness measuring method using the concrete surface hardness measuring instrument of the second embodiment.

Hereinafter, the concrete surface hardness measuring instrument and the concrete surface hardness measuring method according to the present invention will be described in detail with reference to the drawings. As shown in FIGS. 1 (A), 1 (B), 1 (C) and 1 (D), the concrete surface hardness measuring instrument 1A according to the first embodiment of the present invention includes a contact portion 10A and a guide portion. 20A and a weight portion 30A are provided. The concrete surface hardness measuring instrument 1A is formed of, for example, a metal such as stainless steel, a synthetic resin such as an engineering plastic such as a copolymer of monomer cast nylon and polyoxymethylene, a stone material, or the like. It is an instrument with a hardness of 10 to 20 cm and a weight of about 300 to 500 g.

The contact portion 10A is placed on the surface of the cast concrete and brought into contact with the surface of the concrete. The guide portion 20A extends upward from the contact portion 10A. As shown in FIGS. 1 (A), 1 (B), 1 (C), 1 (D) and 1 (E), the contact portion 10A and the guide portion 20A are integrated as the base shaft portion 40. ing. The base shaft portion 40 has a cylindrical shape. The weight of the base shaft portion 40 is, for example, 30 to 40 g.

The base shaft portion 40 has a cylindrical contact portion 10A at the lower end of the base shaft portion 40, which is a portion having the smallest diameter in the base shaft portion 40. The diameter of the contact portion 10A is, for example, 5 to 15 mm. The base shaft portion 40 has a cylindrical lower stopper fixing portion 41 having a diameter larger than that of the contact portion 10A directly above the contact portion 10A. The base shaft portion 40 has an upper stopper fixing portion 42 having the same diameter as the lower stopper fixing portion 41 at the upper end of the base shaft portion 40. The base shaft portion 40 has a cylindrical guide portion 20A having a diameter larger than that of the lower stopper fixing portion 41 and the upper stopper fixing portion 42 between the lower stopper fixing portion 41 and the upper stopper fixing portion 42.

The upper stopper fixing portion 42 is not an indispensable configuration, and the lower stopper fixing portion 41 and the upper stopper fixing portion 42 do not have to have the same diameter. The base shaft portion 40 has a strap hole portion 43 for attaching a strap to the upper end of the base shaft portion 40. When the strap is not used, the strap hole 43 is not an indispensable configuration.

As shown in FIGS. 1 (A), 1 (B), 1 (C), 1 (D) and 1 (F), the weight portion 30A has an annular shape and is guided to the center thereof. It has a hole 31A. The weight of the weight portion 30A is, for example, 30 to 50 g. The inner diameter of the guide hole portion 31A is slightly larger than the diameter of the guide portion 20A of the base shaft portion 40. The weight portion 30A in which the guide portion 20A is inserted through the guide hole portion 31A is guided in the vertical direction along the guide portion 20A, and the weight is weighted on the contact portion 10A and the weight is weighted on the contact portion 10A. It is possible to change the state that is not done.

The concrete surface hardness measuring instrument 1A includes a plurality of weight portions 30A separated from each other in the vertical direction, and each of the plurality of weight portions 30A in which the guide portion 20A is inserted into the guide hole portion 31A is a weight portion 30A adjacent to each other. While each can be in contact with each other, they are guided in the vertical direction along the guide portion 20A, and the weight of the weight portion 30A is weighted on the contact portion 10A and the weight of the weight portion 30A is weighted on the contact portion 10A. It is possible to change the state of not being. In the present embodiment, the plurality of weight portions 30A have the same weight, but the plurality of weight portions 30A may have different weights for convenience of measurement. Further, if it is not necessary to change the pressure on the concrete in three or more stages, only one weight portion 30A may be used.

