1. Field
The present invention relates generally to a connector assembly to transfer materials. More specifically, embodiments of the present invention concern a material application system including an applicator and supply station that provide a connector assembly to transfer liquid between the applicator and supply station.
2. Discussion of Prior Art
Releasable fluid connectors have long been used for transferring large volumes of liquid chemicals, such as fertilizer or fuel. Some conventional fluid coupler assemblies are designed to transfer hazardous liquid and can be selectively coupled or decoupled while restricting liquid from leaking from the connection. Specifically, it is known in the art to provide a “drip-less” connection with a pair of mating couplers that each include an integral valve to restrict inadvertent fluid leakage when the couplers are coupled or decoupled.
Agricultural applicators are known in the art for applying liquid onto a crop field. Such applicators carry a liquid container with a limited amount of liquid, and the container is typically replenished from a supply station. A conventional applicator supply station includes a supply line and a storage container that feeds the supply line. The applicator container is refilled by manually positioning the supply line into fluid communication with the applicator container and pumping liquid from the storage container.
Prior art fluid connectors are deficient and suffer from certain limitations. For instance, conventional “drip-less” couplers include a valve that is opened by manual actuation of a corresponding valve handle. Furthermore, to open or close the passage formed by a mated pair of such couplers, an operator must manually open or close both of the valves. So called “drip-less” couplers may also permit inadvertent liquid spillage during fluid transfer or during coupling or decoupling of the couplers.
Conventional applicators and applicator supply stations are also deficient because the refilling process involves manual positioning of the supply line so that the supply line can fluidly communicate with the applicator container. Such conventional manual coupling and decoupling of an applicator and supply station can result in inadvertent and undesirable liquid spillage or contamination of the liquid. Furthermore, inadvertent spillage can cause the operator to become exposed to the transferred liquid.
The following brief summary is provided to indicate the nature of the subject matter disclosed herein. While certain aspects of the present invention are described below, the summary is not intended to limit the scope of the present invention.
Embodiments of the present invention provide a material application system and fluid connector assembly that do not suffer from the problems and limitations of the prior art application systems and connectors set forth above.
A first aspect of the present invention concerns an agricultural liquid material application system that broadly includes a mobile agricultural applicator and a fluid-transferring connection assembly. The mobile agricultural applicator includes a chassis and a liquid material applicator tank supported on the chassis. The fluid-transferring connection assembly is operable to selectively define a fluid passage that intercommunicates the applicator tank and a liquid material source when the connection assembly is in a fluid transfer configuration. The fluid-transferring connection assembly includes a pair of complemental fluid connectors, a first one of which is configured for association with the liquid material source and a second one of which is associated with the applicator. The fluid connectors are moveable into and out of sealing engagement to restrict fluid from leaking out of the connection assembly when in the fluid transfer configuration. The connection assembly includes at least one shiftable valve yieldably biased into a closed position in which flow through the fluid passage is prevented. The valve is operably coupled to a corresponding one of the fluid connectors so as to be automatically shifted out of the closed position when the connectors are in sealing engagement with one another and the connection assembly is in the fluid transfer configuration.
A second aspect of the present invention concerns a mobile agricultural applicator for use with a material supply station including a liquid material storage tank and a station fluid connector fluidly coupled to the storage tank. The mobile agricultural applicator broadly includes a chassis, a liquid material applicator tank supported on the chassis, an applicator fluid connector, and an applicator valve. The applicator fluid connector is fluidly coupled to the applicator tank and is configured to sealingly engage the station fluid connector and thereby define a fluid passage between the tanks. The applicator fluid connector is moveable relative to the station fluid connector as the applicator is moved relative to the supply station. The applicator valve is yieldably biased into a closed position in which flow through the fluid passage is prevented. The valve is operably coupled to the applicator fluid connector so as to be automatically shifted out of the closed position when the connectors are in sealing engagement with one another and the applicator fluid connector is moved toward the station.
