WO2007131998A1

WO2007131998A1 - Sensor assembly for measuring a subjective temperature

Info

Publication number: WO2007131998A1
Application number: PCT/EP2007/054685
Authority: WO
Inventors: Maximilian Fleischer; Uwe Lampe; Roland Pohle; Elfriede Simon
Original assignee: Siemens Aktiengesellschaft
Priority date: 2006-05-17
Filing date: 2007-05-15
Publication date: 2007-11-22
Also published as: DE102006023181A1

Abstract

The invention relates to a sensor assembly for measuring a subjective temperature, consisting of at least two temperature sensors. At least one first temperature sensor (1) is not or is only negligibly influenced by thermal radiation or humidity or an air flow and generates a first ambient temperature signal (3) that is not affected by the aforementioned elements. At least one second temperature sensor (2), corresponding to the first, reacts in response to thermal radiation or humidity or the air flow, or to a combination of all said elements and generates a second temperature signal (4) of a subjective temperature. A differential signal (5) between the first and the corresponding second sensor temperature signal represents a measurement of the absorbed thermal radiation or existent humidity or existent air flow. The assembly can be used in a temperature measurement system for regulating heating or air conditioning systems.

Description

description

Sensor arrangement for measuring a subjective temperature

The invention relates to a sensor arrangement for determining a subjective or sensed temperature, wherein in addition to a room or air temperature further environmental influences are taken into account.

The well-being and health of people are determined to a considerable extent by the ambient temperature. Heaters and air conditioners make it possible for people to create an optimal climate indoors. This optimal climate is characterized by a number of parameters, which are in principle accessible to a control by an air conditioner. The most important parameters to be controlled are, for example, the temperature, the humidity or the air flow. The effect of these individual parameters on the welfare of the people do not each sufficient in itself, but because the Pa ^¬ parameters influence each other, must be the interaction of all factors considered.

An optimal control of a room climate requires that the variables to be controlled are first accessible to a measurement. Numerous technical solutions are available for measuring room temperature. It is known to control heating systems to use the mere room or air temperature. The measurement of the ambient temperature describes al-lerdings poorly perceived by persons Tempe ^¬ ture that is perceived, for example via the contact between air and skin. Since the related Tempe ^¬ raturempfindung to locally occurring on the skin effect is based, as a whole, not all parameters that are gen ^¬ for a perceived temperature to berücksichti included in the considerations with. In particular for the control of heating systems an ambient temperature is thus used as a control variable, which is generated by temperature measurements, the essential order ^¬ gebungseinflüsse not detected and thus the well- being of persons not berücksichtiget total.

The invention has the object of providing a Sensoranord ^¬ voltage that detects a subjective temperature and sets this relatively unaffected peraturmessung to the room or Lufttem-.

The solution of this object is achieved by the feature combination ^¬ nation according to claim 1. Advantageous Ausgestal ^¬ obligations are described in the subclaims.

Temperatures beyond mere room temperature or air temperature measurement result, for example, from the additional measurement of the infrared radiation which acts in the space under consideration or on the person under consideration. Furthermore, air flow of the moisture can be taken into account. Air flow leads to a reduction in the surface temperature of the skin and thus to a lowering of the subjective, perceived temperature. Moisture on the skin, for example, leads to a lowering of the subjective, perceived temperature by evaporation cold. Infra-red radiation incident on the skin leads to a local increase in the temperature on the skin and thus to an increase in the subjective, perceived temperature.

The ambient temperature is generally considered to be optimum, excluding other factors influencing the temperature perception in a range of approximately 18-22 ° C. However, the subjective part of the temperature sensation can not be directly recorded as a measured variable.

An essential aspect of the present invention consists in the approximately simultaneous generation of a plurality of temperature signals, on the one hand by means of a first temperature sensor, wherein an ambient or room or air temperature is reproduced, and secondly by means of a second temperature sensor, which represents a sensed temperature, which in addition to the previously known temperature determination further influences of radiation effects, moisture effects,

Air flow effects u. Ä. considered. A sensor arrangement determines a difference signal between these at ^¬ the generated temperature signals, wherein a measure of the influence of the recorded heat radiation or existing humidity or existing air flow is displayed on the sensed temperature by the resulting difference signal.

In addition to the three effect parameters for radiation, humidity and air flow, other influencing factors can be taken into account. Conceivable occupancy for example, under ^¬ schiedliche Textures of surfaces, a surface with ice or condensed water or the Physiolo gical ^¬ property of the skin.

