EP4010293A1

EP4010293A1 - Expanded granular material consisting of mineral material

Info

Publication number: EP4010293A1
Application number: EP20775638.8A
Authority: EP
Inventors: Hartmut Kremer; Julian Neubacher
Original assignee: Binder and Co AG
Current assignee: Omya International AG
Priority date: 2019-09-23
Filing date: 2020-09-23
Publication date: 2022-06-15
Also published as: US20220340489A1; MX2022001917A; CA3153978A1; IL291411A; WO2021058556A1; EP3795548A1

Abstract

The invention relates to a method for producing an expanded granular material from a sand grain-like mineral material having a bound blowing agent, for example for producing an expanded granular material from perlite sand. The sand grain-like mineral material is introduced into a feed opening at one end of a furnace shaft, conveyed along a thermal treatment section in a conveying direction, preferably by force of gravity, and heated to a critical temperature while being conveyed through the thermal treatment section, wherein the sand grain-like mineral material plasticizes starting at said temperature and begins to expand as a result of the blowing agent, and the expanded granular material is discharged at the other end of the furnace shaft. The aim of the invention is to improve the versatility of the expanded granular material. According to the invention, this is achieved in that the sand grain-like mineral material is heated to a second temperature above the critical temperature after being heated to the critical temperature, said second temperature lying below a third temperature at which the surface of the expanded granular material bursts, and in that the second temperature is selected on the basis of a desired density of the expanded granular material such that a part of the blowing agent remains bound in the granular material.

Description

PANDED GRANULES MADE OF MINERAL MATERIAL

FIELD OF THE INVENTION

The invention relates to a method for producing an expanded granulate from sand-grain-shaped, mineral material which has a bound propellant, for example an expanded granulate made of pearlite sand, the sand-grain-shaped, mineral material being introduced into a feed opening at one end of a furnace shaft, along in a conveying direction a heat treatment section, preferably by gravity, is conveyed while being conveyed through the heat treatment section to a critical temperature above which the sand-grain-shaped, mineral material becomes plastic and begins to expand due to the blowing agent and the expanded granules are discharged at another end of the furnace shaft becomes.

The invention further relates to expanded granules made of sand-grained mineral material, for example expanded granules made of pearlite sand, and the use of the expanded granules as a mineral filler in a bitumen product.

STATE OF THE ART

In the construction industry, lightweight materials are in great demand as starting materials for various applications such as insulation technology and the finished plastering industry. The lightweight materials are basically divided into petroleum-based and mineral materials.

Petroleum-based materials are characterized by a well-researched manufacturing process, but they have the disadvantage of being flammable. In contrast, mineral materials, which are mainly (crystal) water-containing rocks, such as perlite, obsidian, etc., in granulate form, are not flammable. However, research into the manufacturing process has been significantly poorer than that of petroleum-based materials. Especially with regard to the achievable qualities, the manufacturing process still seems to have a lot of development potential.

Furnaces in which hot combustion air is blown from bottom to top through a vertically arranged pipe have long been known from the prior art. The sand grain-shaped, mineral material to be expanded is heated in the hot exhaust gas in countercurrent well above a critical temperature, which is usually between 750 ° C and 800 ° C, in rare cases above 800 ° C, above which the sand-grain-shaped, mineral material becomes plastic and the water bound in the sand-grain-shaped, mineral material evaporates. The evaporation process is accompanied by the bloating of the grain of sand, mineral material.

The major disadvantage of these ovens is that the expansion process of the sand-grain-shaped, mineral material is largely uncontrolled - that is, the sand-grain-shaped, mineral material is heated very quickly and well above the critical temperature, so that the surface of the expanded granulate bursts. This creates an open-line, very light, fragile, but also highly hygroscopic granulate. Wherever this open-line expanded granulate is mixed with other components to form a composite material, abrasion occurs, which reduces the volume and in particular the cavity volume of the open-line expanded granulate and thus the desired relieving and insulating effect. Especially in insulation technology and in the finished plastering industry, the strongly hygroscopic effect of the expanded granulate also proves to be particularly negative, as it attracts and stores moisture. In order to counteract hygroscopy, subsequent impregnation with silicone is necessary. This however, means an expensive, additional process step combined with the disadvantage of the flammability of silicone from approx.

