EP3091123A1 - Method and device for increasing a solid matter content in a material, control device, installation for processing a material and paper mill - Google Patents

Abstract

The invention relates to a method, a device and a plant for increasing the solids content of a base material (1), in particular for increasing the solids content of a black liquor (1) in the production of pulp for papermaking, preferably an evaporating device for black liquor, a control device and a paper machine, having a plurality of vessels (G1, G2, G3, G4, G5) and at least one heat pump (WP, WP'), wherein thermal energy ("Q)" is provided for acting on the base material (1) to increase the solids content. The raw material (1) flows through from a first vessel (G1) to at least one further vessel (G2, G3, G4) to a last vessel (G5). At least one heat pump (WP, WP') is advantageously used to transport thermal energy (”Q) into at least one vessel (G1, G2, G3, G4, G5) and the at least one heat pump (WP, WP') extracts the thermal energy (” Q) from a reservoir (R) and/or from one of the vessels (G1, G2, G3, G4, G5). A higher solids content of the base material can thus advantageously be achieved.

Description

The invention relates to a device for increasing a solids content of a base material, in particular for increasing the solids content of a black liquor, preferably an evaporation device of black liquor, comprising a plurality of vessels, wherein to increase the solids content thermal energy is provided for acting on the base material, wherein a passage of the base material is provided from a first vessel via at least one other vessel to a last vessel.

Furthermore, the invention relates to a method for increasing a solids content of a base material, in particular for increasing a solids content of a black liquor in the production of pulp, preferably a process for the evaporation of black liquor, wherein a base material, a first vessel, then at least one further vessel and then a passing through the last vessel, with thermal energy acting on the base material to increase the solids content.

Furthermore, the invention relates to a control device, a plant for processing a base material and a paper mill.

Such a base material is, for example, black liquor. Black liquor accumulates in the production of pulp. Pulp is a starting material in the production of paper. Black liquor is a large amount of lignin-containing water obtained by digesting wood. Black liquor also contains dissolved inorganic salts such as sodium sulfide and magnesium oxide. Black liquor is advantageously freed for energy production of most of the water (evaporated) and then the (solid) organics (especially lignin and its derivatives) the black liquor burned.

According to the current state of the art, the black liquor is evaporated with the aid of (water) steam, the black liquor successively passing through vessels in which the solids content is successively increased. The black liquor originating from the digestion process is also referred to as a thin liquor and has a solids content of 10% to 15%. The aim is to increase the solids content of the black liquor after passing through a device to increase the solids content to about 80%.

DE 695 20 366 T2 describes a method and apparatus for the final evaporation of black liquor.

US 5,509,977 describes a transformation of the black liquor into a gaseous substance, which is then burned in a recovery boiler and thereby large amounts of heat energy are provided.

Finally describes EP 0 334 398 A2 a method for reducing deposits in systems for evaporating sulfide liquors, wherein the temperature is reduced in individual stages of evaporation.

A disadvantage of the prior art is still not sufficiently high solids concentration of the evaporated black liquor for efficient and low-emission combustion.

It is therefore an object of the invention to provide a method and a device which can further increase the solids content of the base material.

This object is achieved by a device according to claim 1 and by a method according to claim 8. Further, the object is achieved by a control device according to claim 10, by a plant according to claim 11 and by a paper mill according to claim 12.

Advantageous embodiments of the device and the method are described in the dependent claims.

Under a base material is understood here as a suspension or solution of a substance in a liquid, for example black liquor.

Under the base material but here are also other water-containing residues to understand, which have organic compounds that can be burned more efficiently after removing the liquid for energy.

By way of example, organic components of wastewater (e.g., sewage sludge) may also be used to generate energy with this invention. Further, by means of this invention, inorganic constituents can be recovered from the base.

A heat pump is understood to mean a device which transfers heat energy from a reservoir or a vessel into another vessel or reservoir, wherein the temperature of the reservoir or vessel into which the thermal energy is transferred may be higher than the temperature in the vessel or reservoir Reservoir from which the thermal energy originates.

