BR102015005114A2 - forward flotation double-acting ground penetrating device - Google Patents

Abstract

forward flotation double-acting ground penetration device, which is an apparatus for holding a tillage instrument like a plow at a consistent working depth that utilizes a quadrilateral spring bias connection to hold the tillage instrument at a position that needs to float forward and up from the working depth thereby preventing unwanted flotation of the tillage instrument from the working depth until the tillage instrument encounters a substantially vertical load.

Description

DOUBLE FLOATING FLOOR ACTION PENETRATION DEVICE

FIELD OF INVENTION

[002] The present invention relates to an agricultural tillage device and more particularly to a double acting ground penetrating device and even more particularly to the attachment that maintains such a device at a constant working depth.

[003] BACKGROUND

Damage of working tools on the ground such as plows through abnormal pulling forces caused by reaching obstruction such as roots, stones, etc. is an old problem. The problem is suitably described in US Patent No. 5,560,433 to Grimm, which has attempted to solve the problem. Many types of devices have been incorporated into agricultural equipment to compensate for shock loads on the instrument caused by abnormal tractive forces in ground working tools. Earlier ground working devices utilize both floating and firing motions, allowing them to float vertically off the ground or to fire alternately full rearward and upward off the ground. These prior device bonding designs, which include US Patent 5,560,433, do not utilize the tensile load caused by their ground movements to resist vertical fluctuation or to help return the ground working tool to its working depth. original work after a complete firing cycle of said connection is reached. That is, with previous designs, the tillage device ground movement is in direct competition with the main ground load applicator of ground penetration devices (ie a downward pressure spring). Thus, movement of the ground drives the tillage device to float up and back in a manner that opposes downward pressure of the spring. In these earlier projects, precautions need to be taken to deal with the negative effects of ground movement on their opposite binding configurations. A coupling system is required that will utilize the ground movement tensile load thus adding the load of the main ground loader rather than competing with it, keeping the device in place. float at the desired working depth until the fully pre-projected firing load is reached.

SUMMARY OF THE INVENTION

A general object of the invention is to prevent unwanted fluctuation of the tillage tool above its desired tillage level while allowing the tool to fire if excessive force is encountered to prevent damage to the tool or connection. Another object of the invention is to use the tillage instrument's ground movement to increase the downward force applied by the downward pressure spring.

[007] In one embodiment of the ground engaging device coupling configuration, the coupling uses a "float forward" motion design, which requires the tillage device that hits the ground to move forward as the tillage device floats vertically upwards around the pivot connections of the link to the toolbar frame. The result of this design is a ground penetration device that utilizes ground motion to resist vertical fluctuation while the tool is operating at working depth thus allowing the full downward pressure of the associated spring to be applied.

In this embodiment, the project also utilizes ground motion to help return the ground penetration tool to its original working depth after a full shot that pivots the device up and out of the ground around its main pivot connection responsive to excessive force.

910091 BRIEF DESCRIPTION OF DRAWINGS

With reference to the drawings which are attached to this document and which form part of this invention, it can be seen that: [011] Figure 1 is a side elevational view of one embodiment of the invention with the instrument in working position. normal;

[2] Figure 2 is a side elevational view of the embodiment of Figure 1 displaced in a vertically floated position; and [013] Figure 3A is a side elevational view showing the interaction of the links in a floating action cycle of the double acting ground penetrating device;

Figure 3B is a side elevational view showing the interaction of links in a firing cycle of the double acting ground penetrating device;

Figure 4 is a side elevational view of the invention in a side elevational view of a prior art design.

[016] Figure 5 is a side elevational view of one embodiment of the invention with labeled joint connections.

