SK6802001A3 - Method and device for detecting an opened window - Google Patents

Abstract

Method involves measurement of temperature and or airflow velocity variations in the air near a radiator or similar. The temperature and or velocity are measured with a probe whose response time is short relative to the time the window is open. The amplitude and frequency of the temperature and velocity measurement variations are analyzed to determine if a window has been open or shut. An Independent claim is made for a device for determination of when a ventilating window has been opened, etc. The device comprises a sensor (2) for measurement of temperature and or velocity variations and a sensor signal processing and analysis device (5). The sensor can be a hot-wire or hot-film anemometer or can be a dual function temperature sensor which is heated with an electrical current with a change in temperature caused by an airflow used to determine airflow velocity and temperature.

Description

Technical field

The invention relates to a method for detecting the ventilation of a window in a heated room by detecting changes in the temperature or the velocity of the ambient air as well as a suitable device.

BACKGROUND OF THE INVENTION

To save valuable heating energy, it is advisable to minimize the heat output of the room's heating surfaces when ventilating through windows. A particularly great effect can be achieved if the heating surfaces of the room are located in the immediate vicinity of the windows. With conventional thermostatic valves, this is achieved by manually closing the thermostatic valves. With an electronic control device, the closing of the valve can be automated when the corresponding detection of the ventilation by the window is impeded.

There are known systems which evaluate in time the decreasing temperature course during window ventilation. However, this often results in inadequate results, since the corresponding temperature sensor often does not directly detect the cold air, since the position of the sensors cannot in principle be arbitrarily selected. In addition, the temperature does not decrease continuously, as turbulences occur due to the mixing of the incoming cold air and the warm air of the room. Therefore, during the cooling phase, the rising temperature may possibly be incorrectly recognized. Finally, the temperature difference between the room temperature and the outside temperature is often so small during a long transition period that temporary small drops in the room temperature are no longer properly interpreted by the temperature sensor.

It is therefore an object of the invention to allow safe and reliable detection of window opening and the like.

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SUMMARY OF THE INVENTION

This task is solved in the above method by essentially measuring the temperature and / or flow rate during the measurement period and determining the mean temperature and / or flow rate and analyzing the amplitude and / or frequency of deviations from the mean temperature waveform and / or flow rates.

The basis of the invention is the discovery that two air jets overlap when the window is opened: so-called heated air on the heater and suction of cold ground air. the air cylinder overlaps the incoming cold outside air by means of forced flow. This creates a vortex flow and turbulence, which are significant in the vicinity of the heating surfaces of the room, i.e. the heating elements. The hot and cold air streams are vortexed in such a way that the time-varying temperature component is transferred over the central local temperature curve locally. By measuring the amplitude and / or frequency of deviations from the normal temperature or flow rate, a permanent change in ambient variables can be reliably derived therefrom, for example initiated by opening a window. In particular, temperature and flow rate measurements can be combined. Measured values that are not directly correlated to one another are then available, which allow particularly reliable detection of the opening of the window due to redundancy.

To determine the temperature change, the temperature amplitude is determined according to the invention, the deviation from the mean temperature is determined, and the frequency of the deviations is analyzed. Due to the mixing of cold and warm air, the trapped temperature profile during ventilation changes more strongly than when the window is closed. These fluctuations are reliably investigated by determining amplitude and frequency.

Preferably, a temperature sensor with a short response time is also used to measure the temperature amplitude in short time intervals.

To determine the variation in flow velocity, the velocity amplitude is determined and the deviation from the mean flow velocity is determined. From the magnitude of the amplitude of the deviation it is possible to determine the opening of the window, since such deviations are in

31710 / T enclosed spaces do not occur. Typical heating flow velocities for a heater are approximately 0.4 to 0.8 m / s, the flow boundary layer being relatively thin. The speed depends on the upper temperature and the height of the heater. A flow rate of 0.8 m / s is achieved, for example, with a radiator with a surface temperature of 70 ° C and a height of 1 m. Additionally, the frequency of the flow velocity deviations can also be analyzed to reliably record turbulence at the flow velocity.

According to the invention, an anemometer, for example a thermal wire anemometer or a thermoelectric spherical (multidirectional) anemometer, is used to measure the flow velocity. According to a further particularly preferred embodiment, however, the temperature sensor is heated by a current pulse, cooling it with ambient air and determining the time course of the electrical resistance sensor. This sensor is characterized by low current consumption and simple technical construction compared to anemometers. This sensor is therefore particularly suitable for battery-powered systems. Due to the small size and large surface area of the sensor, it also responds quickly enough to changes in the temperature of the ambient air.

