AT390675B - MEASURING DEVICE FOR SUN RADIATION - Google Patents

Description

No. 390 675

The invention relates to a measuring device for solar radiation, which is used in a system for controlling a sun protection system arranged on a window, a door or the like, with a first measuring head provided with a temperature sensor, which is exposed to direct sunlight and absorbs it, and a second measuring head provided with a temperature sensor which is not exposed to solar radiation and the temperature sensors are connected to an electronic evaluation circuit which generates an output signal as a function of the temperature difference determined by the temperature sensors

Such a measuring device is known from DE-OS 1 588 225. The illuminance of direct sunlight is measured with a first photoelectric element and a second photoelectric element determines the general basic brightness of the surroundings. The output signals of the two photo elements are evaluated for controlling an awning, for example, in such a way that the awning is closed only when there is a predetermined difference in brightness.

Furthermore, US Pat. No. 4,355,896 describes a measuring device which is intended to determine and display the relative proportion of the clouds in the visible sky.

For this purpose, a light-sensitive sensor is directly exposed to the sun's rays, while further sensors are shaded by means of light screens in order to detect those areas of the sky that do not contain direct sunlight. A value characterizing the relative cloudiness of the sky is derived from the respectively determined values.

Finally, a radiation measuring device is known from GB-OS 21 05 460, which is provided in particular for an alarm system in which the infrared radiation emitted by an intruder is determined. A filter disc blocks the passage of visible light and only allows infrared radiation to reach the sensor. The sensor is duplicated, this double arrangement is only intended to correct the measurement in the sense that environmental influences such as temperature, pressure, humidity and the like. s. w. be compensated. Therefore, one of the two sensors is covered by a radiation-impermeable screen so far that the expected infrared radiation cannot reach it. However, the other sensor is also partially covered or shaded, so that, unlike the subject of the invention, it is not unhindered from being exposed to incident radiation.

In buildings, the rooms of which are used for living or work purposes, it is often desirable to set up the daylight so that adequate lighting is achieved, but not glare for people. In addition, the incoming radiation should also be such that the desired temperature control of the rooms is not impaired. Direct exposure to the sun in particular can, however, significantly influence the temperature in the room that is regulated by heating or air conditioning systems. These relationships have been known for a long time, which is why z. B. Windows are provided with curtains that prevent direct sunlight, but still cause enough indirect light radiation to achieve sufficient lighting in the room. In addition to the curtains, blinds or blinds for diffuse reflection of direct radiation have recently become popular. The blinds, which are made up of movable slats, are particularly suitable for automatically controlling and regulating the light entering the room. In the event of strong light, the slats are moved into the light path in order to scatter the solar radiation. Awnings or other sun protection devices can also be operated automatically in a corresponding manner. Such automatic control of the shading and / or diffusion devices, such as blinds, awnings or the like, requires measuring devices which determine the amount of light entering the room.

Conventional devices for measuring the intensity of e.g. B. from the sun electromagnetic radiation usually have a light-sensitive component such. B. a photo resistor, by means of which the incident illuminance or the luminance is determined. According to the light values measured in this way, the sun protection device is more or less closed or opened via a control and regulating device. It is also known in the prior art to use a (usually red) filter to narrow the light reaching the photoresistor to a certain wavelength range or else select the photo resistor itself so that it is only effective with regard to certain wavelength ranges (usually the red spectral component of sunlight)

The known methods and devices for measuring the intensity of electromagnetic radiation have the major disadvantage that they cannot distinguish whether the incident light is radiated directly or indirectly into the room. With the same measured illuminance or luminance, the shading device is controlled in the same way regardless of whether the radiation is incident directly or indirectly. It does not take into account that there is a big difference, both physically, physiologically and psychologically, whether the radiation falls directly or indirectly into the room or not. Even with the same amount of light, as measured for example with a conventional photo resistor, the direct light radiation in the room has a stronger heat effect than the indirect radiation. This stronger heat effect extends not only to the objects arranged in the room, such as furniture and. Like., And the room air, but also on the people present in the room. Humans perceive the incident direct radiation from the sun - even with the same amount of light - much more intensely than indirect, due to the -2-

No. 390 675

Scattered light.

The invention has for its object to provide a measuring device for solar radiation, which is used in a system for controlling a sun protection system arranged on a window, so that it is possible to control the sun protection system particularly precisely and reliably depending on whether direct or indirect sunlight hits.

This object is achieved in that the measuring heads are arranged in a housing, the first measuring head being thermally insulated from the second measuring head and the second measuring head being thermally connected to the ambient air through housing openings.

According to the invention, therefore, the illuminance or luminance is not detected, but rather it is determined whether a certain amount of light comes directly from the sun or has been scattered, for example, in the clouds.

The invention thus makes use of the knowledge that a body exposed to direct electromagnetic radiation heats up more than the surrounding air. A comparison of the temperature of the body which can be directly irradiated by the radiation source with the temperature of the outside air therefore gives a measure of whether and to what extent direct radiation is present or not. The more direct radiation falls on the body, the greater the temperature difference will be.

In a preferred embodiment of the invention it is provided that the first and the second measuring head are separated from one another by a pane which is permeable to solar radiation but is thermally insulating.

