WO2007006422A1 - Apparatus and method for determining the energy input into a room by a radiation source - Google Patents

Abstract

The invention relates to a method for determining the energy input into a room (10). Said method comprises the following steps: - the irradiation in the direction of at least one external face (10a, 10b, 10c) of the room encompassing at least one window (12) is determined by means of at least one radiation sensor (20); - the window area on each face (10a, 10b, 10c) of the room (10) is determined; and the energy input is calculated from the radiation power determined with the aid of the radiation sensors (20) integrated over time and the window area. In an advantageous further embodiment of the inventive method, the amount of heat dissipated into the room via the convection of the window area is calculated from the difference in temperature between the internal face of the window pane and the room temperature as well as from the size of the window pane and is taken into account for determining the energy input into a room. The invention also relates to an apparatus for determining the energy input into a room (10) by a radiation source. Said apparatus comprises at least one radiation sensor (20) in the direction of at least one external face (10a, 10b, 10c) of the room encompassing at least one window (12) as well as an evaluation unit (50) which can be connected to the radiation sensors (20). Said evaluation unit calculates the energy input from the window area and the radiation power that is determined by means of the radiation sensors (20) and is integrated over time.

Description

description

Apparatus and method for determining the energy input into a room by a radiation source

The invention relates to a device and a method for determining the energy input into a room by a radiation source.

Dimensioning methods and control devices for heating, ventilating and air conditioning systems which are used in rooms (for example rooms, buildings or vehicles) are known. The dimensioning of heating, ventilation and air conditioning systems is based on different parameters such as the size of the room, insulation, types of use, external and internal heat sources or energy efficiency. The disadvantage, however, is that the external energy that is entered into the room is not o- only on the basis of standard table values is taken into account, which can lead to the fact that systems are installed in their performance over time not the actual requirements of the object and correspond to its use, so that then an increased energy consumption, an inappropriate distribution or even a temporarily insufficient energy supply can result, as would be necessary for the room. This leads to restrictions in the comfort, the provision of heat or cold in the right place at the right time for typical or special conditions unfavorable plant utilization or additional costs for oversized or unfavorable operated equipment.

Also known are various devices and methods for controlling in rooms (eg rooms, buildings or vehicles) arranged heating, ventilation and air conditioning systems. For this purpose, the temperature in the room to be heated or cooled is ideally determined and the thermostat of the system is regulated accordingly. A disadvantage of the known systems is that the control is usually based solely on the determination of the room temperature and foreign energy that is registered in rooms, can not directly consider or capture. As a result, the heating, ventilation or air conditioning is not optimally controlled because, for example, a room in which additional external energy is entered, less heating must be used as a room in which no external energy is entered. If the external energy is considered only indirectly, thus more heating power is provided than is needed, which can reduce the efficiency of the heater. It is therefore desirable to be able to plan or optimize a heating, ventilating or air conditioning system, in particular with regard to its dimensioning, its degree of utilization and its configuration for each external energy input at any temperature at the heating or air conditioning and for each temperature in the corresponding room ,

It is therefore an object of the invention, the external energy, which is registered for example by sunlight through the windows of a room (eg, rooms, buildings or vehicles) in a room, to order a heating, ventilation or air conditioning or the like for a New installation or replacement can be optimally dimensioned or optimally regulated during operation.

The object is achieved by a device for determining the energy input according to claim 1 and a method for determining the energy input according to claim 13.

Advantageous developments and refinements of the invention are specified in the subclaims.

The inventive method for determining the energy input into a room has the following steps. Initially, at least one room outside (eg wise building, room or vehicle outside), which has at least one window, at least one radiation sensor attached. In order to determine the energy input, it is preferable to consider only the outside of the room, at which solar radiation can also occur to a decisive extent. If, for example, outer sides of buildings are constantly shadowed by neighboring buildings, these outer spaces, even if they have windows, do not necessarily have to be provided with a radiation sensor, since no appreciable energy input takes place.

For the attachment of the at least one radiation sensor in the direction of at least one room outer wall, the following alternatives exist. Either at least one radiation sensor is arranged on the corresponding outer space sides, or a radiation sensor package consisting essentially of a cuboid on which radiation sensors are arranged on each surface except the bottom surface and, if necessary, surfaces for which no relevant irradiation is expected , arranged on an unshaded place, for example on the top of the room.

