FR2626210A1 - Method for metering water for manufacturing concrete and device for implementation thereof - Google Patents

Abstract

The subject of the invention relates to the technical sector of installations or methods for collecting or dispensing water. The device implemented according to the invention comprises, in combination: - at least one means A which can differentiate between a displayed water target corresponding to a given program, and the value of water measured at the end of dry mixing, - at least one means B capable of managing the metering and mixing cycle, - at least one metering means C capable of measuring the quantity of water to be added, - calibrated means D for conversion as a function of each type of concrete, capable of establishing the theoretical impedance curve as a function of the water content.

Description

 Method for determining the water for the manufacture of the concrete and the device for implementing it

The subject of the invention relates to the technical sector of facilities or processes for collecting or distributing water
Concrete, which is a mixture of wet aggregates and cement, is known to behave as an electrical conductor whose resistance or impedance is related to the water content of that mixture. The evolution of impedance as a function of water content describes a decreasing exponential curve. Impedance is measured by appropriate probes.

 However, to obtain a concrete with max muma qualities it is very important to get closer to the theoretical curve.

The dosing devices proposed to date are not capable of fulfilling this condition, particularly in the case of rapid mixing. The curves recorded are linear. Generally, we proceed according to two principles
According to the first principle, a resistivity measurement is carried out and from a certain resistance value, water is added to reduce this resistance. When the resistivity reaches a certain threshold, the flow rate of the water supply is gradually reduced until the desired value is reached.

 - According to the second principle. the resistivity is measured and, from an optimum result, the quantity of water required is calculated which is sent as quickly as possible.

 While these principles are more or less satisfactory in the case of slow kneading, there are significant problems with rapid kneading which is most frequently sought after.

Indeed, many disturbing factors intervene and it is important to take into account to get an optimum dosage depending on the type of concrete desired. The main factors on which the impedance of concrete depends are the following:
- factors related to the principle of measurement, namely mainly the influence of the characteristics of the raw materials, dosing and measurement characteristics, the temperature of the mixture,
- factors related to the modalities of the measurement namely mainly influence of the volume of concrete involved, the condition of the probes, the passage of mixing devices near the probes, measurement times,
- factors related to the transmission and conditioning of the measurement, ie influence of the type of transmission, interference and line impedance, component variations, circuit design,
- factors related to the processing of the measurement and the control, namely essentially the influence of the treatment mode, the water addition technique and the water addition technology.

 To solve the problem, the aim of the invention is to set the. point a process and a device able to treat several types of concrete by the same mixer according to several programs corresponding to each type by conoeing the optimum amount of water to be added to obtain a concrete whose impedance according to the water content describes a curve close to the theoretical curve.

The problem is solved by a specific method of assay which is remarkable by the following steps
- we introduce cement and aggregates
- Dry mixing is carried out for an adjustable period,
the impedance of the concrete is measured when the dry kneading operation is completed,
the impedance read at this instant is converted into the value of mixing water,
the volume of water that must be added to the water value measured at the end of the dry kneading is determined,
this value is stored in memory
a quantity of water is added in a single operation and this quantity is measured.

In addition, to solve the problem of tracing the curve and its reproduction, the method is remarkable by the following steps
- Dry mixing is carried out for a constant time, until the resistivity of the mixture is stable,
the dry mixing time is modified and the value of the resistivity of the mixture is noted
- Water is added until the concrete is optimum, the amount of water added in liters corresponding to a set water value
the aggregates are wetted and a second dry kneading is carried out by introducing cement and the value of the resistivity which has decreased, is noted,
- we add water until the concrete is optimal and we note the amount of water added,
water is again added to the aggregates alone and a third dry kneading is carried out for a constant period; the value of the resistivity is measured,
- The mixing is completed by noting the amount of water allowed.

For restitution
- read the value of the resistivity>
one acts on a calibration means so that the resistivity decreases if the value read increases,
the calibration means are set to the indication of the resistivity corresponding to the starting point (A) of the curve drawn,
the water value corresponding to the previously drawn curve is set,
the calibration means are adjusted until a visual indication element illuminates without illuminating it,
the conversion means is acted on to obtain the desired slope corresponding to another point (B),
- we return alternately to the points (A) and (B) to perfect the settings so that the right passes through the points,
- We go back to the point (B) and note the value displayed, then the calibration means is adjusted again until a means of visual indication comes on and we act as previously on the conversion means so that the two points (B) and (B1) contain the curve plotted previously,
- proceed as indicated to identify the other points of the curve.

