Patent Application
20230107266
This disclosure is directed toward systems and apparatuses designed to cool and condition hydraulic oil on mobile equipment and transportation applications with hydraulic drive. The mobile equipment may be a pumper truck including a hydraulic motor connected to a processing pump for pumping liquids into or out of the truck's tank. The pumper truck may be configured for agricultural use and the liquids being pumped may include an agricultural product like corn syrup. A prior art cooler and its installation is shown in
Agricultural pumper trucks may include a hydraulic motor connected to a processing pump that pump liquids such as corn syrup. A hydraulic reservoir cooler may be connected to the hydraulic motor, cooling and conditioning hydraulic fluid returned to the tank of the cooler. The cooled and conditioned hydraulic fluid is then pumped to the hydraulic motor of the processing pump.
The hydraulic reservoir cooler is mounted on the side of truck and space is limited for its mounting. Heat rejection requirements are increasing for these types of applications but the amount of space available on the truck for the cooler remains unchanged.
Embodiments of a hydraulic reservoir cooler of this disclosure include a backward curve centrifugal fan located rearward of a vented front cover of the cooler, the centrifugal fan having a center point “c” and a radius “r” and arranged to provide substantially horizontal air flow through the vented front cover; and a core area including fins and a manifold in fluid communication with a hydraulic fluid tank, the core area being located between the vented front cover and the backward curve centrifugal fan; the core area further including: a straight vertical portion extending in height less than an uppermost upper end of the backward curve centrifugal fan; a straight horizontal portion located above the uppermost upper end of the backward curve centrifugal fan; and a curved portion connecting the straight vertical and horizontal portions, the curved portion having a center point “C” and a radius “R”; where C is located above c and R is greater than r. The cooler may be adapted for use with an agricultural pumper truck.
Elements and Numbering Used in the Drawings
Embodiments of hydraulic reservoir cooler 10 of this disclosure include a heat exchanger 30 having a curved core area 40 with fins 31. The hydraulic fluid flowing into the curve 40B of the core area 40 flows 90 degrees to the path of the air A provided by a backward curve centrifugal fan 50 and the fluid flowing out of the curve 30B flows substantially parallel to the path of air A. The fluid flowing through the curve 30B flows at an oblique angle to the path of air A.
The hydraulic reservoir cooler 10 of this disclosure may be sized having a width no greater than 13 inches, a height no greater than 22 inches (55.88 cm), and a depth no greater than 22 inches. The minimal fan clearance may be in a range of 1½ to 2½ inches (3.81 to 5.08 cm). In some embodiments, the minimal fan clearance may be 2 inches (5.08 cm). The cooler 10 may be installed in a space no greater than 15 inches (38.1 cm) in width. The length, width, and height dimensions may be 22 inches by 12.6 inches by 22 inches (55.88 cm by 32 cm by 55.88 cm).
Embodiments may include only one low pressure hydraulic hose 11. Rear studs 21 may be included for side rail mounting. A bracket assembly (not shown) may be included for behind the cab mounting. The cooler 10 may include all S.A.E. ports and corresponding S.A.E. fittings. In embodiments, a SAE-32 back and bottom suction ports 61, 63, a SAE-8 case drain port 71, a SAE-24 return port 65, a SAE-20 pressure port 67, and an SAE-04 gauge port 69, or their equivalents, are provided.
The cooler 10 may have a capacity of up to 60 gpm (227 Lpm); tank 15 size may be 6 gallons (22.7 L). A dual bullseye sight glass 13 may be provided. The hydraulic fluid filter assembly 15 may include a tank top design with an integral breather and bypass 17. The bypass may be configured for 25 psi (172.4 KPa). The filter element 19 may be 10 micron filter element.
Embodiments of the system in which the hydraulic cooler 10 is used may be configured or adapted for pressures up to 4,000 psi (27.6 MPa), and can include components such as a hydraulic pup, directional control valve, a hydraulic motor, and a processing pump or compressor like in the prior art, along with suction, pressure (feed), and return lines. See e.g. FIGS. & 2. The system may include a system relief valve arrange to ensure that the maximum system pressure does not go any higher than what a user sets the valve at. By way of example, the valve may be an adjustable relief valve in a range of 500 psi to 3,000 psi (3.4 MPa to 20.7 MPa). The system may also include a cold oil bypass valve. This valve may be set, for example, at 60 psi (413.7 KPa) to ensure that the low pressure side of the hydraulic system stays at a low pressure and to protect the cooler 10 from over pressurization due to cold oil.
