CZ22673U1 - Apparatus to measure energy flows at boundary of ground surface and atmosphere - Google Patents

Description

Equipment for measuring energy flows at the interface between the Earth's surface and the atmosphere

Technical field

The technical solution relates to a device for measuring energy flows in nature, which allows to create a temperature map of the studied habitat of the order of hundreds of m ² and based on measurements and calculations with high probability to describe energy flows at the boundary of the Earth's surface and atmosphere energy of sunlight falling on the Earth's surface. The device is designed for absolute and comparative temperature measurement and especially for assessing the impact of incident solar radiation on individual types of stands. It makes it possible to compare methods and sensors for measuring radiation temperatures, air temperatures above the stands and surface temperatures and to determine the energy flows in the ground layer of the atmosphere. The device is used to measure and understand the physical nature of the events taking place in the ground layer of the atmosphere. The equipment is primarily designed to compare the distribution of temperatures and subsequently energy flows in different stands within the habitat and thus to describe the response of the stand to human intervention.

BACKGROUND OF THE INVENTION

The meteorological conditions in the ground-level layer of the atmosphere are determined using stationary or portable measuring stations, referred to as weather stations. Portable weather stations are usually placed on a concrete base plate, with which they can be transported to their destination. These weather stations are equipped with temperature, humidity, rainfall, wind, snow fall, sunlight and other sensors as standard, and are individually remotely connected to the central workstation to evaluate and further process the measured values.

The disadvantage of known stationary and portable weather stations is that they cannot be used for systematic detection of energy flows in the ground-level layer of the atmosphere in a given location, as they are measured at discrete points, even if these weather stations are connected to a sufficiently dense measuring network. , covering the measured locality, it would not be possible to obtain data usable for detecting energy flows from such a network. In addition, building a sufficiently dense metering network at each site is not realistic for construction, legal or financial reasons.

Previously, remote sensing, especially satellite and aerial images in various spectral areas, were used for meteorology, cartography and environmental burden classification. Most of the time, experiments are carried out with images taken from sophisticated airships. There are established procedures to calibrate the physical quantities obtained from these substrates. Due to the orbital height of 350 to 750 km, their detection systems are capable of delivering global surface data with a resolution of 30 to 1000 m per pixel. The density of these data is sufficient to cover the behavior of ecosystems on a regional scale and describe them at tens of km '. From aircraft we are able to achieve a resolution of 0.5 to 2 m per pixel and from airships 0.1 to 1 m. A major problem is the high cost of services of specialized airlines and hence the images obtained by specially modified aircraft and airships. The disadvantage of remote sensing solutions is their low surface resolution compared to a fixed ground station and discontinuity over time. All known solutions are based on measurements made from movable sensor carriers (satellite, aircraft, airship), which limit them over time. The satellite is able to monitor the monitored site once every two days, the aircraft can monitor the site two to five times a day and airships up to twenty times. Another disadvantage of these devices is their low operability, impossibility to influence the crossing time over the measured area and therefore impossible or very difficult to ensure accurate periodicity of measurement to record the dynamics of phenomena in the studied stand. Another disadvantage is the dependence on meteorological conditions, which considerably limit the usefulness of the remote sensing means, and the difficult interpretation of pixel calibration due to its large size and thus considerable variability.

The object of the invention is therefore to develop and implement a device for measuring energy flows at the boundary of the Earth's surface and the ground-level layer of the atmosphere, which removes the above-mentioned shortcomings, characterized both by increased resolution, important for understanding micro-climatic phenomena. correlation between the measurement itself and the results delivered for processing. In addition, the equipment should be characterized by low production and operating costs and hence low cost of images and measured values.

The essence of the technical solution

The above mentioned disadvantages are largely eliminated by the measuring device according to the technical solution, using a transportable measuring mast with a thermal imaging camera and sensors to detect the difference between radiation temperature, stand surface temperature and air mass (mass) temperatures in the stand and over the stand and enabling description of energy flow dynamics in the ground layer of the atmosphere. Sensors for measuring physical quantities are located on the transportable measuring mast and also on the measured area, monitored by a thermal imaging camera. The principle and main advantage of the technical solution is that the device continuously records the temperature scene of the measured area, sensed vertically, which is influenced by the change of the direction of incident direct solar radiation caused by the movement of the Sun in the sky. The measured data are supplemented with spot measurements on the ground weather station and visual images obtained from the mast.

