NL1002157C1 - Remote measurement of air temperature - Google Patents

Abstract

A buoy (1) has a spring-mounted (9) aerial (10). The aerial is a white, flexible tube of e.g. fibreglass. Two identical temperature sensors (11,12) are situated about 1.5m above water level. They are in intimate contact with the tube for efficient heat conduction. The upper sensor (12) is wrapped in black foil. The sensors (11,12) are separated by heat insulating material. Different absorption characteristics of the materials surrounding the white sensor (11) and black sensor (12) enable air temperature to be derived from the white sensor output modified by a function of differential temperature.

Description

-1-

Device for measuring the air temperature.

The invention relates to a device for measuring the air temperature, provided with at least one temperature sensor and means for processing signals coming from the sensor.

5

Such devices are well known, and are usually contained in a weather station with a number of functions, one of which is to measure the air temperature. The temperature sensor is shielded from the incident solar radiation so that the actual air temperature can be measured immediately. These weather stations are usually arranged on an elevation, such as, for example, a pole, the shielding consisting of a housing with a roof arranged around the measuring equipment, the side panels 15 being built up on sloping downwards and staggered parts which shield the interior of the housing from the sun, but where the air can flow more or less freely.

Such a fairly bulky and often also heavy housing will not suffice in all situations in which air temperature measurements have to be carried out. This may include measuring points that are not stationary, or measuring points that are constantly or almost constantly moving, such as, for example, oceanographic or meteorological buoys.

In the "Navy Technical Disclosure Bulletin", volume 5, no. 8, August 1980, a free floating meteorological buoy is described, which is intended to be thrown out of an airplane into the sea, and where among other things facilities for measuring the air temperature.

After the buoy has ended up in the sea, a lower part with a ballast extends downwards, to give some stability to the whole. Then a 10 0 2 i £ 7.

-2- inflatable measuring part inflated from a C02 cylinder, in which on top of the mast part next to a wind speed meter further air temperature and humidity sensors are placed. The air temperature sensor is placed under a 5 shield to prevent errors in the temperature measurements due to solar radiation.

The temperature sensor of this buoyant buoy protrudes about 2 meters above the water surface, so that the stability of the buoy depends to a great extent on the weight of the instruments mounted on top of the mast and on the extent to which the wind can catch it. to get. The size of the shielding of the temperature sensor is particularly important in this respect.

15

The object of the invention is to obviate such drawbacks and it is an object to provide an apparatus for measuring the air temperature which is light in weight, of limited dimensions and which does not need a shield for protecting against solar radiation and which is moreover easy to install.

Accordingly, according to the invention, it is provided that a second sensor 25 is arranged at a distance from the first sensor, such that the sensors receive different amounts of absorbed heat by radiation with equal amounts of incident solar radiation, and that further means are provided to extract from the signals from the first and second sensors derive the air temperature 30.

A simple embodiment of a device according to the invention provides that the first sensor is identical to the second sensor, the sensors being arranged in housings 35 with a different heat absorption coefficient and in conducting contact therewith.

The temperature measured by the sensors is determined by the air temperature plus the through the housing, where the 10 C2 15 7.

-3- sensor is included, heat absorbed by radiation. Assuming a black and a white housing for the sensors, the following applies in steady state: ('^' zwazc ~ Tjucht;) “^ sun * ^ black 5 ^ ö t ~ ^ air ^“ Pgon '^ wi t h-waxmteovexdxachtcoefficient [W / {m2.l0] st -stialing-efficiency [W / m2] A-absorption coefficient [-] then: ^ black ~ ^ 'wiC ^ | _ ^ '^' black ~ ^ ^ white _ ^ black ~ ^ white ^ Twi t Awi t 10 α-text drawing coefficient in which: ^ Tzirart "'^' black ~ Air ^^ 'witm' ^ 'white ~' ^ ' air 15 It should also be noted that the recalculation coefficient is independent of the wind speed.

It will be clear that the recalculation coefficient can be determined quite simply and, with this coefficient known, the air can then be calculated from the values measured by the sensors. y.

-4- temperature can be calculated. Although the heat absorption coefficients of the white and black sensors depend on the frequency of that radiation, it is sufficient in practice to determine the back-calculation coefficient at the moment when the influence of the solar radiation is greatest, therefore at the time when this is at its strongest.

Due to the low weight and small size of the measuring part of the device, and the possibility of arranging the means 10 for processing the signals remotely from the measuring part, the device according to the invention is extremely suitable for use on points that would otherwise not have been eligible at all. This could include small 15 oceanographic buoys, vessels, vehicles and so on. Furthermore, it is of course also possible to place a device according to the invention next to or as a replacement for the outside temperature meter, as it is used in many households, so that the air temperature can be measured without a shielded weather station having to be placed in front of it.

The device can be applied particularly advantageously on small oceanographic buoys, with which, for example, wave data and / or flow data are collected. These buoys are relatively small and therefore unsuitable for mounting a shielded measuring unit on them. However, such buoys have a wide distribution along most coasts, so that if temperature measurements could also be taken at these locations, this is an important one. would mean meteorological contribution. For the transmission of measurement data, the buoys are provided with a transmission device and a antenna projecting relatively high above the buoy. The measuring part of the device according to the invention can be arranged in such an antenna in a particularly simple manner, the processing unit can be placed in the buoy and the air temperature data can be sent to the mainland individually or together with the other data.

