Integral liquid pump and drainback valve

An integral liquid pump and drainback valve for use in pumping popcorn popping oil. A two-part housing is formed with one part having cavities forming inlet and outlet passages extending from an impeller cavity. A second part is formed with inlet and outlet ports and shuttle valve cavity connecting those ports. The inlet and outlet passages and the inlet and outlet ports respectively are in fluid communication with each other when the two parts are secured to each other. A resilient biasing means in the shuttle valve cavity moves the shuttle to a position wherein a fluid path is provided between the inlet and outlet ports when the pump impeller is not driven.

BACKGROUND OF THE INVENTION 
This invention relates to an integral liquid pump and drainback valve 
intended for use in pumping popcorn popping oil from a storage container 
to a popcorn popping kettle. In the production of large quantities of 
popped popcorn, popcorn popping oil is a critical ingredient which must be 
delivered in a predetermined quantity, along with the corn to be popped, 
to the popping kettle at the beginning of a popping cycle. 
This need has been met in the past by dispensing popcorn popping oil from a 
steel pail. A pump for pumping the oil to the popping kettle is placed in 
the pail through the open top of the pail. In the mass production of large 
quantities of popcorn, a series of independent poppers may be operated 
simultaneously with the popcorn popping oil being delivered by the pump to 
each of the plurality of poppers as they begin their respective cycles. In 
such a popping operation, a large quantity of popping oil must be readily 
available. 
To better meet these needs, an improved storage and metering apparatus for 
popcorn popping oil has recently been invented by the applicant for this 
patent. The improved storage and dispensing means includes a housing 
having inclined shelves upon which are placed rectangular boxes containing 
plastic bags filled with popcorn popping oil. The shelves support the 
boxes in a tilted position such that a dispensing connection provided at 
the bottom of the plastic bag, which may be extended through the box, is 
in a lowermost position such that all of the popcorn popping oil may be 
drained through the dispensing connection from the bag. The shelves are 
provided with thermostatically controlled electrical heaters so as to 
maintain the popcorn popping oil at a desired viscosity. A pump is 
provided for withdrawing the popcorn popping oil from the bags and supply 
it to a popping kettle located at a higher elevation than the bags. This 
improved storage and metering apparatus for popcorn popping oil is set 
forth in U.S. patent application Ser. No. 07/984,063, filed Nov. 30, 1992 
by the applicant and is assigned to C. Cretors & Company. The disclosure 
of the cited application, which issued on Apr. 12, 1994 as U.S. Pat. No. 
5,301,601, is incorporated herein by reference. 
As set forth in the cited patent application, the popcorn popping oil 
storage containers are mounted below the elevation at which the popcorn 
popping oil is supplied to the popping kettle. An elongated pipe or tubing 
is provided to deliver the popcorn popping oil from the pump discharge 
outlet to the popping kettle. Since popcorn popping oil may solidify at 
room temperatures, it is desirable that the popcorn popping oil not remain 
in the entire length of the pipe or tubing such that, upon cooling to room 
temperature, it would prevent or make much more difficult further pumping 
of the popcorn oil. To eliminate this problem, as disclosed in the 
above-mentioned patent application, a bypass path is provided between the 
inlet and discharge ports of the pump to permit the popcorn popping oil to 
drain back through the discharge pipe or tubing from the popcorn popping 
kettle to the supply container. When the pump is de-energized, a solenoid 
valve in the bypass path is energized and thereby opened to permit flow 
through the bypass path. Since the popcorn popping oil will flow back into 
the supply container until the level of the popcorn popping oil in the 
discharge line is equal to-the level of the oil in the container, 
considerably less popcorn popping oil remains in the discharge tubing or 
pipe to harden, or at least become more viscous. 
The provision of the drainback path as disclosed in the cited patent 
application require installation of not only the solenoid valve, but also 
a bypass fluid flow path in which to connect the solenoid valve. 
Electronic circuitry to control the energization of the solenoid valve is 
also required. Further, the bypass path itself provides a further flow 
path in which the popcorn popping oil may solidify if not heated. Thus, it 
would be desirable to provide a drainback arrangement without the 
requirement of providing piping or tubing for a separate path, and an 
electrically operated solenoid valve and related electronic control 
circuitry. 
SUMMARY OF THE INVENTION 
It is an object of this invention to provide an integral liquid pump and 
drainback valve bypassing the pump such that a separate drainback path 
including a solenoid operated valve is not required. It is a further 
object of this invention to provide an integral liquid pump and drainback 
valve which is of simple construction and of reduced cost. It is still 
another object of this invention to provide an integral liquid pump and 
drainback valve which is readily assembled from a minimal number of parts. 