In order to prevent the above-mentioned disadvantages, EP 2697181 B1 proposes a method for the expansion of sand-grain-shaped, mineral material with which it can be ensured that the expanded granulate has a largely closed-cell surface, so that there is little or no hygroscopicity having.

The method described there makes use of the finding that the swelling process is an isenthalpic process. The cooling of the granulate associated with the isenthalpic expansion process is detected and the temperature is reduced in a targeted manner along a remaining fall path of the expanded granulate so that there is no further expansion process.

Although the granulate expanded by this process is of high quality and non-hygroscopic properties, certain areas of application are still excluded due to unsuitable physical properties.

OBJECT OF THE INVENTION

The present invention is therefore based on the object of providing an expanded granulate made of mineral material which overcomes the mentioned disadvantages of the prior art. In particular, the expanded granules should be versatile.

DISCLOSURE OF THE INVENTION

This object is achieved in a method for producing an expanded granulate from sand-grain-shaped, mineral material which has a bound propellant, For example, an expanded granulate made of pearlite sand, the sand-grain-shaped, mineral material

- is introduced into a task opening at one end of a furnace shaft,

- is conveyed in a conveying direction along a heat treatment section, preferably by gravity,

- it is heated to a critical temperature during transport through the heat treatment section, above which the sand-grain-shaped, mineral material becomes plastic and begins to expand due to the blowing agent,

- and the expanded granules are discharged at another end of the furnace shaft, solved according to the invention in that the sand-grain-shaped, mineral material is heated to a second temperature above the critical temperature after heating to the critical temperature, which second temperature is below a third temperature , from which third temperature the surface of the expanded granulate bursts and the second temperature being selected as a function of a desired density of the expanded granulate, so that part of the blowing agent remains in bound form in the granulate.

It has been found that, contrary to what is known and assumed from the prior art, a temperature range exists above the critical temperature within which the expansion of the sand-grain-shaped, mineral material is achieved by selecting a second temperature to which the sand-grain-shaped, mineral material is heated , can be controlled within defined limits without the surface of the expanded granules bursting open.

When speaking of the surface bursting open in this context, it should be noted that in the sense of In accordance with the invention, a surface of a puffed granulate is not considered to have cracked open and thus closed-cell if less than 15%, preferably less than 10%, particularly preferably less than 5%, of the surface of the puffed granulate has burst and the remaining surface is smooth.

Such slightly cracked surfaces still cause the slightest or no hygroscopicity and pronounced mechanical stability of the expanded granules.

As has also been found, the controlled expansion of the sand-grain-shaped, mineral material makes it possible to set the density [kg / m ³ ] or an expansion factor of the expanded granulate for fields of application relevant in practice. In other words, by selecting the second temperature accordingly, expanded granules with different densities and thus different strengths can be produced, all of which nevertheless have closed surfaces, are mechanically stable and therefore not hygroscopic.

The term expansion factor is to be understood as the ratio of the volume of the sand-grain-shaped, mineral material before the expansion process to the volume of the granules after the expansion process. The "closer" the second temperature is to the critical temperature, the "less" the sand-grain-shaped mineral material is expanded, i.e. the lower the expansion factor of the granulate. In this case, part of the propellant is not used for the expansion process. This remains in bound form in the granulate. When the second temperature is increased, the expansion factor of the granules also increases. The "closer" the second temperature is to the third temperature, the more propellant is used for the expansion process - i.e. the less propellant remains in bound form in the granulate.

