WO2018185079A1 - Device for drying constructions - Google Patents

Abstract

The invention relates to a device (100, 200) for drying constructions, having a base heating surface (101) for emitting infrared radiation onto the base (201) of a construction and a wall heating surface (102) for emitting infrared radiation onto a construction wall (202) which adjoins the base (201), wherein the base heating surface (101) is arranged in the device (100) at an angle relative to the wall heating surface (102), and the base heating surface (101) adjoins the wall heating surface (102) directly or substantially directly. The device (100, 200) is designed to generate a controlled flow of air heated by the base heating surface (101) along the base heating surface (101) to the wall heating surface (102). The base heating surface (101) laterally has one or more spacers (107) in order to produce a spacing between the base heating surface (101, 204) and the base (201), whereby the base heating surface (101, 204) and the spacers thereof define a first temperature-controlled sub-zone (209, 210), and the wall heating surface (102) laterally has one or more spacers (106) in order to produce a spacing between the wall heating surface (102, 205) and the wall (202), whereby the wall heating surface (102, 205) and the spacers thereof define a second temperature-controlled sub-zone (209, 210).

Description

 Apparatus for drying structures

Field of the invention

The invention relates to the drying of structures. In particular, the invention relates to a device and a method for drying structures by means of a Bodenheizfläche and a Wandheizfläche, and a corresponding program element and a computer-readable medium.

Technological background

Among the devices for drying bodies are in particular

To mention devices and methods for building drying, especially in the construction drying large expenses for a fast and efficient drying must be made. For example, after floods, after water pipe breaks or after extinguishing missions, as well as after heavy rains in unfinished or damaged roofs, it is important to make the rooms affected by water as soon as possible, on the one hand to restore usability as soon as possible and on the other to the Forming mold and avoid the lasting damage of the walls. Usually, especially in the field of building drying this

Air drying equipment used, which is the air in the room to be dried circulate and thereby remove the moisture. However, this procedure is perceived as relatively inefficient, because actually not the walls are dried, but only the air in the room, which contacts the walls. Only over longer periods of time or with additional construction of foil tents thereby also a drying of the walls, which only gradually promote the moisture from their interior to the surface, so that it can be removed from the air dried by the air dryer.

As a solution to this problem are now in the building drying planar

Infrared radiators are known, which can be placed, for example in the form of an infrared panel in front of the wall to dry them. Most

Market entrants offer unregulated planar infrared panels for wall drying. These are placed near the wall and controlled by timers. A critical area for wall drying is the foot area of the wall on the raw ceiling. As the inventors of the present invention have established, there is little or no heat radiation there by means known in the prior art devices for drying of structures. However, the inventors have found that just there the concentration of the ascending

Moisture after entering the soil in the soil structure, especially under the screed, is highest. They have in their tests which of the present

Invention based, the knowledge gained that there is an increased risk of mold growth, if not dried specifically. Depending on the type of masonry, the water can rise up to one meter from the ground by capillary suction in the wall.

Summary of the invention

It can be regarded as an object of the invention to provide an improved

Specify device and a method for drying of structures. In particular, the apparatus and method of the present invention are designed to allow improved drying of corners, especially from the corner between the floor and a wall, by targeted, controlled introduction of infrared radiation into this area.

The object of the invention is achieved by means of the objects of the independent

Claims solved. Further advantages and further developments are in the

Subclaims specified. The described embodiments relate equally to the apparatus for drying of buildings as well as the method, the program element and the computer-readable medium. In other words, features described below with respect to the device may also be implemented in the method, the program element, and the computer readable medium, and be considered as features of those objects.

According to one embodiment, an apparatus for drying of

Structures specified. The device has a Bodenheizfläche for emitting infrared radiation to a floor of the building. Furthermore, the device has a Wandheizfläche for emitting infrared radiation on a wall adjacent to the floor of the building. In this case, the bottom heating surface is arranged angled relative to the wall heating surface in the device.

