RU88082U1 - DEVICE FOR DETERMINING THE LOADING ABILITY OF THE BOLT CONNECTION - Google Patents

Abstract

1. A device for determining the bearing capacity of a bolted connection on high-strength bolts, including fixed and movable parts, a compression unit and a shear unit, made in the form of a lever having an opening for a load bolt, equipped with a force measuring device, characterized in that the stationary part is made of two racks , the end surfaces of which are fastened with a curved strip, each of the racks equipped with holes for bolting for fastening to the metal structure, as well as an opening for the shaft, on which the lever is fixed with a rum, with the possibility of connecting it with a curved strip, and a self-aligning cracker is installed between the lever protrusion and the movable part. ! 2. The device according to claim 1, characterized in that the self-aligning cracker is made of hardened metal with a height equal to the thickness of the movable part. ! 3. The device according to claim 1, characterized in that the position of the racks is fixed with a screed that limits the movement of the lever in a vertical plane.

Description

The utility model relates to devices for determining the magnitude of the bearing capacity of a bolted connection, mainly performed on high-strength bolts, and can be used in bridge construction and other areas of construction and operation of metal structures.

In modern practice of production and installation of metal structures, high-strength bolts are used in friction (shear-resistant) joints.

Shear work is the main type of work of most fixed bolted joints, and in different joints it has its own characteristics.

The quality of shear-resistant joints on high-strength bolts is characterized by the absence of shear of the connected elements during the perception of external load.

In the joints on the bearing high-strength bolts, along with the friction forces, the bolts themselves participate in the force transfer, which come into operation similarly to the bolts of other bolt joints after the effective force overcomes the friction forces, the parts to be joined are shifted, and the smooth part of the bolt shaft begins to contact the edges of the holes of the connected parts. Due to the great mechanical strength of the bolt, the bearing capacity of such joints is limited not by the cut of the rod, but by the crushing of the holes.

In joints on high-strength bolts with a controlled bolt tension force (shear-resistant, frictional), the pulling forces of the connected elements by bolts are so great that under the action of shear forces, the friction forces arising in the joint fully absorb these shear forces and the whole joint works elastically.

Below are the tension values of high-strength bolts depending on their diameter.

P.№ Bolt Diameter (mm) Tension force (kN) Tension (t) one. M18 145 14.8 2. M22 220 22.4 3. M24 258 26.3 four. M27 334 34.0

The shear resistance in friction compounds is determined by the formula:

_{Q bh = R bh * y b} * A _bn * μ / y _h (1), wherein

R _bh is the calculated tensile strength of the high strength bolt;

y _b is the coefficient of the operating conditions of the connection, depending on the number (n) of bolts required to absorb the design effort; A _bn is the cross-sectional area of the bolt;

µ is the coefficient of friction on the contacting surfaces of the connected elements;

y _h is the reliability coefficient, depending on the method of tensioning the bolts, the friction coefficient µ, the difference between the diameters of the holes and the bolts, the nature of the current load.

From this formula it follows that the shear force between the bolts along the length of the connection is taken evenly distributed (L. M. Raber “Connections on high-strength bolts”, Dnepropetrovsk, “System Technologies”, 2008, pp. 8-10)

A practically acting shear force must overcome the rest friction force between two contacting surfaces. The standard coefficient of friction of the contacting surfaces depends on the method of processing or the coating applied to them.

The highest and most stable coefficients of friction are ensured by sandblasting or bead-blasting cleaning of the contact surface. In this regard, in metal structures of bridges with joints on high-strength bolts, only sandblasting is recommended, which ensures a friction coefficient of 0.57-0.58 under normal tension of a high-strength bolt.

However, the tension of the bolt during operation of the friction joints can vary, therefore, the magnitude of the shear force is the main characteristic of the sufficiency of reliability of the metal structure and it is possible to determine the value of the coefficient of friction between the connected surfaces of the metal structure.

It should be noted that at present, the processing of metal surfaces of metal structures is carried out in the factory, therefore, it is necessary to check the actual value of the coefficient of friction with the necessary value of the coefficient of friction before mounting the structure to establish measures to ensure the reliability of its operation during operation.

Given that the shear force is equal to the rest friction force, to determine the bearing capacity of the joints on high-strength bolts, devices can be used to determine the rest friction force.