In other words, by choosing the second temperature, the expansion process is controlled insofar as it reduces the residual moisture of the expanded granules, i.e. the proportion of water not used for the expansion of the starting material, which in turn allows the density of the expanded granules to be set in a targeted manner. The lower the second temperature selected, the higher the density of the expanded granulate. The higher the second temperature selected, the lower the density of the expanded granulate. Since the density is proportional to the mechanical strength, the lower the density of the expanded granulate, the lower the mechanical strength of the expanded granulate, while the higher the density of the expanded granulate, the higher the mechanical strength of the expanded granulate. For any practical application of the expanded granulate, that strength can always be selected for which the mechanical strength is just sufficient. This ensures that the puffed granulate is just as stable as necessary, but at the same time as light as possible. The expanded granules can therefore be used in many ways and, with the aid of the method according to the invention, can be adapted to the particular application in such a way that the solution is particularly efficient.

In a particularly preferred embodiment of the invention, the method proceeds as follows:

The sand-grain-shaped, mineral material is first heated to the critical temperature and then to the second temperature while it is being conveyed through the heat treatment section. From the critical temperature, the sand-grain-shaped, mineral material, which comprises numerous grains, each with a structure and a surface, becomes plastic - i.e. the sand-grained, mineral material becomes soft.

Because of the propellant, the majority of the sand grain-shaped mineral material begins to expand at the critical temperature. In this context, “majority” is understood to mean that more than 80%, preferably more than 90%, particularly preferably more than 95%, of the abandoned sand-grain-shaped, mineral material begins to expand. Since not all grains of the abandoned sand-grain-shaped, mineral material have the same physical and chemical parameters, it cannot be completely avoided that with a certain number of grains the plasticization and thus the expansion process does not start until later than with the majority of the grains. For this reason, it is advantageous if the sand-grain-shaped, mineral material applied has grains with properties that are as identical as possible, so that the heating of the sand-grained, mineral material when carrying out the method according to the invention is the same for all grains, but at least for the majority of the grains Behavior causes.

The second temperature lies in a range between the critical temperature and the third temperature, the surface of the granulate bursting at the third temperature. In the area between the critical temperature and the third temperature, the sand-grain-shaped, mineral material expands to the greatest possible extent without bursting.

The structure and the surfaces of the sand-grain-shaped, mineral material have a temperature-dependent viscosity. At a higher temperature, the surfaces and the bodies of the sand-grain-shaped, mineral material are less viscous, which is why the sand-grain-shaped, mineral material is expanded more by the evaporating propellant. Below the critical temperature, the viscosity is so high that the surfaces and the bodies of the sand-grain-shaped, mineral material do not become plastic and there is no swelling process. Above the third temperature, the viscosity of the body and the surfaces is again so low, and on the other hand the evaporation pressure of the propellant is so high that the surfaces of the expanded granules burst open in the course of the expansion process. In other words, the viscosity of the granulate, the expansion process and, subsequently, the density and mechanical strength of the expanded granulate are set via the level of the second temperature. As already stated above, it has been found that the expansion factor or the density of the expanded granules can be adjusted in a targeted manner by the level of the second temperature in such a way that the level of the second temperature is inversely proportional to the density of the expanded granules, ie the lower the The second temperature is selected, the higher the density of the expanded granules and vice versa. As already written above, the density is proportional to the mechanical strength. Thus, if the density of the expanded granulate is lower, the mechanical strength of the expanded granulate is also lower, while if the density of the expanded granulate is higher, the mechanical strength of the expanded granulate is higher. For any practical application of the expanded granulate, that strength can always be selected for which the mechanical strength is just sufficient.

This ensures that the expanded granulate not only has the advantages associated with a closed-cell structure, but is also just as stable as necessary, but at the same time as light as possible. The expanded granules are therefore versatile and can be adapted to the respective application with the aid of the method according to the invention so that the solution is particularly efficient.

The grains of the expanded granules with a closed-cell surface are ideally spherical, but can also have the shape of an egg, potato or the shape of several interconnected entities - similar to several interconnected soap bubbles.

The propellant is bound, more or less uniformly, within the volume of the grains of the granulate. In the course of the expansion process, depending on the distribution of the propellant, several expanded cells can form within a grain, which do not split off from one another, creating several interconnected entities. In an alternative embodiment of the method according to the invention, it is provided that the sand-grain-shaped, mineral material is first preheated to a preheating temperature below the critical temperature after being introduced into the furnace shaft in preparation for the expansion process, preferably not more than 750 ° C.