With these radiation sensors, the incident radiation is determined over time. In addition, the window area on the associated side of the room is determined. The energy input then results from the radiation detected by the radiation sensors over time and the associated window area per room or building. If the solar radiation is determined in W / m ² and the window area in m ² , the energy input as the integral of the value determined for the solar irradiation over the time multiplied by the value of the window area, for example in the unit kWh / m ² .

The determination of the energy input into a room, such as a room, a multi-room building or a vehicle interior, allows the To determine the energy balance of the room and the energy difference that must be additionally applied by a heater or air conditioning in order to achieve or maintain a predetermined room temperature to determine. In the case of individual rooms, buildings or vehicle interiors, the input of external energy is generally essentially determined by the solar radiation incident through the window. Thus, the external energy input to be considered can be determined by determining the energy input which results from the irradiation, in particular the solar radiation, over time on the different sides of the room and the window area lying on these sides. The use of at least one radiation sensor on at least one outer side of the room, which has a window, thereby carrying the different solar radiation depending on the position of the sun and z. B. weather-related shadowing bill.

The method according to the invention can optimize the degree of utilization of a heating or an air conditioning system in the following way. For example, since a room in which the sun is shining through a window is already heated by the sunlight, less power or work of the heating is required to heat the room to the predetermined final temperature. By taking into account the external energy input only the differential energy is requested by the heater, so that lower losses occur, whereby the degree of utilization of the heating is improved. Furthermore, the knowledge of foreign energy inputs into a room over time (any cycle over seconds, hours, days, weeks) allows a correspondingly optimized technical and energetic room management, for example, for a building, a vehicle or a ship. In particular, from measured radiation progressions, for example from the radiation progressions in the preceding days, in particular the preceding two days, an extrapolation for predicting the energy for the object cooling or heating or reduction of control fluctuations can take place in advance. Should z. B. in a building, a heating, ventilation or air conditioning are installed, the determined with the device according to the invention data on the extraneous heat input, which are determined for example over a day or a week to be used for optimal configuration of the system to the system not to be larger than necessary and thus save investment and energy costs.

In a preferred embodiment of the invention, an additional contribution to the energy input caused by convection is calculated from the difference temperature determined from the internal temperature of the pane of the window and the internal temperature of the room, which is integrated over time, and the window area. Thus, a higher accuracy of the delivered result is achieved.

Preferably, at least one data acquisition device is provided for detecting the determined irradiation.

In a further advantageous embodiment of the invention, at least one evaluation unit for determining the energy input is provided from the radiation power determined with the radiation sensors, which is integrated over time, and the window area.

Preferably, further characteristic data of the room, preferably the volume and / or storage masses and / or building material characteristics and / or U-values, are recorded, since these likewise have effects on the energy input and should therefore be taken into account. Preferably, the energy inputs caused by heating and / or ventilation and / or air conditioning systems already installed in the room are recorded over time as characteristic data of the room. In an advantageous development of the invention, the method according to the invention for determining the energy input into a room is used to determine the dynamic heating or cooling process of a room, wherein in addition to the determined radiation energy input further meteorological data over time can be detected. Particularly in the case of existing buildings, which are to be optimized, rehabilitated or retrofitted, the use of the present method for determining the dynamic heating or cooling processes lends itself to determining the influence of the solar radiation in order to obtain the new heating, ventilation and cooling systems. optimal configuration of ventilation or air conditioning systems.

The heating or cooling process of a room, in particular a building or building parts, takes place in particular depending on meteorological data such as position of the sun, direction and shading effects and thus the course of solar radiation on the outer surface of the room, outside temperature, inside temperature, surface temperature, humidity, wind speed , Air exchange data, the maximum and / or minimum outside temperature determined during the last years, for example the last four years, the maximum and / or minimum solar radiation detected during the last years, for example the last four years, and others meteorological data and preferred other characteristic sizes of the room itself such as Storage factors of the materials used, U-values for walls and roofs, room types and / or other heating, ventilation and / or air conditioning systems that already supply energy into the room. Therefore, some of these data are preferably taken into account and, for example, detected by corresponding sensors on the inside and / or outside of the room over time in order to be able to determine from these the cooling or heating process as a function of time.