A device for measuring the static friction force of the contact surfaces of a bolt shear-resistant joint with one plane of friction, including a fixed and movable parts connected to compression and shear units, the shear unit is made in the form of two levers of the first kind, one connected rigidly to the fixed part, and the second with the ability to move around a fixed part and interact with a fixed part (Patent of Ukraine No. 40198, published in BI No. 6, 2001).

The disadvantages of this device include the lack of reliability of the second thrust and the lack of accuracy in determining the shear force, because its connection with the moving part, the shift of which is necessary to carry out, introduces an error in the measurement.

The best-known devices for determining shear forces (shear meters) are based on the use of strain gauges (RF patents Nos. 21116614, 2155942, etc.) or, if possible, various presses are used. The force at the moment of shear is fixed using an electric signal or a pre-calibrated torque wrench scale.

A common disadvantage of these technical solutions is the limited scope, because it is impossible to use these devices directly in operating metal structures with high-strength bolts or directly when mounting metal structures at construction sites.

A device for determining the shear force, comprising a bed 1, at the ends of which there are two racks 2 and 3. In the rack 2 is mounted a grip 4 having a threaded end 5 with a sample securing the bolt 13. A jack 6 is attached to the rack 3, to which, by means of rods 7, a second grip is attached 8. To the posts 2, 3 a traverse 9 is attached with a movable upper stop 10, which is moved by a screw 11. A jack 12 is attached from the bottom of the bed, along the axis of the stop 10. A test piece consisting of three strips is placed on the supporting plane of the jack 12. The ends of all planks on the racks have grooves for fastening them to the grippers 4 and 8. Screwing the screw, press the stop 10 to the rails, and after the rails are precisely installed in the required position, jack 12 is activated. The required division is set on the jack gauge, after which the jack 6 is actuated , i.e. apply shear force to the middle bar of the sample (L. M. Raber “Connections on high-strength bolts”, Dnepropetrovsk, “System Technologies”, 2008, p. 35-36).

This device has several drawbacks: design complexity, insufficient measurement accuracy and limited use - only in the design of metal structures, to determine the estimated shear force or before installation.

The closest technical solution to the claimed utility model is a device for determining the coefficient of static friction, which can be applied both at the design stage and directly on mounted structures. It consists of fixed 1 and movable 2 parts, a compression unit and a shear unit. The compression unit contains a bolt 3 equipped with a torque wrench 4. The shear unit contains two levers of the first kind 11, to each of which a clip 12 is rigidly attached. A finger 13 is located in the spherical recesses of the clips 12, the position of which is fixed by washers and cotter pins. The clips 12 divide the levers 11 into two parts - short and long. The levers with the ends of the short parts rest on the fixed part 1, touching the side faces with the edge of the movable part and the thrust part 16, rigidly attached to the lever and the fixed part 1 with bolts 17. Through the hole 18 available on the long ends of the levers 11, a bolt 19 is released, equipped with a force measuring device ( L. M. Raber “Connections on high-strength bolts”, Dnepropetrovsk, “System Technologies”, 2008, p. 41-43).

The operation of the device is as follows. In the process of controlled tension of the bolt 19, the levers with their lateral faces abut against the edges of the movable and thrust 16 parts, trying to push them apart. The tension of the bolt 19 is carried out until the shift of the part 2 relative to the part 1. The part 16 remains stationary, since it is fixed to the part 1 with two bolts. The shear force of the part 2 relative to the part 1 is fixed on the scale of the power measuring device 20. The resting friction force of the part 2 relative to the part 1 is determined from the condition of the lever equilibrium and the rolling friction in the hinge (finger) at the moment of the part 2 shift.

The disadvantages of the device include the fact that the axis of the finger is offset relative to the point of application of the shear force, therefore, a lifting force is generated that distorts the accuracy of the measurement result. In addition, given that the second lever is rigidly connected

with a fixed plate 16, the tension force of the bolt 19 is applied to the finger, so the cotter pin fixing its position may break.

The design has insufficient rigidity to withstand the required (calculated) load forces.

The technical task of the proposed utility model is to eliminate the disadvantages inherent in the prototype by increasing the reliability of the design of the device and the accuracy of determining shear forces.