Depending on the starting material in the form of sand-grain-shaped, mineral material, it is not necessary that 750 ° C are actually reached in the course of preheating. It is only essential that the 750 ° C is not exceeded, and depending on the grain size of the starting material, the 750 ° C can also be significantly below. For example, the preheating temperature can also be in the range between 500 ° C and 650 ° C.

The preheating is used to slowly warm up the grain of sand-shaped, mineral material down to the core before the expansion process. By heating to the preheating temperature, all layers of the sand-grain-shaped, mineral material - starting from a surface to a core - are heated slowly and not suddenly.

The aim is to ensure that the preheating creates a temperature profile that is as uniform as possible within the layers of the sand-grain-shaped, mineral material. Limiting the preheating temperature prevents outer layers close to the surface from swelling and forming an insulation layer before the core is heated if the temperature is too rapid to reach the critical temperature. Furthermore, the limitation of the preheating temperature serves to prevent the propellant from developing so great a pressure that the sand-grain-shaped, mineral material expands in an uncontrolled manner, whereby the surface bursts open.

In an alternative embodiment of the method according to the invention, it is provided that a duration of up to Reaching the preheating temperature between 0.5 and 1.5 seconds, preferably between 0.5 and 2 seconds, particularly preferably between 0.5 and 3 seconds.

As already stated above, it is considered essential that the starting material in the furnace shaft is slowly preheated and not suddenly heated. In addition to limiting the preheating temperature, it is therefore also necessary to regulate the heat supply in the furnace shaft in such a way that the preheating temperature (not necessarily the maximum preheating temperature) is reached as slowly as possible under the procedural boundary conditions (available conveyor line).

The temperature increase until the preheating temperature is reached is preferably linear. However, it is also conceivable that the temperature rise takes place exponentially or to a limited extent until the preheating temperature is reached.

In a preferred embodiment of the method according to the invention, it is provided that the heat treatment section has heating elements for emitting heat to the sand-grained, mineral material, the control from within at least 1 m, preferably within at least 2.5 m, particularly preferably from within at least 4m, measured from the feed opening, arranged heating elements with a feed temperature of at most 750 ° C takes place.

As a result, the start of the expansion process in the furnace shaft can be shifted as far down as possible, depending on the starting material and the density to be set. The further down the start of the bloating process, the longer and more even the preheating. In any case, it must be ensured that the remaining conveying path is sufficient to achieve the second temperature and thus the desired density. With a correspondingly light starting material, it may be sufficient to control only the heating elements arranged within 1m after the feed opening with a feed temperature of at most 750, since this can be sufficient for slow, even heating. In the case of heavier starting material, however, it may be necessary to control all heating elements arranged within 4 m of the feed opening with a feed temperature of no more than 750 ° C, since in this case the uniform, continuous heating requires a longer fall distance.

In an alternative embodiment of the method according to the invention, it is provided that the control of the heating elements located in the conveying direction after the heating elements controlled by the feed temperature takes place at a temperature that is above the feed temperature, preferably between 800 ° C and 1100 ° C. This ensures that at least the critical temperature is reached, so that a swelling process occurs.

In an alternative embodiment of the method according to the invention, it is provided that the second temperature is in a range between the critical temperature and 1.5 times or 1.4 times or 1.3 times or 1.2 times or 1.1 times the critical temperature .

That means, depending on the nature of the raw material and the initial grain size, the second temperature does not exceed 1.5 times the critical temperature. By choosing the second temperature, which is in any case below the third temperature, it is ensured that - depending on the starting material - more than 85%, preferably more than 90%, particularly preferably more than 95%, of the expanded granules after the expansion process in the second Temperature has a closed-cell, unbroken surface.

In an alternative embodiment of the method according to the invention, it is provided that the first temperature and / or the critical temperature and / or the third Temperature for a certain type of starting material is determined experimentally before it is introduced into the furnace shaft, the first and / or the critical temperature being determined, for example, with the help of a test furnace, preferably with the help of a muffle furnace. In other words, the corresponding temperatures are determined experimentally - especially in the case of unknown starting materials - before the granulate is introduced into the furnace shaft. For this purpose, among other things, the moisture content of the granulate and its decrease in mass during drying are determined. However, if the starting materials are similar (raw sand type and grain size), a new determination is not necessary.

