This invention relates to the improvement of a new hay rake system that is comprised of two separate wheel-type rakes into one by mounting them on one frame in such a manner permitting them to fold in for traveling and fold out for the raking position.

Patent
   4882900
Priority
Feb 24 1988
Filed
Feb 24 1988
Issued
Nov 28 1989
Expiry
Feb 24 2008
Assg.orig
Entity
Small
0
26
EXPIRED
1. A wheel rake system comprising, in combination, a wheeled transport frame and articulated wheel rake means mounted thereon, said rake system being characterized in that:
(a) said wheeled transport frame comprises a pair of longitudinally disposed side rails having a pair of cross members extending therebetween and axle shaft means with transport wheels journably mounted for rotation thereon coupled to and supporting said transport frame;
(b) said articulated wheel rake means includes a pair of individual wheel rake assemblies operatively mounted one on either side of said wheeled transport frame and with wheel rake assembly articulation means coupling each of said wheel rake assemblies to said transport frame and arranged to accommodate pivotal folding of each of said wheel rake assemblies outwardly to a working position and inwardly to a transport position;
(c) each of said wheel rake assemblies comprises an elongated support beam, a plurality of longitudinally spaced-apart tined wheel rakes coupled to said elongated support beam and including wheeled rake support means arranged for adjustably positioning the working height of said wheel rakes along said elongated supported beam;
(d) each of said elongated support beams being pivotally coupled to said wheeled transport frame at a rearward pivotal mounting point adjacent the rear ends of said elongated support beams and said wheeled transport frame respectively, and arranged for arcuate pivotal outward rotational movement about said pivotal mounting point, at least one laterally extending support arm assembly pivotally secured to said transport frame forwardly of said rearward pivotal mounting point between said wheeled transport frame and each of said elongated support beams for determining and controlling the outward pivotal rotational position of said elongated support beam relative to said wheeled transport frame;
(e) each of said lateral support arm assemblies comprising a pair of cooperating telescopically engaged length adjustable support braces with opposed ends of each of said support arm assemblies being pivotally secured to said elongated support beam and a cross member of said wheeled transport frame respectively, with the adjusted length of each of said support arm assemblies operating to determine the extent of outward angular rotational movement of said elongated support beam relative to said wheeled transport frame to thereby vary the working width of the wheel rake system;
(f) said wheel rake transport means further comprising:
(1) a wheel rake support crank shaft with an upper end segment, a lower end segment, and an intermediate segment therebetween, and with the said upper segment being pivotally engaged with said elongated support beam, and with said lower segment journably supporting one of said tined wheel rakes thereon; and
(2) a threaded wheel rake height control shaft, a tined rake height adjust actuating arm comprising first and second angularly disposed arm elements joined together at an apex and with the apex zone having pin means rotatably engaged with one of said elongated support beams for coupling each of said actuating arms thereto, and with the outer end of the first one of said angularly disposed arm elements of each height adjust actuating arm having a laterally outwardly extending support pin secured thereto for underlying, engaging and supporting the intermediate segment of said wheel rake support crank shaft thereover, and with the outer end of said second height adjust actuating arm being pivotally coupled to a threaded wheel rake height control shaft mounted for adjustable longitudinal positioning along said elongated support arm, the arrangement being such that the longitudinal position of said height control shaft along said elongated support arm determines the angular position of each of said height adjust actuating arm elements and thus the height of each of said tined wheel rakes from the ground surface.
2. The wheel rake system as defined in claim 1 being particularly characterized in that said lateral support arm assemblies are each coupled to said wheeled transport frame along the upper surface thereof, and are arranged to rest at least partially upon said transport frame.
3. The wheel rake system as defined in claim 2 being particularly characterized in that two lateral support arm assemblies are provided for support of each elongated support beam, with said lateral support arm assemblies being longitudinally spaced, one from the other, along said wheeled transport frame.
4. The wheel rake system as defined in claim 1 being particularly characterized in that said tined rack height adjust actuating arms are adapted to raise the height of said tined wheel rakes upwardly away from the ground surface into transport position.

The harvesting of grass or forage crops namely making hay, comprises of cutting the grass or forage and then leaving it lie on the ground for drying, thereby curing. This period of time is determined by the elements of the weather, which usually takes about 48 hours. At this period of time the dried or cured grass becomes hay. At this particular time it is very important to put the hay up as soon as possible. To put the hay up too soon results in too much moisture in the hay, causing molding, rotting and serious deterioration to the hay. If it is left lying on the ground too long, it readily becomes parched and the nutrients, especially protein, decreases rapidly. The hay making industry has long recognized the wheel type rakes, such as cited in U.S. Pat. Nos. 3,516,238 and 3,841,070, as a useful and workable method of raking hay. It also recognizes that the more wheels added to a given frame, making a larger rake, the more vulnerable time saved. This time saved is in relation to its size and bulk. However, the larger the rake the more difficult to hook the rake to a power vehicle and the more difficult it is in transporting the rake from one field to another. Here-in lies the problem. Presently, the industry uses two complete and separate rakes by hooking them up in gang fashion or by an opposing position. The rakes that traverse the hay to the center as cited in U.S. Pat. No. 4,185,447 and other wheel-type rakes, do so only with considerable amount of work and delay, especially in transporting the rakes from one field to another. The Bi-Fold rake system contained herein addresses this particular problem.