As shown in FIGS. 1 (A), 1 (B), 1 (C), 1 (D), and 1 (G), guide portions 20A are provided in each of the guide hole portions 31A of the plurality of weight portions 30A. The stopper 50 is fixed to each of the lower stopper fixing portion 41 and the upper stopper fixing portion 42 in a state where the stopper 50 is inserted. The stopper 50 has an annular shape and has a stopper hole 53 in the center thereof. The weight of the stopper 50 is, for example, 20 to 30 g. The inner diameter of the stopper hole 53 is slightly larger than the diameter of the lower stopper fixing portion 41 and the upper stopper fixing portion 42 of the base shaft portion 40.

The outer diameter of the stopper 50 is larger than the inner diameter of the guide hole portion 31A of the weight portion 30A. The stopper 50 has a screw hole portion 52 that penetrates from the outer peripheral surface of the stopper 50 to the inner peripheral surface of the stopper hole portion. With the lower stopper fixing portion 41 and the upper stopper fixing portion 42 inserted into the respective stopper hole portions 53 of the two stoppers 50, the screw 51 is screwed into the screw hole portion 52, so that the two stoppers 50 become the lower stopper. It is fixed to the fixing portion 41 and the upper stopper fixing portion 42, respectively.

When the stopper 50 is fixed to each of the lower stopper fixing portion 41 and the upper stopper fixing portion 42, the plurality of weight portions 30A can move in the vertical direction along the guide portion 20A, but fall off from the base shaft portion 40. Is prevented. The stopper 50 fixed to the upper stopper fixing portion 42 is not essential. In addition, an appropriate through hole may be provided in the base shaft portion 40 instead of the screw 51, and the stopper 50 may be fixed to the base shaft portion 40 by a split pin, a spring pin, or the like inserted into the through hole. Further, a predetermined groove may be provided on the outer peripheral surface of the base shaft portion 40, and a snap ring or the like attached to the groove may prevent the weight portion 30A from falling off from the base shaft portion 40.

Hereinafter, a concrete surface hardness measuring method using the concrete surface hardness measuring instrument 1A of the present embodiment will be described. As shown in FIG. 2A, the strap 60 is passed through the strap hole 43. When any one of the plurality of weight portions 30A is gripped at the support point P, the weight portion 30A gripped and the weight portion gripped by the contact portion 10A via the stopper 50 fixed to the lower stopper fixing portion 41. The weight of the weight portion 30A above the 30A is not weighted, and the weight of the weight portion 30A below the gripped weight portion 30A is weighted to the contact portion 10A.

For example, it is assumed that the total weight of the base shaft portion 40, the two stoppers 50, the two screws 51, and the strap 60 is 100 g, and the weight of one weight portion 30A is 50 g. Further, it is assumed that the area of the contact portion 10A in contact with the surface S of the concrete C is 1.0 cm ² (the diameter of the contact portion 10A is 1.128 cm). When the lowermost weight portion 30A is gripped, the weights of all the weight portions 30A are not weighted on the contact portion 10A, so that the cumulative weight weighted on the surface S of the concrete C is 100 g and the pressure is 0.1 kg. / Cm ² .

When the second weight portion 30A from the bottom is gripped, the contact portion 10A holds the second weight portion 30A from the bottom and the weight above the second weight portion 30A from the bottom gripped. Since the weight of the portion 30A is not weighted and the weight of the weight portion 30A below the gripped second weight portion 30A from the bottom is weighted on the contact portion 10A, the cumulative weight is applied to the surface S of the concrete C. The weight is 150 g and the pressure is 0.15 kg / cm ² .

Similarly, when the first to seventh weight portions 30A from the bottom are gripped, the cumulative weights weighted on the surface S of the concrete C are 100 g, 150 g, 200 g, 250 g, 300 g, 350 g, 400 g and 450 g, respectively. , and the respective 0.1 kg ^/ cm ^{2 pressure, 0.15kg / cm 2, 0.2kg /} cm 2, 0.25kg / cm 2, 0.3kg / cm 2, 0.35kg / cm 2, 0. 4 kg / cm ² and 0.45 kg / cm ² .