Preferably, the energy input and the further meteorological data and / or the other characteristic Data collected over a period of 24 hours or a period of several 24-hour cycles to determine the dynamic heating or cooling process as a function of the course of the day and optimally dimension the heating, ventilation and / or air conditioning systems or to be able to configure.

The device according to the invention for carrying out the method according to the invention comprises at least one radiation sensor in the direction of at least one outer space side with at least one window and at least one evaluation unit, which can be connected to the solar sensors. The radiation sensors detect the radiation, in particular the solar radiation, over time. Taking into account the respective window areas, the evaluation unit determines the respective energy input through each window by integrating the radiation power over time. The evaluation can be carried out directly after recording a single measured value of the radiation sensors or after recording a series of measured values of the radiation sensors.

An advantageous embodiment of the device according to the invention additionally has a data acquisition device. The data acquisition device detects the data supplied by the radiation sensors and records them over time. The values for the irradiation ascertained in certain periods of time can thus be detected and stored either in the data acquisition device or in associated storage and / or evaluation units and if necessary also directly evaluated.

By integrating the radiation power over time periods, the energy inputs during certain time periods, for example of a few hours, and in particular periodically fluctuating energy inputs during the course of the day, can be taken into account by the control of the heating or of the air conditioning system. Furthermore, the energy entries can also be determined over a whole day or a week in order to correctly dimension or parameterize a heating, ventilation or air conditioning system, taking into account the expected energy inputs or the energy inputs occurring at the measuring time.

If a window has a plurality of radiation sensors, it may be advantageous to provide an evaluation unit for each window, which determines the energy input into the respective window from the data supplied by the radiation sensors of a window by suitable averaging and forwards the results obtained to a further evaluation unit, which collects the results from all windows and thus all the radiation sensors and, if appropriate, reuses them accordingly.

In an advantageous embodiment of the invention, at least one radiation sensor is arranged in each window of the room. Thus, it can be taken into account that the input radiation, in particular the solar radiation, may also be different for windows lying on one side, since, for example, different windows of one room are shaded by trees, while other windows on the same side are illuminated directly by the sun , The energy input into the different windows of a page can thus be determined more precisely, which is particularly important if, for example, the windows belong to different rooms of a building in which different final temperatures are to be achieved by heating, cooling or ventilation.

If the radiation sensor is arranged on the outside of the window or on the outside of the room on a wall surface, to accurately determine the energy input into the room, the radiation passage through the window pane must be taken into account, in which energy losses occur. The actual energy input into the room is included a function of the angle of incidence of the radiation on the windowpane, permeability of the window, reflection and absorption of the radiation and the duration of the incident radiation. For the exact determination of the energy input into the room thus the knowledge of a variety of factors is necessary, which brings a lot of effort. Preferably, the radiation sensor is therefore arranged on the inside of the window directly behind the window pane, particularly preferably parallel to the window pane, so that these factors are automatically taken into account and only the radiation power actually falling into the room is measured by the radiation sensor over time , After multiplication with the window area, the energy input into the room results directly without further calculations.

The radiation sensor preferably has a temperature sensor for determining the internal pane temperature. When the solar radiation passes through the window pane, the window pane is heated by absorption of the radiation, which results in the window pane acting as a convection surface. This effect depends on the temperature difference between the room interior temperature and the window pane interior temperature. In order to be able to take into account the convection caused by the warming up of the window pane, it is therefore necessary to determine the window pane interior temperature. For precise determination of the convection caused by the heating of the window pane, the device according to the invention preferably additionally has a temperature sensor for detecting the internal temperature of the room.

At least two solar sensors can be arranged in each window of a room (for example, rooms, buildings, vehicle interior), since even a single window can only be partially shaded. This problem especially occurs

Rooms with large windows, for example, in winter gardens, on. If only one sensor were arranged in a window, which would be directly exposed to the sun while much of the window was in shadow, the energy input from the solar radiation detected by the radiation sensor and the corresponding window area would differ significantly from the actual energy input. Two or more radiation sensors can determine the solar radiation at different locations of the window, and the energy input can be determined from a suitably formed mean value of the solar radiation measured by the various radiation sensors. These radiation sensors are preferably arranged at different heights and / or diagonal angles of the window. It should be noted that, when arranged directly at an angle, shading of the radiation sensor by the window frame or an additional heat source could be exposed by radiation, so that preferably the radiation sensors are arranged at an appropriate distance from the window-covering components.

