Automatic tire pressurizing system

A tire pressurizing system is provided for automatically pressurizing a pneumatic tire. The system employs centrifugal force to actuate a pump which is attached to the interior of the tire. Centrifugal force causes a pump actuating member to follow a different orbital path around a rotating tire from the path of the pump housing, which is attached to the tire. The difference is due to the flexing of the tire in the load bearing "footprint" area. The result is reciprocation of the actuating member, which in turn operates a pump. Piston and diaphragm pump embodiments are disclosed. An automatic pressure regulator is also provided.

BACKGROUND OF THE INVENTION 
This invention relates generally to a system for inflating and for 
maintaining the inflation of pneumatic tires and more specifically to an 
automatic tire inflation system which requires no outside source of 
pressurized air. 
Pneumatic tires have a maximum service life and provide the best vehicular 
handling and safety when properly inflated. While the procedure for 
checking tire pressure and adding additional pressurized air when required 
is relatively simple, it is frequently neglected to the detriment of the 
consumer. Furthermore, during intervals between pressure checks, tires 
will lose a certain amount of pressure. It would therefore be desirable to 
have an effective system for continuously and automatically monitoring and 
maintaining the air pressure in pneumatic tires. 
Previous attempts have been made to provide automatic tire inflators. Prior 
art devices generally consist of pumping mechanisms disposed within the 
tire which are operated by the compression or flexing of the tire. A lever 
arm is often provided in such devices, extending across the tire either 
laterally or radially to operate a pump. The usual experience with these 
prior art pumping systems is that the constant impact from contact between 
the lever arm and the tire quickly damages both the tire and pumping 
mechanism. Many prior art devices are also overly complex or require 
highly specialized attachment or bellows arrangements to function. 
Examples of prior art tire inflators are found in U.S. Pat. Nos. 939,020; 
1,029,340; 1,327,371; 1,456,567; 2,021,646; 2,420,224 and 4,269,252. 
It would be advantageous to have an automatic tire inflator which is simple 
and rugged and operates without damaging impact between the inflator and 
the tire. It would also be advantageous to have such a tire inflator which 
will automatically stop operating when the correct tire pressure is 
reached. It would also be desirable to have a tire inflator which is light 
in weight and easily installed in a pneumatic tire. 
SUMMARY OF THE INVENTION 
Accordingly, tire pressurizing means is provided for use with pneumatic 
tires. The tire pressurizing means comprises a pump housing and means for 
attaching the pump housing to the interior surface of a tire at a location 
adjacent the exterior road contact surface of the tire. A conduit is 
provided for supplying air from outside the tire to the pump housing. A 
pump within the pump housing serves to draw air through the conduit and 
pressurizes the air for delivery to the interior of the tire. The pump 
includes an actuating member responsive to the centrifugal force caused by 
tire rotation to actuate the pump. The actuating member is supported for 
movement relative to the pump housing in a direction generally radial with 
respect to the tire, between a radially inward first position and a 
radially outward second position. First biasing means are provided for 
urging the actuating member toward the first position while yielding to 
centrifugal force acting to urge the member toward the second position. 
The result is that the actuating member will tend to follow a different 
orbital path from that of the pump housing when rotating inside a tire 
having a flattened load bearing portion on its periphery. As such, the 
forces acting on the actuating member during tire rotation will alternate 
between centrifugal force moving the actuating member toward the second 
position and the first biasing means returning the actuating member toward 
the first position. The reciprocations of the actuating member will 
thereby serve to actuate the pump and pressurize the tire. 
The invention also encompasses a method of pressurizing a pneumatic tire 
using pump means incorporated in a pump housing and actuated by an 
actuating member movable relative to the pump housing for pressurzing air. 
The method comprises steps which include attaching the pump housing to the 
interior surface of a tire at a location adjacent the exterior road 
contact surface of the tire. A supply of air is provided from outside the 
tire to the pump means. The actuating member, which is movable to actuate 
the pump means, is oriented for movement in a direction generally radial 
with respect to the tire between a radially inward first position and a 
radially outward second position. The actuating member is urged toward the 
first position using yieldable first biasing means such that the actuating 
member will be free to respond to the action of centrifugal force urging 
the actuating member toward the second position during tire rotation. The 
method includes permitting the member to follow a different orbital path 
due to centrifugal force from that of the pump housing, when rotating 
inside a tire having a flattened load bearing portion on its periphery. As 
a result, forces acting on the actuating member during tire rotation 
alternate between centrifugal force moving the actuating member toward the 
second position and the first biasing means returning the actuating member 
toward the first position. The result is reciprocation of the actuating 
member, which actuate the pump means and pressurize the tire.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring to FIG. 1, the tire pressurizing means of the present invention 
includes a pump housing 10 which is attached to the inside of a pneumatic 
tire 12. The pump housing 10 preferably includes an attaching base 14 
which can be conveniently molded into the inside surface 16 of tire 12. 
