Field of the invention

The present invention relates to primers for marine engines and more particularly to a rigid primer bulb pump that does not emit any hydrocarbons. Description of the Prior Art

Outboard mounted spark ignition marine engines used on stern drive boats currently employ a semi-rigid rubber primer bulb type pumping device to provide initial prime to the fuel supply system. These devices are simply rubber bulbs mounted on fuel hoses usually equipped with a set of one-way valves to direct the direction of pumping when the bulb is squeezed.

This type of prior art device, by nature of its makeup and material, is generally permeable. Because of that, it releases a small percentage of the hydrocarbons that pass through it into the atmosphere. It is very undesirable to pass any fuel hydrocarbons into the atmosphere since that represents a source of pollution and may violate future government regulations. It would be advantageous to have a primer for outboard mounted engines that was made from a rigid polymer and avoided this shortcoming by not allowing leakage or permeation of hydrocarbons into the atmosphere.

SUMMARY OF THE INVENTON

The present invention relates to a hand operated primer pump for small marine or other engines generally spark ignition engines used on stern drive boats that prevents transfer of hydrocarbons into the atmosphere. The primer of the present invention generally mimics and replaces prior art rubber primer bulbs in general shape and possibly color, although it can be made in any shape or color. It is generally made from rigid or semi-rigid polymer material. The primer of the present invention contains a pump that delivers a precise measured amount of fuel with each stroke of the actuator. The present invention can have an ergonomically designed actuator that creates the farthest distance from a fulcrum point for maximum leverage and hence, maximum ease of use. The primer of the present invention is designed to tightly fit together to seal any source of hydrocarbon leakage and generally to use a continuously molded fuel path as well as being made from materials that prevent transfer of hydrocarbons to the atmosphere.

DESCRIPTION OF THE FIGURES

Attention is directed to several illustrations that aid in understanding the present invention:

Fig. 1 shows a side view of an embodiment of the present invention.

Figs. 2A-2C show a side view, top view and rear end view of the embodiment of Fig. 1.

Fig. 3 shows a side sectional view of an embodiment of the present invention.

Fig. 4 shows an exploded view of the embodiment of Fig. 3.

Fig. 5 shows an exploded side view of the piston guide, piston and seal from Fig. 4.

Several drawings and illustrations have been provided to help understand the invention. The scope of the present invention is not limited to what is shown in this figures. DESCRIPTION OF THE INVENTION

The priming system of the present invention uses a hand squeeze or thumb press operation to pump fuel in one direction through the device by means of a piston pump 1 shown in Fig. 1. A supply hose 2 runs to a fuel tank to supply fuel to the system. An exit hose 3 runs to the engine. A hand or thumb squeeze actuator 4 is mounted on the top of the pump 1 and delivers a precisely measured amount of fuel to the engine when it is squeezed. While the pump is in the relaxed position, the engine can draw fuel through it from the tank in normal operation.

Figs 2A-2C show a side view, top view and rear end view of the embodiment of Fig. 1. A rear entrance orifice 5 and a front exit orifice 6 can be seen. Fuel hoses generally attach to these orifices. The actuator 4 is generally located at the top of the device and can be captured at a lower extremity on each side at two pivot points. The pivot points on the actuator 4 can be holes that correspond to a pair of protrusions molded onto the top of the lower fuel path section of the pump body 1. The actuator 4 can sit directly on top of a cup shaped piston guide, which in turn fits onto the outside surface of the generally cylindrical piston housing protruding extremity at the top of the pump body. The piston is either directly or indirectly affixed to a seal which is positioned inside the pump body cylinder bore facing downward towards the fuel path in the lower section of the pump body. A spring placed under tension between the piston assembly and a corresponding cylindrical cup shaped recess that can be molded in the lower extremity of the pump body.

Fig. 3 and Fig. 4 show a side sectional view and an exploded view of an embodiment of the pump mechanism of the present invention. Fuel enters the entrance orifice 5 in a molded entry fitting 13a where it encounters a entry check plunger 7a. A continuous channel connects the rear part of the pump to the front part allowing fuel to pass through the pump chamber 9 when the pump is in the relaxed position (as shown in Fig. 3). At the front of the pump, fuel can flow out through an exit check plunger 7b into an exit orifice 6 in a molded exit fitting 13b. The rear and front check plungers 7a, 7b act as oneway valves that prevent any reverse fuel flow during pumping. The check plungers 7a, 7b are facing in the same direction with a dome towards the direction from which the fuel will enter the pump body. The molded fittings 13a and 13b have a molded valve seat that corresponds to the domed end of the check plunger 7a or 7b.

