Self-priming system for pumps

A self-priming pump system having a repriming valve opened in response to variations in fluid movement through a reservoir that includes a flow restriction. A control system is provided that includes a first sensor for sensing pressure within the flow restriction, a second sensor for sensing pressure within a portion of the reservoir spaced from the flow restriction, and a control mechanism for comparing the sensed signals and for opening the repriming valve when the difference between the signals falls to or below a predetermined value.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a self-priming pumping system. More 
particularly, the present invention relates to self-priming pumping 
systems of the type described in U.S. Pat. Nos. 3,370,604 and 3,381,618, 
the contents of which are incorporated herein by reference. 
2. Description of the Prior Art 
In the past, there have been many different devices developed to 
automatically prime a liquid pump when the pump runs dry due to an 
insufficient amount of liquid being present at the pump inlet and to 
prevent air from being introduced to the suction side of the pump. These 
devices are essential to the efficient operation of a pumping system, 
since, as is well known, once air is admitted to the suction passage in 
sufficient quantities to allow the pump to exhaust the supply of liquid in 
the suction well, the pump no longer is able to maintain suction to pump 
the liquid. Consequently, the pumping operation must be stopped and the 
attention of an operator is required, if no automatic mechanism for 
repriming the system is provided. 
Previously known automatic mechanisms, such as those described in the 
aforementioned U.S. patents and U.S. Pat. No. 3,434,430, generally provide 
satisfactory performance; however, problems are sometimes encountered when 
pumping high viscosity liquids over prolonged periods of time. During such 
pumping operations, vapor pressures can build up within the system and 
cause unnecessary actuations of the self-priming system. Also, difficulty 
has been experienced with previously known self-priming systems when the 
systems are used to pump liquids having different viscosities and/or vapor 
pressures. 
SUMMARY OF THE INVENTION 
In accordance with the present invention, a pump is primed by liquid from a 
suction well or reservoir located at the pump inlet. The suction well is 
normally supplied with liquid to be pumped by a suction line communicating 
with the liquid source of pumpage. A power-operated repriming valve is 
located in the pump discharge column to allow automatic recycling of 
liquid from the discharge line to the suction well when the pump has lost 
suction. A one-way check valve is positioned downstream from the repriming 
valve and allows fluid movement only in the downstream direction, and thus 
limits the quantity of liquid which may be recycled to that in the system 
between the priming valve and the check valve. An air relief line with a 
one-way check valve connects the top of the suction well to the discharge 
column intermediate the first mentioned check valve and the repriming 
valve. Air is displaced from the suction well through the air relief line 
by the liquid which is recycled from the discharge column through the 
repriming valve to the suction well. When a portion of the recycled liquid 
flows from the suction well into the pump inlet, the liquid will be pumped 
into the discharge column causing the repriming valve to close. If the 
pump is not fully reprimed, the repriming valve will thereafter again 
allow the same liquid to be recycled to the suction well. This recycling 
will continue in this fashion until the normal pumping cycle is restored. 
The present invention is designed for automatically repriming single or 
multi-stage pumps employing any reasonable length suction line. In the 
event of loss of suction head due to the pump running dry, there is no 
danger of pump damage since the system will continue to reprime itself. 
According to a feature of the present invention, an air relief line vents 
air from the impeller inlet casing. It has been found that when liquid in 
the suction well is exhausted and air is sucked into the pump, an air lock 
may be formed between the inlet of the pump intake line and the impeller. 
This entrapped air may keep liquid from reaching that point in the 
impeller section of the pump where sufficient velocity can be imparted to 
it to force the liquid and the entrapped air into the discharge column. By 
the use of an air relief line extending through the casing of the pump 
impeller chamber, a path is provided for venting such entrapped air when 
the repriming fluid flows into the pump inlet. According to a still 
further feature of the present invention, the controlled automatic 
recycling of liquid from the discharge side of a pump to its suction side 
is provided by a controllable power actuated valve that responds to the 
loss of suction of the pump, as evidenced by a reduced flow level. The 
amount of pressure variation required to actuate the valve is selectively 
variable so that the system responds to the characteristics of the fluid 
being pumped. 