A third aspect of the present invention concerns a fluid-transferring connection assembly for fluid transfer between liquid material tanks of a mobile agricultural applicator and a liquid material supply station, with the connection assembly operable to selectively intercommunicate the tanks when the assembly is in a fluid transfer configuration. The fluid-transferring connection assembly broadly includes a pair of complemental fluid connectors and a drive. The pair of complemental fluid connectors is operable to selectively define a fluid passage that fluidly communicates the tanks in the fluid transfer configuration, a first one of which is configured for association with the liquid material supply station and a second one of which is configured for association with the applicator. The fluid connectors are moveable into and out of sealing engagement to restrict fluid from leaking out of the connection assembly when in the fluid transfer configuration. The connection assembly includes at least one shiftable valve yieldably biased into a closed position in which flow through the fluid passage is prevented. The drive interconnects a corresponding one of the fluid connectors and the valve. The corresponding one of the fluid connectors is shiftable into and out of a valve-closing position, with the fluid connectors being in sealing engagement and relatively fixed to one another when the corresponding one of the fluid connectors is out of the valve-closing position. The drive automatically shifts the valve into and out of the closed position in response to shifting movement of the corresponding one of the fluid connectors into and out of the valve-closing position.
Other aspects and advantages of the present invention will be apparent from the following detailed description of the preferred embodiments and the accompanying drawing figures.
Preferred embodiments of the invention are described in detail below with reference to the attached drawing figures, wherein:
The drawing figures do not limit the present invention to the specific embodiments disclosed and described herein. The drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the preferred embodiment.
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The sprayer assembly 32 preferably serves to distribute liquid material uniformly and preferably includes an applicator tank 44 and boom assembly 46. The tank 44 is conventional and serves to hold liquid material (not shown) in the usual manner. The tank is mounted on the rolling chassis 26 between the boom assembly 46 and cab 28. The boom assembly 46 preferably includes booms 48 and boom support frame 50. The booms 48 are shiftably attached to corresponding ends of the boom support frame 50. The boom assembly 46 supports a plurality of spray nozzles (not shown) and fluid tubing (not shown) that fluidly connects the tank 44 and nozzles. The boom assembly 46 is preferably mounted to the rolling chassis 26 adjacent an aft end of the chassis 26. Thus, as the applicator 22 moves in a forward direction, the sprayer assembly 32 applies liquid material rearwardly of the chassis 26. However, it is also within the ambit of the present invention where the boom assembly 46 is alternatively mounted on the chassis 26, e.g., where the boom assembly 46 is mounted adjacent the fore end of the chassis 26. As is customary, the boom assembly 46 is preferably foldable for transport and when obstacles in the field are encountered.
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The telescopic fill tube 54 is supported on the chassis 26 by a bracket 70 such that the fill tube 54 preferably extends longitudinally along the chassis 26 and extends longitudinally beyond the front end of the applicator 22. However, it is also within the scope of the present invention where the fill tube 54 projects in an alternative direction relative to the chassis 26 (e.g., rearwardly, upwardly, or in a sideward direction). The bracket 70 secures the outer tube section 60 to the chassis 26 and permits the inner tube section 58 to shift along the longitudinal direction. The outer tube section 60 is fluidly attached to a supply conduit 72 that extends from the proximal end 62 in a rearward direction to the tank 44 so that the supply conduit 72 fluidly connects the fill tube 54 and tank 44.
The hydraulic cylinder 56 is conventional and includes a cylinder housing 74 and piston 76 slidably received in the housing 74. The hydraulic cylinder 56 is attached to the telescopic fill tube 54 by attaching the end of the piston 76 to weldment 66 mounted on the inner tube section 58 and attaching an end of the cylinder housing 74 to weldment 66 mounted on the outer tube section 60. The hydraulic cylinder 56 is operably coupled to a hydraulic system (not shown) of the applicator 22 that permits the operator to preferably control the position of the piston 76 from within the cab. Although the fluid probe assembly 34 preferably includes the hydraulic cylinder 56 to shift fill tube 54, it is also within the ambit of the present invention where another drive is employed to position the fill tube 54, e.g., another type of linear motor such as a pneumatic cylinder or a linear electric motor.