The radiation sensor is preferably a solar sensor, so that it is particularly suitable for the special requirements in the measurement of the radiation, in particular the solar radiation.

Preferably, at least one further sensor is arranged on the outside of the room for acquiring meteorological data. This enables the determination of the energy input into a room to determine the dynamic heating or cooling process of a room, which depends on the weather conditions outside the room and thus on meteorological conditions

Data depends.

The invention will be explained below with reference to the embodiments illustrated in the figures. It shows

1 shows a perspective view of a house equipped with an embodiment of the invention, Figure 2 is a perspective view of a house equipped with a second embodiment of the invention,

Figure 3 is a schematic representation of a window equipped with a third embodiment of the invention and

Figure 4 is a schematic representation of a window equipped with a fourth embodiment of the invention and a schematic representation of the evaluation unit.

Figure 1 shows a perspective view of a house 10 with a front side 10a, a longitudinal side 10b and a roof surface 10c. Both the front side 10a and the longitudinal side 10b each have two windows 12, while only one window 12 is arranged in the roof surface 10c. For example, the two windows 12 in the longitudinal side 10b of the house

10 an area of 4 m ² , the window 12 in the front 10a on the ground floor an area of 6 m ² , the window 12 in the front 10a in the gable a surface of 1.5 m ² and the window 12 in the roof surface 10c an area of 1 m ² .

In order to be able to determine the energy input through the windows 12 into the house 10, a radiation sensor 20, which is preferably designed as a solar sensor, is arranged on the end face 10a, the longitudinal side 10b and the roof surface 10c. Alternatively, a radiation sensor package could be arranged consisting of a substantially cuboidal element on an unshaded point of the house 10, for example on the gable of the roof surface 10c, whose side surfaces extend substantially parallel to the side and roof surfaces of the house 10, wherein the side surfaces of the element radiation sensors are arranged. By such a radiation sensor package can also Solar radiation from the different directions are detected.

The outer sides of the house 10, which have no windows, for example the non-visible outer sides of the house 10, are not taken into account in the determination of the energy input, since the energy input through masonry, in contrast to the energy input through window surfaces, is negligible.

Outside of the house 10, which are constantly shadowed by adjacent buildings, for example, can also be disregarded, so that the effort to determine the energy input into the house 10 remains as low as on a shadowed side of a room no significant energy input through the windows there is produced.

From the radiation sensor 20 on the end face 10a of the house 10, a solar radiation of 400 W / m ^{2 is} detected. The radiation energy input into the larger window 12 with a window area of 6 m ² is thus 400 W / m ² * 6 m ² = 2400 W, while the radiation energy input into the smaller window 12 with a window area of 1.5 m ^{2 is} 600 W. The radiation sensor 20 on the long side 10b of the house 10 registers a solar radiation of 700 W / m ² . The radiation energy input into each of the two windows 12 with a window area of 4 m ² is thus 2800 W. The radiation sensor 20 on the roof surface 10 c of the house 10 measures a solar radiation of 850 W / m ² , so that the radiant energy input through the window 12 in the roof area 10c is 850W.

In this calculation, it was first assumed that the radiation sensors 20 are arranged on the outside of the windows 12. In this case, however, it is to be considered that of the solar energy impinging on the windows 12 a part is reflected, a part is absorbed and only a part is introduced as transmission energy into the interior behind the window 12. The energy input actually introduced into the interior space behind the window 12 is a function of the angle of incidence of the radiation on the window pane, the permeability of the window, reflection and absorption of the radiation and the duration of the incident radiation. In order to avoid a complex calculation taking into account the heat transfer coefficients, etc., the radiation sensors 20 are arranged directly behind the windows 12 on the inside of the windows 12, so that these factors are taken into account automatically and only by the radiation sensors 20 Window 12 is measured in the underlying interior radiation power.