Another object of this invention is to provide an integral liquid pump and 
drainback valve the components of which may be readily made from materials 
suitable for food handling purposes and which may be readily assembled and 
disassembled for cleaning purposes. 
In accordance with this invention, an integral liquid pump and drainback 
valve is formed with a two-part housing. A pump impeller cavity is formed 
in a first of the parts for receiving the pump impeller, which in a 
preferred embodiment is a pair of gears of a positive displacement gear 
pump. Also formed in the same housing part are outlet and inlet passages 
in fluid communications with the pump impeller cavity. The second housing 
part contains an inlet port in fluid communications with the inlet passage 
and an outlet port in fluid communications with the outlet passage for 
connection to a fluid supply line and a fluid discharge line respectively. 
Also formed in the second housing part is a shuttle valve cavity which is 
in fluid communications with both the inlet port and the outlet port. A 
resiliently biased shuttle is located in the shuttle valve cavity. 
When the pump impeller is not being driven, the shuttle is moved by the 
resilient biasing means to a position in which the inlet and outlet ports 
are in fluid communications through the shuttle valve cavity. When the 
pump impeller is driven, such that fluid is pumped from the inlet passage 
to the outlet passage, the pressure of the driven fluid in the outlet 
passage is applied to the shuttle which is moved against the resilient 
biasing force to open a path through the outlet passage and the outlet 
port. 
In a preferred embodiment of this invention, the two-part housing as well 
as the pump impeller, shuttle and resilient biasing means are formed of a 
material acceptable for handling foods such as aluminum or stainless 
steel. A circular groove formed in one of the housing members surrounds 
the pump impeller cavity and inlet and outlet passages such that when the 
housing parts are secured to each other, an O-ring placed in the groove 
forms a liquid tight seal between the housing parts.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring to the drawings, and particularly to FIGS. 1, 2, 4 and 5, a 
preferred embodiment of the integral liquid pump and drainback valve of 
this invention will be described. The integral liquid pump and drainback 
valve 10 is formed from two housing members 12 and 14. The housing members 
12 and 14 are generally of a rectangular shape and in a preferred 
embodiment are formed by machining aluminum blocks, each of which is 
provided with a planar facing side. The planar facing sides mate which 
each other when the housing is assembled. The first housing member 12 has 
formed in its planar facing side a pump impeller cavity 16 in the form of 
partially overlapping cylindrical cavities 18 and 20. Opening into the 
pump impeller cavity 16 is an inlet passage cavity 22 and an outlet 
passage cavity 24. In alignment with the cylindrical cavity 18 is a 
cylindrical bore 26 which extends through the housing member from the 
facing side to the opposite side. A cylindrical bore 28 is provided in 
alignment with the cylindrical cavity 20, but it does not extend through 
to the opposite side of the housing. 
An impeller formed of gears 30 and 32 is received within the pump impeller 
cavity 16. The gear 30 is provided with a shaft 34 which extends through 
the cylindrical bore 26 and projects from the opposite side of the 
housing. The gear 32 is provided with a shaft 36 which is received within 
the cylindrical bore 28, but which does not extend through the opposite 
side of the housing. 
The second housing member 14 is provided with a pair of cylindrical bores 
38 and 40 which extend through the housing member from the facing side to 
the opposite side. The bore 38 is placed such that when the housing 
members are secured to each other, it will be in alignment with the inlet 
passage 22 formed in the first housing member so as to form an inlet port. 
Similarly, the bore 40 is positioned such that a portion of it is in 
alignment with the outlet passage 22 so as to form an outlet port. 
A third cylindrical bore 42 is formed in the second housing member 14 
perpendicular to and intersecting the parallel bores 38 and 40 so as to 
form a shuttle valve cavity. One end of the shuttle valve cavity 42 
terminates in the outlet port 40, and the other end opens to a side of the 
housing where it is provided with internal threads 44. A cylindrical 
shuttle 46 is received within the shuttle valve cavity 42 and is biased 
toward the outlet port 40 by a coil spring 48. The coil spring 48 is 
received around a pin 50 which extends from an externally threaded plug 52 
and the end of which provides a stop for movement of the shuttle 46. The 
threaded plug 52 is engaged with the threads 44 in the shuttle valve 
cavity 42. 