Instead of the heat pumps and heat exchangers can be used. A heat exchanger serves to transfer heat energy from a vessel / reservoir / higher temperature substance to a low temperature substance.

In this context, a vessel is understood as meaning a reaction vessel, a kettle, a short-tube evaporator, a long-tube evaporator, a falling-film evaporator or a pressure vessel. The vessel preferably has an inlet and an outlet, the base material passing through the inlet into the Introduced vessel and is removed through the outlet back out of the vessel. The individual vessels are interconnected by conduits, the vessels also having further inlet and outlet openings for a heat transfer medium.

A first vessel is understood here to mean the vessel which is first passed through by the base material. The raw material then passes through the other vessels. Finally, the raw material passes through the last vessel.

The heat transfer medium, in particular water vapor, passes through the vessels in the same direction as the base material. The heat carrier may also pass through the vessels in a parallel manner, i. in each case a part of the heat carrier is assigned to a vessel. In this case, heat energy is transferred from the heat transfer medium to the base material in each of the vessels. The transmitted heat energy heats the base material and evaporates part of the liquid in the base material. The vaporized portion of the base can be separated from the base and thus the solids content is higher after a swept vessel.

The heat transfer medium advantageously passes first through the first vessel, then the other vessels and finally the last vessel. In a further advantageous embodiment of the device or of the method, the heat transfer medium passes through the vessels in the opposite direction. The heat carrier can also be passed through the vessels in parallel.

In an advantageous embodiment, a heat carrier is used to supply the heat energy for the base material. A heat transfer medium is generally understood to mean a substance which has a high temperature which is suitable for supplying heat energy to a vessel, in particular through a heat exchanger.

Also possible is another passage of the heat carrier and / or the base material through the vessels. For example The heat carrier with the highest temperature is used to heat the one vessel, which is neither first nor last run through by the raw material. After one vessel, the other vessels in the serial and / or parallel flow direction are acted upon by the heat carrier.

Advantageously, the base material first passes through a first vessel, then at least one further vessel up to a last vessel. In each of the traversed vessels, the solids content of the raw material is increased. Thus, the solids content is further increased from a low concentration (about 10% to 20%) by the evaporation of the excess water or other liquid in each of the vessels so that after leaving the last vessel the base has a solids content of over 70%.

The (at least one) heat pump is used to increase the temperature of the base material and / or the heat carrier at least in a vessel, in particular beyond the temperature of the heat carrier and / or the base material.

By using the heat pump, it is possible to increase the temperature in one vessel or in several vessels to the extent that the increase in the solids content of the base material can be made more efficient.

The heat energy for the further increase of the solids content of the base material in a vessel is either taken from another subsequent vessel or a reservoir, which represents, for example, a reservoir of excess heat energy from a further treatment step of the base material.

The method is characterized in that heat energy is introduced by means of at least one heat pump into at least one vessel and that the at least one heat pump removes the heat energy from a reservoir and / or one of the vessels. Also in the method described here is the Influence of heat energy on the base to increase the solids content by reducing the level of liquid in the base.

The control device is advantageously used to control and / or regulate a method described here, wherein sensors for determining temperatures in the vessels, the temperature of the heat carrier, a solids content of the base material and / or pressure values from the individual vessels are provided and wherein the control device based on the temperatures, the solids content of the base material, the pressure values from the individual vessels, for controlling and / or regulating the at least one heat pump is provided.

The sensors transmit the determined values via a technical data connection to the control device. The control device preferably regulates the supply of heat energy for the heat transfer medium and / or for the base material taking into account the determined values by means of an algorithm which maximizes the solids content after passage of the base material through the vessels. The control device can be integrated in the control of the plant, in particular of the paper mill or a part thereof.

In an advantageous embodiment of the device, the reservoir is the excess heat energy resulting from the production or processing of the base material. The reservoir can serve as a storage for thermal energy.

