NL2020002B1 - Sampling wheel - Google Patents

Abstract

The invention relates to a sampling device for taking successive soil samples from a soil, wherein the sampling device is provided with a frame, a sampling wheel with a sample plug and a first ram provided with an expresser for ejecting the soil samples to a sample collector upon passing thereof, and a sample wheel driven drive for operating the sample collector, the drive comprising a first transmission with a first transmission ratio by which the number of times the sample collector is operated from the closed position to the open position is lower than the number of sample plug passages along the sample collector.

Description

Sample wheel

BACKGROUND OF THE INVENTION

The present invention relates to a sampling device for taking successive soil samples from a soil. The soil samples are used, for example, to determine the soil quality or the presence of diseases of a field. The soil samples must form a representative sample of the field.

A known sampling device comprises sample plugs that are driven over a soil to be sampled and thereby protrude soil samples over regular distances.

SUMMARY OF THE INVENTION

A drawback of the known sampling device is that the fixed regular distance results in that relatively large sample material is collected for large plots, while only a fraction of material is required for the representative sample.

It is an object of the present invention to provide a sampling device for taking successive soil samples with which a representative sample can be taken for relatively large plots.

The invention provides from a first aspect a sampling device for taking successive soil samples from a bottom, wherein the sampling device is provided with a frame, a sampling wheel rotatably mounted on the frame, and a sample collector for collecting the soil samples, wherein the The sampling wheel comprises a circumferential tread and at least one of its protruding sample plugs for receiving the soil samples, and a first ram provided with an extender in the sample plug for ejecting the soil samples to the sample collector as it passes, the sample collector being operable is between an open position in which an ejected soil sample is received, and a closed position in which the ejected soil sample is rejected, wherein the soil sampling device is provided with a drive driven by the sampling wheel for operating the sample collection each other, wherein the drive comprises a first transmission with a first transmission ratio by which the number of times that the sample collector is operated from the closed position to the open position is lower than the number of sample plug passages along the sample collector.

The sampling device according to the invention has a sampling wheel which is provided with a sample plug and which operates the sample collector via the drive. Here, the number of times the sample collector picks up a discharged soil sample is lower than the number of times the sample plug offers a soil sample. This limits the amount of collected material.

In one embodiment, the first transmission comprises a first gear driven by the sampling wheel, and a second gear engaging the sample collector.

In one embodiment, the first transmission forms part of a switch set with a second transmission with a second transmission ratio that differs from the first transmission ratio, the first transmission and the second transmission being interchangeable. The use of the switch set makes it possible to adjust the number of soil samples taken per distance traveled, so that more or fewer soil samples can be taken per distance traveled.

In an embodiment thereof, the second transmission ratio is lower than the first transmission ratio.

In one embodiment, the first ram rotates with the sampling wheel and is provided with a follower following a curve track fixedly connected to the frame, the curve track moving the expressor between a retracted position in which a soil sample can be received in the sample plug, and an expanded position in which that soil sample was pressed out of the sample plug.

In one embodiment the drive comprises a drive shaft and a curve track connected thereto, and a follower which follows the curve track and thereby operates the sample collector between the open position and the closed position.

In one embodiment, the sample collector is provided with a holder or funnel with an opening for receiving the soil samples, and a valve that is movable relative to the opening between an open position and a closed position and thus the open position and the closed position from the sample collector.

In one embodiment, the sample plug is hollow and the expresser is movable through the sample plug.

In one embodiment, the sampling device is provided with a gimbal coupling to the frame for coupling with a towing vehicle. The gimbal coupling can keep the sampling wheel upright on the bottom.

The aspects and measures described in this description and claims of the application and / or shown in the drawings of this application can, where possible, also be applied separately from each other. Those individual aspects, and other aspects, can be the subject of split-off patent applications directed to them. This applies in particular to the measures and aspects that are described per se in the subclaims.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be elucidated on the basis of an exemplary embodiment shown in the accompanying drawings. 1A and 1B show a left isometric view and a right isometric side view of a sampling device according to an embodiment of the invention which is pulled by a quad over a soil to be sampled; Figures 2A and 2B show the sampling device in the views according to Figures 1A and 1B, some parts broken away or hidden parts with broken lines; and

Figure 3 shows details of the top of sampling device as shown in Figure 1A, with a portion broken away to show hidden parts thereof.

