EP0932726A1 - Method of measuring mechanical data of a soil, and of compacting the soil, and measuring or soil-compaction device - Google Patents

Abstract

In this method for achieving optimum, in particular homogeneous, soil compaction, a compaction device (3) acting upon the soil to be compacted, whose oscillations are registered together with those of the soil as a single compaction vibration system by a computing unit (12), is excited by an oscillation-inducing force in such a way that this compaction vibration system oscillates in resonance, or at a frequency (Φ) that exceeds the resonance value by a specified frequency value that is only determined by adjustment stabilities. The value of the oscillation-inducing force, its periodic frequency (Φ), and the phase angle (ζ) to the oscillation of the compaction vibration system are set automatically by the computing unit (12) so that a specified soil rigidity is achieved, taking into account the mass of the compaction device (3) and of the weight pressing on it statically. The compaction device according to the invention can also be used to determine the soil rigidity and/or the soil modulus of elasticity.

Description

 Method for measuring mechanical data of a soil and for its compaction and measuring or

Soil compacting device

The invention relates to a method for measuring mechanical data of a compacted or compacted soil, a compacting method for achieving an optimal, in particular homogeneous soil compaction, a measuring device for measuring mechanical data of a compacted or compacted soil and a soil compacting device for optimal homogeneous soil compaction.

A method for soil compaction is known from WO 95/10664. In the known method, the frequency of a rotating unbalance is set in such a way that the compression unit in contact with the soil to be compacted does not exceed a predetermined value of harmonics - here the double fundamental vibration. Falling below this specified value is considered a stability criterion. Using two accelerometers arranged perpendicular to each other the acceleration of the compression unit is measured. One of the accelerometers measures the horizontal and the other the vertical accelerometer. The vibration amplitude of the compression device and the direction of the maximum compression amplitude are determined. The frequency of the eccentric and its weight as well as the rolling speed can be set with the aid of a computer. However, they are set so that machine resonance and frame resonance are avoided. The frequency and weight setting of the eccentric is made without taking into account the soil to be compacted. The shear modulus of the compacted soil and its plastic parameters are determined from the measured acceleration values.

Another soil compaction method is known from EP-A 0 459 062. In the known compaction process, attention is paid to the fact that the machine parameters are set in such a way that predetermined forces are achieved against the soil to be compacted.

The object of the invention is to demonstrate a measuring or soil compaction method and to create a measuring or soil compaction device with which or with which homogeneous soil compaction in a compaction method with as few passes as possible, in particular by specifying a desired soil stiffness and / or in particular a desired elasticity module can be reached and mechanical data of the soil to be compacted or compacted can be determined.

The object is achieved in that, in contrast to WO 95/10664 cited above, the local phase position of a maximum oscillation amplitude of a compression or. Measuring device is turned off, but on the temporal phase of the exciting vibration of the eccentric to the phase of the excited vibration of the soil compaction or measuring system, which is identical to that of the compaction or measuring device. Also, in contrast to WO 95/10664 in the resonance range of an oscillation system, formed from the compression or measuring device acting on the soil to be compacted (or already compacted) and the soil. The known soil compaction device of EP-A 0 459 062 operates in the resonance range of its compaction device, but it is not possible for it to determine the soil rigidity c _B achieved by the compaction and to optimize the entire compaction process on the basis of these determined values.

To explain the invention, a soil compaction device according to the invention is described in the following figures. The soil compaction device contains a measuring device according to the invention for determining the mechanical data essential for compaction. Show it

1 shows a schematic representation of a double tandem vibration roller with articulated steering, with which the soil compaction according to the invention can be carried out,

2 is a vibration equivalent mechanical circuit diagram of the soil compaction device of Figure 1,

3 shows a signal-based block diagram for carrying out the soil compaction according to the invention,

4 shows a normalized vibration amplitude of the soil compaction device (ordinate) according to FIG. 2 as a function of a normalized vibration frequency of the unbalance that excites the vibration (abscissa),

5 shows the position of a soil element to be compacted in the soil,

6 shows a compaction force acting on the base element shown in FIG. 5,

7 shows an activation process of a soil compaction device. direction for reaching an optimal operating point in a representation analogous to that in Figure 4 and

Fig. 8 is a schematic representation of a transmission for driving two imbalances of the soil compacting device with adjustable moment of inertia.

The double tandem vibratory roller 1 shown in FIG. 1 with articulated steering has a front and a rear drum 3a and 3b as a soil compacting device. In the following considerations, only one of the two bandages 3a and 3b is considered, which, unless there is a difference between the front and rear bandages 3a and 3b, is designated by the reference number 3. A coupling between the two bandages 3a and 3b in the double tandem vibration roller 1 described here, for example, is negligible for the operating behavior.