That is, the pressure on the surface S of the concrete C can be appropriately changed by changing the weight portion 30A to be gripped. In the example of FIG. 2A, since the third weight portion 30A from the bottom is gripped at the support point P, the pressure on the surface S of the concrete C is 0.2 kg / cm ² .

As shown in FIG. 2B, the contact portion 10A is placed on the surface S of the cast concrete C and brought into contact with the surface S of the concrete C while being in the above state, and the concrete of the contact portion 10A. The hardness of the surface S of concrete C is measured based on the degree of entry of C into the interior.

As shown in FIG. 2C, the hand holding the support point P is lowered, and a gap is formed between the uppermost weight portion 30A and the stopper 50 fixed to the upper stopper fixing portion 42. It is possible to make a gap between the third weight portion 30A gripped at the support point P and the weight portion 30A below the gripped weight portion 30A. The total weight of the base shaft portion 40, the two stoppers 50, the two screws 51 and the strap 60 and the weight of the weight portion 30A below the gripped weight portion 30A are all weighted on the surface S of the concrete C, and the concrete surface hardness. The tension of the strap 60 fixed to the wrist or the like is maintained so that the measuring instrument 1A does not fall down and the surface S does not sink excessively beyond the purpose of measuring the hardness of the surface S.

If the concrete surface hardness measuring instrument 1A is removed from the surface S of the concrete C and no trace of the contact portion 10A remains at the position where the surface S of the concrete C comes into contact with the contact portion 10A, the hardness of the surface S of the concrete C is 0.22 kg. It is determined that a supporting pressure of about / cm ² is the hardness generated on the surface S of the concrete C. If you want to determine whether the hardness of the surface S of concrete C is such ^{that a bearing pressure of more than 0.22 kg / cm 2} is generated, change the gripped weight portion 30A to the fourth or higher weight portion 30A from the bottom. While doing so, the above measurement is performed again.

In the present embodiment, in the concrete surface hardness measuring instrument 1A, the contact portion 10A is placed on the surface S of the cast concrete C and brought into contact with the concrete surface hardness measuring instrument 1A, and the weight is placed along the guide portion 20A extending upward from the contact portion 10A. The contact portion 30A is guided in the vertical direction, and the contact portion is changed from the state in which the weight of the weight portion 30A is weighted to the contact portion 10A and the state in which the weight of the weight portion 30A is not weighted to the contact portion 10A. The load on the surface S of the concrete C by 10A is adjusted. As a result, while adjusting the load on the surface S of the concrete C by the contact portion 10A, the concrete C placed with a simpler configuration is based on the degree of entry of the contact portion 10A into the inside of the concrete C. The hardness of the surface S can be measured.

Further, in the present embodiment, the weight portions 30A are separated into a plurality of weight portions 30A in the vertical direction, and each of the plurality of weight portions 30A can be brought into contact with the guide portion 20A while the weight portions 30A adjacent to each other can be brought into contact with each other. Since the weight is guided in the vertical direction along the contact portion 10A and the weight of the weight portion 30A is weighted on the contact portion 10A and the weight of the weight portion 30A is not weighted on the contact portion 10A, a plurality of weights can be changed. By changing the quantity of the weight portion 30A in which the weight is weighted on the contact portion 10A in the portion 30A, the load on the surface S of the concrete C by the contact portion 10A can be adjusted more finely.

Hereinafter, a second embodiment of the present invention will be described. 3 (A), 3 (B), 3 (C), 3 (D), 3 (E), 3 (F), 3 (G), 3 (H) and 3 As shown in (I), the concrete surface hardness measuring instrument 1B of the second embodiment of the present invention includes a contact portion 10B, a guide portion 20B, and a weight portion 30B. The concrete surface hardness measuring instrument 1B is an instrument formed of, for example, a metal such as stainless steel or lead and having a weight of about 400 to 800 g. In the concrete surface hardness measuring instrument 1B of the present embodiment, a thread, a string, a rope, a thin wire, a thread, a string, a rope, a thin wire, and a thread, a string, a rope, a thin wire, and a thread, a string, a rope, a thin wire, and a thread, a string, a rope, a thin wire, and a thread, a string, a rope, a thin wire, and The guide portion 20B for steel wire or the like extends.