The first temperature and / or the critical temperature and / or the third temperature are then determined as a function of a material class of the mineral material in the form of sand grains, on an initial grain size of the mineral material in the form of sand grains and on the mass of the blowing agent. The second temperature is then selected as a function of the desired density to be achieved.

In an alternative embodiment of the method according to the invention, it is provided that the blowing agent comprises water, which water is bound in the sand-grain-shaped, mineral material.

As already written above, the sand-grain-shaped, mineral material becomes plastic at the critical temperature, whereby the evaporating water-containing propellant exerts pressure on the sand-grain-shaped, mineral material, in particular on the surface of the sand-grain-shaped, mineral material, which leads to the expansion process.

In an alternative embodiment of the method according to the invention, it is provided that after the second temperature has been reached, the supply of heat to the expanded granules is regulated in such a way that the temperature of the expanded granules does not increase any further. This prevents another swelling process, the tearing of the expanded granulate is prevented and the inflation factor set by the second temperature can be maintained. Thus, a large part - ie more than 85%, preferably more than 90%, particularly preferably more than 95% - of the expanded granulate at the other end of the furnace shaft has a closed-cell surface and a density set specifically by the second temperature. The puffed granules are then characterized by a lack of hygroscopicity or a hygroscopicity which is less negative in practice and high mechanical stability.

The heating power of the heating elements in the heating zones in the heat treatment section remaining after the expansion process is preferably successively reduced. This means that after the second temperature has been reached, the temperature of the expanded granulate drops.

It would be conceivable that the second temperature is only reached in a region of the heat treatment section, which region is close to the other end of the furnace shaft. This has the advantage that the number of heating elements located behind this area, viewed in the conveying direction, can be kept low.

If the expansion process takes place in an area of the heat treatment section, which area is not close to the other end of the furnace shaft, but, for example, in a middle section of the furnace shaft, it would also be conceivable that the output in the conveying direction behind the area in which the second temperature is reached, lying heating elements is set to zero.

This ensures that there is no further expansion process after this area and that the expanded granulate, which has an essentially closed-cell surface, does not burst. According to the invention, the expanded granules can be used as a mineral filler in a bitumen product. This is a particularly preferred area of application for the expanded granulate with a closed-cell surface and a targeted density. By using the expanded granulate, the weight of the bitumen product can namely be optimized without adversely affecting the sealing effect of the bitumen product.

WAYS OF CARRYING OUT THE INVENTION

The invention will now be explained in more detail on the basis of two exemplary embodiments, with pearlite sand being used as the raw material for the production of the expanded granules in both exemplary embodiments.

In the first exemplary embodiment (pearlite A), the unexpanded pearlite sand A has an initial grain size in a range from 100 μm to 300 μm. Above a critical temperature, which in this embodiment is 790 ° C, and below a third temperature, which is> 1080 ° C, there is a temperature range within which the expansion of the pearlite sand A by selecting a second temperature to which the pearlite sand A is heated, can be controlled - without the surface bursting, as part of the propellant remains in bound form in the granulate and is not used for expansion.

As a result of this controlled expansion and partial non-use of the bound propellant, a bulk density and, consequently, a compressive strength of the expanded perlite A can be set for fields of application relevant in practice.

Table 1 shows - purely by way of example - an overview of the correlation between the second temperature and the bulk density of the expanded granulate and its compressive strength of the pearlite A when heated to the second temperature. Table 1 also shows the values in the expanded pearlite grains A remaining residual moisture, which is due to the remaining in the expanded granules, bound propellant, eg. Water, setting, evident.