The bandage 3, as is shown schematically in FIGS. 2 and 3, has a rotating unbalance 5 with an adjustable static unbalance moment m _U 'r _u . The unbalance moment is set by changing the radial unbalance distance ru of unbalance 5. The setting of the moment of inertia and the frequency f is described below. In order to simplify the following embodiment, the mass m _{u of} the unbalance is arranged in a rotating manner at a distance r _u from the axis of rotation 7 of the drum 3. The static unbalance moment is therefore m _u -r _u [kg-m]. Vertically above the axis of rotation 7 on the

An accelerometer 11 is provided on the side of a carrier tab 9 of the drum holding fork 10. Acceleration values of the bandage 3 can be measured in the vertical direction with the acceleration sensor 11. The accelerometer 11 is signal-connected to a computing unit 12, which determines the vibration amplitude a of the bandage 3 by means of two integrations. The drum holding fork 10 is connected to the machine chassis via spring and damping elements 13 and 14. sis 15 connected. Spring and damping elements 13 and 14 are designed such that the dynamic forces in the damping element 14 are significantly smaller than the static ones.

In the method according to the invention for achieving an optimal, in particular a homogeneous soil compaction, the movement or the acceleration of the drum 3, as already indicated above, is measured with the acceleration sensor 11. The vibrating movement of the bandage 3 excited by the unbalance 5 can be represented mathematically as follows in the following equation [1]:

_f (t) = a ^ cosf (Ω / 2) t + δ ₁ 2] + a ₁ cos [Ωt + 5 ₁ ] -ta ₃ / 2Cθs [(3Ω / 2) t + ό ^~ ₃ , ₂ ] + a ₂ cos [2Ωt + 5 ₂ ] + a ₅ , ₂ cos [(5Ω / 2) t + <5 ₅ , ₂ ] + a ₃ cos [3Ωt + δ ₃ ]

In this formula, index 1 indicates an assignment to values which have the same angular frequency Ω (Ω = 2πf, where f is the frequency of unbalance 5), as the exciting oscillation of unbalance 5. 1/2 refers to half

Angular frequency Ω, 3/2 to one and a half times and 5/2 to two and a half times the angular frequency Ω. a is the maximum amplitude value of the partial vibration in question, δ denotes the phase-related assignments of the partial vibrations to one another.

The frequency components can be determined in the computing unit 12 from the acceleration signal by means of a Fourier analysis according to the above equation. Depending on the required compression process, the static unbalance moment of unbalance 5 and its frequency f are set differently:

a) If the bandage 3 always remains in contact with the ground, essentially only the rotation frequency l f of the bandage is determined by means of Fourier analysis. This compression process is called load operation.

b) If the bandage 3 periodically lifts off the ground, which results in a stronger compaction compared to a), the Fourier analysis determines harmonics, that is Circular frequencies of 2Ω, 3Ω, ... with a strongly decreasing maximum amplitude. The lifting of the bandage 3 from the ground indicates an optimal operating state, since here the forces transmitted to the ground are greater than in case a), as a result of which greater compaction takes place.

c) Does the machine catch the whole roller 1 starts to jump, i.e. the machine chassis 15 begins to vibrate around its rest position, then vibrations also occur with the half excitation frequency frequency Ω of unbalance 5, that is to say additionally (1/2) Ω, (3/2) Ω, (5 / 2) Ω, ... This condition is unstable and can also loosen the subsoil again. Furthermore, the machine chassis 15 can start here to swing about its longitudinal axis.

According to the mechanical equivalent circuit diagram in FIG. 2, the soil 20 to be compacted is represented as a spring 17 and a damping element 19. This means that a soil compaction system, which contains the bandage 3 with vibration-stimulating imbalance 5, the spring element 17 and the damping element 19 of the soil 20 to be compacted, and the spring element 13 and the damping element 14 between the bandage 3 and the machine frame 15, has a natural vibration. That this is so is evident from the measurement curves shown in FIG. The oscillation angular frequency Ω of the bandage 3 is plotted on the abscissa and the measured maximum oscillation amplitude a is plotted on the ordinate. However, the oscillation circuit frequency Ω is normalized to the natural frequency w _{0 of} the soil compaction system and the value a to a value a ₀ . The curve parameter is the static unbalance moment [product of an unbalanced mass m _u and the radial distance r _u from the axis 7]. The unbalance moment of curve 21a is smaller than that of curve 21b, etc. Above curve 23, roller 1 begins to jump [case c]. Curve 23 must therefore not be exceeded in compression mode. The family of resonance curves 21a to 21d represents an essential identification variable of the operating behavior of the soil compaction system. As explained below, the various influences of the machine parameters and the basic course of the compaction process can be read from it. Compaction is optimal when the soil compaction system resonates, formed from the compaction device acting on the soil 20 to be compacted and the soil 20 to be compacted, that is to say it can be carried out fastest and with the least energy expenditure.