The present invention also provides a self-priming system having a 
power-operated priming mechanism so that positive priming action can be 
achieved under power after either long periods of inactivity, when system 
mechanisms are likely to be fouled, or when system mechanisms are likely 
to become fouled do to the characteristics of the liquid being pumped. 
Still another feature of the present invention is the provision of a system 
that prevents a pump from running without lubrication due to loss of 
suction fluid, which can be caused by the closing of valves on tanks from 
which the pump is taking liquid, or from pumping the liquid level in the 
tank to a point below that which can be accommodated by the pump being 
used. 
Yet another feature of the present invention is the provision of a 
self-priming pumping system using a tunable power-operated priming 
mechanism that allows a system designer or operator to determine the point 
at which the positive priming action takes place. This feature enables the 
system to accommodate required changes and to accommodate a wide range of 
pumped fluids. 
The invention, and its objects and advantages, will become more apparent in 
the detailed description of a preferred embodiment presented below.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
Because self-priming systems for pumps are well known, the present 
description will be directed in particular to elements forming part of, or 
cooperating more directly with, the present invention. Elements not 
specifically shown or described herein are understood to be selectable 
from those known in the art. 
Referring now to the drawing, a self-priming system, which is generally 
designated 10, is illustrated. The system 10 is intended for use with a 
pumping system having a suction well or casing 12 which acts as a 
reservoir for priming liquid 14. In normal operation, liquid 14 is 
supplied to the suction well through a suction line 16 having a tank 
suction valve 18 positioned therein. One end of line 16 is connected to 
well 4, while the other end is connected to pumpage 20. A suction skirt 22 
is positioned with its lower end adjacent the bottom of suction well 12 
and is connected at its other end to an inlet 24 of a pump 26. The pump 
26, which may be either a horizontal or vertical pump, is driven by a 
motor 28 or other suitable mechanism. In the illustated embodiment, 
suction skirt 22 has a curved upper portion, the lower inner surface of 
which is approximately level with the upper inner surface of the eye of 
the impeller, i.e., the horizontal inlet 24. A small aperture may be 
provided in the curved upper portion of the skirt 22 to function as an air 
bleed between this portion of the skirt and the top of the suction well 
12. It is also possible to connect the vertically extending portion of 
skirt 22 to the pump inlet without elevating the upper portion of the 
skirt above the pump inlet 24, for example, by means of a 90.degree. pipe 
elbow. 
Pump 26 pumps fluid through an inlet 30 and a venturi 32, to be described 
hereinafter, into a tee fitting 34 and a discharge column 36. A one-way 
check valve 38 is positioned at the upper end of the discharge column 36 
and connects the discharge column to a discharge line 42. A commercially 
available power-operated valve, commonly referred to as a repriming valve 
or priming valve 44, having a power controller 46, leads from the tee 
fitting 34 through a drain line 48 to the top of the suction well 12, so 
that liquid may be recycled in a manner to be described hereinafter to 
reprime the pump 26. The liquid in discharge column 36 and the quantity of 
liquid in tee fitting 34 above the level of drain pipe 48 are available to 
reprime the pump. Therefore, the discharge column 36 and the 
above-mentioned portion of tee fitting 34 effectively function as a 
reservoir for repriming liquid. The volumetric capacity of this reservoir 
is at least sufficient to ensure that the quantity of liquid available to 
reprime the pump is sufficient to fill the pump inlet, inlet skirt 24, 
skirt 22, and suction well 12 to a level corresponding to the level of the 
eye of the pump impeller. An air relief conduit 50 leads from the top of 
the enclosed suction well 12 to the upper end of the discharge column 36 
upstream from the check valve 38. A one-way check valve 52 in conduit 50 
allows fluid movement only in a direction towards discharge column 36 to 
prevent liquid in column 36 from returning to the suction well via conduit 
50. 
A pressure sensing tube 53 is connected from an opening in the throat of 
the venturi 32 to the power controller 46. A second pressure sensing tube 
54 is connected from an opening in the discharge column 36 to the power 
controller 46. The power controller 46 is supplied with air via line 56. 