1 0 02 1 57.

-5-

The invention will be elucidated hereinbelow with reference to the drawing, in which: fig. 1 shows a view of a buoy with the measuring part of the device according to the invention; Fig. 2 shows a cross-section of the antenna with two sensors incorporated therein, Fig. 3a shows a top view, and Fig. 3b shows a cross-section according to the line III-IIIb in Fig. 3a of a sensor receiving member.

10

In Fig. 1, 1 denotes an oceanographic buoy, for example a buoy for measuring wave frequency and amplitude, which is built up of two parts 2,3 and which is provided with a bumper 4 along the connection weld. The buoy is furthermore provided with an attachment point for anchoring line 5 and with one or more eyes 6, on which the buoy can be hoisted in and out of the water.

A hatch 7 is arranged on the top of the buoy, through which the interior of the buoy can be reached. On the hatch 7 there is a mounting base 8 for the antenna spring 9 and the antenna 10. At some distance, about 1 to 1.5 meters, above the water surface, in the antenna, as indicated schematically, the sensors 11, 12 for 25 measuring the temperature applied.

Fig. 2 schematically shows a cross-section of the antenna 10, which mainly consists of a flexible sleeve 13, for example of glass fiber, in which the actual antenna wire 30 is located. For the sake of clarity, the antenna wire is not shown here.

Within the flexible sleeve 13, receptacles 14,15 are placed for the sensors 11,12. The receptacles consist of cans of a good heat-conducting material, for example brass, and are in direct contact with the sleeve 13. In order to ensure good heat transfer, a heat-conducting paste can be applied between the cans and the sleeve.

10 02 1 57.

-6-

On the outside, at the height of the top sensor, a black layer 16 is applied around the flexible sleeve 13, which is easiest with a black shrink film. In this way, a black sensor 12 and a white sensor 11, 5, the sleeve is approximately white, each having its own heat absorption coefficient.

The black sensor will get the highest temperature and is placed above the white sensor to prevent heat transfer from the black to the white sensor. For this purpose, an insulating material 17 is additionally arranged between the sensors. In order to ensure that the conditions within the sleeve for the sensors are the same, the insulating material is furthermore also arranged on top and bottom of the black and the white sensor, respectively.

Fig. 3a shows a top view of a receiving member 14,15, which has a bore 18 for clampingly receiving a sensor 11,12, in which optionally a heat-conducting paste can be arranged between the sensor and the receiving member. Two further bores 19,20 are made in the receiving member, which serve for the passage of the antenna wire or the passage of the connecting wires of one or both sensors.

25

Finally, Fig. 3b shows a cross section of a sensor 14,15, schematically showing a sensor 11,12 incorporated therein. The sensor will preferably be a temperature dependent resistor, preferably having a negative temperature coefficient.

10 0 2 f 5:

Claims (11)

1. Device for measuring the air temperature, provided with at least one temperature sensor and means for processing signals coming from the sensor, characterized in that a second sensor is arranged at a distance from the first sensor, such that the sensors equal amounts of incident solar radiation to detect different amounts of heat absorbed by radiation, and that further means are provided to derive the air temperature from the signals of the first and second sensors. 2. Device according to claim 1, characterized in that the first sensor is identical to the second sensor, the sensors being arranged in housings with a different heat absorption coefficient and in conducting contact therewith. 3. Device mainly consisting of a floating body and an upwardly projecting part connected thereto, wherein a temperature sensor is arranged in the upwardly projecting part, and the device further comprises means for processing and transmitting the signals coming from the sensor, with the characterized in that a second sensor is arranged in the upwardly projecting part at a distance from the first sensor, such that the sensors receive different amounts of absorbed heat by radiation with equal amounts of incident solar radiation, and that further means are provided to extract from the signals derive the air temperature from the first and second sensors. 30 4. Device as claimed in claim 3, characterized in that the upwardly projecting part is a hollow part in which receiving members, intended to receive the respective sensors, are arranged, in such a way that they are in good conducting contact with a sensor such as also with the wall of the hollow part. 10 02 1 5? -8- Device according to claim 4, characterized in that the hollow part at the height of the upper sensor has a different heat absorption coefficient than in the remaining part of the hollow part. 5 6. Device according to claim 5, characterized in that the hollow part is blackened at the location of the upper sensor. 7. Device as claimed in claim 6, characterized in that black shrink film is arranged around the hollow part at the location of the upper sensor. 8. Device as claimed in claims 4-7, characterized in that the receiving members consist of brass bushes with at least one fitting hole for receiving a sensor. 9. Device as claimed in claims 4-8, characterized in that a heat-insulating material is incorporated in the hollow part between at least the receiving members. 20 Device as claimed in claims 3-9, characterized in that the device further comprises means for transmitting the derived air temperatures. Device according to one or more of the preceding claims, characterized in that the sensor is a thermistor, preferably with a negative temperature coefficient. 10 02 1 57.