The present invention pertains to rock anchors (rock bolts) and, more particularly, to the load monitoring of rock anchors used for ground support in mining and civil engineering applications.
It is well known that the consequences of rock falls in underground mines can be disastrous. Rock falls can cause injuries and fatalities, and can also be responsible for mine production delays. Therefore, much attention is given to the design and installation of adequate rock support systems in underground mines. Rock anchors, such as mechanical rock bolts and resin grouted rebars, are installed in almost all mine access areas such as gate roads, drifts, ramps and shafts. Due to their important role as primary rock support, it is necessary to verify that the rock bolt is functioning adequately and is not subjected to an excessive load. There are many situations in underground mines and tunnels where such a concern may arise especially in development and production areas where the ground response changes constantly due to mining induced stress changes.
The need to measure the rock anchor load with instrumentation methods has been recognized by researchers and new measurement techniques were developed and became commercially available. One of such techniques is the hollow load cell technology. As the load cell is sandwiched between a face plate and a reaction plate, it measures the axial strain inside the cell, from which the axial bolt load is calculated. The disadvantage of this technology is that the face and reaction plates must be placed perpendicular to the rock anchor to capture the correct reaction force, which is not always possible in many mining and civil applications. Also, rock surface preparation is often required to make sure that the rock surface and the reaction plates are perfectly parallel. Another disadvantage is that the hollow load cell reduces the headroom of the mine opening or the tunnel.
To overcome the drawbacks associated with the use of the hollow load cell technology, a design that is based on placing a strain gauge directly in the rock anchor head by drilling a central blind hole that extends beyond the threaded portion was developed, hereinafter referred to as the instrumented rock anchor design. As the strain gauge is placed in the axial direction, it measures the load-induced axial strains, which can be converted to bolt axial loads. Unlike the hollow load cell, the embedded strain gauge in the rock anchor head requires no additional headroom in the drift, and does not require any surface preparation. Thus, this technique is not prone to erroneous measurements due to the position of the face plate with respect to the rock surface. It can be seen that this technique is applicable to virtually any type of rock anchors, such as mechanical rock bolts, cone bolts, grouted rebars, and forged head bolts.
In spite of the above mentioned features, the instrumented rock anchor design has drawbacks that limit its suitability to mining applications. One deficiency of this design is the need to transport the rock anchor back and forth to the mine. This results in additional materials handling work and cost. It also exposes the head connector to damage during shipping and handling. Another deficiency is that the hole drilled in the bolt head reduces its capacity. Even if the diameter of the hole is only 20% of that of the rock anchor diameter, the loss of rock strength is 4%. The strain gauge being installed in the rock anchor itself is thus unable to capture the ultimate breaking strength of the rock anchor. Most rock anchors have an ultimate strength that is 10%-15% greater than the yield load. Thus, it can be said that even if the rock anchor load reaches the yield limit, it can still offer further load supporting capability before it eventually breaks.
While the design concept of the instrumented rock anchor offers advantages over the traditional hollow load cell technology, it is nevertheless not practical for mining applications because of the design deficiencies mentioned above.
There is thus still a need for a new concept for monitoring the axial load on the rock anchor head.
It is therefore an aim of the present invention to provide a novel load-measuring coupling device for rock anchors.
Therefore, in accordance with the present invention, there is provided a load-measuring coupling device for use on an anchor engaged in a structural medium, comprising a body including a threaded section and a hollow section, the hollow section being adapted to be connected to the anchor, the threaded section being adapted to be engaged to the structure for securing the body thereto, at least one strain gauge extending in the body for measuring a load applied to the anchor.
Other objects, advantages and features of the present invention will become more apparent upon reading of the following non-restrictive description of embodiments thereof, given by way of example only with reference to the accompanying drawings.
Reference will now be made to the accompanying drawings, showing by way of illustration an illustrative embodiment of the present invention, and in which:
In general, the present load-measuring coupling device is a rock anchor coupler load cell that is instrumented with one or two or more strain gauges that are embedded in blind boreholes along the axis of the coupler. The coupler load cell is fitted onto the rock anchor, such that, once installed in the rock, the coupler load cell can sense and monitor the rock anchor head axial load. The advantages of this design are numerous. The coupler load cell is designed so that its elastic limit resistance is greater than the ultimate breaking strength of the rock anchor. This design ensures a complete load path monitoring of rock anchor performance until its failure. The coupler load cell design offers the advantages of light weight in shipping and handling as well as ease of installation in the field. Furthermore, it can be fitted to a rock anchor of any length, and any size.