The concrete surface hardness measuring instrument 1B of the present embodiment also includes a plurality of weight portions 30B separated from each other in the vertical direction, and each of the plurality of weight portions 30B can abut each other on adjacent weight portions 30B. While being guided in the vertical direction along the guide portion 20B, the state in which the weight of the weight portion 30B is weighted on the contact portion 10B and the state in which the weight of the weight portion 30B is not weighted on the contact portion 10B can be freely changed. be. A thread, a string, a rope, a thin wire, a steel wire, or the like that suspends the weight portion 30B so that the weight of the weight portion 30B is not weighted on the contact portion 10B is suspended in each of the plurality of weight portions 30B. The holding part 70 is connected.

As shown in FIGS. 4 (A), 4 (B), 4 (C) and 4 (D), the contact portion 10B has a contact 11 and a contact attachment portion 12. The weight of the contact portion 10B is, for example, 50 to 150 g. The contact 11 has a cylindrical shape. The lower end of the contact 11 is brought into contact with the surface S of the concrete C when the contact portion 10B is placed on the surface S of the concrete C. The diameter of the contact 11 is, for example, 5 to 15 mm. A screw groove is provided in the contact base portion 16 above the contact element 11.

The contact attachment portion 12 has an annular shape and has a central hole portion 17 in the center thereof. The inner diameter of the central hole 17 corresponds to the diameter of the contactor 11. A screw groove corresponding to the screw groove of the contact base portion 16 is provided on the inner peripheral surface of the central hole portion 17. The contactor 11 is attached to the contactor attachment portion 12 by screwing the contactor base portion 16 into the central hole portion 17 of the contactor attachment portion 12.

The contact attachment portion 12 is a pair of fixed hole portions 13 which are a pair of through holes arranged so as to face each other with the central hole portion 17 sandwiched around the central hole portion 17, and five pairs of the same number of pairs as the weight portion 30B. Includes an unused hole portion 15 which is a through hole of the above. The inner peripheral surface of the fixing hole portion 13 has an inner diameter of the upper portion smaller than that of the lower portion. A screw groove is provided in the lower part of the inner peripheral surface of the fixing hole portion 13. As shown in FIG. 3D, each of the guide end portions 21 at both ends of the guide portion 20B such as a thread, a string, a rope, a thin wire, and a steel wire is inserted into the pair of fixing hole portions 13 from above. By expanding the diameter of both ends of the guide portion 20B by a ball knot or the like, the guide end portion 21 of the guide portion 20B is fixed so as not to come off from the fixing hole portion 13.

Further, as shown in FIGS. 3 (D) and 4 (C), the hexagon socket set screw 14 is screwed into the fixing hole 13 from below the fixing hole 13, so that the guide end 21 of the guide 20B is screwed. Is protected. The hexagon socket set screw 14 is not essential. Further, the unused hole portion 15 is provided for standardization when manufactured together with the weight portion 30B, but it is not essential.

As shown in FIGS. 4 (E), 4 (F), 4 (G) and 4 (H), the weight portion 30B has the same size and the same size as the contactor mounting portion 12 of the contact portion 10B. Has a shape. The weight portion 30B has an annular shape and has a central hole portion 34 in the center thereof. The weight of the weight portion 30B is, for example, 50 to 150 g.

The fixed hole portion 32, which is a pair of through holes arranged so as to face each other with the central hole portion 34 sandwiched around the central hole portion 34, and the guide hole, which is a pair of five through holes in the same number as the weight portion 30B. Includes part 31B. The inner peripheral surface of the fixing hole portion 32 has an inner diameter of the upper portion smaller than that of the lower portion. A screw groove is provided in the lower part of the inner peripheral surface of the fixing hole portion 32. As shown in FIGS. 3 (E) to 3 (I), both ends of the holding portion 70 such as a thread, a string, a rope, a thin wire, and a steel wire are inserted into the pair of fixing holes 32 from above. By expanding the diameter of the hanging end portions 71 at both ends of the hanging portion 70 by a ball knot or the like, the hanging end portions 71 of the hanging portion 70 are fixed so as not to come off from the fixing hole portion 32.

