RU17155U1 - ANCHOR DEVICE FOR CONCRETE AND REINFORCED CONCRETE STRUCTURES - Google Patents

Abstract

An anchor device for concrete and reinforced concrete structures, comprising a smooth metal core and an adhesive layer, characterized in that the adhesive layer is made of expanding fine-grained concrete with a water-cement ratio of 0.25-0.35 and a linear expansion coefficient of 0.3-2.0%, with a thickness of 0.25-0.6 of the diameter of the rod, while the relative length of the core in the concrete of the structure is determined by the formula l / d = 0.74R / R + 2.4, where l is the length of the core in the concrete of the structure, mm; d - rod diameter, mm; R- design resistance of the anchor material tensile, MPa; R - calculated resistance of fine-grained concrete to compression, MPa.

Description

Anchor device for concrete and reinforced concrete structures

The invention relates to the field of construction and reconstruction of buildings and structures, and in particular to devices for anchor bolts made of smooth reinforcement in concrete and reinforced concrete structures, foundations, ceilings and walls.

There are various methods of installing anchor bolts in the construction of buildings and structures - either in the process of their construction, or in the wells of finished structures. Wells can be drilled or specially provided during the construction of structures. Anchor bolts in drilled wells of finished structures can be fixed using special spacers of various designs: with a conical head or with a sleeve screwed onto the end of the anchor bolt. However, they are all difficult to manufacture and also have a limited bearing capacity / 1 /.

Bolts of a spacer type with a conical end installed in drilled wells of finished structures and secured with a cement-sand mortar by the method of vibration immersion have limited bearing capacity. In addition, due to the shrinkage of the solution, they change (decrease) their bearing capacity by an indefinite value over time.

It is known that anchor bolts from smooth reinforcement are fixed in wells using synthetic glue or epoxy composition / 2 /.

This method is time-consuming, since the glue or composition is prepared in building conditions from six to seven components, some of which are toxic chemicals and working with them requires compliance with special sanitary rules and safety requirements. In addition, when using an epoxy composition, it is additionally required to preheat the anchor bolts at an ambient temperature below plus.

There is also known a method of securing anchor bolts in finished reinforced concrete or concrete structures by vibrosealing using a rigid cement-sand mixture / 3 /.

This method is time consuming and requires the mandatory use of special equipment: a sealing device with a vibrator attached to it.

In addition, with this method, the bolt embedment length is limited and shrinkage effects occur during the hardening of the mortar mixture, reducing the adhesion of the anchor to concrete.

According to SNiP / 4 /, anchors from smooth reinforcement of class A-1 should be used only if there are reinforcements at their ends in the form of plates, upset heads, transverse rods, hooks or loops. Longitudinal smooth rods of stretched and compressed reinforcement must be wound for a section normal to the longitudinal axis of the element, in which they are taken into account with full design resistance of at least 15-7-20 bar diameters and at least 200h-250 mm, depending on the location of the reinforcement in compressed or stretched concrete zone.

The technical task is to simplify the installation of the anchor device, reduce the length of its embedment in concrete and increase the strength of the embedment by using a movable expanding concrete mixture as an adhesive layer.

The problem is solved in such a way that in the anchor device embedded in the hole of the concrete structure, including a smooth metal rod and an adhesive layer, according to the invention, the adhesive layer is made of

expanding fine-grained concrete with a water-cement ratio of 0.25-0.35 and a linear expansion coefficient of 0.32.0% with a thickness of 0.25-0.6 of the diameter of the core, while the relative length of the core seal in the concrete of the structure is determined by the formula:

1 / d 0.74 Rs / Rb + 2.4, where 1 is the length of the core embedment in the concrete of the structure, mm;

d is the diameter of the rod, mm; RS is the calculated tensile strength of the anchor material,

MPa; Rb is the calculated resistance of fine-grained concrete to compression,

MPa

The proposed anchor device differs from the known one in that the anchor bolts in wells formed in finished reinforced concrete or concrete structures are supported through an adhesive layer of expanding concrete with a water-cement ratio of 0.25-0.35 and a linear expansion coefficient of 0.32.0% 0.25-0.6 mm thick rod diameters are compressed due to expansion forces arising as a result of self-tension of expanding concrete with a value of 0.9-3.0 MPa. Recommended mixture composition: cement: sand 1: 1.

For the preparation of a cement-sand mortar using tensile cement / SC / or Portland cement with an expanding additive / RD /. It is laid around a core with a layer thickness of 0.250.6 times the diameter of the core, with a free expansion value during hardening, a linear expansion coefficient of 0.3-2.0%. This fine-grained concrete can develop pressure on the obstacle to its expansion of 0.9-3.0 MPa.

