DE4426059A1 - Harvesting machine, particularly self-propelled chaff-cutter - Google Patents

Abstract

The machine has an operator's position, esp. a driver's cabin, and a delivery device, esp. an ejection chute, for delivering harvested goods, which have been picked up and processed, to a transport lorry. An electrooptical device mounted on the delivery device is used for directional control of the delivery device during delivery to the transport trailer. The electrooptical device is a camera (9) whose monitoring region (B) is directed towards the end region (7b) of the delivery device (7) and the loading chamber (2a) of the transport trailer (2). The camera is connected to a monitor (10) in the operator's position (4) for superimposed representation of the alignment of the end region and loading vol.

Description

The invention relates to a harvesting machine, in particular a self-propelled forage harvester with an operator station, in particular a driver's cab and a delivery device, in particular an ejection sheet to promote ingested and processed crop on a dolly, one at electro-optical device attached to the dispenser to control the direction of the delivery device during the conveying process is provided on the dolly.

Such an agricultural machine, especially in the execution as self-propelled forage harvester is from DE 31 12 826 A1 known. Here is an electro-optical device provided that attached to the discharge chute of the forage harvester and a scanning area with an optical signal (e.g. bundled light beam) illuminated. On the carried Collecting vehicle or transport trolley is a reflector arranged of the optical signal for electro-optical Device reflected back that reflected the Receives output signal and controls logic devices in such a way that control signals are generated to drive a motor can be used to control the direction of the discharge chute. These However, the device for automatic control controls the chute only in the horizontal swivel direction, like this is required especially when cornering. Although therefore for the automatic control operated a considerable amount of construction work this automatic control requires manual Tracking to ensure even filling of the To enable trolleys.

This version with a directly on the forage harvester attached dolly, however, has not been in practice enforced, because the direct attachment of a dolly a self-propelled forage harvester is hardly operated anymore. This is because modern forage harvesters have a very have high crop throughput, so that a trolley in  Filled in minutes, and therefore a very common one Reassignment of the trolley would have to be done with the appropriate Downtime of the forage harvester. Therefore, in practice in general the trolley by means of a tractor or other towing vehicle parallel to the forage harvester, so that a "flying" change between a full and a empty dolly can be done. Are often for one single forage harvester depending on the length of the transport route from the field ten or more transport trolleys in use for the storage silo.

In the system according to DE 31 12 826 A1 everyone would have to individual transport trolleys with a reflector on the front of the trolley. Here arise but again two disadvantages, namely that the reflector at the front of the dolly mostly from the Tractor cabin would be covered, especially if the Dolly parallel and essentially next to the Forage harvester drives. In addition, the reflector is about Drop area of the crop, so that lighter crop, such as for example, corn flakes can interrupt the beam path or dust makes the reflector ineffective.

Accordingly, the invention has for its object the above to avoid the disadvantages mentioned and in particular a simple, effective yet comfortable to use To create a control device for a harvester.

This object is achieved by a harvesting machine according to the Features of claim 1.

By forming the electro-optical device by a Camera instead of a transmitter for a bundled beam of light is achieved that none on the trolley side Reflectors are needed. So the proposed works Control system independently, d. H. without on each one Transport trolleys take special precautions or devices to have to. This means that it is sufficient to set up the control system alone on the harvester, with independently a variety of  different transport trolleys can be used. As a result, the total effort is considerably reduced, whereby also on the cleanliness of the reflectors or the accessibility for a light beam does not have to be considered.

By aligning the surveillance area of the camera the end area of the dispenser and the loading space of the The trolley is in the driver's cab for the operator by the orientation or position of the end area, in particular the chute of the chute in the Training as a forage harvester regarding the direction of conveyance Loading space of the transport trolley is precise and ergonomically cheaper Way visible, since the driver is not constantly on The trolley must turn around. Through the overlaid Representation of the end area, especially the discharge flap or a bearing beam arranged thereon on the one hand and the On the other hand, the loading space of the transport vehicle is the exact one Alignment of the dispenser both horizontally as well as in the vertical direction. Through this The operator can display overlay on the monitor thus the orientation of the crop beam at first glance recognize in right / left or up / down direction and if necessary. readjust so that the dispenser also when cornering or heavily hilly terrain can be readjusted quickly, thus the crop stream conveyed at high speed not hurled past the cargo area of the trolley becomes.

