AU1945183A - Method and apparatus for measuring and controlling the volumetric weight of an expanded particulate material - Google Patents

Description

METHOD AND APPARATUS FOR MEASURING AND CONTROLLING ' THE VOLUMETRIC WEIGHT OF AN EXPANDED PARTICULATE ATERIAL^'

The present invention relates to method and apparatus for measuring and controlling the volu¬ metric weight of an expanded particulate material.

When products including expanded plastic material are being manufactured it is essential considering economy as well as quality that the plastic material has a correct volumetric weight, that is that the material has been allowed to expand to a predetermined degree, because a volumetric weight which is too high means higher production costs, and a volumetric weight which is too low, results in a bad product. Therefore, it is necessary to follow up carefully the volumetric weight of expanded plastic material which is used in product manufacture.

The manufacture of insulating slabs of expanded polystyrene is one example of a product for which it is very important to follow up carefully the volumetric weight of the plastic material included therein. Said product is standardized and it is required for example for an insulating slab which should have nominally a volumetric weight of 15 kg/m³ that the volumetric weight is within the range from 14.5 to 15.5 kg/m³. The basic material is granulated poly¬ styrene having a volumetric weight of 600 to 700 kg/m , an this material is pre-expanded in one or more stages by a continuous or discontinuous process to a volumetric weight of 15 to 20 kg/m³ before it is introduced into the machine for manufacturing the slabs of expanded polystyrene wherein further expansion of the pre-expanded material takes place in order to sinter together^" the material so as to form homogeneous

OMPI ^« WIPO blocks or. slabs. When no accurate control of the volumetric weight is applied one is inclined to main¬ tain said weight in the center of the volumetric weight range established by the prescribed standard so as to be on the safe side. However, when an accurate control is applied the volumetric weight can be maintained closer to the lower limit, which implies a reduced consumption of the basic material and thus a reduction of costs, which is not unimportant if the manufacture of large quantities is concerned. At the same time there will be obtained, without doubt, an acceptable product, thus less scrapping and fewer complaints.

By the method according to the invention which has obtained the characteristics of claim 1 and is well suited to be integrated with existing manu¬ facture processes, said accurate control of the volumetric weight of the expanded material is made possible.

For practising the method the invention also relates to an apparatus according to claim 8.

The invention will be explained in more detail below, applied to the pre-expansion of polystyrene material , reference being made to the accompanying drawings which disclose an illustrative apparatus for practising the method of the invention.

In the drawings

FIG 1 is a diagrammatic view of the apparatus;

FIG. 2 is an enlarged side view of a weigher tray included in the apparatus;

FIG. 3 is a plan view of the weigher tray in FIG. 2; and

FIG. 4 is a diagram showing variations of the volumetric weight over the time when the control according to the invention is applied.

OMPI With reference to FIG. 1 a polystyrene granulate which contains a foaming agent, for example pentane, and may have a polymetric weight of 600 to 700 kg/m³, is stored in a-silo 10 from which the granulate can be discharged by means of a screw conveyor 11 so as to be supplied to an expansion chamber 12. The screw conveyor is driven by a drive unit 13 which allows the rotary speed of the screw conveyor to be set at different values. In the expansion chamber the material enters on top of a perforated bottom 14 below which there is provided an inlet 15 for steam while the expansion chamber at the top thereof has an outlet 16 for the material which has been expanded in the chamber. This outlet opens into a shaft 17. The shaft 17 contains weighing equipment which is shown in more detail in FIGS 2 and 3. Said equipment comprises a weigher tray 18 which can have a volume of for example 20 liters and is supported in a manner not shown in detail here, by a load cell in a frame 19 which is mounted over chock absorbers in the shaft 17. The load cell is not shown in detail because it can be mounted in a manner common¬ ly known and applied in the weighing technique, but the connection for receiving the signal from the load cell is indicated at 20. The bottom of the weigher tray consists of two pivotable bottom doors 21 which can be pivoted between a horizontal closed position and a swung down opened position which is indicateds_.by dash lines in FIG. 2. Furthermore, there is provided above the weigher tray a deflector which consists of a plate 22 pivoted at the upper edge thereof, and a plate 23 mounted for plane parallel displacement in relation to the plate 22, said deflector being inoperative in the positon shown by solid lines in FIG. 2, but can be adjusted