The fan 50 may be a hydraulic drive fan. A flow control valve can be arranged to ensure the delivery of consistent flow to the hydraulically powered cooling blower motor. The flow control valve may be factory set to ensure the most efficient blower speed.
The fan50 has a center point “c” and radius “r” and the curve 40B of the core area 40 may have a different center point “C” and radius “R” than that of the fan 50. In embodiments, a lower straight portion 40A of the core area 40 extends in height to at least the horizontal centerline 51H of the fan 50. The lower straight portion 40A may extend past the horizontal centerline 51 in a range up to the uppermost upper end 55 of the fan 50. An upper straight portion 40C of the core area 40 may begin at or rearward of the vertical centerline 51V of the fan. An overall length of the upper straight portion 40C may be less than the overall length of the lower straight portion 40A. The curved portion 40C of the core area 40 lies between the straight portions 40A, 40C. In embodiments, the curve 40B may begin at a height between the centerline 51H and the uppermost upper end 55 of the fan 50. An upper header 43 is at the upper end of the core area 40 and a lower header 41 is at the bottom end, each header 41, 43 being on opposite sides of the vertical centerline 51V of the fan 50.
Embodiments of a hydraulic reservoir cooler 10 of this disclosure and a prior art hydraulic reservoir cooler were tested by the inventors under substantially identical conditions and their respective heat exchange performance was measured. Table 1 shows the test results of the prior art hydraulic reservoir cooler, an APSCO™ ARC60™ hydraulic reservoir cooler. Tables 2 and 3 show the test results of a hydraulic reservoir cooler 10 of this disclosure, labeled SUPERARC-60.
A hydraulic reservoir cooler 10 of this disclosure provides increased heat rejection in the same space envelope as prior art hydraulic reservoir coolers because of the longer flow path provided by the curved core area 40. For example, a hydraulic reservoir cooler of this disclosure—which may have a heat rejection in a range of 40 HP to 48 HP at 60 gpm (227.1 Lpm) and an entering temperature difference of 80° F.—provides heat rejection in a range of 43% to 71%, 45% to 69%, 47% to 67%, 49% to 65%, 51% to 63%, 53% to 61%, or 55% to 59% greater in the same space as an APSCO™ ARC60™ hydraulic reservoir, which has a heat rejection of 28 HP at 60 gpm (227.1 Lpm) and an entering temperature difference of 80° F. In one test, heat rejection was 42.8 HP compared to the ARC-60's 28.2, a 51% increase. In another test, heat rejection was 45.2 compared to the ARC-60's 28.2, a 60% increase. The broader ranges listed here may have narrower sub-ranges, as well as discrete values, within each of the broader ranges.
Embodiments of a hydraulic reservoir cooler 10 of this disclosure include a backward curve centrifugal fan 50 located rearward of a vented front cover 13 of the cooler 10, the centrifugal fan 50 having a center point “c” and a radius “r” and arranged to provide substantially horizontal air flow through the vented front cover 50; and a core area 40 including fins 41 and a manifold 47 in fluid communication with a hydraulic fluid tank, the core area 40 being located between the vented front cover 13 and the backward curve centrifugal fan 50; the core area 40 further including: a straight vertical portion 41A extending in height less than an uppermost upper end 55 of the backward curve centrifugal fan 50; a straight horizontal portion 40C located above the uppermost upper end 55 of the backward curve centrifugal fan 50; and a curved portion 40C connecting the straight vertical and horizontal portions 40A, 40C, the curved portion 40B having a center point “C” and a radius “R”; where C is located above c and R is greater than r. The cooler 10 may be adapted for use with an agricultural pumper truck.
This application claims priority to U.S. Provisional 63/251,975 filed Oct. 4, 2021.
| Number | Date | Country | |
|---|---|---|---|
| 63251975 | Oct 2021 | US |