170171 DETAILED DESCRIPTION

[018] One or more of the above objectives may be achieved, at least in part, by providing a double-acting connection that creates a tilt up and forward fluctuation path from its full tillage depth when the tillage device encounters a substantially vertical load. More specifically, the linkage is designed to keep the tillage instrument without fluctuation vertically up and forward in the presence of a normal traction load. This tendency to move up and forward is contrary to the forces transmitted to the tillage instrument by the movement of a main engine or tractor that pulls the instrument across the field, so the tensile load components resist such upward movement. and forward and tend to force the tillage instrument to its optimal tilling depth.

Referring to the drawings, for a clearer understanding of the invention, it can be seen that the tillage instrument 11 or plowing unit is connected to a toolbar 12 which is conventionally attached to a main motor or tractor, not shown. Toolbar 12 holds a bracket 14 which is secured thereto by a set of V-bolts 15 with complementary nuts and provides a pair of pivot pins for connection 16 that connects the toolbar to instrument 11. main pivot pin 18 provides an M-joint between bracket 14 and the front end of a main arm 20. The rear end of main arm 20 is connected to rod weld 22 at joint Z by a pivot pin 24. A rod weld 22 has tillage instrument 11 affixed to its lower end. The upper end of the rod weld 22 is connected to a rear linkage arm 28 in joint X by yet another pivot pin 29. The rear linkage arm 28 is connected to joint Y to the front linkage arm. upper 30 by pin 32. Upper front link arm 30 is connected to bracket 14 on joint N via pivot pin 34. Downward snap spring 36 is fitted to joint Y and connected to main arm 14 in P. It should be noted that the coupling configuration is such that the vertical separation between joints Z and X is always smaller than the vertical separation fixed between joints M and N on bracket 14 over the whole range of the tillage tool motion.

[020] In the embodiments shown, when a stone or other immovable object is encountered, two different device reactions are possible. The first possible reaction is when a force (F) greater than the normal tensile load is applied to the tillage instrument 11, all joints rotate except for joint Y, which is the joint between the upper front link link arm. 30 and the upper rear link link arm 28. It is this reaction that causes the "rising" flotation problem of prior art designs. The second possible reaction, when a force (F) greater than the normal tensile load is applied to the tillage instrument 11, all joints rotate except joint Z, which is the joint between the main arm 20 and the weld. It is this reaction that was purposely designed to occur first when the ground penetration device encounters force (F) at the working depth of the devices. This eliminates the "climb" problem experienced in the prior art. That is, in this grounding device coupling configuration, the coupling members were geometrically situated such that when the double acting ground penetrating device is at working depth, any force greater than the tensile load normal is substantially sufficient at the main pivot connection to rotate the Y-joint and fully trigger and rotate the ground penetrating device up and out of the ground. This is because the normal waterline for this mode is in the upward and forward direction, however, movement along this waterline resists ground and forward motion of the main motor, so the Y-joint "breaks" and the tillage instrument spins.

[021] The difference in the waterline of the present invention and the state of the art is shown in Figure 4. As can be seen, the dotted line of the plow point up and back is the float path to the tool point. Thus, the normal traction load tends to cause the tillage instrument to rise along this fluctuation path as opposed to the downward pressure of spring 36 and the soil will be tilled to an inconsistent depth. In contrast, the float path of the present invention is forward and upward and resists the rear and downstream components of the traction load, thereby maintaining the plow at its desired depth and providing a more uniform tillage.

[022] In one embodiment of the invention, the distance between the N and X connections is approximately 73.5% of the length between the M and Z pivot connections when in the normal tillage position. Additionally, the length between the Z and X pivot connections is approximately 50% of the length between the M and Z pivot connections. Additionally, the length between the M and N pivot connections is approximately 48% of the length between the pivot connections. M and Z. Also, the rear horizontal distance from connection N to connection M is approximately 16.05% of the length between pivot connections M and N. The working depth of the tillage device is reached when the vertical distance from connection X to port Z is approximately 91% of the length between pivot and X connections. At this point, the vertical distance produced from port X to port Z is approximately 96.5% of the vertical distance from port N to port. M, although the previous ratios produce a forward and upward fluctuation path for the tillage tool of this modality, it is important to note that the ratios can be varied to accommodate other forward and upward buoyancy paths that do not lead to rearward movement of the tillage instrument point during normal traction loads. Note that the term "length" refers to the measurement along the component, while "distance" refers to the actual linear separation between the designated points.