An advantageous embodiment relates to the Ausfüh ^¬ tion of a first and a second temperature sensor, which differ in terms of their surface properties. The first temperature sensor for measuring the air temperature in this case has a reflective surface, so that thermal radiation plays a subordinate role at its surface. The second temperature sensor has on its surface a heat radiation strongly absorbing surface, so that the subjective, sensed temperature can be detected at this temperature sensor. In this variation, thus the effect of thermal radiation or infrared radiation is considered to be ^¬ additionally to the pure air temperature measurement.

It is particularly advantageous to design the surface of a temperature sensor which strongly absorbs the heat radiation as the ideal black body, so that the absorption is approximately 100%. The same direction is followed when a first temperature sensor is provided with a cover which prevents the action of directed to the sensor array heat radiation.

To take account of existing in a room air humidity, it is advantageous to use a temperature sensor Upper ^¬ superficially hydrophobic form, so that the air temperature without influence of moisture is determined. The entspre ^¬ accordingly second temperature sensor is equipped with a surface made ^¬, which is hydrophilic, so that moisture creates there. This second temperature sensor measures the felt

Temperature taking into account the existing humidity.

If two sensors are equipped with different thermal coupling to the environment in an advantageous manner, then a sensor is operated thermally insulated. If it is heated from the outside by heat radiation, it can not release the heat introduced to the outside to the outside. The corresponding second sensor is coupled to a heat sink or heat source and can partially dissipate the amount of energy radiated in, so that a measured value of this sensor or of this sensor arrangement is less affected by the impinging radiation than in the case of the thermally insulated sensor.

A respectively generated from the claimed sensor assembly difference signal, which includes information about existing next to the room temperature factors such as thermal radiation, humidity, air flow, can be used as a control variable in an advantageous manner in a heating system ^¬ the.

Exemplary embodiments are described below on the basis of schematic figures which do not limit the invention:

FIG. 1 shows a schematic illustration of a sensor arrangement for detecting the sensed temperature, FIG. 2 shows the shielding of a sensor element from the effect of radiation by a cover,

FIG. 3 schematically shows the function of the sensor for detecting heat losses in a heating system,

Figure 4 shows the radially symmetrical arrangement of tempera ^¬ tursensoren for direction-independent measurement,

FIG. 5 shows the structure of a sensor arrangement according to FIG. 4 for direction-dependent measurement,

FIG. 6 shows the radially symmetrical arrangement for direction-independent measurement, whereby the influencing variable-moisture-is taken into account,

FIG. 7 shows an exemplary embodiment which includes a first temperature sensor maintained at a constant temperature, the temperature of a gas flow being measured in order to take into account the influence of the cooling of the gas flows.

To the perceived personal wind chill grasp ^¬ to it, a local measurement of the location of the person is necessary. Since the ge for the perceived temperature rash ^¬ inputting parameters such as solar radiation and the window. Ä. can change small-scale, not only the measurement of the room temperature or the air temperature is sufficient. The following measurement methods can be applied to ^¬.

The influence of infrared radiation on the perceived temperature (subjective temperature) is measured by a combination of two temperature sensors with different interaction with infrared radiation. When impinging infrared radiation on this combination of sensors increases the Temperature of the sensor with stronger interaction on infrared radiation vigorously, which increases the sensor with less interaction on infrared radiation less. The difference between the two measured temperature values is a measure of the influence of the incident radiation on a person, since their temperature perception depends both on the room or air temperature and on the amount of heat radiated. Thus, information is obtained ture over a perceived tempera ^¬, where two signals, the temperature of the ambient air and wind chill are taken.

In a particular embodiment, two sensors are used which have different surfaces. While the measured value of an ideally mirrored or in the infrared and visible spectral range well reflective temperature sensor is not affected by impinging infrared radiation, as this is completely reflected in a strongly absorbing temperature sensor, a large part of the incident infrared radiation is converted into heat, resulting in an increase Temperature compared to the mirrored or white sensor leads. It makes use of the fact that a body with a white surface is ideally regarded as a heat ray reflecting body and a body with a black surface as an ideal heat ray absorbing body.

In a further development, it is provided that alternatively two identically designed black temperature sensors are used, whereby a radiation input is prevented for a sensor by this sensor being shielded by a cover.

In another variant, a thermostatic sensor is provided. This means that one of at least two sensors is kept at a predetermined temperature. With this embodiment, the case of a reduction of the subjective temperature can be detected by local heat losses by means of radiation to the environment. The function provides that a thermostat is applied to the body temperature. holding the black body, the energy is measured to stabilize the temperature and as a measure of the influence of the heat loss to the environment on the perceived tempera ^¬ ture is related. If, for example, two sensors are used with different thermal coupling to the environment, then a temperature sensor can be operated in a thermally insulated manner and thus be heated when irradiated, without giving off heat to the outside. The additional sensor is coupled to a heat sink or to a heat source and can dissipate most of the radiated energy, so that the measured value of this sensor is less affected by the incident radiation as in the thermally isolated sensor.

