The present invention relates generally to gears used in pumps, and more particularly, to gears of positive displacement gear pumps.
Standard gear pumps work well with thick (or high viscosity) fluids because of a large cavity volume allowing the thick fluid to easily flow into the pump. The clearances between the gears and housing do not have a significant effect on pumping efficiency when pumping thick fluids as the fluid tends to ‘seal’ the clearances resulting in high pumping efficiency. When pumping thin (or low viscosity) fluids, the clearances between the gears and the housing on standard gear pumps allow the thin fluids to ‘leak’ between the gears and housing during pumping. Therefore, standard gear pumps are relatively inefficient for thin fluids.
By contrast, thin fluids are pumped efficiently by regular vane pumps due to the constant contact of vanes with the housing. However, standard vane pumps do not handle thick fluids well because the swept volume of the pump is small, which restricts the inflow of the thick fluid into the pump. Additionally, the vanes tend to become clogged by the thick fluid preventing them from sealing.
The following detailed description refers to the accompanying drawings. The same reference numbers in different drawings may identify the same or similar elements.
Exemplary embodiments for a pump fluid driving apparatus are described with reference to
Pumps optimized for a particular environment may be damaged or underperform in an environment with fluids having different properties, such as an environment that includes alternating volumes of thick fluids and thin fluids. The combination of gear teeth with vanes and regular (or solid) gear teeth, as described herein, provides a pump that can handle thick and thin fluids efficiently. The vanes provide a contact seal with the housing for efficiently pumping thin fluids. Thick fluids may present clogging issues for the gear teeth with vanes. However, if the vanes become clogged, the large cavity volume and larger clearances between the solid gear teeth allow for efficient pumping of the thick fluid and thereby avoid clogging problems.
Other advantages, characteristics and details of the invention will emerge from the explanatory description provided below with reference to the attached drawings and examples, but it should be understood that the present invention is not deemed to be limited thereto. To that end,
Spaced apertures 24 register with the inlet 26 and the outlet 28, with the inlet 26 being open to an inlet passage of the pump, and the outlet 28 being open to an outlet passage of the pump. Gear chamber 14 is closed on its front and rear side for a fluid-tight seal within housing 12 in this example, as understood by one skilled in the art.
Referring to
Gears 30 and 32 have peripheral teeth 38 and 40 that intermesh so that the rotation of one of the gears, for example, gear 30 that may be linked to a pump motor, causes rotation of the other gear. Teeth 38 and 40 of gears 30 and 32 may have uniform sizes, and are machined to intermesh for all angular positions in a rotation of the gears. In one implementation, each gear 30 and 32 has slotted teeth 38 and solid teeth 40 arranged with uniform spacing in a repeating pattern about the periphery. In this example of a twelve-tooth gear, each slotted tooth 38 is separated by two solid teeth 40. In other implementations, more or fewer teeth 38, 40 may be used in different arrangements. For example, in another implementation, an eight- or ten-tooth gear may be used with an equal number of alternating slotted teeth 38 and solid teeth 40. In still another implementation, the arrangement of slotted teeth 38 and solid teeth 40 may be asymmetrically arranged around the about the periphery of gear 30 or 32. As one example, regardless of the number of total teeth in each gear, slotted teeth 38 may make up no more than half of the total number of teeth for gear 30 or 32. In another implementation, slotted teeth 38 may make up no more than one third of the total number of teeth for gear 30 or 32. In still another implementation, all of the teeth in gears 30 and 32 may be slotted teeth 38. The uniform size and spacing of slotted teeth 38 and solid teeth 40 may permit different angular orientations of gears 30 and 32, which may provide for simplified installation, and may provide improved wear/noise characteristics (e.g., over geared systems with non-uniform teeth spacing) for pump fluid driving apparatus 10.
Teeth 38 and 40 may be formed to provide a profile with a radius or curvature nearly equal to the radius or curvature of rounded wall sections 20, 22. However, the radius of rounded wall sections 20, 22 may be slightly greater than the radius of gears 30, 32 to, for example, provide radial clearance between gears 30, 32 and respective rounded wall sections 20, 22. It is also noted that gears 30, 32 are provided with identical gaps 42 between each of adjacent teeth 38 and 40.