The implementation of the adhesive layer of fine-grained concrete mixture based on NTs or RD allows to reduce the length of the embedment of the rod due to comprehensive optimal pressure on the rod and adhesion to the concrete structure due to the selected value of self-stress of concrete.

In addition, the use of a movable mixture eliminates vibration and reduces labor costs when installing the anchor.

The proposed calculation formula determines the required termination length of the rod, taking into account the design resistance of the anchor and concrete adhesive layer

1 / d 0.74 RS / Rb + 2.4, where 1 is the length of the core embedment in the concrete of the structure, mm;

d is the diameter of the rod, mm; RS is the calculated tensile strength of the anchor material,

MPa;

Rb - calculated resistance of fine-grained concrete to compression, MPa.

The numerical values of the coefficients in the formula were obtained as a result of processing experiments to test (pull out) anchor bolts with a diameter of 16 and 25 mm from concrete of different strengths, the RS / Rb ratio varied from 3 to 12. The results were processed using the least squares method, and the correlation coefficient was 0.938.

Pa fig. 1 shows an anchor device; figure 2 is a view a of figure 1.

The device consists of a rod 1, surrounded by an adhesive layer of an expanding solution 2, and a well 3. The adhesive layer 2 expands during hardening, which ensures compression of the rod 1 and its reliable anchoring in concrete. Comprehensive

the compression of the rod 1 increases the strength and stiffness of its deposition with concrete.

In FIG. Figure 3 shows a graph of the relative length of the anchoring of the rod 1 / d on the strength ratio of the material of the anchor and concrete of the adhesive layer Rs / Rb- The test results of anchors with diameters of 16 and 25 mm, which are used to obtain the graph, are shown in the table. The obtained direct empirical dependence 1 and possible deviations of the results from graph 2, equal in the middle part ± 5%, are shown in Fig. 3. Correlation coefficient of the formula 0.938; it is valid at d 14-27 mm and the ratio Rs / Rb 3-12.

Installation of the anchor device is as follows. Determine the length of the anchoring zone, equal to the depth of the well, using the half-open formula. For example, it is necessary to anchor a class A-1 rod with a diameter of 16 mm, expand RS 145 МНа; use fine-grained concrete of the ВЗО class Rb 17 MPa.

But the formula required anchoring length is 1 / d-0.74 145/17 + 2.4-8.7 or l d. 8.7 16. 8.7 "140 mm

According to the schedule (FIG. 3), the same anchoring length is obtained at Rs / Rb 145/17 8.5, the anchoring length is 1 / d "8.7.

Then, in the reinforced concrete structure, wells of the required depth and diameter are arranged, a cement-sand mortar mixture 1: 1 (by weight) is prepared, suitable for work with a mobility of 4-14 cm on tension; we use cement NTs-10 or NTs-20, with a water-cement ratio of 0, 3, the wells are filled with the mortar mixture to the level, ensuring its full filling of the well after the anchor is immersed in it. The anchor bolt is lowered into the well, the mixture is compacted by blows to the rod and its position is fixed. A day after the onset of curing, the solution begins to moisturize, which stimulates its expansion and self-tension. After the solution has gained a compressive strength of about 20 MNa (approximately after 3-5 days depending on temperature), it is possible to tighten the bolts. Designations: SC Information sources:

1, Manual for the design of anchor bolts for fastening building structures and equipment (to SNiP 2.09.03). Central Research Institute of Industrial Buildings. M., 1993

2.SU. Copyright certificate No. 209305, Cl. F16 M9 / 00, BI No. 4, 1968

3.SU. Copyright certificate No. 419385, Cl. B28 B1 / 8, BI No. 10, 1974 (Prototype)

4.SPiP 2.03.01-84. Concrete and reinforced concrete structures. Stroyizdat, M., 1985, p. 59.

Table stress cement, PC - Northland cement.

Claims (1)

An anchor device for concrete and reinforced concrete structures, comprising a smooth metal core and an adhesive layer, characterized in that the adhesive layer is made of expanding fine-grained concrete with a water-cement ratio of 0.25-0.35 and a linear expansion coefficient of 0.3-2.0%, with a thickness of 0.25-0.6 of the diameter of the rod, while the relative length of the embedment of the rod in the concrete structure is determined by the formula
l / d = 0.74R _s / R _b +2.4,
where l is the length of the embedment of the rod in the concrete structure, mm;
d is the diameter of the rod, mm;
R _s is the calculated tensile strength of the anchor material, MPa;
R _b - estimated resistance of fine-grained concrete to compression, MPa.