It can in this and in any other embodiment, the

Bodenheizfläche be considered as a separate and provided separately from the Wandheizfläche component. However, in specific embodiments of the present invention, an integral embodiment of the wall heating surface and the bottom heating surface may also be provided. For the first time a dedicated device is provided, which is specially designed for the Corner drying of structures was developed. In this case, the arrangement of the two heating surfaces, for example by radiation-emitting plates, carried out so that as much energy is entered in the corner. As will be explained in the context of specific embodiments hereinafter, for example, heated plastic plates, which can emit infrared radiation, are mounted in a metallic frame to achieve the desired angled arrangement of the two heating surfaces. For this purpose, the two plates in the corner area directly or directly be placed next to each other, for example, these can be glued, entangled, and / or

be pressed together. However, the invention is not limited thereto and quite different arrangements of the bottom heating surface and the wall heating surface are also part of the invention.

Furthermore, the heating zone, or the two sublimation zones respectively defined by the heating surfaces, can be delimited by brushing along the circumference of the heating surfaces. It can thereby be achieved that the corner space can be completely covered by these brushes. This can be seen for example in FIG. These brushes allow a beneficial flow of air from the first sublimation zone, which extends between the floor and the bottom heating surface, and where the air for the corner and wall drying can advantageously be preheated to the second sublimation zone. This second sublimation zone extends between the wall and the wall heating surface. The heated surface or surfaces can be delimited by brushes so that on the one hand little

Energy loss due to air flow, on the other hand, the moisture from the drying zone, or Subklimazone can escape.

In the context of the present invention, a sublimation zone is to be understood as the zone defined by the respective heating surfaces. This will be explained in more detail below in the context of various exemplary embodiments and figures. According to a preferred embodiment, the device may also be provided such that a continuous sublimation zone results. This means that in this case the air heated at the bottom heating surface can flow continuously, preferably barrier-free, along the device towards the wall heating surface and its sublimation zone. More details about this advantageous

Preheating the air and the regulated air flow generated thereby will be further explained in the context of the following exemplary embodiments. The present invention allows a separate control of the two heating surfaces, so that the heat input can be optimized for the drying task.

For example, this may cause a higher temperature on the wall than in the wall

Floor area are generated so that targeted a desired level of convection is excited by means of the device. Such an excited air flow with a preheating of the air at the bottom for improved drying of the corner and / or the wall in the corner, can be seen for example in FIG.

In an advantageous embodiment, the device allows the separate monitoring of the maximum temperatures in both areas, or in the two Subklimazonen. This can in particular overheat of sensitive

Floor coverings (eg wooden floor) are avoided. A corresponding intelligent control by means of a measuring sensor, a control unit and / or a

Program element / computer program is also provided by the present invention. It is understood by those skilled in the art that in this and in any other embodiment of the present invention in the use of a control unit and a sensor, such as a temperature sensor or a flow sensor, in fact a control loop is provided.

Targeted energy entry into the corner allows for faster drying of the critical area with significantly lower energy consumption than alternative Methods and devices. Furthermore, it should be noted that the present invention can also be used for drying in corners of rooms, the corner between a wall and the ceiling and for shaft drying. By means of the invention, the drying can be carried out in the same time or faster as the bottom drying, which corresponds to a substantially simplified implementation of the drying project in practice.

As the inventors have found, the wall sections are close to

Base area on the floor or wall areas below the floor structure for thermal radiation by the prior art bad or not at all achievable. The reasons for this in the prior art are, in particular, cold air flowing from below through the convection triggered by the heat radiation and not enough available heating energy for heating the not directly accessible foot region of the wall. Investigations by the inventors have shown that in the previous wall drying in the prior art, the lower portion of the wall, the base, by the incoming from below cool air from the environment both the

Wall surface, as well as the heating surface of conventional devices up to a range of 10 to 15 cm strongly cools.

The present invention solves this problem by having two in one device

Angled heating surfaces, for example, at right angles or substantially at right angles, are arranged so that a heating surface is directed to the ground and the other to the wall. The heating surfaces can be connected so that a continuous air space is created from the floor to the wall. This is supported by the delimitation of the sub-climate zones by the brushes already described. This creates an air flow that runs from the floor to the wall. The heating surface on the floor heats the air, so that it is already warm on the wall. At the same time, in the critical corner area, the heat radiation from the floor and the wall heating plate overlaps, so that more heat energy is needed for this Available.

