DD241003A1 - DEVICE FOR DISTRIBUTION OF DISTRIBUTION DEVICES - Google Patents

Abstract

The invention relates to a device for distribution accuracy determination of Verteilgeraeten, in particular for koerniges, crystalline and liquid scattered and sprayed, and is preferably used in the field of agriculture and forestry use. The object of the invention is to provide a simply constructed device for rapid determination of the application rate and the distribution accuracy of Verteilgeraeten with minimal manual labor. The invention has for its object to determine the lateral distribution and the total mass or volume throughput per unit time of Verteilgeraeten by automatic data acquisition and measurement data processing. According to the invention, the object is achieved by a device in which the mass distribution transversely to the direction of travel is determined by catching devices arranged at defined distances in the vicinity of the ground, in particular latched collecting surfaces, with coupled sensors, for example piezoelectric pickups, which are connected to a data acquisition and processing unit becomes. Fig. 2

Description

For this 1 page drawings

Field of application of the invention

The invention relates to a device for determining the distribution accuracy of distribution devices, in particular for granular, crystalline and liquid scattered and sprayed and preferably used in the field of agriculture and forestry use.

Characteristic of the known technical solutions

To determine the transverse distribution of distributors collecting trays are used, which are designed individually on the ground or arranged in a frame rigid or tiltable in series transverse to the direction of travel of the Verteilgerätes (DD-PS 202605, 211 051, 214 279 and 214988).

Another known measuring method is to drive the attached to a carrier or carriage drip trays at standstill of the Verteilgerätes through the scattering fan. The contents of the drip trays are collected in measuring tubes and determined volumetrically or gravimetrically. The measured values are calculated by means of a computer and the tubes have to be cleaned individually.

It is also known, below the litter or spray organ in a tubular frame next to each other collecting gutters and / or container to arrange, the content of which is determined in the same way volumetrically or gravimetrically.

To facilitate the collection of the collecting trays they are placed in individual measuring systems on a transverse conveyor belt, so that they can be removed and dumped at the end of this.

The disadvantage is that these measurement methods for practical issues require too much manual labor time and the application rate and the transverse distribution of the scattering and injection material and thus the possible working width and machine adjustment to be made visible only after complex measured value determination and processing.

Also, the detection of the distribution of the scattering and injection material along the road at different distances from the center of the scattering and spraying device is not possible or by parallel arrangement of rows of shells only to a very limited extent.

A partial reduction of the workload is achieved if large gaps are left between the drip trays laid out on the floor (DD-PS 211 051), whereby the detection and evaluation effort remains. Furthermore, it should be noted that the reproducibility of the scattering curve is possible only in a narrowly limited range of errors, so that the income-influencing coarse deviations can not or only insufficiently determined.

Furthermore, it is known that the drip trays has been provided with electronic weighing devices that are directly connected to a computer. Apart from the not practical for the general practice economic expenses and to avoid measuring errors barely complied installation conditions remains the pouring and cleaning the collecting vessels by hand, so that an automatic measurement in a row in self-service is not possible.

It has also been proposed (DD-PS 210119) to determine the distribution accuracy of distribution devices by collecting the material to be spread at a small distance from the centrifugal disc and determining its mass per unit time. Taking into account a changing grain spectrum of the material to be spread, the particle size of the centrifugal disc, the proportion of dust-like particles and the factors influencing the acceleration and the flight of the particles

is a correlation between the thus determined good distribution and the stray inaccuracy on the field is not given with sufficient certainty. Likewise, the measuring device set forth in DE-OS 3033 666 is to be judged for the determination of the scattering distance and application rate.

In individual cases, the measuring devices for determining the transverse distribution of distribution devices by special collecting bag or container or arranged in the direction of drip trays to determine the throughput per unit time and thus the application rate per unit area are added (DD-PS 208746, DE-OS 3229149). Again, the high amount of manual labor makes it difficult to quickly determine this measurand.

The consequence of these shortcomings is that the distribution accuracy of the distribution devices used in practice at very large intervals, but usually not determined at all, so that a corresponding adjustment correction does not occur. Sampling measurements showed significant deviations of the actual plant-based distribution accuracy, resulting in high yield losses and changing sometimes unknown high use of agrochemicals with all the known economic, technological, organic, environmental and health-endangering disadvantages.