For the implementation of this method, the device comprises, in combination
at least one means capable of differentiating between a displayed water setpoint corresponding to a given program and the water value measured at the end of dry mixing,
at least one means capable of managing the dosing and kneading cycle,
at least one counting means capable of measuring the quantity of water to be added,
- Conversion means calibrated according to each type of concrete and able to establish the theoretical curve of the impedance as a function of the water content.

The invention is described below in more detail with the aid of the accompanying drawings in which
- Figure 1 shows the block diagram of the device!
FIG. 2 schematically shows the front face of a device,
FIG. 3 shows the plot of the resistivity curve (p) as a function of the quantity of water,
- Figure 4 shows the reconstruction of the curve.

According to the invention, to ensure an accurate dosage of
water in order to obtain a concrete whose impedance curve re
it is close to the theoretical curve, it was designed and put
to the point a specific process. For this purpose, after introduction
cement and aggregates in a mixing device of the type
known and suitable, dry mixing is carried out during a
adjustable duration depending on the type of concrete.

 When the dry kneading operation is complete, the impedance of the concrete is measured by means of probes connected to supply and measurement circuits. The impedance read at this time is converted to a mix water value.

 The volume of water that is to be added to the water value measured at the end of dry mixing is then determined and this value is stored. The quantity of water to be added is sent at one time and this quantity is measured.

 In the example illustrated, the measuring and dosing method is essentially implemented by the combination of several electronic cards or modules, each slaved to control, measurement and control means. These electronic modules include an analog card (fui), a logic board (B), a counting card (C) and several conversion cards (D).

 The card (A) is shaped to establish the difference between the displayed water setpoint (vc) by a potentiometer corresponding to a given program, and the water value measured at the end of dry mixing. After making the conversion between the resistance measurement and the actual humidity, an operational amplifier makes the difference between the water setpoint and the value of this actual humidity. This difference gives the amount of water to be added and is stored in a capacitor for example.

 A pulse water meter is taken into account by the counting card and converts the state of a sensor into a continuous analog voltage by means of a converter. This voltage is sent in the board (A) so that when the equality between the measurement and the setpoint is reached a valve solenoid cut off the water supply.

 The logic board (B) is shaped to handle the dosing and mixing cycle. Starting from a cycle start signal delivered by a PLC or manually, the board (B) triggers the mixing of the dry aggregates, in particular by sequentially switching on several memories servocontrolled by timing systems.

 For this purpose, a first memory is armed corresponding to a dry mixing time managed by an adjustable time delay being able to ensure the reset of the water meter and the storage of the measurement of the resistivity. A second memory is engaged, cutting the first memory, to control the opening of the water inlet valve and to release the count. This memory takes into account the value of the resistivity stored in the capacitor. When the amount of water is reached, a third memory intervenes (the first and second memories fall back) and cuts off the water. A time delay is then triggered and delivers an end of cycle pulse which is taken into account by the automatism of the central unit for setting the mixing time.

 The counting card (C) is arranged with means capable of ensuring the measurement of the amount of water added to the mixer. For this purpose, the card (C) implements TTL counters of known type with digital-analog converter.

 The conversion maps (D) are calibrated according to each type of concrete being able to restore the theoretical curve of the impedance as a function of the water content. These conversion cards are essential to solve the problem and reach the goal.

 this effect, the map (D) measures at the end of dry mixing, the resistance (po) aggregates and converts this value into a value (Eo) corresponding to a certain amount of water.

 The difference between the value (El) of the quantity of water determined by the potentiometer subject to the analog card (4) and the value (Eo) corresponds to the quantity of water to be added.