DETAILED DESCRIPTION OF THE DRAWINGS

Figures 1A and 1B show the rear of a quad 1 that can be driven by a person. The quad 1 is provided at the rear with a mounting plate 2 to which a sampling device 10 according to the invention is coupled. The sampling device 10 is adapted to take soil samples from the bottom 5 over regular distances, over which the sampling device 10 is pulled by the quad 1.

The sampling device 10 comprises a steel main frame 15 which is coupled to the mounting plate 2 by means of a gimbal coupling 16. The gimbal coupling 16 allows pivotal movements of the main frame 16 relative to the quad 1 about a vertical pivot axis A and a horizontal pivot axis B.

The main frame 15 comprises a rectangular frame 18 under which two bearing supports 19 are mounted halfway. Bearings 20 are mounted on this for a drive shaft 21 with a horizontal axis C extending transversely to the direction of travel. The sampling device 1 comprises a sampling wheel 30 with a circumferential ring 31 forming a flat circumferential tread surface 33, and a partially open connecting plate 32 which forms the transition to a wheel hub which accommodates bearings with which the sampling wheel 30 can rotate and independently of the drive shaft 21. The sampling wheel 30 is always upright on the bottom 5 due to the gimbal coupling 16.

As shown in Figures 2A and 2B, the sampling wheel 30 on the running ring 31 comprises a plurality of pins 34 which project radially outward from the running surface 33. When pulling the sampling device 10, the pins 34 protrude into the bottom 5 so that the sampling wheel 30 rotates in the direction of rotation D without slipping. The sampling wheel 30 comprises on the tread ring 31 in this example two hollow sample plugs 36 which are opposite each other and which project radially outwards from the tread surface 33. The sample plugs 36 protrude into the soil 5 as the sampling device 10 is being pulled and thereby take a soil sample 6 from the soil 5 in direction E.

The sampling wheel 10 comprises two parallel guide bars 37 which are fixed with end blocks 38 at the race ring 31 on the connecting plate 32, and two slides 39 on either side of the drive shaft 21 which can be slid back and forth in the radial direction F along the guide bars 37. The slides 39 are each connected to a first ram 40. As best shown in Fig. 3, at the end of the first ram a protector 41 is provided which is located in the sample plugs 36.

As best shown in Figure 2A, the sampling device 1 is provided with a curve plate 50 which is fixed with a spacer holder 51 free from the drive shaft 21 on the left bearing support 21. The curve plate 50 is free from the sampling wheel 30 and is provided with a smooth internal curve path 53 in which a ball bearing runs per slide 39 which is rotatably fixed to the slide 39. The shape of the curved track 53 thus determines the position of the pushers 41 in direction F relative to the rotational position of the sample plugs 36 in the direction of rotation D, wherein the pushers 41 are movable between a retracted position in which a soil sample 6 can enter the sample plugs 36 and an expanded position in which the inserted soil sample 36 is pressed out of the sample plugs 36.

As best shown in Figures 1A and 2A, the sampling device 10 is provided with a sample collector 60 for selectively collecting the pressed soil samples 6. The sample collector 60 comprises below the main frame 20 a steel subframe 61 hanging behind the sampling wheel 30, and two parallel mounting plates 62 on the subframe 61 between which a pivot axis 63 is rotatably mounted. A plate-shaped lid 64 is mounted on the tilt axis 63. The end thereof which faces the sampling wheel 30 is provided with a recess 65 for the sample plugs 30. As best shown in Figure 2B, the sample collector 60 is provided with two funnel plates 67 which are located under the valve 64 between the mounting plates 62. to form a sample hopper 68, the recess 65 being located outside the sample hopper 68.

The tilt axis 63 is connected to one end of a rod mechanism 70 which is mounted on the left side of the sampling device 10 on a support 71 on the subframe 61. The other end of the rod mechanism 70 is connected to a second ram 73. At the end of the second tappet 73 is secured by a ball bearing 74 which is held against a cam 80 on the drive shaft 21 by means of a compression spring 75. The cam 80 has a smooth external curve path 81 through which the rotation of the drive shaft 21 in direction J the cover 64 in direction G moves back and forth between a normally closed position as shown in the figures, and a momentarily raised open position in which a soil sample 6 can be collected in the sample funnel 68.

