DE10064187C1 - Diameter measuring device for ground foundation or wall element has measuring element provided by rod-shaped profile with 2 concave strips pressed together for switching from flexible state to rigid state - Google Patents

Abstract

The measuring device has a rod (10) and a measuring element (12) displaced in the direction of the ground foundation or wall element via the rod and having at least one rod-shaped profile (14) with 2 conditions exhibiting different flexure rigidities. The rod-shaped profile is provided by 2 curved flexible elongate strips coupled together with their concave sides facing and having a flexible condition in which the strips are separated from one another and a rigid condition in which the strips are pressed together via a deflection device (26).

Description

The invention relates to a device for determining the diameter of im Soil produced by means of a jet spraying support or wall ment according to the preamble of claim 1.

In the case of a nozzle jet process, support or wall elements are thereby produced asked that a flushing rod in a previously made hole in the ground the deepest in the borehole and the surrounding soil by means of a mostly horizontal cutting jet cut out of water or suspension and is milled out. At the same time as milling, the loosened soil is replaced with a Suspension of binder, for example cement or clay-cement, mixed. This intensive mixing creates a homogeneous, under the "Soil crete "well-known floor mortar in disc form or - if the flushing rod pulled from the bottom of the borehole and rotated about its longitudinal axis - in Column shape. The support or wall elements produced in this way also become soil Crete elements and the entirety of these are also called soil concrete bodies.

In the manufacture of soil concrete bodies, it is essential to determine the diameter, wall thickness or range of the soil concrete bodies as precisely as possible, since this depends on the arrangement of the individual soil concrete elements with one another and the amount of the binder to be used. For a given amount of binder / m ^{3 of} ready-mixed soil concrete mixture, the binder content increases with small dimensions and falls with large dimensions. Without knowing the exact dimensions of the Soilcrete body, too much binder can be used on the one hand and the binder content too low on the other to meet the specified strength and / or tightness values.

The following methods are known for example to determine the actual dimensions of soil concrete bodies:

• - Exposing the body
• - core drilling
• - Bar level for acoustic control when the jet hits (DE 197 31 223 A1)
• - mass balance
• - Ultrasound / radar measurements (WO-A-8 703 319)
• - electrical / electromagnetic measurements
• - fixed caliber measurements.

The disadvantage here, however, is that these known methods either only very much are difficult and difficult to carry out or only imprecise results deliver nisse.

A tool for measuring a borehole is known from US Pat. No. 4,251,921 swing-out probe arms known. The probe arms are on both sides connected to a holding device and include between this connection  Joint. The probe arms are constantly with a spring force that folds out aufschlagt. This arrangement has the disadvantage that it is relatively complicated and has many swivel joints, which in operation in a mixture of soil mass, liquid and binder would be very susceptible to failure. The swivel arms are also constantly under the spring force during the measurement of a borehole unfolded so that they are subject to great wear. Also are only Measurements of small to very small relative movements of the probe arms in the am Drilled hole circumference possible condition, which significantly increases the measuring accuracy reduced.

From DE-OS 18 03 736 a probe with articulated arms for boreholes be knows, where tactile shoes or articulated arms by means of leaf springs permanently under Bias held and thus pressed against a wall of a borehole become. This results in the same disadvantages with regard to measuring accuracy as with the known tool described above. The probe covers In addition, a hydraulic retraction device for the swivel arms. This serves however, only for simple insertion of the device into a borehole and has no function during the measurement of the borehole itself.

DE 44 29 917 A1 also describes a device for determining the diameter known or the wall thickness of support or wall elements in bathing, wherein a measuring element from a mechanically the edge region of the mixture scanning measuring rod, which has one end with a holding device is connected, while the other end by means of a drive up to the edge range of the mixture is movable.

EP 0 940 559 A2 describes a device for measuring the diameter a body manufactured by means of high pressure injection in the ground, whereby by means of a biased coil during the drilling process of the current achieved diameter of a HDI body to be produced can be determined. The Coil has a measuring line that can be wound up and unwound, with a free one End of the winding and unwinding device a float or flow body located, which is carried away by the flow of the high pressure injection device is so that the length of the measuring line of the effective length of the high pressure injection jet  equivalent. However, this device is essential from the exact Function of the entrainment of the floating body by the injection jet pending. Furthermore, since it is arranged directly in the injection jet, the arrangement is star not subject to wear. Furthermore, undesirable repercussions are the Measuring device itself does not affect the quality and depth of the injection jet excluded.