A circular groove 54 is formed in the facing side of first housing member 
12 so as to encircle the pump impeller cavity 16 and the inlet and outlet 
passages 22 and 24. A resilient O-ring 56 is received within the circular 
groove 54. When the two housing members 12 and 14 are secured to each 
other with their planar facing sides 58 and 60 engaging each other, the 
O-ring 56 forms a seal therebetween. The housing members 12 and 14 are 
secured to each other by fastening means received in the holes 62, 64, 66 
and 68 formed in the four corners of the two housing members. 
As best shown in FIG. 2 and also in FIGS. 4 and 5, the cylindrical bores 38 
and 40 are internally threaded at their outer ends to receive external 
threads provided on fluid connectors 70 and 72 respectively. The 
connectors 70 and 72 have suitable engaging means 74 and 76 formed thereon 
to ensure a fluid tight connection with tubes connected thereto. 
Referring now to FIG. 5, when the shaft 34 of the gear 30 is driven, fluid 
is drawn through the connector 70, the inlet port 38 and inlet passage 22 
to be driven by the rotating gears 30 and 32 to the outlet passage 24. The 
pressure of the fluid being driven through the outlet passage 24 will 
cause the shuttle 46 to compress the springs 48 to a open path through the 
outlet port 40. Thus, a fluid may be drawn through the inlet port 38 and 
the inlet passage 22, to the pump cavity 16 and discharged through the 
outlet passage 24 and the outlet port 40. When the gear 30 is no longer 
driven, fluid pressure from the outlet passage 24 will no longer be 
adequate to overcome the biasing force of the spring 48 which will then 
force the shuttle 46 into the outlet port 40. With the shuttle positioned 
in the outlet port 40, a flow path is provided between the outlet port 40 
and the inlet port 38 through the shuttle valve cavity 46 as shown in FIG. 
4. 
The pressure required to move the shuttle against the force of the 
resilient means may be adjusted by adjusting the position of the threaded 
plug 52 in the threaded shuttle valve cavity 42. In which case the 
threaded plug 52 also serves as an adjusting means. 
Referring now to FIG. 3, an intended use of the integral liquid pump and 
drainback valve will be described. The inlet connector 70 of the integral 
liquid pump and drainback valve assembly 10 is connected by a tubing 78 to 
a discharge valve 80 provided on a storage or supply container 82. The 
outlet connector 72 of the assembly 10 is connected to a tubing 84 which 
terminates in a popping kettle 86. Thus, when a motor 88 driving shaft 34 
is de-energized, such that fluid is no longer pumped from the storage 
container 82 through the tubing 78 and the tubing 84 to the popping kettle 
86, the fluid in the discharge tubing 84 will drain back through the 
shuttle valve cavity 42 and the inlet tubing 78 to the storage container 
82. When the elevation of the fluid in the discharge tubing 84 is equal to 
that of the upper surface of the fluid stored in the container 82, the 
flow through the shuttle valve cavity 42 and the tubing will cease. While 
the popping kettle 86 is shown to be positioned just slightly above the 
storage container 82 in FIG. 3, in a typical installation, they would be 
separated by a greater vertical distance, and thus, a much longer segment 
of the discharge tubing 84 would be drained of fluid through the shuttle 
valve cavity 42. 
While not shown, the housing members 12 and 14 are secured to each other by 
fastening means such as bolts which extend through the holes 62, 64, 66 
and 68, and nuts. To periodically clean the integral pump and drainback 
valve, it is only necessary to release the fastening means to separate the 
housing parts from each other such that the gears 30 and 32 may be removed 
from the first housing part. Similarly, the shuttle 46 and spring 48 may 
be removed from the shuttle cavity by removing the plug 52 from the 
shuttle cavity. 
While in accordance with the U.S. Patent Statutes, a preferred embodiment 
of the invention has been shown and described, various changes may be made 
in the integral liquid pump and drainback valve of this invention without 
parting from the true spirit and scope of this invention. For instance, in 
another embodiment of this invention, the resilient biasing means, such as 
spring 48, urging the shuttle toward the outlet port may be omitted. In 
this embodiment, the housing is designed to be installed such that the 
side of the housing in which threaded plug 52 is received is the top of 
the housing. Installed in this way, the gravitational force on the shuttle 
46 will cause it to assume the position shown in FIG. 4 when the pump is 
not running. When the pump is running, the shuttle 46 will be lifted by 
the pumped fluid pressure to the position shown in FIG. 5. Thus, the 
gravitational force on the shuttle serves the same purpose as the 
resilient biasing means. 
The appended claims are intended to encompass all such changes and 
modifications which falls within the true spirit and scope of this 
invention.