CROSS-REFERENCE TO RELATED APPLICATIONS None.

STATEMENT OF FEDERALLY SPONSORED RESEARCH AND

DEVELOPMENT

None.

FIELD OF THE DISCLOSURE

The present disclosure relates generally to a venting device system and method for venting a reciprocating device assembly. BACKGROUND

Reciprocating device assemblies can include one or more fixed pathways to vent fluid within a reciprocating device chamber at a specific point during operation of the reciprocating device. The pathways generally address unwanted pressure generated in the chamber during operation of the reciprocating device.

US Patent No. 9,080,710; and 5,735,314 each address various pathways incorporated into a piston assembly to vent the chamber during operation. For example, US Patent No. 9,080,710 discusses an accumulator reservoir including a multitude of paths that can and will operate in parallel and provide an interconnected network of vent flows. US patent 5,735,413 discusses a dampening diaphragm enclosing a damping chamber into which a throttle bore discharges through the housing end wall.

US Patent No. 2,222,811 discusses a breast pump assembly having a disc-like flanged sealing ring clamped to a top of a piston head by a metallic disc. The flanged sealing ring is formed by a leather disc having an out-turned flange that surrounds an endless spiral spring, and by the natural expansion of the latter, is yieldingly held in contact with the walls of the cylinder. Under upward or inward movement of the piston, air caged in the cylinder will find relatively free escape therefrom past the flexible flange of the piston ring, especially at or in line with the flattened portion. The device works without the use of any check valve in any of the air passages to or from the cylinder. However, additional space is required within the cylinder to accommodate the height of the flanged sealing ring above the piston. SUMMARY

In accordance with the principles of the present disclosure, a venting device system of a reciprocating device assembly that eliminates the disadvantages of the previous systems, is set forth. A more compact and efficient assembly can thus be achieved in accordance with the principles herein. Moreover, a system configured to provide an improved flow path for venting a reciprocating device assembly is provided, in accordance with the principles herein.

A wide variety of embodiments are contemplated, and can be constructed in accordance with the principles herein to provide an improved flow path via an improved venting device system while generating fluid pressure in the system.

Although exemplary embodiments are set forth to illustrate the basic advantages of the improvements achieved in accordance with the principles herein, numerous other embodiments are contemplated that achieve a flow path that does not require either structure positioned above a head of the reciprocating device during operation or a fixed vent. For example, in one exemplary embodiment the flow path can vary due to movement of a component, such as a seal or sealing member. The component can move a venting device system, from an open vent, during a return stroke of a reciprocating device, to a closed vent, during a pressure generating stroke of the reciprocating device. The venting device system can be configured in any suitable arrangement to include at least one selectively sealing component, or seal that can be movable or bendable during operation of the reciprocating device to form a variable air flow path, while moving through the reciprocating device assembly. For example, the venting device system can be configured to include a seal that can move and seal the reciprocating device during a pressure generating stroke of the reciprocating device. In an exemplary embodiment, the venting device system can be configured to include a seal that travels back and forth relative to the reciprocating piston assembly head components during operation, where the venting can be tuned based on movement of the seal relative to the reciprocating device, and/or other parameters of the reciprocating device assembly. As a result the venting device system can improve the efficiency of the movement of the reciprocating device by improving the distribution of fluid within a chamber of the reciprocating device assembly during operation.

In yet another exemplary embodiment, the venting device system can include a deformable seal, incorporated in any suitable manner, into the design of the reciprocating device, for example by integrally forming the seal with a head of the reciprocating device, so that the function of the venting device system is an integral part of the reciprocating device. In other exemplary embodiments, the venting device system can include a seal partially formed in the reciprocating device and partially formed as a separate or connectable component to the reciprocating device. In still other exemplary embodiments, the venting device system can include a seal that moves relative to a sealing section of a reciprocating device, such that no direct connection exits continually between the reciprocating device and the seal during operation. Suitable variations and combinations of the examples set forth herein are contemplated as well.

In accordance with the principles of the present disclosure one exemplary embodiment can include a breast pump assembly having a venting device system including a seal selectively connectable to or integrally formed in a head of a reciprocating device. The seal of the venting device system can be disposed below the top of the head of the reciprocating device. The seal of the venting device system can be configured to selectively move, based on forces present in the system during operation of the reciprocating device.

In an exemplary breast pump assembly, the venting device system can be configured to seal the reciprocating device during a pressure generating stroke and to vent the assembly during a return stroke. The breast pump assembly can further include a chamber, wherein the venting device system further eliminates unwanted pressure in the chamber of the assembly during operation without affecting pressure creation in the chamber during a pressure generating stroke of the assembly. The venting device system can be configured of one or more materials, including a deformable material and/or a sealable material.

