The embodiments disclosed herein relate to drying hay bales and, in particular to a system and apparatus for drying hay bales.
In various places around the world hay is cut and stored for later uses, such as use for animal feed or bedding. It is often convenient for this hay to be baled prior to storage or transportation.
In various places around the world a market exists for bales of hay. The price of a bale of hay having a moisture content between 5 percent and 20 percent tends to be considerably higher than the price of a bale having significantly higher or lower moisture content.
When hay is cut from a field, the moisture content may be significantly higher than 20 percent. For example, the moisture content may be 25 percent or 30 percent or more. Often hay will be left in the field to dry. However, in various circumstances, hay left in the field does not dry to an optimal level. For example, rain or dew may fall upon the hay before it is gathered and baled.
In addition, drying hay by leaving it in the field for a time may result in the sun bleaching the hay, or may result in the hay being otherwise reduced in quality as protein-rich leaves may dry and crumble and fall to the ground where they will not be captured by a baling machine.
Accordingly, there is a need for a hay bale dryer, such that damp hay may be baled and processed to a desired moisture content through use of the hay bale dryer. It may be further beneficial to employ a hay bale dryer which is able to dry a bale of hay at a low cost and without changing the shape or appearance of the bale.
According to an embodiment, there is provided a hay bale dryer including a support frame; an upper air intake manifold movably coupled to the support frame for supplying heated air, the upper air intake manifold comprising an upper air chamber and a plurality of hollow needles extending downwardly therefrom, the needles having a series of apertures therein, the apertures allowing the heated air to exit; an lower air intake manifold movably coupled to the support frame for supplying heated air, the lower air intake manifold comprising an air chamber and a plurality of hollow needles extending upwardly therefrom, the needles having a series of spaced apertures therein, the apertures allowing the heated air to exit; a bale retainer fixedly coupled to the support frame between the upper air chamber and the lower air chamber, the bale retainer being configured for retaining at least one hay bale in a fixed position between the upper air chamber and the lower air chamber, the bale retainer comprising an horizontally extending upper bale retaining member and a horizontally extending lower bale retaining member spaced from the upper bale retaining member a vertical distance defining a bale space sized to receive the at least one hay bale, the bale retaining members having openings that allow the plurality of needles to enter the bale space; and an actuator coupled to the upper air intake manifold and the lower air intake manifold, the actuator being configured for moving the upper air intake manifold and the lower air intake manifold between a retracted positon in which the needles are retracted outside the bale space and an extended positon in which the needles extend through the openings into the bale space.
The hollow needles of the upper air intake manifold may terminate in a common first needle plane a first needle length from the upper air intake manifold, and the hollow needles of the lower air intake manifold may terminate in a common second needle plate a second needle length from the lower air intake manifold.
The hollow needles of the upper air intake manifold and the hollow needles of the lower air intake manifold may terminate in tapered points.
The series of apertures in each needle of the hollow needles of the upper air intake manifold and the hollow needles of the lower air intake manifold may be aligned along the length of each needle with the apertures in each series of apertures decreasing in size from the aperture nearest the air chamber to the aperture farthest from the air chamber.
The actuator may include a pair of parallel vertical linear actuators each coupled to the upper air intake manifold and the lower air intake manifold and spaced on opposite sides of the bale space.
The linear actuators may be hydraulic cylinders.
The upper air intake manifold may include an upper manifold coupling assembly for moveably coupling the upper air chamber to the support frame, the lower air intake manifold may include a lower manifold coupling assembly for movably coupling the lower air chamber to the support frame, and the actuator may extend between the upper manifold coupling assembly and the lower manifold coupling assembly.
The support frame may include a pair of vertical support frame members on each end of the support frame, the upper manifold coupling assembly may include a pair of upper end frames extending outwards from end walls of the upper air chamber, and the lower manifold coupling assembly may include a pair of lower end frames extending outwards from end walls of the lower air chamber. Each upper and lower end frame may be configured to be movably coupled to the vertical support frame members and each pair of vertical support frame members may be spaced from one another.