Is operated by means of the proposed sensor arrangement in which at least a pair of sensors at the same time, first two temperature sensors are used, the Annae are ^¬ hernd the same structure, however, the absorption of heat radiation at relevant points differences, moisture, or for example, an air flow zei ^¬ gene. Thus, a relatively pure temperature signal is generated on the one hand, which, di rect ^¬ heat radiation or convection is corrupted ideally not by moisture. The other sensor also measures the above-mentioned disturbance variables and thus includes for a person who is in a room climate, significant factors in the perception of a subjective or perceived temperature.

The proposed arrangement thus allows for the first time the inclusion of the temperature sensation significantly influencing infrared radiation in heating and air conditioning systems. By sensing the sensed temperature, control strategies for heating and air conditioning systems can be optimized to locally capture the optimum environmental conditions for a person's well-being, and to reduce the space heating energy demand by taking into account the increase in temperature caused by solar radiation. A possible variant for a sensor system according to the invention is shown in FIG. There are two Temperatursenso ^¬ ren 1, 2 used, the absorbent, each having an infrared radiation and an infrared radiation reflective coating are provided. The difference signal contains on the one hand the temperature signal 3 for the room or air temperature ^¬ tur and the temperature ^signal 4 for the subjective or ge ^¬ felt temperature. The difference signal contains, in addition to the individual sensor signals or temperature signals 3, 4 information about the radiated ^{Infrarotstrahlungs ¬} amount.

In Figure 1, the temperature sensors 1, 2 are formed differently by being in the direction of the incident infrared radiation / heat radiation 6 in the case of the temperature sensor 1 with a heat radiation reflective coating and in the case of the temperature sensor 2 with a heat radiation ab ^¬ sorbing coating. The actual temperature sensor elements could be, for example, NTC or

PTC elements, as well as thermocouples or platinum tempera ^¬ ture sensor. These are provided with different coatings, which have the highest possible degree of reflection for heat radiation and thus are suitable for measuring the ambient temperature without the radiation component and on the other hand have the highest possible absorption coefficient with respect to the heat radiation, so that they the ambient temperature and in addition the above Thermal radiation capture introduced temperature. The heat radiation is usually in the infrared spectral range. Highly absorbent materials are z. As carbon black or 'palladium black' (palladium oxide) or, platinum black '(platinum oxide).

Alternatively, the formation of one of two identical sensor elements by suitable design of the housing is possible, as shown schematically in Figure 2. FIG. 2 again shows the thermal effect 6 incident on the two described sensors. By means of a cover 9 is one of the two identical sensors, in this case sensor 1 kept free by the cover 9 of the heat radiation 6. Since both identical sensors are temperature sensors 2 with absorbing surface 7, the uncovered sensor in this case will indicate the room temperature and additionally the temperature increase that is produced by the incident heat radiation. The temperature sensor 2 appearing on the left in FIG. 2 is covered by the radiation and thus indicates the room or ambient or air temperature under ideal conditions. Electrical contacts for the removal of electrical signals are not shown in Figure 2.

Figure 3 illustrates a schematic operation of the sensor for de- tektion heat loss is. It should be noted, that can be used to coat the temperature sensors materials chosen as a surface for the intended ^¬ thermostatic body can be used. The heating can be done electrically, wherein when using materials with a temperature-dependent electrical conductivity by measuring the electrical resistance in addition to the determination of the heating power can be done simultaneously, the determination of the temperature, as shown in Figure 3.

Figure 3 shows the scheme of a heating control, wherein as

Controlled variable, the electrical heating of a heated elemen ^¬ tes to a certain temperature via a temperature measurement is controlled and flows through the heating control. The output signal can be used to control electrical power to the heater.

In order to achieve a direction-independent temperature measurement, the temperature sensor elements may be of spherical construction and, for example, like FIG. 4, the sensor 1 may be reflective coated with a reflecting surface 8 and correspondingly with an absorbing surface 7. In any case, a radially symmetric Arrangement Darge ^¬ provides that can measure direction independent. FIG. 5 shows a structure for direction-dependent measurement. In order to protect the sensors mechanically and against the action of high-frequency radiation, they can be covered with a material which is permeable to the infrared region, for example with silicon.

