RU136455U1 - DEVICE FOR STATIC TESTING OF SOIL CARRYING ABILITY - Google Patents

Abstract

1. A device for static testing of the bearing capacity of the soil, containing a rod coaxially mounted in the casing and resting on the soil through a stamp, a hydraulic jack coaxially fastened to the rod and abutting against the thrust beam, which is coaxially fastened to the casing, and two identical deflection meters, which are symmetrically located relative to the axis of the rod and are made with a string with a cylindrical body in which connecting threaded holes are made with a drive pulley and with arrows, with the string of each deflection The hoop covering the pulley is fastened at one end to the load, and the other end of the string is fastened to the rod, and the deflection gauges are equipped with a fastening clamp with a spherical hinge having an integrated swivel head combined with a shank, characterized in that the second end of the deflection string is fastened to the rod (with casing) with an appropriate bracket that is mounted on the rod (on the casing) and is made with intersecting mutually perpendicular holes: a through hole parallel to the axis of the rod, and an additional p a screw hole, while the second end of the string is passed through the through hole of the bracket and secured therein with a screw screwed into the threaded hole, and the body of each deflection gauge is fixed with a clamp on the casing and fixed in an upright position using the shank of the spherical hinge of the clamp located in a given rotary head perpendicular to the axis of the rod, and the connecting threaded hole in the body of the deflection meter, which is located on the horizontal axis of the deflection

Description

The device relates to engineering and geological equipment and can be used in static tests of the bearing capacity of the soil in the field.

Known devices for static tests of bearing capacity, containing a hydraulic jack in communication with a power source, a coaxial beam to support the jack, and a rod with a stamp based on a pound (see AS SU No. 547662, class ΜΠΚ E01D 1 // 00, published in 1977 (1), Patent RU No. 2419706, class IPC E01D 1 // 00, published in 2011 (2), “Guidelines for field test methods for the bearing capacity of piles and pounds”, published by the All-Union Institute Transport Construction, 1979, Section 4, General Provisions, Appendix 4, Appendix 6 (3) and GI Tayukin's book “Instruments and Equipment for Static Tests research of building structures ”, Laboratory workshop, Tomsk, ed. TGASU, 2011, from 8-9 (4))

In (1), (2), (3), a hydraulic jack creates a load on a pound through a rod, and control of soil sedimentation is performed by string deflection meters. However, devices (1), (2) are extremely complex and expensive, which reduces the reliability and limits their use for testing.

In (4), general information is given, a kinematic diagram of typical deflection meters is given, and an example of their fastening is given, which is a special case and is not applicable for all types of tests.

The closest analogue is a device for static testing of soil bearing capacity (3), containing a rod coaxially mounted in the casing pipe and resting on a pound through a stamp, a hydraulic jack coaxially attached to the rod and abutting against the thrust beam, which is coaxially attached to the casing pipe, and two identical deflection meters, which are symmetrically located relative to the axis of the rod, and are made with a string, with a cylindrical body in which the connecting threaded holes are made, with a drive pulley and with Christmas trees, wherein each string deflectometer covering pulley, one end fastened to the load, and the second end of the string is secured to the pole, and deflectometer provided with fastening clamp with a spherical hinge having a built-in swivel head, combined with the shank.

However, in (3), fixing the drive pulley of the reference system of the deflection meter with a non-rigid frictional joint reduces the accuracy of the control of the draft. In addition to this, in all the analogs cited, the means for coordinated arrangement of the deflection meter and the controlling end of the string, fastened by the reference system, respectively, with fixed and movable supports, are not considered. This can lead to distortion of the control precipitation during field tests, and reduce the reliability of the control. At the same time, a hole is made in the body of the deflection meter, which is located on the central axis, which complicates installation and reduces the reliability of holding the deflection meter in position, convenient for taking readings, and further reduces the reliability of the control.

The objective of the proposed device is to increase the accuracy of control of the device by attaching a reference system of deflection gauges relative to the rod and casing, which does not distort the reliability of the control while improving the convenience of taking readings.