Each of the vertical support frame members may include an upper vertical track set and a lower vertical track set and each of the upper and lower coupling assemblies may include a pair of track gears rigidly attached to the each upper and lower end frame. Each track gear may be configured to mesh with a respective vertical track set of the vertical support frame members to movably couple each upper and lower end frame to the vertical support frame members.
The upper coupling assembly may also include a pair of upper drive shafts extending from one upper end frame through the upper air chamber to the other upper end frame, and the lower coupling assembly may also include a pair of lower drive shafts extending from one lower end frame through the lower air chamber to the other lower end frame. The upper drive shafts may be spaced from one another and the lower drive shafts may be spaced from one another such that the upper and lower manifold coupling assemblies are balanced from end-to-end during movement between the retracted positon and the extended positon.
The upper coupling assembly may also include a pair of upper balancing gears rigidly attached to each upper end frame near an end of a respective track gear, an upper idler gear attached to a central portion of each upper end frame and an upper synchronization chain extending around the upper balancing gears and the upper idler gear of each upper end frame, and the lower coupling assembly may also include a pair of lower balancing gears rigidly attached to each lower end frame near an end of a respective track gear, a lower idler gear attached to a central portion of each lower end frame and a lower synchronization chain extending around the lower balancing gears and the lower idler gear of each lower end frame.
The upper and lower bale retaining members may be racks formed of parallel and perpendicular beams with gaps between the beams through which the needles of the upper and lower pluralities of needles may pass.
The upper and lower bale retaining members may be plates having a plurality of apertures through which the needles of the upper and lower pluralities of needles may pass.
According to a another embodiment, there is provided an apparatus for drying bales, including a support frame; at least one air intake manifold movably coupled to the support frame for supplying heated air, the air intake manifold comprising an air chamber and a plurality of hollow needles extending therefrom, the needles having a series of apertures therein, the apertures allowing the heated air to exit; a bale retainer fixedly coupled to the support frame, the bale retainer being configured for retaining at least one bale in a fixed position vertically spaced from the at least one air intake manifold, the bale retainer defining a bale space sized to receive the at least one bale, the bale retainer having openings that allow the plurality of needles to enter the bale space; and an actuator coupled to the at least one air intake manifold, the actuator being configured for moving the at least one air intake manifold between a retracted positon in which the needles are retracted outside the bale space and an extended positon in which the needles extend through the openings into the bale space.
Other aspects and features will become apparent, to those ordinarily skilled in the art, upon review of the following description of some exemplary embodiments.
The drawings included herewith are for illustrating various examples of articles, methods, and apparatuses of the present specification. In the drawings:
Various apparatuses or processes will be described below to provide an example of each claimed embodiment. No embodiment described below limits any claimed embodiment and any claimed embodiment may cover processes or apparatuses that differ from those described below. The claimed embodiments are not limited to apparatuses or processes having all of the features of any one apparatus or process described below or to features common to multiple or all of the apparatuses described below.
By way of general overview,
Blower 112 includes an engine 116, such as a 275 horse power 6.8 liter diesel engine. Engine 116 draws in ambient air to be used by or in hay bale drying apparatus 20. Engine 116 can provide sufficient pressure to blow air through apparatus 20 into hay bales placed within a bale space 48 of hay bale drying apparatus 20 when upper and lower air intake manifolds 24 and 26 are in extended positions with upper and lower pluralities of needles 30 and 34 extended into bale space 48. Engine 116 is be configured or chosen or built or modified so as to provide an air pressure sufficient to push air through the hay bales.
Table 115 is removably coupled to hay bale drying apparatus 20 and configured to support at least one bale of hay. Table 115 can be any appropriate structure capable of supporting one or more bales of hay 42. Table 115 can include a conveyor belt, rollers or the like for use in providing bales of hay 42 to the hay bale drying apparatus 20 for drying.
Further details of the operation of blower 112, table 115 and hay bale drying apparatus 20 are provided below.