The essence of the device for measuring energy flows at the boundary of the Earth's surface and atmosphere in the measured area according to the technical solution consists in that the device consists of a transportable measuring mast provided with means for positioning the mast in the measured area and further equipped with thermovision camera and NET radiometer for monitoring the temperature scene measurement area and evaluation and recording unit. The apparatus further comprises at least one ground weather station arranged in the measurement area, wherein the sensors for measuring physical quantities are arranged underground and / or above ground and are fixed to the ground weather station and / or to the mast.

NET radiometer senses incident and reflected radiation in infrared and visible spectral range and temperature of NET sensor itself. The sensor has an aperture of 180 °. The infrared camera can capture the earth's surface with an aperture of 12 °, 24 °, 45 °. The values are important for assessing the effect of the length of the expo25 and especially the direction of the incident solar radiation on the evaluation of satellite images in the infrared region. The energy of the incident and reflected short-wave component of global solar radiation in the spectral range 300 to 2800 nm is directly measured on the mast. The measuring instrumentation of the mast includes two heat flow sensors in the soil. The incident and reflected radiation in the thermal range 4500 to 42000 nm and the sensor temperature are also measured at the station, from which the effective sky temperature for a given region and the air pressure to determine the water vapor pressure are calculated.

In a preferred embodiment of the invention, the sensors for measuring physical quantities mounted on the mast consist of a temperature and relative humidity sensor and a wind speed and direction sensor, the sensors being arranged on the mast at at least two height levels, and the thermal imaging camera vertical movement with respect to the earth's surface in the measuring area to be handled at different heights above the measuring area and to be easily and quickly dismantled.

In order not to obscure the thermovision camera and the NET radiometer, in another preferred embodiment of the invention, a horizontal cantilever is mounted at the top of the mast, at one end of which a platform is provided with means for positionally reproducible mounting of the vertically movable carrier. mounted NET radiometer. The reproducible position of the carrier and hence the thermal imaging camera relative to the cradle and mast is very important for the accuracy of the measurement. In addition to the thermal imaging camera, a camera for taking visual images of the measured area is preferably provided on the carrier.

In order to achieve a structurally simple, light yet sufficiently precise mechanism for raising and lowering the carrier, it is preferred that the thermal imaging camera carrier and the platform are triangular in shape, and the carrier is mounted at the apex of the triangle on three handling lines that pass through apertures at the apex of the platform triangle. . These handling ropes are further guided through a set of pulleys to the opposite end of the cradle, and further connected by a triangular compensator, from whose center of gravity the central handling rope extends, by which the lifting and lowering of the carrier can be controlled manually or mechanically. The infrared camera and camera carrier can be lowered to the operator's position or pulled to the working position within a few tens of seconds. This _ 1 _

The CZ 22673 Ul option is used to collect data from the camera's memory card and when the weather conditions suddenly change.

In another structurally advantageous embodiment of the invention, the means for positively reproducing the vertically movable carrier carrying the infrared camera onto the platform is formed by three balls arranged on the carrier, which abut into three prismatic grooves on the platform. pulley platform grooves.

With respect to the ground weather station which is part of the device according to the invention, the ground weather station is preferably portable, arranged on a base plate and provided with temperature and relative humidity sensors at a height of 0.3 m above the ground and 2 m above the ground. ground, then the wind speed and direction sensor. Rainfall sensor, soil profile temperature sensor, energy flow sensor and soil moisture content sensor.

In another preferred embodiment of the invention, the ground weather station is provided with an automatic recording and control unit with an independent power supply, provided with a telecommunication device for transmission of electronic data to a remote server.

Since the mast is a cotton yarn from one measuring area to another, it is preferable that the mast consists of at least two removably connected sections made of carbon composites and connected by flanges to centering washers, with flanges or centering washers attached sensor carriers for measuring physical quantities. The mast can thus be transported in the unfolded state and assembled in the measuring area. K. Measurement of meteorological data in height profile utilizes the division of the tower into sections. The sensors are located on the sensor carriers, which are fixed to the flanges inserted between the individual sections. At each section, the temperature and relative humidity in the meteorological radiation cover and the wind speed and direction are measured.