Object of the invention

The aim of the invention is to provide a cheap and simply constructed, robust and functionally reliable device for rapid determination of the application rate and the distribution accuracy of distribution devices and based thereon Einstellhinweisen for distribution devices with minimal manual labor.

Essence of the invention

The invention is based on the object by a corresponding device, the transverse or longitudinal distribution and the total mass or volume throughput per unit time of distributors by an automatic and cost-effective data acquisition of the arriving at the bottom or in the amount of plant life spill and spray quantity determine and thus enable a coupling of measured data acquisition and processing.

According to the invention, the object is achieved by a device moved relative to the distribution device, in which the distribution of masses of a distribution device is determined transversely or longitudinally to the direction of travel by ground level or in the plant stand corresponding height at defined intervals or gapless arranged collecting devices with coupled sensors, the In turn, via Kabei, radio or the like with a data acquisition and processing unit are connected. Setting instructions can be derived from the calculation result or are given directly by the data processing unit by comparison with type-specific deviations of the scattering curve.

As a collecting device preferably serves an inclined collecting surface, which can be optionally provided with a collecting funnel with or without lattice-like internals up and is connected directly or indirectly via an open outlet with a mass or flow sensor. The collecting surface can be adapted in its inclination to the grain spectrum of the material to be spread in direct coupling with the sensor, for example, piezoelectric pickup. If the sensor of the oblique collecting surface, which causes an approximate equalization of the speed of the particles downstream, it is also variable depending on the Gutart and the desired self-cleaning effect, the measuring surface of the sensor at a distance from the transfer edge of the collecting surface and the angle of attack. Depending on the design of the sensor, the number of grains of the material to be spread, for example. As the number of pulses or the mass as the pulse density, both in time, determined.

If the distribution accuracy of liquid agents are determined, the inclined collecting surface is arranged downstream of a funnel inlet a tuned in length and inside diameter on the sample and calibrated in terms of flow rate measuring tube through which the trapped spray liquid flows with complete filling of the inner cross section of the tube. Beginning and end of the outflow are detected, for example, via a light barrier, so that it can calculate the collected volume. For safe switching of the light barrier, if necessary, the liquid can be stained, for example by means of special color stripes, which are glued to the collecting surface, or from the outset. Different weather conditions can be simulated with the blower which can optionally be positioned in the outer measuring range, and with extremely large scattering width the transverse distribution of the scattered material can be defined in a squeezable manner. The lateral boundary of the entry and exit path and the measuring surface is used to avoid spillage losses and the weather protection to maintain the measuring device. The basic results calculated by the computer are based solely on measured values, or the intermediate and external values of the scattering curve have been calculated in continuation of their course given by sampling measurements.

The coefficient of variation of the transverse or longitudinal distribution and the height of the regression line belonging to the respective working width, which is proportional to the total mass flow, are preferably calculated. By comparing the coefficient of variation of the lateral distribution of the distribution device calculated with respect to the overlap with that determined by standard or other guidelines, such as the mass distribution number to be observed, z. B. confirmed for a given working width compliance with the distribution quality or the maximum working width can be specified. Information about the correction of the application rate can be derived from the position of the regression line calculated for the specific working width and comparison with the error range corresponding to the given application rate. By comparing the actual distribution curve with stored machine-typical deviations of the distribution curves including the required machine-specific corrections immediately after the Meßdurchfahrt the necessary adjustment bases are available or the distribution device in conjunction with the corresponding scattered and sprayed to perform the distribution work in the required quality and in compliance with the constraints, such as working width and coefficient of variation, released.

embodiment

Hereinafter, preferred embodiments of the invention will be described with reference to the drawings. Show:

Figure 1: A collecting surface with directly connected sensor (side view - schematic) Figure 2: A collecting surface with funnel and downstream sensor (partial section - schematically) Figure 3: A collecting surface with funnel and downstream measuring tube (partial section - schematic)

The z.T. in different levels can be set up collecting surface (1) is adjustable in accordance with the Gutart in the angle of attack and directly to the sensor (2), for example piezoelectric pulse counter combined. It is arranged without gaps or with a defined distance in the stray field and moved relative to the distribution device.