A bale retainer 40 is fixedly coupled to frame 22 between upper air chamber 28 and lower air chamber 32 to retain at least one hay bale 42 in a fixed vertical position between upper air chamber 28 and lower air chamber 32. Bale retainer 40 includes a horizontally extending upper bale retaining member 44 and a horizontally extending lower bale retaining member 46 spaced from upper bale retaining member 44 a vertical distance defining a bale space 48 sized to receive the at least one hay bale 42. Each of upper and lower bale retaining members 44 and 46 have openings 50 that provide for the upper and lower pluralities of needles 30 and 34 to enter the bale space 48. Each of upper and lower bale retaining members 44 and 46 may be vertically fixed in position, or may be movable such that the size of bale space 48 may be adjusted.
As shown in
Each of upper and lower air intake manifolds 24 and 26 are moveable between a retracted position, in which upper and lower pluralities of needles 30 and 34, respectively, are retracted outside bale space 48, and an extended position, in which upper and lower pluralities of needles 30 and 34, respectively, extend through openings 50 into bale space 48. The retracted and extended positions of the upper and lower plurality of needles 30 and 34 are shown in
Also shown in
Upper air chamber 28 has an upper air intake opening 54 and lower air intake chamber 32 has a lower air intake opening 56. Each of upper and lower air chambers 28 and 32 may include internal baffles (not shown) to direct air flow.
Upper plurality of needles 30 are fluidly connected to upper air chamber 28 at the upper ends 60 of the needles 70 of upper plurality of needles 30, such as by way of needle bases 68, as shown in
An actuator 52 is coupled to the upper air intake manifold 24 and the lower air intake manifold 26. Actuator 52 moves the upper air intake manifold 24 and the lower air intake manifold 26 between a retracted position, in which the upper and lower pluralities of needles 30 and 34 are retracted outside the bale space 48, such as shown in
Actuator 52 comprises at least one hydraulic cylinder to move the upper air intake manifold 24 and lower air intake manifold 26 between the retracted and extended positions. In the embodiments shown in the Figures, actuator 52 comprises a first hydraulic cylinder 74 and a second hydraulic cylinder 76. Each of the first hydraulic cylinder 74 and second hydraulic cylinder 76 is coupled to upper air intake manifold 24 and lower air intake manifold 26. First and second hydraulic cylinders 74 and 76 are parallel, spaced across bale space 48 from one another, and oriented substantially vertically or perpendicular to upper and lower bale retaining members 44 and 46. In this configuration, actuation of either or both of hydraulic cylinders 74, 76 can move the upper air intake manifold 24 and lower air intake manifold 26 between the retracted and extended positions. In one embodiment, hydraulic cylinders 74 and 76 may be between 1 and 10 inch hydraulic cylinders, and more specifically between 2 and 4 inch hydraulic cylinders. Larger cylinders may be more expensive and bulkier, but may provide more force to drive needles 70 of upper and lower pluralities of needles 30 and 34 into hay bales placed within bale space 48.
Referring now to
Lower air intake manifold 26 includes a lower manifold coupling assembly 45 (see
First hydraulic cylinder 74 and second hydraulic cylinder 76 extend between the upper manifold coupling assembly 43 and the lower manifold coupling assembly 45.
Support frame 22 includes four vertical support frame members 55 arranged such that each end of the support frame 22 has a pair of vertical support frame members 55 spaced apart from one another. Each vertical frame member 55 has a vertical track set 63 including an upper track set 82 and a lower track set 84.
First upper end frame 49 is secured to and extends outward from upper end wall 282 of upper air chamber 28 and second upper end frame 51 is secured to and extending outwards from upper end wall 283 of upper air chamber 28. Likewise, first lower end frame 53 is secured to and extends outward from lower end wall 322 of lower air chamber 32 and a second lower end frame 57 secured to and extending outward from lower end wall 323 of lower air chamber 32. Upper end frame 49 and lower end frame 53 are each configured to be movably coupled to one pair of vertical support frame members 55 and upper end frame 51 and lower end frame 57 are each configured to be movably coupled to the other pair of vertical support members 55.