The invention has for its object a device of the above. Kind available supply, which the above-mentioned. Disadvantages eliminated and with regard to functional reliability and operation has been improved and the structure has been simplified.

This task is accomplished with a device of the above. Kind with the ge in claim 1 characterized features resolved. Advantageous configurations result from the other claims.

In the device according to the invention, the measuring element comprises at least one rod-shaped profile with two states, the profile in a first state is more rigid than in a second state. There is also a deflection device provided, which transfers the rod-shaped profile in the second state the linkage in the direction of the edge area of the support or wall redirected mentes and brought back into the first state.

This has the advantage that the measuring element for insertion or deflection in the so Pull out the support or wall element that has just been produced from the frame is flexible and at the same time has increased bending stiffness for the measurement has, so that it is functionally reliable up to a wall of the support or wall element is extendable.

For an automatic transition to the first more rigid state, this is rod-shaped profile designed so that it is stable in the absence of external external forces automatically go into the first state and maintain it holds.  

In a preferred embodiment, the rod-shaped profile comprises two ge arched, flexible longitudinal strips, for example made of spring steel or another elastic material, which knows each other with their concave sides send are connected to one another, the longitudinal strips in the first state of are arched away from each other and are pressed together in the second state or abut each other. The two longitudinal strips are, for example Welding, soldering or a close-fitting one that surrounds the longitudinal strips Tube, in particular shrink tube, connected to each other.

The deflection device comprises, for example, a deflection roller, which is connected to a Deflection shoe works together. As an alternative or in addition to the redirection appropriately trained hollow channel provided.

In an alternative embodiment, the deflection device comprises a profile worm, which is designed for example with a thread.

The invention is explained below with reference to the drawing. This shows in

Fig. 1 shows a first preferred embodiment of an inventive pre direction in sectional view,

Fig. 2 shows a measuring element of the device according to Fig. 1 in a perspective view;

Fig. 3 shows a second preferred embodiment of a device according to the invention in sectional view and

Fig. 4 shows a third preferred embodiment of a device according to the invention in sectional view.

The preferred embodiment shown in FIG. 1 of a device according to the invention for determining the diameter of support or wall elements, not shown, produced in the floor by means of a nozzle jet method comprises a linkage 10 and a measuring element 12 . For measurement, the rod 10 is sunk into the still liquid suspension produced by the jet method and the measuring element 12 is extended from the rod 10 at various points until it strikes the hard surrounding soil. From the path by which the measuring element was extended, one can directly deduce the thickness of the support or wall element produced at the respective measuring location. A corresponding height profile of the support or wall element can be created by appropriate measurements at different depths.

In the device according to the invention in the form of a mechanical diameter measuring device, a rod-shaped, flexible profile 14 with a predetermined length L is provided as the measuring element, as shown in FIG. 2, which initially satisfies two opposing requirements: while the profile 14 for the measuring process is extended out of the linkage 10 through the suspension until it comes into contact with the surrounding soil. Secondly, for the deflection of the profile 14 from the vertical or a drill string axis 16 into the horizontal or a measuring axis 18, it must be flexible.

To meet these two requirements, the profile 14 comprises two flexible ge curved longitudinal strips 20 , 22 which are fixed to each other with their respective concave sides. The material for the longitudinal strips 20 , 22 is flexible, such as spring steel. The connection of the two curved profiles 20 , 22 takes place, for example, by mechanical adhesion by means of welding or soldering on the longitudinal edges 24 lying against one another. As an alternative or in addition, the profile 14 is inserted into a tube, such as a shrink tube, which fits tightly against it.

Due to this design of the profile 14 , this can assume two states. In a first state, the two longitudinal strips 20 , 22 are bent away from one another, as can be seen from FIG. 1. The profile 14 assumes this state automatically if no external forces act on it. In this first state, the profile 14 is essentially rigid. By compressing the two longitudinal strips 20 , 22 or by applying a bending moment which exceeds the shape retention of the combined longitudinal strips 20 , 22 , a second state is obtained in which the profile 14 is considerably more flexible than in the first state. However, as soon as you stop the external force to press together, the profile automatically returns to the first state.