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. A Sλ>- WIPO J C to an operative position which is shown by dash lines in FIG. 2. The operation of the bottom doors between closed and opened positions and the operation of the deflector between operative and inoperative positions preferably is accomplished by means of pneumatic cylinders which are not shown here, how¬ ever, because the application of such cylinders can easily be arranged by the man skilled in the art without_, detailed instructions. When the deflector is in the inoperative position and the bottom doors are in closed position, the weigher tray 18 receives material which has been expanded in the expansion chamber 12 and is delivered therefrom through the outlet 16. When the tray is full , the deflector is adjusted to the operative position, material at the same time being wiped off along the upper edge of the weigher tray. Then, when the deflector has reached the operative position, it prevents expanded material which is being supplied to the shaft, from falling down into the weigher tray such that the material will instead fall down laterally of the weigher tray. Below the shaft there is provided a so-called fluidized bed 24 for the reception of the material falling down through the shaft, material falling down laterally of the weigher tray as well as material which has been collected in the weigher tray and after having been weighed is discharged therefrom by the bottom doors being opened. In the fluidizedXbed the expanded material shall be dried and cooled then to be stored and used for the manu¬ facture of for example insulating slabs of expanded polystyrene.

In the weigher tray 18 there is arranged a humidity meter 25, and in the expansion chamber 12 there is arranged a temperature sensor 26 located above the perforated, bottom 14 spaced therefrom to ' measure the temperature in the expansion zone. These two transducers together with the load cell 20 are connected to a -microcomputer 27 as has been indicated by dot-and-dash lines in FIG. 1. The computer is connected to a printer 28 and also to the drive unit 13 of the screw conveyor 11 as has been indicated by dash lines in FIG. 1 , so as to control by the output signals thereof the printer and the drive unit. Said output signals are dependent of the processing of data supplied, inter alia the signals from the transducers, which takes place in the micro¬ computer according to the program integrated there¬ w th.

As the polystyrene granulate is fed from the silo 10 into the expansion chamber 12 by means of the screw conveyor 11 the polystyrene is expanded in the expansion chamber by be.ing h-eated with steam supplied at 15 and passing through the perforated bottom 14. The expanded polystyrene material raises in the expansion chamber during the expansion, the volumetric weight thereof being reduced from 600 - 700 kg/m³ to for example 15 - 20 kg/m³. The period during which the material stays in the expansion chamber is dependent of the desired final volumetric weight; in the example given herein a period of 3 - 6 minutes may be expected. The expanded material passes through the outlet 16 at the upper end of the expansiorivchamber into the shaft 17 and falls down through the shaft. Once every minute a predetermined quantity of the expanded polystyrene is weighed in the weigher tray 18, namely 20 liters as previously mentioned, by the material falling down being collect¬ ed in the weigher tray when the deflector 22, 23 thereof is inoperative. When the tray is full , the deflector is adjusted to the operative position. The ^* material received by the weigher tray then is weighed at level measure, the signal of the load cell 20, representing the weight M of the quantity measured, being supplied to the computer together with a signal from the humidity meter 25, which represents the moisture content F of the material that has been weighed. Then the bottom doors 21 are opened and the weighed material is dumped onto the fluidized bed 24 wherein this material together with such expanded material as have passed laterally of the weigher tray during the weighing, is allowed to dry and cool before it is transferred to a storage wherein the material is allowed to stay for a pre- determined period in order to allow air to diffuse into the cells before the material is used in the manufacture of insulating slabs.

The operations described for the adjustment of the deflector 22, 23 and the bottom doors 21 can be controlled by means of a timer or from the micro¬ computer 27.

In the microcomputer the signals supplied are processed for the calculation of the actual volumetric weight at the prevailing moisture content and are compared with a programmed adjustable nominal value of the volumetric weight. At the same time the temperature in the expansion zone is registered. Said comparison can be performed either by the absolute differences between the actual value and the nominal value of the volume weight being established or by the change tendency of the actual value (increasing or decreasing) being established. It is preferred to use said latter type of measurement, derivative measurement, and in that case two points of measuring following one after the other, are required. If the

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OMPI . WIPO , measurement indicates an increasing volumetric weight, the computer 27 supplies a signal to the drive unit 13 of the screw conveyor 11 for decreasing the speed thereof and thus decreasing the supply of material per unit of time such that the raw material supplied to the expansion chamber 12 will have a longer duration of stay in the expansion chamber and thus will be able to expand more, which means a lower volumetric weight. However, if the measurement indicates a decreasing volumetric weight, the microcomputer will supply a signal to the drive unit of the screw conveyor, by which the supply of raw material will be increased. Since a change of the rate at which the granulate is supplied to the expansion chamber effects a change of the volumetric weight of the expanded material with some delay, it is suitable to allow a predeter¬ mined period from the time at which a change of the supply rate is called for by the microcomputer, to the time of the next change, and for this reason it is suitable after two measurements following one on the other, which initiate an adjustment signal from the microcomputer to the drive unit 13 of the screw conveyor 11, to allow a predetermined number of measurements without any steps being taken, before a further adjustment signal is supplied to the drive unit.