Advantageously, both energy is saved by the invention, as well as a possibility for increasing the solids content in the evaporation of the raw material provided.

Due to an increased solids content, the combustion of the black liquor residues leads to less sulfur dioxide in the combustion exhaust gases.

In a further advantageous embodiment, the heat exchanger and / or the heat pump transports thermal energy counter to the direction of passage of the base material through the individual vessels.

The heat pump and / or the heat exchanger transport a portion of the heat energy, for example, from the last vessel in the penultimate vessel. In this case, the heat pump and / or the heat exchanger can extract part of the heat energy from the heat transfer medium and / or part of the heat energy from the base material.

Furthermore, a heat pump and / or a further heat pump can transfer the heat from at least one vessel into at least one further vessel.

As a result of this configuration, the temperature in at least one of the vessels can be increased and thus the solids content of the basic substance can be further increased with such a device.

In a further advantageous embodiment of the device, the vessels are provided for gradually increasing the solids content of the base material, wherein in the first vessel, the temperature of the base material and / or the heat carrier is higher than the temperature in the last vessel.

The gradual decrease of the temperature in the vessels is due to the transfer of heat energy (by the heat transfer medium) to the base material in the vessels. When increasing the solids content of the base material in a vessel heat energy is removed from the heat transfer medium. The heat transfer medium is transferred from the first vessel into a further vessel, thermal energy also being withdrawn from the heat carrier in the further vessel and the solids content of the base material being further increased with the heat energy removed.

Therefore, the temperature of the base material in the last vessel through which the base material passes is lower than in the first vessel, in which the base material is heated with the "unconsumed" heat transfer medium.

It is therefore advantageous to transfer the heat energy to the individual vessels in such a way that the most efficient possible increase of the solids content takes place.

In a further advantageous embodiment of the device, the heat pump for transporting heat energy from the last vessel is provided in a further vessel. As a further vessel here in particular the vessel passed through before the last vessel is provided. This embodiment of the device makes it possible to increase the temperature in the vessel passed through before the last vessel by removing heat energy from the subsequent vessel and transferring it to the respective other vessel. By increasing the temperature at which the heat energy is transported, a more efficient increase in the solids content of the base can be achieved.

An advantage of this embodiment is the possibility even with a limited number of vessels, for example five, to obtain a very high solids content of a base material.

In a further advantageous embodiment of the device, the device has at least one sensor and a control device, wherein the control device and / or sensors for controlling and / or regulating the supply of heat energy are provided in at least one vessel.

Advantageously, the at least one heat pump is controlled or regulated with the aid of the control device, so that the solids content is increased with a limited supply of heat energy. The sensors are used in particular for determining the solids content of the base material in the vessel, for Determining the temperature of the base material and / or the heat carrier in one of the vessels, for determining the pressure of the base material and / or the heat carrier in the vessel.

The possibility of controlling on the basis of the parameters set out above makes it possible to use the heat energy efficiently to increase the solids content of the raw material. In particular, in the case of a limited reservoir of heat energy, a control for the most efficient use of the heat energy is advantageous.

The control or regulation of the at least one heat pump with the aid of the control device can be effected by a comparison of the heat energy transferred with a simulation. In this case, for example, the method for increasing the solids content of the base material is simulated and the results of the simulation form the basis of the control or regulation of the heat pump.

Advantageously, a consistently high concentration of the solid can be ensured with this design.

In an advantageous embodiment of the method, the heat energy is transferred from a last vessel into the penultimate vessel. Under the penultimate vessel, the vessel is understood, which passes through the base material before entering the last vessel.

In a further advantageous embodiment of the method, a heat pump and / or a heat exchanger are used to transfer heat energy from a reservoir into a vessel, in particular the last vessel through which the raw material has passed. A further heat pump may optionally transfer heat energy from the last vessel and / or the reservoir into at least one further vessel, in particular the penultimate vessel. This advantageous embodiment makes it possible to increase the temperature in one of the vessels considerably and thus to increase the solids content of the base material.