Given the required mast height, the challenge is to erect the already assembled mast and anchor it to a stable, weather-resistant position. In a further preferred embodiment of the invention, the lower part of the mast is fixed to the base by means of a Kardan joint with two degrees of freedom, and the mast is anchored to the ground using a lower anchor rope system and a higher anchor rope system to prevent axis. The ends of the anchor ropes are preferably fastened to ground screws which are quick to install and reusable.

In order to overcome the so-called lifting point, it is advantageous that the mast is provided with a hoisting rope, one end of which is fixed in the middle of the mast and the other end fixed in the upper part of the mast. a pulley for a differential pulley coupled to a winch arranged on the base.

Finally, it is preferred that the winch is a two-drum winch, and the differential pulley is connected to a compensating pulley through which the rope is guided to both winch drums.

The advantages of the device according to the technical solution are that it is suitable for measuring energy flows at the boundary of the Earth's surface and the ground layer of the atmosphere without the drawbacks that accompanied the known devices. The device is characterized by an increased resolution, important for microclimate closure, and a temporal correlation between the measurement itself and the results delivered for processing. The device is further characterized by low production and operating costs and hence low cost of images and measured values.

Overview of enclosures in drawings

The technical solution will be explained in more detail in the drawings, in which FIG. 1 shows a general perspective view of the erected mast without anchoring ropes with the detail of the cut in the connection area of the two mast sections, and the ground weather station when measuring in the measured area. Fig. 3 is a sectional view of a detail of a device for positively reproducible mounting of a vertically movable camera carrier to a platform; Fig. 4 a schematic view of an erected sto-3 and a hoisting rope, FIG. 5 is a schematic view of a mast in the initial phase of lifting through a support pulley structure.

Examples of technical solution

The main part of the implemented equipment is a transportable dismountable mast made of four sections 3 made of carbon composite. Each section 3 is formed by a pipe of 230 mm in diameter and 7800 mm in length, which is provided at both ends with reinforced flanges 4 for connecting four threaded bolts. Between the sections 3 are inserted centering pads 5 forming integral parts with flanges 4, which serve to accelerate assembly work and as holders for sensor carriers 6 on which the temperature and relative humidity sensor 16 and the wind speed and direction sensor 17 are located. 7.8, 15.6, 23.4 and 31.2 m. On the bottom section 3 there is an evaluation and recording unit 30 in a watertight wiring box 31 and a soil radiometer 18.

The mast 1 is supported by a heel in a Kardan joint 13, which is connected to a solid base 14 in the shape of a cross, which is anchored to the soil by ground screws 25. The mast of the mast resp. its first (lower) section 3 is connected to the free end of the longitudinal part of the base 14 by a cardan joint 13. The axes of the cardan joint 13 are oriented so that the mast 1 can be erected around the first horizontal axis and . The cardan joint 13 eliminates rotation about the longitudinal axis of the mast 1, which is necessary in order to maintain the directional stability of the thermal imaging camera 10 and the camera ϋ. The rigid base 14 forms a compact power unit comprising, in addition to attaching the mast 1 via the Kardan joint 13, a two-drum winch 24 with el. For the initial lifting phase, a support pulley structure 15 is secured to the base 14 to overcome the dead point at the initial horizontal position of the mast I.

The mast 7 is lifted by means of a hoisting rope 22, the ends of which are connected to the flanges 4 in the middle of the mast 1 and in the upper part of the mast χ. The tensile force exerted by the double drum reel 24 is transmitted to this rope 22 by a differential pulley 27 which ensures the equality of forces acting on the top and in the middle of the mast 1 and the fixed pulleys 41. In order to achieve the same level of safety An independent safety rope tensioned between the second flange 4 (at a height of 7800 mm) and the rear end of the base 14. A balancing pulley 28 is used to ensure the equilibrium of the forces exerted on the two reel drums 24.

