DE102008061087B4 - Process and device arrangement for the acquisition and evaluation of indoor climate data - Google Patents

Abstract

Method for recording and evaluating indoor climate data, with the following steps: - Measurement of a first humidity and a first temperature at a neutral point of a room; - Determination of a first dew point τtheo at the neutral point from the first humidity and the first temperature; second temperature at a cold point in the room; determination of a second dew point τ cold at the cold point from the second humidity and the second temperature; comparison of the first dew point τ theom with the second dew point τ cold; and evaluation of the indoor climate based on the comparison of the two dew points τtheound τcold.

Description

The invention relates to a method for acquiring and evaluating room climate data. The invention also relates to a device arrangement for carrying out such a method.

Modern and modernized buildings often suffer from insufficient air changes. The room climate can quickly become too humid due to modern insulation. CO ₂ enrichment through breathing air then often leads to permanent tilting of the windows and permanent ventilation due to reduced comfort. Classic and unrenovated building fabric, on the other hand, often suffers from stronger temperature contrasts between the indoor air and the inner room boundary surfaces (inner surfaces of the room walls, especially the outer walls). In both cases there is a potential for strongly increased humidity and possibly condensation at so-called cold points within the living environment.

With long-term temperature control of the cold points close to or below the dew point, there is a risk of mold formation. This risk increases if the room temperature is permanently below 18 ° C due to continuously insufficient heating.

In the accompanying 1 the risk areas for condensation and mold formation depending on the relative room humidity and the temperature of the inner wall surface (cold point) are shown as an example for an average room temperature of 20 ° C. Corresponding diagrams can be created for other mean room temperatures.

In many cases, there is a specific need for clarification as to whether and to what extent mold pollution is the sole result of insufficiently renovated or damaged building fabric on the one hand and / or the heating behavior of the apartment users not adapted to the energetic state of the building on the other. Corresponding assessments are usually not or not clearly possible with a single humidity measurement at any point, but must at least refer to the temporal course of mean humidity and temperature as well as to heat sinks in the living space.

From the DE 19 932 549 B4 a method and an arrangement for determining the relative humidity at any point within a thermodynamic boundary layer on the surface of a measurement object are known. By means of a probe, which has two sensors arranged at a defined distance and thermodynamically separated from one another, the relative humidity is measured at two points spaced apart from the surface of the measurement object. From this the humidity gradient is formed, from which the relative humidity at any point between the surface and the sensor of the probe closer to the surface can be calculated.

The DE 10 2006 032 858 A1 describes a method and a device for the controlled ventilation of a room. For this purpose, a maximum permissible relative humidity within the room is calculated and compared with a relative humidity measured within the room. To calculate the maximum permissible relative humidity, temperature and relative humidity are measured inside and outside the room and passed on to a control unit for evaluation together with a calculated minimum heat transfer coefficient of the room.

The DE 19 952 519 A1 proposes a control for a fan, which is provided for venting a room. The control takes into account situations in which the partial pressure of the air outside the room is greater than the partial pressure of the room air. To determine the partial pressures, temperature and humidity sensors are used, including a surface temperature sensor attached to the inside of a room edge or corner.

The DE 33 00 389 A1 shows a device for measuring the climate values, especially in living rooms, bedrooms and work rooms. The device has devices for measuring the air temperature and humidity, which are arranged in a common housing with a connection to the power supply network and with a microprocessor that records the measured air temperature and humidity values and constantly calculates comfort coordinates from the air temperature and relative humidity. When the limit values in the preprogrammed comfort zone are reached, electrical warning lights for the instructions »HEATING«, »VENTILATION« and »COOLING« light up on the housing. The device has socket connections for electronic remote sensors for measuring temperature, relative humidity and / or CO ₂ content of the room air and / or the temperature and humidity of the surrounding walls.

The object of the invention is to enable a meaningful assessment of a room climate in a living environment.

This object is achieved by a method for recording and evaluating indoor climate data with the features of claim 1 and by a device arrangement set up to carry out the method with the features of claim 10. Advantageous and expedient developments of the method according to the invention and the device arrangement according to the invention result from the subclaims.