FIG 1

ein Aufbauschema der Vorrichtung zur Erhöhung des Feststoffgehalts eines Grundstoffs,

FIG 2

eine erste Abwandlung dieser ersten Vorrichtung,

FIG 3

eine Darstellung der Temperaturen in den einzelnen Gefäßen gemäß dem ersten Aufbauschema,

FIG 4

eine Darstellung der Temperaturen für eine Vorrichtung gemäß der ersten Abwandlung,

FIG 5

eine zweite Abwandlung der Vorrichtung,

FIG 6

eine dritte Abwandlung der Vorrichtung sowie

FIG 7

sich ergebende Temperaturen in den einzelnen Gefäßen für die dritte Abwandlung der Vorrichtung.

In the following the invention will be described and explained with reference to figures. The figures show various embodiments of the invention. Show it:

FIG. 1

a construction diagram of the device for increasing the solids content of a base material,

FIG. 2

a first modification of this first device,

FIG. 3

a representation of the temperatures in the individual vessels according to the first construction scheme,

FIG. 4

a representation of the temperatures for a device according to the first modification,

FIG. 5

a second modification of the device,

FIG. 6

a third modification of the device as well

FIG. 7

resulting temperatures in the individual vessels for the third modification of the device.

Subsequently, it is assumed that the heat transfer medium D passes through the vessels G1, G2, G3, G4, G5 in the same direction as the base material 1.

FIG. 1 shows a construction scheme of a device P for increasing the solids content of a base material 1. The device P shown here is based on the current state of the art. A base material 1, in particular a black liquor, is transferred to a first vessel G1. In the first vessel G1, the temperature of the base material 1 is increased by means of a heat transfer medium D. In the vessel G1, a temperature T1 is present. By increasing the temperature T1 of the base material 1, part of the liquid from the base material 1 evaporates. The base material 1 with an increased solids content is subsequently transferred to the second vessel G2 and separated from the evaporated liquid. In the second vessel G2 there is a temperature T2. Also in the second vessel G2, the temperature T2 of the base material 1 is increased by means of the heat transfer medium D. Also in the vessel G2 Part of the liquid from the base 1 evaporates and the solids content of the base 1 is further increased. Also subsequent vessels G3, G4, G5 serve the same purpose, namely the further increase of the solids content of the base material 1. For efficient use of heat energy, which is transmitted through the heat transfer medium D in the vessels G1, G2, G3, G4, G5, the Heat transfer medium D, for example, introduced into the first vessel G1, wherein the heat transfer medium D is then transferred from the first vessel G1 in the second vessel G2, then in the third vessel G3, then in the fourth vessel G4, etc. The possible passage directions of the heat carrier D through the vessels G1, G2, G3, G4, G5 are symbolized by the broken (double) arrows. Thus, other passage directions of the heat carrier D through the vessels G1, G2, G3, G4, G5 are conceivable, which do not belong to the prior art. The thermal energy .DELTA.Q is transmitted, for example, by a heat exchanger (which is arranged in the vessels) from the heat transfer medium D to the base material 1. Such a heat exchanger for the transmission of heat energy ΔQ of the heat carrier to the base material is present in each of the vessels G1, G2, G3, G4, G5, but is symbolically shown in this figure and the following figures in the second vessel G2.

A transfer of the thermal energy .DELTA.Q can also be effected by a direct contact of the heat carrier D with the base material 1. The heat exchanger is shown symbolically leidglich in the second vessel G2.

Upon evaporation of the liquid from the base material 1, a part of the heat energy ΔQ, which is brought by the heat transfer medium D in the vessels G1, G2, G3, G4, G5, "consumed". Therefore, the temperature T1 of the heat carrier decreases successively from the first vessel G1 via the second vessel G2 to the last vessel G5. Although the solids content of the base material 1 does not increase to the optimum value as a result of this drop in the temperature from T1 through T2, T3, T4 to the temperature T5 in the fifth vessel G5, the heat energy of the heat carrier D is used efficiently.