The natural frequency w _{0 of} the soil compaction system is the square root of the quotient of the soil stiffness c _B [MN / m] and the weight m ^ [kg] of the drum 5:

, 0 = ( ^c B / * d) ^1/2

In the above equation, 5 parts of the respective wheel support and arithmetical "floor parts" must be added to the weight of the drum. However, these additional proportions are only a maximum of 10% of the pure bandage weight. They are preferably determined experimentally and can be neglected as a first approximation. The ground rigidity Cg is usually between 20 MN / m and 130 MN / m. It is determined according to the invention as described below. The natural frequency w ₀ is most easily measured by driving over the floor 20 with a small static unbalance torque according to curve 21a. The frequency of the unbalance 5 at the maximum curve value 25 of a / a _Q indicates the natural frequency w ₀ . The normalized amplitude value of a / a _Q = 1 is where the

Maximum values of curves 27a to 21d connecting curve 27 begins to bend to the left. The amplitude value a ₀ results approximately from the formula

a ₀ = (m _f + m _d ) g / c _B [2]

provided that the bandage 3 does not lift off (Case b), which is the case here. m _f is the load on the machine chassis 15 per drum 3. g is the acceleration due to gravity with g «10.

In addition to the acceleration sensor 11, a position sensor 29 for the temporal determination of the rotating unbalance 5 by its vertical lowest point (= compression direction) is arranged in a fixed position relative to the carrier plate 9. This passage is identical to the time of the maximum unbalance force directed against the floor 20. The maximum force acting against the floor 20 is transmitted from the bandage 3 into the floor 20 and takes place with a phase shift by the angle φ. That the phase shift φ reflects the position of the exciting vibration due to the unbalance 5 relative to the vibration of the soil compaction system.

A maximum compaction force in the soil 20 is achieved when the soil compaction system resonates. The soil compaction system always resonates at maximum values of curves 21a to 21d, which lie on curve 27. In the event of resonance, there is a phase shift of the exciting vibration system from the unbalance 5 to the soil compaction system of 0 = 90 °. This means that an optimal compaction is given with roller parameters [static unbalance moment m _u -r _u and unbalance rotation frequency Ω], which enable operation on curve 27. The resonance curves 21a to 21d in FIG. 4 are now recorded with constant soil properties. The ground properties, represented by the spring element 17 and the damping element 19 in FIG. 2, can change, and so can the position of the resonance curves 21a to 21d. As can be seen from the illustration in FIG. 4, the vibration amplitude responsible for the compaction of the soil 20 changes very strongly in the sub-resonant range [oscillation circle frequency Ω is less than the resonance frequency, phase angle φ is less than 90 °]; in the over-resonant range [oscillation circuit frequency Ω is greater than the resonance frequency, phase angle φ is greater than 90 °], however, relatively little. For a stable len compression mode, one selects the over-resonant range and sets the phase angle φ to a range between 95 ° and 110 °, preferably 100 °.

The phase angle φ is set at a given static unbalance torque m _u -r _u by reducing the rotational angular frequency Ω of unbalance 5. For example, one runs on the resonance curve 21d in the direction of arrow 35. The area of roller jumping, characterized by the area above the curve 23, must of course be avoided. An intrusion into this area is perceived by the roller operator by a different vibration behavior of his roller 1. In terms of measurement technology, however, as already mentioned above, vibrations occur with half the frequency [and odd multiples] of the orbital frequency Ω of unbalance 5. This unstable [jumping] operation can also be determined by the fact that successive vibration amplitudes of the bandage 3 are of different heights.

To achieve the maximum possible compaction performance, the compaction amplitude of the drum 3 must be chosen as large as possible. In order to achieve a predetermined soil elasticity module E or a predetermined soil rigidity c _B , the required amplitude is set automatically by the computing unit 12 and an actuator 36, as explained below.

The travel speed v of the roller 1 is also set to a uniform compression work per travel unit despite the variable orbital frequency Ω of the unbalance 5. The speed setpoint depends on the type of layer to be compacted. An unbound layer requires a lower travel speed v than a bound layer due to a low orbital frequency Ω. For example, on an unbound layer with a travel speed of v _u = 3 km / h with a rotation frequency f _u = 30 Hz and on a bound layer with a Travel speed of v «= 4.5 km / h with a rotation frequency f _g = 45 Hz.