At the top of the mast 1, a 3 m cantilever 7 is mounted, at the end of which is a platform 8 designed so that the carrier 9 of the thermal imaging camera W and the JT camera is clearly oriented relative to the mast i and the cantilever 7. the position was exactly reproducible. Three carbon composite tubes are used to construct the cradle 7, at the rear of the Al profile sections and a set of pre-stressed cables. The cradle 7 is secured by a stabilizing rope 2L. The cradle 2 is equipped with a NET radiometer 12 so that its sensors are not shielded. Given the cost of the thermal imaging camera 10, it is essential that the operator, especially in the event of a non-standard weather situation, be able to lower the camera carrier 9 with the thermal imaging camera 10 and the camera 11 to the ground within a few tens of seconds.

The reproducible engagement of the withdrawable carrier 9 in the working position on the platform 8 is ensured by the support 9 having three balls 42 that abut three prismatic grooves 43 on the platform 8. The stainless steel handling ropes 23 of the withdrawable carrier 9 of the camera 10 pass through the centers of the balls 42 and holes 32 in prismatic grooves 43 for pulleys 33 which direct them through other pulleys 33 to pulleys 33 at the rear end of the cradle 7. To compensate for length differences and the possibility of replacing the handling ropes 23, the ends of the ropes 23 are fixed in balls 42 by adjusting screws 44. in this way, the unambiguous and permanent assignment of the corresponding balls 42 and prismatic grooves 43 is guaranteed, so that after each manipulation the retractable carrier 9 of the camera 10 and the camera 1T is brought into the correct position on the cradle 7.

In order to ensure a good fit of the camera carrier 9 into the prismatic grooves 43 on the cantilever 7, it is necessary to compensate the force conditions in the individual handling lines 23 of the telescopic carrier 9 and thereby compensate for the longitudinal unevenness in all three branches of these ropes 23. 29, which is connected to its center of gravity

22673 U1, the sole central handling rope 23 'of the camera 9 carrier 10, which is manually operated by the operator from the ground or can be wound mechanically.

The stability of the erected mast 1 is ensured by two independent rope systems. The first set of lower anchor ropes 19 is connected to the mast i at half of its height, the second set of higher anchor ropes 20 is fixed under the cantilever 7. Each system consists of five steel ropes 19, 20 with a diameter of 6.3 mm which are fixed to flanges 4. Multiple-use ground screws 25 are used to anchor the ropes 19, 20 to the ground. The same ground screws 25 are anchored to the ground and base 14.

The measuring device according to the invention also includes a portable terrestrial weather station 2 located in the measured area 26. The portable terrestrial weather station 2 is arranged on the base plate 38 and is provided with temperature and relative humidity sensors 16 at a height of 0.3 m above the ground and 2 m. above the ground, as well as a wind speed and direction sensor 17, a rainfall total sensor 34, a soil profile temperature sensor 35, an energy flow sensor 37 and a soil volume moisture sensor 36. The weather station 2 is further provided with an automatic recording and control unit 39 with an independent power source 40, and with a telecommunications device for transmitting electronic data to a remote server. The recording and control unit 39 comprises a universal data logger, a telemetric station with a built-in GSM / GPRS module, a programmable controller and a solar photovoltaic panel using solar radiation. The unit 39 enables continuous year-round recording and transmission of data to the server, where the data is available to all users.

To measure the meteorological data in the altitude profile, the division of the mast 3 into sections is used. At each section 3, the temperature and relative humidity in the meteorological radiation housing and the wind speed and direction are measured. The NET radiometer 12 senses both incident and reflected radiation in the infrared and visible spectral regions and the temperature of the sensor itself. The sensor has an aperture of 180 °. The infrared camera 10 can scan the earth's surface with an aperture of 12 °, 24 °, 45 °. The energy of the incident and reflected shortwave component of global solar radiation in the spectral range 300 to 2800 nm as well as the incident and reflected radiation in the thermal region 4500 to 42000 nm and the temperature of the sensor from which the effective sky temperature for the region is calculated air pressure to determine water vapor pressure.

Industrial applicability

The device according to the technical solution can be used for the measurement of energy flows at the boundary of the Earth's surface and the ground layer of the atmosphere, especially for research purposes with the aim of understanding microclimatic phenomena in the measured area.