Depending on the direction of passage of the heat carrier D and / or the base material 1, the heat transfer medium D can first be transferred to the fifth vessel G5, then into the fourth vessel G4, etc., up to the first vessel G1. In such a case, the temperature rises from the first vessel G1 to the fifth vessel G5 and thus also the stepwise increase of the solids content of the base material. 1

FIG. 2 shows a first modification of the device P, which in FIG. 1 will be shown. Also in the device P of FIG. 2 the base material 1 subsequently passes through a first vessel G1, a second vessel G2 up to a fifth vessel G5 and in the individual vessels G1, G2, G3, G4, G5 there is a temperature T1, T2, T3 (assigned to the respective vessel) T4, T5, ie a first temperature T1 in the first vessel G1, a second temperature T2 in the second vessel G2, etc. Depending on the direction of passage of the heat carrier D, the temperature of the base 1 and / or of the heat carrier D increases from the first vessel G1 to last vessel G5 or it decreases from the first vessel G1 to the fifth vessel G5.

For a more efficient use of the heat carrier to increase the solids content of the base material 1 is here a heat pump WP, which heat energy ΔQ transferred from the fourth vessel G4 in the fifth vessel G5 or the fifth vessel G5 in the fourth vessel G4, depending on the passage of the heat carrier D. By the transmission of heat energy ΔQ, the temperature T4 in the fourth vessel decreases and the temperature T5 in the fifth vessel G5 is increased, or vice versa, according to the direction of the transport of the heat energy ΔQ. By transporting heat energy ΔQ, the content of the solid in the base material 1 is increased, with more liquid evaporating from the base material 1 in one of the vessels G4, G5, and thus the solids content of the base material 1 in comparison with the current state of the art with the extended system can be increased.

For controlling the heat pump WP is a control device SE, which with sensors S, in particular temperature sensors S, which determines the temperature in the fourth vessel G4 and the temperature T5 in the fifth vessel G5.

FIG. 3 shows the course of the temperature of the base material 1 in the vessels G1, G2, G3, G4, G5. In this case, a first temperature T1 is present in the first vessel G1. Next is in the second vessel G2, a second temperature T2, etc. The FIG shows the temperature profile of the heat carrier D and / or the base material 1 without the use of a heat pump WP. The temperature T1, T2, T3, T4, T5 decreases steadily from vessel to vessel. Depending on how the heat carrier D passes through the vessels G1, G2, G3, G4, G5, a corresponding different pattern of the temperatures T1, T2, T3, T4, T5 may also result.

FIG. 4 shows a representation of the temperatures T1, T2, T3, T4, T5 for a device P according to the first modification. In particular shows FIG. 4 the influence of the heat pump WP on the temperatures in the fourth vessel G4 and in the fifth vessel G5. The transferred heat energy ΔQ from the fifth vessel G5 into the fourth vessel G4 causes a lowering of the temperature T5 in the fifth vessel G5 with a simultaneous temperature increase of the temperature T4 in the fourth vessel G4.

Due to this temperature transfer, the solids content of the raw material in the vessel G4 is considerably increased, so that the slightly smaller increase in the solids content of the base material 1 in the fifth vessel G5 is also overcompensated. The transfer of heat energy ΔQ is represented by the arrow from the last bar (which symbolizes the temperature T5 in the fifth vessel G5) to the penultimate bar (which symbolizes the temperature T4 in the fourth vessel G4). The temperature rise in the fourth vessel G4 is symbolized by the hatched area.

• aus dem fünften Gefäß G5 und dem dritten Gefäß G3 in das vierte Gefäß G4,
• vom fünften Gefäß G5 über das vierte Gefäß G4 in das dritte Gefäß G3 oder
• vom dritten Gefäß G3 über das vierte Gefäß G4 in das fünfte Gefäß G5.