In addition, each type of concrete according to the various aggregates that compose it, corresponds to a different impedance curve. It is therefore appropriate to calibrate each conversion card (D) according to a type of aggregate. For this, it is necessary to trace the impedance curve by working in manual mode
For this purpose several kneading is carried out by modifying each time the value of the resistance (po) of the aggregates during the dry kneading. We then add a certain amount of water to obtain a concrete of good quality. It is therefore sufficient, each time, to raise the value (po) and the value of the quan quante water added matching by performing as indicated, the difference (E1) - (Eo). It is thus possible to obtain several points for drawing the impedance curve corresponding to the type of aggregate. On the ordinate, we enter the signal (Po) that is converted into voltages being a reminder that when the voltage increases (po) decreases.

 The detected voltage will trigger a number of comparators whose number is determined to have a sufficiently precise resolution. It appears that a dozen comparator is satifaisante. These different comparators, at well-defined levels, will switch each by means of a field effect transistor, increasing gains as the voltage corresponding to (increases or decreases as and when the water is added in. The gain is adjusted to conform to the particular curve of each concrete.

 After calibration of the card according to the type of concrete desired one can carry out an automatic mixing.

The various cards as described are controlled by control, control and measurement means namely essentially
- a multi-position manual switch (1) capable of selecting the programs whose number corresponds to the desired type of concrete
setpoint potentiometers (2) corresponding to the different programs, each potentiometer (2) acting directly on the quantity of water
- A manual-automatic switch (3) shaped to ensure the selection of programs, either by an external controller or by the multi-position manual switch,
a measurement switch (4) for the calibration of each of the conversion cards,
display members (5) (6) () indicating in particular the impedance of the concrete and the quantity of water added,
a push button for starting the cycle (7).

 Note that the probe (s) are galvanically isolated so as not to alter the measurement.

 Each of the cards, in particular the conversion cards (D), are subject to means for visual indication of the LED (light emitting diode) type. Hereinafter described> with the aid of numerical examples with reference to FIGS. 3 and 4, the method is the basis of the invention and able to reproduce the theoretical plot of the curve of the resistivity as a function of the amount of water and trace this curve point by point.

 To plot the curve of the resistivity (p) = f (water) corresponding to a type of concrete (Figure 3), one works in manual mode and makes several measurements.

$ First measure
the mixer or other aggregates and cement are loaded according to the desired type of concrete,
the dry kneading is carried out until the resistivity of the dry mixture is stable, the duration of the dry kneading being constant: this parameter is included in the curve f (water),
the dry mixing time is modified, which makes this curve evolve.

the value (p) of the mixture is then noted and the water is added manually until the concrete is optimum, the assessment being carried out by experiment,
- The amount of water added in liters corresponds to the value (Vc) setpoint. For example, 50 liters of water correspond to 1000 graduations. Suppose that we added 32 1 which entrains (Vc) 640 graduations.

* Second measure:
the aggregates are wetted and a second dry kneading is carried out by introducing the cement as before. The resistivity read decreases, we read (pl). We add the water in manual to obtain a perfect concrete as before and we note the amount added, ie: 21 1 for example of po E 1 corresponds to 32 - 21 = it 1.

$ Third measure
- we add more water in the aggregates alone and we do a third dry mixing (constant mixing time)!
the resistivity (-p) is measured,
- The mixing is completed by noting the amount of water allowed for example (p2) = 1060 which gives an added amount of water of 4 1 where the point (E2). Of course, it is desirable to obtain many points to be able to draw the curve of a concrete type, passing through the points measured.

For the reconstruction of the curve p = f (water) from a conversion card, we go into calibration mode and proceed as follows (FIG. 4)
the value of the resistivity is read, the push button (7) not being lit,
- It acts on the calibration potentiometer (4); the resistivity decreases if the value read increases,
- the luminescent dipods (LEDs) of the 4 conversion cards (D) light up according to the value of the rxsisti- vitre,
the number of illuminated dipods increases when the reading of the resistivity increases,
the calibration potentiometer (4) is set to the resistivity indication = 300, for example corresponding to point (A),
by means of the potentiometer (2) of the conversion card chosen, the water value corresponding to the curve drawn previously is set, ie on the example chosen;
- 150 graduations by reading the value Water,
- the calibration potentiometer (4) is adjusted until the LED (LED 12) comes on but does not illuminate,
- we act on the conversion card to get the desired slope,
- we get the point (B),
- we return alternately to the points (A) and (B) to complete the previous settings until the right passes through the points (A) and (B> of the curve
- Then we go back to point (B): diode (LED 12) unlit and note the value displayed,
the potentiometer is adjusted to turn on the diode (LED 12) and the new value (B1) is noted by means of the corresponding potentiometer and the latter is adjusted so that the two points (B) and (B1) contain the curve drawn earlier,
- then proceed as indicated for all other points of the curve (C-C1, D-D1, E-E1, F-F1, G-G1, H-H1, J
J1, K-K1, L-L1, M-M1) so as to obtain an adjustment according to FIG.