The present invention thus overcomes the disadvantages of the prior art, as by means of the angled arranged Bodenheizfläche and Wandheizfläche a direct entry of infrared energy is made possible in the desired area. In addition, a temperature sensor may be present in the heating plate, which makes it possible to continuously monitor the wall temperature in the area of influence of the infrared radiation. In this case, the drying process can be controlled by means of the bottom heating surface and the wall heating surface by a control unit which controls the energy input into the wall.

Each heating surface can have its own power control via its own or alternatively via a common control unit. It is also possible to provide individual sensors for measuring the wall temperature or the floor temperature at the device. In addition, similar physical properties can also be detected by means of corresponding sensors and used to control the wall heating surface and / or the bottom heating surface. For example, the temperature of the sensor itself can be measured, which, interestingly and unexpectedly, also allows the inventors to draw conclusions about the drying process. In addition, sensors for the

 Air temperature, the humidity and / or the air flow velocity used and used to control the Wandheizfläche and / or the Bodenheizfläche. An integrated computer control can control the wall heating surface and / or

Adjust the floor heating surface so that the desired convection flow and thus the preheating of the air for wall drying are ensured. The sensor control can prevent overheating of temperature-sensitive floor or wall structures. Due to the quick drying of the wall, this water will draw from the soil structure. This automatically turns one supporting soil drying.

According to one exemplary embodiment, the bottom heating surface directly or substantially directly adjoins the wall heating surface. Thus, for example, a seamless, continuous transition of Bodenheizfläche be ensured in the Wandheizfläche. This means that no volume is wasted to produce infrared radiation for wall drying. Likewise, the advantage is achieved that the radiating surfaces are closer to the corner, since no disturbing

Zwischenstege are present. In addition, the air flow is facilitated. In one embodiment, webs are provided, which are arranged flush.

According to a further embodiment of the invention, the device is designed to generate a regulated air flow of air heated by the bottom heating surface along the bottom heating surface to the wall heating surface. For this example, one or more sensors for measuring the

Air flow rate can be used.

According to a further embodiment of the invention, the

Bodenheizfläche at least one or more spacers laterally to

Generating a distance of Bodenheizfläche to the ground. As a result, the bottom heating surface and its spacers, together with the bottom, define the first sub-climate zone during operation. Furthermore, the wall heating surface at least laterally know one or more spacers for generating a distance of the Wandheizfläche to the wall. As a result, define the Wandheizfläche, their spacers and the wall in operation a second Subklimazone. For example, these spacers may be provided to one or both of the heating surfaces by the brushes described above and hereinafter.

According to a further embodiment of the invention, the device is for generating a targeted convection of heated by the Bodenheizfläche air from the first subclimatic zone to the second subclimatic zone. Such a targeted and controlled collection, for example, the embodiment of Figure 2 are taken. According to a further embodiment, the device has at least one control unit, which for the separate control of the heating activity of

Floor heating and the heating activity of Wandheizfläche is executed. As has been described in the context of the present invention, it can be used

For example, in the bottom-side climate zone certain temperature cycles are generated, which match the temperature cycles of the wall-side subclimate zone. Thus, an ideal temperature and air exchange between the two sub-climates and the environment of the device can be made possible. It may be of particular advantage if a substantially barrier-free and hurdles-free air flow from the first Subklimazone in the second Subklimazone between the device and the building is made possible.

According to a further embodiment, the heating activity of the

Floor heating a heating power and / or one or more heating times, in particular heating intervals, for the Bodenheizfläche. Furthermore, the

Heating activity of Wandheizfläche a heating power and / or one or more heating times, in particular heating intervals, for Wandheizfläche.

According to a further embodiment, the device has a first temperature sensor arranged on or in the bottom heating surface for determining a bottom temperature. Furthermore, the device knows a second on or in the Wandheizfläche arranged temperature sensor for determining a

Wall temperature on. In addition, the device is designed by means of the first and second temperature sensor for separate temperature monitoring at the bottom and on the wall. In another preferred form of this

Embodiment is the apparatus for continuously measuring the Wall temperature and the bottom temperature, in particular a respective

Maximum temperature, carried out by means of the first and the second temperature sensor. According to a further embodiment, the device is designed to control the heating activity of the wall heating surface, measuring the

Wall temperature, controlling the heating activity of the Bodenheizfläche and measuring the soil temperature to produce a wall temperature which is greater than the soil temperature generated by the Bodenheizfläche.