The coupler load cell basically comprises a solid round bar or body typically made from steel, which at one (visible) end, called the threaded section, is threaded on the outside to receive a bearing plate with a central hole and a nut, and which at an other (hidden) end, called the hollow section, has a threaded hole to allow a threaded rock anchor head to be threadably fitted thereinto. Each strain gauge is embedded in a blind hole in the body and is oriented in the hole length direction, to sense the axial stretch induced in the gauge due to applied loads on the rock anchor head. The embedded strain gauges are attached to a connector located at the threaded end. The connector permits the transmission of the strain gauge signal to a strain gauge reader unit through an instrumentation wire.
More particularly, and with reference to the drawings, there will now be described a load-measuring coupling device D, also called the instrumented coupler load cell, as being used in mining applications to monitor the axial load in a rock anchor supporting a roof of a mine or tunnel. However, it should be understood that other applications of the load-measuring coupling device D are contemplated. For example, the load-measuring coupling device D could be used to monitor the axial load in a soil anchor supporting a retaining wall or a slope.
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A blind hole 8 is defined in the body 1, the blind hole 8 being driven from the threaded section 2. A strain gauge 9 is embedded in the blind hole 8 and is oriented in the hole length direction, to sense the axial stretch induced in the gauge 9 due to a load applied on the rock anchor head 7. The embedded strain gauge 9 is attached to a connector 10 located at a proximal end of the threaded section 2.
The load-measuring coupling device D is fitted onto the rock anchor head 7 before it is installed. A typical installation using a mechanical rock anchor with expansion shell requires that a drill hole 11 be first driven in the rock R to a length of that corresponds to the combined length of the rock anchor A and the load-measuring coupling device D. The load-measuring coupling device and rock anchor assembly D and A is inserted into the drill hole 11 and rotated by means of a conventional drill like a stoper or a jackleg or specialized rock bolting equipment. Rotation is maintained until the expansion shell has gripped to the surface of the drill hole 11 and the bearing plate 3 is firmly pushed against the rock surface 12. A torque is further applied by the drill to the nut 4 to achieve the desired pretension.
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This installation requires that the drill hole 11 is first defined in the rock R to a length of that corresponds to the combined length of the rock anchor A and the load-measuring coupling device D″. Bonding material 17 such as resin cartridges are then inserted into the drill hole 11, with the fast setting resin being inserted first, followed by the slow setting resin. The load-measuring coupling device D″ and the rock anchor head 7, once attached, are pushed into the hole 11 by means of a conventional drill like a stoper or a jackleg or specialized rock bolting equipment. The pushing action causes the resin cartridges to rupture. The drill is then used to rotate the nut 4 of the load-measuring coupling device D″. This causes the nut 4 to advance until the bearing plate 3 comes in contact with the rock surface 12 and the rock anchor head 7 to advance down the threaded hole 6 until it hits the shear pin 15. The rock anchor head 7 will then spin in the drill hole 11 thus mixing the resin components 17. After some time has been allowed for the fast resin to set at the toe of the drill hole 11, the drill is used to apply further torque to the nut 4 until the shear pin 15 breaks off and falls in the borehole 16, and the rock anchor head 7 advances further in the bore hole 16 thus causing anchor tensioning and the bearing plate 3 to push firmly against the rock surface 12.
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In all of the above described embodiments, the connector 10 has the function of transmitting the strain gauge signal to a strain gauge readout unit through an instrumentation wire. The strain gauge or gauges 9, 14 are connected with dummy precision resistors inside the threaded section 2 to complete a Wheatstone Bridge circuit. Alternatively, the Wheatstone Bridge circuit can be completed outside the threaded section 2 using the strain gauge readout unit, in which case only the strain gauge or gauges 9, 14 inside the drill hole(s) 11 are attached to the connector 10. The protective cap 20, which is removably threadably engaged to the proximal (visible) end of the threaded section 2 is provided for protecting the connector 10,
The embedded strain gauge 9 or strain gauges 14 can be fastened in place by using a bonding material such as glue or epoxy to ensure that the strain gauge is well adhered and will sense the stretch in the load-measuring coupling devices D, D′, D″ and D′″ once load is applied to the rock anchor head 7.
The threaded section 2 of the load-measuring coupling devices can be made to any desired size and type. The hollow section 5 is threaded on the inside to fit any size and type of rock anchor A. The threaded hole 6 is deep enough to transmit the maximum rock anchor force possible, which corresponds to the rock anchor ultimate breaking strength. The diameter of the round bar or body 1 is designed such that its elastic limit resistance is greater than the ultimate breaking strength of the rock anchor A.
In the event that the drill hole 11 is smaller in diameter than the diameter of the round bar 1, the drill hole 11 may be collared by enlarging the end toward the rock surface 12 enough to fit the instrumented coupler load cell.
Although the present invention has been described hereinabove by way of embodiments thereof, it may be modified, without departing from the nature and teachings of the subject invention as described herein.
This application claims priority on U.S. Provisional Application No. 61/460,802 filed on Jan. 10, 2011, which is herein incorporated by reference.
Number | Date | Country | |
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61460802 | Jan 2011 | US |