Further, as shown in FIGS. 3 (E) to 3 (I) and FIG. 4 (G), the hexagon socket set screw 33 is screwed into the fixing hole 32 from below the fixing hole 32 to be suspended. The hanging end 71 of the portion 70 is protected. The hexagon socket set screw 33 is not essential. Further, the central hole portion 34 is provided for standardization when manufactured together with the contactor mounting portion 12, but is not essential.

As shown in FIG. 3D, each of the guide end portions 21 at both ends of the guide portion 20B such as a thread, a string, a rope, a thin wire, and a steel wire is a pair of guide holes for each of the plurality of weight portions 30B from above. It is inserted through the portion 31B and inserted into the pair of fixing holes 13 of the contactor mounting portion 12 to be fixed. The length of the guide portion 20B is, for example, 10 minutes of the weight portion 30B between the pair of weight portions 30B when the pair of weight portions 30B adjacent to each other are moved in the opposite directions along the guide portion 20B. The length is such that there is a gap of about 1 to 1 of.

As shown in FIG. 3 (E), each of the suspension end portions 71 at both ends of the suspension portion 70 such as a thread, a string, a rope, a thin wire, and a steel wire is above the first weight portion 30B from the top to the bottom. It is inserted into each pair of guide hole portions 31B of the weight portion 30B, and is inserted into the fixing hole portion 32 of the first weight portion 30B from the bottom and fixed. The length of the suspension portion 70 is the same as that of the guide portion 20B, for example.

Similarly, as shown in FIGS. 3 (F) to 3 (H), each of the suspension end portions 71 at both ends of the suspension portion 70 is a weight above the weight portions 30B of the second to fourth from the top to the bottom. It is inserted into each pair of guide hole portions 31B of the portion 30B, and is inserted into the fixing hole portion 32 of the second to fourth weight portions 30B from the bottom and fixed. The length of each of the suspension portions 70 is, for example, the same. As shown in FIG. 3 (I), with respect to the first weight portion 30B from the top, each of the suspension end portions 71 at both ends of the suspension portion 70 does not pass through the guide hole portion 31B of the other weight portion 30B. , It is directly inserted into the fixing hole 32 of the first weight portion 30B from the top and fixed.

The lengths of the guide portion 20B and the suspension portion 70 may be different from each other. For example, the guide portion 20B and the suspension portion 70 may have a length such that the upper ends thereof reach the same height above the first weight portion 30B from the top. Further, the guide portion 20B and the suspension portion 70 may be attached with a tag or the like indicating whether they are fixed to the contactor attachment portion 12 or the weight portion 30B. Further, in the present embodiment, the plurality of weight portions 30B have the same weight, but the plurality of weight portions 30B may have different weights for convenience of measurement. Further, if it is not necessary to change the pressure on the concrete in three or more stages, only one weight portion 30B may be used.

Hereinafter, a concrete surface hardness measuring method using the concrete surface hardness measuring instrument 1B of the present embodiment will be described. As shown in FIGS. 5 (A), 5 (B), 5 (C), 5 (D), 5 (E) and 5 (F), a plurality of suspension portions 70 or guide portions 20B are used. By suspending either the weight portion 30B or the contactor mounting portion 12 of the above, the suspended weight portion 30B or the contactor mounting portion 12 and the suspended weight portion 30B or the contactor are attached to the contact portion 10B. The weight of the weight portion 30B above the mounting portion 12 was not weighted, and the weight of the suspended weight portion 30B or the weight portion 30B below the contactor mounting portion 12 was weighted on the contact portion 10B. Be in a state.