Claims (1)

REVELATIONS - add a certain amount of water in one operation and measure that amount. this value is stored in memory, the volume of water which must be added to the measured water value at the end of dry mixing is determined, the impedance read at this instant is converted into a value of mixing water, - the impedance of the concrete is measured when the dry kneading operation is finished, - dry mixing is carried out for an adjustable period, - cement and aggregates are introduced, - 1 - Method for the determination of water for the manufacture of concrete, characterized by the following steps  - Dry mixing is carried out for a constant time, until the resistivity of the mixture is stable.  - 9 - A method according to claim 1, characterized in that to reproduce the curve of the resistivity as a function of the amount of water, after putting the aggregates and cement in correspondence with the desired type of concrete  - We finish the mixing, noting the amount of water allowed.  water is again added to the aggregates alone and a third dry kneading is carried out for a constant period; the value of the resistivity is measured,  - we add water until the concrete is optimal and we note the amount of water added,  the aggregates are wetted and a second dry kneading is carried out by introducing cement and the value of the resistivity, which has decreased, is noted,  water is added until the concrete is optimum, the quantity of water added in liters corresponding to a set water value,  the dry mixing time is modified and the value of the resistivity of the mixture is recorded,  - proceed as indicated to identify the other points of the curve.  - We go back to the point (B) and note the displayed value (B1), then reattempt the calibration means until a means of visual indication comes on and we act as previously on the conversion means so that the two points (B) and (B1) contain the curve plotted previously,  - we return alternately to the points (A) and (B) to perfect the settings so that the right passes through the points,  the conversion means is acted on to obtain the desired slope corresponding to another point (B),  the calibration means are adjusted until a visual indication element lights up without, however, illuminating it!  the water value corresponding to the previously drawn curve is set,  the calibration means are set to the indication of the resistivity corresponding to the starting point (4) of the curve drawn,  one acts on a calibration means so that the resistivity decreases if the value read increases,  the value of the resistivity is read, - 3 - Process according to any one of claims 1 and characterized in that for the restitution of the curve from a conversion means, one proceeds as follows  - Conversion means (D) calibrated according to each type of concrete and able to establish the theoretical curve of the impedance as a function of the water content.  at least one counting means (C) able to measure the quantity of water to be added,  at least one means (B) capable of managing the dosing and kneading cycle,  at least one means (A) capable of differentiating between a displayed water setpoint corresponding to a given program and the water value measured at the end of dry mixing, - 4 - Device for implementing the method according to any one of claims 1, 2 and 3, characterized in that it comprises, in combination: - 5 - Device according to claim 4, characterized in that the means (A) are shaped to establish the difference between the displayed water setpoint corresponding to a given program and the water value measured at the end of mixing at dry and memorize this difference. - 6 - Device according to claims 4 and 5, characterized in that the means or (B) are shaped to ensure, from a cycle start issued manually or by a PLC, triggering the mixing of aggregates to dry according to the memory value.  - a start button cycle.  display elements (5) indicating in particular the impedance of the concrete and the quantity of water added,  a measurement switch (4) for the calibration of each of the conversion cards,  - a manual-automatic switch () configured to ensure program selection !, either by an external controller or by the multi-position manual switch  setpoint potentiometers (2) corresponding to the different programs, each potentiometer (2) acting directly on the quantity of water, - 7 - Device according to claim 4, characterized in that each means CD> comprises in particular a plurality of organs adapted to ensure each at specific levels, increasing gains as and the hove that the voltage corresponding to the value of their the reactivity of the aggregates increases or decreases as water is added, - 8 - Device according to claims 4 to 7, characterized in that the means (A) (B) (C) and (D) are subject to control and control devices in particular, a manual switch t1) at several positions able to select the programs whose number corresponds to the desired type of concrete,