In the case of a soil cultivation device with multiple harrow tines, the harrow tines are fastened to levers, which are mounted to pivot on tie bars of the supporting frame via carriers. The operating position of the harrow tines is defined by the levers being adjacent to tie bars, and the harrow tines are prestressed into the operating position by springs assigned to them in the form of pneumatic cylinders.

An agricultural implement assembly, which may comprise a support frame and a tine support structure for supporting a plurality of tine members. The assembly may comprise a clamping mechanism operable for securing the tine members to the tine support structure. The clamping mechanism comprises an upper clamping arm, a lower clamping arm and a medial connecting member which are operable to securely hold or otherwise constrain the tine members against or in close proximity to the tine support structure. The clamping mechanism may comprise a tine angled portion engaging component operable to engage an upper surface of the angled end portion of the tine member. The upper and lower clamping arms may comprise at least one upper ridge and at least one lower ridge for engaging in contact with a first portion and a second portion respectively of outward facing surface regions of the tine support structure.

An agricultural implement assembly, which may comprise a support frame and a tine support structure for supporting a plurality of tine members. The assembly may comprise a clamping mechanism operable for securing the tine members to the tine support structure. The clamping mechanism comprises an upper clamping arm, a lower clamping arm and a medial connecting member which are operable to securely hold or otherwise constrain the tine members against or in close proximity to the tine support structure. The clamping mechanism may comprise a tine angled portion engaging component operable to engage an upper surface of the angled end portion of the tine member. The upper and lower clamping arms may comprise at least one upper ridge and at least one lower ridge for engaging in contact with a first portion and a second portion respectively of outward facing surface regions of the tine support structure.

A soil cultivator comprises a frame attachable to a tractor and at least one processing unit attached to the frame. The processing unit has a frame-like element, a first soil cultivation tool attached to the frame-like element via a first connecting element, a second soil cultivation tool attached to the frame-like element via a second connecting element, and a swiveling axis element. The first soil cultivation tool and the second soil cultivation tool are arranged on different sides of the swiveling axis element. The first connecting element has a first annular section, and the second connecting element has a second annular section. The first and the second connecting elements are arranged so that they can swivel around the swiveling axis element such that a change in the extent of the frame-like element can effect a change in the distance between the first and the second soil cultivation tools.

A soil cultivator comprises a frame attachable to a tractor and at least one processing unit attached to the frame. The processing unit has a frame-like element, a first soil cultivation tool attached to the frame-like element via a first connecting element, a second soil cultivation tool attached to the frame-like element via a second connecting element, and a swiveling axis element. The first soil cultivation tool and the second soil cultivation tool are arranged on different sides of the swiveling axis element. The first connecting element has a first annular section, and the second connecting element has a second annular section. The first and the second connecting elements are arranged so that they can swivel around the swiveling axis element such that a change in the extent of the frame-like element can effect a change in the distance between the first and the second soil cultivation tools.

The present invention relates to a soil tillage implement having soil tillage tools in particular tine-type tools such as wing share cultivator tines or goosefoot share cultivator tines, and a centre longitudinal axis, wherein the soil tillage implement comprises a number n of soil tillage tools, which are arranged in one or more tool rows following one another in the working direction and oriented transversely to the working direction, and comprises a number s of disc tools which are arranged in one or more disc rows following one another in the working direction and oriented transversely to the working direction and located in the working direction in front of the soil tillage tools. The soil tillage tools comprise at least a first tool region and a second tool region and the first tool region, through its exposed arrangement, is subjected to greater wear than the second tool region. The invention furthermore relates to a method for producing such a soil tillage implement.

The invention relates to a soil-working device having a support frame (11), on which harrow tines (17) are arranged, which are preloaded by means of spring systems (18), the preload being centrally adjustable by means of a hydraulic cylinder (21). The harrow tines (17) are designed as two-armed levers, and the entire adjustment mechanism consisting of hydraulic cylinder (21), transverse bar (22), longitudinal bars (23), levers (19), and spring systems (18) is arranged above the fulcrums of the harrow tines (17). Thus, nearly only the harrow times (17) are located in the space below the fulcrums of the harrow tines (17). In addition, the harrow tines (17) can be not only pressed downward but also raised by means of the adjustment mechanism.

The invention relates to a soil-working device having a support frame (11), on which harrow tines (17) are arranged, which are preloaded by means of spring systems (18), the preload being centrally adjustable by means of a hydraulic cylinder (21). The harrow tines (17) are designed as two-armed levers, and the entire adjustment mechanism consisting of hydraulic cylinder (21), transverse bar (22), longitudinal bars (23), levers (19), and spring systems (18) is arranged above the fulcrums of the harrow tines (17). Thus, nearly only the harrow times (17) are located in the space below the fulcrums of the harrow tines (17). In addition, the harrow tines (17) can be not only pressed downward but also raised by means of the adjustment mechanism.

In one aspect, a system for determining subsurface soil layer characteristics as an agricultural implement is towed across a field by a work vehicle may include a RADAR sensor configured to capture data indicative of a subsurface soil layer characteristic of the field. Furthermore, the system may include a load sensor configured to capture data indicative of a load applied to the agricultural implement by soil within the field, with the load being indicative of the subsurface soil layer characteristic. Additionally, a controller of the system may be configured to determine a first value of the subsurface soil layer characteristic based on the data received from the RADAR and a second value of the subsurface soil layer characteristic based on the data received from the load sensor. Moreover, the controller may be configured to determine a differential between the first value and the second value.

A system for determining field surface conditions may include a frame member and a ground engaging tool coupled thereto. The ground engaging tool may be configured to engage soil within a field as an agricultural implement is moved across the field. The system may further include a vision sensor having a field of view directed towards a portion of a surface of the field and being configured to capture vision-based data indicative of a field surface condition of the field. The system may also include a secondary sensor coupled to the ground engaging tool and configured to capture secondary data indicative of the field surface condition. Additionally, the system may include a controller configured to determine an initial surface condition as a function of the vision-based data and to adjust the initial surface condition based at least in part on the secondary data received from the secondary sensor.