Still referring to
As shown in
It is also understood that extendable vanes 44 are not required to actually contact the surface of the tooth gap 42 of the adjacent gear 30 or 32 during rotation. In particular, the extension length of vanes 44 beyond the tips of slotted teeth 38 and the depth and shape of tooth gaps 42 can be designed so the end of vane 44 never contacts the surface of the tooth gap when the gears 30, 32 mesh for spatial clearance between the vanes and tooth gaps. As described further below, gears 30 and 32 may have either straight spur teeth or helically oriented teeth (
Preferably housing 12, and gears 30, 32, are made of metal or other hard durable material. For example, gears 30, 32 may preferably be made of stainless steel. In other implementations, housing 12 may be made from plastics. Vanes 44 may be made of an engineered plastic, metal, a resin, rubber, polypropylene, or other materials. Springs 48 may be formed of a metal, such as stainless steel, or other materials, such as plastic, both strong and resilient to function as a biasing member.
As can be seen in
To further maintain a balance bias against piston 62, main body 80 may be provided with a tunnel 70 providing fluid communication between gear chamber 14 and a spring chamber 72 that houses spring 60. Under pressure (e.g., during pump operation), fluid from gear chamber 14 may be forced under pressure into spring chamber 72 to thereby hydraulically activate piston 62 into floating side plate 52 and further maintain a tight fitted relationship between floating side plates 50, 52 opposite gears 30, 32. When the pumping operation ceases, the relaxation of fluid pressure in tunnel 70 and spring chamber 72 allows a relaxation of the bias against floating slide plate 52, which may allow a cover 74 of the housing 12 to be safely removed for access to gear chamber 14. However, it is beneficial that during use, the heightened fluid pressure provided during the pumping operation urges floating side plates 50, 52 together to seal off lateral slip paths on the sides of gears 30, 32.
Housing 12 preferably includes cover 74 and a main body 80. While not being limited to a particular implementation, main body 80 may be a one-piece body (
As can be seen in
Still referring to
Tunnel 70 is a passageway connecting chambers 96, 72 behind pistons 98, 62 to the discharge side of the pump. As discussed above with piston 62, higher liquid pressure on the discharge side of the pump is transmitted through tunnel 70 to hydraulically actuate piston 100 and further maintain a tight fitted relationship between floating side plates 50, 52 opposite gears 30, 32. While not being limited to a particular theory, gear shaft 34 is a drive shaft extending out of the housing 12 for coupling to the pump motor. A grommet 104, preferably made of a resilient material (e.g., rubber, polypropylene, plastic, resin) or a mechanical seal, is fitted within housing 12 about gear shaft 34 for providing a liquid seal.
In implementations described herein, a pump fluid driving apparatus includes a housing having a chamber, with two gears mounted within the chamber. The housing includes a first rounded wall section and a second rounded wall section, the first and second rounded wall sections defining at least a portion of the chamber. The gears have teeth located about their respective peripheries and operatively positioned with the teeth of the first gear and the teeth of the second gear intermeshed for all angular positions. The teeth include slotted teeth and solid teeth, each of the slotted teeth and solid teeth having a same profile along a right flank and a left flank, with each of the slotted teeth having a vane slot with an opening at the tip of the slotted tooth and a radially extending vane extending from the vane slot, each radially extending vane being movable within the respective vane slot and being configured to contact the respective first or second rounded wall sections.
The foregoing description of exemplary implementations provides illustration and description, but is not intended to be exhaustive or to limit the embodiments described herein to the precise form disclosed. Modifications and variations are possible in light of the above teachings or may be acquired from practice of the embodiments.
Although the invention has been described in detail above, it is expressly understood that it will be apparent to persons skilled in the relevant art that the invention may be modified without departing from the spirit of the invention. Various changes of form, design, or arrangement may be made to the invention without departing from the spirit and scope of the invention. Therefore, the above-mentioned description is to be considered exemplary, rather than limiting, and the true scope of the invention is that defined in the following claims.
No element, act, or instruction used in the description of the present application should be construed as critical or essential to the invention unless explicitly described as such. Also, as used herein, the article “a” is intended to include one or more items. Further, the phrase “based on” is intended to mean “based, at least in part, on” unless explicitly stated otherwise.
This application claims priority under 35 U.S.C. § 119, based on U.S. Provisional Patent Application No. 62/446,928 filed Jan. 17, 2017, the disclosure of which is hereby incorporated by reference herein.
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Number | Date | Country | |
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20180202437 A1 | Jul 2018 | US |
Number | Date | Country | |
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62446928 | Jan 2017 | US |