As shown in
For each of upper and lower air intake manifolds 24, 26, each track gear 101 is held against the corresponding track of upper and lower track sets 82, 84, by a support assembly 104, as shown particularly in
Upper balancing assembly 61 includes a first upper drive shaft 90, a second upper drive shaft 92, a balancing gear 98, an idler gear 107 and a synchronization chain 102. Lower balancing assembly 65 includes a first lower drive shaft 91, a second lower drive shaft 93, a balancing gear 98, an idler gear 107 and a synchronization chain 102. Upper and lower balancing assemblies 61, 65 can provide side-to-side balancing of the upper and lower air intake manifolds 24, 26 as they move between the extended and retracted positions (i.e. movement of the ends of the upper and lower air intake manifolds 24, 26 between the extended and retracted positions is substantially synchronized (e.g. at the same or similar rate)). Synchronization chain 102 can be any appropriate tightening mechanism for transferring motion of one of balancing gears 98 and/or idler gear 107 to the other gears (e.g. a belt).
First upper drive shaft 90 and a second upper drive shaft 92 (see
This configuration of first upper drive shaft 90 and second upper drive shaft 92 can provide the hay bale drying apparatus 20 with end-to-end balancing as the movement of first upper end frame 49 and second upper end frame 51 between the retracted and extended positions is substantially synchronized (e.g. at the same or similar rate)). Similarly, the configuration of first lower drive shaft 91 and second lower drive shaft 93 can also provide the hay bale drying apparatus 20 with end-to-end balancing as the movement of first lower end frame 53 and second lower end frame 57 between the retracted and extended positions is substantially synchronized (e.g. at the same or similar rate)). For example, actuation of actuator 52 provides vertical movement of upper and lower air intake manifolds 24, 26 between the extended and retracted positions. Vertical movement of upper and lower air intake manifolds 24, 26 causes rotation of each track gear 101 along track sets 82, 84 and rotation (e.g. synchronized rotation) of drive shafts 90, 91, 92, 93. Upper drive shafts 90, 92 and lower drive shafts 91, 93 extend from end-to-end of the upper and lower air intake manifolds 24, 26 and rotationally couple respective track gears 101 on opposite sides the upper and lower air intake manifolds 24, 26. As such, rotation of drive shafts 90, 91, 92, 93 provides for synchromonious rotation of track gears 101 positioned on opposite sides of the upper and lower air intake manifolds 24, 26. The spacing between each of upper drive shafts 90, 92 and each of lower drive shafts 91, 93 disperses the weight of the respective upper and lower air intake manifolds 24, 26 such that the upper air intake manifold 24 and the lower air intake manifold 26 remain balanced from end-to-end during vertical movement of upper and lower air intake manifolds 24, 26.
Each of upper and lower balancing assemblies 61, 65 include a pair of balancing gears 98 spaced across the upper and lower air chambers 28, 32 (e.g. across bale space 48). Balancing gears 98 are each rigidly attached to one of drive shafts 90, 91, 92, 93 near to track gear 101. Each balancing gear 98 is spaced from a respective track gear 101, as shown in
Each of upper and lower balancing assemblies 61, 65 also includes an idler gear 107 attached to a central portion of a respective end frame of end frames 49, 51, 53, 57 and a synchronization chain 102. Synchronization chain 102 extends around a pair of balancing gears 98 and idler gear 102 as shown in the Figures. Again, actuation of actuator 52 provides vertical movement of upper and lower air intake manifolds 24, 26 between the extended and retracted positions. Vertical movement of upper and lower air intake manifolds 24, 26 causes rotation of each track gear 101 along track sets 82, 84 and rotation of each respective balancing gear 98. As pairs of balancing gears 98 are spaced across each end of upper and lower air intake manifolds 24, 26 and rotationally coupled via chain 102, the upper air intake manifold 24 and the lower air intake manifold 26 remain balanced from side-to-side during vertical movement of upper and lower air intake manifolds 24, 26.
