DE19614785A1 - Measuring unit for detecting rainfall amount in difficult or dangerous terrain - Google Patents

Abstract

The measuring unit uses a system of individual measuring stations, working in autonomously, and distributed at critical points, over the terrain to be observed. The individual measuring stations communicate with a central control station, arranged at a safe and easily accessible place. The individual measuring stations (2) are provided with a control and a processing system (4). The processing unit (16) of this, across a relevant computer programme, ensures a continuous operation so that no measurement faults result due to overfilling or by necessary emptying operations.

Description

The invention relates to a measuring system for recording precipitation amounts. Due to the intensive use of forests, many mountain slopes are natural Robbed of water storage, so that increased landslides due to larger Precipitation amounts can be observed. At the same time is due to the expansion the settlement in potentially endangered areas the risk of personal injury with fatal consequences increased significantly. That is why early warning systems are essential required.

The necessary knowledge of the relationship between topographical Conditions, soil conditions and water flow in the subsurface, which Triggering of mountain slides is present. There is also a connection between rainfall in the affected areas and water supply known. Therefore, in order to be able to set up a reliable early warning system to get a reliable and accurate measurement of the amount of precipitation. The The requirement also applies to topographically difficult to access and landslide-prone terrain.

Measuring stations for recording the amounts of precipitation are known per se, but mostly require manual reading and regular maintenance in short Intervals, or if they are automated, an external energy supply and a connection for the transmission of measurement data.

The present invention is intended to avoid these weaknesses. The Measuring system according to the invention must have the following properties:

• - It must consist of several measuring stations, since each spread over a mountain slope Different amounts of precipitation may occur depending on proximity and location.
• - Since the measuring stations can be arranged over a wide area, they should work independently, d. H. they must have their own energy supply and one wireless transmission of the measurement data.
• - Since the measuring stations are also in a topographically difficult location and potentially landslide-prone terrain, they must work reliably without maintenance over longer periods of time; it would be favorable to them would only require maintenance during the dry periods.
• - The measuring stations should have very different amounts of precipitation can grasp d. H. both high resolution for small amounts as well as a continuously operating automatic emptying at high Show precipitation values.
• - A central measured value collecting station must be available in a safe location be able to continue working reliably in the event of a landslide.
• - The individual measuring stations must be inexpensive to manufacture so that they can also be arranged at particularly critical points where a loss in the event of a landslide must be expected.

According to the invention, these requirements are met by that described below System solved.

The system according to sketch 1 consists of a different number of individual measuring stations 2 , depending on the topographical requirement, which transmit their measured data wirelessly to a central station 1 arranged in a safe position. The radio link required for this is constructed using elements of wireless transmission technology known per se.

Those for radio transmission and for the automatic functioning of the measuring station necessary energy is from natural renewable energy sources with itself known means won. For use in tropical areas, this is an option Solar energy. When used in areas with low solar radiation wind energy can also be used. Times of low energy intake have to be taken into account an energy storage technology known per se, e.g. B. accumulator bridges will.

Each individual measuring station therefore has a structure as shown in sketch 2 and consists of a precipitation measuring device 3 , control and measurement data processing system 4 , energy store 5 and energy source 6 .

Because of its location, the central acquisition station can be connected to a normal one Power supply can be connected.

The control and measurement data processing system takes over control of the entire unit, ie checking the energy level of the energy storage unit 5 with the necessary blocking of the energy supply or warning message to the central station 1 in the event of a drop below a minimum limit and impending failure of the station.

An essential part of the invention lies in the design of the precipitation measuring device 3 . Due to the poor accessibility, regular checks and maintenance are only possible at longer intervals. Therefore, this device must work absolutely independently and reliably even under difficult weather conditions, and may only have a low energy consumption due to the limited energy supply in bad weather periods.

Because especially in tropical areas with algae formation and putrefaction in the collected Water is to be expected, level measurement methods with mechanically moved Hand out like swimmers etc. Since also with varying degrees of pollution of rainwater due to dust or pollen count are also Measuring method with detection of the static pressure of the water column not as reliable enough to look at.

For this reason, the amount of precipitation is recorded with a non-contact measuring methods based on known to provide temperature-dependent PTC resistors on the Level measuring tube are attached.

The level in the measuring tube is monitored with these measuring elements. The Activation of the measuring elements takes place cyclically at time intervals which are different from the Processor unit can be defined.  