• - Messung einer ersten Feuchte und einer ersten Temperatur an einem Neutralpunkt eines Raumes;
• - Bestimmung eines ersten Taupunkts τ_theo am Neutralpunkt aus der ersten Feuchte und der ersten Temperatur;
• - Messung einer zweiten Feuchte und einer zweiten Temperatur an einem Kaltpunkt des Raumes;
• - Bestimmung eines zweiten Taupunkts τ_cold am Kaltpunkt aus der zweiten Feuchte und der zweiten Temperatur;
• - Vergleich des ersten Taupunkts τ_theo mit dem zweiten Taupunkt τ_cold; und
• - Bewertung des Raumklimas auf der Grundlage des Vergleichs der beiden Taupunkte τ_theo und τ_cold.

In its most general form, the method according to the invention comprises the following steps:

• - Measurement of a first humidity and a first temperature at a neutral point of a room;
• - Determination of a first dew point τ _theo at the neutral point from the first humidity and the first temperature;
• - Measurement of a second humidity and a second temperature at a cold point in the room;
• - Determination of a second dew point τ _cold at the cold point from the second humidity and the second temperature;
• - Comparison of the first dew point τ _theo with the second dew point τ _cold ; and
• - Evaluation of the indoor climate based on the comparison of the two dew points τ _theo and τ _cold .

The indoor climate data obtained on the basis of the dew point determinations and comparisons can be documented and submitted to an evaluation, which over a longer period of time provides an objective assessment of the indoor climate with regard to the spatial distribution of temperature and humidity as well as the possible effects caused by this, in particular the risk of condensation and mold formation on boundary surfaces and cold spots.

In principle, such conclusions are not possible through temperature and humidity measurements exclusively at a neutral point. This is only possible to a limited extent through the sole measurement of a humidity and a temperature directly at a cold point. In this case, there is no reliable knowledge of the mean room temperature and room humidity, i.e. the source or cause of the humidity cannot be clearly qualified and quantified: it could come from the masonry itself or from particularly warm and humid room air.

The present invention, on the other hand, comprises a combined specific compilation, arrangement and procedural evaluation of humidity and temperature sensors as well as proposals for their integration into commercially available measurement technology.

The invention therefore also relates to a device arrangement set up to carry out the method according to the invention. The device arrangement according to the invention comprises a first sensor device for measuring a first temperature and the first humidity at the neutral point of the room, a second sensor device for measuring a second temperature and the second humidity at the cold point of the room, and a remote data processing device for comparing the first dew point τ _theo with the second dew point τ _cold and to evaluate the room climate on the basis of the comparison of the two dew points τ _theo and τ _cold .

• 1 ein exemplarisches Diagramm zur Kondenswasser- und Schimmelpilzbildung bei einer mittleren Raumtemperatur von 20°C; und
• 2 eine erfindungsgemäße Vorrichtungsanordnung zur Erfassung und Auswertung von Raumklimadaten.

Further features and advantages of the invention emerge from the following description and from the accompanying drawings, to which reference is made. In the drawings show:

• 1 an exemplary diagram for condensation and mold formation at an average room temperature of 20 ° C; and
• 2 a device arrangement according to the invention for recording and evaluating room climate data.

This in 1 The diagram shown has already been explained in the introduction to the description.

With the in 2 The device arrangement shown schematically is used to record climate data of a room. For this purpose, sensor devices are arranged at various points in the room.

A first sensor device 10 comprises a first humidity sensor and a first temperature sensor. The first sensor device 10 is arranged at a so-called neutral point of the room. In the context of the invention, a neutral point is to be understood as a point in the room at which predominantly medium and little variable humidity and temperature values occur and where neither heat sources or sinks nor moisture sources or sinks are to be expected. A typical neutral point of a living space is the proximity to the ceiling in the middle of the room, usually the preferred mounting point for fire or smoke alarm devices. In the illustrated embodiment, therefore, is the first sensor device 10 into a smoke alarm device 12 integrated.

A second sensor device 14th comprises a second humidity sensor and a second temperature sensor. The second sensor device 14th is arranged at a so-called cold point of the room. Cold spots or cold bridges in the context of the invention are primarily to be understood as the points in a heated room which are usually the lowest temperatures and possibly the have the highest water content. Typical cold spots are room corners and the inner surfaces of external walls with inadequate thermal insulation and possibly additional water that has penetrated. Cold spots generally represent the heat sinks in a heated living environment.