Thus, a regulation of the wall temperature and the bottom temperature by means of the control unit in combination with the measuring sensor, that is in this case with the two temperature sensors allows. This provides a control loop. The expert understands that in this and in each other

Embodiment of the present invention in the use of a

 Control unit and a sensor, such as a temperature sensor or a flow sensor, a control loop is actually provided.

In another embodiment, the apparatus is configured to process a user specified target wall temperature and a target floor temperature, the apparatus configured to separately control the floor heating area and the wall heating area with respect to their respective heating activity based on these target temperatures. For example, the target wall temperature and / or the target floor temperature may be wirelessly or wired to the device by the user. For example, by means of a remote control unit, a corresponding data transmission to the

Device be caused. For example, the user can enter the desired temperatures via a display of the device according to the invention or via an input field. Or the device may fetch the target temperatures from a data store located inside or outside the device can.

According to a further embodiment, the device is designed to receive data relating to a material of the soil and / or data relating to a material of the wall. Furthermore, the device is designed to automatically based on the received data heating intervals for the

Floor heating surface and the Wandheizfläche to determine separately and to control these separately. In some cases, the heating of the air in the bottom subclimate zone should take place in certain temperature cycles, which should then match the temperature cycles of the wall subclimate zone, in order to allow an ideal exchange of temperature and air under the sub-climates and the environment. This embodiment enables such control of the two heating activities. According to a further embodiment, the at least one control unit controls the bottom heating surface and the wall heating surface such that an alternating activation of the bottom heating surface and the wall heating surface takes place. In a further preferred form of this embodiment, the activation of the

Bodenheizfläche and Wandheizfläche is alternated such that the maximum power consumption is smaller than the sum of the power consumption of the two heating surfaces.

This embodiment plays a role when the available power supply is limited. In particular, this offers a further possibility to further reduce the power consumption.

According to another aspect of the invention, there is provided a program element or computer program which, when executed on a processor, instructs the processor to perform the following steps:

Controlling a heating activity of a Bodenheizfläche a device for drying structures for emitting infrared radiation to a floor of a structure, and controlling a heating activity of a wall heating surface of the wall heating surface to emit infrared radiation to a wall of the structure adjacent to the floor.

According to a further aspect of the present invention, a corresponding computer-readable medium is specified on which such a program element is stored. According to a further exemplary embodiment of the present invention, control data can additionally be stored there.

The program element may be part of a computer program, but it may also be a complete computer program. For example, that can

Program element to be executed as an update of an existing computer program, with which you get through the update to the invention. The computer-readable medium may be considered as a storage medium, such as a USB stick, a CD, a DVD, a data storage unit, a hard disk, or any other medium upon which a program element as described above may be stored. According to another aspect of the present invention, a method of drying structures is disclosed. The process comprises the following steps: Using a floor heating surface to emit

Infrared radiation on a floor of a structure, using a wall heating surface to emit infrared radiation onto a wall of the structure adjacent to the floor, the floor heating surface being angled relative to the wall heating surface in the apparatus, the floor heating surface being directly or substantially immediately adjacent to the wall heating surface, Generating a regulated air flow of heated by the Bodenheizfläche air along the Bodenheizfläche to Wandheizfläche, wherein the Bodenheizfläche laterally one or more spacers for generating a distance of the Bodenheizfläche to the Floor, whereby the Bodenheizfläche and its spacers define a first Subklimazone, and wherein the Wandheizfläche laterally one or more spacers for generating a distance of the Wandheizfläche to the wall, whereby the Wandheizfläche and their spacers define a second Subklimazone.

The present invention comprises as further exemplary embodiments of the method, which are analogous to the exemplary embodiments of the device disclosed herein. According to another aspect of the present invention, a method of drying structures is disclosed. In this case, the method comprises the following steps: controlling a heating activity of a floor heating surface of a

Apparatus for drying buildings to emit infrared radiation to the floor of the structure and controlling a heating activity of a building

Wall heating surface for emitting infrared radiation to a wall of the structure adjacent to the floor.