Apparatus 20 may be portable, so that it can be moved from one location to another. Apparatus 20 may be separable into two halves, one half including the upper elements and an upper portion of frame 22, and the other half including the lower elements and the lower portion of frame 22. Frame 22 may be formed of upper and lower portions joined together at one or more seam points 110, as shown particularly in
Referring again to
Blower 112 includes an engine 116, such as a 275 horse power 6.8 liter diesel engine, which engine 116 draws in ambient air to be used by or in apparatus 20. Engine 116 provides sufficient pressure to blow air through tube 114, through upper and lower air intake manifolds 24 and 26 and into hay bales placed within bale space 48 when upper and lower air intake manifolds 24 and 26 are in extended positions with upper and lower pluralities of needles 30 and 34 extended into bale space 48. Engine 116 is be configured or chosen or built or modified so as to provide an air pressure sufficient to push air through the hay bales.
The radiant heat of engine 116 is used warm the air blown into upper and lower air intake manifolds 24 and 26. For example, a heat exchanger is used to cool engine 116, and the heat exchanger includes a radiator 118 in cases of liquid cooling of engine 116. Radiator 118 is positioned between engine 116 and tube 114, and engine 116 blows air through radiator 118 to warm the air before or as the air enters into tube 114. Heating air by use of radiant heat may be preferable to use of other heating techniques, such as those which use an open flame, as other heating techniques may be particularly dangerous when used in close proximity to dry hay.
In some situations the temperature of air directed into at least one hay bale 42 in bale space 48 is raised to at least 80 degrees Fahrenheit, at least 90 degrees Fahrenheit, at least 150 degrees Fahrenheit, or higher, as these temperatures facilitate the drying of hay. The heat of the air blown into tube 114 is controlled by increasing or decreasing the flow of liquid coolant to the radiator 118, which may be an automatic process controlled by the sensed temperature of the air at various points or in various components of the system including apparatus 20. In some cases, a boiler or other heat source could also be used to raise the temperature of the air blown into at least one hay bale 42 in bale space 48.
Engine 116 can also be used to drive the actuator 52, such as when actuator 52 includes first and second hydraulic cylinders 74 and 76. The system of blower 112 and dryer 20 is generally indicated in
Bales of hay for drying may be loaded into apparatus 20 in various ways. For example, hay bales may be placed on a surface, such as table 115, positioned next to apparatus 20 and at the height of lower bale retaining member 46 (see
Apparatus 20 may be configured to dry hay bales of various sizes. For example, bale space 48 may be configured to receive either three hay bales of a first size 120, first size bales 120 being 3 feet in height by 3 feet in width by 7 feet in length (see
The vertical height of bale space 48 may be adjustable, such as if bale retaining members 44 and 46 are movably coupled to frame 22. However, a user may desire to maintain a fixed vertical height of bale space 48 at substantially 3 feet or 3.5 feet or 4 feet or more, to receive bales with a height of 3 feet easily and to reduce the number of moving parts.
A gap of between 2 and 10 inches may be maintained between hay bales received in the bale space. In one embodiment, a gap of approximately 6 inches may be maintained between bales. The needles 70 of upper and lower pluralities of needles 30 and 34 may be unordered in arrangement, this may be beneficial if the arrangement of at least one bale 42 within bale space 48 is not known. However, an unordered distribution of needles 70 of upper and lower pluralities of needles 30 and 34 may result in needles being between bales when upper and lower air intake manifolds 24 and 26 are in extended positions. This may result in heated air being blown by blower 112 through tube 114, through upper and lower air intake openings 54 and 56, through upper and lower air chambers 28 and 32, through the openings 50 between the air chambers and the pluralities of needles, into needles 70 of upper and lower pluralities of needles 30 and 34, out apertures 72 in the needles, and into the ambient air rather than into a bale. Alternatively, the needles 70 may instead be ordered, such as arranged in rows. Needles 70 arranged in rows may permit needles which will not be driven into at least one bale 42 when upper and lower air intake manifolds 24 and 26 are in extended positons to be removed and replaced with plugs 130 blocking needle bases 68 (see
The ends of needles 70 of upper plurality of needles 30 may terminate in a common upper needle plane 132, as shown in
Switching between first size bales 120 and second size bales 122 may involve reconfiguring the positions of upper and lower pluralities of needles 30 and 34. For example, each needle 70 of upper and lower pluralities of needles 30 and 34 may be removably secured to needle bases 68 (see
When configured to dry first sized bales 120, three sets of four rows of needles 70 may be secured to needle bases 68, with one row of needle bases 68, blocked by plugs 130, separating each of the three sets. When first sized bales 120 are received into bale space 48, actuator 52 moves upper and lower manifolds 24 and 26 into extended positions, and upper and lower pluralities of needles 30 and 34 are driven into the bales, four rows of needles 70 driven into each bale.