It should be noted that by capturing and Representation of the end region of the delivery device, in particular the discharge flap also one compared to the prior art Orientation in the height direction at the same time as the superimposed one Representation in the width direction is possible. The preferred Representation of the ejection flap on the upper edge of the monitor serves as a bearing mark with which in the manner of a rear sight grain Targeting the impact area in the hold of the Transport vehicle can be targeted precisely. This bearing leaves  through an over or to the side of the chute attached light beam transmitter, especially a laser or further improve bright lighting (spot).

In a preferred embodiment, the camera is with a Wide-angle lens, as is common with video or CCD cameras, equipped, the total length of the cargo space of the Transport carriage is detected, so that by the vertical control (Up / down) of the discharge flap swept the entire cargo space can be. This allows the driver to control the Ejection flap through a joystick-style stick Take over directly from the operator station, using the joystick preferably following the monitor with the same orientation is arranged so that the driver's field of vision corresponding control by right / left or forward / backward for the directional control of the ejection direction to adapt to the Carriage length can be made, and the result by the Feedback is immediately visible on the monitor. By this quickly responding control can also do so brief changes in distance between the forage harvester and the Transport trolleys, such as this during switching operations and / or braking of either the forage harvester or the Transport trolley occurs.

In a preferred embodiment, however, manual instead of this Control also an automatic or semi-automatic control for both or one direction of movement of the discharge chute be made by the one recorded by the camera External delimitation of the cargo space as a border area by means of a Image capture is defined, and as another graphic Condition is that the camera also captured image and moved on the monitor in the manner of a cursor the end region of the dispenser (in particular the Ejection flap) the outer limit shown on the monitor must not leave the hold. So if this is different from the Camera captured image of the chute, e.g. B. at one Braking of the trolley and / or acceleration  of the forage harvester and the rear wall of the transport vehicle a control signal is given, that the chute is lowered and / or the Ejection bow is twisted so that the discharge length of the Crop is shortened.

Since the pictures of the trolley were taken or the end portion of the dispenser essentially the are the same, namely a rectangular shape of the loading space of the Trolley and a relatively short edge of the discharge flap, which on the monitor essentially as a short line or Circular arc section appears, using a Graphics processing these two superimposed, typical Images are schematic and using a Contrast enhancer these two are relatively movable, but also as a whole moving images to each other are shown more clearly.

Further advantageous embodiments are the subject of further subclaims.

An exemplary embodiment is described below with reference to the drawings explained and described in more detail. Here show:

Figure 1 is a schematic overall view of the harvesting machine with an associated transport carriage. and

Fig. 2 is an enlarged view of the delivery device of the harvesting machine with the associated control system.