Furthermore, measuring the wall temperature and measuring the

Soil temperature may be included in the method, wherein by means of controlling the heating activity of the Wandheizfläche, measuring the wall temperature, controlling the heating activity of the Bodenheizfläche and measuring the ground temperature

Wall temperature is generated, which is greater than the soil temperature generated by the Bodenheizfläche. According to another aspect of the present invention, there is provided a method of making a corresponding device.

The invention will be explained in more detail below with reference to the accompanying figures with reference to schematic representations of preferred exemplary embodiments. This also provides further details and advantages of the invention. Brief description of the figures

1 shows a schematic, two-dimensional view of a device for drying structures according to an exemplary embodiment of the present invention.

FIG. 2 shows a schematic, two-dimensional illustration of a device for drying structures according to a further exemplary embodiment of the present invention.

3 shows a schematic flowchart of a method according to an embodiment of the present invention. The illustrations in the figures are schematic and not to scale. In the figure descriptions, the same reference numerals are used for the same or similar elements.

Detailed description of embodiments

FIG. 1 shows a device 100 for drying structures according to an exemplary embodiment of the present invention. The device 100 has a bottom heating surface 101 for emitting infrared radiation to the floor of the structure. Furthermore, a Wandheizfläche 102 is shown which the

Emission of infrared radiation is carried out on a wall adjacent to the floor of the building. It is clearly shown in the figure 1 that the

Floor heating surface 101 immediately adjacent to the Wandheizfläche 102.

As can be seen from FIG. 1, the bottom heating surface 101 and the wall heating surface 102 are wound in the frame 109 of the device 100 so as to be wound against one another. Furthermore, the device knows a first on the Wandheizfläche 102nd arranged temperature sensor 103 for determining the wall temperature. A corresponding temperature sensor 104 for determining the ground temperature is placed on the bottom heating surface 101. The sensors 103, 104 allow

Wall temperature and ground temperature in the sphere of influence of the infrared radiation continuously track. In this case, the drying process by means of

 Bodenheizfläche and Wandheizfläche by a control unit, not shown, which controls the energy input into the wall, are controlled. In addition, sensors for the air temperature, humidity and / or the

Used air flow velocity and used to control the Wandheizfläche and / or the Bodenheizfläche. In Figure 1, the first part of the outer frame 108, the second part of the outer frame 109, the

External connection hole with inner frame 110 and the tab 111 to

Connection / toothing of the device 100 with other identical

Devices. Through this tab, a modular system can be provided in which a plurality of devices 100 are arranged and operated side by side.

The device 100 thus enables a continuous climatic zone from the first to the second sub-climate zone. This means that in this case the air heated at the bottom heating surface 101 can flow continuously and barrier-free along the device 100 towards the wall heating surface 102 and its sublimation zone (see also the embodiment of FIG. 2). This allows an advantageous preheating of the air and the thus generated, regulated air flow allows improved corner drying in buildings. This device 100 provides angled two heating surfaces in one device, so that in operation, a heating surface is directed to the ground and the other to the wall. The heating surfaces 101, 102 are connected so that a continuous air space is created from the bottom to the wall. The heating surface on the floor heats the air, so that it is already warm on the wall. At the same time, heat radiation from the floor and wall heating surfaces overlaps in the critical corner area, so that more heat energy is available here. FIG. 2 shows another device 200 according to another

Embodiment of the present invention. The device 200 allows the generation of an air flow with a preheating of the air at the bottom for improved drying of the corner and / or the wall in the corner. The

 Apparatus 200 is shown in Figure 2 in operation on a floor structure 201 and a wall 202, wherein the wall 202 and the floor 201 are on a raw ceiling 203. The device 200 has a bottom heating surface 204 and a wall heating surface 205. Respective temperature sensors 211 and 212 are connected to a control unit 213. The first sublimation zone 209 is located between the bottom heating surface 204 and the bottom 201, whereas the second sublimation zone 210 is located between the wall heating surface 205 and the wall 202. The first sub-climate zone is bounded at the edge by brushes, which serve as spacers, through the bottom and the bottom heating surface. The same applies to the second subclimatic zone. The heating zone, or the two respectively by the

 Heating surfaces 204, 205 defined Subklimazonen 209, 210 is thus delimited by brushing along the circumference of the heating surfaces. It can thereby be achieved that the corner space can be completely covered by these brushes. These brushes allow beneficial air flow from the first sublimation zone 209 to the second sublimation zone 210. This second sublimation zone extends between the wall and the wall heating surface. The heated surface or surfaces can be delimited by brushing, so that on the one hand little energy loss occurs due to air flow, on the other hand, the moisture from the drying zone, or Subklimazone can escape.