Referring to Figure 1 to 3a for a clearer understanding of the invention, it is noted that in Figure 1 the instrument is depicted in its full pulling position. In Figure 2, the instrument is depicted at ground level. Figure 3a is a combined image of the tillage instrument at full traction and in an untriggered floating position just above ground level. It may be noted that the tip of the instrument 11 above ground level is slightly ahead of the tip of the instrument 11 in its full traction.

[024] As can be seen from Figure 3B, when the excess force of a predetermined amount is found, the bond reacts along a rearward upward path T until it reaches its full firing position at the point at that the reset operation begins. This triggering action occurs before the tillage instrument floats, so the stored energy limb or spring 36 serves to dampen the tillage instrument during operation, but does not allow the tillage instrument to rise above its defined towing depth. .

Although in the foregoing descriptive report this invention has been described with respect to certain embodiments thereof and many details have been set for illustration purposes, it should be apparent to those skilled in the art that the invention is susceptible to additional embodiments and that certain The details described herein may be varied considerably without departing from the basic principles of the invention.

Claims (11)

1. DOUBLE FRONT FLOATING ACTION PENETRATION DEVICE, which has a connection that connects a tillage instrument 11 to a toolbar 12 characterized in that it comprises: a. a shank member having said tillage instrument 11 connected to its lower end; B. a main arm connected between said rod member and a support 14 attached to said toolbar 12; ç. front and rear snap links pivotably connected to each other with said front snap link pivotally connected to said support and said rear link being pivotably connected to said rod member; d. an energy storage member connected between said main arm 20 and the pivot connection between said front and rear rupture links; wherein the geometric configuration of each of said arms, links and welds is such that the tensile force applied to said tillage instrument 11 creates rotation in the pivot connection between said front and rear rupture links prior to rotation between said main arm and said shank member such that said tillage instrument is limited to floating up and forward during normal operation. CONNECTION according to claim 1, characterized in that said coupling maintains the angular relationship of said shank member as said coupling pushes said tillage device to move upwards and forwards as required. said tillage device encounters a substantially vertical load. CONNECTION according to claim 1, characterized in that the vertical distance from the pivot connection between said rod member and said rear breaking link to the pivot connection between said main arm and said member The stem length is less than 100% of the vertical distance between the front rupture arm connection to said support and the connection of said support to said main arm over the full range of movement of the tillage instrument 11. 4. APPARATUS FOR SUSTAINING A CLEANING DEVICE fixed to a bracket on a main engine so that the tillage device is propelled up and forward against a substantially vertical load, characterized in that it comprises: a. a substantially vertically oriented shank member pivotally connected to a main arm connected to said support and rigidly connected to said tillage device at a lower end thereof; and b. a coupling including a stored energy device for inclining said coupling in a ground engaging position, connected to an upper end of said rod member and said bracket to maintain the angular relationship of said member as said coupling drives said tillage device to move up and forward as said tillage device encounters a substantially vertical load. Apparatus according to claim 3, characterized in that the vertical distance from the pivot connection between said rod member and said connection to the pivot connection between said main arm and said rod member is less than 100% of the vertical distance between the connection of said connection with said support and the connection of said support with said main arm over the full range of motion of the tillage instrument. Apparatus according to claim 3, characterized in that said connection includes a front link rupture member and a rear link rupture member pivotally connected to one another and wherein said energy storage device is a spring connected to said pivot connection between said break members and said main arm with said spring maintaining sufficient tension between said main arm and said link break members to maintain said connection in balance until a force excessive traction is exerted on said tillage instrument. 