Movement of piston 76 in and out of the housing 74 causes corresponding movement of the inner tube section 58 relative to the outer section 60 between an extended position (see
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The poppet valve 82 is preferably unitary and includes a head 102 and stem 104. The poppet valve 82 is slidably mounted on the male connector 78. In particular, the stem 104 is slidably received in bore 98, with the spring 84 being positioned between the support frame 96 and head 102. The poppet valve 82 is slidable into and out of a closed position where the head 102 is received by the internal seat 92 and prevents fluid flow through the passage 100 (see
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The support assembly 112 includes, among other things, a support frame 120, upper and lower bracket guide rods 122,124, intermediate connector guide 126, and mounting brackets 128. The support frame 120 is substantially rigid and includes upper and lower wall sections 130,132, and sidewall section 134. The support frame 120 also includes end flanges 136 attached to ends of the upper and lower wall sections 130,132 opposite the sidewall section 134. The support frame 120 additionally includes a bushing 138 attached below the lower wall section 132, and the bushing 138 is configured to mount the support frame 120 on the trailer 106. The support frame 120 further includes a toothed rack 140 and a bracket 142 that supports the rack 140. The bracket 142 is attached to the sidewall section 134, with the bracket 142 and rack 140 extending longitudinally between upper and lower wall sections 130,132. The rack 140 serves to permit opening and closing of valves associated with the connector assemblies 52,110, as will be discussed further.
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Furthermore, the pivot joint cooperatively presented by support frame 120 and frame mount 156 also preferably permits pivotal movement about an upright pivot axis (see
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With the sleeve 180 in the unlocked position, the hooked ends of pawls 226 are positioned adjacent proximal groove 218 and are shiftable radially outwardly by springs 230 to be received by the proximal groove 218. With the sleeve 180 in the locked position, the hooked ends of pawls 226 are positioned distally from the proximal groove 218 so that the sleeve 180 restricts pivotal movement of the pawls 226 relative to the housing 178.
The female connector 164 also preferably includes a pair of interlocks 232 that selectively allow the sleeve 180 to shift between the locked and unlocked positions. The interlocks 232 each include a hooked end 234. The interlocks 232 are positioned within corresponding openings 192 of the housing 178 and are pivotally mounted on corresponding pins 194, with the hooked ends 234 facing radially outwardly. Springs 236 are positioned in the corresponding openings 192 and urge the hooked end 234 to extend radially outwardly from the opening 192.
With the sleeve 180 in the unlocked position, the hooked end 234 is urged to be shifted radially outwardly into engagement with the intermediate groove 222 and thereby restricts axial sleeve movement relative to the housing 178. The interlocks 232 are shifted out of engagement with the intermediate grove 222 by inserting the connector assembly 52 into engagement with the connector assembly 110. In particular, the male connector 78 presents an endless outer rib 238 operable to engage a tabbed end of the interlock 232 opposite the hooked end 234. When the connector assemblies 52,110 are in sealing engagement, the interlocks 232 are engaged by the outer rib 238 so that the hooked ends 234 are shifted out of engagement with the groove 222. In this manner, the sleeve 180 is permitted by the interlocks 232 to be shifted from the unlocked position and into the locked position. While the connector assembly 110 preferably includes female connector 164, it is also within the scope of the present invention where the connector assembly includes male connector 78 (e.g., where the applicator 22 includes female connector 164 and support assembly 112). The manner of interconnecting the connectors 78 and 164 may also be varied without departing from the scope of the present invention.