The following embodiment is described for measuring the influence of an existing measured temperature on a conventionally measured temperature:

The humidity affects the heat capacity and thermal conductivity ^¬ the air. These contributions are considered by the ^¬ be written arrangements. In addition, the occupation of surfaces with moisture is determined by the moisture content of the air. Cold on the occurrence of evaporative ^¬ can have on the well-being moisture major negative impact. A measurement of the evaporative cooling can be realized by a system of a hydrophobically coated and a system which is similar to a skin covered with moisture, while for the hydrophobically coated sensor, the evaporation cold is negligible, the signal of the hydrophilic sensor also the local temperature changes Play or contain evaporation.

FIG. 6 shows correspondingly temperature sensors S1, S2, which have a hydrophobic coating 12 or a hydrophilic coating 11, respectively. Due to the radially symmetric Anord ^¬ voltage one direction-independent measurement is possible.

Reference to a schematically depicted in Figure 7 system, an embodiment for handling the heat Trans ^¬ can port relationships with existing gas flow along the at least two temperature sensors are illustrated. The arrangement shown can be used to measure the air flow. In this case, part of the heat radiated by the first temperature sensor, which is kept at a constant temperature, is absorbed by gas flowing past it. men. This leads to a change in the gas temperature. A sensor mounted at a certain distance second temperature sensor undergoes a Temperaturände ^¬ tion, which depends on the gas flow and thus serves as a measure for the gas flow in the flow past the gas. In addition, the energy which is used for stabilization ^¬ the temperature of the first temperature-stable element capitalization need be detected. This can represent the heat loss or entry,

Claims

claims

1. Sensor assembly for measuring a subjective temperature comprising at least two temperature sensors, of which: - at least a first temperature sensor (1) is a non or only slightly influenced by heat radiation or moisture or air flow of an undisturbed first Tem ^¬ peratursignal (3) Environment generated, - at least one second to the first corresponding Tempe- ratursensor (2) with respect to the heat radiation or humidity or air flow or a combination thereof is associated with significant interactions, a second temperature signal (4), which is influenced by environmental parameters, generated, - wherein a combination signal (5) between a first and at least a second corresponding temperature sensor signal is a measure of the subjectively perceived temperature.

2. Sensor arrangement according to claim 1, wherein a difference signal between a first and at least one second corresponding temperature sensor signal is a measure of recorded heat radiation or existing humidity or existing air ^¬ flow.

3. Sensor arrangement according to claim 1 or 2, wherein one of the temperature sensors (1, 2) has a heat radiation reflecting surface (8) and the corresponding other tempera ^¬ tursensor (1, 2) has a heat radiation strongly absorbing surface (7).

4. The sensor assembly of claim 1 or 2, wherein both temperature sensors (1, 2) has a heat radiation strongly absorbing surface having and having the first temperature sensor (1), the riert the unaffected temperature signal (3) around gene ^¬ a cover which the Entry of heat ^¬ radiation prevented.

5. Sensor arrangement according to one of the preceding claims, wherein a temperature sensor with a high heat radiation absorbing surface is formed as a black body.

6. Sensor arrangement according to claim 1 or 2, wherein one of the temperature sensors (1, 2) has a hydrophobic surface and the corresponding other temperature sensor (1, 2) has a hydrophilic surface.

7. Sensor arrangement according to claim 1 or 2, wherein the at least one first temperature sensor (1, 2) which is designed such that it absorbs only existing heat radiation and ge ^¬ gene further heat exchange is thermally insulated and at least a second thermally non-isolated Temperature sensor (1, 2), which is connected to a heat sink or to a heat source, are present.

8. Sensor arrangement according to one of the preceding claims, wherein the signal of the subjectively perceived temperature

Control or regulation signal for a heating system or air conditioning is.

9. Sensor arrangement according to one of the preceding claims, wherein the influences of heat radiation, moisture or

Flow or a combination thereof containing dif ^¬ rence signal is generated as a control or control signal for a Hei ^¬ tion system or air conditioning.

10. Sensor arrangement according to claim 1 or 2, wherein both temperature sensors are thermostatically operated at a set body temperature, respectively, the corresponding energy consumption is measured and these signals are evaluated so that the second temperature sensor for measuring the environmental influence generates a temperature signal, which influences the heat radiation or Moisture or air flow or a combination thereof on the subjective Tempe ^¬ rature reproduces.

11. Sensor arrangement according to claim 10, wherein the proportion of the heat released by the thermostatically operated first temperature sensor is absorbed by the air flow to account for an air flow and by means of the second temperature sensor which is detectable by the flow rate of these dependent amount of heat.