In Fig. 1, a harvesting machine 1 is shown in the form of a self-propelled forage harvester, which runs parallel to the harvesting operation and in front of a transport carriage 2 with a loading space 2 a. The transport carriage 2 is pulled by a tractor 3 shown here only in broken lines, which is largely covered here by the harvesting machine 1 due to the offset direction of travel. At the harvesting machine 1 , an operator station 4 is provided for the driver, which is generally designed as a closed driver's cabin. Due to the elevated arrangement of the operator station 4 on the front of the harvesting machine 1 , the driver has a good view of a pick-up device 5 , which in the embodiment shown here is designed as a maize header, but can also be a pick-up for the use of grass. The pick-up device 5 cuts off the corn to be picked up and conveys it to a chopping device 6 below the operating station 4 . The chopping device 6 , in particular in the version as a drum chopper, hurls the chopped crop in connection with a downstream blower (not specified in more detail) at high speed through a dispensing device 7 , which is designed in the usual form as an ejection sheet 7 c. The discharge chute 7 c can be rotated about a vertical axis 7 a to the right or left for lateral control of the crop beam A emerging from the dispensing device 7 at high speed and shown in dash-dotted lines. For further adjusting the crop material A in the longitudinal direction with respect to the loading space 2 a of the trolley 2 is at the end portion 7 of the dispenser b an ejection flap 8 preferably, as a so-called. Double flap provided by at least a horizontal axis 8 a in the vertical direction according to the arrow shown in the drawing plane is adjustable. If the discharge flap 8 is thus pivoted downwards or downwards in the direction V with respect to the position shown, the crop beam hits further forward (in relation to the direction of travel) in the loading space 2 a of the transport vehicle 2 . The opposite direction is in this case identified by the letters Z, since then the crop discharge flow A further back in the loading space 2 a is incident, and can drive the trolley 2 further set back by a distance change with respect to the forage harvester. 1 It should be noted that the distance a shown here is difficult to maintain during operation, since acceleration and / or braking operations are required at the beginning or end of the field, which are difficult for the two drivers to synchronize. Even during switching operations, the distance a changes accordingly, so that by adjusting the discharge flap 8, the discharge angle of the crop jet A must be continuously adjusted. On the other hand, the position of the dispensing device 7 in the width direction (right / left) must be readjusted frequently, particularly when cornering. This complicates the fact that many drivers prefer an almost parallel driving style when harvesting, that is, tractor drivers and choppers are roughly level in the direction of travel. Since the discharge chute is oriented approximately 45-60 ° to the direction of travel, a change in the distance a must then be readjusted both about the vertical axis 7 a and about the horizontal axis 8 a.

According innovation is now on the underside of the spout 7 c a camera 9, for example. B. a video or CCD camera is provided, which is aligned with its monitoring area B indicated by two dash-dotted lines both on the end area 7 b of the dispensing device 7 , that is to say in this exemplary embodiment, on the ejection flap 8 and also on the loading space 2 a of the transport carriage 2 . The image recorded by the camera 9 is displayed on a monitor 10 arranged at the operator station 4 within the driver's cabin. This monitor 10 is preferably arranged obliquely in front of the driver, so that he has the monitor 10 together with the receiving device 5 in view. The camera 9 is preferably equipped with a wide-angle lens in order to record the total length of the loading space 2 a of the transport vehicle 2 , and to be able to display it on the monitor 10 as an image 2 a '(see FIG. 2), the end region 7 b also Dispensing device 7 with the discharge flap 8 as corresponding images 7 b ', 8 ' are displayed in a superimposed representation on the monitor 10 . In order to be able to carry out work at night as well, in addition to the already existing illumination of the rear area of the harvesting machine 1 , a headlamp 11 aligned parallel to the camera 9 can also be arranged on the discharge chute 7 c in order to ensure appropriate illumination of the working area in the loading space 2 a . In order to control the dispensing device 7 with respect to the transport carriage 2, that a pivoting of the spout 7 around the vertical axis 7a in the width direction (left / right), as is indicated in Fig. 2 with the letters R and L, in the grip region on the operator's cab 4 a joystick 12 is provided in the manner of a joystick, with the addition to the right / left control (by means of a on the vertical axis 7a acting twisting or servo motor 13) and the adjustment of the end portion 7 b, in particular the discharge flap 8 about the horizontal axis 8a (by means of an adjusting motor 14 ) in order to set the discharge angle of the crop beam A with respect to the transport carriage 2 .