By hanging the upper end of the guide portion 20B on the upper surface of the first weight portion 30B from the top, it is possible to prevent the weight portion 30B below the suspended weight portion from falling off from the concrete surface hardness measuring instrument 1B. In addition, in FIGS. 5A to 5F, the suspension portion 70 which is not suspended is not shown.

For example, it is assumed that the contact portion 10B and one weight portion 30B each weigh 100 g. Further, it is assumed that the area of the tip of the contactor 11 in contact with the surface S of the concrete C is 1 cm ^2. As shown in FIG. 5A, when the lowermost weight portion 30B is suspended, the weights of all the weight portions 30A are not weighted on the contact portion 10B, so that the cumulative weight is applied to the surface S of the concrete C. The weight is 100 g and the pressure is 0.1 kg / cm ² .

Further, as shown in FIG. 5B, when the second weight portion 30B from the bottom was suspended, the second weight portion 30B from the bottom and the suspended weight portion 30B were suspended by the contact portion 10B. The weight of the weight portion 30B above the second weight portion 30B from the bottom is not weighted, and the weight of the weight portion 30B below the second weight portion 30B suspended from the bottom is weighted on the contact portion 10B. Therefore, the cumulative weight weighted on the surface S of the concrete C is 200 g, and the pressure is 0.2 kg / cm ² .

Similarly, as shown in FIGS. 5A to 5E, the cumulative weight weighted on the surface S of the concrete C when the first to fifth weight portions 30B from the bottom are suspended. 100g each, 200 g, 300 g, is 400g and 500 g, respectively 0.1 kg ^/ cm ^{2 pressure, 0.2kg / cm 2, 0.3kg /} cm 2, 0.4kg / cm 2 and 0.5 kg / cm It is ^2.

Further, as shown in FIG. 5 (F), when the contactor mounting portion 12 is suspended by the guide portion 20B, all the weights of the contactor mounting portion 12 and the weight portion 30B are weighted, and the surface of the concrete C is weighted. The cumulative weight weighted by S is 600 g and the pressure is 0.6 kg / cm ² . That is, the pressure on the surface S of the concrete C can be appropriately changed by changing the weight portion 30B to be suspended.

While being in the above state, the contact 11 of the contact portion 10B is placed on the surface S of the cast concrete C and brought into contact with the surface S of the concrete C. The hardness of the surface S of the concrete C is measured based on the degree of entry of the contact 11 of the contact 11 into the inside of the concrete C.

When the weight portion 30B is suspended by the suspension portion 70 as shown in FIGS. 5A to 5E, the weight portion 30B to be suspended and the weight portion 30B to be suspended are lower than the weight portion 30B to be suspended. A gap is created between the contact member mounting portion 12 and the weight portion 30B. The weight of the contact portion 10B and the weight portion 30B below the suspended weight portion 30B are all weighted on the surface S of the concrete C, the concrete surface hardness measuring instrument 1B does not fall, and the purpose of measuring the hardness of the surface S is The tension of the suspension portion 70 or the guide portion 20B is maintained so as not to cause excessive sinking exceeding the above. The load and pressure on the surface S of the concrete C may be changed by suspending any of the suspension portion 70 and the guide portion 20B while connecting them to each other.

According to the present embodiment, the weight portion 30B is connected to the suspension portion 70 that suspends the weight portion 30B so that the weight of the weight portion 30B is not weighted to the contact portion 10B. By simply suspending the weight portion 30B by the suspending portion 70, the weight of the weight portion 30B is not weighted on the contact portion 10B, and it is easy to adjust the load on the surface S of the concrete C by the contact portion 10B. It becomes.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments and is implemented in various forms. For example, the configurations of the contact portions 10A, 10B, the guide portions 20A, 20B, the weight portions 30A, 30B, the suspension portion 70, and the like can take any form as long as they have the same operations as those in the above embodiment.