As can be seen from Figure 2, due to the control by the control unit 213, the heating activity of each of the Wandheizfläche and the

Floor heating surface adapted such that a desired air flow 206, 207, 208 is generated along the Bodenheizfläche to Wandheizfläche. This allows the air, which in the critical area of the corner and in the adjoining wall part to cause drying, optimally with regard to its temperature,

Humidity and / or flow rate are regulated. Thus, the targeted convection device 200 is the first one

Sublimation zone 209 executed in the second sublimation zone 210. The control unit is designed for the separate control of the heating activities of the bottom heating surface 204 of the wall heating surface 205. In this case, the respective heating activity comprises the heating power and / or heating times, in particular heating intervals. In a preferred embodiment, the device 200 is designed to generate a wall temperature greater than that through the wall by controlling the heating activity of the wall heating surface, measuring the wall temperature, controlling the heating activity of the bottom heating surface and measuring the bottom temperature

Floor heating surface generated floor temperature. It will be understood by those skilled in the art that in this and any other embodiment of the present invention, a control loop is provided when using the control unit and sensors.

3 shows a schematic flow diagram of a method for drying structures according to an embodiment of the present invention. The method controls in a first step, Sl, the heating activity of a Bodenheizfläche to emit infrared radiation to a floor of a building. In a second step, S2, of the method, the heating activity of a wall heating surface for the emission of infrared radiation is controlled on a wall of the building adjacent to the floor. Thereby, an air flow caused by this control can be generated from the first to the second sublimation zone, which is shown as step S3.

The present invention can be used in principle for various types of drying of structures and is not limited to the specified combination of the features of claim 1 and the dependent claims. In addition, there are other possibilities, individual features, if they are based on the claims, the following description of the Embodiments or directly resulting from the drawing to combine with each other. In addition, the reference of the claims to the

Draw by the use of reference numerals, the scope of the claims in no case limited to the illustrated embodiments.

In addition, it should be noted that "comprising" does not exclude other elements or steps, and "a" or "an" does not exclude a plurality. "It should also be understood that features or steps described with reference to any of the above embodiments are also in combination may be used with other features or steps of other embodiments described above

To look at limitation.

Claims

1. Device (100, 200) for drying of buildings, the

Comprising device

 a Bodenheizfläche (101) for emitting infrared radiation to a

Floor of a building,

 a Wandheizfläche (102) for emitting infrared radiation to a wall adjacent to the floor of the building, and

 wherein the bottom heating surface (101) is angled relative to the wall heating surface (102) in the device (100).

 wherein the bottom heating surface (101) directly or substantially directly adjacent to the wall heating surface (102).

 wherein the apparatus is adapted to generate a controlled flow of air through the bottom heating surface (101) of heated air along the bottom heating surface (101) to the wall heating surface (102).

 wherein the bottom heating surface (101) laterally has one or more spacers (107) for creating a distance of the bottom heating surface from the bottom, whereby the bottom heating surface and its spacers define a first sublimation zone, and

 wherein the wall heating surface (102) laterally includes one or more spacers

(106) for generating a distance of the Wandheizfläche to the wall, whereby the Wandheizfläche and their spacers define a second Subklimazone. 2. Device according to claim 1,

 the device for generating a targeted convection from the first sublimation zone into the second sublimation zone.

3. Device according to one of claims 1 or 2, the first subclimate zone seamlessly and directly into the second

Sublimation zone passes.