An optional third sensor device 16 comprises at least one third temperature sensor which is arranged at a so-called hot spot of the room. For the purposes of the invention, hot spots are to be understood as the heat sources in a living environment, ie radiators or other heating surfaces whose temperatures are at times well above the interior temperature. In the illustrated embodiment, the third temperature sensor is part of a radiator 18th attached electronic heat cost allocator 20th that is thermally attached to the radiator 18th is coupled. A customary electronic heat cost allocator usually has a further (fourth) temperature sensor which is arranged on the side of the heat cost allocator facing away from the radiator, that is to say on the side of the heat cost allocator facing the room.

The method according to the invention is first described using a two-point model. At the neutral point and at the cold point, the first sensor device 10 or with the second sensor device 14th continuously (at regular or irregular intervals) the humidity and temperature are measured. The relative humidity at the location of the measurement can be calculated from the measured absolute humidity and the temperature. In addition, the dew point is calculated at this point. The dew point is generally the temperature to which air that is not completely saturated with water vapor would have to be cooled so that it is completely saturated (corresponds to a relative humidity of 100%).

The measured values at the neutral point are regarded as representative values for the mean room temperature T _R and the mean room humidity r _R , because the neutral point is usually tempered solely by the room air. Even when windows and doors are temporarily opened, incoming cold air will primarily flow in near the floor and be heated there directly so that the conditions at the neutral point are not directly affected.

As a first approximation, a minimum dew point τ _theo can be calculated from the humidity at the neutral point, which theoretically indicates the temperature below which moisture condensate (condensation water) could form at a point in the room. This theoretical dew point τ _theo is compared with the dew point τ _cold derived at the cold point, the cold point being regarded as representative of the coldest point in the room.

Corresponds to the theoretical dew point τ _theo in about the dew point derived on the cold spot τ _cold, it means that the temperatures of the inner wall surfaces T _W are close to the middle room temperature T _R. The room air and the room boundary surfaces are almost equally warm, so that no condensation is to be feared. In this case, it can be concluded that the cold point is well insulated from the outside.

On the other hand, if the walls are poorly insulated and if there is an additional high moisture content in the building structure, the dew point τ _cold derived at the cold point is increased compared to the theoretical dew point τ _theo and the wall temperature T _{W is} usually significantly lower than the mean room temperature T _R.

The gradients between the dew points τ _theo and τ _cold and between the temperatures T _R and T _W are used by the underlying model to identify and quantify the risk of condensation and mold formation at the neuralgic cold points. On the basis of the gradients, the room boundary surfaces can be evaluated in terms of their (undesirable) property as heat sinks for the interior. Depending on how pronounced the depressions are, conclusions can be drawn quantitatively about the (negative) quality of the thermal insulation, i.e. about the quality of the building fabric and its proportion of mold formation potential.

A more extensive comparative evaluation of the temperature gradients on the one hand and dew point gradients on the other hand (at or near the cold point) also provides a criterion for the detection of possible water damage in the building structure: an above-average moisture content in the wall increases the dew point τ _cold significantly at the cold point the actual difference between τ _cold and surface temperature T _W there again falls substantially below the value that would result from the cooling of the moist room air alone. The measurement parameters of the neutral point are used as a measure of room humidity and room temperature.

The two-point model described above can be achieved by including the third sensor device 16 can be extended to a three-point model. The third and possibly the fourth temperature sensor enable the active heating energy input of the associated room heating surface (radiator 18th ). The same applies, of course, to other space heating surfaces / hot spots; however, the term three-point model is retained.

In practice, the heat energy input can be qualitatively and quantitatively with the help of the electronic heat cost allocator 20th to be determined. For this purpose, the electronic heat cost allocator 20th Relative consumption data produced anyway on the basis of the continuous temperature measurements are used. In addition to the operating temperature of the radiator 18th the further (fourth) temperature sensor of the electronic heat cost allocator can 20th continuously provide the prevailing room temperature at leg height as additional information. According to the practiced two-sensor measuring principle (according to DIN / EN 834 ) a relative measure for the energy output of the radiator can be derived from this.