The collecting surface (1) shown in Figure 2 with attached funnel (3), which may be provided with cross plates (4) is placed analogously to the collecting surface of Figure 1 and arranged in the stray field, also moves and opens through an open outlet (5). over the measuring surface of a sensor (2) or goes into this. The measuring surface of the sensor (2), for example a piezoelectric pulse meter or equipped with strain gauges, can be adjusted according to the material to be used and the sensitivity of the sensor at a distance from the transfer edge (6) of the collecting surface (1) and in terms of angle of attack. For measuring liquids, the outlet of the collecting surface (1) according to FIG. 3 opens into a measuring tube (7) tuned in length and inner diameter to the material to be measured and calibrated in terms of flow rate. The sensor used is, for example, a light barrier detecting the liquid flow (8). If necessary, special foil can be glued to the collecting surface to stain the liquid.

To determine the driving speed of the distributor or the carrier of the collecting surfaces, for example, a non-illustrated, laterally mounted on the distributor or support resilient measuring flag is guided past at a certain distance arranged proximity sensors.

In the outer measuring range, a variable in jet direction and strength fan can be set up. The entry and exit path is preferably confined with flexible material and the collecting surfaces (1) can be covered in case of need.

All sensors and proximity sensors are connected via cable, radio or the like with a data acquisition and processing unit with a corresponding result representation.

At the beginning of the measuring run, the particles or droplets falling on the collecting surface (1) are determined depending on the type of good and existing sensor (2) overpayment, pulse density measurement or by means of weighing plate and flow tube until the end of the measuring drive or journeys depending on the used Sensor electronically added and stored and charged by computer for specified working widths and / or strains inaccuracies and application rate.

If machine-typical setting errors including the associated setting correction are stored, appropriate setting instructions for the distributing device can be given by comparison. The optionally deployable blower generates a defined against the flight of the particles defined air flow, so that weather conditions can be simulated.

The main advantages of the invention will become apparent from the elimination of the laborious and tedious determination of the transverse and longitudinal distribution and application rate of distribution devices of different types. This makes it possible to measure the quality of work of these devices at short intervals and optimally adjust them at change of center and changed requirements such as working width, application rate and height of the crop. By supplying plants with nutrients as needed, a considerable increase in yield, less consumption of agrochemicals and a reduced environmental impact are to be expected.

Another advantage of the invention is the significant rationalization of scientific investigations into the distribution of solid and liquid substances. In this case, an increase in the accuracy of the measured value acquisition is achieved with immediate data processing.

Claims (8)

Invention claim: 1. Device for distribution accuracy determination of distributors, especially agricultural litter and spray vehicles, in which in their work consistently or incompletely arranged, relative and defined moving to the distribution device or stationarily set up, and with known volume or mass flow sensors that directly or indirectly to a computer coupled with integrated result representation and evaluation, coupled collecting devices are used, characterized in that the can be set up as required in different levels collecting devices have a sloping collecting surface (1) with a collecting funnel (3) or shaft with or without lattice-shaped Internals (4) can optionally be provided and which are connected directly or via an open outlet (5) indirectly with a mass or flow sensor (2). 2. collecting device according to item 1, characterized in that the sensor (2) preferably a pulse, Partikelzähl- or -meßeinrichtung, a weighing plate or with a light barrier (8) or the like. Provided, interchangeable calibrated tube (7), a tilting bowl or the like. 3. collecting device according to item 1 and 2, characterized in that the measuring surface of the sensor (2) in an inclined position and indirect connection of the collecting surface with the sensor is additionally adjustable at a distance from the transfer edge. 4. collecting device according to item 1 to 3, characterized in that the collecting surface can optionally be provided with a slightly soluble, the measuring liquid without volume change staining substance. 5. collecting device according to item 1 to 4, characterized in that it optionally has a conventional weather protection and the associated input and Ausfahrstrecke and measuring surface can be limited laterally by preferably with flexible material covered, easily deployable frame. 6. collecting device according to item 1 to 5, characterized in that it has a high degree of corrosion protection and the applied surfaces temporarily with protective material, but releasable, can occupy and / or can be easily cleaned by special surface finish. 7. Collecting device according to item 1 to 6, characterized in that at the legs of the distribution device or a carrier of the collecting device at a defined distance proximity, photocells or the like. Installed, which are connected for example by a distributor or carrier resiliently mounted metal tab and the direct computer are connected. 8. collecting device according to item 1 to 7, characterized in that optionally a fan can be arranged in the lateral outer region.