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The shaft 172 is elongated and is journaled in transverse shaft bore 244 in housing 178. The linkage 170 includes a drive link 246 mounted on the shaft 172 and driven links 248 that interconnect the drive link 246 and poppet valve 168. In particular, the driven links are pivotally attached to the drive link by pin 250 and are also pivotally attached to the poppet valve 168 by pin 252. Thus, rotation of shaft 172 and corresponding movement of linkage 170 is operable to shift the poppet valve 168 between the open and closed positions.
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The illustrated connector assembly 110 is selectively shiftable into and out of the valve-closing position. With the male fluid connector assembly 52 disengaged from the connector assembly 110, interlocks 232 engage the groove 222 to restrict movement of sleeve 180 relative to the housing 178. Consequently, the locked sleeve 180 restricts cam 174 and shaft 172 from rotating. Because the pinion gear 176 and toothed rack 140 are in intermeshing engagement, the connector assembly 110 is also restricted from shifting longitudinally relative to the support assembly 112.
With the connector assemblies 52,110 in sealing engagement with each other and in the valve-closing position, the outer rib 238 shifts the interlocks 232 out of engagement with the groove 222 to permit movement of sleeve 180, as will be discussed in greater detail. In turn, this permits rotation of cam 174 and shafts 172, and thereby permits longitudinal shifting movement of the connector assembly 110. Thus, the connector assembly 110 can shift distally from the valve-closing position once the connector assemblies 52,110 are positioned in sealing engagement. As the connector assembly 110 is shifted in the distal direction out of the valve-closing position, the pinion gear 176 causes rotation of shaft 172 and cam 174, which shifts the sleeve 180 into the locked position. Furthermore, shifting of connector assembly 110 out of the valve-closing position causes shaft 172 to drive the linkage 170 so that poppet valve 168 is shifted out of the closed position. Thus, poppet valve 168 is shifted out of the closed position once connector assembly 110 is in sealing engagement with connector assembly 52 and is shifted out of the valve-closing position.
The connector assembly 110 is urged by distal springs 148b to shift proximally from the fluid transfer configuration and into the valve-closing position. As the connector assembly 110 shifts proximally into the valve-closing position, the pinion gear 176 rotates the shaft 172, which causes the poppet valve 168 to shift into the closed position while the connector assemblies remain in sealing engagement. Proximal movement into the valve-closing position also rotates the cam 174 out of engagement with sleeve 180. Thus, proximal springs 148a urge the sleeve 180 to return to the unlocked position. Furthermore, once the poppet valve 168 in the closed position, the connector assemblies 52,110 can move out of sealing engagement.
Thus, the support assembly 112 and the pinion gear 176 cooperatively provide a drive assembly 262 to preferably provide automatic shifting of the valve assembly 166 into and out of the closed position (see
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As connector assembly 52 is shifted into sealing engagement with connector assembly 110, the connector assembly 110 remains in the valve-closing position. The rib 238 preferably serves as a catch and presents a cam surface that is automatically releasably engaged by cam surface 228 of pawls 226. Thus, the pawls 226 releasably engage the rib 238 so that connectors 78,164 are releasably interconnected. Once the connector assemblies 52,110 are in sealing engagement, the poppet valves 82,168 can be opened.
With the connector assemblies 52,110 in sealing engagement, the poppet valves 82,168 are preferably positioned with endmost faces adjacent to each other. As discussed above, poppet valve 168 is opened provided that the connector assembly 110 is in sealing engagement with connector assembly 52 and is shifted out of the valve-closing position. The poppet valve 82 of connector assembly 52 opens when the endmost face of poppet valve 168 engages the corresponding endmost face of poppet valve 82 and shifts the poppet valve 82 open. Thus, the illustrated connector assemblies are constructed so that poppet valves 82,168 open once the connectors are in sealing engagement.