In the first exemplary embodiment, the pearlite sand A is first brought to the critical temperature of 790 ° C. while being conveyed through a heat treatment section and then heated to the second temperature. From the critical

At a temperature of 790 ° C, the pearlite sand A becomes plastic, whereby the water bound in the pearlite sand A, the so-called crystal water, begins to evaporate and thus acts as a blowing agent. As the evaporation process begins, the pearlite sand A swells to a multiple of its original volume. When it is heated above the third temperature, which in this exemplary embodiment is above 1080 ° C., that is to say, for example, 1090 ° C. or 1100 ° C. or 1200 ° C., the surface of the perlite A begins to burst. The water that was still bound in the granulate at the beginning evaporates completely.

However, if the temperature is limited to a temperature (second temperature) below the third temperature, water remains in bound form in the granulate. By selecting the second temperature, the proportion of bound water remaining in the granulate and thus the bulk density to be achieved can be adjusted. This fact can be seen from table 1 using numerical values. Since there is proportionality between bulk density and compressive strength, you can choose the second Temperature also the compressive strength can be adjusted.

In concrete terms, this means: the lower the second temperature selected, the higher the bulk density of the expanded perlite A and thus also its compressive strength. The higher the second temperature selected, the lower the bulk density of the expanded perlite A and thus also its compressive strength. By selecting the second temperature accordingly, it can be ensured that the closed-cell expanded and thus non-hygroscopic perlite A is just as stable as necessary, but at the same time as light as possible - the expanded perlite A is therefore versatile.

The lowest bulk density of 90 kg / m ³ and the lowest compressive strength of 0.15 N / mm ² is achieved with perlite A at a second temperature of approx. 1080 ° C - this is because in this case the second temperature is very close to the third Temperature is. A high bulk density of 400 kg / m ³ and a high compressive strength of 3.60 N / mm ^{2 of} the expanded perlite A is achieved at a second temperature of 950 ° C. - in this case the second temperature is closer to the critical temperature. For comparison: the bulk density of the non-expanded perlite sand A (raw material) is approx. 1050 kg / m ³ , the moisture 3.66 m%, which is only intended to serve as a comparison value for the original proportion of bound water.

The "closer" the second temperature is to the critical temperature, the "less" the pearlite sand A is expanded. Part of the water remains in bound form in perlite A. The "closer" the second temperature is to the third temperature, the more water evaporates - that is, the less water remains in bound form in perlite A. The residual moisture shown in Table 1 is a measure of the water remaining after the expansion process in perlite A. With a bulk density of the expanded perlite A of 90 kg / m ³ , only 0.74 m% of bound water remains in the expanded perlite A, while with a bulk density of 400 kg / m ³ 1.40 m% of bound water remains in the expanded perlite A. In this context, it should be mentioned that here The unit used for the residual moisture is percent by mass [m%].

In the second exemplary embodiment (perlite B), the unexpanded pearlite sand B has an initial grain size in a range from 75 μm to 170 μm. The statements / definitions generally made in the first exemplary embodiment with regard to critical temperature, second temperature, third temperature, bulk density, residual moisture and compressive strength and their relationship to one another also apply to the second exemplary embodiment.

Table 2: Overview - Perlite B In the second exemplary embodiment, the pearlite sand B is likewise first brought to the critical temperature of 790 ° C. while being conveyed through the heat treatment section and then heated to the second temperature. From the critical temperature of 790 ° C, the pearlite sand B also becomes plastic, whereby the water bound in the pearlite sand B begins to evaporate and thus acts as a blowing agent. When it is heated above the third temperature, which in this exemplary embodiment is above 1015 ° C., that is to say, for example, 1025 ° C. or 1050 ° C. or 1100 ° C., the surface of the perlite B begins to burst. The water that was still bound in the granulate at the beginning evaporates completely.

The lowest bulk density of 220 kg / m ³ and the lowest compressive strength of 1.50 N / mm ² is achieved with perlite B at a second temperature of approx. 1015 ° C. A high

Bulk density of 550 kg / m ³ and high compressive strength of 7.80 N / mm ^{2 of} the expanded perlite B is reached at a second temperature of 825 ° C. With regard to the residual moisture, it is stated that in the second embodiment, with a bulk density of 220 kg / m ^3, 1.03% by weight of bound water remains in the expanded perlite B, while with a bulk density of 550 kg / m ^3, 1.62% by weight of bound water remains in the expanded perlite Perlite B remains. For comparison: the bulk density of the non-expanded perlite sand B (raw material) is approx. 1000 kg / m ³ , the humidity 3.66 m%, which in this exemplary embodiment is only intended to serve as a comparison value for the original proportion of the bound water.