7. CROPPING INSTRUMENT characterized by the fact that it has a transverse toolbar 12, a tillage instrument 11 configured to seek a predetermined operating ground engagement position as it is pulled across the ground and a linkage assembly for connect tillage instrument 11 to toolbar 12 to induce the damped unit's vertical buoyant movement in a generally forward and upward direction from its operational ground engagement position when a substantially vertical load is encountered and firing motion from a normal operating position below a ground surface to a fired position above ground when highly abnormal traction conditions are encountered, said coupling assembly comprising a generally vertical rod member connected to said instrument 11, a bracket 14 affixed to said toolbar 12, a lower fixed length main arm 20 which is pivotally connected at one end to said support by a first pivot connection and at an opposite end to said rod member for movement around a second pivot connection, wherein a rear break link extends above the main arm 20, said rear break link being pivotally connected at one end to said rod member in a third pivot connection and at an end opposite a front break link by a fourth pivot connection, said front snap link is pivotally connected to said support for movement around a fifth pivot connection, said front and rear snap links joined together in said fourth pivot connection are disposed between and above one in a center relation with respect to said third and fifth pivot connections and a spring mechanism for normally retaining said rupt links. a front and rear relative relationship not collapsible with each other in the operating position of the plowing unit and to inhibit said plowing unit from moving backward until a predetermined traction load has been exceeded as the plowing unit is pulled said spring mechanism further allowing said elements of said upper link to move into a related collapsed relationship in response to a predetermined firing load that is applied against the plowing unit in particular. that said second and third pivot connections are separated by a vertical distance which is less than the vertical distance separating the first and fifth pivot connections at all positions of said tillage instrument. CROPPING INSTRUMENT according to claim 7, characterized in that said coupling assembly maintains the angular relationship of said rod member as said coupling assembly pushes said tillage device to move towards up and forward as said tillage device encounters a substantially vertical load. 9. CROPPING INSTRUMENT characterized by the fact that it has a transverse toolbar, a tillage instrument configured to seek a predetermined operating ground engagement position as it is pulled across the ground, and a connection assembly for connecting the tillage tool to the toolbar to induce the cushion unit's cushioned vertical fluctuation motion in a generally forward and upward direction from its operational ground engagement position when a substantial vertical load is encountered and triggers the motion from a normal operating position below a ground surface to a triggered above ground position when highly abnormal traction conditions are encountered, said coupling assembly comprising a generally vertical shank member connected to said tillage instrument, a bracket affixed to said toolbar, with one arm p Main of lower fixed length is pivotally connected at one end to said bracket at the first pivot connection and at an opposite end to said rod member for movement around a second pivot connection, with a rear breaking link extending above the main arm, said rear snap link is pivotally connected at one end to said rod member in a third pivot connection and at an end opposite a front snap link by a fourth pivot connection, said said pivot connection. front snap link is pivotally connected to said support for movement around a fifth pivot connection, said front and rear snap links are joined together in said fourth pivot connection disposed between and above a relation in the center relative to it. said third and fifth pivot connections and a spring mechanism for normally maintaining said front and rear break links in relation to collapsible with each other in the operating position of the plowing unit, said pivotal connection around said first and fifth pivot connections to maintain said tillage instrument in said predetermined operating ground engagement position wherein said second and third pivot connections are separated by a vertical distance that is less than the vertical distance separating the first and fifth pivot connections at all positions of said tillage instrument and inhibiting said tillage instrument to float backwards. . CROPPING INSTRUMENT according to claim 9, characterized in that said spring mechanism further allows said elements of said upper link to move in a relationship collapsed relative to one another in response to a excessive tractive force that is applied against the tillage instrument. Cultivation instrument according to claim 9, characterized in that said coupling assembly maintains the angular relationship of said shank member as said coupling assembly drives said tillage device to move towards up and forward as said tillage device encounters a substantially vertical load.