The arrangement mentioned above is shown enlarged in FIG. 2, the same reference numerals as in FIG. 1 being used. As can be seen, here on the monitor 10 in the upper region of the end region 7 b of the dispensing device 7 with the ejection flap 8 as corresponding images 7 b 'and 8 ', as well as the image 2 a 'of the loading space 2 a. It is essential here that these images are overlapping or overlapping, so that the operator can judge at a glance in which area of the transport carriage 2 the crop crop beam A strikes. If thus the driver of the tractor 3 would brake heavily or, for example, interconnected, the image 2 a 'of the transport carriage 2 would move upwards on the monitor 10 due to the increase in the distance a (see FIG. 1), so that at further braking the front edge of the cargo space 2 a would overlap with the slightly curved curve 8 shown here for illustration 8 'of the discharge flap 8 . This would mean that the crop beam A moves towards the front end of the loading space 2 a or even beyond, so that the crop beam A would strike the front wall of the transport vehicle 2 . By appropriate readjustment on the control stick 12 , namely here in the direction "back", that is in the direction marked with the letter Z, the adjusting motor 14 for the ejection flap 8 would be actuated, namely pivoting upward, so that compared to the total upward pushed image 2 a 'also the Fig. 8 ' of the discharge flap 8 moves upwards on the monitor 10 , since it is moving away from the monitoring area B upwards. This will at the same time again the superposition of the images 8 'and 2 a' is reached, so that the image arcuately shown here 8 'of the discharge flap 8 again within the trapezoidal image 2a' of the cargo space 2 there is a. Through this mutual association of, ejection flap 8 and loading space 2 a or the taken by the camera 9 images, the driver must pay attention only to the fact that the image is 8 'within the trapezoidal-shaped frame 2 a', whereby in addition to the Up and downward movement on the monitor 10 also lateral movements in the right / left direction or inclined positions can be detected. The driver must thus only pay attention in the manner of a known computer or video game controls cursor control that the image 8 'of the discharge flap 8 within the trapezoid-shaped frame 2 a', that is, the image of the loading space 2 a, is located.

To enhance the contrast and clearer representation, the fact known from image processing systems can be exploited that the trolleys 2 basically have a rectangular base area, so that the loading space 2 a appears on the monitor 10 as a trapezoidal image 2 a 'due to the perspective image, as is indicated here in particularly strong lines. This basic shape, which is essentially always the same, can be recognized by means of a graphic evaluation or computer-controlled image recognition, and the contrast effect on the monitor 10 can be increased, for example, by colored application. The same applies to the ejection flap 8 or its image 8 ', since this image remains basically the same in size and only moves on the monitor 10 depending on the pivoting position about the horizontal axis 8 a up or down.

In a further development of this image recognition of the relative position of the ejection flap 8 or its image 8 'can also be defined by appropriate image processing that the adjusting motors 13 and 14 are controlled so that the image 8th by means of an automatic control instead of manual readjustment by the control stick 12 'The discharge flap 8 must not leave the appearing as a trapezoidal frame image 2 a' of the cargo area 2 a. Thus, if the driver of the tractor 3 steers sharply to one side, the trapezoidal frame 2 a 'would move laterally on the monitor 10 or tilt, so that there is a point of contact with the image 8'. When this touch occurs, the adjustment motor 13 can thus be controlled by a corresponding graphics program (or in the case of a semi-automatic version, a warning signal is given to the driver, which becomes more intense, for example, with an increasing overlap of the picture elements 8 ′ with 2 a ′) thus comply with the position shown here on the monitor 10 , namely that the image 8 'is enclosed within the trapezoidal frame 2 a', but does not touch this line drawn here more strongly or when touching occurs due to deviations between the harvester 1 and the trolley 2 is made a corresponding correction via the adjusting motors 13 and / or 14 .

It should be pointed out that such image processing and image typing is known per se from the video area, as are the cameras 9 used here with autofocus systems and corresponding monitors 10 . By using such standard components, the proposed control system for the harvesting machine 1 results in a portable cost, which is also due to the advantages achieved, namely the relief of the two drivers of the harvesting machine or the tractor, and a full filling of the transport vehicle 2 without the risk of Loss of crop material is compensated for by inexperienced drivers by moving the crop beam A past the transport carriage 2 . It should be noted that even with a colored application of the picture elements 2 a 'and 8 ', a black and white camera is sufficient, because due to the typical outlines, these pictures can be schematized and only created in color by software.