The technical result is achieved due to the fact that in the known device containing a fixed and movable part, a compression unit and a shear unit, made in the form of a lever having a bolt hole equipped with a force measuring device, design changes and additions are made, namely:

- the fixed part of the device is made in the form of two racks, each of which has an opening for bolted connections, and is also equipped with holes for the shaft and screed for their fixation;

- to the rear (end) surface of the racks attached figured bar, which is an emphasis for the lever;

- the lever of the shear assembly is placed on the shaft between the uprights and in the tail end has an opening for the load bolt connecting it to the curly strip;

- the device is additionally equipped with a self-aligning cracker located between the cylindrical protrusion of the lever and the movable part, and its height is equal to the thickness of the part.

Below (Fig.1, 2) is a detailed design of a device for determining the bearing capacity of a bolt shear-resistant joint of a metal structure, which is determined by the shear force of one of the two contacting surfaces of the structure, and in Fig.3 - the principle of operation of the device.

In each case, some details of the device can be changed, but the main components are functionally and constructively performed in a similar way.

Figure 1 shows a General view of the device.

Figure 2 is a section along the Central plane of the lever, which is the node of the shift.

Figure 3 is a schematic diagram of the operation of the entire device.

Figure 1 shows: two racks 1, equipped with an opening 2 for a shaft 6 and holes for a bolt, a bar 3 used to transport the device, a curved bar 4 connecting the racks 1, a lever 5 mounted on the shaft 6 and a coupler 7.

Figure 2 (section) shows: rack 1, transportation unit 3, curved strip 4, lever 5, shaft 6, screed 7, self-aligning cracker 8 made of hardened metal, assembly 9 for fixing cracker 8, load bolt 10, support unit 11, spring 12, hole 13 in the figure bar 4 for the bolt 10, floating bearing 14 and nut 15.

Figure 3 shows: a fixed part (sheet) 16, a movable part (sheet) 17, a sleeve sleeve 18, a force measuring device 19 (torque wrench) equipped with a scale 20, a mount 21 of the fixed part of the device to the work 16, a mount 22 parts 16 and movable parts 17.

Figure 3 also conditionally shows a bolt connection 15, including a load bolt 10, a lever 5, a curved strip 4.

The node 14 is made in the form of washers having ground spherical surfaces (convex and concave, respectively), forming a floating support, ensuring no gap.

The operation of the device is as follows.

A device for determining the amount of shear, by means of strap 3, is transported to the metal structure by the bearing ability of the connection of the surfaces of which they want to determine. The posts 1 are fixed by means of a bolted connection 21 to a fixed part 16, and a bolted connection 22 to a movable part 17, and the tightening force of the bolted connections corresponds to the calculated force. The sleeve sleeve 18 of the torque wrench 19 is mounted on the head of the load bolt 10, the position of which, by means of the support 11, the spring 12, the floating support 14 and the nut 15, ensures reliable fastening of the lever 5 with the figured bar 4 connecting the fixed racks 1 of the device.

The rotation of the torque wrench 19 carries the load of the bolt 10. The tension of the bolt through the lever 5 is transmitted to the cracker 8, which acts on the movable part 17, secured by high-strength bolts 22 with a metal sheet 16. The torque of the bolt 15 is fixed on the scale 20 of the torque wrench 19.

At the moment of shear, the parts 17 fix the magnitude of the force, which is the shear force (rest friction force). The obtained value is compared with the calculated value and if they differ, then they are adjusted by additional tension of high-strength bolts or additional processing of the contacting surfaces of the metal structure is carried out.

The advantage of the proposed utility model is to increase the reliability of the structure, which is ensured by increasing the accuracy of determining the shear force, and according to it, the bearing capacity of the high-strength bolted connection of a particular design.

The device is manufactured and tested during the installation of building and bridge metal structures. Its implementation will be carried out in 2009 on bridge and building structures, both newly designed and working metal structures of the friction type.

Claims (3)

1. A device for determining the bearing capacity of a bolted connection on high-strength bolts, including fixed and movable parts, a compression unit and a shear unit, made in the form of a lever having an opening for a load bolt, equipped with a force measuring device, characterized in that the stationary part is made of two racks , the end surfaces of which are fastened with a curved strip, each of the racks equipped with holes for bolting for fastening to the metal structure, as well as an opening for the shaft, on which the lever is fixed with a rum, with the possibility of connecting it with a curved strip, and a self-aligning cracker is installed between the lever protrusion and the movable part. 2. The device according to claim 1, characterized in that the self-aligning cracker is made of hardened metal with a height equal to the thickness of the movable part. 3. The device according to claim 1, characterized in that the position of the racks is fixed with a screed that limits the movement of the lever in a vertical plane.