From Table 2 it can be seen, among other things, that pearlite B has a lower temperature than pearlite A due to the finer initial grain size. As a result, compared to pearlite sand A, pearlite sand B achieves higher bulk densities of expanded pearlite B and thus also higher compressive strengths.

A person skilled in the art can understand that it is particularly advantageous for the method according to the invention if the raw material used is appropriately conditioned before it is subjected to the method according to the invention in order to create the same starting conditions as possible for the individual grains.

Particularly preferably, it is provided that more than 80%, preferably more than 90%, particularly preferably more than 95%, of the raw material (e.g. pearlite sand A or pearlite sand B) at the critical temperature specified in the two exemplary embodiments begin to expand and begin to break open at the third temperature listed in the tables, in order to be able to ensure by choosing the second temperature that only part of the water bound in the raw material is used for the expansion and the rest remains in the expanded granulate.

Claims

PATENT CLAIMS

1. A method for the production of expanded granules from sand-grain-shaped, mineral material which has a bound propellant, for example an expanded granulate from pearlite sand, wherein the sand-grain-shaped, mineral material

- Is introduced into a feed opening at one end of a furnace shaft, in a conveying direction along a

Heat treatment section, preferably by gravity, is conveyed, while conveying through the heat treatment section is heated to a critical temperature, from which the sand-grained, mineral material becomes plastic and begins to expand due to the blowing agent, and the expanded granules are discharged at another end of the furnace shaft is, characterized in that the sand grain-shaped, mineral material is heated to a second temperature above the critical temperature after heating to the critical temperature, which second temperature is below a third temperature, from which third temperature the surface of the expanded granules bursts and where the second temperature is selected as a function of a desired density of the expanded granules, so that part of the blowing agent remains in bound form in the granules.

2. The method according to claim 1, characterized in that the sand grain-shaped, mineral material after being introduced into the furnace shaft in preparation for the expansion process is first preheated to a preheating temperature below the critical temperature, preferably preheated to a maximum of 750 ° C.

3. The method according to claim 2, characterized in that the time until the preheating temperature is reached is between 0.5 and 1.5 seconds, preferably between 0.5 and 2 seconds, particularly preferably between 0.5 and 3 seconds.

4. The method of claim 1, wherein the

Heat treatment section having heating elements for the transfer of heat to the sand-grain-shaped, mineral material, characterized in that the control of heating elements arranged within at least 1m, preferably within at least 2.5m, particularly preferably within at least 4m, measured from the feed opening a feed temperature of at most 750 ° C takes place.

5. The method according to claim 4, characterized in that the

The control of the heating elements located in the conveying direction after the heating elements controlled by the feed temperature takes place at a temperature which is above the feed temperature, preferably between 800 ° C and 1100 ° C.

6. The method according to any one of claims 1 to 5, characterized in that the second temperature is in a range between the critical temperature and 1.5 times or 1.4 times or 1.3 times or 1.2 times or 1.1 times critical temperature.

7. The method according to any one of claims 1 to 6, characterized in that the first temperature and / or the critical temperature and / or the third temperature is determined experimentally before introduction into the furnace shaft

5 become.

8. The method according to any one of claims 1 to 7, characterized in that the propellant comprises water, which water is bound in the sand-grain-shaped, mineral material.

9. The method according to any one of claims 1 to 8, characterized in that after reaching the second temperature, the heat supply to the expanded granules is regulated in such a way that the temperature of the expanded granules does not increase any further.

1510. Expanded granules made of sand-grain-shaped, mineral material, for example expanded granules made of pearlite sand, which expanded granules can be obtained by a method according to one of Claims 1 to 9.

11. Use of the expanded granules according to claim 10 as

20 mineral filler in a bitumen product.