Turf grasses, such as are commonly found on golf courses and other athletic fields, typically require extensive maintenance to ensure high quality playing conditions. Such maintenance includes application of top dressing materials such as sand or organic matter, as well as application of treatments such as fungicides and fertilizer. However, each application results in undesirable compaction of the soil as machinery drives across the turf grass, as well as disruption in use of heavily used turf areas such as golf courses.
The embodiments described herein provide various configurations of a solid carrier sprayer apparatus, such as a sand sprayer apparatus, and methods related thereto. In one embodiment, a sand sprayer apparatus includes a sand container, a liquid container, a sand spreading apparatus, and a liquid application apparatus. The sand spreading apparatus can be coupled to receive sand from the sand container, and can further be configured to drop the received sand substantially evenly over an area of ground. In one embodiment, the liquid application apparatus is coupled to receive liquid from the liquid container, and is configured to spray received liquid substantially evenly over the received sand, such that the liquid is sprayed substantially evenly over the received sand before the sand is dropped substantially evenly over turfgrass.
In one embodiment, the sand sprayer apparatus further comprises a foam marker apparatus, configured to deposit a visible foam trail marking the dropped sand.
In one embodiment, the liquid application apparatus comprises two or more spray nozzles, and in a further embodiment are separately controllable to provide coverage to a portion or all of the sand being spread via the sand spreading apparatus. The sand may comprise material selected from silica, cristobolite, flint, chert, opal, chalcedony, and mixtures thereof. In one embodiment, the liquid application apparatus comprises two or more nozzles on a turret, such as nozzles that have different flow rates or that may be easily switched in for a clogged nozzle by rotating the turret.
In one embodiment, the liquid container comprises a mixer operable to keep liquid in the container in a mixed state. The mixer comprises, in various embodiments, a mechanical mixer, such as one or more paddles, propellers, screws, and/or other such devices. In various embodiments, the mixer can further comprise one or more liquid nozzles and/or jets that are configured to recirculate liquid in the container, such as via an external pump. The external pump can include any suitable pump known in the art capable of performing the intended function. In one embodiment, the liquid container comprises a conical portion that narrows near its bottom, reducing surface area and corners on the bottom of the liquid container to reduce settling. Various embodiments include containers of any suitable shape, such as square liquid containers, barrel liquid containers, and the like, further including liquid container configurations configured to include a sump (i.e., container). These liquid containers may further comprise other components, such as an internal sump (pump) mixer operable to keep liquid in the containers in a mixed state.
In one embodiment, the sand sprayer apparatus further comprises a second, smaller liquid container, such as a liquid container having a size that is less than half, a third, or a quarter, or any range therebetween, of the main liquid container. The smaller liquid container can, in various embodiments, be selectable for spraying sand, such as for a small batch that will consume as much liquid material as will fit in the smaller liquid container or less. In one embodiment, the smaller liquid container is configurable for other purposes, such as for use as a rinse tank to rinse the main liquid container, hoses, nozzles, and the like with fresh water.
The various embodiments described herein provide an improved sand sprayer apparatus that is operable to spray liquid materials onto sand and/or other solids that are spread over turfgrass to reduce the number of application passes that must be made. This results in a reduction in compaction of the turfgrass, and reduces the time and labor that are spent on turf maintenance. This also reduces downtime on heavily used turfgrass, such as golf courses and other such facilities.
In the following detailed description, reference is made to the accompanying drawings that form a part hereof and in which are shown, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. Other embodiments may be utilized, and structural, logical, mechanical, electrical, and other changes may be made.
Turfgrass maintenance typically includes application of a variety of top dressing materials, as well as application of liquid treatments such as fungicides and fertilizer. However, each application (i.e., trip or pass with the application machinery) results in undesirable compaction of the turf as application machinery drives across the turfgrass, as well as disruption in use of heavily used turf areas, such as golf courses. Because reduction in the amount of time and labor spent applying turfgrass treatment is desirable, as is reducing compaction of the turfgrass, it is desirable to reduce the number of vehicle passes used to apply material to turfgrass.