The Bi-Fold rake system is an invention which relates to the improvement in the hay raking machinery. This is accomplished by combining two frames with wheel rakes attached to one moveable transport frame in such a manner that it comprises two rakes in one. The transporting problem is resolved by the unique feature the rake possesses by folding out for the raking or field position. This is accomplished by the use of a unique set of folding braces which have a telescoping feature.

FIG. 1 Is a top view of the Bi-Fold Hay Rake System in the expanded or raking position. The wheel rake assemblies FIG. 1-6 are attached to the support beams FIG. 1-3 by the wheel rake arms FIG. 1-7. The support beams are connected to the support braces FIG. 1-15 and FIG. 1-23 at point FIGS. 1-4, 1-12 and to the transport frame FIG. 1-2 at point FIG. 1-13. The support braces telescope and are adjustable at points FIG. 1-14 and FIG. 1-16 by inserting a pin. The support braces are attached to the transport frame at points FIG. 1-19 and FIG. 1-20. They rest on, but are not connected to the transport frame at points FIGS. 1-17 and 1-18 holding up the support frame. The telescoping feature of the support braces vary the distance between points FIG. 1-4 and FIG. 1-5, thereby describing the width or swath the rake can be expanded. The wheels FIG. 1-7 are attached to the transport frame in a conventional manner, thereby constituting the trailer transport system by hooking up to a power vehicle at point FIG. 1-1. FIGS. 1-8, 1-9, 1-10 and 1-11 make up the mechanism for raising and lowering the wheel rake assemblies as described in FIG. 3.

FIG. 2 Is a top view of the Bi-Fold rake system in a folded or transport position. The support beams FIG. 1-3 with the wheel rake assemblies FIG. 1-6 attached, are resting on top or parallel and they coincide with the transport frame FIG. 1-2. The hypotenuse side of the triangle FIG. 1-15 and FIG. 1-23 formed is in the contracted position. The number and arrangement of the wheel rakes can vary and is obvious to the novice and no claims are being made as part of this invention.

FIG. 3 Is a disassembled view of a section of the support beam FIG. 3-3 where the wheel rake FIG. 3-6 is attached. FIG. 3 is a given section of the support beam as depicted in FIG. 1-3. This support beam has the wheel rake assembly FIG. 3-6 attached to it by the wheel rake arm FIG. 3-7. The wheel rake is raised or lowered by a rotating action of the actuating arm FIG. 3-9 the stopping pin FIG. 3-8 which prevents the wheel rake arm from dropping too low because of the supporting action of the stopping pin, yet it allows free upward motion of the wheel rake arm which is connected to the wheel rake at the hub of the wheel. By moving the connecting rod FIG. 3-11 in a forward or backward motion which is connected to the actuating arm at FIG. 3-22, it rotates the actuating arm around the shaft FIG. 3-10, resulting in the stopping pin pushing against the wheel rake arm and raising or lowering the wheel rake assembly. The connecting rod is threaded at point FIG. 3-21 in a conventional manner and this distance can be varied by other conventional methods by a hydraulic cylinder or whatever, and is not part of this invention.