1A, 1B ... Concrete surface hardness measuring instrument, 10A, 10B ... Contact part, 11 ... Contact, 12 ... Contact attachment part, 13 ... Fixing hole part, 14 ... Hexagon socket set screw, 15 ... Unused hole part, 16 ... Contact base, 17 ... Central hole, 20A, 20B ... Guide, 21 ... Guide end, 30A, 30B ... Weight, 31A, 31B ... Guide hole, 32 ... Fixed hole, 33 ... Hexagonal hole Set screw, 34 ... Central hole, 40 ... Base shaft, 41 ... Lower stopper fixing part, 42 ... Upper stopper fixing part, 43 ... Strap hole, 50 ... Stopper, 51 ... Screw, 52 ... Screw hole, 53 ... Stopper hole, 60 ... Strap, 70 ... Suspended end, 71 ... Suspended end, C ... Concrete, S ... Surface, P ... Support point.

Claims (5)

A contact portion that is placed on the surface of the cast concrete and brought into contact with the surface of the concrete,
A guide portion extending upward from the contact portion and
It is provided with a weight portion that is guided in the vertical direction along the guide portion and can change between a state in which the weight is weighted on the contact portion and a state in which the weight is not weighted on the contact portion. Concrete surface hardness measuring instrument. It is provided with a plurality of the weight portions separated from each other in the vertical direction.
Each of the plurality of weight portions is guided in the vertical direction along the guide portion while each of the weight portions adjacent to each other can be brought into contact with each other, and the weight of the weight portion is weighted on the contact portion. The concrete surface hardness measuring instrument according to claim 1, wherein the state in which the weight is applied and the state in which the weight of the weight is not weighted on the contact portion can be freely changed. The concrete according to claim 1 or 2, wherein a hanging portion for suspending the weight portion is connected to the weight portion so that the weight of the weight portion is not weighted to the contact portion. Surface hardness measuring instrument. A contact portion that is placed on the surface of the cast concrete and brought into contact with the surface of the concrete,
A guide portion extending upward from the contact portion and
A plurality of weight portions separated in the vertical direction along the guide portion are provided.
Each of the plurality of weight portions is guided in the vertical direction along the guide portion while each of the weight portions adjacent to each other can be brought into contact with each other, and the weight of the weight portion is weighted on the contact portion. It is a concrete surface hardness measuring method using a concrete surface hardness measuring instrument that can freely change between the state of being in the state and the state in which the weight of the weight portion is not weighted on the contact portion.
By gripping any of the plurality of weight portions, the weights of the gripped weight portion and the weight portion above the gripped weight portion are not weighted on the contact portion, and the weight portion is not weighted. The contact portion is placed on the surface of the concrete into which the contact portion is cast, while the weight of the weight portion below the gripped weight portion is weighted to the contact portion. A concrete surface hardness measuring method in which the hardness of the surface of the concrete is measured based on the degree of entry of the contacting portion into the concrete by being brought into contact with the surface. A contact portion that is placed on the surface of the cast concrete and brought into contact with the surface of the concrete,
A guide portion extending upward from the contact portion and
A plurality of weight portions separated in the vertical direction along the guide portion are provided.
Each of the plurality of weight portions is guided in the vertical direction along the guide portion while each of the weight portions adjacent to each other can be brought into contact with each other, and the weight of the weight portion is weighted on the contact portion. It is possible to change between the state in which the weight is applied and the state in which the weight of the weight is not weighted on the contact portion.
Each of the plurality of weight portions is provided with a concrete surface hardness measuring instrument in which a suspension portion for suspending the weight portion is connected so that the weight of the weight portion is not weighted to the contact portion. This is the concrete surface hardness measurement method used.
When any one of the plurality of weight portions is suspended by the suspension portion, the weight of the weight portion suspended from the contact portion and the weight portion above the suspended weight portion. Is not weighted, and the weight of the weight portion below the suspended weight portion is weighted on the contact portion, and the surface of the concrete on which the contact portion is placed is placed. A concrete surface hardness measuring method in which the surface of the concrete is brought into contact with the surface of the concrete, and the hardness of the surface of the concrete is measured based on the degree of penetration of the contact portion into the inside of the concrete.

Images