A floor element 37, as shown in FIG. 5, at a depth z ₀ "sees" a two-band roller 1 passing by at a speed v during the compaction process. Depending on the location of the two drums 3a and 3b rolling over the floor element 37, this sees according to FIG 6 another load peak 39. The two load profiles for the two bandages 3a and 3b, the pulse train 40a coming from the bandage 3a and the pulse train 40b coming from the bandage 3b, can be superposed linearly. Their effects add up. Depending on the vibration amplitude a of the soil compaction system, the center distance d of the two drums 3a and 3b and the depth z ₀ of the soil element 37 under consideration, an overlap zone 41 can be formed, in which load portions act on the soil element 37 from both drums 3a and 3b. The time interval t _{s of} the load components acting on the floor element 37 should be kept constant during operation in order to always achieve the same compression quality. As can be seen from the explanations below, the roller 1 controlled according to the invention is operated with increasing ground rigidity c _B with a higher orbital frequency Ω, which then results in an increased travel speed v. That means that the compression takes place faster and faster.

In contrast to known rollers and known compaction methods (for example WO 95/10664), compaction is now no longer carried out only on a constant shear modulus, but on a predefined, preferably constant ground stiffness c _B and, if necessary, on a predefined, constant elastic modulus E. With the previous rollers and compacting machines, it was always assumed that at least minimal compaction, defined by the soil stiffness c _B or the soil elasticity module E, would be achieved. The large differences between minimum and maximum compression resulting from the known methods result for the known, but undesirable, irregular subsidence and unevenness, for example of road surfaces. These differences are avoided by the invention.

In contrast to this, the method according to the invention compresses, inter alia, to a constant modulus of elasticity E. A constant soil elasticity module E, in contrast to the known soils compacted to a minimum of soil stiffness, results in significantly greater long-term stability. It is emphasized once again that not only is a predetermined soil stiffness c _B , but also a predetermined soil elasticity module E is compressed. For example, a floor 20 of a road structure compacted to a constant soil elasticity module will lower uniformly as it ages as a result of the traffic load and thus retain its flatness for a much longer time than one which is compacted according to the prior art. Road structures compacted according to the known methods become uneven over time due to inhomogeneous compaction, tear on the surface and are then exposed to destruction by traffic and weather influences.

According to the invention, the soil elasticity module E is continuously determined with the roller 1 and the machine parameters are continuously adjusted, whereby care must be taken here that no hollows remain in the soil, i.e. the soil surface 42 is already well compacted. In practice, the exact soil elasticity module E is only of interest at the end of the compaction process. At this point, however, the ground surface (42) is already sufficiently compacted. The soil elastic modulus E results from the following formula [3].

This equation results from a postitulated continuum mechanical consideration of a curved body, which is in contact with an elastic, semi-infinite Chen room.

Since the value of the soil elastic modulus E of interest occurs on both sides of the above equation, its value must be determined with a simple iteration. To start the calculation, the equation value for E

E [MN / m ² ] = 2.3 [1 / m] • c _ß [MN / m] [4]

used. The ground stiffness c _B is determined by the computing unit 12 using the formulas below, since all values are known to it or are set by it.

In load operation [case a)], ie there is no lifting of the bandage 3 (this operating state is given up to amplitudes a / a ₀ = 1), the ground rigidity c _B is calculated by the computing unit 12 using the formula

m _u - r _u - cos (φ) c _B = Ω - [m _d +] [5] a

determined.

If the drum 3 is lifted, which the computing unit 12 registers with the occurrence of angular frequencies with 2Ω, 3Ω, ..., it calculates the ground stiffness c _B using the formula

F (at ä = 0)

in which

F = -m _d • ä + m _u • r _u • Ω ² • cosφ + (m _f + m _d ) 'g [7]

and ^F max _κ = _[8]

(m _f + m _d ) - g

ä is obtained by integrating the value measured with the accelerometer 11, ä is the vertical speed of the drum 5. This is the time-changing drum speed, which, however, should not be confused with the travel speed v. ä = 0, ie a zero speed of the drum 5 is always reached in the upper and lower oscillation reversal point, ä is the value determined with the accelerometer 11. The static unbalance moment m _u -r _u [kg m] in the above formula can be determined from the data of unbalance 5. The determination of the phase angle φ has already been described above. m _d [kg] is known as the weight of the bandage 3 in question. Ω is set as the rotational angular frequency of the drum 3 and is therefore known. The maximum vibration deflection a of the bandage 3 can also be determined.

In formula [3], the transverse contraction number of the substrate is set at μ = 0.25 (it lies between 0.20 and 0.30). L [m] is the width of the bandage 3, (m _f + m _d ) the weight bearing on each bandage 3a or 3b plus the weight of the bandage 3a or 3b concerned, R [m] is the radius of the bandage 3, g [= 10 m / s ² ] the acceleration due to gravity and In the natural logarithm. All values for the automatic determination of the soil stiffness c _B are thus known or can be determined by the computing unit 12, whereby the elasticity module E can also be determined with the computing unit 12.