The solar energy absorbed by the windows 12 leads to an increase in the temperature of the window pane. The window 12 then acts as a function of the temperature of the inside of the window 12 and the interior temperature of the behind

Window 12 lying interior as Konvektionsflache for the interior. In order to be able to take account of this convection, the radiation sensors 20 have a temperature sensor, not shown, for determining the temperature of the inside of the window 12. Furthermore, a device for determining the internal temperature of the behind the window 12 lying interior is provided. The possible consideration of the convection, which results from the difference temperature between the inside temperature of the window pane and the inside temperature of the room behind it over time and the window area, increases the accuracy of the determination of the energy input into the respective room. The consideration of convection is part of the determination of the energy input in the respective room in an advantageous embodiment of the invention. The determination of the radiant energy input through windows 12 on a side 10a, 10b, 10c of the house 10 becomes inaccurate if, as shown for example in Figure 2, the windows 12 on a side 10a, 10b, 10c are shaded differently. The same parts in the other figures 2 to 4 are designated by the same reference numerals as in Figure 1.

Next to the house 10 is a tree 30, which throws a shadow 35 on the house and thus shadows the right of the two windows 12 in the longitudinal side 10b of the house 10. If the radiant energy input through this window 12 were now calculated based on a solar sensor 20 directly lit by the sun, the determined radiant energy input would be significantly too large and too little power would be required by a room-operated heater or too much from an air-conditioned air conditioner Performance requested. Therefore, in the second exemplary embodiment illustrated in FIG. 2, a radiation sensor 20 is arranged in each window 12. While the radiation sensor 20 arranged in the unshaded window 12 on the longitudinal side 10b of the house 10 detects a solar radiation of 700 W / m ² and the radiation energy input into this window 12 continues to be 2800 W as in the first embodiment, the radiation sensor detects 20 in the shadowed by the shadow 35 of the tree 30 windows 12 of the longitudinal side 10 b of the house 10 a solar radiation of only 100 W / m ² , so that the radiation energy input into this window 12 calculated to 400 W.

Again, as in the exemplary embodiment according to FIG. 1, the radiation sensors 20 can be arranged on the outside or the inside of the windows 12, but preferably on the inside of the windows 12.

In order to be able to take into account a partial shading of the windows 12 in the determination of the radiation energy input, according to the third embodiment shown in FIG. For example, two radiation sensors 20 are arranged in the window 12. In this case, the radiation sensors 20 are located in the lower left and upper right corners of the window 12 shown in FIG. 3. In order to prevent shadowing effects or heat radiation effects by the window surround components, the radiation sensors 20 are arranged at a certain distance from the window surround components. A shade 40 partially covering the window 12, which is thrown, for example, from the roof overhang of the house 10, runs horizontally and thus parallel to the top and bottom edge of the window 12. The radiation sensor 20 in the upper right corner is thus shaded and detects, for example Solar radiation of 100 W / m ² , while the radiation sensor 20 in the lower left corner is still exposed to the sun and registered a solar radiation of 700 W / m ² . A suitable mean value for the radiation energy input through this window 12 is determined as follows: The illustrated window 12 is one of the windows 12 in the longitudinal side 10b of the house 10 shown in FIGS. 1 and 2 with an area of 4 m ² . It is assumed that the radiation sensor 20 in the lower left corner of the window 12 provides a value of solar radiation representative of the lower half of the window 12, while the radiation sensor 20 in the upper right corner of the window 12 provides one for the upper half of the window 12 representative value registered. The instantaneous radiation energy input into the window 12 is thus determined to be 700 W / m ² * 2 m ² + 100 W / m ² * 2 m ² = 1600 W.

Again, as in the embodiments according to FIG. 1 or 2, the radiation sensors 20 can be arranged on the outside or preferably on the inside of the windows 12.

In order to determine the determined radiation energy input, especially for very large glass surfaces, which, for example, in winter gardens can occupy entire outer space surfaces, even more precisely can, the use of further radiation sensors 20 is possible. For example. For example, in a fourth exemplary embodiment shown in FIG. 4, four radiation sensors 20 are arranged in the window 12 along the left-hand side edge of the window 12. The radiation sensors 20 are equidistantly arranged so that the upper radiation sensor 20 provides a representative of the solar radiation for the upper quarter of the window 12, while the second radiation sensor 20 provides from above a representative of the solar radiation for the second quarter from above. Similarly, the two lower radiation sensors 20 each provide a representative of the solar radiation for the third and fourth quarters of the surface of the window 12.