In yet another embodiment constructed in accordance with the principles herein a medical device assembly can include a venting device system configured to move based on forces present in the assembly. The venting device system can be further configured to include a seal adapted to selectively engage a portion of a head of a reciprocating device below the top of the reciprocating device on a pressure generating stroke of the reciprocating device to substantially seal the reciprocating device within a chamber of the assembly.

In still another embodiment the venting device system can include a seal that movingly engages different parts of the head of the reciprocating device. The venting device system can be suitably disposed on, around or near the reciprocating member. For example, in an embodiment the venting device system can include a seal movably seated about an interior of a head of the reciprocating member. The venting device system can be configured to allow fluid to flow in an opposite direction from a direction of travel of a reciprocating device, given movement of the reciprocating device on a return stroke. The venting device system can be configured to include a seal that at least partially moves into a position to seal the reciprocating device during a pressure generating stroke of the reciprocating device.

An exemplary method of reducing unwanted pressure in a venting device system within a reciprocating device assembly can include the following steps: venting air from above a reciprocating device around a top of the reciprocating device on a return stroke with a seal disposed below the top of the reciprocating device; and sealing air below the top of the reciprocating device on a pressure generating stroke with the seal of the venting device system on a pressure generating stroke. The method can further include the step of configuring the seal of the venting device system to move from a first position substantially near the top of the reciprocating member on a pressure generating stroke to a second position displaced away from the first position, and disposed directly or indirectly against a surface of the reciprocating device on a return stroke.

Various advantages of the present disclosure are specifically described below in reference to the exemplary embodiments, or conceptually embodied therein. The drawings and description herein are provided to merely illustrate examples of the general concepts discussed throughout the present disclosure. Numerous changes and modifications can be made, as known to those of skill in the art, without departing from the general principles set forth herein. BRIEF DESCRIPTION OF THE DRAWINGS

These and other features and advantages of the various exemplary

embodiments disclosed herein will be better understood with respect to the following description and drawings, in which:

Figure 1 is a view, partially in section, of a venting device system including a reciprocating device assembly and a seal during a return stroke of a reciprocating device;

Figure 2 is a view, partially in section, of a venting device system including a reciprocating device assembly and a seal during a pressure generating stroke of a reciprocating device;

Figure 3 is a top view of an exemplary embodiment of a customized seal for a venting device system constructed in accordance with the principles herein;

Figure 4 is a side view of the exemplary seal of Figure 3 ;

Figure 5 is a bottom view of the exemplary seal of Figure 3;

Figure 6 is a front sectional view taken along lines VI- VI of the exemplary seal of Figure 3;

Figures 7 and 8 are exemplary embodiments of exemplary venting device system components including custom features to fine tune fluid flow in the system; and

Figure 9 is another embodiment of a venting device system including a magnetic drive mechanism formed of at least one magnet. Common reference numerals are used throughout the drawings and the detailed description to indicate the same elements.

DETAILED DESCRIPTION

The detailed description set forth below in connection with the appended drawings is intended as a description of certain exemplary embodiments of various system components constructed in accordance with the principles herein. These examples are not intended to represent the only embodiments or forms that may be developed or utilized according to these principles. It is further understood that the use of relational terms such as first and second, and the like are used solely to distinguish one entity from another without necessarily requiring or implying any actual such relationship or order between such entities.

Certain aspects of some embodiments constructed in accordance with the principles herein are directed toward a reciprocating device assembly having improved venting efficiency during operation.

It is understood that the systems described herein may be used to deliver a wide range of fluid contents to a wide variety of reciprocating device assemblies for delivering positive or negative pressure. Such contents will be collectively referred to herein as "fluid" for purposes of simplicity.

An exemplary embodiment of a venting device system including a reciprocating device assembly constructed in accordance with the principles herein is shown generally at 100 in Figure 1. A suitable reciprocating device 110 can be provided and the venting device system 100 can further include a seal 120 configured and arranged within the reciprocating device assembly 110 to seat in a first position A relative to the reciprocating device 110 during a return stroke of the reciprocating device 110 (in this example the reciprocating device assembly is oriented in an upright position, although numerous other orientations are contemplated and are within the scope of the present disclosure). In position A, the seal 120 provides a fluid path of a preselected height h, (shown here between a top of the seal 120 and a lower surface of a head 140 of the reciprocating device 110), determined to best meet the needs of a particular system. Thus, during the return stroke the seal 120 provides a fluid path that vents fluid from one side of the piston to an opposite position 140 in the reciprocating device assembly 110, illustrated here as disposed below the head 140 of the piston. Thus, Figure 1 shows an example of how a system constructed in accordance with the principles herein can provide a desired fluid flow path without requiring a fixed vent or an enlarged structure. The reciprocating device assembly 110 can further include a stem 150 for moving the head 140 back and forth in a chamber 160 of the venting device system. A suitable motor assembly 170 can be provided and connected either directly or indirectly to the chamber 160 and/or stem 150 to facilitate movement of the stem 150, if desired. One example of a suitable motor for certain applications is a gear motor. Other force driving motors or devices can be provided and selected based on desired system performance or to meet specific requirements, for example a piston driving device as described in Figure 9 below, or any other suitable device. The system illustrated in Figure 1 is a negative pressure generating system. Other systems, such as positive generating pressure systems, are