Housing 10 could alternatively be attached to the tire by other means, but 
whatever attaching method is used must be capable of withstanding high 
stress and vibration without loosening. The housing 10 should be attached 
on the interior surface of the tire at a location adjacent the road 
contact surface (tread) 18. That location is the farthest outward, 
radially, from the center of the tire and consequently subjects the pump 
mechanism in housing 10 (described below) to the maximum centrifugal 
force. 
The present invention makes use of centrifugal force to actuate a 
pressurizing pump, as illustrated in FIG. 2. Described in greater detail 
below, the basic principal of operation of the pump involves harnessing 
the centrifugal force acting on a small mass 20, called an actuating 
member. The actuating member is held radially inward in housing 10 by a 
spring or other biasing means 22. As the tire rotates, the housing 10 and 
actuating member 20 acquire inertia developed by centrifugal force. When 
the tire is load bearing, meaning it supports the weight of a vehicle or 
the like, it will have a flattened portion 24 on its periphery where the 
tire contacts the road surface. That flattened or load bearing portion 
(hereinafter called the "footprint"), is indicated in FIG. 2 by segment 24 
of tire 12. As pump housing 10 orbits the tire and enters footprint 24, 
the centrifugal force on the housing is nullified. The centrifugal force 
acting on actuating member 20 will cause the actuating member to continue 
following its original orbital path within housing 10. In a vehicle moving 
to the left in FIG. 2, the relative positions of housing 10 and actuating 
member 20 before they reach footprint 24 is shown at "A." As the footprint 
is entered, housing 10 is deflected from its orbital path and actuating 
member 20 begins to move downward within the housing, as shown at "B." The 
actuating member is, in effect, attempting to follow its original orbital 
path and is carried downward by inertia in the housing until stopped at 
"C." When the centrifugal force on actuating member 20 is finally 
nullified, the force of spring 22 will return the actuating member to its 
original position, as shown at "D." The different orbital paths followed 
by housing 10 and actuating member 20 results in the motive force which 
operates the tire pressurizing pump of the present invention. 
FIGS. 1, 3 and 4 illustrate in greater detail the elements of the pump. A 
conduit 26 is connected between pump housing 10 and tire valve stem 30. 
The conduit carries air from outside the tire to the pump and is 
preferably formed of a non-collapsable material. The valve stem 30 shown 
in FIG. 3 is a modified form of a conventional valve stem. In addition to 
a conventional tire valve (not shown), valve stem 30 includes a fitting 32 
for the connection of one end of conduit 26, and a check valve 34 for 
permitting one-way flow of air into conduit 26. A passage 36 in the body 
of valve stem 30 admits air from outside the tire to the inlet side of 
check valve 34, which can be a conventional ball valve. Air enters passage 
36 through openings (not shown) in a valve cover 38, passing through 
filter material 40, which prevents particulate matter from entering. Valve 
stem 30 is mounted in the conventional manner in an opening 42 in tire rim 
44. A hex nut 46 can be used to secure the valve stem 30 to the rim. 
The other end of conduit 26 is connected to an air inlet 48 on pump housing 
10 (FIG. 4). Air inlet 48 includes a one-way check valve 50, such as a 
ball-type valve, which allow outside air to enter pump housing 10. Pump 
housing 10 is divided into first and second pump chambers, 52 and 54, 
respectively. In the embodiment of FIG. 4, actuating member 20 is a piston 
which separates the first and second pump chambers. Air coming into the 
pump housing through conduit 26 enters first pump chamber 52, which is the 
low pressure side of the pump. 
Actuating member 20 is movable relative to the pump housing in a direction 
generally radial with respect to tire 12. The actuating member is urged 
toward its radially inward position, termed the first position, at the top 
of the housing in FIG. 4, by a first biasing means such as spring 22, as 
was discussed with reference to FIG. 2. Spring 22 forces actuating member 
20 against upper stop 58. Only when centrifugal force is sufficiently 
strong to overcome the force of spring 22 will the actuating member move 
away from stop 58, as shown in FIG. 4, and at "B" in FIG. 2. The radially 
outward position of actuating member 20, termed the second position, is 
illustrated at "C" in FIG. 2, and represents the maximum downward travel 
of actuating member 20, where it rests against lower stop 60. 
Air flows between first and second pump chambers 52 and 54 through a 
passage 62 extending between the chambers. In the preferred embodiment 
passage 62 extends through the body of actuating member 20. A one way 
check valve 64, termed a first valve means, controls the air flow in 
passage 62, permitting air to flow only from chamber 52 to chamber 54. An 
outlet port 66 permits the flow of air from chamber 54 into the interior 
of tire 12. The chamber 54 serves as the high pressure side of the pump. 
Pumping of air to pressurize the tire is accomplished in the following 
manner, using the motion of actuating member 20 described above with 
reference to FIG. 2: When centrifugal force causes actuating member 20 to 
move downward (as viewed in FIG. 4) against the force of spring 22, the 
volume of first pump chamber 52 is increased, lowering the pressure 
inside. The partial vacuum draws air into chamber 52 through conduit 26 
and through valves 34 and 50. The downward force of actuating member 20 
also forces the air in chamber 54 out into the tire interior through 
outlet 66. When the centrifugal force is nullified, spring 22 begins to 
force the actuating member to the top again, compressing the air in 
chamber 52. At the point where the air pressure in chamber 52 equals the 
pressure in chamber 54, check valve 64 opens, as shown in FIG. 5, and air 
in chamber 52 moves to chamber 54. The pump is then ready for another 
cycle. Valve 50 prevents the air in chamber 52 from escaping through 
conduit 26, thus air is pressurized and pumped into the tire. In addition, 
as the actuating member moves upward, the air in chamber 54 will be 
cooled, due to decompression, preventing overheating of the pump. 