Modern top dressing includes application of a variety of materials to the turfgrass, which materials are deposited in a thin layer of material over the turf surface. Top dressing materials include, but are not limited to, fertilizer, sand, organic matter, soil, turfgrass seed, and other such materials. Various topdressings can limit thatch, level and smooth the turf grass surface, and improve the drainage, organic matter composition, or other qualities of the turfgrass. Application of top dressing materials can be performed in a variety of ways, including by hand (such as with a landscaping rake), with a mechanical drop spreader that drops the material substantially uniformly onto the turfgrass, or with a mechanical broadcast spreader that broadcasts or distributes the top dressing material outward from a spinner.
Application of liquid turfgrass treatments such as fungicides, insecticides, and herbicides and/or weed killers is typically performed with different equipment, designed to distribute and apply liquid material rather than solid matter. Although some fertilizers are provided as solids and may be distributed in a manner similar to top dressing distribution, many fertilizers are liquid, and are therefore also sprayed onto turfgrass. Sprayers typically used for applications of liquids, such as fertilizers and fungicides include an array of spray nozzles attached to a vehicle, such as a bar having attached spray nozzles extending perpendicular to the vehicle's direction of travel, coupled to a liquid container.
However, such sprayers often allow sprayed material to drift somewhat, as the height of the nozzle array above the turfgrass must be sufficiently high to ensure even coverage to the turfgrass and to avoid contact with uneven ground. Furthermore, hauling large amounts of liquid in a sprayer vehicle results in a heavy sprayer apparatus that compacts the soil supporting the turfgrass, just as hauling large amounts of topdressing for distribution results in turfgrass soil compaction. It is therefore desirable to ensure even distribution of liquid turfgrass treatments, and to reduce the number of vehicle trips to apply material to turfgrass to reduce soil compaction, labor, and application time.
Various embodiments presented herein therefore utilize a combination spreader/sprayer apparatus, such as a sand sprayer configured to deposit sand comprising sand particles that are substantially evenly sprayed with liquid from a container using a sprayer to form sprayed sand while being conveyed before being deposited on turfgrass as deposited sand. This configuration eliminates the need to deposit sand and liquid separately, and reduces the amount of time and labor needed relative to configurations in which the sand and liquid are deposited separately. It also reduces turfgrass soil compaction, and provides more even application of the liquid than may sometimes be achieved using a conventional spray apparatus.
The sand sprayer apparatus 104 shown in
In the embodiment shown in
In the embodiment of
In the embodiment shown in
The liquid sprayer 118 of the sand sprayer apparatus 104 can be coupled to the large container 108 and/or the small container 110, and configured to receive liquid from the large container 108 and/or the small container 110. As discussed above, the received liquid is sprayed substantially evenly over the conveyed sand 109 on the sand conveyor 117 to form sprayed sand 111, which is thereafter spread substantially evenly over the turf grass 105 in two contiguous sections 114, 116, as deposited sand 115. This results in substantially even distribution of both the contained sand 107 from the sand hopper 106 and the received liquid. Because liquids sprayed over ground using traditional sprayer apparatus tend to drift in wind and volatize, the sand sprayer apparatus 104 further provides, in some applications, more even application and less volatization of the liquid than can be achieved using traditional spray apparatus.
In operation, a user or users 119 drives the tractor 102, i.e., moves the tractor 102 forward, towing the sand sprayer apparatus 104 behind it. As the tractor 102 moves forward, one of the users 119 can initiate operation of the sand sprayer 104 or pre-set desired parameters can be activated as described below, to cause the sand sprayer apparatus 104 to operate to extract contained sand 107 from the sand hopper 106 via the sand conveyor 117. The conveyed sand 109 is then sprayed with liquid from the liquid sprayer 118, to form sprayed sand 111 that is then delivered to the sand spreader apparatus 103. The sand spreader apparatus 103 distributes the sprayed sand 111 onto the turfgrass 105 as the tractor 102 and sand sprayer apparatus 104 drive forward, resulting in a path (i.e., two contiguous sections 114 and 116) of deposited sand 115 being deposited on the turf grass 105 behind the sand sprayer apparatus 104, as shown in
The rate of sand deposited, the rate of liquid sprayed, and other such variables are controlled in some embodiments by pre-setting the desired parameter on the sand sprayer apparatus 104 before driving, and, in other embodiments, the user 119 controls one or more of these parameters from the tractor 102. In a more detailed embodiment, the sand conveyor 117, liquid sprayer 118, and sand spreader apparatus 103 operate based on the speed of the sand sprayer apparatus 104, such as by the rate of rotation of trailer wheels 124. In another embodiment, the amount of liquid sprayed per volume of sand is controlled by selection of various nozzles on the liquid sprayer 118, or by other means such as regulation of liquid pressure or number of nozzles used.