FIG. 4 additionally shows an evaluation unit 50, which is connected to the four radiation sensors 20 of the window 12, which registers the values measured by the radiation sensors 20 for the solar radiation and evaluates them accordingly. In the evaluation unit 50 it is deposited, which area the window 12 has in total and which radiation sensor 20 registers for which partial area of the window 12 a value of the solar radiation. The evaluation of the values for the solar irradiation determined by the radiation sensors 20 can take place either directly after recording a single measured value or after taking a series of measured values by the evaluation unit 50.

If additional windows 12 have to be taken into consideration in the room to be heated, cooled or ventilated, the evaluation unit 50 can be connected to further radiation sensors 20 by further windows 12 or it forwards the registered data to a further evaluation unit which stores all data from all of them to take into account windows collects and reuses.

In addition, in another embodiment of the invention, a data acquisition device (not shown) is provided. which is able to supply the values measured by a single connected radiation sensor 20 for certain periods of time, for example over a few hours or over a whole day, and to add, if necessary, in the control of the heating and ventilation - Or air conditioning or for dimensioning such in a room, in particular in the house 10, to be incorporated installation. This data acquisition device can be integrated in the radiation sensor 20 or the evaluation unit 50 or connected to the radiation sensor 20 or the evaluation unit 50 as an external data acquisition device. Such a data acquisition device is not necessary when the radiation sensors 20 are connected directly to a control of a system and based on the direct control by the radiation sensors 20.

However, each of the windows 12 in the exemplary embodiments according to FIG. 1 or 2 can be provided with radiation sensors 20 according to one of the embodiments in FIGS. 3 or 4 or with further arrangements of different numbers be equipped by radiation sensors 20 depending on the expected shadowing.

If several rooms are located in a building, a preferred embodiment of the invention, not shown, can be seen to provide for each room a radiation sensor, which according to the preceding embodiments is preferably arranged in the window or one of the windows and particularly preferably on the inside of the window area , as usually one radiation sensor per room is sufficient to be able to determine the radiation energy input into this room due to the solar radiation power with sufficient accuracy. The method according to the invention for determining the radiation energy input into a room can be used to determine the dynamic heating and cooling processes of a room in a further method. These processes take place in dependence on the energy input into the room, whereby further meteorological influences and possibly also characteristic data of the room itself must be taken into account. For this purpose, the meteorological data as well as any other characteristic data are recorded over time. The meteorological data include, for example, the sun gear, the direction, shading effects, the wind speed, the humidity and the outside, inside and surface temperature of the room and the maximum and / or minimum outside temperature, which during the last years, for example the last four years , was determined and the maximum and / or minimum solar radiation, which was also determined during the last years, for example, the last four years. Other characteristic data of the room include storage factors, U-values of the walls and roofs of the room, nature, location and size of the window areas, which do not change over time, and other internal heat gains or losses from already installed ones Heating, ventilation and / or air conditioning systems are generated time-dependent.

In order to record this data, in the embodiments described above, in addition to the radiation sensors 20, further corresponding sensors for detecting the data on the house 10, either like the radiation sensors 20 in the windows 12 or on the outside walls of the house 10, can be arranged and with corresponding data acquisition devices and Evaluation units are connected. Depending on the size to be determined, these sensors are arranged both on the outside of the house 10 and on the inside of the house. In particular, both on the inside of the windows 12 and on the outside of the windows are 12 radiation sensors for determining the solar radiation. All data, which are determined by the various sensors are detected time-dependent, in particular in 24-h cycles with the corresponding data acquisition device, so as to be able to determine the dynamic heating and cooling processes using one or more evaluation.

Claims

claims

1. A device for determining the energy input into a room (10) by a radiation source with

- At least one radiation sensor (20) in the direction of at least one outer space side (10 a, 10 b, 10 c), which has at least one window (12), and

- An evaluation unit (50) which is connectable to the radiation sensors (20), wherein the evaluation of the calculated with the radiation sensors (20) radiation power, which is integrated over time, and the window area calculates the energy input.