As shown in Figs. 1B and 2B, the sampling device 10 is provided on the right-hand side with a drive 90 for the drive shaft 21. The drive 90 comprises a driving gear 91 on the sampling wheel 30 and a gear wheel 92 engaging it on a stub shaft 93 which is rotatable mounted on the main frame 15. The drive 90 is furthermore provided with a first interchangeable set 95 with an interchangeable housing 96 in which a first transmission 97 is accommodated. The first interchangeable set 95 can easily be exchanged manually with a second interchangeable set with a second transmission different therefrom.

The first transmission 97 comprises a small first sprocket 98 that is slid over the stub shaft 93, and in engagement therewith a large second sprocket 99 which is slid over the drive shaft 21 and drives it in direction J. The first transmission 97 provides a first transmission ratio between the revolutions of the sampling wheel in the direction of rotation D, and thus between the number of passes of the sample plugs 36 along the sample collector 60, and the number of times that of those passages the valve 64 accesses the sample funnel 68 to collect a soil sample 6. Here, the inner curve track 53 and the outer curve track 81 are synchronized by means of indexations such that the pushers 41 make the ejection movement in direction F when the sample plugs 36 move through the recess 65 in the valve 64. The most usable part of the soil sample 6 is thereby pressed out of the sample plug 36 so that it is driven through the valve 64 into the sample funnel 68. The trailing contaminated portion falls on top of the valve 64 and slides off, leaving it outside the sample funnel 68. The number of passes of the sample plugs 36 along the sample collector forms an integer multiple N of the number of times the valve 64 is thereby opened, the integer multiple N = 1, 2, 3, 4, etc, increasing by integers.

In the example shown with the first interchangeable set 95, the valve 64 is opened once every two revolutions of the sampling wheel 30 in the direction D, whereby only one of the four inserted soil samples 6 is collected in the sample hopper 68. With the second interchangeable set, for example, it can be set that the valve 64 is opened once per rotation of the sampling wheel 30 in the direction D, so that only one of the two soil samples 6 is collected in the sample hopper 68. The person who pulls the sampling device 1 over the bottom 5 can determine and assemble the desired interchangeable set on site.

The above description is included to illustrate the operation of preferred embodiments of the invention, and not to limit the scope of the invention. Starting from the above explanation, many variations will be evident to those skilled in the art that fall within the scope of the present invention.

Claims (10)

A sampling device for taking successive soil samples from a soil, the sampling device comprising a frame, a sampling wheel rotatably mounted on the frame, and a sample collector for collecting the soil samples, the sampling wheel having a circumferential tread at least one of them protruding sample plug for receiving the soil samples, and a first ram provided with an extender in the sample plug for ejecting the soil samples to the sample collector upon passing thereof, the sample collector being operable between an open position in which an ejected soil sample is picked up, and a closed position in which the ejected soil sample is rejected, the soil sampling device being provided with a drive driven by the sampling wheel for operating the sample collector, the drive transmitting a first transfer comprises a first transmission ratio with which the number of times the sample collector is operated from the closed position to the open position is lower than the number of sample plug passages along the sample collector. A sampling device according to claim 1, wherein the first transmission comprises a first gear wheel driven by the sampling wheel, and a second gear wheel engaging the sample collector thereon. 3. A sampling device according to any one of the preceding claims, wherein the first transmission forms part of a switch set with a second transmission with a second transmission ratio that differs from the first transmission ratio, the first transmission and the second transmission being interchangeable. A sampling device according to claim 3, wherein the second transfer ratio is lower than the first transfer ratio. 5. A sampling device according to any one of the preceding claims, wherein the first ram rotates with the sampling wheel and is provided with a follower following a curve track fixedly connected to the frame, the curve track moving the expresser between a retracted position in which a soil sample can be received in the sample plug, and an expanded position in which that soil sample is pressed out of the sample plug. A sampling device according to any one of the preceding claims, wherein the drive comprises a drive shaft and a curve track connected thereto, and a follower that follows the curve track and thereby operates the sample collector between the open position and the closed position. A sampling device according to any one of the preceding claims, wherein the sample collector is provided with a holder or funnel with an opening for receiving the soil samples, and a valve which is movable relative to the opening between an open position and a closed position and therewith takes care of the open position and the closed position of the sample collector. A sampling device according to any one of the preceding claims, wherein the sample plug is hollow and the expresser is movable through the sample plug. A sampling device according to any one of the preceding claims, provided with a gimbal coupling to the frame for coupling to a towing vehicle. A computer-readable medium with computer-executable instructions adapted to cause an additive manufacturing apparatus, in particular a 3D printer, to manufacture a sampling device according to any one of the preceding claims.