In order to prevent overpressurizing tire 12, a pressure regulator is 
provided for halting the operation of the pump when a selected ambient 
pressure is reached. In the embodiment of FIG. 4, the pressure regulator 
is of the diaphram type, indicated generally at 70. Pressure regulator 70 
includes a latch piece 72 which is movable laterally with respect to 
actuating member 20. FIG. 4 illustrates the latch piece in its nonengaging 
position, retracted out of the path of actuating member 20. Spring 74 and 
detent means 76 hold the latch piece in the retracted position until the 
ambient pressure reaches a selected limit, determined by the force of 
spring 74. An orifice 77 admits ambient air from inside the tire against 
diaphram 78. To protect against leakage of pressurized air around latch 
seal 79, a pressure release conduit 80 can be connected to conduit 26 to 
maintain low pressure behind diaphram 78. When the pumping action of the 
tire pressurizer increases the tire pressure sufficiently, the pressure 
against diaphram 78 will overcome the force of spring 74 and detent 76 and 
latch piece 72 will move rightward to its engaging position. If actuating 
member 20 is in its second position, latch piece 72 will engage notch 82, 
preventing substantial movement of the actuating member. If actuating 
member 20 is not in its second position, latch piece 72 will engage cam 
surface 84 and subsequently engage notch 82 on the next downstroke. The 
actuating member will remain locked and the pump inoperative until the 
ambient tire pressure decreases sufficiently to allow latch piece 72 to 
return to its non-engaging position. 
An alternative form of pressure regulator is shown in FIG. 6. This pressure 
regulator 86 employs a piston in place of diaphram 78. Piston 88 is 
connected to latch piece 72 and serves to move it to its engaging position 
when the ambient pressure against the piston is sufficient to overcome the 
force of spring 90. 
FIG. 7 shows an alternative embodiment of a tire pressurizer, employing a 
diaphram-type pump. In this embodiment a flexible diaphram 100 separates 
first and second pump chambers 102 and 104, respectively, in pump housing 
10. The pump housing 10 is attached to tire 12 at base 14 in exactly the 
same manner as the previous embodiment. Actuating member 20 is attached to 
diaphram 100 and moves with the diaphram between a radially inward first 
position, shown in FIG. 7, and a radially outward second position. As in 
the embodiment of FIG. 4, the actuating member moves in a direction which 
is generally radial with respect to tire 12. The forces acting on 
actuating member 20 in the diaphram pump of FIG. 7 are the same as those 
described with respect to FIG. 2. A biasing spring 106 serves to urge the 
actuating member toward the upper position and centrifugal force urges the 
actuating member toward the lower position, against stop 108. 
To pressurize a tire, air supplied through conduit 26 enters chamber 102 
when the actuating member moves downward under the influence of 
centrifugal force. Simultaneously, air in chamber 104 is pressurized and 
forced into the tire through an outlet (not shown). When the actuating 
member returns to its first position, air in chamber 102 passes through 
passage 62 and check valve 64 into chamber 104 in the manner shown in FIG. 
5. 
An alternative type of pressure regulator is illustrated for use with the 
embodiment of FIG. 7. Pressure regulator 110 is a pressure responsive 
valve which admits ambient pressure from the interior of the tire into 
upper pump chamber 102 when a selected ambient pressure is reached. The 
pressure at which that occurs is determined by the strength of internal 
spring 112 which holds the valve closure 114 closed. Once pressurized 
ambient air is admitted into chamber 102, the movement of actuating member 
20 is halted. Only when the tire pressure falls below the selected 
pressure and valve 114 closes does pumping action resume. 
Both the piston and diaphram embodiments of the present invention offer 
significant advantages over prior art tire inflators. Because the power 
source is centrifugal force, the actuating member can be entirely enclosed 
in the pump housing, without the need for linkages or the like. Only one 
point of attachment to the tire is necessary, greatly simplifying 
installation. Although air is drawn in through a special passage in the 
valve stem to the pump of the present invention, it is also possible to 
use the conventional valve stem to pressurize the tire from an outside 
source of pressurized air. Thus, the system is highly flexible and 
convenient. Furthermore, the system employs a minimum of moving parts and 
can be inexpensively made in a manner which is both lightweight and 
rugged. 
Alternative embodiments are possible within the scope of the invention. 
Different types of biasing means and pressure regulators will occur to 
those skilled in the art, for example. 
The invention provides an automatic tire inflator that is simple and rugged 
and operates without damaging impact between the inflator and the tire. 
The inflator automatically stops operating when the correct tire pressure 
reached. The inflator is also light in weight and easily installed in a 
pneumatic tire.