In some embodiments, an appropriate rate of sand spreading for a desired tractor speed is determined and an appropriate conveyor speed for the sand conveyer 117 is selected, and a desired rate of liquid application is determined and appropriate nozzles and/or liquid pressure are selected. In a further embodiment, a user 119 activates the sand sprayer apparatus 104 only after the user 119 has determined that the tractor 102 has reached a desired speed, resulting in the desired rate of sand and liquid application.
Some embodiments of sand sprayer apparatus 104 further comprise a foam marker apparatus 122 mounted at or near the center of the sand sprayer apparatus 104, such as under or near a hitch. The foam marker apparatus 122 is operable to deposit a foam track 120 on the ground, thus covering the center area of the two contiguous sections 114, 116 as they are being deposited to cause the two contiguous sections 114, 116 to appear instead as two separate sections of deposited sand 115, which, in this embodiment, are of substantially the same size and shape. In other embodiments, the foam marker apparatus 122 is located at another position along or to the side of the sand spreader apparatus 103, such as near the far left edge of left section 114 or near the far right edge of right section 116.
The foam in various embodiments comprises any material that will not harm the turf grass, but that remains visible for at least several minutes such that user 119 can see the path of deposited sand 115. In some embodiments, the foam comprises a gas, such as air, trapped in pockets of a liquid. Although traditional foams are formed by mechanically forming air or other gas pockets in a liquid foam material having a surfactant, a wide variety of suitable commercial foam products are available and are suitable for use with a foam marker as shown in
In one embodiment, the sand sprayer apparatus makes additional passes, with each sand pattern overlapping the previous pattern by about 50%, resulting in an application rate approximately double that of a single pass across the turf grass. Although the percentage overlap may vary based on driver accuracy or by design, such as from about 40 to about 60% overlap or from about 45% to about 55% overlap, or any range there between, use of multiple overlapping passes near 50% (±1 to 5%) helps ensure that each area of turf grass 205 receives at least one pass of coverage. In other embodiments, the foam stripe 206 and sand path 204 can have different configurations, resulting in different coverage and/or overlap. In one such embodiment, approximately no overlap is desired between a first set of passes going west-east or east-west, but a second set of passes going north-south or south-north provides a second layer of sprayed sand, resulting in more even coverage than may be obtained with non-overlapping passes in a single direction.
In one embodiment, the sand sprayer apparatus 202 deposits a foam line 206 at one or more edges of sand pattern 204, such that on the next pass, the user can follow the foam line 206 such that the sand sprayer apparatus 208 can be centered over the foam line for approximately 50% (±1 to 5%) overlap, or can be adjacent to the edge foam line 206, such that the sprayed sand is deposited as deposited sand 210 up to the edge foam line 206 for no overlap.
In this embodiment, the sand sprayer apparatus 302 deposits a sand path 304 with a foam line 306 near one edge of the sand path, rather than near the center of the sand path as in
Centered foam lines 206 as shown in
The foam material is in some embodiments provided as a liquid from a liquid container to a foam marker apparatus or foamer, such as from smaller liquid container 110 of
The liquid container 402 in this embodiment further includes liquid nozzles or jets, 406 used to agitate the liquid in the bottom conical portion of the liquid container by recirculating the liquid. These features prevent viscous liquids or fine particles suspended in the liquid from settling to the bottom of the liquid container 402, keeping the liquid mixed. In other embodiments, other types of agitators may be used, such as a spinning disc, moving paddles, a submersible sump pump, and/or other such mechanisms.
In the embodiment illustrated in
Liquid is drawn from the liquid containers and provided to sprayers using pipes, hoses, or other such fittings as shown in
Small liquid container 504 is similarly coupled to a pump 516 that is operable to provide liquid from the small liquid container 504 to the sprayer apparatus 506, and optionally to provide a liquid to small liquid container agitator nozzle 518 through configuration of valve 520.