The pump priming system of the present invention is designed primarily for a human hand to squeeze; however, it can be depressed by thumb, foot or other body extremity to cause the actuator 4 to depress by lever action around a fulcrum point and cause a piston guide 8 and piston assembly to displace the internal volume of mass in the pump cylinder bore.

The pump actuator 4 pushes a piston 12 downward against a spring 10 when squeezed by means of a piston guide 8 attached to the actuator. The piston 12 pushes a seal 11 down into the pump chamber 9 causing the amount of fuel in the pump chamber to be forced out of the exit orifice 6 through the exit check plunger 7b. The volume of fuel in the bore travels into the fuel path underneath the cylinder. When the pump actuator 4 is released, the spring 10 causes the piston 8 and seal 11 to return to their relaxed position as shown in Fig. 3. However, as the piston and seal return upward, they draw a quantity of fuel in from the entrance orifice 5 through the entrance check plunger 7a. As previously stated, the entrance and exit check plungers 7a, 7b act as one-way valves allowing the pumping action to take place and not permitting any fuel flow in the opposite direction.

Fig. 4 also shows a possible construction of the pump using a pump central body 16, a left side housing 14a, a right side housing 14b and a molded check seat 15 to receive the exit check plunger 7b. The molded fittings 13a and 13b can optionally be identical for ease in manufacture. The left and right side housings 14a, 14b each can form a half-shell the fit together around the pump central body 16 and check plungers 71, 7b.

Fig. 5 shows a side exploded view of the relationship between the piston guide 8, the piston 12 and the seal 11.

As previously stated, the primer pump of the present invention can mimic current rubber primer bulbs in shape and color, although it can be made rectangular, tubular or any other shape and can be designed to be attached to a fuel tank, a marine engine or be mounted in-line with the fuel hose. The preferred material for the body of the present invention is polybutylene terephthalate (PBT), polycarbonate, polycarbonate PBT (PC/PBT) Nylon 6, acetal (acetyl), polyethylene's with nano-sized platelets that act as a hydrocarbon barrier or any rigid polymer material that meets federal low permeation standards of less than 15 g/sq. m./day. A preferred material is a polymer with an embedded layer of carbon or other platelet particles that prevent hydrocarbon transfer. Acetal is also a preferred material. The material used must generally be capable of being molded into components for assembly. It is essential that the molded components to either have no seams or to fit together in such a way that there is no leakage or transfer of hydrocarbons at any seams.

U.S. Government rules for marine fuel system hydrocarbon emissions are 0.4 g/gallon/day for diurnal venting from a fuel tank at 35.6 degrees C; 1.5 g/gallon/day permeation from a fuel tank at 40 degrees C; and 15/g/sq. meter/day for hose and primer bulb permeation at 23 degrees C (15 g/sq. meter/day with 15% methanol blend fuel). A test fuel of 10% ethonol and 90% indolene can be used for normal testing. The final primer assembly should meet these requirements. Acetal generally has a permeation of around 1.2 g/sq. meter/day, so for a fuel path with a surface area of around 10.6 sq. inches (0.00684 sq. m) for example, the total emission for the pump would be around 0.0082 g/day.

The primer spring can be made from stainless steel or from a polymer with the ability to compress and expand sufficiently to provide sufficient force. The seal can be made from a low permeation elastomer such as VITRON (TM) manufactured by DuPont Dow.

The primer pump of the present invention is made from several molded parts as has been described. These parts are together into a finished unit so that the final product meets permeation requirements. In particular, in a preferred embodiment, the fuel path is a continuous molded unit from the entry hose to the exit hose. The only opening is around the pump seal 11 and, of course, where the fuel lines terminate. The pump seal can be made from a low permeation elastomer as previously explained to keep hydrocarbon emission within limits. While the primer of the present invention is intended primarily for fuels, it can also be used in any type of suction application such as the suction and delivery of any oils or other fluids needing priming, and particularly in the suction and delivery of any fluid needed to prime a fluid circuit, or pump fluid from a reservoir to another place.