Fourier analysis serves for simple analysis of amplitude and frequency variations.

Preferably, the determined deviations are recorded in the form of statistical parameters such as mean, standard deviation and the like, so that the determined parameters of the other deviations can be compared.

Additionally, the mean temperature and / or flow velocity gradient may be determined to provide additional information about changes in these environmental variables. In particular, a combination of temperature and flow velocity measurements can also be performed, in which variations in amplitude or frequency are determined in each case, thereby permitting a particularly reliable reverse conclusion with regard to the cause of the variations in the ambient variables.

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Further, the invention relates to a device for detecting window ventilation based on detecting changes in temperature or ambient air flow rate with at least one sensor for measuring temperature amplitude and / or adjustable flow rate. The amplitude and / or frequency of deviations from the mean temperature and / or flow velocity are analyzed by means of the sensor signal processing device.

An anemometer, such as a thermal wire anemometer, a thermoelectric anemometer with a spherical (multidirectional), a temperature-dependent pulse current temperature sensor or a fluctuation sensor, in particular a short response time temperature sensor, can be used as the sensor. In particular, the latter two sensors are of simple technical construction and can therefore be used in equipment at low cost. The measuring device may also comprise a combination of several such sensors.

The sensor may have a low pass filter to process its output signals.

Preferably, the sensor signal processing device is a program-controlled computer device storing programs for evaluating the sensor signal. This can, for example, be carried out with the aid of a so-called. “Fuzzy-Seed * followed by“ When - Then - Ask ”.

According to the invention, the sensor signal processing device may also comprise an integration device for determining the mean temperature and / or mean flow rate which integrates the temperature and / or flow rate over a longer period and determines the average value relative to the integration time.

In addition, the sensor signal processing device preferably comprises a recording device for recording measured values and parameters which are thus available for later comparison.

According to a special embodiment, a control and control device, connected by wire or by radio to the device, is also designed for the device

31710 / T • · for processing the sensor signal, especially for opening and closing the motorized radiator valves. In this way, the window ventilation detected by the device can be immediately adjusted in the heating control on the motorized thermostatic valve.

The invention will now be described with reference to the drawings and examples.

BRIEF DESCRIPTION OF THE DRAWINGS

The figures show:

Fig. 1 schematically the construction of a device for detecting changes in environmental variables; and

Fig. 2 shows the temperature curve with the window closed and open.

DETAILED DESCRIPTION OF THE INVENTION

The device 1 comprises a sensor 2, which is located near the heating surface formed by the heater 3 and the window 4. The sensor 2 is connected to the sensor signal processing device 5.

When the window 4 is opened in the heated room, the cold outside air flows into the room while being mixed with the free air convection cylinder. This happens mainly near the window 4 and the heater 3, where a sensor 2 is also located to record changes in the ambient variables. The sensor 2 can be an anemometer, for example, to record the flow rate of the surrounding air. In this case, the sensor 2 is preferably an electronic temperature sensor which is heated by a current pulse and cooled by the ambient air. The time course of the electrical resistance sensor is then evaluated in the sensor signal processing device 5.

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Alternatively or additionally, the sensor 2 may also be an intelligent fluctuation sensor which consists of a temperature sensor with a short response time. Thus, the amplitude of the temperature can be measured in short successive time sequences, whereby the frequency of deviations from the mean temperature curve can be analyzed in addition to the amplitude in the sensor signal processing device 5. The analysis is preferably performed in the arithmetic logic unit 6 of the sensor signal processing device 5 formed as a computer device. The known Fourier analysis method and programs utilizing it can be used. In addition, the sensor signal processing device 5 comprises an integration device 7 and a recording device 8. In the integration device 7, the measured values may be transmitted sequentially by the sensor in order to obtain a mean temperature curve. For this purpose, the sensor 2 may have at its output a low-pass filter (not shown) which smooths the signal.

The recording device 8 makes it possible to store the statistical parameters calculated by the arithmetic logic unit, such as the mean value and the standard deviation of the calculated deviation from the mean temperature curve, thereby allowing the sensor signal processing device 5 to compare the sensor signal over longer periods of time.