Alternatively, power controller 46 can be operated by another power fluid, 
such as hydraulic oil, or can be operated electrically such that the 
operating medium in line 58 controls the position of the priming valve 44. 
The controller 46 is a commercially available unit and is externally 
adjustable through an adjusting mechanism 60 in accordance with the 
readings on a valve actuating pressure gauge 62 and the gauges 64 and 66, 
which read the sensed venturi pressure and the sensed discharge column 
pressure, respectively. 
The operation of the self-priming system illustrated in the drawing will 
now be described. 
When the system 10 is idle and no liquid is being pumped, the priming valve 
44 is in the closed position and is held closed by a spring or other 
suitable mechanism. 
When liquid is being pumped during normal operation, the priming valve 44 
is also in the closed position in that the power controller 46 senses the 
differential pressure between line 53 and line 54, due to the velocity 
head of the liquid being moved through the venturi 32, and operates to 
maintain the valve in closed position. 
When the velocity of the liquid flowing through the system is reduced or is 
stopped by, for example, the introduction of air or other gases to the 
pump suction when, for example, the pumpage 20 is at a reduced level, or 
by the closure of tank suction valve 18, the pressure differential between 
the sensing lines 54 and 53 is reduced inasmuch as the velocity head of 
the fluid being pumped is reduced. In this case, the power controller 46 
acts to open the priming valve 44, thereby dumping or discharging the 
liquid in discharge column 36 through tee 34, valve 44, and line 48 to the 
suction well 12. This dumping or discharging ensures that pump 26 has a 
sufficient supply of fluid at its suction inlet 22. 
The point at which priming valve 44 opens in response to a change in 
pressure differential is influenced by many factors, such as the viscosity 
of the fluid being pumped and the vapor pressure of the fluid. Therefore, 
in order to enable the system operator to suitably adjust the response 
point, priming valve controller 46 is provided with an adjusting knob 60 
to vary the amount of valve actuating pressure in line 58 in proportion to 
and in response to a predetermined pressure differential sensed in lines 
53 and 54. 
As repriming liquid enters into suction well 12, air is displaced through 
air relief conduit 50 and check valve 52 into the now empty upper end of 
discharge column 36. When the repriming flue from the suction well passes 
through the suction skirt 22 into the pump inlet 24, the pump 26 then 
draws the repriming liquid out of the suction well and pumps it into the 
discharge column 36. The flow of the repriming liquid from the pump outlet 
reestablishes the pressure differential which causes the power controller 
46 to move the repriming valve 44 into a closed position. Check valve 52 
closes as the liquid enters the discharge column 36, and the air which has 
entered the discharge column is now forced through check valve 38 into 
discharge line 42. The removal of liquid from the suction well 12 reduces 
the pressure at the opening of suction line 16, so that liquid is drawn 
upward therein. When the repriming liquid is depleted, the cycle is 
repeated as many times as necessary until suction is reestablished for the 
pump 26. Factors such as the length and diameter of the suction line 16 
determine how many times the pump will be reprimed before full pumpage 
flow is reestablished. 
As an aide to understanding the present invention, some components usable 
with the present invention will now be identified. A suitable repriming 
valve 44 is manufactured by the Norris Division of The Dover Corporation. 
The valve uses a NORRISEAL diaphragm actuator to control a NORRISEAL 
butterfly valve. Suitable pressure sensing elements associated with lines 
53 and 54 include the model 40 series pneumatic indicating controllers and 
transmitters for pressure manufactured by the Ametek Controls Division. A 
suitable power controller 46 is the electronic indicating differential 
pressure transmitter, model 70, also manufactured by the Ametek Controls 
Division of Feasterville, Pennsylvania. 
While a preferred embodiment of the present invention has been illustrated 
and described, it will be understood that various changes and 
modifications may be made without departing from the scope and spirit of 
the present invention. Accordingly, the present invention is intended to 
encompass all changes and modifications that fall within the scope and 
spirit of the appended claims.