Embodiments having separate pumps for each liquid container further enable a user to agitate one liquid container without providing liquid to the nozzles while the other liquid container provides liquid to the nozzles, and enables the liquid containers to be used for different purposes. For example, the small liquid container 504 may be filled with fungicide and used for small applications of sprayed sand one day (such as applications where the small liquid container can hold all the liquid needed for a particular task), and may be filled with fresh water and used to flush or clean the large liquid container 502, piping, and sprayer apparatus 506 later on the same day or the next day. In one such embodiment, clean water from small liquid container 504 is pumped through pump 516 and a control valve 522 connecting the pumped liquid from smaller liquid container 504 to an optional hose fitting or the like, which is attached to a hose used to clean other sand sprayer parts.
In one embodiment, pumps 516 and 510 are replaced with a single pump, placed between liquid container selector valve 524 and valves 526/528. Such a configuration works well where recirculation nozzles are also selected by a valve coupled to 524, so that only liquid containers in use are recirculated. This configuration also works in applications where other agitation mechanisms are used or no agitation is used, such as with liquid containers having a mechanical agitator. However, when a single pump is used to drive the sprayer assembly 506 and agitator nozzles, the liquid container not selected is not agitated or available for other applications requiring pumped liquid.
Returning to the embodiment shown in
Liquid from liquid container selector valve 524 flows to left nozzle selector valve 526 and right nozzle selector valve 528, which enable a user to selectively spray either the right half or left half of the sand 509, or both halves of the sand 509. Such a feature is particularly useful when using a sand spinner to apply sand near sensitive areas that are not to receive a sprayed solid carrier, such as sprayed sand, such as near sand traps on golf courses or near water. In some embodiments, the user is able to select which nozzles are active by actuating valves 526 and 528 while driving, such as by using remote levers or electronic or solenoid-operated valves.
A user can similarly monitor fluid flow through nozzles 508 by using electronic flow meters with remote readouts, but in some embodiments will use a more cost-effective in-line flow indicator such as visible ball apparatus 530 and 532. In one embodiment, these visible ball apparatus each include a floating ball that is either pushed downward, or otherwise moves in a clear tube or other transparent housing as a result of fluid flow through the apparatus, providing a visible indicator of fluid flow from a moderate distance such as from a tractor seat. In another embodiment, the visible ball is a sinking ball, and fluid flow from bottom of the visible ball apparatus to top drives the ball upward or otherwise moves the ball, visibly indicating fluid flow. One example of such a visible ball apparatus is the commercially available Redball™ spray monitor.
Visible ball flow indicators, such as the ones described and shown herein, simplify the sand sprayer apparatus and reduce cost relative to electronic flow indicators, while still providing a visible indication of the rate of flow of liquids through each visible ball indicator. They enable a user to quickly observe irregular flow or stoppages, such as a failed pump 510, an empty liquid container 502, or a clogged nozzle 508. The user can then promptly remedy the problem by performing appropriate actions, such as replacing a clogged nozzle, and can easily observe where or when such a liquid flow problem occurs so that the problem can be promptly corrected and accurate turfgrass coverage can be maintained.
In operation, liquid from a liquid container is provided to one or more turrets 604, such as through a pump or by gravity. The turrets in the embodiment of
Although the turrets 604 here are shown as rotating turrets having three different configurations, turrets having two, four, or other numbers of configurations or nozzles are also used in other embodiments. Similarly, although the turrets shown are configured such that the nozzles pointing down such as nozzle 606 are the active nozzles on each turret, other configurations and nozzle orientations are used in other embodiments.
Should a nozzle such as nozzle 606 clog during sprayer operation, the turret 604 can be rotated to move nozzle 608 into the downward position, making nozzle 608 the active spray nozzle on that turret. This enables a sand sprayer apparatus to be easily reconfigured after a nozzle becomes clogged, so that sand spraying can continue without stopping for removal, replacement, or cleaning the clogged nozzle.
In another embodiment, nozzles on a turret such as nozzles 606 and 608 on turret 604 are different nozzles, such as nozzles having different flow rates. For example, turret 604 may have nozzles that spray 0.25, 0.5, and 1 gallon per minute at a specified pressure, and the sand sprayer operator selects the appropriate nozzle for a particular liquid to be sprayed on the sand to achieve the desired application rate.