The rib 238 also shifts the interlocks 232 out of engagement with groove 222. Once the interlocks 232 are disengaged from sleeve 180, further distal movement of connector assembly 52 (where “distal” movement refers to movement away from the applicator 22 and “proximal” movement refers to movement toward the applicator 22) causes connector assembly 110 to shift distally out of the valve-closing position. Thus, pinion gear 176 causes shaft 172 to rotate and thereby shift the poppet valve 168 open, with the sleeve 180 being shifted into the locked position. Although the connector assemblies 52,110 are preferably shifted into the fluid transfer configuration by distal movement of the connector assembly 52 out of the valve-closing position, the connection assembly 162 could be alternatively configured to be shifted into the fluid transfer configuration. As discussed above, the support assembly 112 could include a powered drive operably coupled to the valve assembly 166 to shift the poppet valve 168 open and the sleeve 180 into the locked position.
While being shifted into the open position, the endmost face of poppet valve 168 engages the corresponding endmost face of poppet valve 82 of connector assembly 52 and shifts the poppet valve 82 into the open position. Thus, the connector assembly 110 and support assembly 112 are preferably operable to shift the poppet valve 82 open when the connector assembly 52 urges the connector assembly 110 into the fluid transfer configuration. In this manner, the poppet valves 82,168 are automatically shifted out of the closed position and the connector assemblies 52,110 are correspondingly shifted automatically into the fluid transfer configuration. However, for some aspects of the present invention, the poppet valve 82 could be shifted into the open position by a mechanism other than the connector assembly 110 and support assembly 112. For instance, the connector assembly 52 could include a valve assembly similar to valve assembly 166, and the applicator 22 could include a support assembly similar to support assembly 112 for driving the valve assembly and poppet valve 82.
Again, shifting of the connector assembly 110 out of the valve-closing position causes the cam 174 to rotate and shift the sleeve into the locked position. With the sleeve 180 in the locked position, the proximal groove 218 is spaced proximally from the pawls 226 such that the pawls 226 are restricted from pivoting out of engagement with the rib 238. In this manner, the male and female connectors 78,164 are automatically releasably interlocked with one another and are in sealing engagement.
Similarly, the applicator 22 and supply station 24 are operable to be automatically fluidly disengaged by shifting the male fluid connector assembly 52 in a proximal direction away from the female fluid connector assembly 110 and out of sealing engagement with the female fluid connector assembly 110. This movement is preferably provided by shifting the tube section 58 of probe assembly 34 away from the station 24 without moving the applicator 22 (i.e., by controlling the hydraulic cylinder 56).
As connector assembly 52 is initially shifted in a proximal direction out of the fluid transfer configuration, the connectors 78,164 remain releasably locked in sealing engagement. The connector assembly 52 is preferably shifted proximally out of the fluid transfer configuration by driving the hydraulic cylinder 56 of the fluid probe assembly 34 so that the inner tube section 58 shifts proximally relative to the outer tube section 60. However, it is also within the scope of the present invention where the connector assembly 52 is shifted out of the fluid transfer configuration by driving the entire applicator 22 in the proximal direction away from the supply station 24 or shifting the supply station 24 distally away from the applicator 22 to shift the connector assemblies 52,110 out of the fluid transfer configuration.
As the connector assemblies 52,110 move proximally relative to support assembly 112, the pinion gear 176 causes shaft 172 to rotate and thereby shift the poppet valve 168 into the closed position. Consequently, the spring 84 of connector assembly 52 urges the poppet valve 82 to also return to the closed position. Furthermore, the pinion gear 176 causes the cam 174 to rotate out of engagement with the distal end of the sleeve 180. As the connector 164 approaches the valve-closing position, the sleeve 180 is urged from the locked position to the unlocked position by proximal springs 148a. In this manner, the poppet valves 82,168 are automatically shifted into the closed position while the connectors remain sealed and the connector assemblies 52,110 are correspondingly shifted automatically out of the fluid transfer configuration. Once the poppet valves 82,168 are closed, the connectors can shift out of sealing engagement.