The actual value of the expanded polystyrene material will vary about the nominal value set in the microcomputer. This is illustrated in FIG. 4 where the vertical axis indicates the time and the horizontal axis indicates the value of the volumetric weight. From the time t₀ to the time t-_j the actual value of the volumetric weight represented by the curve 29, has varied about the nominal value B set, which is represented by the horizontal axis B in

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WΪPO FIG. 4. As will be seen variations have taken place upwards and downwards in relation to the nominal value set, said variations being maintained, however, within the desired limits due to the application of the control proposed according to the invention. However, the average value of the volumetric weight of the product produced will be dependent of how long and how much the volumetric weight has been above and be¬ low, respectively, the nominal value set. Considering the production technique it is desired that the average value of the volumetric weight of the expanded polystyrene material produced is the same from one day to the other and equals the nominal value set such that there is obtained a final product wherein the expanded polystyrene material is included, which is of uniform quality and satisfies an estab¬ lished standard. In order that this shall be achieved the following procedure is followed. The deviations- from the nominal value B set are integrated in the microcomputer over the period tg - t-. and the average value of the volumetric weight for this period is calculated in the microcomputer, which can be accomplished without the necessity of using_. co plicat- ed programs. Then, a modified nominal value is calculated in the microcomputer, which should be used for the control during the following period, that is from the time t-j to the time t in order to keep the production on the desired average value (the nominal value B) of the volumetric weight. If it is assumed that this calculation produces the nominal value B' , the continued control takes place with reference to this nominal value from the time t-. to t . The control during this period will of course produce an average value with some deviation from the nominal value B' modified in the computer, in the same manner as during the proceeding period. Therefore, the control then continues in the same manner during the following period, a modified nominal value B' being set in the computer in order to obtain over the total of the periods a volumetric weight which sub¬ stantially equals the nominal value B set. The intervals tg - t-. and t-t - t2 etc. can be chosen to be for example half an hour to one hour.

Over the computer 27 the measured and calculated values of the quantities measured and of the volu¬ metric weight calculated may be printed at desired intervals on the printer 28 where also the times as well as other data may be given, which have reference to the pre-expansion and the material used.

The method of the invention can be practised by using other apparatus than that described herein. However, the apparatus described has been found to be well suited for practising the invention.

Claims (8)

1. Method for measuring and controlling the volumetric weight of an expanded particulate material, c h a r a c t e r i z e d by the steps of measuring the moisture content (F) and the volumetric weight

(M) of the expanded material, comparing the measured volumetric weight with a nominal value (B-,) of the volumetric weight at the measured moisture content, and controlling the expansion of the material in dependence of the comparison.

2. Method as claimed in claim 1 , c h a r a c - t e r i z e d in that the comparison is performed by derivative measurement.

3. Method as claimed in claim 1 or 2, c h a - r a c t e r i z e d in that the measurement is performed at predetermined intervals.

4. Method as claimed in claim 3, c h a r a c ¬ t e r i z e d in that the control is performed at times which are spaced apart a predetermined number of measurement intervals.

5. Method as claimed in any of claims 1 to 4, c h a r a c t e r i z e d in that an operative quantity affecting the expansion of the material is controlled in dependence of the measured value of the volumetric weight.

6. Method as claimed in claim 5, c h a r a c ¬ t e r i z e d in that the controlled operative quantity comprises the amount of raw material to be expanded, which is supplied per unit of time.

7. Method as claimed in any of claims 1 to 6, c h a r a c t e r z e d in that existing deviations from the nominal value (B) are integrated over a period (tg - t-_j), that the average value of the volumetric weight is calculated, and that the volumetric weight is controlled in accordance with a modified nominal value (B¹) during a follow¬ ing period (t-, - t₂) to provide an average value over the added periods, which substantially equals the predetermined nominal value (B) set.

8. Apparatus for practising the method as claimed in any of claims 1 to 7 comprising an expansion cham¬ ber (12) and means (11 , 15) for the supply of raw material to be expanded, to the expansion chamber, c h a r a c t e i z e d by means (18, 25) for measuring the volumetric weight (M) and the moisture content (F) of the expanded material and supplying signals which represent the measured values obtained, a microcomputer (27) receiving the signals supplied and programmed for comparing the volumetric weight as measured with a nominal value of the volumetric weight and the prevailing moisture content of the expanded material and supplying a signal in dependence of the comparison made, for the control of said means (11 , 13) for the supply of the raw material , to increase or decrease the amount of raw material supplied per unit of time.