To derive the above formula [3], it is assumed that two elastic rollers are touched. The first role has an elastic modulus E- ^, a radius R _{j ^} and a transverse contraction number μ _j L. The second role has an elastic modulus E ₂ , a radius R ₂ and a transverse contraction number μ ₂ . Both rolls have the length L. For the surface Pressure p [N / m ² ] between the two rollers then results

4-P p = [l- (4-y ²⁾ / b ^{2] 1/2} [10] 7T Lb

where P is the force acting on the first roller, b is the width of the contact surface (L-b) over which the two rollers touch due to elastic deformation and y is the current coordinate perpendicular to the roller axis with the zero point on the roller axis.

For the transition to a roller compacting a soil (drum), the soil is assumed to be the second roller described above, the radius R ₂ = = then being set here. Furthermore, the elastic modulus E- ^ of the first role is significantly larger than that E _{2 of} the floor. So it applies

E-j_ >>

El -> ∞ can thus be set in relation to E ₂ .

The force P acting on the first roller is a function of time in a soil compacting device. It is not constant over time. The force P is identical to the ground reaction force F in equations [6], [7] and [8]. The time averaging over the force P during one revolution of the drum 3 results

P - dt = (itif + iri _fj ) g [11]

T

It is thus set in equation [10] that P = (m _f + m _d ) -g. Equation [10] solved for b then gives

b [m] = [(16 / τr) V '[12]

E ₂ L μ ₂ and E ₂ are the transverse contraction and the elastic modulus of the floor.

Due to the elasticity of the floor E ₂ , when the force P is applied, the center of the first roller approaches the floor surface. This approximation δ results in

P l-μ ² ₂ δ [m] = • • Θ (b / L) [13]

LE ₂

Since the width of the contact surface (L-b) is significantly smaller than its length L (b << L) applies

2 Θ (b / L) »- • [1.89 + ln (L / b)] π

The following also applies (feather equation)

F = c _B -δ

and thus

FP LE ₂ δ δ (l-μ ² ₂ ) -Θ (b / L)

It follows from this

E _{2 =} α-κ ² 2 ⁾ Θ (b / L) -C _B [15] L

The above value for b is now used

2 1 π ^■ E ₂ • L ³ Θ (b / L) = - - [1, 89 + - In [] [16] π 2 16 (l- / ι ² ₂ ) - R _r (m _f + m _d ) - g

Using equation [16] in equation [15] gives the above equation [3], where R- ^ = R.

For optimal compaction, the soil areas to be compacted must be run over by roller 1 more often. Since it is usually a non-pre-compacted soil, maximum compaction is carried out in a first or subsequent compaction crossing.

The setting of an optimal unbalance angular frequency Ω and an optimal static unbalance torque is explained with reference to FIG. 7, the normalized unbalance angular frequency Ω [Ω / w ₀ ] as the abscissa value and the normalized maximum amplitude a [a / a ₀ ] of the unbalance being analogous to FIG 5 is plotted as the ordinate value. At the start of soil compaction, the unbalance 5 has a minimal distance r _u0

_Rotation axis 7 to [static unbalance _moment m _u • r _u0 ]. Starting from standstill, the orbital frequency Ω of the unbalance 5 is increased to a value Ω ₀ , which lies above the resonance of the above-mentioned soil compaction system. The respective travel speed v of the roller 1 is adapted to the rotational frequency f of the unbalance 5 in accordance with the above statements. The dependence of the amplitude a of the bandage 3 on the orbital frequency Ω takes place according to curve 43a. The resonance of the soil compaction system lies at point 45. This resonance point is exceeded for the tolerance reasons stated above until the phase angle φ between the drum vibration and the unbalance vibration is approximately 100 ° [point 47]. In a next step, the static unbalance _{torque is increased} to r _ul by increasing the radial _distance r _u0 O _u - r _ul ]. By increasing the static unbalance torque at the same unbalance rotation frequency f, the phase angle φ increases to a value greater than 100 °, as can be seen from the distance of the new setting point 50 from the resonance curve 49 (analogously to curve 27 in FIG. 4). It will now be in a next one

Step reduces the orbital frequency of unbalance 5 with a constant static unbalance moment [m _u -ru] from Ω ₀ to Ω- ^ until the phase angle φ is again only 100 ^° . Radia- Distance r _u and orbital frequency Ω are now changed alternately until roller 1 begins to jump. According to the above statements, this "jumping" can be recognized by the occurrence of odd multiples of half the unbalance rotation frequency [crossing curve 52]. The static unbalance torque m _u -r _u is reduced in order to reach the stable curve point 51. The unbalance angular frequency Ω could also be reduced, but this adjustment method is difficult to handle since two values change, namely the angular frequency Ω and the moment of inertia. The machine parameters belonging to curve point 51 define a state in which maximum compression work is performed. Curve 53 in FIG. 7 shows the optimal setting curve, which always ensures a phase angle φ of 100 °.