By expanding to the three-point model, the heating energy input can be included qualitatively and quantitatively in the assessment of the room climate. Well-founded statements can therefore be made about whether and how much a room is actively heated and - after combination with the data from the first and second sensor devices 10 or. 14th and corresponding evaluation - how the active heating behavior is presented in the balance against possible structural defects.

The evaluation of the measurement data and the data in the sensor devices 10 and 14th or in the electronic heat cost allocator 20th The calculated data and the assessment of the room climate based on it takes place in a remote data center. For this purpose, the measurement and / or evaluation data relevant for evaluating the room climate are optionally provided by the first sensor device 10 , the second sensor device 14th , the electronic heat cost allocator 20th and / or fed to a separate data collector (via cable or radio) and stored there. From there, the stored data are sent to a remote data processing facility 22nd transmitted, preferably by means of a GSM-based GPRS transmission service.

According to a further development of the invention, data from a weather service can also flow into the assessment of the room climate, so that the local and temporally changing climatic conditions can be taken into account in the form of a weather adjustment.

Claims (15)

Method for acquiring and evaluating room climate data, with the following steps: measurement of a first humidity and a first temperature at a neutral point of a room; - Determination of a first dew point τ _theo at the neutral point from the first humidity and the first temperature; - Measurement of a second humidity and a second temperature at a cold point in the room; - Determination of a second dew point τ _cold at the cold point from the second humidity and the second temperature; - Comparison of the first dew point τ _theo with the second dew point τ _cold ; and evaluation of the indoor climate based on the comparison of the two dew points τ _theo and τ _cold . Procedure according to Claim 1 , characterized in that the determination and the comparison of the two dew points τ _theo and τ _cold are repeated at regular or irregular intervals. Procedure according to Claim 1 or 2 , characterized in that the first humidity and a first temperature at the neutral point or the second humidity and a second temperature at the cold point are each measured in combination. Procedure according to Claim 3 , characterized in that a room temperature gradient formed from the first room temperature and the second room temperature is compared with a dew point _gradient formed from the first dew point τ _theo and the second dew point τ _cold . Method according to one of the preceding claims, characterized in that a heating input is also taken into account in the assessment of the room climate. Procedure according to Claim 5 , characterized in that a third room temperature is measured at a hot point to determine the heat input. Procedure according to Claim 5 or 6th , characterized in that the determination of the heat input takes place on the basis of consumption data from a heat cost allocator (20). Method according to one of the preceding claims, characterized in that for the evaluation of the room climate relevant measurement and / or evaluation data of a first sensor device (10) for measuring the first temperature and the first humidity, a second sensor device (14) for measuring the second temperature and the second humidity, a heat cost allocator (20) and / or a separate data collector and stored there. Procedure according to Claim 8 , characterized in that the stored data are transmitted to a remote data processing device (22), in particular by means of a GSM-based GPRS transmission service. Device arrangement, set up for performing the method according to one of the preceding claims, with - a first sensor device (10) for measuring a first temperature and a first humidity at the neutral point of the room, - a second sensor device (14) for measuring a second temperature and a second Humidity at the cold point of the room, as well as - a remote data processing device (22) for comparing the first dew point τ _theo with the second dew point τ _cold and for evaluating the indoor climate based on the comparison of the two dew points τ _theo and τ _cold . Device arrangement according to Claim 10 , characterized in that the first sensor device (10) is integrated in a fire or smoke alarm device (12). Device arrangement according to Claim 10 or 11 , characterized by a heating cost allocator (20) for determining a heat input on the basis of the temperature measurements made in the heating cost allocator (20) and / or the consumption data determined by the heating cost allocator (20). Device arrangement according to one of the Claims 10 to 12 , characterized by a data collector with a memory in which the measurement and / or evaluation data relevant to the assessment of the room climate are collected and stored. Device arrangement according to Claim 13 , characterized in that the data collector has an interface for transmitting the stored data to the remote data processing device (22). Device arrangement according to Claim 13 or 14th , characterized in that the data collector (22) is integrated in the first sensor device (10), the second sensor device (14) or the heating cost allocator (20).

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