The first measuring head intended for the measurement of the directly incident radiation is thermally connected to the outside air in such a way that on the one hand it heats up quickly in the event of direct sunlight and on the other hand it cools down quickly when the sun suddenly disappears (behind e.g. clouds). In the first case, some moderate insulation is required, in the second case, good thermal contact with the outside air is required. Experimentally, a convection contact between the measuring head and the outside air has proven to be suitable for this. If several radiation sources are conceivable, the measuring head is covered in the direction of all possible radiation sources.

The disk is preferably selected so that it is transparent to selected wavelength ranges, so that the radiation that is let through can be adapted to the absorption properties of the measuring head body.

It is also possible that adjustable diaphragms are provided, by means of which the solar radiation conditions on the measuring device can be set such that the first measuring head is directly irradiated and the second measuring head is shadowed

This ensures that this one measuring head can no longer absorb direct radiation, so that its temperature will adapt to that of the ambient air.

In all of these embodiments, it is advantageous if at least one of the measuring heads has indentations which enlarge the surface, as a result of which both the heat exchange of the shaded measuring head with the ambient air and that of the other measuring head with the solar radiation can be further improved.

If, for at least one of the temperature sensors, a component which responds to temperature changes with a pressure and / or volume change is provided, the pressure and / or volume change being converted into an electrical signal, a particularly simple construction of the device can be achieved.

In a further development of the invention, a wind strength measuring device can be provided in all of these embodiments, which acts upon a protective disk that can be moved in front of at least one of the measuring heads when a predeterminable wind strength is exceeded is.

The invention is described in detail below with reference to the drawing. It shows:

Figure 1 is an illustration of the housing receiving the eifindungsggenössische device.

FIG. 2 shows a section through the device shown in FIG. 1 along the line (A-A); and

Fig. 3 shows a section through the device shown in Fig. 2 along the line (B-B).

1 shows the device, which is provided overall with the reference number (100) and is enclosed by a housing (104). The housing (104) is surrounded by an outer air space (102).

2, two measuring heads (41), (51) are arranged in the housing (104), which are separated from one another by means of a thermally insulating disk (31). The first measuring head (41) is designed such that it absorbs the electromagnetic radiation to be measured. For example, its surface is blackened. Furthermore, the first measuring head (41) is arranged in such a way that it is thermally insulated as well as possible from the air space surrounding the measuring head (51), so that its temperature can change quickly depending on the incident direct radiation. The radiation incident from the radiation source to be taken into account must therefore have direct access to the measuring head (41), so that there must be no obstacles in the light path between the measuring head (41) and the radiation source, unless the objects causing indirect radiation, such as clouds.

The second measuring head (51), on the other hand, is shaded from the radiation source to be measured and is not thermally insulated from the ambient air (102), but rather is in good thermal contact with it. For this purpose, openings (33) are provided in the housing (104) through which the air from the surrounding air space (102) can enter the housing (104). This ambient air also reaches -3-

Claims (7)

No. 390 675 contact to the first measuring head (41). By means of the displaceable diaphragms (21), (22) and (23), the two measuring heads (41) and (51) can be positioned according to all possible irradiation conditions so that the first measuring head (41) is irradiated directly, while the second measuring head ( 51) is shaded from the radiation source (or radiation sources). Both measuring heads (41) and (51) are each provided with a temperature sensor (42), (52) which determine the body temperature of the measuring heads (41), (51) and enter them in an electronic control (not shown). From the temperature difference between the measuring heads (41) and (51) determined by the temperature sensors (42) and (52) it can be determined whether and to what extent direct irradiation takes place. If the measuring head (41) is at an elevated temperature compared to the measuring head (51), there is direct radiation. Accordingly, the sun protection device acted upon by the control is moved to shade the room and to scatter the incident light. According to FIGS. 2 and 3, openings (14) are provided in the rear wall (12) of the housing (104) with which the device can be attached to a Wall can be attached. 1. Measuring device for solar radiation, which is used in a system for controlling a sun protection system arranged on a window, a door or similar openings, with a first measuring head provided with a temperature sensor, which is exposed to and absorbs the direct solar radiation, and one second measuring head provided with a temperature sensor which is not exposed to solar radiation and the temperature sensors are connected to an electronic evaluation circuit which generates an output signal depending on the temperature difference determined by the temperature sensors, characterized in that the measuring heads (41), (51 ) are arranged in a housing (104), the first measuring head (41) being thermally insulated from the second measuring head (51) and the second measuring head (51) being thermally connected to the ambient air through housing openings (33). 2. Measuring device according to claim 1, characterized in that the first and the second measuring head (41), (51) are arranged separately from one another by a pane which is permeable to solar radiation but is thermally insulating (31). 3. Measuring device according to claim 2, characterized in that the disc (31) is transparent for selected wavelength ranges. 4. Measuring device according to claim 1, 2 or 3, characterized in that adjustable diaphragms (21), (22), (23) are provided, by means of which the solar radiation conditions on the measuring device can be adjusted in such a way that the first measuring head (41 ) directly irradiated and the second measuring head (51) is shadowed 5. Measuring device according to one of claims 1 to 4, characterized in that at least one of the measuring heads (41), (51) has the surface-enlarging indentations 6. Measuring device according to one of claims 1 to 5, characterized in that for at least one of the temperature sensors (42), (52) a component reacting to temperature changes with a pressure and / or volume change is provided, the pressure and / or Volume change is converted into an electrical signal. 7. Measuring device according to one of claims 1 to 6, characterized in that a wind strength measuring device is provided, which acts upon at least one of the measuring heads (41), (51) movable protective pane when a predetermined wind strength is exceeded. Here 1 sheet drawing -4 -