To achieve the objectives in the proposed device for static testing of the bearing capacity of the soil, containing a rod coaxially mounted in the casing pipe, and resting on a pound through a stamp, a hydraulic jack coaxially attached to the rod and abutting against the thrust beam, which is coaxially attached to the casing pipe, and two identical deflection meters, which are symmetrically located relative to the axis of the rod, and are made with a string, with a cylindrical body in which the connecting threaded holes are made, with a drive pulley ohm and with arrows, while the string of each deflection meter, covering the pulley, is fastened at one end to the load, and the second end of the string is fastened to the rod, and the deflection meters are equipped with a fastening clamp with a spherical hinge having a built-in rotary head combined with a shank, according to a utility model, the second end of the deflection string is fastened to the rod (with casing) with a corresponding bracket, which is fixed to the rod (on the casing) and made with intersecting, mutually perpendicular holes: through with a bore parallel to the axis of the rod and an additional threaded hole, while the second end of the string is passed through the through hole of the bracket and secured therein with a screw screwed into the threaded hole, and the body of each deflection meter is fixed with a clamp on the casing and fixed in a vertical position using a spherical shank a hinge of a clamp located in a predetermined rotary head perpendicular to the axis of the rod, and a connecting threaded hole in the housing deflection ra, which is located on the horizontal axis of the deflection gauge and serves to screw the deflection gauge body onto the shank, and the shank is additionally fastened with the deflection gauge screwed onto it with an external nut, the vertical tangent to the deflection drive pulley, from the side of the second end of the string, is distant from the casing equal to the difference between the distance from the casing to the axis of the rod and the distance from the axis of the rod to the axis of the through hole in the bracket. In addition, according to a utility model, a lock nut can be integrated into the spherical hinge, with emphasis on the pivoting head, to hold the shank in a predetermined pivoting head perpendicular to the axis of the rod.

The technical result of the proposed device is to increase the accuracy of control, due to the coordinated location of the drive pulley of the deflection meter and its movable string relative to the rod and casing, which made it possible to perform non-distorting measurements of the upsetting and improve the convenience of taking readings.

In Fig 1 shows a structural diagram of the proposed device.

Figure 2 shows the node A.

Figure 3 shows the kinematic diagram of the fastening of the drive pulley with a string and with the arrows of the deflection meter.

Figure 4 shows the design of the clamp with a built-in spherical joint.

Figure 5 shows a graph of the change in pile settlement from load.

Figure 6 shows graphs of the change in pile upset over time.

The proposed device for static testing of the stamp contains a rod 1. The rod 1 is supported on the ground 2, through a stamp 3 coaxially attached to it, and coaxially mounted in the casing 4. A hydraulic jack 5 is designed to create a pine load on the stamp, located with a stop in the stop beam 6 and communicated with the power source 7. Two identical deflection meters 8 are symmetrically installed, relative to the axis of the rod 1, and are designed to control the precipitation of the soil. Sediment in the analysis of bearing capacity is calculated as the arithmetic mean of the readings of the deflection meters. Each deflection meter 8 contains (see FIG. 1, FIG. 3, FIG. 4) a cylindrical body 9, a drive pulley 10, which is kinematically connected with arrows 11 and a string 12. One end of the string 12, covering the drive pulley 10, is fastened with a load 13 .

For fastening the second end of the string 12, the device is equipped with a bracket 14, fastened to the rod 1. In the bracket 14 there are two holes 15, 16 (see Fig. 2). One of them, the through hole 15, is parallel to the axis of the rod, and the other, the threaded hole 16, intersecting with the through hole 15, is perpendicular to the hole 15. The screw 17 is used to fix the second end of the string 12. For attaching the body of each deflection gauge 8 to the casing 4, a clamp 18 is used, which is made with an integrated spherical hinge 19. The spherical hinge 19 is formed by a rotary head 20 integrated in the clamp, and a shank 22 made integral with the head 20. A stop is integrated in the spherical hinge another nut 21, designed to fix the rotary head in a predetermined position. The housing 9 of the deflection meters is made with a diametrical connecting hole 23, which is located on the horizontal axis of the housing 9. The outer nut 24, screwed onto the shank, is designed for additional fixation of the deflection meter on the shank of the ball joint. Figure 3 shows the drive pulley 10, which is fastened to the arrows 11, through the first gear pair 25 of the speed reducer (not disclosed).

“A” is the distance from the casing to the vertical tangent to the drive pulley, from the side of its interaction with the second end of the string, “b” is the vertical tangent to the drive pulley, from the side of the second end of the string, “c” is the distance from the axis of the rod 1 to the axis of the through hole in the bracket, d is the distance from the axis of the rod to the casing.

The device is used as follows.

The cylindrical body 9 of the deflection gauges 8 can be fixed (externally or internally) to the casing (or to the rod) by attaching the second end of the string 12 to the rod (or to the casing), which depends on the convenience of taking readings. Figure 1 shows the option of attaching the second end of the string 12 of the deflection meters to the rod 1, and the bodies 9 of the deflection meters to the casing 4. The second end of the string 12 is fastened to the movable rod 1 by an arm 14.

During testing, the hydraulic jack 5, in communication with the power source 7, creates a stepwise increasing load on the rod 1, which is transmitted through the stamp 3 to the ground 2.