4. Device according to one of the preceding claims, the device further comprising

 at least one control unit, and

 wherein the control unit is configured to separately control a heating activity of the bottom heating surface and a heating activity of the wall heating surface. 5. Apparatus according to claim 6,

 wherein the heating activity of the Bodenheizfläche a heating power and / or one or more heating times, in particular heating intervals, the

Includes floor heating surface, and

 wherein the heating activity of the wall heating surface comprises a heating power and / or one or more heating times, in particular heating intervals, of the wall heating surface.

6. Device according to one of the preceding claims, the device further comprising

 a first on or in the Bodenheizfläche arranged temperature sensor

(104) for determining a soil temperature,

 a second temperature sensor (103) arranged on the wall heating surface for determining a wall temperature, and

 wherein the device is designed by means of the first and second temperature sensor for separate temperature monitoring at the bottom and on the wall.

7. Device according to claim 6, wherein the device for continuously measuring the wall temperature and the bottom temperature, in particular a respective maximum temperature, by means of the first and the second temperature sensor is executed. 8. Device according to one of the preceding claims,

 the device being designed to control the

Heating activity of the wall heating surface, measurement of the wall temperature, control of the heating activity of the bottom heating surface and measurement of the ground temperature

To produce wall temperature which is greater than the floor temperature generated by the Bodenheizfläche.

9. Device according to one of the preceding claims,

 the device being for receipt by the user

predetermined target wall temperature and a target floor temperature, wherein the device is designed to, based on the received

Target temperatures to control the Bodenheizfläche and Wandheizfläche separately with respect to their respective heating activity.

10. Device according to one of the preceding claims,

 the apparatus for processing data relating to a

 Material of the soil and / or of data relating to a material of the wall is executed,

 wherein the device is designed to determine based on the data automatically heating intervals for the Bodenheizfläche and Wandheizfläche separately and to control them accordingly.

11. Device according to one of the preceding claims,

 wherein at least one control unit, the Bodenheizfläche and the

 Wandheizfläche such controls that an alternating activation of the

Floor heating and the Wandheizfläche takes place.

12. Device according to claim 11,

 wherein the activation of the bottom heating surface and the wall heating surface is alternated such that the maximum power consumption is smaller than the sum of the power consumption of the two heating surfaces.

13. A method of drying structures, comprising the method

Using a floor heating surface (101) to emit

Infrared radiation on a floor of a structure,

 Use a Wandheizfläche (102) for the transmission of

 Infrared radiation on a wall of the structure adjacent to the floor, and

 wherein the bottom heating surface (101) is angled relative to the wall heating surface (102) in the device (100),

 wherein the bottom heating surface (101) is directly or substantially directly adjacent to the wall heating surface (102),

 Generation of a regulated air flow of air heated by the bottom heating surface (101) along the bottom heating surface (101) to the wall heating surface (102),

 wherein the bottom heating surface (101) laterally has one or more spacers (107) for creating a distance of the bottom heating surface from the bottom, whereby the bottom heating surface and its spacers define a first sublimation zone, and

 wherein the wall heating surface (102) has laterally one or more spacers (106) for creating a distance of the wall heating surface from the wall, whereby the wall heating surface and its spacers define a second sublimation zone.

14. A program element that, when executed on a processor, instructs the processor to perform the following steps:

Controlling a heating activity of a Bodenheizfläche (101) of a device for drying buildings to emit infrared radiation to a Floor of a building (Sl), and

 Controlling a heating activity of a Wandheizfläche (102) for emitting infrared radiation to a wall adjacent to the floor of the building (S2). 15. The program element according to claim 16, which when on a

 To run the processor that instructs the processor, follow these steps

perform:

 Measuring the wall temperature,

 Measuring the soil temperature, and

 wherein the program element is designed to, by means of control of

Heating activity of the wall heating surface, measurement of the wall temperature, control of the heating activity of the bottom heating surface and measurement of the ground temperature

To produce wall temperature which is greater than the floor temperature generated by the Bodenheizfläche.

A computer-readable medium having stored thereon a program element that, when executed on a processor, directs the processor to perform the following steps:

 Controlling a heating activity of a Bodenheizfläche (101) of a device for drying structures for emitting infrared radiation to a floor of a building (Sl), and

 Controlling a heating activity of a Wandheizfläche (102) for emitting infrared radiation to a wall adjacent to the floor of the building (S2).