When window ventilation is detected by the sensor signal processing device 5, the arithmetic logic unit 6 can send a signal to the control and control device, which is located on the thermostatic valve of the heater 3, and has a motor for controlling the thermostatic valve. Thus, the radiator valve can be closed when the window is opened, thus avoiding unnecessary heat dissipation. When the closing of the window is determined based on a corresponding change in temperature and / or flow velocity which has been detected by the sensor 2, the control and control device 9 can reopen the valve on the heater 3.

Although in the schematic representation the sensor 2, the sensor signal processing device 5 and the control and control device 9 are shown

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as separate elements, they can be integrated, for example, in a housing and placed directly on the valve of the heater 3.

It is also possible to place the sensor 2 in a location in a room that is particularly sensitive to changes in temperature and / or flow velocity and to establish a wired or radio connection to a separate sensor signal processing device. Also, a connection can be established between the sensor signal processing device 5 and the control and control device 9 by a wired or radio link.

In FIG. 2 shows the temperature curve with the window open and closed as a function of time. The curve T1 shows the temperature curve measured on the sensor 2 with a short sampling time of several seconds. As opposed to the temperature T2 in the control and control device 9, which is shielded in comparison to the turbulence in the vicinity of the heater 3, it is possible to recognize distinctly higher RF frequencies during the window opening time F during T1. On the other hand, when the window is closed, the temperature curve T1 is essentially constant and is only affected by slight changes in amplitude. As demonstrated by the experiments, changes in the sampling period do not adversely affect the outcome of the T1 temperature measurement as long as the sampling period relative to the window opening time F is short. Therefore, the temperature curve T1 is very well suited for detecting window opening.

Thus, by analyzing the amplitude and / or frequency of deviations from the temperature and / or flow velocity, it is possible to ventilate the windows in the heated rooms reliably and safely, and optionally to operate electronic control devices for closing and opening the heater valve.

Claims (16)

* 1. A method of recognizing window ventilation in heated rooms by detecting changes in temperature and / or flow rate, such as temperature and Okol ambient air velocity, characterized in that the temperature and / or velocity are measured as a function of time, and the mean temperature and / or velocity is determined and the amplitude and / or frequency deviations of the individual measured values from the mean are analyzed temperature and / or flow velocity. Method according to claim 2, characterized in that a temperature sensor with a short response time is used to measure the temperature amplitude at short intervals. Method according to claim 1, characterized in that an anemometer, preferably a thermal wire anemometer or a thermoelectric spherical (multidirectional) anemometer is used to measure the flow rate. T Method according to claim 1, characterized in that the temperature sensor is heated by a current pulse, in which it is cooled by ambient air, and that the time course of the electrical resistance sensor is determined. Method according to one of the preceding claims, characterized in that a Fourier analysis of the measured values is carried out for the analysis of the amplitude and the frequency of the deviations. 31710 / T ········································· Method according to one of the preceding claims, characterized in that the calculated deviations are converted into statistical parameters such as mean, standard deviation and the like. Method according to one of the preceding claims, characterized in that a gradient of the mean temperature and / or flow rate is determined. Apparatus for detecting window ventilation in heated rooms by detecting changes in temperature and / or ambient air velocity with at least one sensor (2) for measuring temperature amplitude and / or velocity at an adjustable frequency and with a sensor signal processing device (5) to analyze the amplitude and / or frequency of deviations from the mean temperature and / or flow rate Device according to claim 8, characterized in that the sensor (2) is an anemometer, such as a heat-wire anemometer or a thermoelectric spherical (multidirectional) anemometer. Device according to claim 8 or 9, characterized in that the sensor (2) is a pulse current temperature sensor with a temperature-dependent resistance. Device according to one of claims 8 to 10, characterized in that the sensor (2) is a fluctuation sensor, in particular a sensor with a short response time. Device according to one of Claims 8 to 11, characterized in that a low-pass filter is provided on the sensor (2). 31710 / T · · · · · · · · · · • · • · • • • • with · • · · · • • · · · • • • · ·· • · ·· • · · • • e • · • • ·· · Device according to one of claims 8 to 12, characterized in that the sensor signal processing device (5) is a program-controlled computer device. > Device according to one of claims 8 to 13, characterized in that the sensor signal processing device (5) comprises an integration device (7) for determining the mean temperature curve and / or the mean flow rate. Device according to one of claims 8 to 14, characterized in that the sensor signal processing device (5) comprises a recording device (8) for storing the measured values and parameters. Device according to one of Claims 8 to 15, characterized by a control and control device (9) for opening and closing the motorized radiator valves, which is connected by wire and / or radio to the sensor signal processing device (5).