When configured to dry second sized bales 122, two sets of six rows of needles 70 may be secured to needle bases 68, with two rows of needle bases 68, blocked by plugs 130, separating the two sets. When second sized bales 122 are received into bale space 48, actuator 52 moves upper and lower manifolds 24 and 26 into extended positions, and upper and lower pluralities of needles 30 and 34 are driven into the bales, six rows of needles driven into each bale. This configuration is depicted as the lower needle set of
Needles 70 may also be removable, not just so they can be reconfigured for use with various bale sizes, but also so that they can be replaced if they wear out or become deformed or broken. The specific shape of each needle 70 of the upper and lower pluralities of needles 30 and 34 may vary. In the embodiment shown in FIGS. 12A and 12B, the needles 70 have a long, cylindrical shape with a tapered point 136. Needles 70 are hollow to provide for air to pass through the needles 70 from and out the apertures 72 in the sides, and provided the needles 70 may be driven or pushed or pulled into at least one bale 42 in bale space 48. However, each needle 70 may be a hollow cylinder of circular cross section, and needles 70 may be of substantially uniform width or diameter along substantially the length of the needle, which width or diameter may be kept small so as not to deform bales dried by apparatus 20, as deformed bales may be of lower commercial value. The width or diameter of the needles 70 may be less than 2 inches or less than 1 inch or less than ¾ inch. The ends of the needles 70 of upper and lower pluralities of needles 30 and 34 farthest from the upper and lower air chambers 28 and 32 may terminate in tapered points 136 to more easily permit the needles to be driven or pushed or pulled into bales. Tapered points 136 may also be removable, which may permit them to be easily replaced if worn or deformed or broken.
In some embodiments, between 1 and 56 needles 70 may be used per bale from each of upper and lower air intake manifolds 24 and 26. In other embodiments, more than 56 needles 70 may be used per bale from each of upper and lower air intake manifolds 24 and 26. In other embodiments, between 5 and 36 needles may be used per bale from each of upper and lower air intake manifolds 24 and 26. A greater number of needles 70 may provide for bales of hay to be dried more uniformly. Further, a greater number of needles 70 may also provide for the needles 70 to be narrower so as to deform bales dried by the needles less than would be the case with wider needles. A greater number of needles 70 may also provide for bales to be dried more quickly and more cheaply, with substantially all warmed air being piped or pumped or applied directly into damp bales.
Baling hay with baling machines tends to produce a layered bale structure. Driving or pushing or pulling needles 70 into bales vertically may provide for air to flow more freely through typical bale structures or may permit the needles to be driven more easily into the bales. Particularly when the width of a bale may change, such as between first sized bales 120 and second sized bales 122, but the height remains the same, a user may desire to have a fixed height of bale space 48. In some situations this may result in at least one bale 42 in bale space 48 having a bale structure including layers stacked vertically. Needles driven or pushed or pulled into bales vertically may take advantage of the bale structure to more easily dry bales or more easily move needles into bales.