When the soil is sedimented, the rod 1 moves, the bracket 14 fastened with it, and the second end of the string 12 fastened with the bracket 14 (see Fig. 1, Fig. 3). The mobility of the string 12 is transmitted to the drive pulley 10, the rotations of which are recorded by the arrows 11. Based on the results of registration of precipitation, graphs of the variation of precipitation from the load and graphs of the variation of precipitation in time are constructed (see Fig. 5, Fig. 6), according to which the bearing capacity of the soil is estimated.

The bodies 9 of the deflection meters are fixedly mounted on the casing 4 by the clamp 18 and are fixed in a vertical position. This is done by arranging the shank 22 of the spherical hinge 19 of the clamp 18, relative to the axis of the rod, and the directivity of the connecting hole 23 in the body 9 of the deflection gauges 8. By corresponding rotation of the head, the shank 22 of the spherical hinge is fixed perpendicular to the axis of the rod 1. Using the connecting hole 23, directed along the horizontal axis of the housing 9, the deflection gauges 8 are screwed onto this shank. This ensures the fixation of the deflection in the specified vertical position. The deflection gauges are additionally fixed on the shank 22 by an external nut screwed onto the shank 24. The locking nut 21 is locked in the required position by the locking nut 21, which is integrated (screwed) into the spherical hinge with a stop in the head 20. The locking nut increases the reliability of holding the head, and therefore shank, in a given position. All this increases the reliability of fixing the deflection meters in an upright position, improves the convenience of taking readings and creates conditions for increasing the accuracy of registration of soil sediment.

When installing the deflection meters vertically, it is proposed to coordinate the position of the drive pulleys 10 of the deflection meters mounted on the stationary casing and interacting with the pulley, the corresponding ends of the string 12, fastened by brackets with a movable rod 1. For this, the deflection meters (with the drive pulley) are mounted on the casing in this way so that the vertical tangent "b" to the drive pulley of each deflection meter, from the side of the second end of the string, is located relative to the casing 4, at a distance "a" (see figure 1, figure 4), equal to the difference of the distance "d" from the casing to the axis of the rod, and the distance "c" from the axis of the rod to the axis of the through hole in the bracket. This allows you to direct the string exactly in the direction of measurements, to eliminate distortion of measurements and to increase the accuracy of control of precipitation, while improving the convenience of reading.

The second end of the string 12 is preloaded in the through hole 15 of the bracket 14 with a screw Loose in the threaded hole 16. By loosening the screw 17, the string 12 is released for movement and fixation, which will ensure its tension is adjusted. This allowed to exclude errors during measurements and to further increase the accuracy of control.

The technical and economic effect of the proposed device is to increase the accuracy of control of the device by attaching a reference system of deflection meters relative to the rod and casing, which does not distort the reliability of control while improving the convenience of taking readings.

Claims (2)

1. A device for static testing of the bearing capacity of the soil, containing a rod coaxially mounted in the casing and resting on the soil through a stamp, a hydraulic jack coaxially fastened to the rod and abutting against the thrust beam, which is coaxially fastened to the casing, and two identical deflection meters, which are symmetrically located relative to the axis of the rod and are made with a string with a cylindrical body in which connecting threaded holes are made with a drive pulley and with arrows, with the string of each deflection The hoop covering the pulley is fastened at one end to the load, and the other end of the string is fastened to the rod, and the deflection gauges are equipped with a fastening clamp with a spherical hinge having an integrated swivel head combined with a shank, characterized in that the second end of the deflection string is fastened to the rod (with casing) with an appropriate bracket that is mounted on the rod (on the casing) and is made with intersecting mutually perpendicular holes: a through hole parallel to the axis of the rod, and an additional p a screw hole, while the second end of the string is passed through the through hole of the bracket and secured therein with a screw screwed into the threaded hole, and the body of each deflection gauge is fixed with a clamp on the casing and fixed in an upright position using the shank of the spherical hinge of the clamp located in a given rotary head perpendicular to the axis of the rod, and the connecting threaded hole in the body of the deflection meter, which is located on the horizontal axis of the deflection ra and serves to screw the body of the deflection gauge onto the shank, and the shank is additionally fastened to the deflection by an external nut screwed onto it, and the vertical tangent to the drive pulley of the deflection gauge from the side of the second end of the string is removed from the casing by a distance equal to the difference in distance from the casing to the axis of the rod and the distance from the axis of the rod to the axis of the through hole in the bracket. 2. A device for static tests of soil bearing capacity according to claim 1, characterized in that a lock nut is built into the spherical joint with an emphasis in the rotary head to hold the shank in a predetermined rotary head perpendicular to the axis of the rod.

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