As can be seen from FIG. 1, a deflection device is provided in the linkage 10 , which comprises a deflection roller 26 and a deflection shoe 28 . The profile 14 is pushed for measurement within the linkage 10 in its first, rigid state and downward between guide roller 26 and 28 Umlenkschuh quantitative presses together and thereby transferred to the second, flexurally soft state. In this second state, the profile 14 is deflected onto the measuring axis 18 and leaves the linkage through a window 30 . After a corresponding section from the profile 14 leaves the area between the deflection roller and the deflection shoe, the external pressure on the longitudinal strips 20 , 22 ends. As a result, the Pro fil 14 returns to the first, rigid position and can thus move to the surrounding floor as far as it will go without the risk of the suspension kinking. In the embodiment of FIG. 1, the profile 14 leaves the linkage in so-called. Flat edge position, ie the abutting longitudinal edges 24 of the profile 14 are in a horizontal plane. The extension dimension, which corresponds to a radius of the support or Wandele element produced, can be measured or displayed on the vertical strand of the profile 14 .

In an alternative, not shown, the deflection takes place without a roller, at for example by means of a suitably designed hollow channel as a guide. The However, roller is particularly advantageous for reasons of friction reduction.

FIG. 3 shows an alternative embodiment in which a profile screw 34 with a thread, not shown, is provided as the deflection device. Here, the profile 14 emerges edgewise from the linkage 10 , ie the abutting longitudinal edges 24 of the profile 14 are in a vertical plane. This has the additional advantage that the action of gravity on the profile 14 takes place in the direction of a line 32 connecting the longitudinal edges 24 ( FIG. 2), in which the profile 14 has its greatest bending rigidity.

FIG. 4 illustrates a preferred development of the device according to FIG. 3, the measuring element 12 comprising two profiles 14 . This arrangement is made possible by the deflection device in the form of the screws 34 . A 1/2 thread turn is sufficient.

A suitable choice of material for the guide equipment (Teflon, chrome-plated steel, etc.) can be used to counteract dirt that impairs its function, while at the same time reducing friction effects between profile 14 and guide and deflection device.

The profile 14 is preferably inserted into guide rods (not shown) from above into the linkage 10 and threads itself its way through the deflection devices and through the side profile openings 30 . In this way, the profile 14 can easily be removed for cleaning purposes and reinserted or replaced.

Claims (6)

1. Device for determining the diameter of support or wall elements produced in the floor by means of a jet process, the device having a linkage ( 10 ) and a measuring element ( 12 ) which, starting from the linkage ( 10 ), towards an edge region of the support or wall element can be extended, the measuring element ( 12 ) comprising at least a rod-shaped profile ( 14 ) with two states, which is more rigid in a first state than in a second state, and further comprising a deflection device ( 26 , 28 ; 34 ) is provided which converts the rod-shaped profile ( 14 ) into the second state, deflects it out of the linkage ( 10 ) in the direction of the edge region of the support or wall element and converts it back into the first state, characterized in that
that the rod-shaped profile ( 14 ) comprises two curved, flexible longitudinal strips ( 20 , 22 ) which are connected to one another with their respective concave sides, the longitudinal strips ( 20 , 22 ) being curved away from one another in the first state and in the second State lying flat against one another, the rod-shaped profile ( 14 ) being designed to be dimensionally stable,
that in the absence of external forces it automatically changes to the first state and maintains it. 2. Device according to claim 1, characterized in that the two longitudinal strips ( 20 , 22 ) by welding, soldering or one of the longitudinal strips fen ( 20 , 22 ) surrounding, closely fitting tube, in particular shrink tube, are interconnected. 3. Apparatus according to claim 1 or 2, characterized in that the longitudinal strips ( 20 , 22 ) are made of spring steel or another elastic mate rial. 4. The device according to at least one of the preceding claims, characterized in that the deflection device comprises a deflection roller ( 26 ) which cooperates with a deflection shoe ( 28 ) and / or a hollow deflection channel. 5. The device according to at least one of the preceding claims, characterized in that the deflection device comprises one or more profile screws ( 34 ). 6. The device according to claim 5, characterized in that the profile screw ( 34 ) are provided with a thread.