FIG. 5 shows a second modification of the device P. Here, a further heat pump WP 'is used to transfer heat energy ΔQ from the fourth vessel G4 to the third vessel G3 or vice versa. Analogous to in FIG. 2 shown first modification In the second modification, a heat pump WP is also shown between the fourth vessel G4 and the fifth vessel G5. By pointing in both directions arrows the two possible directions of transmission of the thermal energy ΔQ are indicated. Due to the different directions of transmission, there are several ways of combining a transmission of heat energy ΔQ. Possible is a transfer of heat energy ΔQ

• from the fifth vessel G5 and the third vessel G3 into the fourth vessel G4,
• from the fifth vessel G5 via the fourth vessel G4 into the third vessel G3 or
• from the third vessel G3 via the fourth vessel G4 into the fifth vessel G5.

Again, a control device SE (not shown) with the help of (temperature) sensors S control or regulate the use of the heat pump WP and the other heat pump WP '. For the sake of clarity, here is the in FIG. 2 referenced control device.

By the further heat pump, the solids content of the base material 1 can be further increased by means of the device P shown. Both heat pumps WP, WP 'are controlled or regulated by the control device SE. The direction of transfer of the thermal energy ΔQ can also be controlled or regulated by the control device SE. Advantageously, but not shown for simplicity, the vessels G1, G2, G3, G4, G5 are equipped with sensors S or at least the vessels G3, G4, G5, in / from which heat energy ΔQ is transmitted.

FIG. 6 shows a third modification of the device P. The third modification of the device P, the heat pump WP and possibly the other heat pump WP ', which serve to increase the temperature T4, T5 in the fourth vessel G4 and the fifth vessel G5. Here, the heat pump transfers WP or Heat pumps WP, WP '(or heat exchangers) heat energy ΔQ from a reservoir R in the respective vessel G4, G5. Particularly advantageous in this embodiment of the device P is a simple control of the temperatures T4, T5 by means of the control device SE, which is connected to the sensors S for determining the temperature T4, T5. As a reservoir R, a steam boiler or a source of waste heat, such as a paper mill serve. Sensors S can also be assigned in the other vessels for determining the relevant variables (temperature, pressure, solids content, chemical composition).

FIG. 7 indicates by analogy FIG. 4 the effect of the heat pumps (or heat exchangers) WP, WP 'thus used on the temperature profile of the base material 1 in the individual vessels G1 to G5. Analogous to FIG. 4 the temperatures T1, T2, T3, T4, T5 in the individual vessels G1, G2, G3, G4, G5 are shown in a diagram. By transferring the heat energy ΔQ into the fourth vessel G4 and the fifth vessel G5, the rise of the temperature T4, T5 in the penultimate vessel G4 and in the last vessel G5 is shown. The temperature rise of the heat carrier D and / or the base material 1 is symbolized by the respective hatched part. Symbolically, the, from the reservoir R supplied, heat energy ΔQ, which justifies the rise in temperature, symbolized by the hatched arrows.

It is clear to the skilled person that the in FIG. 6 shown embodiment with the execution of FIG. 2 and / or with the execution FIG. 5 can be combined. Further, a heat pump / heat exchanger heat energy from a reservoir R and the other vessels G1, G2, G3 perform. In particular, for the transfer of heat energy from a reservoir R in the penultimate vessel G4 or the last vessel G5, a heat exchanger is very well suited.

In summary, the invention relates to a method and a device P for increasing a solids content in a Base material 1, in particular for increasing the solids content of a black liquor 1 in the production of pulp for papermaking, preferably an evaporation apparatus of black liquor, comprising a plurality of vessels G1, G2, G3, G4, G5 and at least one heat pump WP, WP ', wherein to increase the solid content thermal energy ΔQ is provided for acting on the base material 1. In this case, a passage of the base material 1 from a first vessel G1 to at least one further vessel G2, G3, G4 takes place to a last vessel G5. At least one heat pump WP, WP 'advantageously serves to transport heat energy ΔQ into at least one vessel G1, G2, G3, G4, G5 and the at least one heat pump WP, WP' removes the heat energy ΔQ from a reservoir R and / or from one of the Vessels G1, G2, G3, G4, G5. Thus, advantageously, a higher solids content of the base material 1 can be achieved.