Various modifications to the upper and lower air chambers 28 and 32, to the tube 114, etc. may be made to direct a substantially similar volume of warmed air into each needle 70. Various modifications may be made to the needles 70 and apertures 72 to direct a substantially similar volume of warmed air through each aperture 72 of a needle 70. For example, the size of apertures 72 may be varied along the length of a needle 70. Apertures 72 may be arranged in one or more series of apertures vertically along the length of needles 70. The size of apertures 72 may decrease or increase regularly along the length of needles 70. In one embodiment, the diameter of apertures 72 is largest for the apertures 72 near the air chambers 28, 32 to which the needles 70 are connected and decreases along the series towards tapered point 136.
A drying cycle may include the steps of moving at least one bale 42 into bale space 48, moving upper and lower air intake manifolds 24 and 26 into extended positions, turning on blower 112, turning off blower 112, moving upper and lower air intake manifolds 24 and 26 into retracted positions, and removing at least one bale 42 from bale space 48. When upper and lower air intake manifolds 24 and 26 are in extended positions, blower 112 may blow air across radiator 118, into tube 114, through air intake openings 54 and 56 of upper and lower manifolds 24 and 26, respectively, into upper and lower air chambers 28 and 32, through openings 50, into needles 70 of upper and lower pluralities of needles 30 and 34, through apertures 72, and into at least one bale 42 placed within bale space 42.
The period of time between turning blower 112 on and turning blower 112 off may be automatically determined by sensing the moisture content of at least one bale 42. For example, a scale may be placed under apparatus 20 to determine the weight of at least one bale 42, and may permit blower 112 to be turned off automatically when the weight of at least one bale 42 reaches a desired weight.
When hay is first cut, the moisture content may be 50 percent, it may be 60 percent, it may be 70 percent, it may be 80 percent, or it may be more. In some situations hay may be left to dry in the field until the moisture content reaches a desired level, such as between 5 and 20 percent, and then baled. In other situations, hay may be left in a field to dry for a period of time to reduce the moisture content somewhat before being baled. Baled hay may have a moisture content of 25 percent, or 30 percent or 35 percent or more. In some situations, a user may desire to dry at least one bale 42 to a moisture content of between 5 and 20 percent, or between 10 and 15 percent, or approximately 10 percent.
In some situations a user may desire to bale hay without leaving it in the field for a significant period of time, as the sun may bleach hay and cause the protein-rich leaves to dry and crumble or break or be removed or fall to the ground before the hay can be baled. In some situations a user may desire to bale the hay while still damp so as to ensure that the protein-rich leaves remain in the hay. In some situations damp hay may pose a mold risk or rot risk or fire risk or lower value risk, which may be lessened by drying the hay to a desired moisture content.
In one embodiment, a period of time between when blower 112 turns on and when blower 112 turns off may be determined automatically by sensing when at least one bale 42 has a desired moisture content.
While apparatus 20 is depicted and described as symmetrical, with upper and lower portions mirroring one another, in other embodiments it may be convenient to limit apparatus 20 to one set of manifold and bale retaining member, or to make other modifications to the above description.
All elements or features or components of apparatus 20 and the associated hoses, tubes, engines, blowers, etc. may be removable such that they may be replaced or repaired unless expressly described otherwise.
While apparatus 20 has been described primarily with relation to its use in drying hay bales, hay bales are only used as a convenient example. Apparatus 20 may also be used to dry bales of straw or other similar materials, such as other similar fodder materials. Apparatus 20 may be modified for use with different materials as well. For example, when used to dry relatively loose bales of fodder, such as straw bales, apparatus may employ a small number of larger needles, however when used to dry bales of denser fodder, such as hay bales, a greater number of narrower needles 70 may permit apparatus 20 to more easily be used to dry dense material.
While the above description provides examples of one or more apparatus, methods, or systems, it will be appreciated that other apparatus, methods, or systems may be within the scope of the claims as interpreted by one of skill in the art.
This application claims the benefit of U.S. Patent Application No. 62/534,903, filed Jul. 20, 2017, the contents of which are incorporated herein by reference.
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Number | Date | Country | |
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20190024973 A1 | Jan 2019 | US |
Number | Date | Country | |
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62534903 | Jul 2017 | US |