After the first passes, as long as the soil still behaves plastically, the maximum compaction performance is used. The plastic behavior results from the measured values obtained. In the "plastic range", the floor stiffness c _B can only be determined approximately. Knowing well that the determination of the soil elastic modulus is affected by an error on a still plastic substrate, it is calculated according to the above statements. When about 90% of the required soil elasticity value is reached, the plastic range is exceeded and the control uses the above-mentioned calculation method to set the static unbalance torque m _u -r _u and the unbalance rotation frequency f (unbalance rotation angular frequency Ω) such that a specified soil elasticity module E is achieved. Using the formulas [3] and [5], the computation unit 12 can determine the soil elasticity module E that has already been reached during the compaction process, and then use these values to determine the relevant machine parameters for the further compaction process, such as static unbalance moment m _u - r _u , unbalance frequency f and travel speed v can be set. The setting is made during the procedure. The setting of the travel speed v is can be carried out quickly and easily. However, in order to set the static unbalance torque m _u ■ r _u to a predetermined determined value in the fraction of a second, the procedure followed, for example, is as follows.

Instead of changing the radial distance r _{u of} the unbalanced mass, as explained above, two unbalances 56 and 64 rotating in the same direction can be used, the mutual radial distance of which is set via a planetary gear. If the radial distance is 180 °, the effective total unbalance value is zero. At 0 ^° the unbalance value is maximum. With angle values between 0 ° and 180 °, all intermediate values between zero and maximum unbalanced mass can be set.

The planetary gear 53 shown schematically in FIG. 8 is used to drive two unbalances 56 and 64 rotating in the same direction, the mutual position of which is adjustable for setting the static unbalance torque m _u -r _u . In contrast to the above statements, it is no longer the radial distance r _{u of} a point-like eccentric mass that is set, but the effective unbalanced mass m _u with the same radial distance r _u . The settings according to FIG. 7 are then made starting from [Ω _Q , m _u0 -r _u0 ] in curve point 47 for the following curve points with [Ω ₀ , ^m u _l ' ^r u _θ J instead of [Ω ₀ , m _u -r _ul ] at set point 50, with [Ω _l7 m _ul • r _u0 ] instead of [Ω _] _, ro _u -r _ul ], t ^Ω i ' ^m u ₂ ' ^r u ₀ ^ instead of [Ω-L, m _u ^• r _u2 ] etc. With the planetary gear 53 shown in Figure 8, an unbalance mass changeover is possible in a fraction of a second.

The planetary gear 53 shown in FIG. 8 is driven by a drive 54 via a shaft 55 which acts directly on the balancer 56 without any intermediate gear. A toothed belt pulley 57 is arranged on the shaft 55 and acts on a toothed belt pulley 60 via a toothed belt 59. The toothed belt pulley 60 in turn interacts with a gear part 61. The gear part 61 has three meshing gears 63a, 63b and 63c, wherein the gear 63a is rotatably connected to the toothed belt pulley 60. The axis of the gear 63b can be rotated radially to the axis of rotation of the gear 63a. The angle of rotation is a measure of the radial rotation of the two unbalances 56 and 64 and thus a measure of the effective total unbalanced mass or the effective static unbalanced _moment m _u0 -r _u to m _u3 r _u . On the axis 65 of the gear 63c is a gear 66 which meshes with a gear 69 seated on a hollow shaft 67. The hollow shaft 67 interacts with the second unbalance 64.

Since one of the two unbalances 56 and 66 is driven directly and only the unbalance 64 by the planetary gear 53, this only has to transmit half the torque. The bisector between the centers of gravity of the two unbalances is used as the reference point for determining the phase angle φ 56 and 64.

Instead of circulating both imbalances in the same direction with one and the same rotation frequency Ω, one of the two imbalances can also rotate at twice the rotation frequency by selecting the toothed belt pulleys 57 and 60 and / or the gearwheels 66 and 69 accordingly.

The transmission described above, as shown in FIG. 8, can also be replaced by superimposed transmissions which have the same effect but are constructed differently. Good results have been achieved, for example, with a so-called "harmony drive gearbox" which, with only three components ["Wave Generator", "Circular Spline", "Flexspline"], has high single-stage

Reductions achieved. In this transmission, the "circular spline" is a rigid steel ring with an internal toothing which is in engagement with the external toothing of the "Flexεplines" in the area of the large ellipse axis of the "wave generator". The "Flexspline" is an elastically deformable, thin-walled steel sleeve with an external toothing that has a smaller pitch circle diameter than the "Circular Spline" and thus, for example, two teeth less possesses the entire scope. The "Wave Generator" is an elliptical disc with a mounted thin ring ball bearing that is inserted into the "Flexspine" and deforms it elliptically. During the rotation of the "Wave Generator" the meshing area with the large ellipse axis moves. After rotating the "Wave Generator" by 180 ° there is a relative movement between "Flexspline" and "Circular Spline" around a tooth. After each complete rotation of the "Wave Generator", the "Flexspline" as the output element rotates exactly two teeth opposite to the drive. The mechanical structure using this gear is extremely compact.