Claims (12)

Device (P) for increasing a solids content of a base material (1), in particular for increasing the solids content of a black liquor in the production of pulp for papermaking, preferably a black liquor evaporator, comprising a plurality of vessels (G1, G2, G3, G4, G5 ), wherein to increase the solids content thermal energy (.DELTA.Q) for acting on the base material (1) is provided, wherein a passage of the base material (1) from a first vessel (G1) via at least one further vessel (G2, G3, G4) to a last vessel (G5) is provided, characterized in that at least one heat pump (WP, WP ') or a heat exchanger for the transport of heat energy (ΔQ) in at least one vessel (G1, G2, G3, G4, G5) is provided and the at least one heat pump (WP, WP ') extracts the heat energy (ΔQ) from a reservoir (R) and / or from one of the vessels (G1, G2, G3, G4, G5). Device (P) according to claim 1, characterized in that the reservoir (R) is excess heat energy (ΔQ) of an adjacent plant. Device (P) according to one of the preceding claims, characterized in that the heat exchanger or the heat pump (WP, WP ') transports thermal energy (ΔQ) counter to a direction of passage of the base material (1). Device (P) according to one of the preceding claims, characterized in that in the vessels (G1, G2, G3, G4, G5) a gradual increase of the solids content of the base material (1) by means of heat energy is provided, and that the temperature ( T1) of the base (1) in the first vessel (G1) is higher than in the last vessel (G5). Device (P) according to one of the preceding claims, characterized in that the heat pump (WP) for transport of thermal energy (ΔQ) from the last vessel (G5) is provided in at least one further vessel (G1, G2, G3, G4). Device (P) according to one of the preceding claims, characterized in that for supplying thermal energy (ΔQ) for the base material, a heat transfer medium (D) is provided. Device (P) according to one of the preceding claims, further comprising at least one sensor (S) and a control device (SE), characterized in that the control device (SE) and / or the sensors (S) for controlling and / or regulating the supply of thermal energy (ΔQ) are provided in at least one of the vessels (G1, G2, G3, G4, G5). Process for increasing a solids content in a base material (1), in particular for increasing the solids content of a black liquor in the production of pulp for papermaking, preferably a process for evaporating black liquor, the raw material (1) first a first vessel (G1) then Finally, a last vessel (G5) passes through at least one further vessel (G2, G3, G4), heat energy (ΔQ) acting on the base material (1) to increase the solids content, characterized in that heat energy (ΔQ) is generated by means of at least one Heat pump (WP, WP ') is introduced into at least one vessel (G1, G2, G3, G4, G5) and that the at least one heat pump (WP, WP') from a reservoir (R) and / or from one of the other vessels (G1, G2, G3, G4, G5). A method according to claim 8, characterized in that heat energy (ΔQ) from the last vessel (G5) in one of the other vessels (G1, G2, G3, G4) is transported. Control device (SE) for controlling and / or regulating a method according to one of claims 8 or 9, characterized in that sensors (S) for determining temperatures (T1, T2, T3, T4, T5) in the vessels (G1, G2 , G3, G4, G5), the temperature of the heat carrier (D), a solids content of the base material (1), and / or pressure values from the individual vessels (G1, G2, G3, G4, G5) are provided and that the control device (SE) for controlling and / or regulation of the at least one heat pump (WP, WP ') as a function of the temperatures (T1, T2, T3, T4, T5), the solids content of the base material (1) and the pressure values from the individual vessels (G1, G2, G3 , G4, G5) is provided. Plant for processing a base material, in particular a plant for the evaporation of black liquor, comprising a device according to one of claims 1 to 7 and / or a control device according to claim 10. Paper mill, in particular an integrated pulp and paper mill, comprising a plant according to claim 11.

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