If the maximum fill level has been reached or a sufficiently long time interval has been exceeded, an automatic emptying process is initiated by the processor unit. Due to the amount of rain per unit of time measured before and after emptying, an update of the trend for the time of emptying is determined in the processor unit and thus an uninterrupted recording of the amount of precipitation is ensured, see sketch 5 .

The precipitation measuring device as an essential point of the invention is shown as an exemplary embodiment in sketch 3 or with another piston shape in sketch 4 .

A rain collecting funnel 7 with a sieve-like retention protection in a convex shape to avoid the penetration of coarse dirt particles such. B. leaves or insects in the fill pipe 8th

The fill level tube 8 is equipped at regular intervals with the measuring elements 9 which detect the respective fill level 10 .

The lower end of the fill level tube 8 is formed by the emptying unit, which consists of a housing 11 with a piston 13 , which is actuated via a bistable solenoid 12 and runs in a sliding guide 15 , and works against a seal 14 .

Due to these easy-to-operate parts, a low energy requirement is required simultaneous rapid emptying ensured. Due to the protected location of the moving parts, the risk of failure due to contamination is kept low.

The use of commercially available elements guarantees low costs for the Unit of measurement.

The control and measurement data processing system consists of a processor unit 16 and a data transmission unit 17 , which are housed in a common moisture-proof housing made of stainless steel. For this, too, marketable elements are preferably used, e.g. B. for the data transmission unit a radio link from known technology.

The control of the measuring unit is carried out by the processor unit 16 . The associated software package, both for the processor unit 16 and for the evaluation of the data collected within the central station 1, is an in-house development and is adapted to the respective application according to the number of measuring stations 2 .

There is no question that the individual measuring unit 2 can also be used as an autonomous individual system for recording the amounts of precipitation for meteorological purposes.

Claims (8)

1. Measuring device for recording amounts of precipitation in topographically difficult to access and / or endangered terrain, characterized in :

• - That the system consists of individual self-sufficient measuring stations ( 2 ) distributed over the area to be observed at critical points, which communicate with a central station arranged at a safe and easily accessible location.

2. Measuring device for detecting amounts of precipitation according to claim 1, characterized in that the individual measuring stations ( 2 ) are provided with a control and processing system ( 4 ), the processor unit ( 16 ) ensures continuous operation via an associated computer program, so that none Measurement errors result from overfilling or due to necessary emptying processes. 3. Measuring device for detecting amounts of precipitation according to claim 1 and 2, characterized in that the individual measuring stations ( 2 ) with a self-sufficient energy supply unit ( 6 ) are fed from natural energy sources and are provided with an associated energy store ( 5 ). 4. Measuring device for detecting amounts of precipitation according to claim 3, characterized in that the power supply unit preferably with Collectors for the use of solar energy or with generators for use is equipped with wind energy. 5. Measuring device for detecting amounts of precipitation according to claim 1 and 2, characterized in that the measurement data transmission to the central station happens over a wireless radio link and the individual measuring stations on only one carrier frequency can be called using special identifiers. 6. Measuring device for detecting amounts of precipitation according to claim 1 and 2, characterized in that the individual measuring stations are very robust and simple in their mechanical structure, ie only one in a housing ( 15 ) sliding piston ( 13 ) with a conical head as a movable Have part that controls the collection or emptying process via an electrical bistable solenoid ( 12 ) by means of seals ( 14 ) or ( 16 ). 7. Measuring device for detecting amounts of precipitation according to claim 1 and 2, characterized in that the fill level ( 10 ) in the measuring tube ( 8 ) is detected by means of non-contact PTC resistors, which are arranged at defined intervals. 8. A method for detecting amounts of precipitation in a measuring system according to claims 1 and 2, characterized by an associated computer program with the following functions and program sequences:

• - The program starts after a crash due to external influences, e.g. B. interruption of the energy supply, by itself and is fully functional without having lost the essential measurement data.
• - The program regularly checks the functioning of the precipitation measuring device ( 3 ) and reports any faults to the central station.
• - The program checks the level of the energy storage and reports the fault to the central station if the limit falls below.
• - The program empties the measuring device depending on the level and duration.
• - The program varies the frequency of the query with the precipitation intensity, according to sketch ( 5 ).
• - The program determines the level from the measured values and calculates the intensity of precipitation from successive data of the level depending on the elapsed time.
• - for the period of emptying, the program interpolates the amount of precipitation from the measurements before and after emptying.
• - The program transmits the calculated measured values to the central station on request.