It has been discovered that two rakes can be comprised into one by the use of a set of support beams FIG. 1-3 and folding braces FIG. 1-15 and FIG. 1-23 that are attached to a standard type frame as depicted in FIG. 1 by folding in or out. The support beam attached to the transport frame at point FIG. 1-13 is the apex of the triangle formed. The support beams attached at FIG. 1-4 and FIG. 1-12 are the vertex of the triangle formed and the telescoping braces FIG. 1-15 and FIG. 1-23 are the hypotenuse side of the triangle. Furthermore, the support braces hold up the support beams by resting on the transport frame FIG. 1-2 at points FIG. 1-17 and FIG. 1-18 but is made possible only by connecting at points FIG. 1-19 and FIG. 1-20 and not at the resting points as these points must be allowed to vary. The support beam forms a right triangle in relation to the support braces when in the folded or transport position. As the support beams fold out and the hypotenuse side, which is the telescoping braces, extend an oblique triangle is formed. Furthermore, the unique feature of the telescoping hypotenuse side of the triangle formed permits the rake to be adjustable in width from FIG. 1-5 to FIG. 1-4, this is important and useful because if the hay is too heavy (thick) the operator can adjust the raking width to suit the existing conditions by inserting a pin FIG. 1-16 at a point FIG. 1-14, for example. The Bi-Fold action of the braces gives the rake the ability to rake from both sides towards the center. This is important and useful in as much as to rake hay for a lateral distance of 24 feet makes it very difficult because the amount of hay, that has to traverse that distance would accumulate into a large amount of hay creating a plugging of the hay raking machine. By employing the Bi-Fold rake system that is: raking from both sides toward the center, the hay has to traverse only half the distance or for 12 feet versus 24 feet, for example. While this has been attempted as cited in U.S. Pat. No. 4,185,447 it does not solve the transport problem. The transport frame assembly FIG. 1-2 with the wheels (tires) located at point FIG. 1-7 permits the manufacturer to build in a conventional trailer like manner so as to adjust the weight of the hay rake machine on the tongue FIG. 1-1 where it hooks up to the power vehicle. By balancing the hay rake over the tires it permits the operator to hook up with ease and simplicity. It also allows the operator to tow the Bi-Fold rake with his pickup, for example, at speeds up to 50 mph. The wheel rakes attached to the support beams which are connected to the transport frame at points FIG. 1-13 and to the telescoping support braces at points FIG. 1-4 and FIG. 1-12 the braces rest at points FIG. 1-17 and FIG. 1-18 but are connected at points FIG. 1-19 and FIG. 1-20 actually comprise a complete hay rake system when mounted on a conventional trailer type frame, as depicted in FIG. 1.

Referring to FIG. 3 as depicted in a disassembled view, the wheel rakes FIG. 3-6 are attached to the wheel rake arm FIG. 3-7 can be raised or lowered with a unique actuating arm FIG. 3-9 with a stopping pin FIG. 3-8 that supports the wheel rake arm. This actuating arm, as depicted, can raise or lower the wheel rakes by virtue of its own weight, yet provides free upward movement of the wheel rake. This feature is accomplished by actuating the arm forward or backward at point FIG. 3-22 of the actuating arm either mechanically or hydraulically.

This feature is important and useful because it raises the wheel rakes into road or traveling position, yet it has the ability to lower the wheel rake for raking purposes but will not force the wheel rake to be lowered too far, allowing the wheel rake to possibly drag on the ground and become damaged. Furthermore, the actuating arm FIG. 3-9 makes tedding hay possible by raising the wheel rakes just high enough so that it can be allowed to pass over and remove the top half of the hay in the windrow, thereby letting the sun dry the bottom half of the windrow. This is a very desirable feature in slow drying weather. Furthermore, this dual purpose of raking and tedding the hay eliminates the cost and maintenance of a second machine.

The above mentioned features, as illustrated, are exemplary in nature and are not to be construed as limitations of the present invention as set forth in the following claims.

Kuehn, Melvin C.

Patent Priority Assignee Title
Patent Priority Assignee Title
1906606,
2179583,
2222840,
2658324,
2683345,
2906351,
2925702,
2982081,
3108424,
3145522,
3466860,
3516238,
3667200,
3706191,
3757500,
3841070,
4040490, Mar 08 1976 ANDERSON, RODNEY C Rock windrower
4077189, Apr 23 1976 Front mounted adjustable twin rakes
4078366, May 03 1976 Lateral movement of side delivery rake
4183198, Feb 24 1978 Lely Pacific V-rake
4185447, Apr 27 1978 DAYCO PRODUCTS, INC Hay conveying belt and hay rake
4214428, Oct 18 1978 Raking and baling machine
4245458, Nov 24 1978 Extendable tool bar for hay rakes
4315546, May 05 1980 Double roll rock windrower
4496003, Jan 03 1983 Rock gathering apparatus
4723401, Sep 24 1986 BLUE LEAF I P , INC Steerable wheel assembly for unitized rakes
Executed onAssignorAssigneeConveyanceFrameReelDoc
Date Maintenance Fee Events
Jun 29 1993REM: Maintenance Fee Reminder Mailed.
Nov 28 1993EXP: Patent Expired for Failure to Pay Maintenance Fees.


Date Maintenance Schedule
Nov 28 19924 years fee payment window open
May 28 19936 months grace period start (w surcharge)
Nov 28 1993patent expiry (for year 4)
Nov 28 19952 years to revive unintentionally abandoned end. (for year 4)
Nov 28 19968 years fee payment window open
May 28 19976 months grace period start (w surcharge)
Nov 28 1997patent expiry (for year 8)
Nov 28 19992 years to revive unintentionally abandoned end. (for year 8)
Nov 28 200012 years fee payment window open
May 28 20016 months grace period start (w surcharge)
Nov 28 2001patent expiry (for year 12)
Nov 28 20032 years to revive unintentionally abandoned end. (for year 12)