In the valve-closing position, the sleeve 180 returns to the unlocked position, and the interlocks 232 are urged by springs 236 to pivot so that the hooked ends 234 engage the groove 222. In addition, the proximal groove 218 returns to a position adjacent the hooked ends of pawls 226, and the pawls 226 are operable to be pivoted out of engagement with rib 238.
Proximal movement of the connector assembly 52 out of sealing engagement with connector assembly 110 preferably occurs by driving the hydraulic cylinder 56 so that the inner tube section 58 shifts proximally relative to the outer tube section 60 (see
As the connector assemblies are shifted out of sealing engagement, the poppet valves 82,168 remain in the closed position. The closed poppet valves 82,168 are preferably positioned adjacent to ends of the connectors 78,164 so that the heads of poppet valves 82,168 are adjacent to each other when the connectors 78,164 are in sealing engagement. In this manner, any space between the poppet valves 82,168 that could collect liquid during the liquid transfer process is substantially eliminated. Consequently, the connector assemblies are constructed to restrict liquid spillage, particularly when the connector assemblies are shifted out of sealing engagement with each other.
While the illustrated probe assembly 34 is preferably associated with the applicator 22 and the support assembly 112 is preferably associated with the supply station 24 to provide selective fluid connection, it is also within the scope of the present invention where the applicator 22 and supply station 24 are alternatively configured. For example, the applicator 22 could include the support assembly 112 and connector assembly 110, with the supply station 24 including the probe assembly 34 and connector assembly 52.
In operation, the applicator 22 dispenses liquid material along a field until little or no liquid remains in the tank 44, or the applicator 22 is conveniently located at or near a supply station. The applicator 22 is refilled by driving the applicator 22 into a position adjacent the supply station 24 so that the connector assemblies 52,110 can be positioned in sealing engagement with each other. In particular, the connector assembly 52 can be shifted into sealing engagement by driving the applicator 22 toward the supply station 24 or shifting the probe assembly 34 toward the supply station 24. Once in sealing engagement, the connection assembly 162 permits the connector assembly 52 to be further shifted in the distal direction from the valve-closing position until the connection assembly is in the fluid transfer configuration. While in the fluid transfer configuration, liquid can be pumped from the tank 108 through the connection assembly 162, the probe assembly 34, the supply conduit 72, and into the tank 44.
Once transfer of liquid into the tank 44 is complete, the connection assembly 162 is shifted out of the fluid transfer configuration by retracting the connector assembly 52 until the connector assemblies 52,110 return to the valve-closing position. In the valve-closing position, the connector assemblies 52,110 are unlocked and the corresponding poppet valves are closed. Thus, the connector assembly 52 can be shifted out of sealing engagement with the connector assembly 110, and the applicator 22 can return to the field to continue applying liquid material.
The preferred forms of the invention described above are to be used as illustration only, and should not be utilized in a limiting sense in interpreting the scope of the present invention. Obvious modifications to the exemplary embodiments, as hereinabove set forth, could be readily made by those skilled in the art without departing from the spirit of the present invention.
The inventors hereby state their intent to rely on the Doctrine of Equivalents to determine and assess the reasonably fair scope of the present invention as pertains to any apparatus not materially departing from but outside the literal scope of the invention as set forth in the following claims.
Number | Name | Date | Kind |
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2733079 | Worlidge | Jan 1956 | A |
3473569 | Murray et al. | Oct 1969 | A |
3809122 | Berg | May 1974 | A |
3976100 | Souslin | Aug 1976 | A |
4540144 | Perrella | Sep 1985 | A |
5048577 | Kuusisto | Sep 1991 | A |
5810292 | Garcia et al. | Sep 1998 | A |
7503510 | Vickers et al. | Mar 2009 | B2 |
8186393 | Huegerich et al. | May 2012 | B2 |
Number | Date | Country | |
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20110139302 A1 | Jun 2011 | US |