If paving material is to be compacted on a construction site, it is advisable to determine or check the rigidity c _{B of} the subsurface by means of a pass before the compaction material is brought in. Of course, the soil elasticity module E can also be determined. If there is already a weak point in the subsurface, the installation goods cannot be compacted to the required extent.

Instead of using rotating unbalances, vertically vibrating unbalances, designed as piston-cylinder units, can also be used. To compress

Bandages are rolled over the floor 20; however, a vibrating plate can also be moved over the floor 20.

The measuring device according to the invention differs from the soil compaction device according to the invention only in that the device acting on the soil and together with it forming an oscillation system does not cause any substantial soil compaction compared to the compaction device of the soil compaction device. This means that the force acting on the floor is reduced during the measurement. The mass of the oscillating force is generally chosen to be smaller during the measurement. The measuring device according to the invention can be used with known compression be assembled to produce an improved soil compaction with these machines.

Claims

claims

1. Method for measuring mechanical data of a compacted or compacted soil with a device (3a, 3b) acting on the soil (20), which together with the soil (20) vibrates as a single vibration system from a computing unit (12) is detected and is excited by an oscillation-stimulating force such that this oscillation system oscillates in resonance or oscillates at a frequency (Ω) exceeding the resonance by a predetermined frequency value determined only by setting stabilities, the value of the oscillation-stimulating force being its periodic frequency (Ω) and their phase angle (φ) for vibration of the vibration system are automatically set by the computing unit (12) in such a way that taking into account the mass (m ^) of the device (3a, 3b) acting on the floor and the one statically loaded on it Weight (ntf) the floor stiffness (c _B ) and / or the elastic modulus (E) of the floor (20 ) is determined.

2. The method according to claim 1, characterized in that to determine the vibration deflection (a) of the vibration system, the movement of the device (3a, 3b) in the direction of the required measurement vector is determined in particular with an accelerometer (11), the phase angle (φ ) is set to preferably between 95 ^° and 110 ° leading and preferably the vibration-stimulating force is generated with an accelerated, in particular rotating mass, the static unbalance moment (m _u r _u ) of which is predefined by the computing unit (12).

Compaction method for achieving an optimal, in particular homogeneous soil compaction (1) using the measuring method according to claim 1 or 2 with a ner on the soil to be compacted (20), a compacting device (3a, 3b) which, together with the bottom (20), is recorded in terms of vibration as a single compression vibration system by a computing unit (12) and is excited by a vibration-stimulating force such that this compression vibration system vibrates in resonance or vibrates at a frequency (Ω) which exceeds the resonance by a predetermined frequency value, which is only determined by setting stabilities, the value of the vibration-stimulating force, its periodic frequency (Ω) and its phase angle (φ) being used Vibration of the compression vibration system can be set automatically by the computing unit (12) in such a way that, taking into account the mass (m ^) of the compression device (3a, 3b) and the weight (m _f ) that statically loads on it, a predetermined ground rigidity (c _B ) is reached.

4. Compression method according to claim 3, characterized in that to determine the vibration deflection (a) of the compression vibration system, the movement of the compression device (3a, 3b) in the direction of the required compression vector is determined in particular with an acceleration esser (11), the phase angle ( φ) is preferably set to be between 95 ^° and 110 ° leading and preferably the vibration-stimulating force is generated with an accelerated, in particular rotating mass, the static unbalance moment (m _u r _u ) of which is predefined by the computing unit (12).

5. Compaction method, in particular according to claim 3 or 4, characterized in that the compaction process is ended as soon as a predetermined elasticity module (E) of the soil (20) is automatically determined by the computing unit (12), the elasticity module (E) during the passage with an iterative calculation is determined in particular by additionally using the soil rigidity (c _B ) and the vibration amplitude (a) of the compression device (3a, 3b) or their acceleration (ä).

6. Compaction method according to one of claims 3 to 5, characterized in that the non-compacted soil material is compacted in a first compaction process, preferably depending on the nature of the soil and the state of compaction, with maximum compaction power limited only by the machine properties, in particular the vibration-stimulating force automatically but only set so high that there is no jumping of the soil compacting device (1) and preferably the jumping of the

Soil compaction device (1) is determined by a frequency analysis of the vibration of the compaction device (3a, 3b) for the occurrence of half a vibration component component to the fundamental vibration and / or by an amplitude comparison of successive vibrations of the compaction device (3a, 3b) up to a predetermined deviation value.