2. Device according to claim 1, characterized in that the device has a data acquisition device which detects the data supplied by the at least one radiation sensor (20) over time.

3. Apparatus according to claim 1 or 2, characterized in that in each window (12) of the space (10) at least one radiation sensor (20) is arranged.

4. Device according to claim 1, 2 or 3, characterized in that the at least one radiation sensor (20) on the inside of the window (12) of the space (10) is arranged.

5. Device according to one of the preceding claims, since you rchgeke nn zeic hn et, that the at least one radiation sensor (20) has a temperature sensor for determining the temperature of the inside of the window (12).

6. Device according to claim 5, characterized in that a temperature sensor for detecting the internal temperature of the room (10) is provided.

7. Device according to one of the preceding claims, since there is at least two radiation sensors (20) arranged in each window (12) of the space (10).

8. Device according to claim 7, characterized in that in each window (12) of the space (10) two radiation sensors (20) are arranged, which are arranged in two diagonally lying angles of the window (12).

9. Device according to one of the preceding claims, since it can be checked that at each window (12) of the room (10) at least two radiation sensors (20) are arranged at different heights.

10. Device according to one of the preceding claims, since it is not possible that the room is a room, a building or a vehicle interior.

11. Device according to one of the preceding claims, since it can be checked that the radiation sensor (20) is a solar sensor.

12. Device according to one of the preceding claims, characterized in that at least one further sensor is arranged on the outside of the room for acquiring meteorological data.

13. A method for determining the energy input into a room (10) comprising the steps of: - determining the irradiation with at least one beam in the direction of at least one outer space (10a, 10b, 10c), which has at least one window (12),

Determining the window area on each side (10a, 10b, 10c) of the space (10) and

- Calculation of the energy input from the radiation power determined with the radiation sensors (20) integrated over the time and the window area.

14. A method according to claim 13, wherein at least one radiation sensor (20) is arranged in each window (12) of the room (10).

15. The method according to claim 13 or 14, characterized in that the at least one radiation sensor (20) is arranged on the inside of the window (12) of the space (10).

16. Method according to claim 13, wherein the at least one radiation sensor (20) has a temperature sensor for determining the temperature of the inside of the window (12).

17. Method according to claim 13, wherein a temperature sensor is provided for detecting the internal temperature of the room (10).

18. Method according to claim 16 and 17, since it is immediately apparent that an additional contribution to the energy input caused by convection results from the difference determined from the internal temperature of the window pane (12) and the internal temperature of the room. temperature, which is integrated over time, and the window area is calculated.

19. The method according to any one of claims 13 to 18, d a d u r c h e c e n e c e s in that in each

Window (12) of the space (10) at least two radiation sensors (20) are arranged.

20. The method according to claim 13, wherein at least one data acquisition device is provided for detecting the determined irradiation over time.

21. The method according to claim 13, wherein at least one evaluation unit is provided for determining the energy input from the radiation power determined with the radiation sensors over time, and the window area.

22. The method of claim 13, wherein the room is a room, a building or a vehicle interior.

23. The method according to any one of claims 13 to 22, since it c h e c e c e s that more characteristic data of the space, preferably the volume and / or storage masses and / or building material characteristics and / or U-values are detected.

24. Method according to claim 23, wherein as characteristic data of the room the energy inputs caused by heating and / or ventilation and / or air conditioning systems already installed in the room are recorded over time.

25. A method for determining the heating or Abkühlvorgangs a room, wherein the energy input into the room after the Method according to one of claims 13 to 24 is determined and additionally further meteorological data over time are detected.

26. The method according to claim 25, wherein a further meteorological data is used to record the course of solar radiation on the outer surface of the room and / or the profile of the outside temperature of the room and / or the course of the internal temperature of the room.

27. The method according to any one of claims 25 to 26, since you rhgekennzeic hn et, that as further meteorological data, the course of the wind speed of the room and / or the course of the humidity in the room and / or the course of the surface temperatures of the room and / or air exchange data are recorded.

28. The method according to claim 25, wherein the energy input and the further meteorological data are transmitted via a

Period of 24 h or a period of several 24 -h cycles are recorded.

29. Method according to claim 28, wherein a further characteristic data is recorded over a period of 24 h or a period of several 24 h cycles.