Turrets having nozzles with different flow rates are particularly useful in environments where the same sand sprayer apparatus is used to apply different materials to sand, such as fungicides on one application and insecticides on a subsequent application. A groundskeeper may similarly desire to apply different amounts of sand or other solid material on top of turf grass, changing the amount of liquid that should be applied per volume of sand to achieve the same liquid coverage per turf grass area.
For example, a solid carrier, such as sand, may be sprayed with a liquid such as any type of humate (e.g., humic acid), herbicide (e.g., dicamba), insecticide (e.g., Merit®), plant growth regulator (e.g., trinexapac-ethyl), supplement (e.g., micronutrients, plant extracts), oils (e.g. mineral oil), a nematicide, and/or soil wetting agent (e.g., Cascade®). Similarly, a solid insecticide or fertilizer may be sprayed with an antifungal, a solid supplement may be sprayed with a growth regulator or humate, and other combinations of solids and liquids may be combined in the sand sprayer by spraying a solid with a liquid before spreading the solid. Many other examples of suitable application materials are found in the incorporated references, such as in U.S. Pat. No. 8,202,343 at col. 16-col. 64, and in the definitions at col. 5-col. 15.
Some experimental evidence suggests that the systemic (root and foliar absorbed) fungicides work particularly well when applied as sprayed-on sand, while the contact, surface protectant, non-systemic or limited systemic fungicides also work when applied as sprayed-on sand but may require higher application rates than if sprayed directly on turf grass. Because some insecticides and herbicides also work through surface contact with foliage, they may similarly require higher application rates when sprayed on deposited sand.
While not wishing to be bound by this proposed theory, this result may occur because there is less complete foliar coverage with sand-based applications than with direct spraying, such that sand-based active ingredients that rely on foliar absorption or coverage will require greater application rates when spread with sand. Examples of such foliar absorption or coverage materials include some fungicides, insecticides, and herbicides. Other sand-based active ingredients that are easily absorbed through the roots, such as many fertilizers, systemic fungicides and herbicides, and other such systemic materials, are also expected to work particularly well with the embodiments described herein, with effectiveness similar to direct spraying. Active ingredients that are primarily soil-active, such as soil wetting agents, are also expected to work well, with effectiveness similar to direct spraying.
Spraying such materials onto sand or other solids that are spread over turfgrass reduces the number of application trips that must be made. This results in a reduction in compaction of soil supporting the turfgrass, and reduces the time and labor that are spent on turf maintenance. This also reduces downtime on heavily used turfgrass, such as golf courses and other such facilities.
Although specific embodiments have been illustrated and described herein, any arrangement that achieve the same purpose, structure, or function may be substituted for the specific embodiments shown. For example, although the solid carrier sprayer apparatus has been described as a sand sprayer apparatus, other solid carriers are possible, including, but not limited to, a solid carrier which comprises a majority of weight sand and/or can otherwise contain peat, organic matter, soil, or mixtures thereof This application is intended to cover any adaptations or variations of the embodiments of the invention described herein, and these and other embodiments are within the scope of the following claims and their equivalents.
This application is a continuation-in-part of U.S. patent application Ser. No. 13/472,213 filed on May 15, 2012, now allowed, which application is a continuation of U.S. patent application Ser. No. 12/288,194, filed on Nov. 13, 2008, which issued as U.S. Pat. No. 8,202,343 on Jun. 19, 2012, which application claims priority to U.S. Provisional Patent Application Ser. No. 61/002,898, filed on Nov. 13, 2007, all of which are hereby incorporated by reference herein in their entireties. This application is also a continuation-in-part of U.S. patent application Ser. No. 12/288,188, filed on Oct. 7, 2008, which is hereby incorporated by reference in its entirety, which application also claims priority to U.S. Provisional Patent Application Ser. No. 61/002,898, filed on Nov. 13, 2007.
Number | Date | Country | |
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61002898 | Nov 2007 | US | |
61002898 | Nov 2007 | US |
Number | Date | Country | |
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Parent | 12288194 | Oct 2008 | US |
Child | 13472213 | US |
Number | Date | Country | |
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Parent | 13472213 | May 2012 | US |
Child | 14101723 | US | |
Parent | 12288188 | Oct 2008 | US |
Child | 12288194 | US |