contemplated herein.

Figure 2 illustrates an exemplary embodiment of a venting device system shown generally at 200 and including a reciprocating device 210 and a seal 220. The seal 220 is shown seated in a different position relative to a reciprocating device assembly 210 compared to the position shown in Figure 1 during a pressure generating stroke of the system 200. As the direction of the reciprocating device turns so that the stem 250 moves due to the driving force of a suitable device or assembly 270 for the pressure generating stroke, the seal 220 can be configured to move, by the forces in the system via 270 or by any other suitable force or combination of forces, to a different position from the Position A of Figure 1 to a Position B in Figure 2. To this end, any suitable shape or materials can be used to form the seal 220, so long as the device seals the system during the pressure generation stroke. Additionally, an off the shelf seal may be suitable for certain applications. Any suitable material or combination of materials can be used to form the seal 220, including an elastic material, so long as the material can be configured to seal the system at the cylinder and the piston. From the Position B the seal 220 can expand toward an interior wall 265 of a chamber 260 of the venting device system 200 and substantially or fully seal the fluid above or below a head 240 (depending on whether the system is creating vacuum or pressure) of the reciprocating device 210 during the pressure generating stroke. As a result, a highly efficient pressure performance can be achieved in accordance with the principles herein.

Venting device systems constructed in accordance with the principles herein can include a selectively connectable sealing member in association with a reciprocating device assembly, that selectively seals the fluid in the chamber, either directly or indirectly as the seal in the system can be configured to float, either partially or fully, from position A to position B, or from a non-sealing position to a sealing position. A stem can be provided for moving the reciprocating device in a chamber of the system. The stem can be powered by any suitable device or configuration, as desired, to achieve output requirements of the reciprocating device assembly for a chosen system. The stem can be connectable to a suitable driving component of the system. Figures 3 through 6 illustrate various views of an exemplary embodiment of a custom seal of a venting device system constructed in accordance with the principles herein. Figure 3 illustrates a top view, Figure 4 illustrates a side view, Figure 5 illustrates a bottom view and Figures 6 illustrates front/back sectional views taken along VI- VI of Figure 3.

Figure 7 illustrates yet another exemplary embodiment including customized components constructed for use in a venting device system, wherein one or more customizable features can be provided, as desired, in order to fine tune the venting requirements of a particular system. Such customizable features can include, for example, a groove in a vented piston head 720, and at least one deformable seal portion 710. In this exemplary embodiment the seal portion 710 only partially moves in response to movement of the reciprocating member head 720. In yet another exemplary embodiment, shown in Figure 8, a rib or feature to seal and prevent leaking can be incorporated into an embodiment of a venting system 800 constructed in accordance with the principles herein. For example, a reciprocating head 810 can include a sealing feature, such as sealing feature 830, which can also provide a tortuous path on the sealing surface when mated with a custom seal 820 (also illustrated in Figures 3 to 6 above). The top of seal 820 and the reciprocating head 810 can be customized with any number of a variety of geometries in accordance with the needs of a given system. Additionally, any suitable geometry 840 can be selected in a lower head of the piston to help facilitate a desired air flow path.

As illustrated in Figure 9, a magnetically-driven venting device system, shown generally at 900, can include a chamber 910 and one or more magnets 930 to 960 selected to cooperate to move a reciprocating member 920. Here, one or more seals 970 can be incorporated into the system, as desired, to accommodate the requirements for a particular system. Many other embodiments are contemplated herein, and include customizing the pressure generating component of the system to improve fluid flow to vent the system during a return stroke while maintaining a compact pressure generating chamber, without directing the fluid through a head of the pressure generating component.

Exemplary systems wherein the principles herein can provide the

aforementioned advantages include, but are not limited to, breast pump assemblies, wound drainage and therapy devices, and other systems including reciprocating devices assemblies.

Variations of the specific exemplary device configurations shown and additional configurations constructed in accordance with the principles herein are within the scope of the principles of the present disclosure, and are included in all claims deriving therefrom.