Claims (13)

PROTECTION REQUIREMENTS An apparatus for measuring energy flows at a boundary of the Earth's surface and the atmosphere in a measuring area (26), comprising sensors for measuring physical quantities connected to an evaluation unit for processing the measured values of these quantities, characterized in that it consists of a transportable measuring mast (1) provided with means for aligning the mast (1) in the measured area (26), and further equipped with a thermal imaging camera (10) and a NET radiometer (12) for monitoring the temperature scene of the measured area (26) and evaluation and recording unit (30); a ground weather station (2) arranged in the measurement area (26), wherein the sensors for measuring physical quantities are arranged underground and / or above the ground and are fixed to the ground weather station (2) and / or to the mast (1). Device according to claim 1, characterized in that the sensors for measuring physical quantities mounted on the mast (1) comprise a temperature and relative humidity sensor (16) and a wind speed and direction sensor (17), the sensors (16, 17) are arranged on the mast (1) at at least two height levels, and the thermal imaging camera (10) is mounted on the mast (1) with the possibility of its vertical movement relative to the earth surface in the measured area (26). - 5 CZ 22673 Ul Device according to claim 2, characterized in that a horizontal cantilever (7) is fixed at the top of the mast (1), at one end of which a platform (8) is provided with means for positionally reproducible abutment of a vertically movable carrier (9) carrying a thermal imaging camera. (10), and a NET radiometer (12) is mounted at its other end. Device according to claim 3, characterized in that a camera (11) is arranged next to the thermal imaging camera (10) on the carrier (9). Device according to claim 3 or 4, characterized in that the infrared camera carrier (9) and the platform (8) are triangular in shape, and the carrier (9) is fixed at the vertices of the triangle on three handling ropes (23), which extend through the apertures (32) at the apexes of the platform triangle (8), are further guided through a set of pulleys (33) to the opposite end of the cradle (7) and further connected by a triangular compensator (29). '). Apparatus according to claim 5, characterized in that the means for positively reproducing the vertically movable support (9) supporting the thermal imaging camera (10) onto the platform (8) is formed by three balls (42) arranged on the support (9) which abut into three prismatic grooves (43) on the platform (8), wherein the handling ropes (23) from the carrier (9) pass through the centers of the balls (42) and through the openings (32) in the prismatic grooves (43) of the platform (8) ). Device according to one of the claims 1 to 6, characterized in that the ground meta-station (2) is portable, is arranged on the base plate (38) and is provided with temperature and relative humidity sensors (16) at two constant elevation levels above the ground. and a wind speed and direction sensor (17), a rainfall total sensor (34), a soil profile temperature sensor (35), an energy flow sensor (37), and a soil volume moisture sensor (36). Device according to claim 7, characterized in that the ground weather station (2) is provided with an automatic recording and control unit (39) with an independent power source (40), provided with a telecommunication device for transmitting electronic data to a remote server. Device according to one of Claims 1 to 8, characterized in that the mast (1) consists of at least two detachably connected sections (3) made of carbon composites and connected by flanges (4) to the centering washers (5), and to the flanges (4) or to the centering washers (5) are mounted carrier (6) of sensors (16, 17) for measuring physical quantities. Device according to one of Claims 1 to 9, characterized in that the lower part of the mast (1) is fixed to the base (14) by means of a universal joint (13) with two degrees of freedom, and the mast is anchored to the ground 19) and higher anchoring ropes (20) to prevent the mast (1) from rotating about the longitudinal axis. Device according to claim 10, characterized in that the ends of the anchor ropes (19, 20) are fastened to ground screws (25). Device according to one of claims 10 to 11, characterized in that the mast (1) is provided with a hoisting rope (22), one end of which is fixed in the central part of the mast (1) and the other end fixed in the upper part of the mast (1). 1), wherein the loop forming hoisting rope (22) is guided through the support pulley structure (15) and the fixed pulleys (41) to a differential pulley (27) connected to a winch (24) arranged on the base (14). Device according to claim 12, characterized in that the winch (24) is a two-drum winch and the differential roller (27) is connected to a compensating roller (28) through which a rope is guided to the two winch drums (24).