To support and improve the range and bearing accuracy even a light transmitter 15 can, on the ejector cover. 8 B. a laser or bright spot can be arranged, which marks the point of incidence 16 'of the crop beam A in the hold 2 a with a light beam 16 due to the parallel orientation. This point of impact 16 'is also shown as a light spot on the monitor 10 , and also makes it easier for the driver to find the target, since this simulates the point of impact of the crop beam A. It should be noted that when the light transmitter 15 is arranged on the side of the ejection flap 8, the light beam 16 with its point of impact 16 'is also visible during operation and with a wide crop beam A. As a result, the point of impact 16 'on the monitor 10 can supplement or at least partially replace the image of the discharge flap 8 as a bearing mark 8 '. Instead of the light emitter 15 with the light beam 16 and the rotational position of the ejection flap 8 can be obtained by scanning of horizontal axis 8 a or the adjustment of the adjusting motor 14 are detected and inputted to the monitor 10 by means of a data line 17th In this way, the movement of the bearing mark 8 'or 16 ' in the y direction can be controlled, so that an intersection point for determining the bearing mark can be formed by the position determined by the camera 9 in the x direction and can be displayed on the monitor.

The preferred application relates to one below Fan chute of a forage harvester, however, others working in multiple directions can also Dispensers of other harvesters equipped with it will.

Claims (10)

1. Harvesting machine, in particular a self-propelled forage harvester with an operator station, in particular a driver's cab and a delivery device, in particular an ejection sheet for conveying picked and processed crops onto a transport trolley, an electro-optical device attached to the delivery device for controlling the direction of the delivery device during the conveying process onto the transport trolley is provided, characterized in that the electro-optical device is formed by a camera ( 9 ) whose monitoring area (B) is directed towards the end area ( 7 b) of the delivery device ( 7 ) and the loading space ( 2 a) of the transport carriage ( 2 ) and the camera (9) having disposed at the operator station (4) monitor (10) for the superposed representation of the orientation of the terminal segment (b 7) and the loading space (2 a) is connected. 2. Harvester according to claim 1, characterized in that the camera ( 9 ) is equipped with a wide-angle lens for detecting the total length of the loading space ( 2 a) of the trolley ( 2 ). 3. Harvester according to claim 1 or 2, characterized in that the end region ( 7 b) of the dispensing device ( 7 ) is formed by at least one ejector flap ( 8 ) which can be pivoted in the vertical direction. 4. Harvester according to claim 3, characterized in that the discharge flap ( 8 ) in the upper region of the monitor ( 10 ) is shown as a bearing mark ( 8 '). 5. Harvester according to one of claims 1 to 4, characterized in that the camera ( 9 ) on the underside of the ejection sheet ( 7 c) of the dispenser ( 7 ) is attached in the region of its greatest curvature. 6. Harvester according to one of claims 1 to 5, characterized in that at least one parallel headlight ( 11 ) is provided on the camera ( 9 ). 7. Harvester according to one of claims 3 to 6, characterized in that for controlling the ejection flap ( 8 ) in two dimensions (right / left; up / down) movable control stick ( 12 ) at the operator station ( 4 ) in the vicinity of the monitor ( 10 ) is provided. 8. Harvester according to one of claims 1 to 6, characterized in that the dispensing device ( 7 ), in particular its ejection flap ( 8 ) is controlled so that the images taken by the camera ( 9 ) of the end region of the dispensing device ( 7 b ' ) or the discharge flap ( 8 ') overlap with the monitor image of the cargo area ( 2 a'). 9. Harvester according to one of claims 1 to 8, characterized in that the images of the end region ( 7 b ') or the ejection flap ( 8 ') and / or the outer boundary of the loading space ( 2 a ') shown on the monitor ( 10 ) ) are shown in a schematic, contrast-enhanced form. 10. Harvesting machine according to one of claims 1 to 9, characterized in that at the end region ( 7 b) of the dispensing device ( 7 ), in particular above or to the side of the discharge flap ( 8 ), a light transmitter ( 15 ) for emitting a crop beam (A) parallel light beam ( 16 ) is provided in the loading space ( 2 a), the point of impact ( 16 ') on the monitor ( 10 ) is shown as a bearing mark.