7. Compression method according to one of claims 3 to 6, characterized in that the compression device

(3a, 3b) is driven faster over a soil (20) that has already been compacted to a predetermined value than over soil (20) that is still to be compacted, preferably with reduced vibration-stimulating force, in order to minimize unnecessary passes from the perspective of the compaction process.

8. Measuring device (1) for measuring mechanical data of a compacted or to be compacted soil (20) with a measuring method according to claim 1 or 2 with at least one device (3a, 3b) at least temporarily in contact with the soil (20), at least one a periodic force acting on it in the measuring direction generating, oscillating mass (5), the oscillation frequency (Ω) of which can be set by a drive (54), a measuring element (11), in particular an acceleration sensor (11), which determines the time of the maximum oscillation amplitude (a ₀ ) of the device (3a, 3b) in

Direction of measurement, a sensor (29) which determines the time of the maximum vibration amplitude in the soil compaction direction of the vibrating mass (5), a comparator device (12) which determines the phase distance (φ) of the two vibration maxima, a control unit (12 ), with which the oscillation frequency (Ω) of the oscillating mass (5) can be adjusted via the drive (54) until a predetermined phase distance, preferably a leading phase angle (φ) of the exciting mass oscillation compared to the excited one, with the comparator device (12) Device vibration between 95 ° and 110 ° can be determined, and an arithmetic unit (12) signal-connected to an actuator (36), with which from the data determined with the measuring element (11) and the sensor (29) and mechanical data (m _f , m ^, m ^ -r _y ) of the device (1) a floor stiffness (c _B ) and / or an elastic modulus (E) of the floor (20) can be determined.

9. Measuring device (1) according to claim 8, characterized in that the oscillating mass (5) has at least one rotating unbalance, the static unbalance moment (n ^ -r ^ of an actuating device (53) depending on the with the comparator (12) determined phase distance (φ) is adjustable.

10. Measuring device (1) according to claim 8 or 9, characterized by a frequency analysis device (12), which by the device (3a, 3b) due to the exciting vibration (Ω) of the vibrating mass (5) excited vibration to half vibration frequency components and multiples of the stimulating vibration (Ω) is analyzed and if these vibrational components occur the stimulating Vibration frequency (Ω) increased by the drive (54) and / or the static unbalance torque (BB- _J - ^) of the vibrating mass (5) decreased via an adjusting device (53).

11. Soil compaction device (1) for optimal homogeneous soil compaction with a measuring device according to one of claims 8 to 10 for carrying out a compaction method according to one of claims 3 to 7 with at least one with the soil to be compacted (20) at least temporarily in contact with the compacting device (3a, 3b), at least one vibrating mass (5) acting on it and generating a periodic force in the soil compaction direction, the oscillation frequency (Ω) of which can be adjusted by a drive (54), a measuring element (11), in particular an accelerometer (11), which determines the time of the maximum vibration amplitude (a ₀ ) of the soil compaction device (bandage) (3a, 3b) in the soil compaction direction, a sensor (29) which determines the time of the maximum vibration amplitude in the soil compaction direction of the vibrating mass (5), a comparator device (12) which determines the phase distance (φ) of the be The oscillation maxima are determined by a control unit (12) with which the oscillation frequency (Ω) of the oscillating mass (5) can be set via the drive (54) until a predetermined phase distance, preferably a leading phase angle (φ), is achieved with the comparator device (12). the exciting mass vibration compared to the excited soil compacting device vibration can be determined between 95 ° and 110 °, and a computing unit (12) which is signal-connected to an actuator (36) and which calculates with the measuring element (11) and the sensor (29) Data as well as mechanical data (ni _f , m ^, m _u -r _u ) of the soil compaction device (1) a soil stiffness (c _B ) of the just compacted soil (20) can be determined, and in particular the frequency (Ω) and the periodic force the actuary can be adjusted via (36) to achieve a specified floor stiffness (c _B ).

12. The device (1) according to claim 11, characterized in that the oscillating mass (5) has at least one rotating unbalance, the static unbalance moment (n ^ -r ^ _j ) of an actuating device (53) depending on the with the comparator device ( 12) determined phase distance (φ) is adjustable.

13. The device (1) according to claim 11 or 12, characterized by a frequency analysis device (12) which the vibration excited by the compression device (3a, 3b) as a result of the exciting vibration (Ω) of the vibrating mass (5) to half the vibration frequency components and multiples of the stimulating oscillation (Ω) are analyzed and, if these oscillation components occur, the excitation oscillation frequency (Ω) is increased by the drive (54) and / or the static unbalance moment (m _u -r _u ) of the oscillating mass (5) via an adjusting device ( 53) decreased.

14. The device (1) according to any one of claims 11 to 13, characterized in that the oscillating mass (5) consists of two partial masses (56, 64) rotating in the same direction, which can be driven via a planetary gear (53) and their position adjustable relative to one another are.